儿童功能性便秘肠道传输功能与肠道微生态的关系

目的 采用不透光X线标志物测定结肠传输指数(TI)对功能性排便障碍进行分型,探讨各型功能性便秘患儿之间及其与健康儿童之间肠道菌群差异。 方法 选取功能性便秘儿童40例,进行结肠传输试验并进行分型,其中33例出口梗阻型(出口梗阻组),7例慢传输型(慢传输组)。留取便秘儿童新鲜粪便样本,同时收集20例正常儿童(对照组)粪便标本,存放于-80 ℃冰箱。采用16S rRNA测序技术鉴定菌群。 结果 菌群多样性分析:出口梗阻组、慢传输组与对照组粪便标本在丰富度上差异存在统计学意义(P结论 出口梗阻型与慢传输型相比,有部分菌种在慢传输型便秘儿童中明显减少,这需要进一步研究论证;便秘儿童肠道菌群与健康人群存在较大差异,改变肠道菌群可能成为治疗慢性功能性便秘的新策略。慢传输型便秘病例数较少,需增加样本量后进一步分析。     

肠道菌群多糖利用及代谢

宿主与肠道共生菌之间存在一种互利共生的关系.肠道共生菌可以代谢宿主自身不能消化的多糖.进入肠道内的多糖是影响肠道共生菌生理状态和组成的重要因素,这些多糖主要来自饮食和宿主的粘膜分泌物.人类饮食中含有几十种不同的膳食多糖,其中大多数不能被人类基因组中编码的酶降解,并进入大肠,供肠道共生菌利用.肠道共生菌将这些不易消化的多...     

CircORC2 is involved in the pathogenesis of slow transit constipation via modulating the signalling of miR-19a and neurotensin/motilin

In this study, we aimed to investigate the role of circORC2 in modulating miR-19a and its downstream signalling during the pathogenesis of STC. In this study, three groups of patients, that is healthy control (HC) group, normal transit constipation (NTC) group (N = 42) and slow transit constipation (STC) group, were, respectively, recruited. RT-PCR and Western blot analysis were exploited to investigate the changes in the expression levels of miR-19a and circORC2 in these patients, so as to establish a circORC2/miR-19a signalling pathway. The basic information of the patients showed no significant differences among different patient groups. Compared with the HC group, concentrations of neurotensin (NST) and motilin (MLN) were both significantly reduced in the NTC and STC groups, especially in the STC group. Also, miR-19a level was highest, whereas circORC2 level was lowest in the STC group. Furthermore, circORC2 was validated to sponge the expression of miR-19a, and the transfection of circORC2 reduced the expression of miR-19a. Meanwhile, MLN and NST mRNAs were both targeted by miR-19a, and the transfection of circORC2 dramatically up-regulated the expression of MLN and NST. On the contrary, the transfection of circORC2 siRNA into SMCs and VSMCs exhibited the opposite effect of circORC2. Collectively, the results of this study established a regulatory relationship among circORC2, miR-19a and neurotensin/motilin, which indicated that the overexpression of circORC2 could up-regulate the levels of neurotensin and motilin, thus exerting a beneficial effect during the treatment of STC.     

Structural and functional characterization of BaiA,an enzyme involved in secondary bile acid synthesis in human gut microbe

Despite significant influence of secondary bile acids on human health and disease, limited structural and biochemical information is available for the key gut microbial enzymes catalyzing its synthesis. Herein, we report apo‐ and cofactor bound crystal structures of BaiA2, a short chain dehydrogenase/reductase from Clostridium scindens VPI 12708 that represent the first protein structure of this pathway. The structures elucidated the basis of cofactor specificity and mechanism of proton relay. A conformational restriction involving Glu42 located in the cofactor binding site seems crucial in determining cofactor specificity. Limited flexibility of Glu42 results in imminent steric and electrostatic hindrance with 2′‐phosphate group of NADP(H). Consistent with crystal structures, steady state kinetic characterization performed with both BaiA2 and BaiA1, a close homolog with 92% sequence identity, revealed specificity constant (k_cat/K_M) of NADP⁺ at least an order of magnitude lower than NAD⁺. Substitution of Glu42 with Ala improved specificity toward NADP⁺ by 10‐fold compared to wild type. The cofactor bound structure uncovered a novel nicotinamide‐hydroxyl ion (NAD⁺‐OH^?) adduct contraposing previously reported adducts. The OH^? of the adduct in BaiA2 is distal to C4 atom of nicotinamide and proximal to 2′‐hydroxyl group of the ribose moiety. Moreover, it is located at intermediary distances between terminal functional groups of active site residues Tyr157 (2.7 Å) and Lys161 (4.5 Å). Based on these observations, we propose an involvement of NAD⁺‐OH^? adduct in proton relay instead of hydride transfer as noted for previous adducts. Proteins 2014; 82:216–229. © 2013 Wiley Periodicals, Inc.