Aberrant repair and fibrosis development in skeletal muscle

The repair process of damaged tissue involves the coordinated activities of several cell types in response to local and systemic signals. Following acute tissue injury, infiltrating inflammatory cells and resident stem cells orchestrate their activities to restore tissue homeostasis. However, during chronic tissue damage, such as in muscular dystrophies, the inflammatory-cell infiltration and fibroblast activation persists, while the reparative capacity of stem cells (satellite cells) is attenuated. Abnormal dystrophic muscle repair and its end stage, fibrosis, represent the final common pathway of virtually all chronic neurodegenerative muscular diseases. As our understanding of the pathogenesis of muscle fibrosis has progressed, it has become evident that the muscle provides a useful model for the regulation of tissue repair by the local microenvironment, showing interplay among muscle-specific stem cells, inflammatory cells, fibroblasts and extracellular matrix components of the mammalian wound-healing response. This article reviews the emerging findings of the mechanisms that underlie normal versus aberrant muscle-tissue repair

Impaired Embryonic Development in Mice Overexpressing the RNA-Binding Protein TIAR

TIA-1-related (TIAR) protein is a shuttling RNA-binding protein involved in several steps of RNA metabolism. While in the nucleus TIAR participates to alternative splicing events, in the cytoplasm TIAR acts as a translational repressor on specific transcripts such as those containing AU-Rich Elements (AREs). Due to its ability to assemble abortive pre-initiation complexes coalescing into cytoplasmic granules called stress granules, TIAR is also involved in the general translational arrest observed in cells exposed to environmental stress. However, the in vivo role of this protein has not been studied so far mainly due to severe embryonic lethality upon tiar invalidation.Journal ArticleResearch Support, Non-U.S. Gov'tSCOPUS: ar.jinfo:eu-repo/semantics/publishe

Contribution à l'étude de la fonction de la protéine TIAR dans l'embryogenèse et la réponse innée

Le TNF-α est une cytokine pro-inflammatoire du système immunitaire qui, lorsque sa production est déréglée, induit de nombreuses pathologies chez l’homme (cachexie, arthrite rhumatoïde, etc.) Outre une régulation transcriptionnelle de cette cytokine, il existe aussi une régulation post-transcriptionnelle permettant un contrôle affiné de sa production. Le laboratoire de Biologie du Gène étudie cette régulation post-transcriptionnelle faisant intervenir une séquence consensus dans l’ARNm appelée séquence AU-riche (ou ARE pour AU-rich element) et les protéines qui y sont impliquées. Généralement, les ARNm porteurs d’ARE codent pour des protéines dont l’expression est transitoire. Ces gènes requièrent un contrôle très précis de leur expression et c’est pourquoi, en plus d’être soumis à de nombreux contrôles transcriptionnels, la traduction et la stabilité de leurs ARNm sont très finement régulées. La réponse immune innée implique de nombreux ARNm de ce type. Jusqu’à présent, la fonction de la protéine TIAR dans la régulation de l’expression du TNF-α n’a pas été complètement élucidée. Outre le TNF-α, la participation à la réponse immune innée de nombreuses protéines encodées par des ARNm porteurs d’ARE pourrait conférer à la protéine TIAR un rôle de régulateur essentiel dans le contrôle de l’inflammation. Nous avons donc générés plusieurs lignées de macrophages RAW 264.7 surexprimant la protéine TIAR entière ou différents mutants de TIAR afin de déterminer, par une analyse globale par puces à ADN, les ARNm cibles de TIAR au cours de la réponse immune. Cette approche nous a permis de démontrer que la protéine TIAR exerce un contrôle sur le métabolisme de l’ARNm du TNF-α et de MKP-1 (MAP kinase phosphatase 1), une phosphatase majeure dans la voie de signalisation de la MAPK p38. Cette voie de signalisation joue un rôle essentiel dans la stabilisation et la traduction de nombreux ARNm porteurs d’ARE encodant des protéines de la réponse inflammatoire. D’autre part, nous avons voulu étudier in vivo la fonction de la protéine TIAR au cours de la réponse immune. Nous avons, dans ce but, généré des souris transgéniques surexprimant l’isoforme courte de la protéine TIAR. Si nous n’avons pas encore pu mesurer les effets d’une surexpression de TIAR sur la réponse inflammatoire chez ces souris, ces individus transgéniques ont révélé qu’une expression anormale de la protéine TIAR induit une létalité importante au cours du développement embryonnaire.Doctorat en Sciencesinfo:eu-repo/semantics/nonPublishe

Genome-wide analysis of TIAR RNA ligands in mouse macrophages before and after LPS stimulation

TIA-1 related protein (TIAR) is a RNA-binding protein involved in several steps of gene expression such as RNA splicing Aznarez et al. (2008) [1] and translation Piecyk et al. (2000) [2]. TIAR contains three RNA recognition motifs (RRMs) allowing its interaction with specific sequences localized in the untranslated regions (UTRs) of several mRNAs. In myeloid cells, TIAR has been shown to bind and regulate the translation and stability of various mRNA-encoding proteins important for the inflammatory response, such as TNFα Piecyk et al. (2000), Gueydan et al. (1999) [2,3], Cox-2 Cok et al. (2003) [4] or IL-8 Suswam et al. (2005) [5]. Here, we generated two macrophage-like RAW 264.7 cell lines expressing either a tagged full-length TIAR protein or a RRM2-truncated mutant unable to bind RNA with high affinity Dember et al. (1996), Kim et al. (2013) . By a combination of RNA-IP and microarray analysis (RIP-chip), we identified mRNAs specifically bound by the full-length protein both in basal conditions and in response to LPS (GSE77577). Keywords: RIP-chip, AU-rich element, TIAR, Translation repression, LP

Understanding the process of fibrosis in duchenne muscular dystrophy

Fibrosis is the aberrant deposition of extracellular matrix (ECM) components during tissue healing leading to loss of its architecture and function. Fibrotic diseases are often associated with chronic pathologies and occur in a large variety of vital organs and tissues, including skeletal muscle. In human muscle, fibrosis is most readily associated with the severe muscle wasting disorder Duchenne muscular dystrophy (DMD), caused by loss of dystrophin gene function. In DMD, skeletal muscle degenerates and is infiltrated by inflammatory cells and the functions of the muscle stem cells (satellite cells) become impeded and fibrogenic cells hyperproliferate and are overactivated, leading to the substitution of skeletal muscle with nonfunctional fibrotic tissue. Here, we review new developments in our understanding of the mechanisms leading to fibrosis in DMD and several recent advances towards reverting it, as potential treatments to attenuate disease progression.The authors thank C. Mann and the members of the Cell Biology Group for their helpful discussions and acknowledge funding from MINECO-Spain (SAF2012-38547, FIS-PS09/01267, FIS-PI13/025, and PLE2009-0124), AFM, E-Rare, Fundació MaratóTV3, Duchenne PP-NL, MDA, and EU-FP7 (Myoage, Optistem, and Endostem). Yacine Kharraz and Patrizia Pessina were supported by postdoctoral fellowships from AF

Macrophage plasticity and the role of inflammation in skeletal muscle repair

Effective repair of damaged tissues and organs requires the coordinated action of several cell types, including infiltrating inflammatory cells and resident cells. Recent findings have uncovered a central role for macrophages in the repair of skeletal muscle after acute damage. If damage persists, as in skeletal muscle pathologies such as Duchenne muscular dystrophy (DMD), macrophage infiltration perpetuates and leads to progressive fibrosis, thus exacerbating disease severity. Here we discuss how dynamic changes in macrophage populations and activation states in the damaged muscle tissue contribute to its efficient regeneration. We describe how ordered changes in macrophage polarization, from M1 to M2 subtypes, can differently affect muscle stem cell (satellite cell) functions. Finally, we also highlight some of the new mechanisms underlying macrophage plasticity and briefly discuss the emerging implications of lymphocytes and other inflammatory cell types in normal versus pathological muscle repair.Funding from MICINN (SAF2009-09782, FIS-PS09/01267, SAF2012-38547, PLE2009-0124, and CIBERNED), AFM, Fundación Marató-TV3, MDA, EU-FP7 (Myoage, Optistem, and Endostem). Y. Kharraz was supported by a postdoctoral fellowship from AF

Macrophage plasticity and the role of inflammation in skeletal muscle repair

Effective repair of damaged tissues and organs requires the coordinated action of several cell types, including infiltrating inflammatory cells and resident cells. Recent findings have uncovered a central role for macrophages in the repair of skeletal muscle after acute damage. If damage persists, as in skeletal muscle pathologies such as Duchenne muscular dystrophy (DMD), macrophage infiltration perpetuates and leads to progressive fibrosis, thus exacerbating disease severity. Here we discuss how dynamic changes in macrophage populations and activation states in the damaged muscle tissue contribute to its efficient regeneration. We describe how ordered changes in macrophage polarization, from M1 to M2 subtypes, can differently affect muscle stem cell (satellite cell) functions. Finally, we also highlight some of the new mechanisms underlying macrophage plasticity and briefly discuss the emerging implications of lymphocytes and other inflammatory cell types in normal versus pathological muscle repair.Funding from MICINN (SAF2009-09782, FIS-PS09/01267, SAF2012-38547, PLE2009-0124, and CIBERNED), AFM, Fundación Marató-TV3, MDA, EU-FP7 (Myoage, Optistem, and Endostem). Y. Kharraz was supported by a postdoctoral fellowship from AF

Fibrogenic cell plasticity blunts tissue regeneration and aggravates muscular dystrophy

Preservation of cell identity is necessary for homeostasis of most adult tissues. This process is challenged every time a tissue undergoes regeneration after stress or injury. In the lethal Duchenne muscular dystrophy (DMD), skeletal muscle regenerative capacity declines gradually as fibrosis increases. Using genetically engineered tracing mice, we demonstrate that, in dystrophic muscle, specialized cells of muscular, endothelial, and hematopoietic origins gain plasticity toward a fibrogenic fate via a TGFβ-mediated pathway. This results in loss of cellular identity and normal function, with deleterious consequences for regeneration. Furthermore, this fibrogenic process involves acquisition of a mesenchymal progenitor multipotent status, illustrating a link between fibrogenesis and gain of progenitor cell functions. As this plasticity also was observed in DMD patients, we propose that mesenchymal transitions impair regeneration and worsen diseases with a fibrotic component.The authors acknowledge funding from the Ministry of Economy and Competitiveness (MINECO)-Spain (SAF2012-38547, PI13/02512, and PLE2009-0124), Association Française Myopathies (AFM), E-Rare, Fundació Marató TV3, Muscular Dystrophy Association (MDA), European Commission Research and Innovation funding EU-FP7 (Myoage, Optistem, and Endostem), and Duchenne PP-NL. P.P. and Y.K. were partly supported by postdoctoral fellowships from AFM