Nelsa L. Estrella scite author profile

SUMMARYUnderstanding the molecular mechanisms of skeletal muscle regeneration is crucial to exploiting this pathway for use in tissue repair. Our data demonstrate that the MEF2A transcription factor plays an essential role in skeletal muscle regeneration in adult mice. Injured Mef2a knockout mice display widespread necrosis and impaired myofiber formation. MEF2A controls this process through its direct regulation of the largest known mammalian microRNA (miRNA) cluster, the Gtl2-Dio3 locus. A subset of the Gtl2-Dio3 miRNAs represses secreted Frizzled-related proteins (sFRPs), inhibitors of WNT signaling. Consistent with these data, Gtl2-Dio3-encoded miRNAs are downregulated in regenerating Mef2a knockout muscle, resulting in upregulated sFRP expression and attenuated WNT activity. Furthermore, myogenic differentiation in Mef2a-deficient myoblasts is rescued by overexpression of miR-410 and miR-433, two miRNAs in the Gtl2-Dio3 locus that repress sFRP2, or by treatment with recombinant WNT3A and WNT5A. Thus, miRNA-mediated modulation of WNT signaling by MEF2A is a requisite step for proper muscle regeneration, and represents an attractive pathway for enhancing regeneration of diseased muscle.

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Perceptual variation in umami taste and polymorphisms in TAS1R taste receptor genes

Chen

Alarcon

Tharp

et al. 2009

The American Journal of Clinical Nutrition

118

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MEF2 Transcription Factors Regulate Distinct Gene Programs in Mammalian Skeletal Muscle Differentiation

Estrella

Desjardins

Nocco

et al. 2015

Journal of Biological Chemistry

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Background: Myocyte enhancer factor 2 (MEF2) proteins are essential for skeletal muscle development and regeneration, but their diverse roles in differentiation have not been defined. Results: Individual MEF2 proteins regulate distinct gene programs in skeletal muscle. Conclusion: Certain genes are preferentially sensitive to a specific MEF2 isoform. Significance: These findings provide opportunities to modulate MEF2 isoform-sensitive genes in skeletal muscle health and disease.

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Transcriptional networks regulating the costamere, sarcomere, and other cytoskeletal structures in striated muscle

Estrella

Naya

2013

Cell. Mol. Life Sci.

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Structural abnormalities in striated muscle have been observed in numerous transcription factor gain- and loss-of-function phenotypes in animal and cell culture model systems, indicating that transcription is important in regulating the cytoarchitecture. While most characterized cytoarchitectural defects are largely indistinguishable by histological and ultrastructural criteria, analysis of dysregulated gene expression in each mutant phenotype has yielded valuable information regarding specific structural gene programs that may be uniquely controlled by each of these transcription factors. Linking the formation and maintenance of each subcellular structure or subset of proteins within a cytoskeletal compartment to an overlapping but distinct transcription factor cohort may enable striated muscle to control cytoarchitectural function in an efficient and specific manner. Here we summarize available evidence that connects transcription factors, those with established roles in striated muscle such as MEF2 and SRF as well as other non-muscle transcription factors, to the regulation of a defined cytoskeletal structure. The notion that genes encoding proteins localized to the same subcellular compartment are coordinately transcriptionally regulated may prompt rationally designed approaches that target specific transcription factor pathways to correct structural defects in muscle disease.

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MEF2D Deficiency in Neonatal Cardiomyocytes Triggers Cell Cycle Re-entry and Programmed Cell Death in Vitro

Estrella

Clark

Desjardins

et al. 2015

Journal of Biological Chemistry

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Background: Myocyte enhancer factor 2 (MEF2) proteins are key regulators of cardiac muscle differentiation and hypertrophy, but additional roles in this cell type have not been defined. Results: MEF2D regulates the cell cycle and survival of post-mitotic cardiomyocytes. Conclusion: MEF2D is required for proper neonatal cardiomyocyte homeostasis. Significance: These findings provide opportunities to modulate MEF2D activity in cardiomyocyte proliferation and survival.

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Nelsa L. Estrella

MEF2A regulates the Gtl2-Dio3 microRNA mega-cluster to modulate WNT signaling in skeletal muscle regeneration

Perceptual variation in umami taste and polymorphisms in TAS1R taste receptor genes

MEF2 Transcription Factors Regulate Distinct Gene Programs in Mammalian Skeletal Muscle Differentiation

Transcriptional networks regulating the costamere, sarcomere, and other cytoskeletal structures in striated muscle

MEF2D Deficiency in Neonatal Cardiomyocytes Triggers Cell Cycle Re-entry and Programmed Cell Death in Vitro

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