The functional consequences of age-related changes in microRNA expression in skeletal muscle

A common characteristic of ageing is disrupted homeostasis between growth and atrophy of skeletal muscle resulting in loss of muscle mass and function, which is associated with sarcopenia. Sarcopenia is related to impaired balance, increased falls and decline in quality of life of older people. Agei...

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Veröffentlicht in:	Biogerontology (Dordrecht) 2016-06, Vol.17 (3), p.641-654
Hauptverfasser:	Soriano-Arroquia, Ana, House, Louise, Tregilgas, Luke, Canty-Laird, Elizabeth, Goljanek-Whysall, Katarzyna
Format:	Artikel
Sprache:	eng
Schlagworte:	Age Aging Aging - metabolism Aging - pathology Animals Atrophy Biomedical and Life Sciences Cell Biology Developmental Biology Enzymes Gene expression Gene Expression Regulation Geriatrics/Gerontology Homeostasis Life Sciences Male Mice Mice, Inbred C57BL MicroRNAs MicroRNAs - metabolism Muscle, Skeletal - metabolism Muscle, Skeletal - pathology Musculoskeletal system Older people Quality of life Research Article Sarcopenia Sarcopenia - metabolism Sarcopenia - pathology
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creator	Soriano-Arroquia, Ana House, Louise Tregilgas, Luke Canty-Laird, Elizabeth Goljanek-Whysall, Katarzyna
description	A common characteristic of ageing is disrupted homeostasis between growth and atrophy of skeletal muscle resulting in loss of muscle mass and function, which is associated with sarcopenia. Sarcopenia is related to impaired balance, increased falls and decline in quality of life of older people. Ageing-related transcriptome and proteome changes in skeletal muscle have been characterised, however the molecular mechanisms underlying sarcopenia are still not fully understood. microRNAs are novel regulators of gene expression known to modulate skeletal muscle development and homeostasis. Expression of numerous microRNAs is disrupted in skeletal muscle with age however, the functional consequences of this are not yet understood. Given that a single microRNA can simultaneously affect multiple signalling pathways, microRNAs are potent modulators of pathophysiological changes occurring during ageing. Here we use microRNA and transcript expression profiling together with microRNA functional assays to show that disrupted microRNA:target interactions play an important role in maintaining muscle homeostasis. We identified miR-181a as a regulator of the sirtuin1 ( Sirt1 ) gene expression in skeletal muscle and show that the expression of miR-181a and its target gene is disrupted in skeletal muscle from old mice. Moreover, we show that miR-181a: Sirt1 interactions regulate myotube size. Our results demonstrate that disrupted microRNA:target interactions are likely related to the pathophysiological changes occurring in skeletal muscle during ageing.
doi_str_mv	10.1007/s10522-016-9638-8
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Sarcopenia is related to impaired balance, increased falls and decline in quality of life of older people. Ageing-related transcriptome and proteome changes in skeletal muscle have been characterised, however the molecular mechanisms underlying sarcopenia are still not fully understood. microRNAs are novel regulators of gene expression known to modulate skeletal muscle development and homeostasis. Expression of numerous microRNAs is disrupted in skeletal muscle with age however, the functional consequences of this are not yet understood. Given that a single microRNA can simultaneously affect multiple signalling pathways, microRNAs are potent modulators of pathophysiological changes occurring during ageing. Here we use microRNA and transcript expression profiling together with microRNA functional assays to show that disrupted microRNA:target interactions play an important role in maintaining muscle homeostasis. We identified miR-181a as a regulator of the sirtuin1 ( Sirt1 ) gene expression in skeletal muscle and show that the expression of miR-181a and its target gene is disrupted in skeletal muscle from old mice. Moreover, we show that miR-181a: Sirt1 interactions regulate myotube size. 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Sarcopenia is related to impaired balance, increased falls and decline in quality of life of older people. Ageing-related transcriptome and proteome changes in skeletal muscle have been characterised, however the molecular mechanisms underlying sarcopenia are still not fully understood. microRNAs are novel regulators of gene expression known to modulate skeletal muscle development and homeostasis. Expression of numerous microRNAs is disrupted in skeletal muscle with age however, the functional consequences of this are not yet understood. Given that a single microRNA can simultaneously affect multiple signalling pathways, microRNAs are potent modulators of pathophysiological changes occurring during ageing. Here we use microRNA and transcript expression profiling together with microRNA functional assays to show that disrupted microRNA:target interactions play an important role in maintaining muscle homeostasis. We identified miR-181a as a regulator of the sirtuin1 ( Sirt1 ) gene expression in skeletal muscle and show that the expression of miR-181a and its target gene is disrupted in skeletal muscle from old mice. Moreover, we show that miR-181a: Sirt1 interactions regulate myotube size. 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We identified miR-181a as a regulator of the sirtuin1 ( Sirt1 ) gene expression in skeletal muscle and show that the expression of miR-181a and its target gene is disrupted in skeletal muscle from old mice. Moreover, we show that miR-181a: Sirt1 interactions regulate myotube size. Our results demonstrate that disrupted microRNA:target interactions are likely related to the pathophysiological changes occurring in skeletal muscle during ageing.</abstract><cop>Dordrecht</cop><pub>Springer Netherlands</pub><pmid>26922183</pmid><doi>10.1007/s10522-016-9638-8</doi><tpages>14</tpages><orcidid>https://orcid.org/0000-0001-8166-8800</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Age Aging Aging - metabolism Aging - pathology Animals Atrophy Biomedical and Life Sciences Cell Biology Developmental Biology Enzymes Gene expression Gene Expression Regulation Geriatrics/Gerontology Homeostasis Life Sciences Male Mice Mice, Inbred C57BL MicroRNAs MicroRNAs - metabolism Muscle, Skeletal - metabolism Muscle, Skeletal - pathology Musculoskeletal system Older people Quality of life Research Article Sarcopenia Sarcopenia - metabolism Sarcopenia - pathology
title	The functional consequences of age-related changes in microRNA expression in skeletal muscle
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