Single‐cell RNA‐seq reveals interferon‐induced guanylate‐binding proteins are linked with sarcopenia

Background Sarcopenia is defined as an age‐related progressive loss of muscle mass and/or strength. Although different factors can contribute to this disease, the underlying mechanisms remain unclear. We assessed transcriptional heterogeneity in skeletal muscles from sarcopenic and control mice at s...

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Published in:Journal of cachexia, sarcopenia and muscle sarcopenia and muscle, 2022-12, Vol.13 (6), p.2985-2998
Main Authors: Peng, Zhi, Zhang, Ruoyu, Kuang, Xiaolin, Yu, Chen, Niu, Shiwei, Du, Yongjun, Lu, Di, Li, Shaobo, Teng, Zhaowei, Lu, Sheng
Format: Article
Language:English
Subjects:
Animals
Antibodies
Biopsy
Carrier Proteins - genetics
Carrier Proteins - metabolism
Cross-Sectional Studies
Endothelial cell
Endothelial Cells - metabolism
Gene expression
Genomics
Guanylate‐binding protein
Humans
Interferon
Interferons - genetics
Interferons - metabolism
Medical research
Membranes
Mice
Muscle, Skeletal - pathology
Musculoskeletal system
Original
Proteins
Sarcopenia
Sarcopenia - pathology
Senescence
Single-Cell Gene Expression Analysis
Single‐cell RNA‐seq
Skeletal muscle
Sucrose
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Summary:Background Sarcopenia is defined as an age‐related progressive loss of muscle mass and/or strength. Although different factors can contribute to this disease, the underlying mechanisms remain unclear. We assessed transcriptional heterogeneity in skeletal muscles from sarcopenic and control mice at single‐cell resolution. Methods A mouse model was established to study sarcopenic skeletal muscles. Single‐cell RNA‐seq was performed on tibialis anterior (TA) muscle cells collected from sarcopenic and control mice. A series of bioinformatic analyses were carried out to identify and compare different cell types under different conditions. Immunofluorescence staining and western blotting were used to validate the findings from single‐cell experiments. Tube formation assays were conducted to further evaluate the effects of Gbp2 on endothelial cells during angiogenesis. Results A murine sarcopenia model was successfully established using a senescence‐accelerated mouse strain (SAMP6, n = 5). Sarcopenia phenotype was induced by administration of dexamethasone (20 mg/kg) and reduced physical activity. Senescence‐resistant mice strain (SAMR1) and SAMP6 strain with similar activity but injected with PBS were recruited as two control groups. As signs of sarcopenia, body weight, muscle cell counts and cross‐sectional fibre area were all significantly decreased in sarcopenic mice (P value = 0.004, 0.03 and 0.035, respectively). After quality control, 13 612 TA muscle single‐cell transcriptomes were retained for analysis. Fourteen cell clusters were identified from the profiled cells. Among them, two distinct endothelial subtypes were found to be dominant in the sarcopenia group (42.2% cells) and in the two control groups (59.1% and 47.9% cells), respectively. 191 differentially expressed genes were detected between the two endothelial subtypes. Sarcopenia‐specific endothelial cell subtype exhibited a dramatic increase in the interferon family genes and the interferon‐inducible guanylate‐binding protein (GBP) family gene expressions. For example, Igtp and Gbp2 in sarcopenic endothelial cells were 5.4 and 13.3 times higher than those in the control groups, respectively. We further validated our findings in muscle specimens of sarcopenia patients and observed that GBP2 levels were increased in endothelial cells of a subset of patients (11 of 40 patients, 27.5%), and we identified significantly higher CD31 and GBP2 co‐localization (P value = 0.001128). Finally, we overexpresse
ISSN:2190-5991
2190-6009
2190-6009
DOI:10.1002/jcsm.13091