Background Skeletal muscle atrophy is defined as a reduction of muscle mass caused by excessive protein degradation. However, the development of therapeutic interventions is still in an early stage. Although glucagon‐like peptide‐1 receptor (GLP‐1R) agonists, such as exendin‐4 (Ex‐4) and dulaglutide, are widely used for the treatment of diabetes, their effects on muscle pathology are unknown. In this study, we investigated the therapeutic potential of GLP‐1R agonist for muscle wasting and the mechanisms involved. Methods Mouse C2C12 myotubes were used to evaluate the in vitro effects of Ex‐4 in the presence or absence of dexamethasone (Dex) on the regulation of the expression of muscle atrophic factors and the underlying mechanisms using various pharmacological inhibitors. In addition, we investigated the in vivo therapeutic effect of Ex‐4 in a Dex‐induced mouse muscle atrophy model (20 mg/kg/day i.p.) followed by injection of Ex‐4 (100 ng/day i.p.) for 12 days and chronic kidney disease (CKD)‐induced muscle atrophy model. Furthermore, we evaluated the effect of a long‐acting GLP‐1R agonist by treatment of dulaglutide (1 mg/kg/week s.c.) for 3 weeks, in DBA/2J‐mdx mice, a Duchenne muscular dystrophy model. Results Ex‐4 suppressed the expression of myostatin (MSTN) and muscle atrophic factors such as F‐box only protein 32 (atrogin‐1) and muscle RING‐finger protein‐1 (MuRF‐1) in Dex‐treated C2C12 myotubes. The suppression effect was via protein kinase A and protein kinase B signalling pathways through GLP‐1R. In addition, Ex‐4 treatment inhibited glucocorticoid receptor (GR) translocation by up‐regulating the proteins of GR inhibitory complexes. In a Dex‐induced muscle atrophy model, Ex‐4 ameliorated muscle atrophy by suppressing muscle atrophic factors and enhancing myogenic factors (MyoG and MyoD), leading to increased muscle mass and function. In the CKD muscle atrophy model, Ex‐4 also increased muscle mass, myofiber size, and muscle function. In addition, treatment with a long‐acting GLP‐1R agonist, dulaglutide, recovered muscle mass and function in DBA/2J‐mdx mice. Conclusions GLP‐1R agonists ameliorate muscle wasting by suppressing MSTN and muscle atrophic factors and enhancing myogenic factors through GLP‐1R‐mediated signalling pathways. These novel findings suggest that activating GLP‐1R signalling may be useful for the treatment of atrophy‐related muscular diseases.
Outer membrane vesicles (OMVs) are produced by various pathogenic Gram-negative bacteria such as Escherichia coli, Pseudomonas aeruginosa, and Acinetobacter baumannii. In this study, we isolated OMVs from a representative soil bacterium, Pseudomonas putida KT2440, which has a biodegradative activity toward various aromatic compounds. Proteomic analysis identified the outer membrane proteins (OMPs) OprC, OprD, OprE, OprF, OprH, OprG, and OprW as major components of the OMV of P. putida KT2440. The production of OMVs was dependent on the nutrient availability in the culture media, and the up- or down-regulation of specific OMPs was observed according to the culture conditions. In particular, porins (e.g., benzoate-specific porin, BenF-like porin) and enzymes (e.g., catechol 1,2-dioxygenase, benzoate dioxygenase) for benzoate degradation were uniquely found in OMVs prepared from P. putida KT2440 that were cultured in media containing benzoate as the energy source. OMVs of P. putida KT2440 showed low pathological activity toward cultured cells that originated from human lung cells, which suggests their potential as adjuvants or OMV vaccine carriers. Our results suggest that the protein composition of the OMVs of P. putida KT2440 reflects the characteristics of the total proteome of P. putida KT2440.
The factors that control fat deposition in adipose tissues are poorly understood. It is known that visceral adipose tissues display a range of biochemical properties that distinguish them from adipose tissues of subcutaneous origin. However, we have little information on gene expression, either in relation to fat deposition or on interspecies variation in fat deposition. The first step in this study was to identify genes expressed in fat depot of cattle using the differential display RT-PCR method. Among the transcripts identified as having differential expression in the two adipose tissues were cell division cycle 42 homolog (CDC42), prefoldin-5, decorin, phosphate carrier, 12S ribosomal RNA gene, and kelch repeat and BTB domain containing 2 (Kbtbd2). In subsequent experiments, we determined the expression levels of these latter genes in the pig and in mice fed either a control or high-fat diet to compare the regulation of fat accumulation in other animal species. The levels of CDC42 and decorin mRNA were found to be higher in visceral adipose tissue than in subcutaneous adipose tissue in cattle, pig, and mice. However, the other genes studied did not show consistent expression patterns between the two tissues in cattle, pigs, and mice. Interestingly, all genes were upregulated in subcutaneous and/or visceral adipose tissues of mice fed the high-fat diet compared with the control diet. The data presented here extend our understanding of gene expression in fat depots and provide further proof that the mechanisms of fat accumulation differ significantly between animal species. differential display and reverse transcriptase-polymerase chain reaction; fat depot THERE ARE TWO TYPES OF ADIPOSE TISSUE, subcutaneous and visceral. Recent studies indicate that adipocytes in these two fat depots show differences in basal metabolic properties, for example, in regulating volume, lipid composition, and so on (22,24). There is considerable current interest in visceral adipose tissue because of its relationship with various diseases such as cardiovascular disease, type 2 diabetes mellitus, hyperlipidemia, and syndrome X. There are a number of potential reasons why visceral adipose tissue may contribute to abnormalities in metabolism; among these are its anatomical site and pattern of venous drainage, and the presence of intrinsic and unique features of visceral adipocytes. The venous drainage of visceral adipose tissue is via the portal system, directly providing free fatty acid as a substrate for hepatic lipoprotein metabolism and glucose production (16,22,24). Additionally, in vitro studies using labeled tracers have demonstrated that visceral adipocytes have higher rates of lipid turnover than subcutaneous adipose tissue (19,20).Fat depot metabolism is also of importance in the commercial rearing of livestock such as cattle and pigs. One of the most important themes in the animal industry is the production of high quality meat at low cost. A better understanding of the specific accumulation mechanisms of fat depots should c...
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