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Literature DB >> 26526994

Age-Associated Methylation Suppresses SPRY1, Leading to a Failure of Re-quiescence and Loss of the Reserve Stem Cell Pool in Elderly Muscle.

Anne Bigot¹, William J Duddy¹, Zamalou G Ouandaogo¹, Elisa Negroni¹, Virginie Mariot¹, Svetlana Ghimbovschi², Brennan Harmon², Aurore Wielgosik¹, Camille Loiseau³, Joe Devaney², Julie Dumonceaux¹, Gillian Butler-Browne¹, Vincent Mouly⁴, Stéphanie Duguez⁵.

Abstract

The molecular mechanisms by which aging affects stem cell number and function are poorly understood. Murine data have implicated cellular senescence in the loss of muscle stem cells with aging. Here, using human cells and by carrying out experiments within a strictly pre-senescent division count, we demonstrate an impaired capacity for stem cell self-renewal in elderly muscle. We link aging to an increased methylation of the SPRY1 gene, a known regulator of muscle stem cell quiescence. Replenishment of the reserve cell pool was modulated experimentally by demethylation or siRNA knockdown of SPRY1. We propose that suppression of SPRY1 by age-associated methylation in humans inhibits the replenishment of the muscle stem cell pool, contributing to a decreased regenerative response in old age. We further show that aging does not affect muscle stem cell senescence in humans.

Entities: Gene Species

Keywords: DNA methylation; aging; human muscle stem cell; myoblast; quiescence; sprouty1

Mesh：

Substances：

Year: 2015 PMID： 26526994 DOI： 10.1016/j.celrep.2015.09.067

Source DB: PubMed Journal: Cell Rep Impact factor: 9.423

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Cited

47 in total

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6. CDK6 coordinates JAK2 ^V617F mutant MPN via NF-κB and apoptotic networks.

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Age-Associated Methylation Suppresses SPRY1, Leading to a Failure of Re-quiescence and Loss of the Reserve Stem Cell Pool in Elderly Muscle.

Review 1. DNA damage in aging, the stem cell perspective.

Review 2. Epigenetic regulation of muscle development.

3. Motor unit number and transmission stability in octogenarian world class athletes: Can age-related deficits be outrun?

Review 4. Cellular Mechanisms and Regulation of Quiescence.

5. Isolation of Human Myoblasts, Assessment of Myogenic Differentiation, and Store-operated Calcium Entry Measurement.

6. CDK6 coordinates JAK2 ^V617F mutant MPN via NF-κB and apoptotic networks.

7. In vivo analysis of γH2AX+ cells in skeletal muscle from aged and obese humans.

Review 8. Tissue Stem Cells: Architects of Their Niches.

Review 9. NAD⁺ centric mechanisms and molecular determinants of skeletal muscle disease and aging.

Review 10. Sarcopenia: What Is the Origin of This Aging-Induced Disorder?

Age-Associated Methylation Suppresses SPRY1, Leading to a Failure of Re-quiescence and Loss of the Reserve Stem Cell Pool in Elderly Muscle.

Review 1. DNA damage in aging, the stem cell perspective.

Review 2. Epigenetic regulation of muscle development.

3. Motor unit number and transmission stability in octogenarian world class athletes: Can age-related deficits be outrun?

Review 4. Cellular Mechanisms and Regulation of Quiescence.

5. Isolation of Human Myoblasts, Assessment of Myogenic Differentiation, and Store-operated Calcium Entry Measurement.

6. CDK6 coordinates JAK2 V617F mutant MPN via NF-κB and apoptotic networks.

7. In vivo analysis of γH2AX+ cells in skeletal muscle from aged and obese humans.

Review 8. Tissue Stem Cells: Architects of Their Niches.

Review 9. NAD+ centric mechanisms and molecular determinants of skeletal muscle disease and aging.

Review 10. Sarcopenia: What Is the Origin of This Aging-Induced Disorder?

6. CDK6 coordinates JAK2 ^V617F mutant MPN via NF-κB and apoptotic networks.

Review 9. NAD⁺ centric mechanisms and molecular determinants of skeletal muscle disease and aging.