Your search keyword '"Taccola G"' showing total 57 results

1. La museificazione del dolore. L'elaborazione del trauma della Grande guerra tra mostre e musei nel primo dopoguerra

Author

Bracco, B, Ungari, A, Taccola, G, Bracco, B, Ungari, A, and Taccola, G

Published

2023

2. A cento anni dalla 'Marcia su Roma': memorie dalle Civiche Raccolte Storiche di Milano

Author

Fondazione Anna Kuliscioff, Taccola, G, Fondazione Anna Kuliscioff, and Taccola, G

Published

2023

3. Le case e i traslochi di Quarto Stato. Appunti per una storia espositiva e museale

Author

Addari, A, Alberti, R, Bolzacchini, E, Bracco, B, Bigogno, A, Bonizzoni, L, Caccia, M, Caglio, S, Castiglioni, I, Cefalì, AM, Capurro, R, Caramenti, M, De Nicola, A, Edallo, E, Facchinetti, F, Ferrero, L, Galli, A, Gargano, M, Germagnoli, F, Giacon, D, Grifoni, E, Interlenghi, M, Lantini, R, Ludwig, N, Martini, M, Melada, J, Montaldo, AM, Nascimbene, R, Nuvolati, G, Rota, M, Pernigotti, P, Perticucci, I, Palifori, A, Reale, R, Schiavi, A, Scotti Tosini, A, Tacci, M, Taccola, G, Tariffi, F, Zuccoli, F, Taccola G, Addari, A, Alberti, R, Bolzacchini, E, Bracco, B, Bigogno, A, Bonizzoni, L, Caccia, M, Caglio, S, Castiglioni, I, Cefalì, AM, Capurro, R, Caramenti, M, De Nicola, A, Edallo, E, Facchinetti, F, Ferrero, L, Galli, A, Gargano, M, Germagnoli, F, Giacon, D, Grifoni, E, Interlenghi, M, Lantini, R, Ludwig, N, Martini, M, Melada, J, Montaldo, AM, Nascimbene, R, Nuvolati, G, Rota, M, Pernigotti, P, Perticucci, I, Palifori, A, Reale, R, Schiavi, A, Scotti Tosini, A, Tacci, M, Taccola, G, Tariffi, F, Zuccoli, F, and Taccola G

Published

2020

4. «Memorie di un centurione della Grande Guerra». Il pittore Max Guala tra immagini e parole

Author

Taccola, G and Taccola, G

Abstract

In this article, painter Max Guala’s experience during the Great War is reconstructed for the first time by connecting the words of his war diaries with the images of 162 graphic works now preserved in the Historical Collections of Milan. The first-person narration and the narrative elaborated by the history museum are two moments of the same memorial process that transformed ego-documents into civic monuments for eternal preservation. The museum history of the Guala’s words and images allows us to reconsider this process, to overcome the grand narrative and reflect on the museology of history.

Published

2022

5. La ricostruzione dei panorami

Author

Almini, S, Taccola, G., Bianchi, A, Almini, S., Taccola, G, Gregorio Taccola, Almini, S, Taccola, G., Bianchi, A, Almini, S., Taccola, G, and Gregorio Taccola

Published

2019

6. Schede delle opere

Author

Leydi, S., Orsini, O., Vismara, N., Buss, C., Rocca, A., Tosi, L., Bitto, A. De Rosa, R., Domenici, D., Riello, G., Antonini, A., Bianchi, A., Mazzeo, E., Francina, C., Barzett, G, Berthe, S., Taccola, G., De Palma, I., Sebath, K, Villa, F., Santanera, G., Bargna, L, Bargna, LI, Leydi, S., Orsini, O., Vismara, N., Buss, C., Rocca, A., Tosi, L., Bitto, A. De Rosa, R., Domenici, D., Riello, G., Antonini, A., Bianchi, A., Mazzeo, E., Francina, C., Barzett, G, Berthe, S., Taccola, G., De Palma, I., Sebath, K, Villa, F., Santanera, G., Bargna, L, and Bargna, LI

Published

2021

7. Il cavaliere dell’Apocalisse alla foce del fiume Magra: domande e metodologie di una ricerca-azione per lo studio integrato del territorio

Author

Taccola, G and Taccola, G

Published

2021

8. Le fonti africane al Civico Museo di Storia: il Museo di Guerra al Castello Sforzesco

Author

Taccola, G and Taccola, G

Published

2021

9. Milano città museo

Author

Capurro, R, Galli, A, Taccola, G, Nuvolati, G, Capurro, R, Galli, A, Taccola, G, and Nuvolati, G

Published

2021

10. Acute neuromodulation restores spinally-induced motor responses after severe spinal cord injury.

Author

Taccola G, Gad P, Culaclii S, Wang P-M, Liu W, Edgerton VR, Taccola G, Gad P, Culaclii S, Wang P-M, Liu W, and Edgerton VR

Abstract

Epidural electrical spinal stimulation can facilitate recovery of volitional motor control in individuals that have been completely paralyzed for more than a year. We recently reported a novel neuromodulation method named Dynamic Stimulation (DS), which short-lastingly increased spinal excitability and generated a robust modulation of locomotor networks in fully-anesthetized intact adult rats. In the present study, we applied repetitive DS patterns to four lumbosacral segments acutely after a contusive injury at lumbar level. Repetitive DS delivery restored the spinally-evoked motor EMG responses that were previously suppressed by a calibrated spinal cord contusion. Sham experiments without DS delivery did not allow any spontaneous recovery. Thus, DS uniquely provides the potential for a greater long-term functional recovery after paralysis.

Published

2020

11. Using EMG to deliver lumbar dynamic electrical stimulation to facilitate cortico-spinal excitability.

Author

Taccola G, Gad P, Culaclii S, Ichiyama RM, Liu W, Edgerton VR, Taccola G, Gad P, Culaclii S, Ichiyama RM, Liu W, and Edgerton VR

Abstract

BACKGROUND:Potentiation of synaptic activity in spinal networks is reflected in the magnitude of modulation of motor responses evoked by spinal and cortical input. After spinal cord injury, motor evoked responses can be facilitated by pairing cortical and peripheral nerve stimuli. OBJECTIVE:To facilitate synaptic potentiation of cortico-spinal input with epidural electrical stimulation, we designed a novel neuromodulation method called dynamic stimulation (DS), using patterns derived from hind limb EMG signal during stepping. METHODS:DS was applied dorsally to the lumbar enlargement through a high-density epidural array composed of independent platinum-based micro-electrodes. RESULTS:In fully anesthetized intact adult rats, at the interface array/spinal cord, the temporal and spatial features of DS neuromodulation affected the entire lumbosacral network, particularly the most rostral and caudal segments covered by the array. DS induced a transient (at least 1 min) increase in spinal cord excitability and, compared to tonic stimulation, generated a more robust potentiation of the motor output evoked by single pulses applied to the spinal cord. When sub-threshold pulses were selectively applied to a cortical motor area, EMG responses from the contralateral leg were facilitated by the delivery of DS to the lumbosacral cord. Finally, based on motor-evoked responses, DS was linked to a greater amplitude of motor output shortly after a calibrated spinal cord contusion. CONCLUSION:Compared to traditional tonic waveforms, DS amplifies both spinal and cortico-spinal input aimed at spinal networks, thus significantly increasing the potential and accelerating the rate of functional recovery after a severe spinal lesion.

Published

2020

12. Arte, musei e partecipazione

Author

Capurro, R, Galli, A, Taccola, G, De Nicola, A, Zuccoli, F, Capurro, R, Galli, A, Taccola, G, De Nicola, A, and Zuccoli, F

Abstract

Le riflessioni del contributo provano a esaminare l'opera Quarto Stato, grazie a un questionario, in relazione ai futuri docenti e al ricordo di come questo quadro è stato proposto nei loro percorsi scolastici. Lo scritto presenta alcuni dei dibattiti attuali maturati sulla partecipazione al patrimonio culturale.

Published

2020

13. Nel Quarto Stato: indagine interdisciplinare sull’opera di Giuseppe Pellizza da Volpedo

Author

Galli, A, Capurro, R, Taccola, G, Galli, A, Capurro, R, and Taccola, G

Abstract

Il volume, di solido impianto scientifico ma taglio divulgativo, presenta i risultati inediti del progetto interdisciplinare Mobartech (finanziato da Regione Lombardia nell’ambito di un ampio intervento nel quadro dei Fondi Europei di Sviluppo Regionale, FESR, previsto nel Programma Operativo Nazionale) per il caso di studio Quarto Stato di Giuseppe Pellizza da Volpedo. Al progetto prendono parte quattro dipartimenti dell’Università di Milano-Bicocca in partnership con altre importanti istituzioni italiane di ricerca scientifica: l’Università di Milano, l’Università Cattolica, l’Istituto IBFM del Consiglio Nazionale delle Ricerche, CNR, l’Istituto Eucentre, che svolge attività di ricerca, sviluppo e innovazione nel settore del patrimonio culturale, dell’ingegneria sismica e, più in generale, dell’ingegneria della sicurezza, la XGLab del gruppo Bruker, che sviluppa strumentazione scientifica in particolare nell’analisi elementare e la società Space, impresa che opera nel settore delle tecnologie dell’informazione applicate alla valorizzazione e gestione del patrimonio culturale. L’opera viene studiata da vari punti di vista: i) storico e sociale, approfondendo il suo significato nel contesto di produzione e di uso pubblico; ii) materico e composizionale, studiando le tecniche e i materiali con i quali è stata realizzata; iii) di interazione con l’ambiente e il pubblico, elaborando prospettive di conservazione e valorizzazione. Il volume si articola in tre parti: nella prima si affronta il significato proprio dell’opera nei suoi contesti prima di produzione quindi nei successivi museali ed espositivi; nella seconda parte si illustrano le diverse modalità di studio dello spazio di conservazione, degli elementi materiali dell’opera e la fruizione da parte del pubblico contemporaneo; infine, nella terza parte si avanzano alcune proposte per la migliore conservazione e fruizione dell’opera. Gli autori dei contributi sono ricercatori afferenti al progetto e altri e

Published

2020

14. Automatic calibration with character recognition software

Author

Taccola, G M, primary and Saita, M T, additional

Published

2021

15. Reti di big data e digital storytelling: conoscere e raccontare il patrimonio delle Civiche Raccolte Storiche di Milano

Author

Paci, D, Almini, S, Taccola, G, Saverio Almini, Gregorio Taccola, Paci, D, Almini, S, Taccola, G, Saverio Almini, and Gregorio Taccola

Abstract

Avvalendosi dell’informatica la storiografia ha potuto elaborare grandi quantità di dati che, grazie alla pubblicazione infotelematica, possono essere confrontati attraverso reti di relazioni non predeterminate. La condivisione e l’accumulazione delle conoscenze prodotte mediante le digital technologies è però ostacolata dalla disomogeneità nelle pratiche di raccolta e trasmissione dei big data. Questo contributo nasce da un caso di studio di ambito museale per dimostrare le potenzialità del digital storytelling nell’integrare in modo scientifico, accessibile ed efficace le basi di dati elaborate per rispondere alle necessità di pubblici differenziati. Il Museo del Risorgimento di Milano possiede una serie di registri iniziata nel 1884 e tuttora aperta, nella quale sono annotati i materiali che entrano a far parte del patrimonio eterogeneo dell’istituto (collezioni settoriali, biblioteca e archivio). A questa continuità nella prassi amministrativa si è contrapposta nel tempo una discontinuità nell’organizzazione delle raccolte, che ha ottenebrato i nessi originari tra gli oggetti, cioè la storia che è loro propria. L’uso di software diversi per la descrizione dei beni culturali e la pubblicazione in rete ha confermato la difficoltà di integrare big data strutturati in modo difforme con insufficiente attenzione per la dimensione gerarchica. Nell’era digitale il professionista in public history può avvalersi dello storytelling per ricostruire l’informazione frammentata in diversi repository di big data. Trasformando in affabulazione le reti di relazioni è possibile integrare le conoscenze in schemi coerenti per suscitare nei pubblici la percezione della realtà come complesso di fattori talvolta in contraddizione ma senza rinunciare agli strumenti di verificabilità del racconto.

Published

2019

16. Antonio Monti e l’Archivio della guerra

Author

Almini, S., Taccola, G, Bianchi, A, Almini, S, Gregorio Taccola, Almini, S., Taccola, G, Bianchi, A, Almini, S, and Gregorio Taccola

Published

2019

17. Custodire e interpretare la storia

Author

Almini, S, Taccola, G, Bianchi, A, gregorio taccola, Almini, S, Taccola, G, Bianchi, A, and gregorio taccola

Published

2019

18. Un’arca di memorie

Author

Almini, S, Taccola, G, Bianchi, A, gregorio taccola, Almini, S, Taccola, G, Bianchi, A, and gregorio taccola

Published

2019

19. Emilio Franzina, Al caleidoscopio della Gran Guerra. Vetrini di donne, di canti e di emigranti (1914-1918)), Isernia, Cosmo Iannone Editore, 2005

Author

Taccola, G, gregorio taccola, Taccola, G, and gregorio taccola

Published

2019

20. And yet it moves: Recovery of volitional control after spinal cord injury

Author

Taccola, G, Sayenko, D, Gad, P, Gerasimenko, Y, Edgerton, VR, Taccola, G, Sayenko, D, Gad, P, Gerasimenko, Y, and Edgerton, VR

Abstract

© 2017 The Authors Preclinical and clinical neurophysiological and neurorehabilitation research has generated rather surprising levels of recovery of volitional sensory-motor function in persons with chronic motor paralysis following a spinal cord injury. The key factor in this recovery is largely activity-dependent plasticity of spinal and supraspinal networks. This key factor can be triggered by neuromodulation of these networks with electrical and pharmacological interventions. This review addresses some of the systems-level physiological mechanisms that might explain the effects of electrical modulation and how repetitive training facilitates the recovery of volitional motor control. In particular, we substantiate the hypotheses that: (1) in the majority of spinal lesions, a critical number and type of neurons in the region of the injury survive, but cannot conduct action potentials, and thus are electrically non-responsive; (2) these neuronal networks within the lesioned area can be neuromodulated to a transformed state of electrical competency; (3) these two factors enable the potential for extensive activity-dependent reorganization of neuronal networks in the spinal cord and brain, and (4) propriospinal networks play a critical role in driving this activity-dependent reorganization after injury. Real-time proprioceptive input to spinal networks provides the template for reorganization of spinal networks that play a leading role in the level of coordination of motor pools required to perform a given functional task. Repetitive exposure of multi-segmental sensory-motor networks to the dynamics of task-specific sensory input as occurs with repetitive training can functionally reshape spinal and supraspinal connectivity thus re-enabling one to perform complex motor tasks, even years post injury.

Published

2018

21. Il 1866 ne Museo del Risorgimento di Milano: raccogliere, ordinare, esporre

Author

Taccola, G.

Subjects

Settore M-STO/04 - Storia Contemporanea

Published

2016

22. Phosphorylation and Alternative Splicing of MEF2C, a Dual Switch Function in Muscle Regeneration

Author

Riuzzi, F., Beccafico, S., Sorci, G., Donato, R., Baruffaldi, F., Badodi, S., De Feo, L., Ganassi, M., Battini, R., Imbriano, C., Nicoletti, C., Musarò, A., Buckingham, M., Montarras, D., Molinari, S., Marroncelli, N., Noviello, C., Di Francescantonio, S., Consalvi, S., Saccone, V., Puri, P. L., Olson, E. N., Adamo, S., Moresi, V., Spada, F., Fuoco, C., Pirrò, S., Reggio, A., Paoluzi, S., Gargioli, C., Castagnoli, L., Cesareni, G., Basile, V., Dolfini, D., Ricci, L., Mantovani, R., Mancinelli, R., Guarnieri, S., Di Filippo, E.S., Pietrangelo, T., Fulle, S., Giordani, L., Le Grand, F., Giacomazzi, G., Quattrocelli, M., Sampaolesi, M., Serena, E., Zatti, S., Mattei, N., Vetralla, M., Giulitti, S., Selmin, G., Torchio, E., Vitiello, L., Elvassore, N., Marinkovic, M., Pavlidou, T., Ziraldo, G., Taccola, G., Coslovich, T., Lorenzon, P., Sciancalepore, M., Marcucci, L., Washio, T., Yanagida, T., Niewiadomski, P., Gawor, M., Bernadzki, K., Jóźwiak, J., Rojek, K., Rędowicz, M. Jolanta, Prószyński, T., Boncompagni, S., Michelucci, A., Pietrangelo, L., Dirksen, R.T., Protasi, F., Pisu, S., Rizzuto, E., Del Prete, Z., Nogara, L., Naber, N., Pate, E., Canton, M., Cooke, R., Reggiani, C., Bianco, P., Melli, L., Falorsi, G., Pertici, I., Coceano, G., Cojoc, D., Lombardi, V., Pierucci, F., Frati, A., Battistini, C., Bruzzone, E., Matteini, F., Penna, F., Costelli, P., Meacci, E., Passafaro, M., Madaro, L., Schirone, L., Berghella, L., Puri, P.L., Pin, F., Ballarò, R., Costamagna, D., Martinelli, G.B., Olivari, D., Talamini, L., Lecker, S.H., Ottoboni, L., Resovi, A., Giavazzi, R., Cervo, L., Piccirillo, R., Martinelli, G. B., Re Cecconi, A., Cerruti, F., Cascio, P., Bach, M. Beltrà, Guttridge, D.C., Giovarelli, M., Touvier, T., Clementi, E., DePalma, C., Pescatore, F., Albiero, M., Lutz, C., Schiaffino, S., Sandri, M., Conte, M., Armani, A., Franceschi, C., Salvioli, S., Petrilli, L.L., Codenotti, S., Faggi, F., Poliani, P. L., Cominelli, M., Chiarelli, N., Colombi, M., Vezzoli, M., Monti, E., Bono, F., Tulipano, G., Fiorentini, C., Zanola, A., Gavazzi, S., Lo, H. P., Parton, R. G., Keller, C., Fanzani, A., Mitola, S., Ronca, R., Bouche, M., Poliani, L., Longhena, F., Salani, B., Maggi, D., Kravic, B., Harbauer, A. B., Simeone, L., Kaiser, T., Romanello, V., Buttgereit, A., Neuhuber, W., Straubinger, M., Heuss, D., Rudolf, R., Friedrich, O., Meisinger, C., Hashemolhosseini, S., Huraskin, D., Eiber, N., Reichel, M., Zidek, L., Bernkopf, D., von Maltzahn, J., Behrens, J., Gherardi, G., Mammucari, C., Zamparo, I., Raffaello, A., Chemello, F., Cagnin, S., Braga, A., Zanin, S., Pallafacchina, G., Zentilin, L., De Stefani, D., Lanfranchi, G., Rizzuto, R., Perpetuini, A. Cerquone, Desiderio, G., Chrisam, M., Castagnaro, S., Spizzotin, M., Braghetta, P., Grumati, P., Cecconi, F., Bonaldo, P., Filomena, M.C., Yamamoto, D.L., Mastrototaro, G., Carullo, P., Caremani, M., Lieber, R., Nigro, V., Linari, M., Chen, J., Bang, M.L, Lo Verso, F., Soares, R., Albiero1, M., Guescini, M., Pelosi, L., Coggi, A., Forcina, L., Legnini, I., Di Timoteo, G., Rossi, F., Briganti, F., Sthandier, O., Morlando, M., Fatica, A., Andronache, A., Wade, M., Rajewsky, N., Bozzoni, I., Testa, S., Bianconi, V., Petrilli, L. L., Bernardini, S., Cannata, S., Torcinaro, A., De Santa, F., De Marco, A., Hamilton, S. L., Paolini, C., Canato, M., Salvadori, L., Sagheddu, R., Chiappalupi, S., Di Fonso, A., D’Onofrio, L., Camps, J., Carotenuto, F., Minieri, M., Di Nardo, P., Pigna, E., Coletti, D., Cescon, M., Gattazzo, F., Sabatelli, P., Megighian, A., Sanchez-Riera, C., Lahm, A., Guido, L., Cipriano, A., Tita, R., Bisceglie, L., Ballarino, M., Martini, M., Dobrowolny, G., Del Re, V., Spinozzi, S., Gamberucci, A., Barone, V., Sorrentino1, V., Sandonà, M., Tucciarone, L., Marsolier, J., Patissier, C., Gicquel, E., Adjali, O., Richard, I., Giambruno, R., Micheloni, S., Ferri, G., Jothi, M., Cabianca, D. S., Huber, J., Warner, S., and Gabellini, D.

Subjects

MyoNews, Article

Abstract

Muscle regeneration is a multistep process that is regulated by a restricted number of transcription factors whose activity is modulated at multiple levels. However, how different layers of regulation are coordinated to promote adult myogenesis is not yet understood. Here we show that the MEF2C transcription factor controls multiple steps of muscle regeneration, including myogenic progression of satellite cells and muscle maturation of newly generated myofibers, exhibiting multiple functions that depend on alternative splicing and post-translational modifications. Inclusion of the α1 exon in Mef2c transcripts is upregulated in proliferating mouse satellite cells and in the early phases of muscle regeneration. The encoded MEF2Cα1 isoform stimulates expansion of primary myoblasts ex vivo and in vivo. The pro-proliferative activity of MEF2C is mediated by phosphorylation of two phosphoserines located in exon α1. Subsequent terminal differentiation and growth of newly formed myofibers are promoted by dephosphorylated MEF2Cα1 and MEF2Cα2. Our results thus reveal an important role for regulatory interactions between alternative splicing and post translational modifications of a single transcription factor in the control of the multilayered regulatory programs required for adult myogenesis., Skeletal muscle exhibits a high capacity to regenerate, mainly due to the ability of satellite cells to replicate and differentiate in response to stimuli. Epigenetic control is effective at multiple steps of this process. The chromatin remodeling factor, HDAC4, is up-regulated in skeletal muscle upon injury, suggesting a role for this protein in muscle regeneration. With the aim to elucidate the role of HDAC4 in satellite cells and skeletal muscle regeneration, we generated inducible mice lacking HDAC4 in Pax7+ cells (HDAC4 KO mice). Despite having similar amount of satellite cells, HDAC4 KO mice show impaired muscle regeneration in vivo, and compromised satellite cell proliferation and differentiation in vitro. HDAC4 deletion in satellite cells is sufficient to block their differentiation, not acting via soluble factors, and possibly through the inhibition of Pax7 expression. The molecular mechanisms underling compromised muscle regeneration in HDAC4 KO mice are currently under investigation. All together, these data delineate the importance of HDAC4 in satellite cell differentiation and suggest a protective role of HDAC4 in response to muscle damage., The adult skeletal muscle has the ability to self-renew and repair in response to increased workload, stress conditions or limited damage. These properties rely on an array of different progenitor cell populations. While satellite cells play a central role in muscle regeneration, a variety of other mononuclear progenitor cells, either resident in the muscle or recruited from the blood stream, contribute to the complex crosstalk leading to muscle repair. In pathological conditions or with aging, the relative abundance and the activation stage of the different cell populations in the myogenic stem cell compartment vary. The ability to probe the heterogeneity and the dynamic of the muscle tissue is fundamental to achieve a complete understanding of muscle regeneration. To this end we have invested in a novel approach exploiting mass cytometry technology (CyTOF2 platform). CyTOF technology enables probing single cell events, by labelling intracellular and cell surface markers with up to 40 antibodies tagged with stable heavy metal isotopes. The sharp mass peaks obtained by TOF inductively coupled plasma mass spectrometry eliminates the problems of spectra overlap typical of fluorescence based flow cytometry. I will describe the panel of tagged antibodies that I have developed to characterize the heterogeneous muscle mononuclear cell populations and the advantages and limitations of mass cytometry. In addition I will present preliminary data on the dynamic of cell populations under different conditions and stimuli., The mechanisms that regulate skeletal muscle development involve the coordinated activity of transcription factors (TFs) and a precise timing of gene expression patterns. NF-Y is a heterotrimeric TF with a pioneer role in the transcriptional and epigenetic regulation of promoters containing the CCAAT-box. NF-Y activates the expression of various genes related to the cell cycle, particularly genes of the G2/M phase. NF-YA, the regulatory DNA-binding subunit of the complex, is expressed in proliferating myoblasts and down-regulated during terminal differentiation. The NF-YA gene encodes for two alternatively spliced isoforms, namely NF-YAs and NF-YAl, which are not functionally identical. Using mouse C2C12 cells, we provide evidence of a different role for NF-YA variants in the myogenic program. While NF-YAs enhances myoblasts proliferation, NF-YAl boosts their differentiation by up-regulating the transcription of novel target genes, among which Mef2D, Sixs and Cdkn1C, which are known to be involved in the differentiation program. We further demonstrate that NF-YA is expressed in resident stem cells (SCs) and the two isoforms are transcribed at different levels during SCs activation and differentiation. The inhibition of NF-Y activity impairs both proliferation and differentiation of SCs and the overexpression of the two NF-YA isoforms differentially affects their fate., Sarcopenia is the age-related loss of muscle leading to loss of muscle power, which in the end results in frailty and disability. At molecular level, sarcopenia is characterized by insufficient antioxidant defense mechanism, increased oxidative stress and altered function of respiratory chain. It has been hypothesized that the accumulation of oxidative stress is also related to an impaired regeneration cooperating to the atrophic state that characterizes muscle ageing. To the purpose, we investigated the myogenic process in satellite cells, the skeletal muscle stem cells, as myoblasts and myotubes collected by human Vastus Lateralis skeletal muscle of young and old subjects through needle-biopsies. To measure both the O2- and ROS level we used NBT and H2DCF-DA assays revealing higher concentration in elderly myoblasts compared to young ones. To evaluate if mitochondria are damaged by ROS we measured mitochondrial transmembrane potential after an oxidant insult as H2O2. We found that in elderly myoblasts mitochondrial transmembrane potential decreases much more than in young ones probably due to their lower endogenous antioxidant abilities. Specifically, MitoSOX™ Red reagent for direct measurements of O2- in mitochondria revealed that in elderly myoblasts O2- production is increased respect to young ones and the result is worsened in myotubes. Furthermore, the upregulation of the atrophic and ubiquitin-proteasome pathways together with a dysregulation of the proliferative one revealed an alteration at gene expression level in elderly myoblasts vs young ones. Overall our data confirm that oxidative stress impairs muscle regeneration in elderly subjects., Skeletal muscle is a complex structure endowed with extreme regenerative capability; this ability relies on the orchestrated interplay between different muscle populations that reside within the tissue. Functional changes occurring at the microenvironmental level during aging or pathological conditions however interfere with this ability leading to fibrosis and fat infiltration. Despite a large body of work still we are far from completely understanding these changes; even when genetic cause is known (e.g. Duchenne muscular Dystrophy) we are still unable to pin-point the steps that lead from the molecular cause to the outcome of the disease. The main reason for this bottleneck is that our knowledge has been limited so far by the lack of technical tools to dissect the heterogeneity of these populations. The use of bulk-scale methods able only to provide averaged information has frustrated our effort to characterize those pathological changes leaving those dysfunctional, disease-specific subpopulation to remain hidden within the bulk. Here we present a novel approach based on single cell mass spectrometry to study the populations that reside in the muscle. Using Cytof technology we would profile at single cell resolution the muscle resident populations during aging and in diseased state. This would allow us to identify dysfunctional subsets involved in the regeneration defect. This study would not only shed light on the mechanisms underpinning muscle regeneration but would provide a solid ground for the future identification of diagnostic biomarkers through the study of disease specific subpopulations., Hypertrophy and dystrophy are distinct, yet linked processes that remodel both skeletal and cardiac muscles in physiological or pathological settings. Not only is hypertrophy important during development, but it also plays major role upon acute or chronic damage. Muscular dystrophies (MDs) cause progressive degeneration and loss of functionality in both striated muscle types. In MD patients and animal models, an initial hypertrophic response occurs, with contrasting effects on skeletal and cardiac muscle. Recently it has been established that muscle fibers secrete exosomes, whose cargo acts as endocrine signals during myogenesis. We aim at deciphering the exosomal information guiding hypertrophy/dystrophy in both muscle in order to establish a new strategy based on miRNA modulation for novel myogenic regeneration. We performed ex vivo exosome analysis comparing age-matched WT, Sgcb-null (dystrophic), and MAGIC-F1+/+ (hypertrophic) mice. We detected several differentially regulated miRNAs, virtually relevant for striated muscle remodeling and de-/re-generation. We have preliminary results on the effects of ex vivo exosomes on cell types relevant for skeletal and cardiac muscle analysis. Moreover we are currently investigating the uptake routes of exosomes in both muscle types. In the future we will rely on miRNA-sequencing of ex vivo exosomes, to identify key mRNA/miRNA distinctive signatures by means of an high-throughput approach and place our ongoing results into a genome-wide setting. As a final goal, the hypertrophic/dystrophic signatures and tissue-specific information will further be integrated to establish skeletal- and cardiac-enhancing cocktails to selectively improve the regenerative outcome of patient-specific progenitors in vivo, into a xenograft-permissive murine model., Duchenne muscular dystrophy (DMD) is the most common, lethal, inherited myopathy, which results in muscle degeneration. In this work, we aimed at developing an innovative 3D satellite cell niche derived from human induced pluripotent stem cells (hiPSC) within their native sublaminal position in an engineered human skeletal muscle myofiber. One of the main limitations of cell therapy for DMD is the high number of myogenic cells required and the efficiency of engraftment in vivo. hiPSC ensure large amount of cells and the possibility of derive patient-specific cells, but obtaining myogenic cells in vitro from hiPSC is difficult and the yield is low. In this work, we induced the myogenic differentiation of hiPSC through multiple transfection of modified mRNA of the master transcription factors MYOD, PAX3 and PAX7. To this aim, we exploited a microfluidic platform that allows the downscaling of the process for performing cost-effective, multiparametric and highthroughput experimental investigations. We optimized the protocol for transfecting hiPSC colonies leading to a transfection efficiency of 60% per single transfection. After multiple transfections, exogenous MyoD is expressed in 95% of the cells and endogenous expression of desmin and myosin heavy chain was observed (4 days after the last transfection). Ongoing experiments are extending these results to Pax3 and Pax7. Another key factor for a successful cell therapy is the cell delivery. In this sight, we developed a 3D poly-acrilammide/hyaluronic acid hydrogel (HY) scaffold and optimized its biochemical and mechanical properties in order to sustain the myogenic differentiation of human primary myoblasts and to reproduce the protective microenvironment of the satellite cell niche. The scaffold was designed in order to control the cell topology: 3D parallel micro-channels (80-160 μm in diameter, 10-15 mm long) were produced inside the scaffold and functionalized with ECM proteins. To reproduce the physiological mechanobiology, HY chemical composition was optimized in order to obtain a soft scaffold with physiological elastic modulus, E≈12±4kPa. Human primary myoblasts were used to optimize the seeding, culture and differentiation protocols. At 10 days, we observed tightly packed myotubes bundles, expressing myosin heavy chain, α-actinin and dystrophin. We are now integrating hESC-derived myoblast and we observed differentiation into myoubes and expression of myosin heavy chai, α-actinin and desmin.We hypothesize that such engineered niche will provide, upon in vivo implantation, satellite cells able to regenerate the damaged muscle of DMD patients, and reconstitute the stem cell pool for future muscle damages. On the other hand, our 3D niche could be exploited as an in vitro tool to study the biology of the niche itself, the mechanism of the pathology or as a tool for testing new drugs and therapies in a personalized manner., Skeletal muscle regeneration is mediated by a complex crosstalk between various resident mononucleated cell populations. These cell interactions after fiber damage or stress are finely regulated in time and space. Satellite cells, skeletal muscle stem cells, play a pivotal role during regeneration being the main source of new myoblasts. However, their activation, proliferation and differentiation relies on environmental cues shaped by cell populations such as macrophages, pericytes, and fibro-adipogenic progenitors (FAPs). FAPs have a leading role in the regeneration process since they promote myotube formation by positively regulating satellite cell differentiation. However, in pathological conditions, such as muscular dystropies, these cells play a negative role since they are responsible for fibrosis and fatty tissue accumulation. In in vitro experiments we have observed an improvement in the maturation of myotubes derived from satellite cells, when co-cultured with FAPs. Furthermore, we have also observed that direct contact of these two cell populations inhibits adipogenic differentiation of FAPs while in the transwell system this inhibition does not occur. Even though there is a clear interaction between these two populations, it has not been thoroughly characterized yet. Thus exploiting Luminex technology we are aiming at identifying molecules affecting the differentiation process of these two cell types focusing on cytokines, chemokines and growth factors. In addition we are planning to include in these studies macrophages and pericytes in order to obtain a more complete picture of molecular networks involved in myogenesis and finally build a cell-cell interaction model of skeletal muscle regeneration., Electrical stimulation (ES) of skeletal muscle has been proposed to mimic the beneficial effects of physical training and to counteract the muscle atrophy associated with reduced motor activity. If properly used, it can be a potent tool to increase strength and endurance in patients affected by muscle weakness due to ageing or prolonged debilitating illness. However, classical ES exhibits several limitations, such as the unpleasant symptoms due to pulse strength and the occurrence of muscle fatigue. The most appropriate parameters of stimulation, such as intensity, frequency and pulse duration, are still under debate. Field ESs were given to mouse skeletal myotubes in culture. Changes in membrane potential were detected by perforated patch recordings and calcium dynamics was followed using fluorescent indicators. Different patterns of ES were tested. Tetanic high frequency stimulation at 45 Hz induced voltage changes invariably characterized by failures, and discontinuous firing preceding the complete disappearance of the electrical activity, whereas low-frequency stimulations at 1 Hz more efficiently elicited single action potentials. An innovative “noisy” waveform ES pattern was tested, obtained from a segment of electromyogram recording, sampled from a limb muscle of adult volunteers during the execution of a rhythmic motor activity. Using half of the intensity of stimulation employed for more stereotyped ES patterns, it was found to be more efficient in inducing repetitive cell firing, calcium transients and cell twitching. We suggest this approach as a new strategy for the design of new electrical devices able to provide a therapy option for injured muscles in human patients., Muscle contraction is generated by cyclical interactions of myosin heads with actin filaments to form the actomyosin complex. The stable configurations of the actomyosin complex have been described in detail, but whether in vivo, at physiological temperatures, these configurations are fixed to the ones observed in cryomicroscopy (at low temperature) or undergo thermal oscillations is unknown and not generally considered in mathematical modeling. By comparing three mathematical models, we analyze how this intrinsic property of the actomyosin complex affects muscle contraction at three level; namely, single cross-bridge, single fiber and organ levels, in a ceteris paribus analysis. We observed that state fluctuations allow the lever arm of myosin to easily and dynamically explore all possible minima in the energy landscape, generating several backward and forward jumps between states during the lifetime of the actomyosin complex, whereas the rigid case is characterized by fewer force generating events. Therefore, dynamical oscillations enable an efficient contraction mechanism, in which a higher force is sustained by fewer attached cross-bridges., Mammalian neuromuscular junctions (NMJs) undergo a postnatal topological transformation from a simple oval plaque to a complex branch-shaped structure often called a “pretzel”. Although abnormalities in NMJ maturation and/or maintenance are frequently observed in neuromuscular disorders, such as congenital myasthenic syndromes (CMSs), the mechanisms that govern synaptic developmental remodeling are poorly understood. It was reported that myotubes, when cultured aneurally on laminin-coated surfaces, form complex postsynaptic machinery, which resembles that at the NMJ. Interestingly, these assemblies of postsynaptic machinery undergo similar stages in developmental remodeling from “plaques” to “pretzels” as those formed in vivo. We have recently demonstrated that podosomes, actin-rich adhesive organelles, promote the remodeling process in cultured myotubes and showed a key role of one podosome component, Amotl2. We now provide evidence that several other known podosome-associated proteins are present at the NMJ in vivo and are located to the sites of synaptic remodeling. Additionally, we identified proteins that interact with Amotl2 in muscle cells. We show that two of them: Rassf8 and Homer1, together with other podosome components, are concentrated at postsynaptic areas of NMJs in the indentations between the AChR-rich branches. Our results provide further support for the hypothesis that podosome-like organelles are involved in synapse remodeling and that Rassf8 and Homer1 may regulate this process., Depletion of calcium (Ca2+) from intracellular stores (endoplasmic reticulum, ER), triggers Ca2+ entry across the plasma membrane, a process known as store-operated Ca2+ entry (SOCE). SOCE is mediated by the interaction between STIM1 (stromal interaction molecule 1), which functions as the Ca2+ sensor in the ER, and Ca2+ permeable Orai1 channels in the external membrane. In skeletal muscle, SOCE is the primary mechanism of Ca2+ entry during repetitive activity, a crucial step that prevents/delays fatigue. Despite the importance of this mechanism for proper muscle function during sustained activity, the subcellular sites for SOCE in skeletal fibers have not been identified. Here we show that prolonged muscle activity (treadmill running in mice) drives the formation of previously unidentified intracellular junctions between the sarcoplasmic reticulum (SR) and extensions of the external transverse tubule (TT) membrane. The activity-dependent formation of these unique SR-TT junctions reflects a striking and unexpected remodeling of the existing sarcotubular system at the I band of the sarcomere. Using immunochemistry and immuno-gold labeling we also demonstrate that these newly formed, activity-driven junctions contain the molecular machinery known to mediate SOCE in muscle: STIM1 Ca2+ sensor proteins in the SR, already present in the I band in control conditions, and Ca2+- permeable Orai1 channels, which move into the I band with TTs during prolonged muscle activity. Thus, we refer to these junctions as Ca2+ Entry Units, the first new, molecularly defined subcellular structure in skeletal muscle in over 30 years., The loss of connection between muscle and nerve is a crucial biological mechanism involved in Amyotrophic Lateral Sclerosis (ALS), a neurodegenerative disease associated with motor neuron degeneration, muscle atrophy and paralysis [1]. Recent studies showed the primary role of the skeletal muscle in the pathogenesis of the disease, pointing out the key role of the communication between muscle and nerve. In this context, we developed a protocol to measure, ex vivo, the neuromuscular junction (NMJ) functionality [2]. The experimental technique is based on the comparison between the muscle contractile response elicited by membrane stimulation and the response evoked by nerve stimulation. Since this latter stimulation bypasses the neuronal signalling, any difference between the two responses may be related to NMJ alterations. In particular, we started studying the Soleus-sciatic nerve preparation of one of the most studied ALS animal models, the SOD1G93A mouse [3], with the particular aim of following the pathology’s progress. We observed that the first functional alterations begin at 90 days of age, with an intrinsic damage of the muscle and defects in NMJ functionality who increase until the end-stage of the disease. Subsequently, we approached the study of the MLC/SOD1G93A mouse model, in which superoxyde dismutase-1 mutated gene is expressed exclusively in the skeletal muscle [4]. Our preliminary results highlighted defects in soleus muscle and NMJs functionality in MLC/SOD1G93A mouse model, compared to the wild type, suggesting a direct muscle impairment. Further analysis on this model will provide useful information about the NMJ alterations directly related to oxidative stress on skeletal muscles., Myosin is an abundant ATPase protein. It is estimated that 10% of muscle tissue weight is myosin. Due to its abundance, myosin can be a good target to raise basal metabolic rate in animals. A new low-ATP-consumption state of myosin has recently been proposed (1, 2). This new state has been called the “Super Relaxed State (SRX)” of Myosin. Structural evidence for the SRX state have recently been published showing a close complex formed by the two-myosin heads (3). It is characterized by an ATPase time constant in the order of 300 seconds versus the 15 seconds for the so-called “Disordered Relax State” (DRX)(1,2). The idea is that behind that large number of “dormant” ATPases, there is the key to raise basal metabolism in a physiological way. The amount of myosin in the SRX state is estimated to be approximately 60% of the total. Switching of the myosin heads from the SRX state to the DRX state is regulated by phosphorylation in a cooperativeness-driven-equilibrium. Controlling this equilibrium may lead to an increase in basal metabolism that would consume an additional energy of up to 1000 Kcal/day. We studied the effect of several Regulatory Light Chain mutants on the SRX state and we applied this information to the development of a high throughput screen. We are searching a molecule that is able to destabilize the SRX state in skeletal muscle fibers. We screened 2000 compound of an FDA approved library. Potential lead compounds will be discussed, The muscle cell is a biological machine where steady force and shortening are generated by arrays of the motor protein myosin II pulling the actin filament towards the centre of the sarcomere (the ~2 μm long structural unit of muscle) during cyclical ATP-driven interactions. The fraction of the time of the ATP hydrolysis cycle that myosin II spends attached to actin depends on the sarcomere load and at low load can be as small as 0.02. The array-type arrangement of the motors enhances and makes steady the production of force and shortening, but has so far limited the investigation of mechanics, energetics and structural dynamics of this collective motor to top-down approaches, such as single-cell mechanics and X-ray diffraction (Piazzesi et al. Cell 131:784-795, 2007). The laser trap technique in the Three Bead Assay (TBA) configuration allowed the recording of single actin-myosin interaction in vitro, but only when the duration of attachment was increased by reducing the ATP concentration to a few tens of micromolar (two orders of magnitude lower than that in situ in physiological conditions). In this project we use an alternative approach consisting in assembling molecular motor proteins on a nanostructured support to generate a synthetic sarcomere-scale machine, the mechanical output of which is measured with a double laser optical tweezers apparatus (Bianco et al. Biophys. J. 101:866-874, 2011). The shape, the material and the coating of the support carrying the motor array have been optimised using a preliminary version of the machine consisting of an ensemble of motor proteins randomly adsorbed on a flat surface and brought to interact with an actin filament attached to the trapped bead with the correct polarity. Tests on the density and the disposition of the myosin motors on the surface have been done using AFM. The most reproducible results have been obtained when the support for the motor ensemble is the lateral surface of a chemically etched single mode optical fibre (diameter 4 µm). In solution with physiological [ATP] (2 mM), the ensemble drives 350 nm of actin filament sliding developing a steady force of 50 pN. Supported by Italian Institute of Technology-SEED, project MYOMAC (Genova) and PRIN-MIUR, Italy., Skeletal muscle atrophy is caused by several and heterogeneous conditions, such as cancer (cachexia), neuromuscular disorders and aging. In most types of skeletal muscle atrophy overall rates of protein synthesis are suppressed, protein degradation is consistently elevated and atrogenes, such as the ubiquitin ligase Atrogin-1/MAFbx, are up-regulated. Sphingolipids represent a class of bioactive molecules capable of modulating the destiny of many cell types, including skeletal muscle cells. In particular, we and others have shown that sphingosine 1-phosphate (S1P), formed by sphingosine kinase (SphK), is able to act as trophic and morphogenic factor in myoblasts. Here, we report that the inhibition of SphK1 by specific gene silencing or pharmacological inhibition drastically reduced myotube size and myonuclei number, and increased Atrogin-1/MAFbx expression. Notably, the atrophic phenotype of C2C12 myotubes treated with dexamethasone and of muscle fibers obtained from cachectic mice inoculated with C26 adenocarcinoma, was characterized by increased expression of Atrogin-1/MAFbx and reduced levels of active SphK1. In addition, we found that C2C12 muscle cell atrophy was accomplished by changes in the pattern of expression of S1P receptor subtypes (S1PRs) and treatment of myotubes with S1P was able to prevent Dexa-induced atrophic marker expression. Finally, by using specific S1PR agonists and antagonists, we extended the investigation on the role played by S1PRs in the control of Atrogin-1/MAFbx expression. Altogether, these findings provide the first evidence that S1P/SphK1/S1PR axis acts as a molecular regulator of skeletal muscle atrophy, thereby representing a new possible target for therapy in many physiological and pathological conditions., Skeletal muscle is a dynamic tissue that can respond to external stimuli through both anabolic and catabolic processes. In a variety of conditions, including immobilization, AIDS and neuromuscular disorders, skeletal muscle mass is decreased (atrophy). Upon denervation or disuse, skeletal muscle undergoes atrophy, leading to reduced size of myofibers, impaired contractile and metabolic activities. Previous studies have identified key molecular pathways leading to protein breakdown and degradation of sarcomeric proteins; yet, it remains a gap of knowledge on whether muscle resident cell populations can regulate the response of muscle to atrophic stimuli. Indeed, the recent identification of muscle-derived interstitial cells, named fibro-adipogenic progenitors, that can adopt multiple lineages and contribute, either directly o indirectly, to muscle regeneration (Joe et al,2010; Uezumi et al,2010) indicates a previously unrecognized complexity in the regulation of muscle homeostasis (Saccone et al,2014). We have discovered an unexpected key role of specific muscle-derived mononuclear cells in the pathogenesis of muscle atrophy. The characterization of the mechanism by which these cells contribute to the loss of muscle mass may lead to the identification of new therapeutic targets to counteract muscolar atrophy., PGC-1α overexpression is able to protect skeletal muscle from fasting or denervation-induced atrophy (1) and to improve sarcopenia in old mice (2). Consistently, in the skeletal muscle of cachectic tumor-bearing mice, PGC-1α expression is reduced (3), in Association with the accumulation of PAX7+ cells, which is suggestive of an impairment of myogenesis (4). Preliminary observations obtained in mice overexpressing PGC-1α specifically in the skeletal muscle show that the number of CD34+/Sca1+ cells, both integrin-α7 positive (satellite cells) and negative (other myogenic precursors), was higher in the muscle of transgenic (TG) mice than in those of wild-type (wt) animals. Not only, myotubes originating from TG-derived myogenic precursors were increased in both number and size in comparison to those obtained from wt progenitors. Aim of the present study was to investigate if PGC-1α overexpression can improve the regenerative capacity in the muscle of tumor (C26)-bearing animals after chemically-induced injury. BaCl2 (30 μl, 1.2% w/v) was injected in the tibialis anterior muscle the day after tumor implantation. Thirteen days after injury, both wt and TG controls almost completely recovered the initial myofiber cross sectional area (CSA; 70% of uninjured muscle). By contrast, CSA recovery was markedly delayed in wt or TG tumor-bearing mice (30% of uninjured muscle). Such a lack of CSA rescue in TG C26 hosts occurred despite TG mice constitutively possess a number of myogenic precursors higher than wt animals. As an estimate of mitochondria number, cytochrome c expression was evaluated. The results show that cytochrome c levels were significantly reduced in the regenerating muscle of wt C26 hosts, while remained comparable to those of uninjured muscle in BaCl2-treated TG tumor bearers. Previous observations showed that inhibition of ERK activity improved muscle wasting and myogenesis in the C26 hosts (4). In this regard, muscle pERK levels were significantly lower in TG tumor bearers than in wt C26 hosts. In conclusion, the present study shows that PGC-1α overexpression in the regenerating muscle of tumor hosts resulted in improved mitochondrial mass, and likely, oxidative capacity, and in reduced pERK levels, however without obtaining a significant CSA rescue. These observations suggest that while PGC1α overexpression exerts positive effects on tumor-induced derangements at the molecular level, it does not appear able to impinge on the multifactorial nature of muscle wasting., Cancer cachexia is a life-threatening syndrome that affects most patients with advanced cancers and involves severe body weight loss, with rapid depletion of skeletal muscle. No effective treatment is available. We analyzed microarray datasets to identify a subset of genes whose expression is specifically altered in cachectic muscles of Yoshida hepatoma-bearing rodents, but not in those with diabetes, disuse, uremia or fasting. By Ingenuity Pathways Analysis, we found three genes belonging to the CXCR4 pathway downregulated only in muscles atrophying because of cancer: SDF1, PAK1 and ADCY7. Consistently, we show that the expression of all SDF1 isoforms declines also in Tibialis Anterior from cachectic mice bearing colon adenocarcinoma or renal cancer and anti-cachexia drugs such as sunitinib restore it. Overexpressing genes of this pathway (i.e. SDF1 or CXCR4) in cachectic muscles increases the fiber area by 20%, partially protecting them from wasting. The mechanisms behind this muscle preservation during cachexia include both reduced degradation of long-lived proteins, by either SDF1α or SDF1β on atrophying myotubes, and increased protein synthesis, mainly by SDF1α. However, inhibiting CXCR4 signaling with the antagonist AMD3100 does not affect protein homeostasis in atrophying myotubes at all, whereas normal myotubes treated with AMD3100 display decreased diameter in a time- and dose-dependent manner, until a plateau. This further confirms the involvement of a saturable pathway (i.e. CXCR4). Overall, these findings support the idea that activating the CXCR4 pathway in muscle suppresses the deleterious wasting associated with cancer., Cancer cachexia is a systemic syndrome that consists of a dramatic weight loss with rapid muscle depletion due to enhanced protein degradation, irrespective of food intake. Remarkably, 50% of advanced cancer patients are affected by cachexia, which accounts for approximately 20% of cancer deaths. No therapy is available. Interestingly, females are more resistant to cancer cachexia than males. We analyzed previous microarray datasets to identify genes whose expression is specifically altered in cachectic muscles of Yoshida hepatoma-bearing male rodents. Among these genes, we found that apelin was drastically downregulated to 8% of controls in cachectic gastrocnemius muscles (with 14% of weight loss) from male rats bearing Yoshida hepatoma for 5 days. We confirmed by Q-PCR that apelin was downregulated to 45% and 2% of controls also in Tibialis Anterior (TA) muscles in Lewis Lung Carcinoma and in Colon Adenocarcinoma 26 (C26)-bearing mice, respectively. Moreover, in TA from C26-bearing mice also the expression of apelin receptor (APJ), a member of G-protein coupled receptors, was reduced to 16%. Q-PCR analysis further confirmed that apelin downregulation occurred at all stages of cancer cachexia of C26-bearing male mice, while the expression of APJ was significantly reduced to 30% of controls only in early cachectic mice with less than 14% of body weight loss. Since apelin is expressed on X chromosome both in humans and mice and it is not downregulated in muscles from C26-bearing female mice, we believe that apelin could be a good candidate to explain the gender difference of cancer cachexia., Cachexia is a syndrome frequently occurring in cancer patients. It is characterized by body and skeletal muscle wasting and by metabolic abnormalities. These latter are mediated, partially at least, by humoral factors. Energy balance perturbations also contribute to the onset of cachexia. In this regard, impaired mitochondrial functions and altered energy expenditure likely play a role. Recent observations suggest that in addition to classical humoral factors such as hormones or cytokines, also tumor-derived microvesicles (MVs), circulating particles containing different molecules such as proteins, mRNAs and microRNAs, may contribute to derangements associated with cachexia (1). MVs were isolated by differential ultracentrifugation from the conditioned medium of LLC (Lewis Lung Carcinoma) cells and were quantified by a NanoSight apparatus. After five day culture in differentiation medium, C2C12 myotubes were treated for 24 h with LLC-derived MVs. In C2C12 myotubes tumor-derived MVs induce a reduction of PGC-1α, the master regulator of oxidative metabolisms and mitochondrial biogenesis, as well as of Cyt-c mRNA expression. These results are in agreement with previous observations showing decreased PGC1α expression in the skeletal muscle of cachectic mice. In myotubes oxygen consumption is significantly decreased while lactate levels in the culture medium are increased after treatment with MVs. BNIP3 mRNA expression is significantly increased, while no differences can be observed as for myotube size and mRNA expression of both Atrogin1 and MuRF-1, two muscle-specific ubiquitin ligases. These results suggest that tumor-derived MVs affect mitochondria in C2C12 cultures. The reduction of mitochondrial mass (decreased Cyt-c mRNA expression) and function is associated with down-regulation of PGC-1α expression and enhancement of selective autophagy (mitophagy). On the whole, MV-induced alterations could contribute to muscle wasting during cancer cachexia., High mobility group box 1 (HMGB1) is a nuclear protein that acts extracellularly as an alarmin to modulate inflammation and tissue repair by recruiting cells and promoting their migration and activation. Recently, we showed that HMGB1 orchestrates both processes by switching among mutually exclusive redox states. Fully reduced HMGB1 acts as a chemoattractant, whereas a disulfide bond makes it a proinflammatory cytokine and further cysteine oxidation by reactive oxygen species (ROS) abrogates both activities. The fully reduced HMGB1 is prevalent in the extracellular environment immediately after acute muscle injury, and disulfide- HMGB1 appears a few hours later. Thus, the generation of ROS during muscle damage might modulate the redox status of the protein and eventually limit its lifespan and functions. We created a mutant (3S-HMGB1) not susceptible to redox modifications and we evaluated its regenerative activity in a model of acute muscle injury induced by cardiotoxin. We demonstrated so far that HMGB1 has beneficial effects in skeletal muscle regeneration after acute injury by dramatically increasing the number of healthy fibers and the number of satellite cells and M2c macrophages, two cell types essential for muscle repair. Moreover, HMGB1 acts directly on primary myoblasts by inducing their migration and their fusion to form large myotubes. Remarkably, 3S-HMGB1 behaves as a superagonist of HMGB1 in vivo, suggesting that it is a promising candidate for muscle repair therapies. Our study will be extended to other models of muscle damage, in particular dystrophies, in order to evaluate the therapeutic potential of 3S-HMGB1 in chronic conditions., Atrophy is an active process controlled by specific signaling pathways and transcriptional programs. The identification of the precise signaling cascades that regulate muscle wasting remains poorly understood. The Ubiquitin Proteasome System (UPS) is one of the major systems that control protein breakdown during muscle wasting. The specificity of ubiquitin-dependent degradation derives from many E3s that recognize specific substrates. This work is focus on a novel muscle-specific circadian-rhythm dependent ubiquitin ligase named Asb2β. To dissect its role, we have generated muscle specific and tamoxifen-inducible muscle specific knock-out mice. We have characterized these knockout mice in physiological and in catabolic conditions. Asb2β defective muscles show normal muscle morphology and mitochondrial content but muscles display a fiber type switch and glycogen accumulation. Glucose tolerance test revealed an improved glucose uptake in knockout mice. Moreover, glycogen content dramatically decreased in Asb2β knockout mice during fasting. The changes in glucose homeostasis are Akt independent but TBC1D1and AS160 dependent. However, absence of nutrients triggers necrotic degeneration and appearance of abnormal mitochondria in Asb2β-null muscles. We have also started to characterize the tamoxifen-inducible knockout mice. Preliminary data show that acute inhibition of Asb2β induces a time dependent muscle growth. In conclusion, we have identified a novel muscle specific ubiquitin ligase, Asb2β, that plays an important role in glucose homeostasis and muscle hypertrophy., Aging is characterized by loss of skeletal muscle mass and function, condition known as sarcopenia. The mechanisms underlying sarcopenia are not completely understood, however a role for ectopic fat accumulation has been proposed. Skeletal muscle accumulates lipid in form of triglycerides within lipid droplets (LDs). LDs are characterized by the presence of Perilipins (Plins), that control lipid accumulation and metabolism under physiological and pathological conditions. In skeletal muscle one of the most representative is Plin2, particularly involved in lipid storage. However, the exact role of Plin2 is not still clear. We found that in human muscle the expression of Plin2 increases with aging and it is inversely associated with muscle mass and strength. Moreover, Plin2 expression is associated with atrophy-related genes, MuRF-1 and Atrogin, suggesting a role for Plin2 in muscle aging and atrophy. We also analysed the expression of Plin2 in adult mice where muscle atrophy was induced by denervation. Denervation of tibialis anterior muscle was compared with the contralateral intact side. After denervation, beside the expected increase of MuRF-1 and Atrogin, also Plin2 expression actually increases. This suggested that Plin2 expression is somehow associated with muscle atrophy. To support this hypothesis, we performed muscle-specific in vivo silencing experiments of Plin2. After 7 days from injection, a decrease of Plin2 was observed, and most interestingly the cross-sectional area (CSA) of Plin2-negative fibres resulted increased of about 30% with respect to Plin2-positive ones. As a whole, these data suggest that in skeletal muscle Plin2 is involved not only in muscle atrophy, but also in hypertrophy. Further studies are ongoing to better clarify this new role of Plin2 in skeletal muscle., The rhabdomyosarcoma (RMS) is the most common soft tissue sarcoma in people under 20 years of age. It can commonly arise anywhere in the body but the head and neck, the extremities and the genitourinary tract are predominant sites. Based on histology, RMS tumors are classified into two major subtypes, embryonal and alveolar, which also differ in the molecular pathogenesis of development. Despite these differences, the origin of aRMS and eRMS seems to be the same but the precise cell type that triggers RMS is still unclear. Some evidence supports the notion that skeletal muscle precursors, probably satellite cells, may initiate RMS. Alternative theories propose mesenchymal stem cells, or even cells belonging to the adipocyte lineage, as possible tumor-initiating cells. In order to shed light on the origin of eRMS, we adopted the KrasG12D/+Trp53Fl/Fl conditional mouse model. This model allows us to generate eRMS in the hind limb of mice by infecting them with an adenovirus vector carrying the CRE recombinase. In a first approach we want to describe and rationalize the changes in the tumor mass cell populations by analyzing the tumor at different stages of development by using flow and mass cytometry techniques. In a second approach we aim at identifying the cell population(s) that are responsible for initiating the tumor. To this end we induce the gene mutations that are responsible for rhabdomyosarcoma development by infecting, with the CRE recombinase adenovirus, isolated muscle mononucleate cell populations and monitor their ability to develop rhabdomyosarcoma tumorigenic properties in vitro., The purpose of this study was to investigate whether MURC/cavin-4, a plasma membrane and Z-line associated protein exhibiting an overlapping distribution with Caveolin-3 (Cav-3) in heart and muscle tissues, may be expressed and play a role in rhabdomyosarcoma (RMS), an aggressive myogenic tumor affecting childhood. We found MURC/cavin-4 to be expressed, often concurrently with Cav3, in mouse and human RMS, as demonstrated through in silico analysis of gene datasets and immunohistochemical analysis of tumor samples. In vitro expression studies carried out using human cell lines and primary mouse tumor cultures showed that expression levels of both MURC/cavin-4 and Cav-3, while being low or undetectable during cell proliferation, became robustly increased during myogenic differentiation, as detected via semi-quantitative RT-PCR and immunoblotting analysis. Furthermore, confocal microscopy analysis performed on human RD and RH30 cell lines confirmed that MURC/cavin-4 mostly marks differentiated cell elements, colocalizing at the cell surface with Cav-3 and labeling myosin heavy chain (MHC) expressing cells. Finally, MURC/cavin-4 silencing prevented the differentiation in the RD cell line, leading to morphological cell impairment characterized by depletion of myogenin, Cav-3 and MHC protein levels. Overall, our data suggest that MURC/cavin-4, especially in combination with Cav-3, may play a consistent role in the differentiation process of RMS., Rhabdomyosarcoma (RMS) is a childhood soft tissue tumor with broad expression of markers that are typically found in skeletal muscle. Cavin-1 is a recently discovered protein actively cooperating with Caveolin-1 (Cav-1) in the morphogenesis of caveolae and whose role in cancer is drawing increasing attention. Using a combined in silico and in vitro analysis here we show that Cavin-1 is expressed in myogenic RMS tumors as well as in human and primary mouse RMS cultures, exhibiting a broad subcellular localization, ranging from nuclei and cytosol to plasma membrane. In particular, the coexpression and plasma membrane interaction between Cavin-1 and Cav-1 characterized the proliferation of human and mouse RMS cell cultures, while a downregulation of their expression levels was observed during the myogenic differentiation. Knockdown of Cavin-1 or Cav-1 in the human RD and RH30 cells led to impairment of cell proliferation and migration. Moreover, loss of Cavin-1 in RD cells impaired the anchorage-independent cell growth in soft agar. While the loss of Cavin-1 did not affect the Cav-1 protein levels in RMS cells, Cav-1 overexpression and knockdown triggered a rise or depletion of Cavin-1 protein levels in RD cells, respectively, in turn reflecting on increased or decreased cell proliferation, migration and anchorage-independent cell growth. Collectively, these data indicate that the interaction between Cavin-1 and Cav-1 underlies the cell growth, migration and differentiation grade in myogenic tumors., Recently, it was shown that in yeast CK2-dependent phosphorylation of the mitochondrial import receptor Tom22 promotes biogenesis of the TOM translocase and is required for import of mitochondrial proteins. We asked whether CK2-dependent phosphorylation of TOM proteins also occurs in mammals. Using CK2β-deficient skeletal muscle lysates, we observed less phosphorylation of Tom22. Moreover, we confirmed CK2 phosphorylating residues serine 15 and threonine 43 of murine Tom22. Further, CK2-dependent phosphorylation of Tom22 changes its binding affinity for proteins need to be imported into mitochondria. In the absence of CK2 mitochondrial protein import is impaired in muscle fibers and mitochondria are dysfunctional. Pink1, a mitochondria health sensor and involved in Parkinson s disease, accumulates within mutant muscle cells, and labels removal of dysfunctional mitochondria by mitophagy and involvement of autophagic adaptor protein p62/SQSTM1. Consequently, the metabolism of oxidative muscle fibers in mutant muscles shifted towards glycolytic. As proof of concept, removal of aggregated p62/SQSTM1 by muscular in vivo electroporation of phosphomimetic Tom22 was successful. This is the first evidence for both, regulated protein import into mammalian mitochondria, and muscle weaknes due to a mitochondrial protein import defect., Canonical Wnt/β-catenin signaling plays a role in myogenic differentiation, but its role in adult muscle fibers is completely unknown. We approached canonical Wnt signaling in adult myofibers by well-known reporter Axin2-lacZ mice, monitoring X-Gal staining in muscle stem cells, in adult muscle fibers and at their neuromuscular synapse. In muscle stem cells, canonical Wnt signalling is absent in quiescent cells and 72 h proliferating cells. In adult muscle fibers, canonical Wnt signaling is strongly detectable by Axin2- and β-catenin-positive skeletal muscle fibers, where it is expressed only in fast fiber types with small cross-sectional areas. In these fibers, canonical Wnt signaling is active together with Hippo signaling members, YAP/TAZ and TEAD1. During differentiation of C2C12 cells, Axin2 increases together with the expression of TEAD1-target genes: CTGF, Ankrd1 and Cyr61. In cultured primary muscle cells, we observed Axin1 and Axin2 being involved in proliferation and myotube formation in a Wnt1 and Wnt3a dependent manner. We present a model how canonical Wnt/β-catenin signaling, together with YAP/TAZ and TEAD1, influences muscle fiber diameter in fiber-type specific manner., Muscle atrophy contributes to the poor prognosis of many pathophysiological conditions, but pharmacological therapies are still limited. Muscle activity leads to major swings in mitochondrial [Ca2+] which control aerobic metabolism, cell death and survival pathways. We have investigated in vivo the effects of mitochondrial Ca2+ homeostasis in skeletal muscle function and trophism, by overexpressing or silencing the Mitochondrial Calcium Uniporter (MCU). The results demonstrate that both in developing and in adult muscles MCU-dependent mitochondrial Ca2+ uptake has a marked trophic effect that does not depend on aerobic control, but impinges on two major hypertrophic pathways of skeletal muscle, PGC-1α4 and IGF1-AKT/PKB. In addition, MCU overexpression protects from denervation-induced atrophy. These data reveal a novel Ca2+-dependent organelle-to-nucleus signaling route, which links mitochondrial function to the control of muscle mass and may represent a possible pharmacological target in conditions of muscle loss., PKC (protein kinase C) family is composed by 3 subgroups: conventional, novel and atypical PKC. These kinases are involved in a large number of biological processes (such as protein synthesis, glucose metabolism, apoptosis). PKCzeta and PKClambda/iota belong to the atypical PKC subgroup and differ from conventional and novel PKCs for their activation mechanism. Indeed atypical PKCs are calcium and diacylglycerol (DAG) insensitive, while classical PKCs are activated by calcium and DAG, and novel PKCs are activated by DAG but not by calcium (1,2). Little is known on the role of PKCzeta on skeletal muscle homeostasis. Thus, we overexpressed this kinase by in vivo transient transfection. We observed a marked hypertrophy in PKCzeta positive myofibers compared to surrounding not transfected fibers. In addition PKCzeta overexpression protected muscle from denervation-induced atrophy. Next, we studied the effects of 3 different PKCzeta mutants on fiber size: 1) PKCzeta-DN (a dominant negative isoform carrying a point mutation on the ATP-binding site); 2) PKCzeta-ΔNPS (a costitutive active mutant); 3) PKCzeta-InLoop (a dominant negative isoform mutated in the activation loop). Surprisingly all these mutants cause muscle hypertrophy and protect from denervation-induced atrophy suggesting a possible kinase-independent mechanism of PKCzeta on skeletal muscle trophism., P38 mitogen activated protein kinases (MAPKs) are required at several stages during differentiation of muscle progenitor cells. P38 phosphorylation initially accompanies satellite cells activation and triggers asymmetric division. At a later stage, it orchestrates myoblast differentiation promoting myotube formation. The signals that trigger or modulate p38 activation during the differentiation process are still debated. Both cellJtoJcell contact and TNFα prime p38α/β phosphorylation and activation during myogenesis. Cdo, a multifunctional surface protein has been implicated in myogenesis. Following cellJtoJcell contact and ligation to cadherin, Cdo binds JLP and BnipJ2 which act as scaffolds for recruitment of p38α/β and Cdc42. The formation of the complex leads to activation of Cdc42, which is fundamental to promote p38α/β phosphorylation and myogenic differentiation. However, the phosphorylation cascade leading to p38α/β activation has not been elucidated. We focused on Pak1, a member of the p21 activated kinase family, which is activated by Cdc42. We have observed that treatment of differentiating myogenic progenitors (mesoangioblasts) with the Pak1 inhibitor IPAJ3 negatively modulates p38α/β phosphorylation and myogenin expression without affecting cell proliferation. This inhibition of the myogenic differentiation program results in a lower efficiency of myotube formation. We followed these observations in vivo by monitoring regeneration efficiency in mice treated with IPA-3 and we observed that mice treated with IPA-3 displayed a delayed recovery after cardiotoxin injury. These results suggest the Pak1 contributes to myogenic differentiation of progenitor cells in vitro and participates in muscle regeneration in vivo., Ambra1 (activating molecule in Beclin 1-regulated autophagy) is an adaptor protein involved in a plethora of cellular processes. Studies in mice with a randomly mutated Ambra1 locus (Ambra1gt/gt) showed that this gene is essential for the development of the central nervous system. A recently published work by our team suggests that Ambra1 may also play a key role for muscle development in zebrafish and mouse. Indeed, Ambra1gt/gt E13.5 mouse embryos display severe defects of neck, tongue, dorsal and limb muscles, being characterized by increased cellularity and a marked disorganization of myofibers. To better clarify the role of Ambra1 in skeletal muscles, we generated mice with a floxed Ambra1 allele (Ambra1flox/flox). Ambra1flox/flox mice were then crossed with a CAG-Cre transgenic line, which express Cre recombinase in the oocytes, thus obtaining Ambra1+/- mice. Here we show that Ambra1–/– mice die at late developmental stages and display severe morphological defects, similar to Ambra1gt/gt embryos. Adult Ambra1+/- mice show an increased percentage of centrally nucleated fibers and a decreased proportion of oxidative fibers. Ambra1flox/flox mice were then bred with MLC-1f-Cre transgenic animals, which only express Cre recombinase in mature myofibers. Our preliminary data in adult Ambra1flox/flox;MLC-1f-Cre mice show a significant increase of centrally nucleated fibers, although we did not observe any overt defect of oxidative fibers. Altogether, our data suggest that Ambra1 is important for the development of skeletal muscle. Further studies in different muscles of Ambra1flox/flox;MLC-1f-Cre mice under different stress conditions will allow elucidating the role of this adaptor protein in myofiber homeostasis, Myopalladin (MYPN) is a striated muscle-specific sarcomeric protein belonging to a small family of actin-associated immunoglobulin-containing proteins. MYPN mutations have been identified in patients with dilated (DCM), hypertrophic, and restrictive cardiomyopathy. Furthermore, we identified three MYPN mutations in limb girdle muscular dystrophy (LGMD) patients with associated DCM. Within the sarcomeric Z-line, myopalladin binds to α-actinin, nebulin, and PDZ-LIM proteins. Furthermore, it is present in the nucleus and the I-band where it binds to the stress-inducible transcriptional cofactor CARP/Ankrd1, which, in turn, binds to the I-band region of titin, suggesting a role of MYPN in mechanosensing. In our preliminary studies, we found that MYPN can bind to and bundle filamentous actin, thereby promoting actin polymerization. Moreover, MYPN interacts with MRTF-A and strongly increases MRTF-A-mediated activation of serum response factor (SRF) signaling. In studies of MYPN knockout (MKO) mice, we found that MKO mice are significantly smaller compared to wildtype (WT) mice and have an about 30% reduction in skeletal muscle cross-sectional area (CSA) at all ages. Consistently, reduced differentiation rate and myotube width was observed in primary skeletal muscle cultures derived from MKO mice. Furthermore, studies of muscle performance in 2-month-old MKO mice showed reduced isometric force and power during isotonic shortening at any loads as a result of the reduced cross sectional area, whereas the force developed by each myosin molecular motor was unaffected. By up- and downhill treadmill running, MKO and WT mice performed similarly. However, while the performance of WT mice was unaffected following four consecutive days of downhill running, the performance of MKO mice decreased progressively and signs of muscle regeneration following muscle damage were observed. Consistent with a higher susceptibility to muscle damage, progressive Z-line widening was observed in MKO skeletal muscle from about 8 months of age. RNAseq revealed downregulation of actin isoforms and other SRF-target genes in MKO muscle both at 2 and 4 weeks of age, suggesting altered SRF signaling as a possible explanation for the reduced CSA in MKO mice., Impairment of autophagy in muscle leads to precocious ageing1. In particular, autophagy deficient mice are characterized by weakness are atrophy that are associated with alteration in Neuro Muscular Junction (NMJ) and loss of innervation. In order to investigate the cross-talk between muscle and nerve, we found that the expression of FGFBP1, a neurotrophic factor that is critical to preserve muscle-nerve interaction, is suppressed in muscle of autophagy deficient mice. FGFBP1 has been found to be regulated by miRNA206, the muscle-specific miRNA2. When we checked the level of miRNA206 expression, we found higher level of miRNA206 in serum of muscle specific autophagy deficient mice than in controls. Importantly, miRNA206 was detected in the heart of those mice. To understand whether autophagy deficient muscles released vesicles containing microRNAs, we analysed exosomes Quantitative RT-PCR analyses confirmed an increased expression of miRNA206 in purified exosomes from both denervated and autophagy deficient fibers. Moreover expression of BDNF in neurons treated with purified exosomes containing miRNA206 was down-regulated. This finding suggests a potential role of exosomes and miRNA206 in modulating synaptic plasticity. In order to mimic autophagy deficient mice condition, we systemically injected exosomes transfected with miRNA206 in wild-type animals. MiRNA206 was found in several tissues, in particular liver and heart. Moreover the treatment was sufficient to induce skeletal muscle atrophy and changes in the expression of several neurotrophic factors. These data support the role of exosome as a signaling mechanism that connects muscle with different tissues including motorneuron, heart and liver., Duchenne muscular dystrophy (DMD) is a genetic disease in which loss of functional dystrophin protein results in progressive skeletal muscle degeneration. Although the genetic defect is widely known, the mechanisms by which the absence of dystrophin leads to the complex pathophisiology of the disease is not completely understood. MiRNAs are small non coding RNA that are important regulatory elements for muscle development and function [1]. Altered levels of specific miRNAs were found in several muscular disorders, including DMD [2, 3]. In particular it has been identified a specific DMD-signature miRNAs that may serve as a marker for therapeutic purposes [4]. Moreover, in a recent work it has been defined a specific group of miRNAs strictly correlated to dystrophin levels and whose deregulated expression could explain several pathogenetic features of DMD [5]. Previously we have demonstrated that the local expression of mIGF-1 in mdx mice ameliorates the dystrophic phenotype reducing myonecrosis and upregulating survival pathways such as AKT pathway [6]. In this work, we show that a specific group of miRNAs, dystrophin-indipendent, are modulated by mIGF-1 expression. In particular, local expression of mIGF-1 promotes the modulation of miR-206 and miR-24 as well as muscle specific genes associated with maturation of regenerating muscle fibers and differentiation. These results indicates that local overexpression of the anabolic factor mIGF-1 in mdx mice ameliorates the dystrophic microenviroment modulating the expression of a specific group of miRNAs and inducing a partial rescue of the characteristic DMD-signature., Circular RNAs have been recently re-discovered as a large class of putative non-coding RNAs with a peculiar structure and poorly understood functions. Although their biogenesis, which proceeds via a back-splicing reaction, has been studied and dissected in the last years, their role in biologically relevant processes is still uncharacterized. Here, we performed expression profiling of circRNAs during in vitro differentiation of murine and human myoblasts, we selected and validated the expression of a subset of highly expressed, conserved circular RNAs and applied a high-content functional genomic screen in order to identify molecules that were able to impact on the differentiation process. We focused on three circRNAs whose down-regulation resulted in important phenotypes and further scrutinized one of them, named circ-ZNF609, with the aim of undestanding its molecular function. We found that circ-ZNF609 contains an open reading frame spanning from the native start codon of its host transcript and terminating at an in-frame stop codon that is created upon circularization. Circ-ZNF609 is associated to heavy polysomes and is translated into a 30-KDa peptide that is able to promote human myoblasts proliferation., Stem cells and regenerative medicine have greatly increased the expectations of the scientific community and the public for their potential in applications that aim at recovering or replacing injured, aged and diseased tissues. Nevertheless their clinical application is currently hindered by cell survival, inflammatory response, tissue engraftment, vascularization and efficient differentiation. Tissue engineering exploits biomaterials to improve stem cell engraftment and differentiation by mimicking organogenesis. Skeletal muscle tissue engineering is an up-and-coming biotechnology that could offer great potential, in the near future, for muscle repair. Reconstructing the skeletal muscle architecture and function is still a challenge requiring parallel alignment of myofibrils arranged into organized sarcomeres. We show that an “anatomical bioreactor-like” represented by the surface of mouse tibialis anterior muscle (TA), positively influences maturation and alignment of fibers derived from adult muscle stem/progenitor cells embedded into a poly-ethylene-glycol-fibrinogen (PF) hydrogel. This approach leads to the generation of an artificial normal muscle. Furthermore by the same approach we succeeded in replacing a complete mouse TA after massive muscle ablation, recovering morphology and function of the substituting artificial TA. Starting from these observations, we are now developing a novel approach for regeneration and/or reconstruction of skeletal muscle tissue segments human-like size in order to translate this technique to clinical application. For this purpose human derived muscle pericytes have been isolated from muscle biopsies and have been investigated for their myogenic potential. Moreover by exploiting the PF properties, we demonstrated the noteworthy potential of this cell population for human skeletal muscle tissue engineering., Histone deacetylases (HDACs) control the transcriptional networks underlying both muscle differentiation and progression of dystrophy. Considering that, HDAC inhibitors (HDACi) are important candidate drugs for pharmacological interventions in muscular dystrophies. Although the beneficial effects of HDACi in the treatment of muscular dystrophy are known, it remains to dissect the mechanism of action and the cellular mediators of these drugs. The goal of this project is to analyze the molecular mechanisms underlying the role of resident satellite cells and infiltrating macrophages in mediating the activity of HDACi ITF2357 (also referred to as Givinostat) in dystrophic muscle of mdx mice, the best animal model of Duchenne Muscular Dystrophy (DMD). We analyzed the dystrophic phenotype of mdx mice treated with Givinostat at different stages of disease, specifically 6, 12 and 36 weeks, corresponding to necrotic/inflammatory, regenerative and fibrotic stage, respectively. The histopathological and morphometric analyses show an amelioration of dystrophic phenotype with a significant increase of muscle fiber cross-sectional area and a consistent reduction of intramuscular fibrosis, surprisingly also at late stage of disease, suggest a positive outcome also in old mdx mice. Moreover, gene expression analysis of whole skeletal muscle and purified cell populations pointed out a modulation of fibrosis and inflammatory markers and fibroadipogenic differentiation. Overall, these data confirm the beneficial effects of Givinostat on dystrophic muscle and identify the involvement of macrophages in mediating Givinostat activity., Central Core Disease (CCD) and Malignant Hyperthermia (MH) are related disorders linked to mutations in the ryanodine receptopr-1 (RYR1) gene, encoding for the sarcoplasmic reticulum (SR) Ca2+ release channel. CCD is a congenital myopathy characterized by amorphous regions lacking mitochondrial activity (cores) in skeletal fibers. In humans, the RYR1-Y522S mutation is associated with MH and formation of structural cores. Skeletal fibers of knock-in RYR1Y522S/WT mice develop mitochondrial damage and cores, caused by excessive oxidative stress (Boncompagni et al. 2009 PNAS). We treated RYR1Y522S/WT mice with an antioxidant, N-acetylcysteine (NAC), provided ad-libitum in drinking water (1%w/v) for 2 months and verified reduction of oxidative stress: indeed, level of 3-nitrotyrosine was increased by 1.44-folds in RYR1Y522S/WT mice, but reduced to control levels after NAC treatment. Electron microscopy was used to assess mitochondrial integrity following NAC-treatment: a) mitochondria swelling and frequency of damaged mitochondria were both decreased (-24% and -10%, respectively); b) the number/100 µm2 of mitochondria (25.9 ± 0.7 vs 29.1 ± 0.6) and their proper association with the SR (+22%) were both increased. Using histological analysis, we also verified that NAC was effective in reducing the frequency of cores (-20% contracture cores; -30% unstructured cores). Finally, we evaluated muscle function in treated mice by grip strength test: NAC was able to improve muscle strength of about 80%. This work provides the bases for clinical trial as it demonstrate that NAC-administration prevents mitochondrial damage, development of cores, and improves muscle function in a mouse model of CCD., In humans, lethal hyperthermic episodes can be trigger by anesthetics (a disorder known as Malignant Hyperthermia, Susceptibility, MHS) and by high temperature and/or strenuous exercise (crises identified as Environmental/Exertional Heat Strokes, EHSs). The correlation between MHS and EHS is strongly supported by extensive work in animal models: indeed, both RYR1Y522S/WT knock-in and CASQ-1 knockout mice trigger similar lethal crises when exposed to both halothane and heat. Here we tested the following hypotheses: a) strenuous exercise is a stimulus capable to trigger EHS-lethal episodes; b) MHS and EHS share common molecular mechanisms underlying crises. When RYR1Y522S/WT and CASQ1-null mice were subjected to an exertional-stress (ES) protocol (executed on a treadmill placed in an environmental chamber), which was well tolerated by WT animals (0% of deaths), the mortality rate was dramatically increased (80% and 75%, respectively), with a rise in core temperature (hyperthermia) significantly higher than in WT at the end of the stimulus. During exertional-crises, most fibers from RYR1 Y522S/WT and CASQ1-null mice suffer severe structural damage (~99% and ~64% of fibers, respectively), indication of rhabdomyolysis. Importantly, pre-treatment of animals with azumolene (a more water soluble dantrolene analog, the only drug approved for treatment of MH crises in humans) almost completely abolished mortality rate in RYR1 Y522S/WT and CASQ1-null animals, by reducing hyperthermia, rhabdomyolysis, and Ca2+leak from the SR. All these results strongly suggest that EHS share common molecular mechanisms with anesthetic-induced MH episodes and that drugs used to treat classic MH should be considered for treatment of EHS., Duchenne muscular dystrophy (DMD) is an X-linked neuromuscular disorder characterized by progressive muscle degeneration due to lack of dystrophin, a protein essential for the integrity of sarcolemma during contraction. In DMD compensative degeneration/regeneration cycles determine a condition of chronic inflammation contributing to progressive muscle wasting. RAGE (receptor for advanced glycation end-products) is a multiligand receptor belonging to the immunoglobulin superfamily involved in physiological and pathological processes including inflammation and myogenesis [1]. RAGE is not expressed in adult muscle tissue, whereas it is expressed in regenerating myofibers during muscle regeneration [2,3], in dystrophic muscles and activated immune cells. To have information about the role of RAGE in the pathophysiology of DMD we generated a double mutant mdx/Ager–/– mouse lacking dystrophin and RAGE (Ager). We analyzed diaphragms and hind-limb muscles (i.e., tibialis anterior and quadriceps femoris) of mdx, mdx/Ager–/–, Ager–/– and WT mice at different ages (i.e., 2, 3, 4 and 5 weeks, and 3 and 6 months of age). We found that although the absence of RAGE in dystrophic mice did not affect the onset of the pathology, muscles of 5 week- and 6 month-old mdx/Ager–/– mice showed significantly reduced numbers of necrotic myofibers, and reduced areas of immune cell infiltrate compared with age-matched mdx mice. Also, muscles of mdx/Ager–/–mice showed strongly reduced expression of the marker of activated macrophages, MAC3, compared with mdx mice. Moreover, muscles of mdx/Ager–/– mice exhibited significantly reduced PAX7+ve and myogenin+ve cell numbers, pointing to a reduced recruitment of muscle precursor cells and a more efficient regeneration in dystrophic mice lacking RAGE. Our results suggest that RAGE has an important role in sustaining inflammatory and degenerative processes in dystrophic muscles, and that inhibition of RAGE expression/activity might represent a potential therapeutic approach in DMD patients., Ageing is associated to a dramatic increase in the incidence of heart failure, even if the existence of a real age-related cardiomyopathy remains controversial. As effective contraction and relaxation of cardiomyocytes also depends on Ca2+ supply to myofibrils (handled by calcium release units, CRUs) and on efficient ATP production (provided by mitochondria), in this study we performed a morphological study of cardiac cells in hearts from adult and old mice (4 months vs. ≥ 24 months of age) using confocal and electron microscopy. The analysis of CRUs indicates that couplons become shorter with age and that the number of CRUs/50 µm2 is decreased of about 24% (adults: 5.1±0.32; old: 3.9±0.19). Also mitochondria present structural modifications, with a significant increase in the percentage of organelles presenting severe alterations (3.5% vs. 16.5%). Importantly, both CRUs and mitochondria undergo a spatial re-organization with respect to sarcomeres/myofibrils: CRUs may be miss-oriented (longitudinal) or miss-placed (found at the A band instead of being correctly placed in proximity of Z-lines), while mitochondria are often grouped in an abnormal fashion. In addition, WB analysis shows that in aged mice, there is a significant reduced expression of junctophilin-2 (JP-2), a membrane protein involved in maintaining stability and morphometry of dyads. These age-related ultra-structural changes may underlie an inefficient supply of Ca2+ and ATP to contractile elements, providing a possible explanation for heart dysfunction associate to age., Progressive muscle degeneration followed by dilated cardiomyopathy is a hallmark of muscular dystrophy. Stem cell therapy is suggested to replace diseased by healthy myofibers, although so far we are faced by low efficiencies of migration, engraftment and differentiation of stem cells. Chemokines are signalling proteins guiding cell migration and have been shown to tightly regulate cardiac repair. We sought to determine which chemokines are expressed in a dystrophic heart that is undergoing cardiac remodelling. Therefor we analysed chemokine expression of Sarcoglycan-α (Sgcα) null, Sarcoglycan-β (Sgcβ) null and immunodeficient Sgcβ-null mice. High expression of all three monocyte-chemotactic proteins was observed, especially Ccl8 in both Sgcβ-null models and to a greater extent in Sgcα-null mice. Additionally, Fractalkine (Cx3cl1) was upregulated in both the immunocompetent and immunodeficient Sgcβ-null mice. In addition, we aim to evaluate the migration potential of cardiovascular progenitors derived from pluripotent stem cells in vitro, that have the potential to differentiate with high efficiency towards cardiomyocytes, smooth muscle cells and endothelial cells in vitro. We plan to test these cells for their in vivo differentiation and migration capacity towards the previously mentioned chemokines. This sheds perspective for an approachable mechanism, which could potentially improve stem cell homing towards the dystrophic myocardium., Cardiac dysfunction from cardiomyopathy is a frequent manifestation of muscular dystrophy. The primary defect common to most dystrophies involves the disruption of the dystrophin-glycoprotein complex (DGC) with subsequent sarcolemma instability and Ca2+ influx, inducing cellular necrosis. Defective Ca2+ uptake resulting from decreased expression and reduced activity of calcium-transporting ATPase (SERCA2a) and, recently, SERCA2a gene therapy has been demonstrated to mitigate dystrophic diseases. Our previous studies have demonstrated that the dystrophic phenotype observed in δ-sarcoglycan–null hamster is dramatically improved by a long-term dietary supplementation with flaxseeds (FS) (rich in n3-PUFAs), but the molecular mechanisms have not yet been fully understood. The present study was designed to test the hypothesis that FS enriched diet could regulate DGC and SERCA2a proteins that play an important structural and functional role in cardiomyocytes. Therefore, the levels of these proteins and mRNAs were analyzed in heart dystrophic hamsters fed with FS diet for long (five months) or short time (48 hours). Results showed that α- distroglycan, α-, β, γ-sarcoglycan and SERCA2a proteins were down-regulated in dystrophic hearts and FS-diet restored their normal expression pattern. The RT-PCR analysis showed that α-distroglycan, α-sarcoglycan and SERCA2a were up-regulated at the transcriptional level. Interestingly, the mRNAs increase was observed even when FS was administered for short periods suggesting the involvement of an epigenetic mechanism. Therefore, it seems plausible to consider the administration of plant-originated n-3 PUFAs as an adjuvant strategy for attenuating sarcolemma instability and defective Ca2+ uptake that represent major damages associated with dystrophic cardiomyopathies., Oxidative stress (OS) is an imbalance between the production of free radicals, in particular reactive oxygen species (ROS), and the ability of the cells to counteract them by antioxidant responses. ROS production in skeletal muscle occurs mainly in mitochondria, both following physiological stimuli (e.g. aging, physical exercise, or at birth) (1-3) and in response to pathological events, such as denervation (4). In all cases, high levels of ROS actively influence the maintenance of muscle homeostasis. Histone deacetylase 4 (HDAC4) is a member the class II of the HDAC superfamily that regulates many cellular processes (5-7). Following denervation, HDAC4 is upregulated in skeletal muscle: it induces muscle atrophy and represses reinnervation (8-9). Increased levels of ROS cause HDAC4 translocation from the nucleus to the cytoplasm, thus inducing the release of genes transcriptionally repressed by HDAC4(10). However, HDAC4 targets in skeletal muscle have not been discovered yet. In order to investigate the role of HDAC4 in response to OS in skeletal muscle, we use a mouse model with the selective deletion of HDAC4 in myogenin positive cells (HDAC4 mKO mice). HDAC4 mKO mice are viable and do not show gross abnormalities in skeletal muscle. We analyzed mice in two different conditions characterized by elevated OS: at birth and in adult mice following denervation. Molecular responses to oxidative stress are blunted in both newborn and adult HDAC4 mKO compared to control mice. Since elevated ROS contribute to mitochondrial damage and are important in redox signaling from the organelle to the rest of the cell, we analyzed mitochondrial ultrastructure. Both newborn and adult HDAC4 mKO muscles presented damaged mitochondria, altered mitochondrial dynamics and defects in myofiber organization. Our results indicate that HDAC4 is important in skeletal muscle to maintain muscle integrity and a proper response upon OS. Current studies are focused on the identification of HDAC4 targets in the OS response in skeletal muscle, Collagen VI (ColVI) is a major extracellular matrix component made of three genetically distinct α chains and abundantly deposited in the basement membrane of both skeletal muscles and peripheral nerves. Mutations in COL6A1, COL6A2 and COL6A3 genes are known to cause different forms of muscle diseases, including Bethlem myopathy, Ullrich congenital muscular dystrophy and myosclerosis myopathy. ColVI null (Col6a1–/–) mice display a myopathic phenotype characterized by latent mitochondrial dysfunction, spontaneous apoptosis, defective autophagy regulation and compromised muscle regeneration. We recently demonstrated that the absence of ColVI in peripheral nerves leads to hypermyelination, altered Remak bundles, sensory-motor functional deficits and decreased nerve conduction velocities, thus pointing at ColVI as a crucial molecule for peripheral nerve structure and function. Given the muscle and nerve defects displayed by Col6a1 null mice, we decided to explore the role of ColVI in the neuromuscular junction (NMJ). Our unpublished studies revealed that ColVI is indeed deposited at the synapse. Immunofluorescence analysis showed ColVI deposition in NMJs. Preliminary results revealed altered expression of synaptic genes and abnormal electrophysiological parameters in Col6a1–/– mice. These findings suggest a potential role for ColVI at the NMJ, and further studies will allow shedding new light on the roles of this extracellular matrix component in the nerve/muscle axis., Muscular dystrophies are non curable diseases. Recently, new strategies shed light to an increase of muscle regeneration. These strategies focus on epigenetic drugs. TSA (HDACi) achieve to enhance the regeneration rate in both mice and humans. However, new challenges stay on the horizon. Monitoring and controlling the changes of the treatment in muscle without invasive techniques are one of that’s. In our research we identified seven microRNAs differential expressed in FAPs population. FAPs are Key players of muscle regeneration under HDACi treatment. From these seven microRNA, miR-143 has been validated with qRT-PCR, and Chip techniques. This miR-143 form part of a cluster with miR-145 that locates into a long non coding RNA non characterized until that moment. The overexpression of this miR-143 turns FAPs into a non adipogenic phenotype, whereas the inhibition of it recovershe adipogenic behavior. Thus, in this work we are trying to characterize the role of this microRNA and their host gene to understand if it could be a good candidate to be used as marker during the treatment., The central dogma of gene expression is that DNA is transcribed into messenger RNAs, which in turn serve as the template for protein synthesis. In recent years, it has been discovered that genomes of multicellular organisms are characterized by the pervasive expression of different types of non-coding RNAs (ncRNA) and, among them, long non-coding RNAs (IncRNAs). In particular the mammalian genome contains many thousands of lncRNAs, which have been proposed to be fundamental in the regulation of many biological processes such as cellular differentiation and show an aberrant regulation in a variety of diseases. A transcriptome analysis performed during in vitro murine muscle differentiation allowed us to identify a subset of new lncRNAs differentially expressed during myogenesis (1). These transcripts were classified on the basis of their expression in proliferating versus differentiated conditions, muscle-restricted activation and subcellular localization. We are now focusing on the characterization of a nuclear lncRNA conserved in human, lnc-405, up-regulated during differentiation, whose expression is cardiac and skeletal muscle restricted. To dissect its role in myogenesis, we performed loss of function experiments using LNA-Gapmers followed by a transcriptome analysis. This approach revealed a strong down-regulation of a subset of genes involved in fiber contraction, cell fusion and related to several cardiomyopathies. With the idea to better explain its crucial role during myogenesis, we are now focusing on the molecular mechanism by which lnc-405 exerts its function in the nucleus by RIP, ChIRP and RNA pull-down assays that are on going., The functional connection between muscle and nerve is affected in several neuromuscular diseases, including Amyotrophic Lateral Sclerosis (ALS) whose major pathological processes are motor neuron degeneration. However, other cells may be involved in the pathogenesis of ALS and open the possibility that alteration in skeletal muscle homeostasis represents one of the principal mediators of motor neuron degeneration. We have evidences that indicate that muscle selective expression of SOD1G93A mutant gene modulates, at the level of spinal cord of MLC/SOD1G93A mice, relevant mRNA and microRNA associated with myelin homeostasis. Our study provided insights into the pathophysiological interplay between muscle and nerve and supports the hypothesis that skeletal muscle is a source of signals that can affect the nervous system., Calsequestrin (CASQ) is the major protein of the sarcoplasmic reticulum of striated muscle that binds Ca2+ with high capacity and moderate affinity. CASQ exist as a monomer and polymers, depending on Ca2+ concentration. CASQ switches from an unfolded state to a folded monomer when the ionic strength increases allowing the formation of front-to-front first and then back-to-back interactions in higher Ca2+ concentrations. In humans, mutations in the cardiac isoform CASQ2 lead to catecholamine-induced polymorphic ventricular tachycardia. Recently we reported one mutation in the skeletal CASQ1 gene in a group of patients with a vacuolar myopathy characterized by the presence of inclusions containing CASQ1 and other SR proteins. The CASQ1 mutation (CASQ1D244G) affects one of the high-affinity Ca2+-binding sites of the protein and alters the kinetics of Ca2+ release in muscle fibers from patients. Expression of the CASQ1D244G in myotubes and in mouse fibers causes the appearance of SR vacuoles containing aggregates of the mutant CASQ1 protein that resemble those observed in patients. Studies of Ca2+ release showed an increase in Ca2+ storage in CASQ1WT COS-7 transfected cells whereas no increase was observed in CASQ1D244G. Moreover both CASQ1WT and CASQ1D244G were expressed in bacteria, purified and analysed for their ability to polymerize at increasing Ca2+ concentrations. The results obtained indicate that the CASQ1D244G protein polymerizes at lower Ca2+ levels and more rapidly than CASQ1WT. These results suggest that the CASQ1D244G mutation interferes with the correct process of Ca2+ -dependent protein polymerization causing altered intracellular calcium storage and the formation of protein aggregates., Muscle regeneration is dependent upon a complex interplay of different cell types in the muscle stem cell niche. In particular, the recently described population of interstitial fibro-adipogenic progenitors (FAPs) and satellite cells (MuSCs) establish a complex network of interactions to coordinate muscle regeneration. FAPs are able to promote satellite cell differentiation and compensate for muscle necrosis. In our recent studies, we demonstrated that FAPs are the key cellular mediators of the beneficial effect of HDAC inhibitors at early stages of Duchenne Muscular Dystrophy (DMD). Indeed, FAPs, from young mdx mice HDACi, induce myogenesis at expense of adipogenesis and enhance their ability to support MuSCs differentiation. Conversely, FAPs from old mdx mice are resistant to HDACi and repress MuSCs differentiation (Mozzetta et al., 2013; Saccone et al., 2014). Given the importance of the cross-talk between FAPs and MuSCs in DMD progression, we are currently deciphering the role of FAP-released extracellular vesicles (and in particular the exosomes - endosome derived vesicles) as mediators of the functional interactions between mononuclear cell types that contribute to muscle regeneration., Limb Girdle Muscular Dystrophies are rare genetic diseases, characterized by weakness and progressive muscular atrophy. A subfamily of LGMD2 regroups sarcoglycanopathies caused by mutations in genes coding for sarcoglycans. These transmembrane proteins are part of the dystrophin complex that protects muscle fibers against mechanical stress due to contraction. There is no treatment available for these diseases.In order to understand the molecular mechanisms implicated in sarcoglycanopathies and to identify new therapeutic targets, we are conducting two studies: 1 - SG mutants are not present at the muscle fiber membrane because they are retained in the endoplasmic reticulum by the quality control (ERQC) and they are prematurely degraded by the proteasome. To study the ERCQ pathways responsible for sarcoglycan disposal at molecular level, we first generated cell lines expressing clonally one SG mutant. Those clones are now used to investigate the SGs cellular trafficking mechanisms and then to test pharmacological compounds modulating ERCQ pathways. 2 – In these diseases, muscular atrophy affects limb muscles and infrequently head muscles. To investigate mechanisms underlying the fact that some muscles are more affected than other, we analyzed different muscles to search for molecular differences that may sign their relative sensitivity to the genetic defects. The content in micro-RNA of muscles from the limbs and face of Macaca fascicularis was explored. Experiments are in progress to analyze the function of identified micro-RNAs and to evaluate their therapeutic potential for sarcoglycanopathies. These projects will improve the knowledge on physio-pathological mechanisms of sarcoglycanopathies in order to identify new therapies for patients., Facioscapulohumeral muscular dystrophy (FSHD) is one of the most common human myopathies and arises with progressive wasting of facial mimic muscles as well as upper arms and shoulder girdle muscles. In 95% of the cases, FSHD is associated with the copy number reduction of D4Z4 macrosatellite repeats at the subtelomeric region of chromosome 4 (4q35). This change is associated with an epigenetic deregulation of the region that ultimately leads to the de-repression of nearby genes, such as DUX4 and FRG1 that have been reported to contribute to the muscular dystrophic phenotype observed in FSHD patients. The chromatin-associated lncRNA DBE-T, encoded by the FSHD locus, has been shown to be one of the main players of such event, though the molecular mechanism has not been yet fully elucidated. DBE-T is preferentially expressed in FSHD patients where it favors the transcription of the 4q35 genes thanks to the recruitment of the histone methyl transferase of the Trithorax group of epigenetic activators ASH1L. Interestingly, through a structural/functional analysis, we have recognized several DBE-T functional domains that can be exploited as new molecular targets for therapeutic purposes. Specifically, we have identified a region and the molecular mechanism required for DBE-T tethering to the chromatin. In addition, we have mapped the minimal binding domains in ASH1L and DBE-T. Finally, we have highlighted a portion of DBE-T required to positively promote transcription. In agreement, a DBE-T mutant lacking this region is unable to trigger transcription. Currently, through proteomic approaches, we are investigating DBE-T protein partners that are specific for each DBE-T functional domain. Our goal is to identify unknown molecular players that, similarly to ASH1L, are recruited by DBE-T to the FSHD locus and can play a role in the disease. Overall, our study elucidates the molecular mechanism of DBE-T in FSHD and might unveil new therapeutic targets for the treatment of the disease.

Published

2016

23. A novel design for a primary measurement standard for the quantity torque

Author

Taccola, G M, primary and Leão, R J, additional

Published

2016

24. Dall'Isonzo al Piave. Cantinotti tra propaganda e descrizione naturalistica

Author

Colombo, A, Guderzo, M, Gorgoni Gufoni, L, Mazzocca, F, Piva, R, Taccola, G, Tamanini, F, Villari, A, Colombo, A, Guderzo, M, Gorgoni Gufoni, L, Mazzocca, F, Piva, R, Taccola, G, Tamanini, F, and Villari, A

Published

2015

25. La grande guerra. I luoghi e l'arte feriti

Author

F. Mazzocca, Mazzocca, F, Taccola, G, F. Mazzocca, G. Taccola, F. Mazzocca, Mazzocca, F, Taccola, G, F. Mazzocca, and G. Taccola

Published

2015

26. Staggered multi-site low-frequency electrostimulation effectively induces locomotor patterns in the isolated rat spinal cord

Author

Dose, F, primary, Deumens, R, additional, Forget, P, additional, and Taccola, G, additional

Published

2015

27. Museo del Risorgimento, Palazzo Moriggia. Guida sintetica alle collezioni

Author

Patrizia Foglia, Foglia, P, Messina, M, Taccola, G, Antonietta Valenti, M, Zatti, P, Patrizia Foglia, Marina Messina, Gregorio Taccola, Maria Antonietta Valenti, Paola Zatti, Patrizia Foglia, Foglia, P, Messina, M, Taccola, G, Antonietta Valenti, M, Zatti, P, Patrizia Foglia, Marina Messina, Gregorio Taccola, Maria Antonietta Valenti, and Paola Zatti

Published

2014

28. Progetto Giovani 14 (1914-2014) : relazione tecnica

Author

P. Barcella, Barcella, P, Mondini, M, Annibale, M, Poltronieri, R, Stefanoni, S, Bertolotti, C, Taccola, G, Pozzetta, A, P. Barcella, M. Mondini, M. Annibale, R. Poltronieri, S. Stefanoni, C. Bertolotti, G. Taccola, A. Pozzetta, P. Barcella, Barcella, P, Mondini, M, Annibale, M, Poltronieri, R, Stefanoni, S, Bertolotti, C, Taccola, G, Pozzetta, A, P. Barcella, M. Mondini, M. Annibale, R. Poltronieri, S. Stefanoni, C. Bertolotti, G. Taccola, and A. Pozzetta

Published

2014

29. Early spread of hyperexcitability to caudal dorsal horn networks after a chemically-induced lesion of the rat spinal cord in vitro.

Author

UCL - SSS/IONS/CEMO - Pôle Cellulaire et moléculaire, Deumens, Ronald, Mazzone, G L, Taccola, G, UCL - SSS/IONS/CEMO - Pôle Cellulaire et moléculaire, Deumens, Ronald, Mazzone, G L, and Taccola, G

Abstract

Hyperexcitability of dorsal horn neurons has been shown to play a key role in neuropathic pain following chronic experimental spinal cord injury. With a neonatal in vitro spinal cord injury model, we show that a chemically-induced lesion leads to rapid gain-of-function of sublesional dorsal horn networks biased to hyperexcitation. The expression of the GABA synthetic enzyme GAD65 was significantly reduced at the same level of the spinal cord, suggesting a compromised inhibitory system. We propose that our model could be useful to test early approaches to contrast spinal cord injury-induced central sensitization of dorsal horn circuits.

Published

2013

30. Schwann cell migration and neurite outgrowth are influenced by media conditioned by epineurial fibroblasts.

Author

UCL - SSS/IONS/CEMO - Pôle Cellulaire et moléculaire, van Neerven, S G A, Pannaye, P, Bozkurt, A, Van Nieuwenhoven, F, Joosten, E, Hermans, Emmanuel, Taccola, G, Deumens, Ronald, UCL - SSS/IONS/CEMO - Pôle Cellulaire et moléculaire, van Neerven, S G A, Pannaye, P, Bozkurt, A, Van Nieuwenhoven, F, Joosten, E, Hermans, Emmanuel, Taccola, G, and Deumens, Ronald

Abstract

The regenerative capacity of the peripheral nervous system is largely related to Schwann cells undergoing proliferation and migration after injury and forming growth-supporting substrates for severed axons. Novel data show that fibroblasts to a certain extent regulate the pro-regenerative behavior of Schwann cells. In the setting of peripheral nerve injury, the fibroblasts that form the epineurium come into close contact with both Schwann cells and peripheral axons, but the potential influence on these latter two cell types has not been studied yet. In the present study we explored whether culture media, conditioned by epineurial fibroblasts can influence Schwann cells and/or neurite outgrowth from dorsal root ganglia neurons in vitro. Our data indicate that epineurial fibroblast-conditioned culture media substantially increase Schwann cell migration and the outgrowth of neurites. Schwann cell proliferation remained largely unaffected. These same read-out parameters were assayed in a condition where epineurial fibroblasts were subjected to stretch-cell-stress, a mechanical stressor that plays an important role in traumatic peripheral nerve injuries. Stretch-cell-stress of epineurial fibroblasts did not further change the positive effects of conditioned media on Schwann cell migration and neurite outgrowth. From these data we conclude that an as yet unknown pro-regenerative role can be attributed to epineurial fibroblasts, implying that such cells may affect the outcome of severe peripheral nerve injury.

Published

2013

31. L’Archivio della Guerra delle Civiche Raccolte Storiche

Author

C. Benincasa, P. Foglia, Taccola, G, G. Taccola, C. Benincasa, P. Foglia, Taccola, G, and G. Taccola

Published

2013

32. Museo del Risorgimento : guida sintetica

Author

Foglia, P, Lucchini, F, Pardini, M, Taccola, G, Tommasini, E, Valenti, M, Zatti, P, P. Foglia, F. Lucchini, M. Pardini, G. Taccola, E. Tommasini, M.A. Valenti, P. Zatti, Foglia, P, Lucchini, F, Pardini, M, Taccola, G, Tommasini, E, Valenti, M, Zatti, P, P. Foglia, F. Lucchini, M. Pardini, G. Taccola, E. Tommasini, M.A. Valenti, and P. Zatti

Published

2012

33. Proclami e avvisi del 1848 nell'Archivio della Civiche Raccolte Storiche di MIlano

Author

P. Peluffo, M. Canella, P. Zatti, Taccola, G, Gasparello, A, G. Taccola, A. Gasparello, P. Peluffo, M. Canella, P. Zatti, Taccola, G, Gasparello, A, G. Taccola, and A. Gasparello

Published

2011

34. I vestiti nuovi di Babbo Natale

Author

Taccola, G, G. Taccola, Taccola, G, and G. Taccola

Published

2011

35. ERG Conductance Expression Modulates the Excitability of Ventral Horn GABAergic Interneurons That Control Rhythmic Oscillations in the Developing Mouse Spinal Cord

Author

Furlan, F., primary, Taccola, G., additional, Grandolfo, M., additional, Guasti, L., additional, Arcangeli, A., additional, Nistri, A., additional, and Ballerini, L., additional

Published

2007

36. Staggered multi-site low-frequency electrostimulation effectively induces locomotor patterns in the isolated rat spinal cord

Author

Dose, F, Deumens, R, Forget, P, and Taccola, G

Abstract

Study design:Experimental animal study.Objectives:Epidural stimulation has been used to activate locomotor patterns after spinal injury and typically employs synchronous trains of high-frequency stimuli delivered directly to the dorsal cord, thereby recruiting multiple afferent nerve roots. Here we investigate how spinal locomotor networks integrate multi-site afferent input and address whether frequency coding is more important than amplitude to activate locomotor patterns.Setting:Italy and Belgium.Methods:To investigate the importance of input intensity and frequency in eliciting locomotor activity, we used isolated neonatal rat spinal cords to record episodes of fictive locomotion (FL) induced by electrical stimulation of single and multiple dorsal roots (DRs), employing different stimulating protocols.Results:FL was efficiently induced through staggered delivery (delays 0.5 to 2 s) of low-frequency pulse trains (0.33 and 0.67 Hz) to three DRs at intensities sufficient to activate ventral root reflexes. Delivery of the same trains to a single DR or synchronously to multiple DRs remained ineffective. Multi-site staggered trains were more efficient than randomized pulse delivery. Weak trains simultaneously delivered to DRs failed to elicit FL. Locomotor rhythm resetting occurred with single pulses applied to various distant DRs.Conclusion:Electrical stimulation recruited spinal networks that generate locomotor programs when pulses were delivered to multiple sites at low frequency. This finding might help devising new protocols to optimize the increasingly more common use of epidural implantable arrays to treat spinal dysfunctions.

Published

2016

37. ERG conductance expression modulates the excitability of ventral horn GABAergic interneurons that control rhythmic oscillations in the developing mouse spinal cord

Author

Micaela Grandolfo, Francesco Furlan, Laura Ballerini, Annarosa Arcangeli, Andrea Nistri, Giuliano Taccola, Leonardo Guasti, Furlan, F., Taccola, G., Grandolfo, M., Guasti, G., Arcangeli, A., Nistri, A., and Ballerini, Laura

Subjects

ERG1 Potassium Channel, genetic structures, Central nervous system, interneuron, Biology, spinal cord, premotor network, interneurons, patch clamp, erg current, development, Bursting, Mice, Organ Culture Techniques, Anterior Horn Cells, Biological Clocks, medicine, Animals, Patch clamp, gamma-Aminobutyric Acid, Inward-rectifier potassium ion channel, General Neuroscience, Gene Expression Regulation, Developmental, Articles, Spinal cord, Ether-A-Go-Go Potassium Channels, Mice, Inbred C57BL, medicine.anatomical_structure, nervous system, GABAergic, NMDA receptor, Erg, Neuroscience

Abstract

During antenatal development, the operation and maturation of mammalian spinal networks strongly depend on the activity of ventral horn GABAergic interneurons that mediate excitation first and inhibition later. Although the functional consequence of GABA actions may depend on maturational processes in target neurons, it is also likely that evolving changes in GABAergic transmission require fine-tuning in GABA release, probably via certain intrinsic mechanisms regulating GABAergic neuron excitability at different embryonic stages. Nevertheless, it has not been possible, to date, to identify certain ionic conductances upregulated or downregulated before birth in such cells. By using an experimental model with either mouse organotypic spinal cultures or isolated spinal cord preparations, the present study examined the role of the ERG current (IK(ERG)), a potassium conductance expressed by developing, GABA-immunoreactive spinal neurons. In organotypic cultures, only ventral interneurons with fast adaptation and GABA immunoreactivity, and only after 1 week in culture, were transformed into high-frequency bursters by E4031, a selective inhibitor ofIK(ERG)that also prolonged and made more regular spontaneous bursts. In the isolated spinal cord in which GABA immunoreactivity andm-ergmRNA were colocalized in interneurons, ventral root rhythms evoked by NMDA plus 5-hydroxytryptamine were stabilized and synchronized by E4031. All of these effects were lost after 2 weeks in culture or before birth in coincidence with decreasedm-ergexpression. These data suggest that, during an early stage of spinal cord development, the excitability of GABAergic ventral interneurons important for circuit maturation depended, at least in part, on the function ofIK(ERG).

Published

2007

38. Suprapontine Structures Modulate Brainstem and Spinal Networks.

Author

Mohammadshirazi A, Apicella R, Zylberberg BA, Mazzone GL, and Taccola G

Subjects

Rats, Animals, Animals, Newborn, Rats, Sprague-Dawley, Electric Stimulation, Spinal Cord, Brain Stem physiology

Abstract

Several spinal motor output and essential rhythmic behaviors are controlled by supraspinal structures, although their contribution to neuronal networks for respiration and locomotion at birth still requires better characterization. As preparations of isolated brainstem and spinal networks only focus on local circuitry, we introduced the in vitro central nervous system (CNS) from neonatal rodents to simultaneously record a stable respiratory rhythm from both cervical and lumbar ventral roots (VRs).Electrical pulses supplied to multiple sites of brainstem evoked distinct VR responses with staggered onset in the rostro-caudal direction. Stimulation of ventrolateral medulla (VLM) resulted in higher events from homolateral VRs. Stimulating a lumbar dorsal root (DR) elicited responses even from cervical VRs, albeit small and delayed, confirming functional ascending pathways. Oximetric assessments detected optimal oxygen levels on brainstem and cortical surfaces, and histological analysis of internal brain structures indicated preserved neuron viability without astrogliosis. Serial ablations showed precollicular decerebration reducing respiratory burst duration and frequency and diminishing the area of lumbar DR and VR potentials elicited by DR stimulation, while pontobulbar transection increased the frequency and duration of respiratory bursts. Keeping legs attached allows for expressing a respiratory rhythm during hindlimb stimulation. Trains of pulses evoked episodes of fictive locomotion (FL) when delivered to VLM or to a DR, the latter with a slightly better FL than in isolated cords.In summary, suprapontine centers regulate spontaneous respiratory rhythms, as well as electrically evoked reflexes and spinal network activity. The current approach contributes to clarifying modulatory brain influences on the brainstem and spinal microcircuits during development. Novel preparation of the entire isolated CNS from newborn rats unveils suprapontine modulation on brainstem and spinal networks. Preparation views (A) with and without legs attached (B). Successful fictive respiration occurs with fast dissection from P0-P2 rats (C). Decerebration speeds up respiratory rhythm (D) and reduces spinal reflexes derived from both ventral and dorsal lumbar roots (E)., (© 2023. The Author(s).)

Published

2023

39. Passive limb training modulates respiratory rhythmic bursts.

Author

Apicella R and Taccola G

Subjects

Animals, Animals, Newborn, Spinal Nerve Roots physiology, Respiration, Spinal Cord physiology, Respiratory Burst

Abstract

Exercise modifies respiratory functions mainly through the afferent feedback provided by exercising limbs and the descending input from suprapontine areas, two contributions that are still underestimated in vitro. To better characterize the role of limb afferents in modulating respiration during physical activity, we designed a novel experimental in vitro platform. The whole central nervous system was isolated from neonatal rodents and kept with hindlimbs attached to an ad-hoc robot (Bipedal Induced Kinetic Exercise, BIKE) driving passive pedaling at calibrated speeds. This setting allowed extracellular recordings of a stable spontaneous respiratory rhythm for more than 4 h, from all cervical ventral roots. BIKE reversibly reduced the duration of single respiratory bursts even at lower pedaling speeds (2 Hz), though only an intense exercise (3.5 Hz) modulated the frequency of breathing. Moreover, brief sessions (5 min) of BIKE at 3.5 Hz augmented the respiratory rate of preparations with slow bursting in control (slower breathers) but did not change the speed of faster breathers. When spontaneous breathing was accelerated by high concentrations of potassium, BIKE reduced bursting frequency. Regardless of the baseline respiratory rhythm, BIKE at 3.5 Hz always decreased duration of single bursts. Surgical ablation of suprapontine structures completely prevented modulation of breathing after intense training. Albeit the variability in baseline breathing rates, intense passive cyclic movement tuned fictive respiration toward a common frequency range and shortened all respiratory events through the involvement of suprapontine areas. These observations contribute to better define how the respiratory system integrates sensory input from moving limbs during development, opening new rehabilitation perspectives., (© 2023. The Author(s).)

Published

2023

40. An epidural stimulating interface unveils the intrinsic modulation of electrically motor evoked potentials in behaving rats.

Author

Taccola G, Culaclii S, Zhong H, Gad P, Liu W, and Edgerton VR

Subjects

Anesthesia, Animals, Behavior, Animal physiology, Disease Models, Animal, Electromyography, Rats, Evoked Potentials, Motor physiology, Nerve Net physiology, Spinal Cord physiology, Spinal Cord Injuries physiopathology, Spinal Cord Stimulation

Abstract

In intact and spinal-injured anesthetized animals, stimulation levels that did not induce any visible muscle twitches were used to elicit motor evoked potentials (MEPs) of varying amplitude, reflecting the temporal and amplitude dynamics of the background excitability of spinal networks. To characterize the physiological excitability states of neuronal networks driving movement, we designed five experiments in awake rats chronically implanted with an epidural stimulating interface, with and without a spinal cord injury (SCI). First, an uninjured rat at rest underwent a series of single electrical pulses at sub-motor threshold intensity, which generated responses that were continuously recorded from flexor and extensor hindlimb muscles, showing an intrinsic patterned modulation of MEPs. Responses were recruited by increasing strengths of stimulation, and the amplitudes were moderately correlated between flexors and extensors. Next, after SCI, four awake rats at rest showed electrically induced MEPs, varying largely in amplitude, of both flexors and extensors that were mainly synchronously modulated. After full anesthesia, MEP amplitudes were largely reduced, although stimulation still generated random baseline changes, unveiling an intrinsic stochastic modulation. The present five cases demonstrate a methodology that can be feasibly replicated in a broader group of awake and behaving rats to further define experimental treatments involving neuroplasticity. Besides validating a new technology for a neural stimulating interface, the present data support the broader message that there is intrinsic patterned and stochastic modulation of baseline excitability reflecting the dynamics of physiological states of spinal networks. NEW & NOTEWORTHY Chronic implants of a new epidural stimulating interface trace dynamics of spinal excitability in awake rats, before and after injury. Motor evoked potentials induced by trains of pulses at sub-motor threshold intensity were continuously modulated in amplitude. Oscillatory patterns of amplitude modulation reduced with increasing strengths of stimulation and were replaced by an intrinsic stochastic tone under anesthesia. Variability of baseline excitability is a fundamental feature of spinal networks, affecting their responses to external input.

Published

2021

41. A Biomimetic, SoC-Based Neural Stimulator for Novel Arbitrary-Waveform Stimulation Protocols.

Author

Culaclii S, Wang PM, Taccola G, Yang W, Bailey B, Chen YP, Lo YK, and Liu W

Abstract

Novel neural stimulation protocols mimicking biological signals and patterns have demonstrated significant advantages as compared to traditional protocols based on uniform periodic square pulses. At the same time, the treatments for neural disorders which employ such protocols require the stimulator to be integrated into miniaturized wearable devices or implantable neural prostheses. Unfortunately, most miniaturized stimulator designs show none or very limited ability to deliver biomimetic protocols due to the architecture of their control logic, which generates the waveform. Most such designs are integrated into a single System-on-Chip (SoC) for the size reduction and the option to implement them as neural implants. But their on-chip stimulation controllers are fixed and limited in memory and computing power, preventing them from accommodating the amplitude and timing variances, and the waveform data parameters necessary to output biomimetic stimulation. To that end, a new stimulator architecture is proposed, which distributes the control logic over three component tiers - software, microcontroller firmware and digital circuits of the SoC, which is compatible with existing and future biomimetic protocols and with integration into implantable neural prosthetics. A portable prototype with the proposed architecture is designed and demonstrated in a bench-top test with various known biomimetic output waveforms. The prototype is also tested in vivo to deliver a complex, continuous biomimetic stimulation to a rat model of a spinal-cord injury. By delivering this unique biomimetic stimulation, the device is shown to successfully reestablish the connectivity of the spinal cord post-injury and thus restore motor outputs in the rat model., Competing Interests: WL and Y-KL hold shareholder interest in Niche Biomedical Inc. P-MW was employed by the company Niche Biomedical Inc. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Culaclii, Wang, Taccola, Yang, Bailey, Chen, Lo and Liu.)

Published

2021

42. Histamine H 3 Receptors Expressed in Ventral Horns Modulate Spinal Motor Output.

Author

Coslovich T, Della Mora A, D'Angelo G, Ortolani F, and Taccola G

Subjects

Animals, Methylhistamines pharmacology, Motor Neurons drug effects, Rats, Spinal Cord Ventral Horn drug effects, Motor Neurons metabolism, Receptors, Histamine metabolism, Spinal Cord Ventral Horn metabolism

Abstract

Motoneuron activity is modulated by histamine receptors. While H 1 and H 2 receptors have been widely explored, H 3 histamine receptors (H 3 Rs) have not been sufficiently characterized. This paper targets the effects of the selective activation of H 3 Rs and their expression on the membranes of large ventral horn cells. The application of selective pharmacological agents to spinal cords isolated from neonatal rats was used to identify the presence of functional H 3 Rs on the membrane of physiologically identified lumbar motoneurons. Intra and extracellular recordings revealed that H 3 R agonist, α-methylhistamine, depolarized both single motoneurons and ventral roots, even in the presence of tetrodotoxin, an effect prevented by H 3 R antagonist, thioperamide. Finally, immunohistochemistry located the expression of H 3 Rs on a subpopulation of large cells in lamina IX. This study identifies H 3 Rs as a new exploitable pharmacological target against motor disturbances.

Published

2021

43. Complications of epidural spinal stimulation: lessons from the past and alternatives for the future.

Author

Taccola G, Barber S, Horner PJ, Bazo HAC, and Sayenko D

Subjects

Electrodes, Implanted adverse effects, Electrodes, Implanted trends, Forecasting, Humans, Neurological Rehabilitation methods, Spinal Cord Compression diagnosis, Spinal Cord Compression etiology, Spinal Cord Injuries physiopathology, Spinal Cord Stimulation methods, Epidural Space physiology, Spinal Cord Injuries therapy, Spinal Cord Stimulation adverse effects, Spinal Cord Stimulation trends

Abstract

Study Design: Systematic review., Objectives: Over the past decade, an increasing number of studies have demonstrated that epidural spinal cord stimulation (SCS) can successfully assist with neurorehabilitation following spinal cord injury (SCI). This approach is quickly garnering the attention of clinicians. Therefore, the potential benefits of individuals undergoing epidural SCS therapy to regain sensorimotor and autonomic control, must be considered along with the lessons learned from other studies on the risks associated with implantable systems., Methods: Systematic analysis of literature, as well as preclinical and clinical reports., Results: The use of SCS for neuropathic pain management has revealed that epidural electrodes can lose their therapeutic effects over time and lead to complications, such as electrode migration, infection, foreign body reactions, and even SCI. Several authors have also described the formation of a mass composed of glia, collagen, and fibrosis around epidural electrodes. Clinically, this mass can cause myelopathy and spinal compression, and it is only treatable by surgically removing both the electrode and scar tissue., Conclusions: In order to reduce the risk of encapsulation, many innovative efforts focus on technological improvements of electrode biocompatibility; however, they require time and resources to develop and confirm safety and efficiency. Alternatively, some studies have demonstrated similar outcomes of non-invasive, transcutaneous SCS following SCI to those seen with epidural SCS, without the complications associated with implanted electrodes. Thus, transcutaneous SCS can be proposed as a promising candidate for a safer and more accessible SCS modality for some individuals with SCI.

Published

2020

44. Selective Antagonism of A1 Adenosinergic Receptors Strengthens the Neuromodulation of the Sensorimotor Network During Epidural Spinal Stimulation.

Author

Taccola G, Salazar BH, Apicella R, Hogan MK, Horner PJ, and Sayenko D

Abstract

Although epidural spinal stimulation (ESS) results in promising therapeutic effects in individuals with spinal cord injury (SCI), its potential to generate functional motor recovery varies between individuals and remains largely unclear. However, both preclinical and clinical studies indicate the capacity of electrical and pharmacological interventions to synergistically increase the engagement of spinal sensorimotor networks and regain motor function after SCI. This study explored whether selective pharmacological antagonism of the adenosine A1 receptor subtype synergizes with ESS, thereby increasing motor response. We hypothesized that selective pharmacological antagonism of A1 receptors during ESS would produce facilitatory effects in spinal sensorimotor networks detected as an increased amplitude of spinally-evoked motor potentials and sustained duration of ESS induced activity. Terminal experiments were performed in adult rats using trains of stereotyped pulses at 40 Hz delivered at L5 with the local administration to the cord of 8-cyclopentyl-1,3-dipropylxanthine (DPCPX). We demonstrated that ESS combined with the blockage of A1 receptors increased the magnitude of the endogenous modulation and postponed the decay of responses that occur during ESS alone. Although DPCPX significantly increased the yield of repetitive stimulation in intact spinal cords, the effects of A1 antagonism on motor evoked responses after an acute spinal transection was not detected. These studies support the future investigation of the optimal dosage, methods of delivery, and systemic effects of the synergistic application of A1 antagonists and spinal stimulation in the intact and injured spinal cord., (Copyright © 2020 Taccola, Salazar, Apicella, Hogan, Horner and Sayenko.)

Published

2020

45. Nanomolar oxytocin synergizes with weak electrical afferent stimulation to activate the locomotor CpG of the rat spinal cord in vitro.

Author

Dose F, Zanon P, Coslovich T, and Taccola G

Subjects

Animals, Electric Stimulation, Membrane Potentials drug effects, Rats, Receptors, Oxytocin metabolism, Serotonin biosynthesis, Spinal Nerve Roots drug effects, Spinal Nerve Roots physiology, Central Pattern Generators drug effects, Central Pattern Generators physiology, Motor Neurons drug effects, Motor Neurons physiology, Oxytocin pharmacology, Spinal Cord cytology, Spinal Cord physiology

Abstract

Synergizing the effect of afferent fibre stimulation with pharmacological interventions is a desirable goal to trigger spinal locomotor activity, especially after injury. Thus, to better understand the mechanisms to optimize this process, we studied the role of the neuropeptide oxytocin (previously shown to stimulate locomotor networks) on network and motoneuron properties using the isolated neonatal rat spinal cord. On motoneurons oxytocin (1 nM-1 μM) generated sporadic bursts with superimposed firing and dose-dependent depolarization. No desensitization was observed despite repeated applications. Tetrodotoxin completely blocked the effects of oxytocin, demonstrating the network origin of the responses. Recording motoneuron pool activity from lumbar ventral roots showed oxytocin mediated depolarization with synchronous bursts, and depression of reflex responses in a stimulus and peptide-concentration dependent fashion. Disinhibited bursting caused by strychnine and bicuculline was accelerated by oxytocin whose action was blocked by the oxytocin antagonist atosiban. Fictive locomotion appeared when subthreshold concentrations of NMDA plus 5HT were coapplied with oxytocin, an effect prevented after 24 h incubation with the inhibitor of 5HT synthesis, PCPA. When fictive locomotion was fully manifested, oxytocin did not change periodicity, although cycle amplitude became smaller. A novel protocol of electrical stimulation based on noisy waveforms and applied to one dorsal root evoked stereotypic fictive locomotion. Whenever the stimulus intensity was subthreshold, low doses of oxytocin triggered fictive locomotion although oxytocin per se did not affect primary afferent depolarization evoked by dorsal root pulses. Among the several functional targets for the action of oxytocin at lumbar spinal cord level, the present results highlight how small concentrations of this peptide could bring spinal networks to threshold for fictive locomotion in combination with other protocols, and delineate the use of oxytocin to strengthen the efficiency of electrical stimulation to activate locomotor circuits.

Published

2014

46. Rat locomotor spinal circuits in vitro are activated by electrical stimulation with noisy waveforms sampled from human gait.

Author

Dose F, Menosso R, and Taccola G

Abstract

Noisy waveforms, sampled from an episode of fictive locomotion (FL) and delivered to a dorsal root (DR), are a novel electrical stimulating protocol demonstrated as the most effective for generating the locomotor rhythm in the rat isolated spinal cord. The present study explored if stimulating protocols constructed by sampling real human locomotion could be equally efficient to activate these locomotor networks in vitro. This approach may extend the range of usable stimulation protocols and provide a wide palette of noisy waveforms for this purpose. To this end, recorded electromyogram (EMG) from leg muscles of walking adult volunteers provided a protocol named ReaListim (Real Locomotion-induced stimulation) that applied to a single DR successfully activated FL. The smoothed kinematic profile of the same gait failed to do so like nonphasic noisy patterns derived from standing and isometric contraction. Power spectrum analysis showed distinctive low-frequency domains in ReaListim, along with the high-frequency background noise. The current study indicates that limb EMG signals (recorded during human locomotion) applied to DR of the rat spinal cord are more effective than EMG traces taken during standing or isometric contraction of the same muscles to activate locomotor networks. Finally, EMGs recorded during various human motor tasks demonstrated that noisy waves of the same periodicity as ReaListim, could efficiently activate the in vitro central pattern generator (CPG), regardless of the motor task from which they had been sampled. These data outline new strategies to optimize functional stimulation of spinal networks after injury.

Published

2013

47. Coapplication of noisy patterned electrical stimuli and NMDA plus serotonin facilitates fictive locomotion in the rat spinal cord.

Author

Dose F and Taccola G

Subjects

Animals, Baclofen pharmacology, Dose-Response Relationship, Drug, Electric Stimulation, GABA-B Receptor Agonists pharmacology, Rats, Spinal Nerve Roots physiology, Evoked Potentials drug effects, Excitatory Amino Acid Agonists pharmacology, Locomotion physiology, N-Methylaspartate pharmacology, Serotonin pharmacology, Spinal Cord physiology

Abstract

A new stimulating protocol [fictive locomotion-induced stimulation (FListim)], consisting of intrinsically variable weak waveforms applied to a single dorsal root is very effective (though not optimal as it eventually wanes away) in activating the locomotor program of the isolated rat spinal cord. The present study explored whether combination of FListim with low doses of pharmacological agents that raise network excitability might further improve the functional outcome, using this in vitro model. FListim was applied together with N-methyl-d-aspartate (NMDA) + serotonin, while fictive locomotion (FL) was electrophysiologically recorded from lumbar ventral roots. Superimposing FListim on FL evoked by these neurochemicals persistently accelerated locomotor-like cycles to a set periodicity and modulated cycle amplitude depending on FListim rate. Trains of stereotyped rectangular pulses failed to replicate this phenomenon. The GABA(B) agonist baclofen dose dependently inhibited, in a reversible fashion, FL evoked by either FListim or square pulses. Sustained episodes of FL emerged when FListim was delivered, at an intensity subthreshold for FL, in conjunction with subthreshold pharmacological stimulation. Such an effect was, however, not found when high potassium solution instead of NMDA + serotonin was used. These results suggest that the combined action of subthreshold FListim (e.g., via epidural stimulation) and neurochemicals should be tested in vivo to improve locomotor rehabilitation after injury. In fact, reactivation of spinal locomotor circuits by conventional electrical stimulation of afferent fibers is difficult, while pharmacological activation of spinal networks is clinically impracticable due to concurrent unwanted effects. We speculate that associating subthreshold chemical and electrical inputs might decrease side effects when attempting to evoke human locomotor patterns.

Published

2012

48. The locomotor central pattern generator of the rat spinal cord in vitro is optimally activated by noisy dorsal root waveforms.

Author

Taccola G

Subjects

Animals, Animals, Newborn, Electric Stimulation methods, Organ Culture Techniques, Rats, Spinal Cord metabolism, Spinal Nerve Roots metabolism, Action Potentials physiology, Motor Activity physiology, Periodicity, Spinal Cord physiology, Spinal Nerve Roots physiology

Abstract

The spinal cord contains an intrinsic locomotor program driven by a central pattern generator that rhythmically activates flexor and extensor limb motor pools. Although long-lasting locomotor activity can be generated pharmacologically, trains of afferent stimuli trigger only few locomotor cycles. The present study investigated whether a new electrical stimulation protocol (termed FListim) could elicit long-lasting fictive locomotion (FL) in the rat spinal cord in vitro. Thus, after first inducing FL by bath application of N-methyl-d-aspartate and serotonin, the recorded waveform obtained from a lumbar ventral root was digitized and then applied to either a lumbar dorsal root or the cauda equina following washout of pharmacological agents. Two FListim cycles were the threshold input to evoke an episode of FL from ventral roots. Longer cycles (up to 1 min) induced sustained FL (up to 1 min) with stereotyped periodicity (2.2 ± 0.5 s), despite changing frequency (2-4 s) or cycle amplitude of FListim. Gradual filtering out of the noise from FListim trace concomitantly decreased the efficiency of FL so that stimulation with equivalent pure sinusoids produced asynchronous, irregular discharges only that could not be converted to FL by adding spontaneous basal activity. This study is the first demonstration that epochs of rhythmic locomotor-like oscillations applied to a dorsal root represent an efficient stimulus to evoke FL as long as they contain the electrophysiological noise produced within FL cycles. These observations suggest novel strategies to improve the efficiency of electrical stimulation delivered by clinical devices for neurorehabilitation after spinal injury.

Published

2011

49. Newborn Analgesia Mediated by Oxytocin during Delivery.

Author

Mazzuca M, Minlebaev M, Shakirzyanova A, Tyzio R, Taccola G, Janackova S, Gataullina S, Ben-Ari Y, Giniatullin R, and Khazipov R

Abstract

The mechanisms controlling pain in newborns during delivery are poorly understood. We explored the hypothesis that oxytocin, an essential hormone for labor and a powerful neuromodulator, exerts analgesic actions on newborns during delivery. Using a thermal tail-flick assay, we report that pain sensitivity is two-fold lower in rat pups immediately after birth than 2 days later. Oxytocin receptor antagonists strongly enhanced pain sensitivity in newborn, but not in 2-day-old rats, whereas oxytocin reduced pain at both ages suggesting an endogenous analgesia by oxytocin during delivery. Similar analgesic effects of oxytocin, measured as attenuation of pain-vocalization induced by electrical whisker pad stimulation, were also observed in decerebrated newborns. Oxytocin reduced GABA-evoked calcium responses and depolarizing GABA driving force in isolated neonatal trigeminal neurons suggesting that oxytocin effects are mediated by alterations of intracellular chloride. Unlike GABA signaling, oxytocin did not affect responses mediated by P2X3 and TRPV1 receptors. In keeping with a GABAergic mechanism, reduction of intracellular chloride by the diuretic NKCC1 chloride co-transporter antagonist bumetanide mimicked the analgesic actions of oxytocin and its effects on GABA responses in nociceptive neurons. Therefore, endogenous oxytocin exerts an analgesic action in newborn pups that involves a reduction of the depolarizing action of GABA on nociceptive neurons. Therefore, the same hormone that triggers delivery also acts as a natural pain killer revealing a novel facet of the protective actions of oxytocin in the fetus at birth.

Published

2011

50. Anoxic persistence of lumbar respiratory bursts and block of lumbar locomotion in newborn rat brainstem spinal cords.

Author

Taccola G, Secchia L, and Ballanyi K

Subjects

Abdominal Muscles innervation, Action Potentials physiology, Animals, Animals, Newborn, Cervical Vertebrae, Excitatory Amino Acid Agonists pharmacology, Facial Nerve cytology, Facial Nerve physiology, Hypoglossal Nerve cytology, Hypoglossal Nerve physiology, Inhalation physiology, Locomotion physiology, Lumbar Vertebrae, Medulla Oblongata cytology, Motor Neurons physiology, N-Methylaspartate pharmacology, Rats, Rats, Sprague-Dawley, Rats, Wistar, Respiratory Center cytology, Serotonin pharmacology, Spinal Cord cytology, Stimulation, Chemical, Exhalation physiology, Hypoxia physiopathology, Medulla Oblongata physiology, Respiratory Center physiology, Spinal Cord physiology

Abstract

The tolerance of breathing in neonates to oxygen depletion is reflected by persistence of inspiratory-related motor output during sustained anoxia in newborn rat brainstem preparations. It is not known whether lumbar motor networks innervating expiratory abdominal muscles are, in contrast, inhibited by anoxia similar to locomotor networks in neonatal mouse lumbar cords. To test this, we recorded inspiratory-related cervical/hypoglossal plus pre/postinspiratory lumbar/facial nerve activities and, sometimes simultaneously, locomotor rhythms in newborn rat brainstem-spinal cords. Chemical anoxia slowed 1 : 1-coupled cervical and lumbar respiratory rhythms and induced cervical burst doublets associated with depressed preinspiratory and augmented postinspiratory lumbar activities. Similarly, anoxia evoked repetitive hypoglossal bursts and shifted facial activity toward augmented postinspiratory bursting in medullas without spinal cord. Selective lumbar anoxia augmented pre/postinspiratory lumbar bursting without slowing the rhythm. This suggests a medullary origin of both anoxic inspiratory double bursts and preinspiratory depression, but a mixed medullary/lumbar origin of boosted postinspiratory lumbar activity. Lumbar respiratory rhythm is likely to be generated by the parafacial respiratory group expiratory centre as indicated by lack of normoxic and anoxic bursting following brainstem transection between the facial motonucleus and the more caudal pre-Bötzinger complex inspiratory centre. Opposed to sustained respiratory activities, anoxia reversibly abolished non-rhythmic spinal discharges and electrically or chemically evoked lumbar locomotor activities, followed by pronounced postanoxic spinal hyperexcitability. We hypothesize that (i) the anoxia tolerance of neonatal breathing includes pFRG-driven lumbar expiratory networks, (ii) the anoxic respiratory pattern transformation is due to disturbed inspiratory-expiratory centre interactions, and (iii) postanoxic lumbar hyperexcitability contributes to spasticity in cerebral palsy.

Published

2007