1. Academic Validation
  2. Muscle stem cells contribute to long-term tissue repletion following surgical sepsis

Muscle stem cells contribute to long-term tissue repletion following surgical sepsis

  • J Cachexia Sarcopenia Muscle. 2023 Mar 8. doi: 10.1002/jcsm.13214.
Rebecca E Schmitt 1 2 3 Aneesha Dasgupta 1 2 3 Paige C Arneson-Wissink 1 Srijani Datta 4 Alexandra M Ducharme 1 Jason D Doles 1 2 3
Affiliations

Affiliations

  • 1 Department of Biochemistry and Molecular Biology, Mayo Clinic, Rochester, MN, USA.
  • 2 Department of Anatomy, Cell Biology, and Physiology, Indiana University School of Medicine, Indianapolis, IN, USA.
  • 3 Indiana Center for Musculoskeletal Health, Indianapolis, IN, USA.
  • 4 Eden Prairie High School, Eden Prairie, MN, USA.
Abstract

Background: Over the past decade, advances in sepsis identification and management have resulted in decreased sepsis mortality. This increase in survivorship has highlighted a new clinical obstacle: chronic critical illness (CCI), for which there are no effective treatment options. Up to half of sepsis survivors suffer from CCI, which can include multi-organ dysfunction, chronic inflammation, muscle wasting, physical and mental disabilities, and enhanced frailty. These symptoms prevent survivors from returning to regular day-to-day activities and are directly associated with poor quality of life.

Methods: Mice were subjected to cecal ligation and puncture (CLP) with daily chronic stress (DCS) as an in vivo model to study sepsis late-effects/sequelae on skeletal muscle components. Longitudinal monitoring was performed via magnetic resonance imaging, skeletal muscle and/or muscle stem cell (MuSCs) assays (e.g., post-necropsy wet muscle weights, minimum Feret diameter measurements, in vitro MuSC proliferation and differentiation, number of regenerating myofibres and numbers of Pax7-positive nuclei per myofibre), post-sepsis whole muscle metabolomics and MuSC isolation and high-content transcriptional profiling.

Results: We report several findings supporting the hypothesis that MuSCs/muscle regeneration are critically involved in post-sepsis muscle recovery. First, we show that genetic ablation of muscle stem cells (MuSCs) impairs post-sepsis muscle recovery (maintenance of 5-8% average lean mass loss compared with controls). Second, we observe impaired MuSCs expansion capacity and morphological defects at 26 days post-sepsis compared with control MuSCs (P < 0.001). Third, when subjected to an experimental muscle injury, sepsis-recovered mice exhibited evidence of impaired muscle regeneration compared with non-septic mice receiving the same muscle injury (CLP/DCS injured mean minimum Feret is 92.1% of control injured, P < 0.01). Fourth, we performed a longitudinal RNA Sequencing study on MuSCs isolated from post-sepsis mice and found clear transcriptional differences in all post-sepsis samples compared with controls. At Day 28, CLP/DCS mice satellite cells have multiple altered metabolic pathways, such as Oxidative Phosphorylation, mitochondrial dysfunction, Sirtuin signalling and oestrogen receptor signalling, compared with controls (P < 0.001).

Conclusions: Our data show that MuSCs and muscle regeneration are required for effective post-sepsis muscle recovery and that sepsis triggers morphological, functional, and transcriptional changes in MuSCs. Moving forward, we strive to leverage a more complete understanding of post-sepsis MuSC/regenerative defects to identify and test novel therapies that promote muscle recovery and improve quality of life in sepsis survivors.

Keywords

muscle regeneration; muscle stem cells; muscle wasting; satellite cells; sepsis; skeletal muscle.

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