Abstract
Skeletal muscle dysfunction is a frequent extra-pulmonary manifestation of Chronic Obstructive Pulmonary Disease (COPD) with implications for both quality of life and survival. The underlying biology nevertheless remains poorly understood. We measured global gene transcription in the quadriceps using Affymetrix HuGene1.1ST arrays in an unselected cohort of 79 stable COPD patients in secondary care and 16 healthy age- and gender-matched controls. We detected 1,826 transcripts showing COPD-related variation. Eighteen exhibited ≥2fold changes (SLC22A3, FAM184B, CDKN1A, FST, LINC01405, MUSK, PANX1, ANKRD1, C12orf75, MYH1, POSTN, FRZB, TNC, ACTC1, LINC00310, MYH3, MYBPH and AREG). Thirty-one transcripts possessed previous reported evidence of involvement in COPD through genome-wide association, including FAM13A. Network analysis revealed a substructure comprising 6 modules of co-expressed genes. We identified modules with mitochondrial and extracellular matrix features, of which IDH2, a central component of the mitochondrial antioxidant pathway, and ABI3BP, a proposed switch between proliferation and differentiation, represent hubs respectively. COPD is accompanied by coordinated patterns of transcription in the quadriceps involving the mitochondria and extracellular matrix and including genes previously implicated in primary disease processes.
Highlights
Chronic Obstructive Pulmonary Disease (COPD) is a systemic disease in which extra-pulmonary manifestations contribute significantly to the morbidity and mortality of patients
In the current study we set out to catalogue transcriptional perturbations that accompany COPD in the quadriceps, and place changes observed within a systems-level context
We have identified 6 modules of tightly co-expressed genes that differentially associate with parameters of disease and show contrasting patterns of enrichment for cellular localisation and disease-gene associations
Summary
Chronic Obstructive Pulmonary Disease (COPD) is a systemic disease in which extra-pulmonary manifestations contribute significantly to the morbidity and mortality of patients. These included genes participating in a diverse range of processes comprising satellite cell regeneration (FST, CDKN1A, and AREG) and differentiation, including Wnt signalling (FST, FRZB, and C12orf75), neuromuscular transmission (MUSK), energy metabolism (FST and C12orf75), stress response and inflammation (ANKRD1, POSTN, TNC and AREG) and muscle structure/composition (MYH1, ACTC1, MYH3 and MYBPH).
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