Journal of Cachexia, Sarcopenia and Muscle (Apr 2023)

Gene polymorphisms associated with heterogeneity and senescence characteristics of sarcopenia in chronic obstructive pulmonary disease

  • Amy H. Attaway,
  • Annette Bellar,
  • Nicole Welch,
  • Jinendiran Sekar,
  • Avinash Kumar,
  • Saurabh Mishra,
  • Umur Hatipoğlu,
  • Merry‐Lynn McDonald,
  • Elizabeth A. Regan,
  • Jonathan D. Smith,
  • George Washko,
  • Raúl San José Estépar,
  • Peter Bazeley,
  • Joe Zein,
  • Srinivasan Dasarathy

DOI
https://doi.org/10.1002/jcsm.13198
Journal volume & issue
Vol. 14, no. 2
pp. 1083 – 1095

Abstract

Read online

Abstract Background Sarcopenia, or loss of skeletal muscle mass and decreased contractile strength, contributes to morbidity and mortality in patients with chronic obstructive pulmonary disease (COPD). The severity of sarcopenia in COPD is variable, and there are limited data to explain phenotype heterogeneity. Others have shown that COPD patients with sarcopenia have several hallmarks of cellular senescence, a potential mechanism of primary (age‐related) sarcopenia. We tested if genetic contributors explain the variability in sarcopenic phenotype and accelerated senescence in COPD. Methods To identify gene variants [single nucleotide polymorphisms (SNPs)] associated with sarcopenia in COPD, we performed a genome‐wide association study (GWAS) of fat free mass index (FFMI) in 32 426 non‐Hispanic White (NHW) UK Biobank participants with COPD. Several SNPs within the fat mass and obesity‐associated (FTO) gene were associated with sarcopenia that were validated in an independent COPDGene cohort (n = 3656). Leucocyte telomere length quantified in the UK Biobank cohort was used as a marker of senescence. Experimental validation was done by genetic depletion of FTO in murine skeletal myotubes exposed to prolonged intermittent hypoxia or chronic hypoxia because hypoxia contributes to sarcopenia in COPD. Molecular biomarkers for senescence were also quantified with FTO depletion in murine myotubes. Results Multiple SNPs located in the FTO gene were associated with sarcopenia in addition to novel SNPs both within and in proximity to the gene AC090771.2, which transcribes long non‐coding RNA (lncRNA). To replicate our findings, we performed a GWAS of FFMI in NHW subjects from COPDGene. The SNP most significantly associated with FFMI was on chromosome (chr) 16, rs1558902A > T in the FTO gene (β = 0.151, SE = 0.021, P = 1.40 × 10−12 for UK Biobank |β= 0.220, SE = 0.041, P = 9.99 × 10−8 for COPDGene) and chr 18 SNP rs11664369C > T nearest to the AC090771.2 gene (β = 0.129, SE = 0.024, P = 4.64 × 10−8 for UK Biobank |β = 0.203, SE = 0.045, P = 6.38 × 10−6 for COPDGene). Lower handgrip strength, a measure of muscle strength, but not FFMI was associated with reduced telomere length in the UK Biobank. Experimentally, in vitro knockdown of FTO lowered myotube diameter and induced a senescence‐associated molecular phenotype, which was worsened by prolonged intermittent hypoxia and chronic hypoxia. Conclusions Genetic polymorphisms of FTO and AC090771.2 were associated with sarcopenia in COPD in independent cohorts. Knockdown of FTO in murine myotubes caused a molecular phenotype consistent with senescence that was exacerbated by hypoxia, a common condition in COPD. Genetic variation may interact with hypoxia and contribute to variable severity of sarcopenia and skeletal muscle molecular senescence phenotype in COPD.

Keywords