Sodium Butyrate Ameliorates Type 2 Diabetes-Related Sarcopenia Through IL-33-Independent ILC2s/IL-13/STAT3 Signaling Pathway

Purpose Sarcopenia has been described as a new complication of type 2 diabetes mellitus (T2DM). T2DM and sarcopenia impact each other, resulting in a variety of adverse outcomes such as frailty, disability, poor quality of life and increased mortality. Sodium butyrate (NaB) is reported to play a protective role against T2DM. The present study aimed to investigate whether NaB could ameliorate T2DM-related sarcopenia and the underlying mechanisms. Materials and Methods The male db/db mice at 7-weeks were used as T2DM-related sarcopenia animal model with C57BL/6J mice as control. Mice were grouped according to whether they received NaB orally as follows: C57BL/6J+water group, C57BL/6J+NaB group, db/db+water group, and db/db+NaB group. Then, db/db mice receiving NaB orally were administered with inhibitors of group 2 innate lymphocytes (ILC2s), anti-CD90.2 by intraperitoneal injection divided into db/db+NaB+PBS group and db/db+NaB+anti-CD90.2 group. NaB dissolved in water at 150 mM. The skeletal muscle mass was measured by dural X-ray (DXA) test. ILC2s in spleen and skeletal muscle were evaluated by flow cytometry. The expressions of IL-33, IL-13, STAT3, P-STAT3, GATA-3 and peroxisome proliferator-activated receptor gamma coactivator-1 alpha (PGC-1α) were assessed by ELISA or WB. The morphology of skeletal muscle fibers was assessed by immunofluorescence staining. Results The proportion of ILC2s and the expressions of ILC2s markers IL-13 and GATA-3 were all significantly decreased in db/db mice, and these changes were improved by NaB. NaB increased the proportion of slow-twitch fibers in gastrocnemius, thus partially reversing the reduced exercise capacity of db/db mice. The expression of slow-twitch fibers marker PGC-1α induced by NaB was increased via activation of ILC2s/IL-13/STAT3 pathway. On the other way, IL-33 was not necessary for the activation of ILC2s/IL-13/STAT3 pathway. After depletion of ILC2s by anti-CD90.2, the ameliorating effect of NaB on T2DM-related sarcopenia was partially antagonized. Conclusion These results indicated that NaB could ameliorate type 2 diabetes-related sarcopenia by activating IL-33-independent ILC2s/IL-13/STAT3 signaling pathway.

[1]  B. Duncan,et al.  IDF diabetes Atlas: Global, regional and country-level diabetes prevalence estimates for 2021 and projections for 2045 , 2021, Diabetes Research and Clinical Practice.

[2]  Xiao-yu Ma,et al.  Effects of anti-diabetic drugs on sarcopenia: Best treatment options for elderly patients with type 2 diabetes mellitus and sarcopenia , 2021, World journal of clinical cases.

[3]  N. Everaert,et al.  A new paradigm for a new simple chemical: butyrate & immune regulation. , 2021, Food & function.

[4]  V. Tremaroli,et al.  Therapeutic Potential of Butyrate for Treatment of Type 2 Diabetes , 2021, Frontiers in Endocrinology.

[5]  J. Jia,et al.  Butyrate ameliorates skeletal muscle atrophy in diabetic nephropathy by enhancing gut barrier function and FFA2‐mediated PI3K/Akt/mTOR signals , 2021, British journal of pharmacology.

[6]  O. Akbari,et al.  Type 2 Innate Lymphoid Cells: Protectors in Type 2 Diabetes , 2021, Frontiers in Immunology.

[7]  H. Kita,et al.  Roles of innate lymphoid cells (ILCs) in allergic diseases: The 10-year anniversary for ILC2s. , 2021, The Journal of allergy and clinical immunology.

[8]  S. Harper,et al.  A stromal progenitor and ILC2 niche promotes muscle eosinophilia and fibrosis-associated gene expression , 2021, Cell reports.

[9]  Jenq-Lin Yang,et al.  Group 2 innate lymphoid cells contribute to IL-33-mediated alleviation of cardiac fibrosis , 2021, Theranostics.

[10]  G. Riccardi,et al.  A Narrative Review on Sarcopenia in Type 2 Diabetes Mellitus: Prevalence and Associated Factors , 2021, Nutrients.

[11]  L. C. Pomatto,et al.  Sarcopenia – Molecular mechanisms and open questions , 2020, Ageing Research Reviews.

[12]  Ziyuan Guo,et al.  Role and mechanism of action of butyrate in atherosclerotic diseases: a review , 2020, Journal of applied microbiology.

[13]  Kristopher J. Stanya,et al.  Interleukin-13 drives metabolic conditioning of muscle to endurance exercise , 2020, Science.

[14]  E. Moors,et al.  Comparison of drug efficacy in two animal models of type 2 diabetes: A systematic review and meta-analysis. , 2020, European journal of pharmacology.

[15]  D. Scott,et al.  Sarcopenia and diabetes mellitus: evidence for a bi-directional relationship , 2019, European Geriatric Medicine.

[16]  B. de Courten,et al.  Sarcopenia and type 2 diabetes mellitus: a bidirectional relationship , 2019, Diabetes, metabolic syndrome and obesity : targets and therapy.

[17]  René Rizzoli,et al.  Sarcopenia: revised European consensus on definition and diagnosis , 2018, Age and ageing.

[18]  S. Koyasu,et al.  The group 2 innate lymphoid cell (ILC2) regulatory network and its underlying mechanisms , 2018, Immunological reviews.

[19]  C. Lloyd,et al.  Type 2 immunity: Expanding our view , 2018, Science Immunology.

[20]  Chenlin Gao,et al.  Sodium butyrate supplementation ameliorates diabetic inflammation in db/db mice. , 2018, The Journal of endocrinology.

[21]  J. S. Kim,et al.  Sodium butyrate inhibits the NF‐kappa B signaling pathway and histone deacetylation, and attenuates experimental colitis in an IL‐10 independent manner , 2017, International immunopharmacology.

[22]  U. Panzer,et al.  IL-33-Mediated Expansion of Type 2 Innate Lymphoid Cells Protects from Progressive Glomerulosclerosis. , 2017, Journal of the American Society of Nephrology : JASN.

[23]  Y. Duan,et al.  Metabolic control of myofibers: promising therapeutic target for obesity and type 2 diabetes , 2017, Obesity reviews : an official journal of the International Association for the Study of Obesity.

[24]  L. Pirola,et al.  The histone deacetylase inhibitor sodium butyrate improves insulin signalling in palmitate-induced insulin resistance in L6 rat muscle cells through epigenetically-mediated up-regulation of Irs1 , 2017, Molecular and Cellular Endocrinology.

[25]  H. Van Remmen,et al.  Muscle fiber type diversification during exercise and regeneration. , 2016, Free radical biology & medicine.

[26]  A. Bayat,et al.  IL-33-dependent group 2 innate lymphoid cells promote cutaneous wound healing , 2015, The Journal of investigative dermatology.

[27]  Gregory M. Fomovsky,et al.  Transcriptional reversion of cardiac myocyte fate during mammalian cardiac regeneration. , 2014, Circulation research.

[28]  J. Adam,et al.  Patients with type 2 diabetes show a greater decline in muscle mass, muscle strength, and functional capacity with aging. , 2013, Journal of the American Medical Directors Association.

[29]  Rahul C. Deo,et al.  Type 2 Innate Signals Stimulate Fibro/Adipogenic Progenitors to Facilitate Muscle Regeneration , 2013, Cell.

[30]  Kristopher J. Stanya,et al.  Direct control of hepatic glucose production by interleukin-13 in mice. , 2013, The Journal of clinical investigation.

[31]  M. Narici,et al.  Sarcopenia, Dynapenia, and the Impact of Advancing Age on Human Skeletal Muscle Size and Strength; a Quantitative Review , 2012, Front. Physio..

[32]  Jun Min,et al.  Butyrate interferes with the differentiation and function of human monocyte-derived dendritic cells. , 2012, Cellular immunology.

[33]  Carlo Reggiani,et al.  Fiber types in mammalian skeletal muscles. , 2011, Physiological reviews.

[34]  R. Meli,et al.  Potential beneficial effects of butyrate in intestinal and extraintestinal diseases , 2011 .

[35]  W. Cefalu,et al.  Butyrate Improves Insulin Sensitivity and Increases Energy Expenditure in Mice , 2009, Diabetes.

[36]  Michael Schuler,et al.  PGC1α expression is controlled in skeletal muscles by PPARβ, whose ablation results in fiber-type switching, obesity, and type 2 diabetes , 2006 .

[37]  R. Paschke,et al.  Altered fiber distribution and fiber-specific glycolytic and oxidative enzyme activity in skeletal muscle of patients with type 2 diabetes. , 2006, Diabetes care.

[38]  Michael Schuler,et al.  PGC1alpha expression is controlled in skeletal muscles by PPARbeta, whose ablation results in fiber-type switching, obesity, and type 2 diabetes. , 2006, Cell metabolism.

[39]  J. Sharman,et al.  Determinants of exercise capacity in patients with type 2 diabetes. , 2005, Diabetes care.

[40]  Kumar Sharma,et al.  Diabetic kidney disease in the db/db mouse. , 2003, American journal of physiology. Renal physiology.