Common Muscle Strength Genes Identified in Humans for First Time Ever
Common genetic factors that influence muscle strength in humans have been identified for the first time in a study led by researchers from the University of Cambridge and published today in Nature Communications.
The researchers used data on hand grip strength from more than 140,000 participants in the UK Biobank study, combined with 50,000 additional individuals from the UK, Netherlands, Denmark and Australia, to identify sixteen common genetic variants that are associated with muscle strength.
Dan Wright, joint first author on this paper and a PhD student at the Medical Research Council Epidemiology (MRC) Unit at the University of Cambridge, said: “The very large number of individuals participating in UK Biobank provides a powerful resource for identifying genes involved in complex traits such as muscle strength, and helps us understand their underlying biology and its relevance to health.”
Many of these variants were located within or near to genes known to play a role in biological processes highly relevant to muscle function, including the structure and function of muscle fibres, and the communication of the nervous system with muscle cells.
Mutations in some of the genes highlighted are also known to be associated with severe monogenic syndromes – conditions caused by a single genetic mutations – characterised by compromised muscle function. This demonstrates that genetic variation in genes which cause serious muscular conditions may also influence differences in strength in the general population.
Dr Robert Scott, who co-led the study with colleagues from the MRC Epidemiology Unit, said: “While we have long suspected a role for genetics in the variation in muscle strength, these findings give the first insights into some of the specific genetic variants that underpin variation in strength.
“These could be important steps towards identifying new treatments to prevent or treat muscle weakness.”
Hand grip strength has been reported to be associated with many health outcomes, including risk of mortality, cardiovascular disease, and fracture – although it has been unclear whether variation in strength actually causes these outcomes, or simply reflects underlying disease processes.
Using the sixteen genetic variants identified for strength, the researchers were able to investigate the hypothesised causal link between strength and these adverse health outcomes. Their study found no evidence that lower strength causally increases risk of death or cardiovascular disease, but they did find evidence that higher muscular strength reduces risk of fracture, supporting the use of strength training interventions as a strategy to reduce risk of fractures.
Professor Nick Wareham, director of the MRC Epidemiology Unit and a senior author of the study, noted: “This work highlights the importance of muscle strength in the prevention of fractures and the complications which can often follow a fall.”
This article has been republished from materials provided by University of Cambridge. Note: material may have been edited for length and content. For further information, please contact the cited source.
Willems, SM et al. Large-scale GWAS identifies multiple loci for hand grip strength providing biological insights into muscular fitness. Nature Communications; 12 July 2017; DOI: 10.1038/ncomms16015
Freedom of Information Request Reveals Benefits of Blocked MS DrugNews
A drug that is blocked by the EU regulatory system has now been found to improve the quality of life of people with multiple sclerosis (MS), according to a study by Queen Mary University of London (QMUL).READ MORE
Researchers Make Surprising Discovery About How Neurons Talk to Each OtherNews
The new findings, made in fruit flies and mice, challenge the existing dogma about how neurons that release the chemical signal dopamine communicate, and may have important implications for many dopamine-related diseases.READ MORE
Brain Circuit Dedicated to Retrieving Memories Discovered at MITNews
MIT neuroscientists have now shown, for the first time, that recalling a memory requires a “detour” circuit that branches off from the original memory circuit.