Your search keyword '"Boido, Marina"' showing total 7 results

1. A new protein curbs the hypertrophic effect of myostatin inhibition, adding remarkable endurance to motor performance in mice.

Author

Boido, Marina, Butenko, Olena, Filippo, Consuelo, Schellino, Roberta, Vrijbloed, Jan W., Fariello, Ruggero G., and Vercelli, Alessandro

Subjects

*MYONEURAL junction, *CHOLINERGIC receptors, *ACTIVIN receptors, *BODY weight, *MONOCLONAL antibodies, *MUSCLE proteins, *MUSCARINIC acetylcholine receptors

Abstract

Current efforts to improve muscle performance are focused on muscle trophism via inhibition of the myostatin pathway: however they have been unsuccessful in the clinic to date. In this study, a novel protein has been created by combining the soluble activin receptor, a strong myostatin inhibitor, to the C-terminal agrin nLG3 domain (ActR-Fc-nLG3) involved in the development and maintenance of neuromuscular junctions. Both domains are connected via the constant region of an Igg1 monoclonal antibody. Surprisingly, young male mice treated with ActR-Fc-nLG3 showed a remarkably increased endurance in the rotarod test, significantly longer than the single domain compounds ActR-Fc and Fc-nLG3 treated animals. This increase in endurance was accompanied by only a moderate increase in body weights and wet muscle weights of ActR-Fc-nLG3 treated animals and were lower than expected. The myostatin inhibitor ActR-Fc induced, as expected, a highly significant increase in body and muscle weights compared to control animals and ActR-Fc-nLG3 treated animals. Moreover, the prolonged endurance effect was not observed when ActR-Fc and Fc-nLG3 were dosed simultaneously as a mixture and the body and muscle weights of these animals were very similar to ActR-Fc treated animals, indicating that both domains need to be on one molecule. Muscle morphology induced by ActR-Fc-nLG3 did not appear to be changed however, close examination of the neuromuscular junction showed significantly increased acetylcholine receptor surface area for ActR-Fc-nLG3 treated animals compared to controls. This result is consistent with published observations that endurance training in rats increased acetylcholine receptor quantity at neuromuscular junctions and provide evidence that improving nerve-muscle interaction could be an important factor for sustaining long term muscle activity. [ABSTRACT FROM AUTHOR]

Published

2020

2. VGF Protein and Its C-Terminal Derived Peptides in Amyotrophic Lateral Sclerosis: Human and Animal Model Studies.

Author

Brancia, Carla, Noli, Barbara, Boido, Marina, Boi, Andrea, Puddu, Roberta, Borghero, Giuseppe, Marrosu, Francesco, Bongioanni, Paolo, Orrù, Sandro, Manconi, Barbara, D’Amato, Filomena, Messana, Irene, Vincenzoni, Federica, Vercelli, Alessandro, Ferri, Gian-Luca, and Cocco, Cristina

Subjects

AMYOTROPHIC lateral sclerosis, NERVE growth factor, C-terminal residues, GENE expression, MESSENGER RNA, DISEASE progression, IMMUNOHISTOCHEMISTRY, ANIMAL models in research

Abstract

VGF mRNA is widely expressed in areas of the nervous system known to degenerate in Amyotrophic Lateral Sclerosis (ALS), including cerebral cortex, brainstem and spinal cord. Despite certain VGF alterations are reported in animal models, little information is available with respect to the ALS patients. We addressed VGF peptide changes in fibroblast cell cultures and in plasma obtained from ALS patients, in parallel with spinal cord and plasma samples from the G93A-SOD1 mouse model. Antisera specific for the C-terminal end of the human and mouse VGF proteins, respectively, were used in immunohistochemistry and enzyme-linked immunosorbent assay (ELISA), while gel chromatography and HPLC/ESI-MS/MS were used to identify the VGF peptides present. Immunoreactive VGF C-terminus peptides were reduced in both fibroblast and plasma samples from ALS patients in an advanced stage of the disease. In the G93A-SOD1 mice, the same VGF peptides were also decreased in plasma in the late-symptomatic stage, while showing an earlier down-regulation in the spinal cord. In immunohistochemistry, a large number of gray matter structures were VGF C-terminus immunoreactive in control mice (including nerve terminals, axons and a few perikarya identified as motoneurons), with a striking reduction already in the pre-symptomatic stage. Through gel chromatography and spectrometry analysis, we identified one form likely to be the VGF precursor as well as peptides containing the NAPP- sequence in all tissues studied, while in the mice and fibroblasts, we revealed also AQEE- and TLQP- peptides. Taken together, selective VGF fragment depletion may participate in disease onset and/or progression of ALS. [ABSTRACT FROM AUTHOR]

Published

2016

3. Expression of Muscle-Specific MiRNA 206 in the Progression of Disease in a Murine SMA Model.

Author

Valsecchi, Valeria, Boido, Marina, De Amicis, Elena, Piras, Antonio, and Vercelli, Alessandro

Subjects

*DISEASE progression, *MICRORNA, *SPINAL muscular atrophy, *NEUROMUSCULAR diseases, *MOTOR neurons

Abstract

Spinal muscular atrophy (SMA) is a severe neuromuscular disease, the most common in infancy, and the third one among young people under 18 years. The major pathological landmark of SMA is a selective degeneration of lower motor neurons, resulting in progressive skeletal muscle denervation, atrophy, and paralysis. Recently, it has been shown that specific or general changes in the activity of ribonucleoprotein containing micro RNAs (miRNAs) play a role in the development of SMA. Additionally miRNA-206 has been shown to be required for efficient regeneration of neuromuscular synapses after acute nerve injury in an ALS mouse model. Therefore, we correlated the morphology and the architecture of the neuromuscular junctions (NMJs) of quadriceps, a muscle affected in the early stage of the disease, with the expression levels of miRNA-206 in a mouse model of intermediate SMA (SMAII), one of the most frequently used experimental model. Our results showed a decrease in the percentage of type II fibers, an increase in atrophic muscle fibers and a remarkable accumulation of neurofilament (NF) in the pre-synaptic terminal of the NMJs in the quadriceps of SMAII mice. Furthermore, molecular investigation showed a direct link between miRNA-206-HDAC4-FGFBP1, and in particular, a strong up-regulation of this pathway in the late phase of the disease. We propose that miRNA-206 is activated as survival endogenous mechanism, although not sufficient to rescue the integrity of motor neurons. We speculate that early modulation of miRNA-206 expression might delay SMA neurodegenerative pathway and that miRNA-206 could be an innovative, still relatively unexplored, therapeutic target for SMA. [ABSTRACT FROM AUTHOR]

Published

2015

4. Myogenic Potential of Whole Bone Marrow Mesenchymal Stem Cells In Vitro and In Vivo for Usage in Urinary Incontinence.

Author

Gunetti, Monica, Tomasi, Simone, Giammò, Alessandro, Boido, Marina, Rustichelli, Deborah, Mareschi, Katia, Errichiello, Edoardo, Parola, Maurizio, Ferrero, Ivana, Fagioli, Franca, Vercelli, Alessandro, Carone, Roberto, and Câmara, Niels Olsen Saraiva

Subjects

MYOBLASTS, MUSCLE cells, BONE marrow cells, CYTOLOGICAL research, MESENCHYMAL stem cells, MULTIPOTENT stem cells

Abstract

Urinary incontinence, defined as the complaint of any involuntary loss of urine, is a pathological condition, which affects 30% females and 15% males over 60, often following a progressive decrease of rhabdosphincter cells due to increasing age or secondary to damage to the pelvic floor musculature, connective tissue and/or nerves. Recently, stem cell therapy has been proposed as a source for cell replacement and for trophic support to the sphincter. To develop new therapeutic strategies for urinary incontinence, we studied the interaction between mesenchymal stem cells (MSCs) and muscle cells in vitro; thereafter, aiming at a clinical usage, we analyzed the supporting role of MSCs for muscle cells in vitro and in in vivo xenotransplantation. MSCs can express markers of the myogenic cell lineages and give rise, under specific cell culture conditions, to myotube-like structures. Nevertheless, we failed to obtain mixed myotubes both in vitro and in vivo. For in vivo transplantation, we tested a new protocol to collect human MSCs from whole bone marrow, to get larger numbers of cells. MSCs, when transplanted into the pelvic muscles close to the external urethral sphincter, survived for a long time in absence of immunosuppression, and migrated into the muscle among fibers, and towards neuromuscular endplates. Moreover, they showed low levels of cycling cells, and did not infiltrate blood vessels. We never observed formation of cell masses suggestive of tumorigenesis. Those which remained close to the injection site showed an immature phenotype, whereas those in the muscle had more elongated morphologies. Therefore, MSCs are safe and can be easily transplanted without risk of side effects in the pelvic muscles. Further studies are needed to elucidate their integration into muscle fibers, and to promote their muscular transdifferentiation either before or after transplantation. [ABSTRACT FROM AUTHOR]

Published

2012

5. Selective Vulnerability of Spinal and Cortical Motor Neuron Subpopulations in delta7 SMA Mice.

Author

d’Errico, Paolo, Boido, Marina, Piras, Antonio, Valsecchi, Valeria, De Amicis, Elena, Locatelli, Denise, Capra, Silvia, Vagni, Francesco, Vercelli, Alessandro, and Battaglia, Giorgio

Subjects

*TREATMENT of spinal muscular atrophy, *MOTOR neurons, *INFANT mortality, *STEREOLOGY, *LABORATORY mice, *DISEASE progression

Abstract

Loss of the survival motor neuron gene (SMN1) is responsible for spinal muscular atrophy (SMA), the most common inherited cause of infant mortality. Even though the SMA phenotype is traditionally considered as related to spinal motor neuron loss, it remains debated whether the specific targeting of motor neurons could represent the best therapeutic option for the disease. We here investigated, using stereological quantification methods, the spinal cord and cerebral motor cortex of ∆7 SMA mice during development, to verify extent and selectivity of motor neuron loss. We found progressive post-natal loss of spinal motor neurons, already at pre-symptomatic stages, and a higher vulnerability of motor neurons innervating proximal and axial muscles. Larger motor neurons decreased in the course of disease, either for selective loss or specific developmental impairment. We also found a selective reduction of layer V pyramidal neurons associated with layer V gliosis in the cerebral motor cortex. Our data indicate that in the ∆7 SMA model SMN loss is critical for the spinal cord, particularly for specific motor neuron pools. Neuronal loss, however, is not selective for lower motor neurons. These data further suggest that SMA pathogenesis is likely more complex than previously anticipated. The better knowledge of SMA models might be instrumental in shaping better therapeutic options for affected patients. [ABSTRACT FROM AUTHOR]

Published

2013

6. Selective Vulnerability of Spinal and Cortical Motor Neuron Subpopulations in delta7 SMA Mice

Author

Giorgio Battaglia, Marina Boido, Antonio Piras, Francesco Vagni, Denise Locatelli, Paolo d'Errico, Elena De Amicis, Valeria Valsecchi, Silvia Capra, Alessandro Vercelli, D'Errico, Paolo, Boido, Marina, Piras, Antonio, Valsecchi, Valeria, De Amicis, Elena, Locatelli, Denise, Capra, Silvia, Vagni, Francesco, Vercelli, Alessandro, and Battaglia, Giorgio

Subjects

Cholinergic Neuron, lcsh:Medicine, SMN1, Biology, Motor Neuron, Muscular Atrophy, Spinal, Mice, Motor system, medicine, Animals, Gliosis, lcsh:Science, Cerebral Cortex, Mice, Knockout, Motor Neurons, Biochemistry, Genetics and Molecular Biology (all), Multidisciplinary, Animal, Pyramidal Cells, lcsh:R, Motor Cortex, Gliosi, Spinal muscular atrophy, Anatomy, Motor neuron, SMA, medicine.disease, Spinal cord, Survival of Motor Neuron 1 Protein, Cholinergic Neurons, Disease Models, Animal, medicine.anatomical_structure, Agricultural and Biological Sciences (all), nervous system, Spinal Cord, Cerebral cortex, Pyramidal Cell, lcsh:Q, Neuroscience, Motor cortex, Research Article

Abstract

Loss of the survival motor neuron gene (SMN1) is responsible for spinal muscular atrophy (SMA), the most common inherited cause of infant mortality. Even though the SMA phenotype is traditionally considered as related to spinal motor neuron loss, it remains debated whether the specific targeting of motor neurons could represent the best therapeutic option for the disease. We here investigated, using stereological quantification methods, the spinal cord and cerebral motor cortex of ∆7 SMA mice during development, to verify extent and selectivity of motor neuron loss. We found progressive post-natal loss of spinal motor neurons, already at pre-symptomatic stages, and a higher vulnerability of motor neurons innervating proximal and axial muscles. Larger motor neurons decreased in the course of disease, either for selective loss or specific developmental impairment. We also found a selective reduction of layer V pyramidal neurons associated with layer V gliosis in the cerebral motor cortex. Our data indicate that in the ∆7 SMA model SMN loss is critical for the spinal cord, particularly for specific motor neuron pools. Neuronal loss, however, is not selective for lower motor neurons. These data further suggest that SMA pathogenesis is likely more complex than previously anticipated. The better knowledge of SMA models might be instrumental in shaping better therapeutic options for affected patients.

Published

2013

7. Selective vulnerability of spinal and cortical motor neuron subpopulations in delta7 SMA mice.

Author

d'Errico P, Boido M, Piras A, Valsecchi V, De Amicis E, Locatelli D, Capra S, Vagni F, Vercelli A, and Battaglia G

Subjects

Animals, Cerebral Cortex metabolism, Cholinergic Neurons metabolism, Cholinergic Neurons pathology, Disease Models, Animal, Gliosis, Mice, Mice, Knockout, Motor Cortex metabolism, Motor Cortex pathology, Motor Neurons metabolism, Muscular Atrophy, Spinal genetics, Pyramidal Cells metabolism, Pyramidal Cells pathology, Spinal Cord metabolism, Survival of Motor Neuron 1 Protein genetics, Cerebral Cortex pathology, Motor Neurons pathology, Muscular Atrophy, Spinal pathology, Spinal Cord pathology

Abstract

Loss of the survival motor neuron gene (SMN1) is responsible for spinal muscular atrophy (SMA), the most common inherited cause of infant mortality. Even though the SMA phenotype is traditionally considered as related to spinal motor neuron loss, it remains debated whether the specific targeting of motor neurons could represent the best therapeutic option for the disease. We here investigated, using stereological quantification methods, the spinal cord and cerebral motor cortex of ∆7 SMA mice during development, to verify extent and selectivity of motor neuron loss. We found progressive post-natal loss of spinal motor neurons, already at pre-symptomatic stages, and a higher vulnerability of motor neurons innervating proximal and axial muscles. Larger motor neurons decreased in the course of disease, either for selective loss or specific developmental impairment. We also found a selective reduction of layer V pyramidal neurons associated with layer V gliosis in the cerebral motor cortex. Our data indicate that in the ∆7 SMA model SMN loss is critical for the spinal cord, particularly for specific motor neuron pools. Neuronal loss, however, is not selective for lower motor neurons. These data further suggest that SMA pathogenesis is likely more complex than previously anticipated. The better knowledge of SMA models might be instrumental in shaping better therapeutic options for affected patients.

Published

2013