Novel Gut Microbiota Modulator, Which Markedly Increases Akkermansia muciniphila Occupancy, Ameliorates Experimental Colitis in Rats.

BACKGROUND: Since gut microbiota is involved in the pathogenesis of inflammatory bowel disease (IBD), antibiotics or probiotics may be attractive options for the treatment of IBD. Akkermansia muciniphila is expected as a next-generation probiotic for IBD, and OPS-2071 is a novel quinolone with potent antibacterial activity against Clostridioides difficile. AIMS: The aim of this study is to assess the potential of OPS-2071 as a gut microbiota modulator for IBD. METHODS: Minimum inhibitory concentrations of several bacteria in the human intestinal microbiota were determined. Microbiota changes in the feces were typed using metagenomic analysis after oral administration of OPS-2071 (100 mg/kg) twice a day to normal rats. The amounts of mucin were determined using the Fecal Mucin Assay Kit. The effects of OPS-2071 (1, 3, 10 mg/kg) twice a day on fecal symptoms and fecal microbiota were evaluated in a colitis rat model induced by free access to drinking water containing 3% dextran sulfate sodium for 10 days. RESULTS: OPS-2071 showed notably low antibacterial activity against only A. muciniphila in spite of higher antimicrobial activity against other strains of intestinal bacteria. OPS-2071 rapidly and dramatically increased the occupancy of A. muciniphila as well as the amount of mucin in the feces of normal rats. OPS-2071 (10 mg/kg) significantly suppressed the exacerbation of stool scores, especially the bloody stool score, with the increase in A. muciniphila occupancy. CONCLUSIONS: OPS-2071 is expected to be a new therapeutic option for IBD as a gut microbiota modulator by significantly increasing A. muciniphila occupancy.

DNA binding-dependent glucocorticoid receptor activity promotes adipogenesis via Krüppel-like factor 15 gene expression.

Glucocorticoids, such as dexamethasone, have been used as in vitro inducers of adipogenesis. However, the roles of the glucocorticoid receptor (GR) in adipogenesis have not been well characterized yet. Here, we show that inhibition of GR activity using the GR antagonist RU486 prevents human mesenchymal stem cell and mouse embryonic fibroblast (MEF) differentiation into adipocytes. Moreover, in MEFs isolated from GR knockout (GR(null)) and GR(dim) mice deficient in GR DNA-binding activity, adipogenesis was blocked. We identified glucocorticoid response element sites in the first intron of KLF15 by bioinformatical promoter analysis and confirmed their functional relevance by demonstrating GR interaction by chromatin immunoprecipitation. Moreover, transfection of MEFs with siRNA for KLF15 significantly attenuated the expressions of adipogenic-marker genes and the lipid accumulation. Our results provide a new mechanism for understanding glucocorticoids-dependent adipogenesis and that GR promotes adipogenesis via KLF15 gene expression as a transcriptional direct target.

mTOR regulates skeletal muscle regeneration in vivo through kinase-dependent and kinase-independent mechanisms.

Rapamycin-sensitive signaling is required for skeletal muscle differentiation and remodeling. In cultured myoblasts, the mammalian target of rapamycin (mTOR) has been reported to regulate differentiation at different stages through distinct mechanisms, including one that is independent of mTOR kinase activity. However, the kinase-independent function of mTOR remains controversial, and no in vivo studies have examined those mTOR myogenic mechanisms previously identified in vitro. In this study, we find that rapamycin impairs injury-induced muscle regeneration. To validate the role of mTOR with genetic evidence and to probe the mechanism of mTOR function, we have generated and characterized transgenic mice expressing two mutants of mTOR under the control of human skeletal actin (HSA) promoter: rapamycin-resistant (RR) and RR/kinase-inactive (RR/KI). Our results show that muscle regeneration in rapamycin-administered mice is restored by RR-mTOR expression. In the RR/KI-mTOR mice, nascent myofiber formation during the early phase of regeneration proceeds in the presence of rapamycin, but growth of the regenerating myofibers is blocked by rapamycin. Igf2 mRNA levels increase drastically during early regeneration, which is sensitive to rapamycin in wild-type muscles but partially resistant to rapamycin in both RR- and RR/KI-mTOR muscles, consistent with mTOR regulation of Igf2 expression in a kinase-independent manner. Furthermore, systemic ablation of S6K1, a target of mTOR kinase, results in impaired muscle growth but normal nascent myofiber formation during regeneration. Therefore, mTOR regulates muscle regeneration through kinase-independent and kinase-dependent mechanisms at the stages of nascent myofiber formation and myofiber growth, respectively.

Signal transduction study using gene-targeted embryonic stem cells.

Gene targeting is one of the most powerful tools to define the role of signaling molecules in animal development and disease etiology. By using this technique, nearly 1000 knockout mice have been produced over the last two decades. Generating knockout mice, however, is a time-consuming procedure. Also, an unexpected embryonic lethality sometimes prevents us from examining the function of the gene in specific tissues. Here, we describe a convenient method to directly disrupt genes at both alleles in murine embryonic stem (ES) cells. These homozygous knockout ES cells have been shown useful to determine the role of the genes in the mediation of various cellular activities such as proliferation, differentiation, apoptosis, survival, transformation, and so on. Furthermore, with the recent advance of in vitro differentiation techniques, it is now feasible to rapidly determine the role of specific molecules in particular tissues.