Feeding with resistant maltodextrin suppresses excessive calorie intake in a high-fat diet, mediated by changes in mouse gut microbiota composition, appetite-related gut hormone secretion, and neuropeptide transcriptional levels

Kaede Ito, Atsushi Haraguchi, Shuhei Sato, Masataka Sekiguchi, Hiroyuki Sasaki, Conn Ryan, Yijin Lyu, S. Shibata
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Abstract

Consuming resistant maltodextrin (RMD) decreases food intake and increase appetite-related gut hormones, but the underlying mechanisms have remained unknown. Therefore, we aimed to elucidate the mechanisms underlying the effects of RMD feeding on food intake (appetite) using Institute of Cancer Research male mice fed with a high-fat diet (HFD-cellulose group) or HFD in which cellulose was replaced with RMD (HFD-RMD group). Feeding mice with an HFD-RMD for approximately 8 weeks inhibited excessive calorie intake and altered the gut microbiota composition. Excessive calorie intake was inhibited for several days in mice fed only with an HFD-cellulose and transplanted with fecal microbiota from the HFD-RMD group (FMT-HFD-RMD group). Moreover, in the HFD-RMD and FMT-HFD-RMD groups, serum active glucagon-like peptide (GLP)-1 and peptide tyrosine tyrosine (PYY) levels were significantly higher, and appetite-related neuropeptide gene transcription in the hypothalamus were significantly altered, compared with the HFD-cellulose and FMT-HFD-cellulose groups. These results suggested that the long-term RMD intake changed the gut microbiota composition, increased the GLP-1 and PYY secretion, and altered the appetite-related neuropeptide gene transcription in the hypothalamus, leading to suppressed excessive calorie intake in an HFD.
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饲喂耐药麦芽糊精可以抑制高脂肪饮食中过多的卡路里摄入,这是由小鼠肠道微生物群组成、与食欲相关的肠道激素分泌和神经肽转录水平的变化介导的
食用耐药麦芽糊精(RMD)会减少食物摄入量,增加与食欲相关的肠道激素,但其潜在机制尚不清楚。因此,我们的目的是阐明RMD喂养对食物摄入(食欲)影响的机制,使用癌症研究所的雄性小鼠喂食高脂肪饮食(HFD-纤维素组)或用RMD代替纤维素的HFD (HFD-RMD组)。用HFD-RMD喂养小鼠大约8周,抑制了过量的卡路里摄入,并改变了肠道微生物群的组成。仅饲喂hfd -纤维素并移植来自HFD-RMD组(FMT-HFD-RMD组)的粪便微生物群的小鼠,在数天内抑制了过量的卡路里摄入。此外,与hfd -纤维素和fmt - hfd -纤维素组相比,HFD-RMD组和FMT-HFD-RMD组血清中活性胰高血糖素样肽(GLP)-1和肽酪氨酸酪氨酸(PYY)水平显著升高,下丘脑食欲相关神经肽基因转录显著改变。这些结果表明,长期摄入RMD改变了肠道菌群组成,增加了GLP-1和PYY的分泌,改变了下丘脑中食欲相关神经肽基因的转录,从而抑制了HFD中过量的卡路里摄入。
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