Gut microbe-derived extracellular vesicles induce insulin resistance, thereby impairing glucose metabolism in skeletal muscle

Choi, Youngwoo; Kwon, Yonghoon; Kim, Dae-Kyum; Jeon, Jinseong; Jang, Su Chul; Wang, Taejun; Ban, Minjee; Kim, Min Hye; Jeon, Seong Gyu; Kim, Min Sun; Choi, Cheol Soo; Jee, Young Koo; Gho, Yong Song; Ryu, Sung Ho; Kim, Yoon Keun

doi:10.1038/srep15878

Cited by 145 publications

(147 citation statements)

References 39 publications

(47 reference statements)

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“…Endotoxin-mediated reductions in glucose tolerance have been similarly shown in humans inoculated with LPS, as evidenced by significant increases in skeletal muscle NF-κβ binding activity and JNK phosphorylation, which synergistically inhibit insulin signaling [36]. These studies and others [30, 37], show that circulating LPS, a prominent component of gut microbiota, induces skeletal muscle inflammation and insulin resistance thereby contributing to the development of metabolic syndrome. While these findings implicate LPS and inflammation as causative agents in the process, inflammation-independent alterations in skeletal muscle metabolism have also been observed.…”

Section: Gut Microbiota and Skeletal Muscle Metabolismmentioning

confidence: 92%

“…Meanwhile, excess nutrient uptake and storage (i.e., obesity) is associated with low microbial diversity and changes in the relative abundance of the major bacterial phyla (Bacteroidetes and Firmicutes) [27–29]. While these findings provide support for microbial regulation of local metabolic function, evidence also suggests that gut microbiota may impact distal metabolic activity in skeletal muscle tissues [23, 30]. …”

Section: Gut Microbiota and Skeletal Muscle Metabolismmentioning

confidence: 99%

“…For example, in response to the gut microbiota-specific metabolite indoxyl sulfate [38], C2C12 myoblasts exhibit an up-regulation of glycolysis and an increase in the activity of the pentose phosphate pathway [39]. Similarly, exposure of myotubes to gut microbial-derived extracellular vesicles induces insulin resistance [30], highlighting the multitude of ways in which gut microbiota may influence the metabolic function of skeletal muscle.…”

Section: Gut Microbiota and Skeletal Muscle Metabolismmentioning

confidence: 99%

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Gut Microbiota Contribute to Age-Related Changes in Skeletal Muscle Size, Composition, and Function: Biological Basis for a Gut-Muscle Axis

2017

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Skeletal muscle is a highly plastic tissue that plays a central role in human health and disease. Aging is associated with a decrease in muscle mass and function (sarcopenia) that is associated with a loss of independence and reduced quality of life. Gut microbiota, the bacteria, archaea, viruses, and eukaryotic microbes residing in the gastrointestinal tract are emerging as a potential contributor to age-associated muscle decline. Specifically, advancing age is characterized by a dysbiosis of gut microbiota that is associated with increased intestinal permeability, facilitating the passage of endotoxin and other microbial products (e.g., indoxyl sulfate) into the circulation. Upon entering the circulation, LPS and other microbial factors promote inflammatory signaling and skeletal muscle changes that are hallmarks of the aging muscle phenotype. This review will summarize existing literature suggesting cross-talk between gut microbiota and skeletal muscle health, with emphasis on the significance of this axis for mediating changes in aging skeletal muscle size, composition, and function.

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Section: Gut Microbiota and Skeletal Muscle Metabolismmentioning

confidence: 92%

Section: Gut Microbiota and Skeletal Muscle Metabolismmentioning

confidence: 99%

Section: Gut Microbiota and Skeletal Muscle Metabolismmentioning

confidence: 99%

See 1 more Smart Citation

Gut Microbiota Contribute to Age-Related Changes in Skeletal Muscle Size, Composition, and Function: Biological Basis for a Gut-Muscle Axis

2017

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“…In addition, the skeletal muscle is a major organ in glucose homeostasis, taking up and storing up to 80% of postprandial glucose via insulin-mediated processes. Gut dysbiosis disrupts the physical and metabolic function in muscles through microbial products such as LPS (29) and gut microbe-derived extracellular vesicles that impair glucose metabolism in skeletal muscle (234). These microbial products leak into the systemic circulation, prompting a proinflammatory response via the release of inflammatory cytokines such as TNF-a and IL-6, culminating in smaller, fat-infiltrated muscles with disrupted insulin signaling pathways and eventually leading to the pathogenesis of metabolic syndrome and sarcopenia (235)(236)(237)(238)(239)(240)(241).…”

Section: Function Of Skeletal Musclementioning

confidence: 99%

The PPAR–microbiota–metabolic organ trilogy to fine‐tune physiology

Visvalingam

Wahli

2019

FASEB j.

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The human gut is colonized by commensal microorganisms, predominately bacteria that have coevolved in symbiosis with their host. The gut microbiota has been extensively studied in recent years, and many important findings on how it can regulate host metabolism have been unraveled. In healthy individuals, feeding timing and type of food can influence not only the composition but also the circadian oscillation of the gut microbiota. Host feeding habits thus influence the type of microbe‐derived metabolites produced and their concentrations throughout the day. These microbe‐derived metabolites influence many aspects of host physiology, including energy metabolism and circadian rhythm. Peroxisome proliferator‐activated receptors (PPARs) are a group of ligand‐activated transcription factors that regulate various metabolic processes such as fatty acid metabolism. Similar to the gut microbiota, PPAR expression in various organs oscillates diurnally, and studies have shown that the gut microbiota can influence PPAR activities in various metabolic organs. For example, short‐chain fatty acids, the most abundant type of metabolites produced by anaerobic fermentation of dietary fibers by the gut microbiota, are PPAR agonists. In this review, we highlight how the gut microbiota can regulate PPARs in key metabolic organs, namely, in the intestines, liver, and muscle. Knowing that the gut microbiota impacts metabolism and is altered in individuals with metabolic diseases might allow treatment of these patients using noninvasive procedures such as gut microbiota manipulation.—Oh, H. Y. P., Visvalingam, V., Wahli, W. The PPAR–microbiota–metabolic organ trilogy to fine‐tune physiology. FASEB J. 33, 9706–9730 (2019). http://www.fasebj.org

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“…Fas/ Fas ligand [48]. Les VE apparaissent donc comme un nouvel acteur dans la communication complexe reliant l'hôte et son microbiote.…”

Section: Production Ve Dans Le Smetunclassified

Vésicules extracellulaires, biomarqueurs et bioeffecteurs du syndrome métabolique

2018

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> Les vésicules extracellulaires (VE) suscitent un intérêt croissant lié à leur capacité à transférer du contenu biologique entre cellules. Les VE, émises dans l'espace extracellulaire, circulent via les différents fluides de l'organisme et modulent localement ou à distance les réponses des cellules avec lesquelles elles ont interagi. Des données cliniques et expérimentales étayent leur rôle dans les maladies liées au syndrome métabolique. Les VE bousculent la vision traditionnelle de la communication intercellulaire et représentent ainsi un mode de communication alternatif et versatile, qui ouvre la porte à de nouveaux concepts et opportunités tant biologiques que thérapeutiques. < intraluminales formées lors de la maturation des corps multivésiculaires (CMV). Elles sont sécrétées dans le milieu extracellulaire après fusion des CMV avec la membrane plasmique [1]. Leur formation implique l'assemblage de quatre complexes ESCRT (endosomal sorting complex required for transport) [1]. La biogenèse exosomale, initiée par l'accumulation de tétraspanines (CD9 et CD63) dans la membrane endosomale, est suivie du recrutement séquentiel d'ESCRT-0 et d'ESCRT-I, qui vont ségréger des cargos transmembranaires ubiquitinylés. Le recrutement du sous-complexe ESCRT-III, via ESCRT-II, induit ensuite la courbure et la fission des vésicules intraluminales (à l'origine des futurs exosomes). Une voie connexe de formation des exosomes implique les protéines syndecans et synténine, mais la participation des ESCRT dans les mécanismes régissant la sortie de ces cargos reste à déterminer. Une formation d'exosomes indépendante du complexe ESCRT a été décrite ; elle fait intervenir une régulation par les tétraspanines (CD9, CD63 ou CD81) et certains lipides (des céramides) [2]. L'adressage à la membrane des exosomes formés dans les CMV et leur sécrétion engagent des protéines de trafic membranaire de la famille des petites protéines G (GTPases), telles que Rab11, Rab35 et Rab27. Alors que Rab11 et Rab35 réguleraient le trafic des vésicules endosomales précoces vers la membrane plasmique, Rab 27 interviendrait plutôt dans l'adressage à la membrane cellulaire des endosomes tardifs (lysosomes) [3]. Les exosomes participent à de nombreuses réponses physiopathologiques. Plusieurs études ont ainsi démontré leur capacité à réguler la

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Gut microbe-derived extracellular vesicles induce insulin resistance, thereby impairing glucose metabolism in skeletal muscle

Cited by 145 publications

References 39 publications

Gut Microbiota Contribute to Age-Related Changes in Skeletal Muscle Size, Composition, and Function: Biological Basis for a Gut-Muscle Axis

Gut Microbiota Contribute to Age-Related Changes in Skeletal Muscle Size, Composition, and Function: Biological Basis for a Gut-Muscle Axis

The PPAR–microbiota–metabolic organ trilogy to fine‐tune physiology

Vésicules extracellulaires, biomarqueurs et bioeffecteurs du syndrome métabolique

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