Fiber-type vulnerability and proteostasis reprogramming in skeletal muscle during pancreatic cancer cachexia
Bowen Xu, Aniket S. Joshi, Meiricris Tomaz da Silva, Silin Liu, Ashok Kumar
Bowen Xu, Aniket S. Joshi, Meiricris Tomaz da Silva, Silin Liu, Ashok Kumar
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Research Article Cell biology Muscle biology

Fiber-type vulnerability and proteostasis reprogramming in skeletal muscle during pancreatic cancer cachexia

Abstract

Cachexia is a debilitating syndrome characterized by progressive skeletal muscle wasting, commonly affecting patients with cancer, particularly those with pancreatic cancer. Despite its clinical significance, the molecular mechanisms underlying cancer cachexia remain poorly understood. In this study, we utilized single-nucleus RNA-seq (snRNA-seq) and bulk RNA-seq, complemented by biochemical and histological analyses, to investigate molecular alterations in the skeletal muscle of the KPC mouse model of pancreatic cancer cachexia. Our findings demonstrated that KPC tumor growth induced myofiber-specific changes in the expression of genes involved in proteolytic pathways, mitochondrial biogenesis, and angiogenesis. Notably, tumor progression enhanced the activity of specific transcription factors that regulate the mTORC1 signaling pathway, along with genes involved in translational initiation and ribosome biogenesis. Skeletal muscle–specific, inducible inhibition of mTORC1 activity further exacerbated muscle loss in tumor-bearing mice, highlighting its protective role in maintaining muscle mass. Additionally, we uncovered new intercellular signaling networks within the skeletal muscle microenvironment during pancreatic cancer–induced cachexia. Our study reveals previously unrecognized molecular mechanisms that regulate skeletal muscle homeostasis, and it identifies potential therapeutic targets for the treatment of pancreatic cancer–associated cachexia.

Authors

Bowen Xu, Aniket S. Joshi, Meiricris Tomaz da Silva, Silin Liu, Ashok Kumar

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Figure 9

Deletion of Raptor exacerbates muscle loss in response to KPC tumor growth.

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Deletion of Raptor exacerbates muscle loss in response to KPC tumor grow...
(AC) Wire hanging time (A), 4-paw grip strength (B), wet muscle weight of tibialis anterior (TA) and quadriceps (QUAD) (C) muscle of control and KPC tumor–bearing Rptorfl/fl and Rptormko mice. (D) Tumor-induced decrease in wet weight of TA and QUAD muscle in Rptorfl/fl and RptormKO mice. (E) Representative images of TA muscle cross-sections after anti-dystrophin and DAPI staining. Scale bar: 50 μm. (FH) Myofiber cross-sectional area (CSA) (F), decrease in average myofiber CSA (G), and myofiber CSA frequency distribution (H) in TA muscle of control and KPC tumor–bearing Rptorfl/fl and RptormKO mice. (I) Representative photomicrographs of TA muscle cross-sections after immunostaining for MyHC isoforms. Scale bar: 50 μm. (J and K) Myofiber CSA (J), and tumor-induced decrease (K) in average myofiber CSA in individual muscle type in TA muscle of Rptorfl/fl and RptormKO mice. n = 3–5 per group. Data are presented as mean ± SEM. *P ≤ 0.05, versus corresponding control mice, #P ≤ 0.05, versus KPC-tumor bearing Rptorfl/fl mice (unpaired Student’s t test or 2-way ANOVA and Tukey’s multiple-comparison test).