Muscle cell organization and therapy of dominant centronuclear myopathy
Muscle cell organization and therapy of dominant centronuclear myopathy
Strengthening knowledge on fundamental aspects of muscle biology is one central challenge in order to decipher pathomechanisms and identify targets for therapeutic intervention for neuromuscular disorders. This is particularly true for diseases due to mutations in genes encoding proteins with pleiotropic roles such as autosomal dominant centronuclear myopathy (CNM) due to mutation of the ubiquitously expressed Dynamin 2 (DMN2) involved in endocytosis, intracellular membrane trafficking and cytoskeleton regulation. In this context, the objectives of the team are: i) to dissect fundamental mechanisms of muscle cells, relevant to understand the dominant CNM, and beyond, numerous other neuromuscular disorders, and ii) to develop experimental therapies for the dominant CNM and study the adeno-associated virus (AAV) vectors fate in pathological muscles to optimize AAV-mediated therapies for neuromuscular disorders. With these objectives, we are developing several projects:
– Role of the endocytosis machinery in mechanobiology at the costameres in healthy and pathological muscles with a particular focus on its adhesive properties and the interplay with mechanosensitive pathways. We also want to better understand how alternative splicing events of the endocytosis machinery cooperates, upon differentiation, to govern clathrin structural diversity (Stéphane Vassilopoulos).
– Role of mechanical stress in muscle homeostasis and growth under physiological and pathological conditions, with a particular focus on the force-mediated regulation of plasma membrane and nuclear stiffness and deformations, chromatin and histone modifications, and genetic programs in muscle cells. We also want to determine how muscle differentiation impacts nuclear characteristics (Catherine Coirault).
– The cellular and molecular mechanisms involved in ventilation-induced diaphragm dysfunction in particular during aging, and the muscle dysfunction occurring in patients in intensive care unit (Catherine Coirault and Adrien Bouglé).
– By combining genetic modifications, live imaging, biophysics, cellular and animal models, we aim at deciphering the pivotal influence of the nucleo-cytoskeleton connection on cell phenotype and genome organization in particular in the context of muscle formation and cardiomyopathy (Bruno Cadot).
– Preclinical development of the allele-specific silencing therapy for the dominant CNM and other DNM2-linked diseases and first proof of concept of allele-specific therapy for other dominant diseases. In addition, we want to develop pharmacological therapy for the DNM2-linked CNM patients (Delphine Trochet & Marc Bitoun).
– In order to optimize AAV-based therapies, we want to identify cellular factors impacting the efficiency of AAV-mediated transduction in diseased muscles. We are focusing on mechanisms regulating the AAV intracellular trafficking and to improve AAV-mediated therapies in DMD and CNM animal models by pharmacological co-treatments (Sofia Benkhelifa-Ziyyat).
Team members:
- Marc Bitoun. Research Director INSERM, co-team leader
- Stéphane Vassilopoulos. Research Director INSERM, co-team leader
- Catherine Coirault. Research Director INSERM
- Delphine Trochet. Research scientist Association Institut de Myologie
- Sofia Benkhelifa-Ziyyat. Research scientist Association Institut de Myologie
- Bruno Cadot. Research scientist Association Institut de Myologie
- Bernard Prudhon. Research Assistant Association Institut de Myologie
- Lylia Mekzine. Research associate INSERM
- Marion Benoist. PhD Student Sorbonne University. Email:
- Kevin Milliet. Master student.
- Ines Akrouf. PhD Student Sorbonne University. Email :
- Joana Martins. PhD Student Sorbonne University. Email :
- Satish Moparthi. Post doc. Email :
- Marine Dumas. Research Assistant AIM. Email :
Contact:
| Name | Position | ORCID |
|---|
- Christophe Lamaze, Nicolas Tardif, Melissa Dewulf, Stéphane Vassilopoulos, Cédric Blouin. The caveolae dress code: structure and signaling. Current Opinion in Cell Biology, 2017, 47, pp.117-125. ⟨10.1016/j.ceb.2017.02.014⟩. ⟨hal-03843342⟩
- Fiona Brown, Michael Collett, Cedric Tremblay, Gerhard Rank, Pietro de Camilli, et al.. Loss of Dynamin 2 GTPase function results in microcytic anaemia. British Journal of Haematology, 2017, 178 (4), pp.616-628. ⟨10.1111/bjh.14709⟩. ⟨hal-03819824⟩
- Marc Bitoun. Therapy for Dominant Inherited Diseases by Allele-Specific RNA Interference: Successes and Pitfalls. 34th Meeting of the European Section of the International Society for Heart Research, Jul 2017, Hamburg, Germany. ⟨hal-03944482⟩
- Stéphane Vassilopoulos. 3D Metal-replica EM in the 21st century. French Society for Microscopy 15th meeting, Jul 2017, Bordeaux, France. ⟨hal-03944502⟩
- Nadia Elkhatib, Enzo Bresteau, Francesco Baschieri, Alba López Rioja, Guillaume van Niel, et al.. Tubular clathrin/AP-2 lattices pinch collagen fibers to support 3D cell migration. Science, 2017, 356 (6343), ⟨10.1126/science.aal4713⟩. ⟨hal-03832688⟩
- Catherine Coirault. Mechanobiology defects in LMNA-related congenital muscular dystrophy. European Intermediate Filaments Meeting, Jun 2017, Saint-Malo, France. ⟨hal-03946249⟩
- Stéphane Vassilopoulos. Flat clathrin lattices, branched actin and intermediate filaments. European Intermediate Filaments Meeting, Jun 2017, Saint-Malo, France. ⟨hal-03944505⟩
- Daniel J Owens. Nuclear envelope protein lamin AC is a crucial mechanosensory component of human skeletal muscle. Cell Symbosia. Exercise Metabolism, May 2017, Gothenburg, Sweden. ⟨hal-03944551⟩
- Stéphane Vassilopoulos. Tubular Clathrin/AP2 lattices in 3D cell migration. University of Warwick Clathrin Meeting, May 2017, Coventry, United Kingdom. ⟨hal-03946217⟩
- Agathe Franck. Clatrhin plaques and dynamin 2 form mecanotransduction platforms . Clathrin Meeting of the University of Warwick, May 2017, Coventry, United Kingdom. ⟨hal-03944487⟩
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