Your search keyword '"Ciciliot, S."' showing total 43 results

1. Head-to-head comparison between flash and continuous glucose monitoring systems in outpatients with type 1 diabetes

Author

Bonora, B., Maran, A., Ciciliot, S., Avogaro, A., and Fadini, G. P.

Published

2016

2. Loss of OPA1 in Muscle Impacts Muscle Mass, Metabolic Homeostasis, Systemic Inflammation, and Epithelial Senescence

Author

Tezze, C, Romanello, V, Desbats, Ma, Fadini, Gp, Albiero, M, Favaro, G, Ciciliot, S, Soriano, Me, Morbidoni, V, Cerqua, C, Loefler, S, Kern, H, FRANCESCHI, CLAUDIO, SALVIOLI, STEFANO, CONTE, MARIA, Blaauw, B, Zampieri, S, Salviati, L, Scorrano, L, Sandri, M., Tezze, C, Romanello, V, Desbats, Ma, Fadini, Gp, Albiero, M, Favaro, G, Ciciliot, S, Soriano, Me, Morbidoni, V, Cerqua, C, Loefler, S, Kern, H, Franceschi, C, Salvioli, S, Conte, M, Blaauw, B, Zampieri, S, Salviati, L, Scorrano, L, and Sandri, M.

Subjects

mitochondria, sarcopenia, endocrine system, oxidative stre, FGF21, inflammation, muscle, aging, FoxO, Opa1, eye diseases

Abstract

Mitochondrial dysfunction occurs during aging, but its impact on tissue senescence is unknown. Here, we find that sedentary but not active humans display an age-related decline in the mitochondrial protein, optic atrophy 1 (OPA1), that is associated with muscle loss. In adult mice, acute, muscle-specific deletion of Opa1 induces a precocious senescence phenotype and premature death. Conditional and inducible Opa1 deletion alters mitochondrial morphology and function but not DNA content. Mechanistically, the ablation of Opa1 leads to ER stress, which signals via the unfolded protein response (UPR) and FoxOs, inducing a catabolic program of muscle loss and systemic aging. Pharmacological inhibition of ER stress or muscle-specific deletion of FGF21 compensates for the loss of Opa1, restoring a normal metabolic state and preventing muscle atrophy and premature death. Thus, mitochondrial dysfunction in the muscle can trigger a cascade of signaling initiated at the ER that systemically affects general metabolism and aging.

Published

2017

3. The role of p66Shc in the development of obesity and metabolic disorders: a translational study

Author

Ciciliot, S, Albiero, M, Poncina, N, Menegazzo, L, Foletto, M, Nitti, D, Giorgio, M, Avogaro, A, and Fadini, G

Published

2014

4. P66Shc mediates bone marrow denervation and impairs stem cell mobilisation in diabetes

Author

Fadini, G, Albiero, M, Poncina, N, Ciciliot, S, Menegazzo, L, Vigili de Kreutzenberg, S, Giorgio, M, and Avogaro, A

Published

2013

5. Transcriptional programming of lipid and amino acid metabolism by the skeletal muscle circadian clock

Author

Thomas O. Eichmann, Mattia Albiero, Alberto Casarin, Michaël Jean Hubert, Vanessa Pertegato, Maximilian Kleinert, Katrin Fischer, Fabiana Quagliarini, Bert Blaauw, Vanina Romanello, S. Mazzucco, Ashfaq Ali Mir, Franziska Greulich, Rosario Rizzuto, Gianni Biolo, Dominik Lutter, Stefano Schiaffino, Leonardo Salviati, Marcia Ivonne Peña Paz, Stefano Ciciliot, Lauren E. Wright, Kenneth A. Dyar, N. Henriette Uhlenhaut, Dyar, K. A., Hubert, M. J., Mir, A. A., Ciciliot, S., Lutter, D., Greulich, F., Quagliarini, F., Kleinert, M., Fischer, K., Eichmann, T. O., Wright, L. E., Pena Paz, M. I., Casarin, A., Pertegato, V., Romanello, V., Albiero, M., Mazzucco, S., Rizzuto, R., Salviati, L., Biolo, G., Blaauw, B., Schiaffino, S., and Uhlenhaut, N. H.

Subjects

0301 basic medicine, Messenger, Circadian clock, Protein metabolism, CLOCK Proteins, Muscle Proteins, Gene Expression, Protein Synthesis, Biochemistry, Energy homeostasis, chemistry.chemical_compound, Mice, 0302 clinical medicine, Medicine and Health Sciences, Homeostasis, Biology (General), Amino Acids, Musculoskeletal System, Protein Metabolism, Mice, Knockout, General Neuroscience, Muscles, Circadian Clock, Methods and Resources, ARNTL Transcription Factors, Chemical Synthesis, Skeletal, 11 Medical And Health Sciences, Lipid, Lipids, Cell biology, Circadian Rhythm, Amino Acid, Protein catabolism, Circadian Oscillators, medicine.anatomical_structure, Neuroscience (all), Biochemistry, Genetics and Molecular Biology (all), Immunology and Microbiology (all), Agricultural and Biological Sciences (all), ARNTL Transcription Factor, Muscle, Anatomy, General Agricultural and Biological Sciences, Human, Muscle Protein Synthesis, endocrine system, Biosynthetic Techniques, QH301-705.5, Knockout, Biology, Research and Analysis Methods, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Circadian Clocks, Homeostasi, medicine, Genetics, Animals, Humans, CLOCK Protein, RNA, Messenger, Muscle, Skeletal, General Immunology and Microbiology, Animal, Protein turnover, Skeletal muscle, Correction, Biology and Life Sciences, Proteins, Lipid metabolism, Metabolism, 06 Biological Sciences, Lipid Metabolism, Amino Acid Metabolism, 030104 developmental biology, chemistry, Skeletal Muscles, RNA, 07 Agricultural And Veterinary Sciences, Chronobiology, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Circadian clocks are fundamental physiological regulators of energy homeostasis, but direct transcriptional targets of the muscle clock machinery are unknown. To understand how the muscle clock directs rhythmic metabolism, we determined genome-wide binding of the master clock regulators brain and muscle ARNT-like protein 1 (BMAL1) and REV-ERBα in murine muscles. Integrating occupancy with 24-hr gene expression and metabolomics after muscle-specific loss of BMAL1 and REV-ERBα, here we unravel novel molecular mechanisms connecting muscle clock function to daily cycles of lipid and protein metabolism. Validating BMAL1 and REV-ERBα targets using luciferase assays and in vivo rescue, we demonstrate how a major role of the muscle clock is to promote diurnal cycles of neutral lipid storage while coordinately inhibiting lipid and protein catabolism prior to awakening. This occurs by BMAL1-dependent activation of Dgat2 and REV-ERBα-dependent repression of major targets involved in lipid metabolism and protein turnover (MuRF-1, Atrogin-1). Accordingly, muscle-specific loss of BMAL1 is associated with metabolic inefficiency, impaired muscle triglyceride biosynthesis, and accumulation of bioactive lipids and amino acids. Taken together, our data provide a comprehensive overview of how genomic binding of BMAL1 and REV-ERBα is related to temporal changes in gene expression and metabolite fluctuations., Author summary Circadian clocks are known to regulate local and systemic homeostasis by anticipating rhythmic changes in behavior and nutritional state and by compartmentalizing incompatible metabolic pathways within precise temporal and spatial windows. Yet a precise mechanistic understanding of how the circadian clock in skeletal muscle controls homeostasis is just beginning to come to light. Here, we investigated how the muscle clock directs 24-hr metabolic rhythms. We compared genome-wide binding of clock transcription factors brain and muscle ARNT-like protein 1 (BMAL1) and REV-ERBα with 24-hr transcriptional and metabolic effects after their loss of function specifically in muscles. We found that the muscle clock plays a major role anticipating the transition from fasting to feeding. This occurs by direct activation of transcriptional programs promoting lipid storage, insulin sensitivity, and glucose metabolism, with coordinated repression of programs controlling lipid oxidation and protein catabolism. Importantly, these gene expression changes occur in the hours prior to systemic metabolic and hormonal cues that arise upon awakening. As such, we find that the muscle clock tips the scales in favor of glucose metabolism, whereas loss of function of the clock transcription factor BMAL1 is associated with persistent lipid metabolism, protein catabolism, and metabolic inefficiency.

Published

2018

6. A Novel MAO-B/SSAO Inhibitor Improves Multiple Aspects of Dystrophic Phenotype in mdx Mice.

Author

Gasparella F, Nogara L, Germinario E, Tibaudo L, Ciciliot S, Piccoli G, Venegas FC, Fontana F, Sales G, Sabbatini D, Foot J, Jarolimek W, Blaauw B, Canton M, and Vitiello L

Abstract

Duchenne muscular dystrophy (DMD) is one of the most frequent and severe childhood muscle diseases. Its pathophysiology is multifaceted and still incompletely understood, but we and others have previously shown that oxidative stress plays an important role. In particular, we have demonstrated that inhibition of mitochondrial monoamine oxidases could improve some functional and biohumoral markers of the pathology. In the present study we report the use of dystrophic mdx mice to evaluate the efficacy of a dual monoamine oxidase B (MAO-B)/semicarbazide-sensitive amine oxidase (SSAO) inhibitor, PXS-5131, in reducing inflammation and fibrosis and improving muscle function. We found that a one-month treatment starting at three months of age was able to decrease reactive oxygen species (ROS) production, fibrosis, and inflammatory infiltrate in the tibialis anterior (TA) and diaphragm muscles. Importantly, we also observed a marked improvement in the capacity of the gastrocnemius muscle to maintain its force when challenged with eccentric contractions. Upon performing a bulk RNA-seq analysis, PXS-5131 treatment affected the expression of genes involved in inflammatory processes and tissue remodeling. We also studied the effect of prolonged treatment in older dystrophic mice, and found that a three-month administration of PXS-5131 was able to greatly reduce the progression of fibrosis not only in the diaphragm but also in the heart. Taken together, these results suggest that PXS-5131 is an effective inhibitor of fibrosis and inflammation in dystrophic muscles, a finding that could open a new therapeutic avenue for DMD patients.

Published

2024

7. A combination of metformin and galantamine exhibits synergistic benefits in the treatment of sarcopenia.

Author

Tezze C, Amendolagine FI, Nogara L, Baraldo M, Ciciliot S, Arcidiacono D, Zaramella A, Masiero G, Ferrarese G, Realdon S, Blaauw B, Detienne G, Beliën AT, Sandri M, and Mercken EM

Subjects

Humans, Mice, Animals, Aged, Infant, Galantamine pharmacology, Aging physiology, Muscle, Skeletal pathology, Mice, Transgenic, Sarcopenia drug therapy, Metformin pharmacology

Abstract

Age-associated sarcopenia, characterized by a progressive loss in muscle mass and strength, is the largest cause of frailty and disability in the elderly worldwide. Current treatments involve nonpharmacological guidelines that few subjects can abide by, highlighting the need for effective drugs. Preclinical models were employed to test the benefits of RJx-01, a combination drug composed of metformin and galantamine, on sarcopenia. In worms, RJx-01 treatment improved lifespan, locomotion, pharyngeal pumping, and muscle fiber organization. The synergistic effects of RJx-01 were recapitulated in a transgenic mouse model that displays an exacerbated aging phenotype (Opa1-/-). In these mice, RJx-01 ameliorated physical performance, muscle mass and force, neuromuscular junction stability, and systemic inflammation. RJx-01 also improved physical performance and muscle strength in 22-month-old WT mice and also improved skeletal muscle ultrastructure, mitochondrial morphology, autophagy, lysosomal function, and satellite cell content. Denervation and myofiber damage were decreased in RJx-01-treated animals compared with controls. RJx-01 improved muscle quality rather than quantity, indicating that the improvement in quality underlies the beneficial effects of the combination drug. The studies herein indicate synergistic beneficial effects of RJx-01 in the treatment of sarcopenia and support the pursuit of RJx-01 in a human clinical trial as a therapeutic intervention for sarcopenia.

Published

2023

8. Porcine Cornea Storage Ex Vivo Model as an Alternative to Human Donor Tissues for Investigations of Endothelial Layer Preservation.

Author

Rodella U, Bosio L, Ferrari S, Gatto C, Giurgola L, Rossi O, Ciciliot S, Ragazzi E, Ponzin D, and D'Amato Tóthová J

Subjects

Humans, Swine, Animals, Cornea, Tissue Donors, Endothelium, Corneal, Endothelial Cells

Abstract

Purpose: Due to the growing shortage of human corneas for research, we developed a porcine cornea storage model with qualitative features comparable to human tissues., Methods: We established a decontamination procedure for porcine eye bulbs to ensure corneal storage at 31°C to 35°C for up to 28 days without contamination. We compared human and porcine corneas under hypothermic (2-8°C) or culture (31-35°C) conditions for central corneal thickness (CCT), corneal transparency, endothelial morphology, endothelial cell density (ECD), and a novel method to quantify whole endothelial mortality. We also examined portions of lamellar tissues consisting of Descemet's membrane and endothelial cells under the microscope after Alizarin red staining., Results: Our decontamination procedure reduced corneal contamination from 94% (control corneas without decontamination) to 18% after 28 days of storage at 31°C to 35°C. ECD, CCT, transparency, and morphology were significantly higher in porcine corneas than in human corneas at day 0. Nevertheless, the qualitative parameters of porcine and human corneas showed comparable trends under both investigated storage conditions for up to 14 days., Conclusions: The presented corneal storage model provides a reliable alternative to human tissues for preliminary corneal investigations., Translational Relevance: The porcine cornea storage model can be used to investigate the efficacy and safety of new media, substances, or storage conditions. Furthermore, the method developed to assess the percentage of endothelial mortality is tissue conservative and can be used in eye banks to monitor endothelial mortality during storage of tissues intended for transplantation.

Published

2023

9. Loss of Hematopoietic Cell-Derived Oncostatin M Worsens Diet-Induced Dysmetabolism in Mice.

Author

Albiero M, Ciciliot S, Rodella A, Migliozzi L, Amendolagine FI, Boscaro C, Zuccolotto G, Rosato A, and Fadini GP

Subjects

Mice, Animals, Oncostatin M genetics, Oncostatin M metabolism, Adipose Tissue metabolism, Diet, High-Fat adverse effects, Glucose Intolerance metabolism, Hematopoietic Stem Cell Transplantation

Abstract

Innate immune cells infiltrate growing adipose tissue and propagate inflammatory clues to metabolically distant tissues, thereby promoting glucose intolerance and insulin resistance. Cytokines of the IL-6 family and gp130 ligands are among such signals. The role played by oncostatin M (OSM) in the metabolic consequences of overfeeding is debated, at least in part, because prior studies did not distinguish OSM sources and dynamics. Here, we explored the role of OSM in metabolic responses and used bone marrow transplantation to test the hypothesis that hematopoietic cells are major contributors to the metabolic effects of OSM. We show that OSM is required to adapt during the development of obesity because OSM concentrations are dynamically modulated during high-fat diet (HFD) and Osm-/- mice displayed early-onset glucose intolerance, impaired muscle glucose uptake, and worsened liver inflammation and damage. We found that OSM is mostly produced by blood cells and deletion of OSM in hematopoietic cells phenocopied glucose intolerance of whole-body Osm-/- mice fed a HFD and recapitulated liver damage with increased aminotransferase levels. We thus uncovered that modulation of OSM is involved in the metabolic response to overfeeding and that hematopoietic cell-derived OSM can regulate metabolism, likely via multiple effects in different tissues., (© 2023 by the American Diabetes Association.)

Published

2023

10. Hematopoietic Stem Cells and Metabolic Deterioration in Alström Syndrome, a Rare Genetic Model of the Metabolic Syndrome.

Author

Dassie F, Albiero M, Bettini S, Cappellari R, Milan G, Ciciliot S, Naggert JK, Avogaro A, Vettor R, Maffei P, and Fadini GP

Subjects

Animals, Mice, Models, Genetic, Bone Marrow Cells metabolism, Hematopoietic Stem Cells, Metabolic Syndrome genetics, Metabolic Syndrome metabolism, Alstrom Syndrome genetics, Alstrom Syndrome metabolism, Diabetes Mellitus, Experimental metabolism

Abstract

Alström syndrome (AS) is a rare genetic disease caused by ALMS1 mutations, characterized by short stature, and vision and hearing loss. Patients with AS develop the metabolic syndrome, long-term organ complications, and die prematurely. We explored the association between AS and a shortage of hematopoietic stem/progenitor cells (HSPCs), which is linked to metabolic diseases and predicts diabetic complications. We included patients with AS at a national referral center. We measured HSPCs with flow cytometry at baseline and follow-up. We followed patients up to January 2022 for metabolic worsening and end-organ damage. We evaluated HSPC levels and mobilization as well as bone marrow histology in a murine model of AS. In 23 patients with AS, we found significantly lower circulating HSPCs than in healthy blood donors (-40%; P = .002) and age/sex-matched patients (-25%; P = .022). Longitudinally, HSPCs significantly declined by a further 20% in patients with AS over a median of 36 months (interquartile range 30-44). Patients with AS who displayed metabolic deterioration over 5.3 years had lower levels of HSPCs, both at baseline and at last observation, than those who did not deteriorate. Alms1-mutated mice were obese and insulin resistant and displayed significantly reduced circulating HSPCs, despite no overt hematological abnormality. Contrary to what was observed in diabetic mice, HSPC mobilization and bone marrow structure were unaffected. We found depletion of HSPCs in patients with AS, which was recapitulated in Alms1-mutated mice. Larger and longer studies will be needed to establish HSPCs shortage as a driver of metabolic deterioration leading to end-organ damage in AS., (© The Author(s) 2023. Published by Oxford University Press on behalf of the Endocrine Society. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2023

11. Signatures of muscle disuse in spaceflight and bed rest revealed by single muscle fiber proteomics.

Author

Murgia M, Ciciliot S, Nagaraj N, Reggiani C, Schiaffino S, Franchi MV, Pišot R, Šimunič B, Toniolo L, Blaauw B, Sandri M, Biolo G, Flück M, Narici MV, and Mann M

Abstract

Astronauts experience dramatic loss of muscle mass, decreased strength, and insulin resistance, despite performing daily intense physical exercise that would lead to muscle growth on Earth. Partially mimicking spaceflight, prolonged bed rest causes muscle atrophy, loss of force, and glucose intolerance. To unravel the underlying mechanisms, we employed highly sensitive single fiber proteomics to detail the molecular remodeling caused by unloading and inactivity during bed rest and changes of the muscle proteome of astronauts before and after a mission on the International Space Station. Muscle focal adhesions, involved in fiber-matrix interaction and insulin receptor stabilization, are prominently downregulated in both bed rest and spaceflight and restored upon reloading. Pathways of antioxidant response increased strongly in slow but not in fast muscle fibers. Unloading alone upregulated markers of neuromuscular damage and the pathway controlling EIF5A hypusination. These proteomic signatures of mechanical unloading in muscle fiber subtypes contribute to disentangle the effect of microgravity from the pleiotropic challenges of spaceflight., (© The Author(s) 2022. Published by Oxford University Press on behalf of the National Academy of Sciences.)

Published

2022

12. Activation of Akt-mTORC1 signalling reverts cancer-dependent muscle wasting.

Author

Geremia A, Sartori R, Baraldo M, Nogara L, Balmaceda V, Dumitras GA, Ciciliot S, Scalabrin M, Nolte H, and Blaauw B

Subjects

Animals, Humans, Mechanistic Target of Rapamycin Complex 1, Mice, Muscle, Skeletal pathology, Proto-Oncogene Proteins c-akt metabolism, Cachexia pathology, Carcinoma, Lewis Lung pathology

Abstract

Background: Cancer-related muscle wasting occurs in most cancer patients. An important regulator of adult muscle mass and function is the Akt-mTORC1 pathway. While Akt-mTORC1 signalling is important for adult muscle homeostasis, it is also a major target of numerous cancer treatments. Which role Akt-mTORC1 signalling plays during cancer cachexia in muscle is currently not known. Here, we aimed to determine how activation or inactivation of the pathway affects skeletal muscle during cancer cachexia., Methods: We used inducible, muscle-specific Raptor ko (mTORC1) mice to determine the effect of reduced mTOR signalling during cancer cachexia. On the contrary, in order to understand if skeletal muscles maintain their anabolic capacity and if activation of Akt-mTORC1 signalling can reverse cancer cachexia, we generated mice in which we can inducibly activate Akt specifically in skeletal muscles., Results: We found that mTORC1 signalling is impaired during cancer cachexia, using the Lewis lung carcinoma and C26 colon cancer model, and is accompanied by a reduction in protein synthesis rates of 57% (P < 0.01). Further reduction of mTOR signalling, as seen in Raptor ko animals, leads to a 1.5-fold increase in autophagic flux (P > 0.001), but does not further increase muscle wasting. On the other hand, activation of Akt-mTORC1 signalling in already cachectic animals completely reverses the 15-20% loss in muscle mass and force (P < 0.001). Interestingly, Akt activation only in skeletal muscle completely normalizes the transcriptional deregulation observed in cachectic muscle, despite having no effect on tumour size or spleen mass. In addition to stimulating muscle growth, it is also sufficient to prevent the increase in protein degradation normally observed in muscles from tumour-bearing animals., Conclusions: Here, we show that activation of Akt-mTORC1 signalling is sufficient to completely revert cancer-dependent muscle wasting. Intriguingly, these results show that skeletal muscle maintains its anabolic capacities also during cancer cachexia, possibly giving a rationale behind some of the beneficial effects observed in exercise in cancer patients., (© 2021 The Authors. Journal of Cachexia, Sarcopenia and Muscle published by John Wiley & Sons Ltd on behalf of Society on Sarcopenia, Cachexia and Wasting Disorders.)

Published

2022

13. Neuromuscular junction instability and altered intracellular calcium handling as early determinants of force loss during unloading in humans.

Author

Monti E, Reggiani C, Franchi MV, Toniolo L, Sandri M, Armani A, Zampieri S, Giacomello E, Sarto F, Sirago G, Murgia M, Nogara L, Marcucci L, Ciciliot S, Šimunic B, Pišot R, and Narici MV

Subjects

Humans, Muscle Contraction, Muscle, Skeletal, Neuromuscular Junction, Quadriceps Muscle, Calcium, Sarcoplasmic Reticulum

Abstract

Key Points: Few days of unloading are sufficient to induce a decline of skeletal muscle mass and function; notably, contractile force is lost at a faster rate than muscle mass. The reasons behind this disproportionate loss of muscle force are still poorly understood. We provide strong evidence of two mechanisms only hypothesized until now for the rapid muscle force loss in only 10 days of bed rest. Our results show that an initial neuromuscular junction instability, accompanied by alterations in the innervation status and impairment of single fibre sarcoplasmic reticulum function contribute to the loss of contractile force in front of a preserved myofibrillar function and central activation capacity. Early onset of neuromuscular junction instability and impairment in calcium dynamics involved in excitation-contraction coupling are proposed as eligible determinants to the greater decline in muscle force than in muscle size during unloading., Abstract: Unloading induces rapid skeletal muscle atrophy and functional decline. Importantly, force is lost at a much higher rate than muscle mass. We aimed to investigate the early determinants of the disproportionate loss of force compared to that of muscle mass in response to unloading. Ten young participants underwent 10 days of bed rest (BR). At baseline (BR0) and at 10 days (BR10), quadriceps femoris (QF) volume (VOL) and isometric maximum voluntary contraction (MVC) were assessed. At BR0 and BR10 blood samples and biopsies of vastus lateralis (VL) muscle were collected. Neuromuscular junction (NMJ) stability and myofibre innervation status were assessed, together with single fibre mechanical properties and sarcoplasmic reticulum (SR) calcium handling. From BR0 to BR10, QFVOL and MVC decreased by 5.2% (P = 0.003) and 14.3% (P < 0.001), respectively. Initial and partial denervation was detected from increased neural cell adhesion molecule (NCAM)-positive myofibres at BR10 compared with BR0 (+3.4%, P = 0.016). NMJ instability was further inferred from increased C-terminal agrin fragment concentration in serum (+19.2% at BR10, P = 0.031). Fast fibre cross-sectional area (CSA) showed a trend to decrease by 15% (P = 0.055) at BR10, while single fibre maximal tension (force/CSA) was unchanged. However, at BR10 SR Ca 2+ release in response to caffeine decreased by 35.1% (P < 0.002) and 30.2% (P < 0.001) in fast and slow fibres, respectively, pointing to an impaired excitation-contraction coupling. These findings support the view that the early onset of NMJ instability and impairment in SR function are eligible mechanisms contributing to the greater decline in muscle force than in muscle size during unloading., (© 2021 The Authors. The Journal of Physiology published by John Wiley & Sons Ltd on behalf of The Physiological Society.)

Published

2021

14. Pharmacologic PPAR-γ Activation Reprograms Bone Marrow Macrophages and Partially Rescues HSPC Mobilization in Human and Murine Diabetes.

Author

Tedesco S, Ciciliot S, Menegazzo L, D'Anna M, Scattolini V, Cappellari R, Cignarella A, Avogaro A, Albiero M, and Fadini GP

Subjects

Adipogenesis, Animals, Bone Marrow Cells physiology, Cellular Reprogramming, Chemokine CXCL12 biosynthesis, Female, Humans, Macrophages physiology, Male, Mice, Mice, Inbred C57BL, Oncostatin M antagonists & inhibitors, Src Homology 2 Domain-Containing, Transforming Protein 1 physiology, Bone Marrow Cells drug effects, Diabetes Mellitus, Experimental drug therapy, Hematopoietic Stem Cell Mobilization, Macrophages drug effects, PPAR gamma agonists, Pioglitazone pharmacology

Abstract

Mobilization of hematopoietic stem/progenitor cells (HSPC) from the bone marrow (BM) is impaired in diabetes. Excess oncostatin M (OSM) produced by M1 macrophages in the diabetic BM signals through p66Shc to induce Cxcl12 in stromal cells and retain HSPC. BM adipocytes are another source of CXCL12 that blunts mobilization. We tested a strategy of pharmacologic macrophage reprogramming to rescue HSPC mobilization. In vitro, PPAR-γ activation with pioglitazone switched macrophages from M1 to M2, reduced Osm expression, and prevented transcellular induction of Cxcl12 In diabetic mice, pioglitazone treatment downregulated Osm , p66Shc , and Cxcl12 in the hematopoietic BM, restored the effects of granulocyte-colony stimulation factor (G-CSF), and partially rescued HSPC mobilization, but it increased BM adipocytes. Osm deletion recapitulated the effects of pioglitazone on adipogenesis, which was p66Shc independent, and double knockout of Osm and p66Shc completely rescued HSPC mobilization. In the absence of OSM, BM adipocytes produced less CXCL12, being arguably devoid of HSPC-retaining activity, whereas pioglitazone failed to downregulate Cxcl12 in BM adipocytes. In patients with diabetes on pioglitazone therapy, HSPC mobilization after G-CSF was partially rescued. In summary, pioglitazone reprogrammed BM macrophages and suppressed OSM signaling, but sustained Cxcl12 expression by BM adipocytes could limit full recovery of HSPC mobilization., (© 2020 by the American Diabetes Association.)

Published

2020

15. Diabetes-Associated Myelopoiesis Drives Stem Cell Mobilopathy Through an OSM-p66Shc Signaling Pathway.

Author

Albiero M, Ciciliot S, Tedesco S, Menegazzo L, D'Anna M, Scattolini V, Cappellari R, Zuccolotto G, Rosato A, Cignarella A, Giorgio M, Avogaro A, and Fadini GP

Subjects

Adult, Aged, Animals, Bone Marrow Transplantation, Chemokine CXCL12 genetics, Diabetes Mellitus metabolism, Female, Granulocyte Colony-Stimulating Factor, Hematopoietic Stem Cell Mobilization, Humans, Male, Mesenchymal Stem Cells metabolism, Middle Aged, Oncostatin M metabolism, Signal Transduction, Src Homology 2 Domain-Containing, Transforming Protein 1 metabolism, Stem Cells, Diabetes Mellitus, Experimental metabolism, Hematopoietic Stem Cells metabolism, Myelopoiesis genetics, Oncostatin M genetics, Src Homology 2 Domain-Containing, Transforming Protein 1 genetics

Abstract

Diabetes impairs the mobilization of hematopoietic stem/progenitor cells (HSPCs) from the bone marrow (BM), which can worsen the outcomes of HSPC transplantation and of diabetic complications. In this study, we examined the oncostatin M (OSM)-p66Shc pathway as a mechanistic link between HSPC mobilopathy and excessive myelopoiesis. We found that streptozotocin-induced diabetes in mice skewed hematopoiesis toward the myeloid lineage via hematopoietic-intrinsic p66Shc. The overexpression of Osm resulting from myelopoiesis prevented HSPC mobilization after granulocyte colony-stimulating factor (G-CSF) stimulation. The intimate link between myelopoiesis and impaired HSPC mobilization after G-CSF stimulation was confirmed in human diabetes. Using cross-transplantation experiments, we found that deletion of p66Shc in the hematopoietic or nonhematopoietic system partially rescued defective HSPC mobilization in diabetes. Additionally, p66Shc mediated the diabetes-induced BM microvasculature remodeling. Ubiquitous or hematopoietic restricted Osm deletion phenocopied p66Shc deletion in preventing diabetes-associated myelopoiesis and mobilopathy. Mechanistically, we discovered that OSM couples myelopoiesis to mobilopathy by inducing Cxcl12 in BM stromal cells via nonmitochondrial p66Shc. Altogether, these data indicate that cell-autonomous activation of the OSM-p66Shc pathway leads to diabetes-associated myelopoiesis, whereas its transcellular hematostromal activation links myelopoiesis to mobilopathy. Targeting the OSM-p66Shc pathway is a novel strategy to disconnect mobilopathy from myelopoiesis and restore normal HSPC mobilization., (© 2019 by the American Diabetes Association.)

Published

2019

16. Modulation of Obesity and Insulin Resistance by the Redox Enzyme and Adaptor Protein p66 Shc .

Author

Ciciliot S and Fadini GP

Subjects

Animals, Energy Metabolism, Humans, Oxidation-Reduction, Signal Transduction, Insulin Resistance, Obesity enzymology, Src Homology 2 Domain-Containing, Transforming Protein 1 metabolism

Abstract

Initially reported as a longevity-related protein, the 66 kDa isoform of the mammalian Shc1 locus has been implicated in several metabolic pathways, being able to act both as an adaptor protein and as a redox enzyme capable of generating reactive oxygen species (ROS) when it localizes to the mitochondrion. Ablation of p66 Shc has been shown to be protective against obesity and the insurgence of insulin resistance, but not all the studies available in the literature agree on these points. This review will focus in particular on the role of p66 Shc in the modulation of glucose homeostasis, obesity, body temperature, and respiration/energy expenditure. In view of the obesity and diabetes epidemic, p66 Shc may represent a promising therapeutic target with enormous implications for human health.

Published

2019

17. Loss of mitochondrial calcium uniporter rewires skeletal muscle metabolism and substrate preference.

Author

Gherardi G, Nogara L, Ciciliot S, Fadini GP, Blaauw B, Braghetta P, Bonaldo P, De Stefani D, Rizzuto R, and Mammucari C

Subjects

Animals, Calcium metabolism, Cytosol metabolism, Energy Metabolism genetics, Glucose metabolism, Glycolysis, Male, Mice, Mice, Transgenic, Mitochondria metabolism, Mitochondrial Membrane Transport Proteins metabolism, Muscle Strength genetics, Oxidation-Reduction, Physical Conditioning, Animal, Protein Phosphatase 2C metabolism, Pyruvate Dehydrogenase Acetyl-Transferring Kinase metabolism, Calcium Channels genetics, Calcium Channels metabolism, Fatty Acids metabolism, Gene Silencing, Muscle, Skeletal metabolism, Myosin Heavy Chains metabolism

Abstract

Skeletal muscle mitochondria readily accumulate Ca 2+ in response to SR store-releasing stimuli thanks to the activity of the mitochondrial calcium uniporter (MCU), the highly selective channel responsible for mitochondrial Ca 2+ uptake. MCU positively regulates myofiber size in physiological conditions and counteracts pathological loss of muscle mass. Here we show that skeletal muscle-specific MCU deletion inhibits myofiber mitochondrial Ca 2+ uptake, impairs muscle force and exercise performance, and determines a slow to fast switch in MHC expression. Mitochondrial Ca 2+ uptake is required for effective glucose oxidation, as demonstrated by the fact that in muscle-specific MCU - /- myofibers oxidative metabolism is impaired and glycolysis rate is increased. Although defective, mitochondrial activity is partially sustained by increased fatty acid (FA) oxidation. In MCU - /- myofibers, PDP2 overexpression drastically reduces FA dependency, demonstrating that decreased PDH activity is the main trigger of the metabolic rewiring of MCU - /- muscles. Accordingly, PDK4 overexpression in MCU fl/fl myofibers is sufficient to increase FA-dependent respiration. Finally, as a result of the muscle-specific MCU deletion, a systemic catabolic response impinging on both liver and adipose tissue metabolism occurs.

Published

2019

18. Transcriptional programming of lipid and amino acid metabolism by the skeletal muscle circadian clock.

Author

Dyar KA, Hubert MJ, Mir AA, Ciciliot S, Lutter D, Greulich F, Quagliarini F, Kleinert M, Fischer K, Eichmann TO, Wright LE, Peña Paz MI, Casarin A, Pertegato V, Romanello V, Albiero M, Mazzucco S, Rizzuto R, Salviati L, Biolo G, Blaauw B, Schiaffino S, and Uhlenhaut NH

Subjects

Amino Acids metabolism, Amino Acids physiology, Animals, CLOCK Proteins genetics, Circadian Rhythm genetics, Gene Expression, Homeostasis, Humans, Lipid Metabolism physiology, Lipids, Mice, Mice, Knockout, RNA, Messenger metabolism, ARNTL Transcription Factors physiology, Circadian Clocks physiology, Muscle, Skeletal physiology

Abstract

Circadian clocks are fundamental physiological regulators of energy homeostasis, but direct transcriptional targets of the muscle clock machinery are unknown. To understand how the muscle clock directs rhythmic metabolism, we determined genome-wide binding of the master clock regulators brain and muscle ARNT-like protein 1 (BMAL1) and REV-ERBα in murine muscles. Integrating occupancy with 24-hr gene expression and metabolomics after muscle-specific loss of BMAL1 and REV-ERBα, here we unravel novel molecular mechanisms connecting muscle clock function to daily cycles of lipid and protein metabolism. Validating BMAL1 and REV-ERBα targets using luciferase assays and in vivo rescue, we demonstrate how a major role of the muscle clock is to promote diurnal cycles of neutral lipid storage while coordinately inhibiting lipid and protein catabolism prior to awakening. This occurs by BMAL1-dependent activation of Dgat2 and REV-ERBα-dependent repression of major targets involved in lipid metabolism and protein turnover (MuRF-1, Atrogin-1). Accordingly, muscle-specific loss of BMAL1 is associated with metabolic inefficiency, impaired muscle triglyceride biosynthesis, and accumulation of bioactive lipids and amino acids. Taken together, our data provide a comprehensive overview of how genomic binding of BMAL1 and REV-ERBα is related to temporal changes in gene expression and metabolite fluctuations., Competing Interests: The authors have declared that no competing interests exist.

Published

2018

19. Interplay between gut microbiota and p66Shc affects obesity-associated insulin resistance.

Author

Ciciliot S, Albiero M, Campanaro S, Poncina N, Tedesco S, Scattolini V, Dalla Costa F, Cignarella A, Vettore M, Di Gangi IM, Bogialli S, Avogaro A, and Fadini GP

Subjects

Animals, Diet, High-Fat adverse effects, Female, Gene Deletion, Male, Mice, Mice, Inbred C57BL, Obesity etiology, Obesity genetics, Obesity microbiology, Pancreatitis-Associated Proteins genetics, Pancreatitis-Associated Proteins metabolism, Src Homology 2 Domain-Containing, Transforming Protein 1 metabolism, Gastrointestinal Microbiome, Insulin Resistance, Obesity metabolism, Src Homology 2 Domain-Containing, Transforming Protein 1 genetics

Abstract

The 66 kDa isoform of the mammalian Shc gene promotes adipogenesis, and p66Shc -/- mice accumulate less body weight than wild-type (WT) mice. As the metabolic consequences of the leaner phenotype of p66Shc -/- mice is debated, we hypothesized that gut microbiota may be involved. We confirmed that p66Shc -/- mice gained less weight than WT mice when on a high-fat diet (HFD), but they were not protected from insulin resistance and glucose intolerance. p66Shc deletion significantly modified the composition of gut microbiota and their modification after an HFD. This was associated with changes in gene expression of Il-1b and regenerating islet-derived protein 3 γ ( Reg3g) in the gut and in systemic trimethylamine N-oxide and branched chain amino acid levels, despite there being no difference in intestinal structure and permeability. Depleting gut microbiota at the end of HFD rendered both strains more glucose tolerant but improved insulin sensitivity only in p66Shc -/- mice. Microbiota-depleted WT mice cohoused with microbiota-competent p66Shc -/- mice became significantly more insulin resistant than WT mice cohoused with WT mice, despite no difference in weight gain. These findings reconcile previous inconsistent observations on the metabolic phenotype of p66Shc -/- mice and illustrate the complex microbiome-host-genotype interplay under metabolic stress.-Ciciliot, S., Albiero, M., Campanaro, S., Poncina, N., Tedesco, S., Scattolini, V., Dalla Costa, F., Cignarella, A., Vettore, M., Di Gangi, I. M., Bogialli, S., Avogaro, A., Fadini, G. P. Interplay between gut microbiota and p66Shc affects obesity-associated insulin resistance.

Published

2018

20. Single Muscle Fiber Proteomics Reveals Fiber-Type-Specific Features of Human Muscle Aging.

Author

Murgia M, Toniolo L, Nagaraj N, Ciciliot S, Vindigni V, Schiaffino S, Reggiani C, and Mann M

Subjects

Aging, Humans, Glycogen physiology, Glycolysis physiology, Muscle Fibers, Skeletal metabolism, Proteomics methods

Abstract

Skeletal muscle is a key tissue in human aging, which affects different muscle fiber types unequally. We developed a highly sensitive single muscle fiber proteomics workflow to study human aging and show that the senescence of slow and fast muscle fibers is characterized by diverging metabolic and protein quality control adaptations. Whereas mitochondrial content declines with aging in both fiber types, glycolysis and glycogen metabolism are upregulated in slow but downregulated in fast muscle fibers. Aging mitochondria decrease expression of the redox enzyme monoamine oxidase A. Slow fibers upregulate a subset of actin and myosin chaperones, whereas an opposite change happens in fast fibers. These changes in metabolism and sarcomere quality control may be related to the ability of slow, but not fast, muscle fibers to maintain their mass during aging. We conclude that single muscle fiber analysis by proteomics can elucidate pathophysiology in a sub-type-specific manner., (Copyright © 2017 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2017

21. Age-Associated Loss of OPA1 in Muscle Impacts Muscle Mass, Metabolic Homeostasis, Systemic Inflammation, and Epithelial Senescence.

Author

Tezze C, Romanello V, Desbats MA, Fadini GP, Albiero M, Favaro G, Ciciliot S, Soriano ME, Morbidoni V, Cerqua C, Loefler S, Kern H, Franceschi C, Salvioli S, Conte M, Blaauw B, Zampieri S, Salviati L, Scorrano L, and Sandri M

Subjects

Aging genetics, Aging pathology, Animals, Cellular Senescence genetics, Endoplasmic Reticulum Stress genetics, Fibroblast Growth Factors genetics, Fibroblast Growth Factors metabolism, GTP Phosphohydrolases genetics, Inflammation enzymology, Inflammation genetics, Inflammation pathology, Mice, Muscle, Skeletal pathology, Muscular Atrophy enzymology, Muscular Atrophy genetics, Muscular Atrophy pathology, Organ Size, Unfolded Protein Response genetics, Aging metabolism, GTP Phosphohydrolases metabolism, Muscle, Skeletal enzymology

Abstract

Mitochondrial dysfunction occurs during aging, but its impact on tissue senescence is unknown. Here, we find that sedentary but not active humans display an age-related decline in the mitochondrial protein, optic atrophy 1 (OPA1), that is associated with muscle loss. In adult mice, acute, muscle-specific deletion of Opa1 induces a precocious senescence phenotype and premature death. Conditional and inducible Opa1 deletion alters mitochondrial morphology and function but not DNA content. Mechanistically, the ablation of Opa1 leads to ER stress, which signals via the unfolded protein response (UPR) and FoxOs, inducing a catabolic program of muscle loss and systemic aging. Pharmacological inhibition of ER stress or muscle-specific deletion of FGF21 compensates for the loss of Opa1, restoring a normal metabolic state and preventing muscle atrophy and premature death. Thus, mitochondrial dysfunction in the muscle can trigger a cascade of signaling initiated at the ER that systemically affects general metabolism and aging., (Copyright © 2017 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2017

22. Microgravity-Induced Transcriptome Adaptation in Mouse Paraspinal longissimus dorsi Muscle Highlights Insulin Resistance-Linked Genes.

Author

Gambara G, Salanova M, Ciciliot S, Furlan S, Gutsmann M, Schiffl G, Ungethuem U, Volpe P, Gunga HC, and Blottner D

Abstract

Microgravity as well as chronic muscle disuse are two causes of low back pain originated at least in part from paraspinal muscle deconditioning. At present no study investigated the complexity of the molecular changes in human or mouse paraspinal muscles exposed to microgravity. The aim of this study was to evaluate longissimus dorsi adaptation to microgravity at both morphological and global gene expression level. C57BL/N6 male mice were flown aboard the BION-M1 biosatellite for 30 days (BF) or housed in a replicate flight habitat on ground (BG). Myofiber cross sectional area and myosin heavy chain subtype patterns were respectively not or slightly altered in longissimus dorsi of BF mice. Global gene expression analysis identified 89 transcripts differentially regulated in longissimus dorsi of BF vs. BG mice. Microgravity-induced gene expression changes of lipocalin 2 (Lcn2), sestrin 1(Sesn1), phosphatidylinositol 3-kinase, regulatory subunit polypeptide 1 (p85 alpha) (Pik3r1), v-maf musculoaponeurotic fibrosarcoma oncogene family protein B (Mafb), protein kinase C delta (Prkcd), Muscle Atrophy F-box (MAFbx/Atrogin-1/Fbxo32), and Muscle RING Finger 1 (MuRF-1) were further validated by real time qPCR analysis. In conclusion, our study highlighted the regulation of transcripts mainly linked to insulin sensitivity and metabolism in longissimus dorsi following 30 days of microgravity exposure. The apparent absence of robust signs of back muscle atrophy in space-flown mice, despite the overexpression of Atrogin-1 and MuRF-1, opens new questions on the possible role of microgravity-sensitive genes in the regulation of peripheral insulin resistance following unloading and its consequences on paraspinal skeletal muscle physiology.

Published

2017

23. Regulatory T cells and skeletal muscle regeneration.

Author

Schiaffino S, Pereira MG, Ciciliot S, and Rovere-Querini P

Subjects

Aging, Amphiregulin genetics, Amphiregulin immunology, Animals, Cell Movement, Gene Expression Regulation, Humans, Interleukin-33 genetics, Interleukin-33 immunology, Macrophages immunology, Macrophages pathology, Mice, Mice, Inbred mdx, Muscle Fibers, Skeletal immunology, Muscle Fibers, Skeletal pathology, Muscular Dystrophy, Duchenne genetics, Muscular Dystrophy, Duchenne pathology, Neutrophils immunology, Neutrophils pathology, Satellite Cells, Skeletal Muscle pathology, T-Lymphocytes, Regulatory pathology, Muscular Dystrophy, Duchenne immunology, Regeneration immunology, Satellite Cells, Skeletal Muscle immunology, T-Lymphocytes, Regulatory immunology

Abstract

Skeletal muscle regeneration results from the activation and differentiation of myogenic stem cells, called satellite cells, located beneath the basal lamina of the muscle fibers. Inflammatory and immune cells have a crucial role in the regeneration process. Acute muscle injury causes an immediate transient wave of neutrophils followed by a more persistent infiltration of M1 (proinflammatory) and M2 (anti-inflammatory/proregenerative) macrophages. New studies show that injured muscle is also infiltrated by a specialized population of regulatory T (Treg) cells, which control both the inflammatory response, by promoting the M1-to-M2 switch, and the activation of satellite cells. Treg cells accumulate in injured muscle in response to specific cytokines, such as IL-33, and promote muscle growth by releasing growth factors, such as amphiregulin. Muscle repair during aging is impaired due to reduced number of Treg cells and can be enhanced by IL-33 supplementation. Migration of Treg cells could also contribute to explain the effect of heterochronic parabiosis, whereby muscle regeneration of aged mice can be improved by a parabiotically linked young partners. In mdx dystrophin-deficient mice, a model of human Duchenne muscular dystrophy, muscle injury, and inflammation is mitigated by expansion of the Treg-cell population but exacerbated by Treg-cell depletion. These findings support the notion that immunological mechanisms are not only essential in the response to pathogenic microbes and tumor cells but also have a wider homeostatic role in tissue repair, and open new perspectives for boosting muscle growth in chronic muscle disease and during aging., (© 2016 Federation of European Biochemical Societies.)

Published

2017

24. Gene Expression Profiling in Slow-Type Calf Soleus Muscle of 30 Days Space-Flown Mice.

Author

Gambara G, Salanova M, Ciciliot S, Furlan S, Gutsmann M, Schiffl G, Ungethuem U, Volpe P, Gunga HC, and Blottner D

Subjects

Animals, Gene Expression Profiling, Male, Mice, Mice, Inbred C57BL, Microarray Analysis, Muscular Atrophy etiology, Muscular Atrophy metabolism, Time Factors, Muscle Fibers, Slow-Twitch metabolism, Muscle, Skeletal metabolism, Muscular Atrophy genetics, Space Flight, Weightlessness adverse effects

Abstract

Microgravity exposure as well as chronic disuse are two main causes of skeletal muscle atrophy in animals and humans. The antigravity calf soleus is a reference postural muscle to investigate the mechanism of disuse-induced maladaptation and plasticity of human and rodent (rats or mice) skeletal musculature. Here, we report microgravity-induced global gene expression changes in space-flown mouse skeletal muscle and the identification of yet unknown disuse susceptible transcripts found in soleus (a mainly slow phenotype) but not in extensor digitorum longus (a mainly fast phenotype dorsiflexor as functional counterpart to soleus). Adult C57Bl/N6 male mice (n = 5) flew aboard a biosatellite for 30 days on orbit (BION-M1 mission, 2013), a sex and age-matched cohort were housed in standard vivarium cages (n = 5), or in a replicate flight habitat as ground control (n = 5). Next to disuse atrophy signs (reduced size and myofiber phenotype I to II type shift) as much as 680 differentially expressed genes were found in the space-flown soleus, and only 72 in extensor digitorum longus (only 24 genes in common) compared to ground controls. Altered expression of gene transcripts matched key biological processes (contractile machinery, calcium homeostasis, muscle development, cell metabolism, inflammatory and oxidative stress response). Some transcripts (Fzd9, Casq2, Kcnma1, Ppara, Myf6) were further validated by quantitative real-time PCR (qRT-PCR). Besides previous reports on other leg muscle types we put forth for the first time a complete set of microgravity susceptible gene transcripts in soleus of mice as promising new biomarkers or targets for optimization of physical countermeasures and rehabilitation protocols to overcome disuse atrophy conditions in different clinical settings, rehabilitation and spaceflight., Competing Interests: The authors have declared that no competing interests exist.

Published

2017

25. Concise Review: Perspectives and Clinical Implications of Bone Marrow and Circulating Stem Cell Defects in Diabetes.

Author

Fadini GP, Ciciliot S, and Albiero M

Subjects

Animals, Cell- and Tissue-Based Therapy, Disease Progression, Humans, Bone Marrow Cells pathology, Clinical Trials as Topic, Diabetes Mellitus pathology, Diabetes Mellitus therapy, Stem Cells pathology

Abstract

Diabetes mellitus is a complex systemic disease characterized by severe morbidity and excess mortality. The burden of its multiorgan complications relies on an imbalance between hyperglycemic cell damage and defective endogenous reparative mechanisms. Inflammation and abnormalities in several hematopoietic components are typically found in diabetes. The discovery that diabetes reduces circulating stem/progenitor cells and impairs their function has opened an entire new field of study where diabetology comes into contact with hematology and regenerative medicine. It is being progressively recognized that such rare circulating cell populations mirror finely regulated processes involved in hematopoiesis, immunosurveillance, and peripheral tissue homeostasis. From a clinical perspective, pauperization of circulating stem cells predicts adverse outcomes and death. Furthermore, studies in murine models and humans have identified the bone marrow (BM) as a previously neglected site of diabetic end-organ damage, characterized by microangiopathy, neuropathy, fat deposition, and inflammation. As a result, diabetes impairs the mobilization of BM stem/progenitor cells, a defect known as mobilopathy or myelokathexis, with negative consequences for physiologic hematopoiesis, immune regulation, and tissue regeneration. A better understanding of the molecular and cellular processes that govern the BM stem cell niche, cell mobilization, and kinetics in peripheral tissues may uncover new therapeutic strategies for patients with diabetes. This concise review summarizes the current knowledge on the interplay between the BM, circulating stem cells, and diabetes, and sets the stages for future developments in the field. Stem Cells 2017;35:106-116., (© 2016 AlphaMed Press.)

Published

2017

26. MRF4 negatively regulates adult skeletal muscle growth by repressing MEF2 activity.

Author

Moretti I, Ciciliot S, Dyar KA, Abraham R, Murgia M, Agatea L, Akimoto T, Bicciato S, Forcato M, Pierre P, Uhlenhaut NH, Rigby PW, Carvajal JJ, Blaauw B, Calabria E, and Schiaffino S

Subjects

Active Transport, Cell Nucleus, Animals, Cell Nucleus metabolism, Gene Expression Profiling, Gene Knockdown Techniques, HEK293 Cells, Histone Deacetylases metabolism, Humans, Hypertrophy, Male, Muscle Fibers, Skeletal metabolism, Muscle Fibers, Skeletal pathology, Muscle, Skeletal pathology, Organ Specificity genetics, Protein Binding, Protein Biosynthesis, RNA Interference, RNA, Small Interfering metabolism, Rats, Wistar, Repressor Proteins metabolism, Transcription, Genetic, Up-Regulation genetics, Aging metabolism, MEF2 Transcription Factors metabolism, Muscle, Skeletal growth & development, Muscle, Skeletal metabolism, Myogenic Regulatory Factors metabolism

Abstract

The myogenic regulatory factor MRF4 is highly expressed in adult skeletal muscle but its function is unknown. Here we show that Mrf4 knockdown in adult muscle induces hypertrophy and prevents denervation-induced atrophy. This effect is accompanied by increased protein synthesis and widespread activation of muscle-specific genes, many of which are targets of MEF2 transcription factors. MEF2-dependent genes represent the top-ranking gene set enriched after Mrf4 RNAi and a MEF2 reporter is inhibited by co-transfected MRF4 and activated by Mrf4 RNAi. The Mrf4 RNAi-dependent increase in fibre size is prevented by dominant negative MEF2, while constitutively active MEF2 is able to induce myofibre hypertrophy. The nuclear localization of the MEF2 corepressor HDAC4 is impaired by Mrf4 knockdown, suggesting that MRF4 acts by stabilizing a repressor complex that controls MEF2 activity. These findings open new perspectives in the search for therapeutic targets to prevent muscle wasting, in particular sarcopenia and cachexia.

Published

2016

27. NETosis Delays Diabetic Wound Healing in Mice and Humans.

Author

Fadini GP, Menegazzo L, Rigato M, Scattolini V, Poncina N, Bruttocao A, Ciciliot S, Mammano F, Ciubotaru CD, Brocco E, Marescotti MC, Cappellari R, Arrigoni G, Millioni R, Vigili de Kreutzenberg S, Albiero M, and Avogaro A

Subjects

Aged, Animals, Cells, Cultured, Diabetes Mellitus, Experimental complications, Diabetes Mellitus, Experimental immunology, Diabetes Mellitus, Type 2 complications, Diabetes Mellitus, Type 2 immunology, Diabetic Foot immunology, Diabetic Foot pathology, Diabetic Foot physiopathology, Female, Humans, Leukocyte Elastase metabolism, Male, Mice, Mice, Inbred C57BL, Middle Aged, Neutrophils metabolism, Time Factors, Wound Healing immunology, Diabetes Mellitus, Experimental physiopathology, Diabetes Mellitus, Type 2 physiopathology, Extracellular Traps physiology, Wound Healing physiology

Abstract

Upon activation, neutrophils undergo histone citrullination by protein arginine deiminase (PAD)4, exocytosis of chromatin and enzymes as neutrophil extracellular traps (NETs), and death. In diabetes, neutrophils are primed to release NETs and die by NETosis. Although this process is a defense against infection, NETosis can damage tissue. Therefore, we examined the effect of NETosis on the healing of diabetic foot ulcers (DFUs). Using proteomics, we found that NET components were enriched in nonhealing human DFUs. In an independent validation cohort, a high concentration of neutrophil elastase in the wound was associated with infection and a subsequent worsening of the ulcer. NET components (elastase, histones, neutrophil gelatinase-associated lipocalin, and proteinase-3) were elevated in the blood of patients with DFUs. Circulating elastase and proteinase-3 were associated with infection, and serum elastase predicted delayed healing. Neutrophils isolated from the blood of DFU patients showed an increased spontaneous NETosis but an impaired inducible NETosis. In mice, skin PAD4 activity was increased by diabetes, and FACS detection of histone citrullination, together with intravital microscopy, showed that NETosis occurred in the bed of excisional wounds. PAD4 inhibition by Cl-amidine reduced NETting neutrophils and rescued wound healing in diabetic mice. Cumulatively, these data suggest that NETosis delays DFU healing., (© 2016 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2016

28. p66Shc deletion or deficiency protects from obesity but not metabolic dysfunction in mice and humans.

Author

Ciciliot S, Albiero M, Menegazzo L, Poncina N, Scattolini V, Danesi A, Pagnin E, Marabita M, Blaauw B, Giorgio M, Trinei M, Foletto M, Prevedello L, Nitti D, Avogaro A, and Fadini GP

Subjects

Adipocytes metabolism, Adipose Tissue metabolism, Adiposity genetics, Adult, Aged, Aged, 80 and over, Animals, Apoptosis genetics, Blood Glucose metabolism, Diet, High-Fat, Female, Humans, Insulin metabolism, Male, Mice, Mice, Knockout, Middle Aged, Obesity metabolism, Oxidative Stress genetics, Src Homology 2 Domain-Containing, Transforming Protein 1, Insulin Resistance genetics, Obesity genetics, Shc Signaling Adaptor Proteins genetics

Abstract

Aims/hypothesis: Oxygen radicals generated by p66Shc drive adipogenesis, but contradictory data exist on the role of p66Shc in the development of obesity and the metabolic syndrome. We herein explored the relationships among p66Shc, adipose tissue remodelling and glucose metabolism using mouse models and human adipose tissue samples., Methods: In wild-type (WT), leptin-deficient (ob/ob), p66Shc(-/-) and p66Shc(-/-) ob/ob mice up to 30 weeks of age, we analysed body weight, subcutaneous and visceral adipose tissue histopathology, glucose tolerance and insulin sensitivity, and liver and muscle fat accumulation. A group of mice on a high fat diet (HFD) was also analysed. A parallel study was conducted on adipose tissue collected from patients undergoing elective surgery., Results: We found that p66Shc(-/-) mice were slightly leaner than WT mice, and p66Shc(-/-) ob/ob mice became less obese than ob/ob mice. Despite their lower body weight, p66Shc(-/-) mice accumulated ectopic fat in the liver and muscles, and were glucose intolerant and insulin resistant. Features of adverse adipose tissue remodelling induced by obesity, including adipocyte enlargement, apoptosis, inflammation and perfusion were modestly and transiently improved by p66Shc (also known as Shc1) deletion. After 12 weeks of the HFD, p66Shc(-/-) mice were leaner than but equally glucose intolerant and insulin resistant compared with WT mice. In 77 patients, we found a direct correlation between BMI and p66Shc protein levels. Patients with low p66Shc levels were less obese, but were not protected from other metabolic syndrome features (diabetes, dyslipidaemia and hypertension)., Conclusions/interpretation: In mice and humans, reduced p66Shc levels protect from obesity, but not from ectopic fat accumulation, glucose intolerance and insulin resistance.

Published

2015

29. The calcineurin-NFAT pathway controls activity-dependent circadian gene expression in slow skeletal muscle.

Author

Dyar KA, Ciciliot S, Tagliazucchi GM, Pallafacchina G, Tothova J, Argentini C, Agatea L, Abraham R, Ahdesmäki M, Forcato M, Bicciato S, Schiaffino S, and Blaauw B

Abstract

Objective: Physical activity and circadian rhythms are well-established determinants of human health and disease, but the relationship between muscle activity and the circadian regulation of muscle genes is a relatively new area of research. It is unknown whether muscle activity and muscle clock rhythms are coupled together, nor whether activity rhythms can drive circadian gene expression in skeletal muscle., Methods: We compared the circadian transcriptomes of two mouse hindlimb muscles with vastly different circadian activity patterns, the continuously active slow soleus and the sporadically active fast tibialis anterior, in the presence or absence of a functional skeletal muscle clock (skeletal muscle-specific Bmal1 KO). In addition, we compared the effect of denervation on muscle circadian gene expression., Results: We found that different skeletal muscles exhibit major differences in their circadian transcriptomes, yet core clock gene oscillations were essentially identical in fast and slow muscles. Furthermore, denervation caused relatively minor changes in circadian expression of most core clock genes, yet major differences in expression level, phase and amplitude of many muscle circadian genes., Conclusions: We report that activity controls the oscillation of around 15% of skeletal muscle circadian genes independently of the core muscle clock, and we have identified the Ca(2+)-dependent calcineurin-NFAT pathway as an important mediator of activity-dependent circadian gene expression, showing that circadian locomotor activity rhythms drive circadian rhythms of NFAT nuclear translocation and target gene expression.

Published

2015

30. Bone Marrow Macrophages Contribute to Diabetic Stem Cell Mobilopathy by Producing Oncostatin M.

Author

Albiero M, Poncina N, Ciciliot S, Cappellari R, Menegazzo L, Ferraro F, Bolego C, Cignarella A, Avogaro A, and Fadini GP

Subjects

Adult, Animals, Bone Marrow Cells cytology, Female, Humans, Macrophages cytology, Male, Mice, Middle Aged, Stem Cells cytology, Bone Marrow Cells metabolism, Diabetes Mellitus, Experimental metabolism, Diabetes Mellitus, Type 1 metabolism, Macrophages metabolism, Oncostatin M metabolism, Stem Cells metabolism

Abstract

Diabetes affects bone marrow (BM) structure and impairs mobilization of stem cells (SCs) into peripheral blood (PB). This amplifies multiorgan complications because BMSCs promote vascular repair. Because diabetes skews macrophage phenotypes and BM macrophages (BMMΦ) prevent SC mobilization, we hypothesized that excess BMMΦ contribute to diabetic SC mobilopathy. We show that patients with diabetes have increased M1 macrophages, whereas diabetic mice have increased CD169(+) BMMΦ with SC-retaining activity. Depletion of BMMΦ restored SC mobilization in diabetic mice. We found that CD169 labels M1 macrophages and that conditioned medium (CM) from M1 macrophages, but not from M0 and M2 macrophages, induced chemokine (C-X-C motif) ligand 12 (CXCL12) expression by mesenchymal stem/stromal cells. In silico data mining and in vitro validation identified oncostatin M (OSM) as the soluble mediator contained in M1 CM that induces CXCL12 expression via a mitogen-activated protein kinase kinase-p38-signal transducer and activator of a transcription 3-dependent pathway. In diabetic mice, OSM neutralization prevented CXCL12 induction and improved granulocyte-colony stimulating factor and ischemia-induced mobilization, SC homing to ischemic muscles, and vascular recovery. In patients with diabetes, BM plasma OSM levels were higher and correlated with the BM-to-PB SC ratio. In conclusion, BMMΦ prevent SC mobilization by OSM secretion, and OSM antagonism is a strategy to restore BM function in diabetes, which can translate into protection mediated by BMSCs., (© 2015 by the American Diabetes Association. Readers may use this article as long as the work is properly cited, the use is educational and not for profit, and the work is not altered.)

Published

2015

31. NETosis is induced by high glucose and associated with type 2 diabetes.

Author

Menegazzo L, Ciciliot S, Poncina N, Mazzucato M, Persano M, Bonora B, Albiero M, Vigili de Kreutzenberg S, Avogaro A, and Fadini GP

Subjects

Aged, Case-Control Studies, Female, Glucose toxicity, Humans, Interleukin-6 metabolism, Male, Middle Aged, Neutrophils metabolism, Apoptosis, Diabetes Mellitus, Type 2 metabolism, Diabetes Mellitus, Type 2 physiopathology, Extracellular Traps metabolism, Glucose metabolism, Neutrophils pathology

Abstract

Aims: The role of neutrophils in diabetes and its complications is unclear. Upon challenge with microbes and inflammatory triggers, neutrophils release enzymes and nuclear material, forming neutrophils extracellular traps (NETs) and thereby dying by NETosis. We herein tested NET formation and NETosis products in high glucose and in the setting of type 2 diabetes (T2D)., Methods: NETosis was assessed in vitro in cells exposed to 0, 5, 25 mM glucose and 25 mM mannitol, DMSO and PMA using immunofluorescence staining for elastase, DNA and chromatin. Single-cell morphometric analysis was used to detect enter of elastase in the nucleus and extrusion of nuclear material. Release of NETs was quantified by staining with Hoechst 33342. In 38 T2D and 38 age- and sex-matched non-diabetic individuals, we determined plasma elastase, mono- and oligonucleosomes and double-strand (ds) DNA, as circulating NETosis products., Results: NETosis was accurately reproduced in vitro: high (25 mM) glucose increased NETosis rate and release of NETs compared with 5 mM glucose and 25 mM mannitol. T2D patients showed increased plasma elastase, mono- and oligonucleosomes and dsDNA compared with non-diabetic control individuals. A positive correlation was found between HbA1c and mono- and oligonucleosomes, whereas dsDNA was correlated with the presence of nephropathy and cardiovascular disease. Serum IL-6 concentrations were higher in T2D compared with CTRL and correlated with serum dsDNA levels., Conclusions: High glucose and hyperglycemia increase release of NETs and circulating markers of NETosis, respectively. This finding provides a link among neutrophils, inflammation and tissue damage in diabetes.

Published

2015

32. Erratum to "Muscle insulin sensitivity and glucose metabolism are controlled by the intrinsic muscle clock" [Mol Metab 3 (2014) 29-41].

Author

Dyar KA, Ciciliot S, Wright LE, Biensø RS, Malagoli Tagliazucchi G, Patel VR, Forcato M, Peña-Paz MI, Gudiksen A, Solagna F, Albiero M, Moretti I, Eckel-Mahan KL, Baldi P, Sassone-Corsi P, Rizzuto R, Bicciato S, Pilegaard H, Blaauw B, and Schiaffino S

Abstract

[This corrects the article DOI: 10.1016/j.molmet.2013.10.005.].

Published

2014

33. Vascular smooth muscle cells and monocyte-macrophages accomplice in the accelerated atherosclerosis of insulin resistance states.

Author

Fadini GP and Ciciliot S

Subjects

Animals, Humans, Atherosclerosis metabolism, Insulin Resistance physiology, Macrophages metabolism, Monocytes metabolism, Muscle, Smooth, Vascular metabolism, Myocytes, Smooth Muscle metabolism

Published

2014

34. Diabetes causes bone marrow autonomic neuropathy and impairs stem cell mobilization via dysregulated p66Shc and Sirt1.

Author

Albiero M, Poncina N, Tjwa M, Ciciliot S, Menegazzo L, Ceolotto G, Vigili de Kreutzenberg S, Moura R, Giorgio M, Pelicci P, Avogaro A, and Fadini GP

Subjects

Aged, Animals, Cells, Cultured, Diabetes Mellitus, Experimental physiopathology, Down-Regulation, Female, Humans, Leukocytes, Mononuclear metabolism, Male, Mice, Middle Aged, Src Homology 2 Domain-Containing, Transforming Protein 1, Bone Marrow physiopathology, Diabetic Neuropathies physiopathology, Hematopoietic Stem Cell Mobilization, Shc Signaling Adaptor Proteins metabolism, Sirtuin 1 biosynthesis

Abstract

Diabetes compromises the bone marrow (BM) microenvironment and reduces the number of circulating CD34(+) cells. Diabetic autonomic neuropathy (DAN) may impact the BM, because the sympathetic nervous system is prominently involved in BM stem cell trafficking. We hypothesize that neuropathy of the BM affects stem cell mobilization and vascular recovery after ischemia in patients with diabetes. We report that, in patients, cardiovascular DAN was associated with fewer circulating CD34(+) cells. Experimental diabetes (streptozotocin-induced and ob/ob mice) or chemical sympathectomy in mice resulted in BM autonomic neuropathy, impaired Lin(-)cKit(+)Sca1(+) (LKS) cell and endothelial progenitor cell (EPC; CD34(+)Flk1(+)) mobilization, and vascular recovery after ischemia. DAN increased the expression of the 66-kDa protein from the src homology and collagen homology domain (p66Shc) and reduced the expression of sirtuin 1 (Sirt1) in mice and humans. p66Shc knockout (KO) in diabetic mice prevented DAN in the BM, and rescued defective LKS cell and EPC mobilization. Hematopoietic Sirt1 KO mimicked the diabetic mobilization defect, whereas hematopoietic Sirt1 overexpression in diabetes rescued defective mobilization and vascular repair. Through p66Shc and Sirt1, diabetes and sympathectomy elevated the expression of various adhesion molecules, including CD62L. CD62L KO partially rescued the defective stem/progenitor cell mobilization. In conclusion, autonomic neuropathy in the BM impairs stem cell mobilization in diabetes with dysregulation of the life-span regulators p66Shc and Sirt1.

Published

2014

35. Muscle insulin sensitivity and glucose metabolism are controlled by the intrinsic muscle clock.

Author

Dyar KA, Ciciliot S, Wright LE, Biensø RS, Tagliazucchi GM, Patel VR, Forcato M, Paz MI, Gudiksen A, Solagna F, Albiero M, Moretti I, Eckel-Mahan KL, Baldi P, Sassone-Corsi P, Rizzuto R, Bicciato S, Pilegaard H, Blaauw B, and Schiaffino S

Abstract

Circadian rhythms control metabolism and energy homeostasis, but the role of the skeletal muscle clock has never been explored. We generated conditional and inducible mouse lines with muscle-specific ablation of the core clock gene Bmal1. Skeletal muscles from these mice showed impaired insulin-stimulated glucose uptake with reduced protein levels of GLUT4, the insulin-dependent glucose transporter, and TBC1D1, a Rab-GTPase involved in GLUT4 translocation. Pyruvate dehydrogenase (PDH) activity was also reduced due to altered expression of circadian genes Pdk4 and Pdp1, coding for PDH kinase and phosphatase, respectively. PDH inhibition leads to reduced glucose oxidation and diversion of glycolytic intermediates to alternative metabolic pathways, as revealed by metabolome analysis. The impaired glucose metabolism induced by muscle-specific Bmal1 knockout suggests that a major physiological role of the muscle clock is to prepare for the transition from the rest/fasting phase to the active/feeding phase, when glucose becomes the predominant fuel for skeletal muscle.

Published

2013

36. Muscle type and fiber type specificity in muscle wasting.

Author

Ciciliot S, Rossi AC, Dyar KA, Blaauw B, and Schiaffino S

Subjects

Animals, Humans, Muscle Fibers, Fast-Twitch metabolism, Muscle Fibers, Slow-Twitch metabolism, Muscular Atrophy metabolism, Muscular Dystrophy, Duchenne metabolism, Muscle Fibers, Fast-Twitch pathology, Muscle Fibers, Slow-Twitch pathology, Muscular Atrophy pathology, Muscular Dystrophy, Duchenne pathology

Abstract

Muscle wasting occurs in a variety of conditions, including both genetic diseases, such as muscular dystrophies, and acquired disorders, ranging from muscle disuse to cancer cachexia, from heart failure to aging sarcopenia. In most of these conditions, the loss of muscle tissue is not homogeneous, but involves specific muscle groups, for example Duchenne muscular dystrophy affects most body muscles but spares extraocular muscles, and other dystrophies affect selectively proximal or distal limb muscles. In addition, muscle atrophy can affect specific fiber types, involving predominantly slow type 1 or fast type 2 muscle fibers, and is frequently accompanied by a slow-to-fast or fast-to-slow fiber type shift. For example, muscle disuse, such as spinal cord injury, causes type 1 fiber atrophy with a slow-to-fast fiber type shift, whereas cancer cachexia leads to preferential atrophy of type 2 fibers with a fast-to-slow fiber type shift. The identification of the signaling pathways responsible for the differential response of muscles types and fiber types can lead to a better understanding of the pathogenesis of muscle wasting and to the design of therapeutic interventions appropriate for the specific disorders. This article is part of a Directed Issue entitled: Molecular basis of muscle wasting., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

37. Mechanisms regulating skeletal muscle growth and atrophy.

Author

Schiaffino S, Dyar KA, Ciciliot S, Blaauw B, and Sandri M

Subjects

Animals, Humans, Muscle, Skeletal metabolism, Muscular Atrophy metabolism, Muscle, Skeletal cytology, Muscular Atrophy pathology, Signal Transduction

Abstract

Skeletal muscle mass increases during postnatal development through a process of hypertrophy, i.e. enlargement of individual muscle fibers, and a similar process may be induced in adult skeletal muscle in response to contractile activity, such as strength exercise, and specific hormones, such as androgens and β-adrenergic agonists. Muscle hypertrophy occurs when the overall rates of protein synthesis exceed the rates of protein degradation. Two major signaling pathways control protein synthesis, the IGF1-Akt-mTOR pathway, acting as a positive regulator, and the myostatin-Smad2/3 pathway, acting as a negative regulator, and additional pathways have recently been identified. Proliferation and fusion of satellite cells, leading to an increase in the number of myonuclei, may also contribute to muscle growth during early but not late stages of postnatal development and in some forms of muscle hypertrophy in the adult. Muscle atrophy occurs when protein degradation rates exceed protein synthesis, and may be induced in adult skeletal muscle in a variety of conditions, including starvation, denervation, cancer cachexia, heart failure and aging. Two major protein degradation pathways, the proteasomal and the autophagic-lysosomal pathways, are activated during muscle atrophy and variably contribute to the loss of muscle mass. These pathways involve a variety of atrophy-related genes or atrogenes, which are controlled by specific transcription factors, such as FoxO3, which is negatively regulated by Akt, and NF-κB, which is activated by inflammatory cytokines., (© 2013 The Authors Journal compilation © 2013 FEBS.)

Published

2013

38. Effects of pleiotrophin overexpression on mouse skeletal muscles in normal loading and in actual and simulated microgravity.

Author

Camerino GM, Pierno S, Liantonio A, De Bellis M, Cannone M, Sblendorio V, Conte E, Mele A, Tricarico D, Tavella S, Ruggiu A, Cancedda R, Ohira Y, Danieli-Betto D, Ciciliot S, Germinario E, Sandonà D, Betto R, Camerino DC, and Desaphy JF

Subjects

Animals, Calcium metabolism, Carrier Proteins genetics, Citrate (si)-Synthase genetics, Citrate (si)-Synthase metabolism, Cytokines genetics, Electron Transport Complex IV genetics, Electron Transport Complex IV metabolism, Gene Expression, Hindlimb Suspension, Humans, Ion Channels genetics, Ion Channels metabolism, Mice, Mice, Inbred C57BL, Mice, Transgenic, Muscle Fibers, Skeletal, Muscle Proteins genetics, Muscle Proteins metabolism, Muscle, Skeletal pathology, Muscular Atrophy metabolism, Sarcolemma metabolism, Space Flight, Carrier Proteins metabolism, Cytokines metabolism, Muscle, Skeletal metabolism

Abstract

Pleiotrophin (PTN) is a widespread cytokine involved in bone formation, neurite outgrowth, and angiogenesis. In skeletal muscle, PTN is upregulated during myogenesis, post-synaptic induction, and regeneration after crushing, but little is known regarding its effects on muscle function. Here, we describe the effects of PTN on the slow-twitch soleus and fast-twitch extensor digitorum longus (EDL) muscles in mice over-expressing PTN under the control of a bone promoter. The mice were maintained in normal loading or disuse condition, induced by hindlimb unloading (HU) for 14 days. Effects of exposition to near-zero gravity during a 3-months spaceflight (SF) into the Mice Drawer System are also reported. In normal loading, PTN overexpression had no effect on muscle fiber cross-sectional area, but shifted soleus muscle toward a slower phenotype, as shown by an increased number of oxidative type 1 fibers, and increased gene expression of cytochrome c oxidase subunit IV and citrate synthase. The cytokine increased soleus and EDL capillary-to-fiber ratio. PTN overexpression did not prevent soleus muscle atrophy, slow-to-fast transition, and capillary regression induced by SF and HU. Nevertheless, PTN exerted various effects on sarcolemma ion channel expression/function and resting cytosolic Ca(2+) concentration in soleus and EDL muscles, in normal loading and after HU. In conclusion, the results show very similar effects of HU and SF on mouse soleus muscle, including activation of specific gene programs. The EDL muscle is able to counterbalance this latter, probably by activating compensatory mechanisms. The numerous effects of PTN on muscle gene expression and functional parameters demonstrate the sensitivity of muscle fibers to the cytokine. Although little benefit was found in HU muscle disuse, PTN may emerge useful in various muscle diseases, because it exerts synergetic actions on muscle fibers and vessels, which could enforce oxidative metabolism and ameliorate muscle performance.

Published

2013

39. Myeloid calcifying cells promote atherosclerotic calcification via paracrine activity and allograft inflammatory factor-1 overexpression.

Author

Albiero M, Rattazzi M, Menegazzo L, Boscaro E, Cappellari R, Pagnin E, Bertacco E, Poncina N, Dyar K, Ciciliot S, Iwabuchi K, Millioni R, Arrigoni G, Kraenkel N, Landmesser U, Agostini C, Avogaro A, and Fadini GP

Subjects

Alkaline Phosphatase metabolism, Animals, Apolipoproteins E deficiency, Apolipoproteins E genetics, Atherosclerosis metabolism, Calcinosis metabolism, Calcium metabolism, Cell Communication physiology, Cells, Cultured, Disease Models, Animal, In Vitro Techniques, Mice, Mice, Inbred C57BL, Mice, Knockout, Muscle, Smooth, Vascular metabolism, Muscle, Smooth, Vascular pathology, Muscle, Smooth, Vascular physiopathology, Myeloid Cells pathology, Osteocalcin metabolism, Atherosclerosis physiopathology, Calcinosis physiopathology, Calcium-Binding Proteins metabolism, Microfilament Proteins metabolism, Myeloid Cells physiology, Paracrine Communication physiology, Up-Regulation physiology

Abstract

Several cell types contribute to atherosclerotic calcification. Myeloid calcifying cells (MCCs) are monocytes expressing osteocalcin (OC) and bone alkaline phosphatase (BAP). Herein, we tested whether MCCs promote atherosclerotic calcification in vivo. We show that the murine spleen contains OC(+)BAP(+) cells with a phenotype similar to human MCCs, a high expression of adhesion molecules and CD11b, and capacity to calcify in vitro and in vivo. Injection of GFP(+) OC(+)BAP(+) cells into 8- or 40-week ApoE(-/-) mice led to more extensive calcifications in atherosclerotic areas after 24 or 4 weeks, respectively, compared to control OC(-)BAP(-) cells. Despite that OC(+)BAP(+) cells had a selective transendothelial migration capacity, tracking of the GFP signal revealed that presence of injected cells within atherosclerotic areas was an extremely rare event and so GFP mRNA was undetectable by qPCR of lesion extracts. By converse, injected OC(+)BAP(+) cells persisted in the bloodstream and bone marrow up to 24 weeks, suggesting a paracrine effect. Indeed, OC(+)BAP(+) cell-conditioned medium (CM) promoted calcification by cultured vascular smooth muscle cells (VSMC) more than CM from OC(-)BAP(-) cells. A genomic and proteomic investigation of MCCs identified allograft inflammatory factor (AIF)-1 as a potential candidate of this paracrine activity. AIF-1 stimulated VSMC calcification in vitro and monocyte-specific (CD11b-driven) AIF-1 overexpression in ApoE(-/-) mice increased calcium content in atherosclerotic areas. In conclusion, we show that murine OC(+)BAP(+) cells correspond to human MCCs and promote atherosclerotic calcification in ApoE(-/-) mice, through paracrine activity and modulation of resident cells by AIF-1 overexpression.

Published

2013

40. Adaptation of mouse skeletal muscle to long-term microgravity in the MDS mission.

Author

Sandonà D, Desaphy JF, Camerino GM, Bianchini E, Ciciliot S, Danieli-Betto D, Dobrowolny G, Furlan S, Germinario E, Goto K, Gutsmann M, Kawano F, Nakai N, Ohira T, Ohno Y, Picard A, Salanova M, Schiffl G, Blottner D, Musarò A, Ohira Y, Betto R, Conte D, and Schiaffino S

Subjects

Animals, Down-Regulation, Immunohistochemistry, Insulin-Like Growth Factor I metabolism, Interleukin-6 metabolism, Male, Mice, Mice, Inbred C57BL, Myosin Heavy Chains metabolism, Nitric Oxide Synthase Type I metabolism, Potassium Channels, Calcium-Activated metabolism, Rats, Space Flight, Ubiquitin-Protein Ligases metabolism, Up-Regulation, Adaptation, Physiological, Muscle, Skeletal metabolism, Weightlessness

Abstract

The effect of microgravity on skeletal muscles has so far been examined in rat and mice only after short-term (5-20 day) spaceflights. The mice drawer system (MDS) program, sponsored by Italian Space Agency, for the first time aimed to investigate the consequences of long-term (91 days) exposure to microgravity in mice within the International Space Station. Muscle atrophy was present indistinctly in all fiber types of the slow-twitch soleus muscle, but was only slightly greater than that observed after 20 days of spaceflight. Myosin heavy chain analysis indicated a concomitant slow-to-fast transition of soleus. In addition, spaceflight induced translocation of sarcolemmal nitric oxide synthase-1 (NOS1) into the cytosol in soleus but not in the fast-twitch extensor digitorum longus (EDL) muscle. Most of the sarcolemmal ion channel subunits were up-regulated, more in soleus than EDL, whereas Ca(2+)-activated K(+) channels were down-regulated, consistent with the phenotype transition. Gene expression of the atrophy-related ubiquitin-ligases was up-regulated in both spaceflown soleus and EDL muscles, whereas autophagy genes were in the control range. Muscle-specific IGF-1 and interleukin-6 were down-regulated in soleus but up-regulated in EDL. Also, various stress-related genes were up-regulated in spaceflown EDL, not in soleus. Altogether, these results suggest that EDL muscle may resist to microgravity-induced atrophy by activating compensatory and protective pathways. Our study shows the extended sensitivity of antigravity soleus muscle after prolonged exposition to microgravity, suggests possible mechanisms accounting for the resistance of EDL, and individuates some molecular targets for the development of countermeasures.

Published

2012

41. Regeneration of mammalian skeletal muscle. Basic mechanisms and clinical implications.

Author

Ciciliot S and Schiaffino S

Subjects

Aging pathology, Aging physiology, Animals, Athletic Injuries pathology, Humans, Models, Biological, Muscle, Skeletal innervation, Muscle, Skeletal pathology, Muscular Dystrophies pathology, Athletic Injuries physiopathology, Muscle, Skeletal physiology, Muscular Dystrophies physiopathology, Regeneration physiology

Abstract

Mammalian skeletal muscles can regenerate following injury and this response is mediated by a specific type of stem cell, the satellite cell. We review here the three main phases of muscle regeneration, including i) the initial inflammatory response and the dual role of macrophages as both scavengers involved in the phagocytosis of necrotic debris and promoters of myogenic differentiation, ii) the activation and differentiation of satellite cells and iii) the growth and remodeling of the regenerated muscle tissue. Nerve activity is required to support the growth of regenerated myofibers and the specification of muscle fiber types, in particular the activation of the slow gene program. We discuss the regeneration process in two different settings. Chronic degenerative diseases, such as muscular dystrophies, are characterized by repeated cycles of segmental necrosis and regeneration involving scattered myofibers. In these conditions the regenerative capacity of satellite cells becomes exhausted with time and fibrosis prevails. Acute traumatic injuries, such as strain injuries common in sport medicine, cause the rupture of large myofiber bundles leading to muscle regeneration and formation of scar tissue and new myotendinous junctions at the level of the rupture. Mechanical loading is essential for muscle regeneration, therefore, following initial immobilization to avoid the risk of reruptures, early remobilization is required to induce correct growth and orientation of regenerated myofibers. Finally, we discuss the causes of age-dependent decline in muscle regeneration potential and the possibility of boosting regeneration in aging muscle and in muscular dystrophies.

Published

2010

42. NFAT isoforms control activity-dependent muscle fiber type specification.

Author

Calabria E, Ciciliot S, Moretti I, Garcia M, Picard A, Dyar KA, Pallafacchina G, Tothova J, Schiaffino S, and Murgia M

Subjects

Animals, Cell Line, Cell Nucleus metabolism, Electricity, Gene Silencing, Humans, Myosin Heavy Chains metabolism, Organ Specificity, Protein Isoforms metabolism, Protein Transport, Rats, Rats, Wistar, Regeneration, Transcription, Genetic, Muscle Fibers, Skeletal metabolism, NFATC Transcription Factors metabolism

Abstract

The intracellular signals that convert fast and slow motor neuron activity into muscle fiber type specific transcriptional programs have only been partially defined. The calcium/calmodulin-dependent phosphatase calcineurin (Cn) has been shown to mediate the transcriptional effects of motor neuron activity, but precisely how 4 distinct muscle fiber types are composed and maintained in response to activity is largely unknown. Here, we show that 4 nuclear factor of activated T cell (NFAT) family members act coordinately downstream of Cn in the specification of muscle fiber types. We analyzed the role of NFAT family members in vivo by transient transfection in skeletal muscle using a loss-of-function approach by RNAi. Our results show that, depending on the applied activity pattern, different combinations of NFAT family members translocate to the nucleus contributing to the transcription of fiber type specific genes. We provide evidence that the transcription of slow and fast myosin heavy chain (MyHC) genes uses different combinations of NFAT family members, ranging from MyHC-slow, which uses all 4 NFAT isoforms, to MyHC-2B, which only uses NFATc4. Our data contribute to the elucidation of the mechanisms whereby activity can modulate the phenotype and performance of skeletal muscle.

Published

2009

43. NFAT is a nerve activity sensor in skeletal muscle and controls activity-dependent myosin switching.

Author

McCullagh KJ, Calabria E, Pallafacchina G, Ciciliot S, Serrano AL, Argentini C, Kalhovde JM, Lømo T, and Schiaffino S

Subjects

Animals, Calcineurin genetics, Calcineurin metabolism, DNA-Binding Proteins genetics, Electric Stimulation, Genes, Reporter, In Vitro Techniques, Male, Muscle Fibers, Fast-Twitch cytology, Muscle Fibers, Fast-Twitch physiology, Muscle Fibers, Slow-Twitch cytology, Muscle Fibers, Slow-Twitch physiology, Muscle, Skeletal cytology, Muscle, Skeletal innervation, Myosins genetics, NFATC Transcription Factors, Oligopeptides metabolism, Rats, Rats, Wistar, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Signal Transduction physiology, Transcription Factors genetics, DNA-Binding Proteins metabolism, Gene Expression Regulation, Motor Neurons metabolism, Muscle, Skeletal physiology, Myosins metabolism, Nuclear Proteins, Transcription Factors metabolism

Abstract

Calcineurin (Cn) signaling has been implicated in nerve activity-dependent fiber type specification in skeletal muscle, but the downstream effector pathway has not been established. We have investigated the role of the transcription factor nuclear factor of activated T cells (NFAT), a major target of Cn, by using an in vivo transfection approach in regenerating and adult rat muscles. NFAT transcriptional activity was monitored with two different NFAT-dependent reporters and was found to be higher in slow compared to fast muscles. NFAT activity is decreased by denervation in slow muscles and is increased by electrostimulation of denervated muscles with a tonic low-frequency impulse pattern, mimicking the firing pattern of slow motor neurons, but not with a phasic high-frequency pattern typical of fast motor neurons. To determine the role of NFAT, we transfected regenerating and adult rat muscles with a plasmid coding for VIVIT, a specific peptide inhibitor of Cn-mediated NFAT activation. VIVIT was found to block the expression of slow myosin heavy chain (MyHC-slow) induced by slow motor neuron activity in regenerating slow soleus muscle and to inhibit the expression of MyHC-slow transcripts and the activity of a MyHC-slow promoter in adult soleus. The role of NFAT was confirmed by the finding that a constitutively active NFATc1 mutant stimulates the MyHC-slow, inhibits the fast MyHC-2B promoter in adult fast muscles, and induces MyHC-slow expression in regenerating muscles. These results support the notion that Cn-NFAT signaling acts as a nerve activity sensor in skeletal muscle in vivo and controls nerve activity-dependent myosin switching.

Published

2004