基于“口腔-肠道微生物失衡”-炎症性肠病的中医药干预

众所周知,人体表型乃基因表达调控而成,同时人体与微生物也是“命运共同体”,在体内所有微生物的编码基因约是人类编码基因数目的百倍,这意味着在人体内存在着“第二基因组”表达来调控人体,此基因组被称为微生物组[1]。而体内最主要的微生态位点位于消化道(上、中、下消化道),表明肠道微生物变化已经与消化道各种疾病相关密切。炎症性肠病(IBD)作为最常见消化道疾病之一,病理上表现为免疫-炎症改变,主要类型包括溃疡性结肠炎(UC)、克罗恩病(CD),临床表现为腹胀、腹泻,偶有腹痛、便血[2]。既往大量研究数据主要集中在IBD的病程与肠道微生态或脑-肠轴密切相关。

微生物失衡与妊娠并发症的研究进展

微生物失衡是指人体局部环境中,微生物组成、数量或活性发生改变,超出正常水平就会致病。越来越多的证据表明,微生物失衡可能通过毒素释放诱导胎盘部位免疫炎性反应等机制参与妊娠相关并发症的发病过程,本文就微生物失衡与妊娠并发症关系的研究进展进行综述。

人头皮微生物与相关头皮疾病的研究进展

近年来基于DNA测序和分子生物学技术的研究表明,头皮微生物特别是主要细菌和真菌与头皮生理指标、免疫状态、屏障功能等相关并且影响头皮健康。人头皮屑、脂溢性皮炎、斑秃、头皮型银屑病等头皮疾病常伴随微生物失衡。针对关键微生物及其相互平衡的干预可缓解或治疗疾病。本文总结了头皮微生物特别是细菌和真菌的研究概况、头皮微生物与头皮疾病,比较了目前的实验室研究方法,为头皮健康的维护、头皮产品开发和实验室研究方法提供参考。

连作对土壤微生物菌群影响及修复研究进展

连作可短时间内带来经济效益,满足日益增长的粮食等农产品需求,但长期连作会加速土壤退化,导致作物减产和病害率增高,破坏土壤微生物结构平衡,不利于土壤生态系统的可持续发展。良好的土壤生态系统中有益微生物、有害微生物及植物间维持着相对平衡。微生物群落结构直接指示整个土壤生态系统的转化方向。通过总结前人在连作对土壤微生物菌群的影响及其修复连作土壤障碍方面的研究结果,探讨修复方式的利弊及其未来的研究方向,旨在为连作障碍土壤修复和植物生长发育创造良好条件,为保持土壤微生物群落结构平衡、保证土壤生态系统的可持续发展提供理论依据。

中国公众营养改善低聚糖OLIGO项目（保龄宝）推进会

针对现阶段我国国民大量存在微生物营养失衡的状况，通过倡导食品与保健品行业在公众摄入食物中加入OLIGO益生元，激活与增殖人体的益生菌群，从而达到促进微生态平衡，改善公众营养健康的目的，属于微生物平衡促进项目。

大蒜连作障碍形成机理的研究进展

大蒜是我国重要的经济作物,大蒜连作障碍是制约其产量和品质的关键因素。本文从连作障碍对大蒜生长的影响入手,通过阐述大蒜土壤微生物群落失衡、土壤养分不均衡、自毒作用及各因素相互关系等,解析大蒜连作障碍形成的机理机制。同时,对目前大蒜生产中常用的,防治连作障碍的手段进行分析,最后对大蒜连作障碍研究方向做出展望。

Greater soil microbial biomass loss at low frequency of N addition in an Inner Mongolia grassland

Soil microbial biomass is critical for biogeochemical cycling and serves as precursor for carbon(C)sequestration.The anthropogenic nitrogen(N)input has profoundly changed the pool of soil microbial biomass.However,traditional N deposition simulation experiments have been exclusively conducted through infrequent N addition,which may have caused biased effects on soil microbial biomass compared with those under the natural and continuous N deposition.Convincing data are still scarce about how the different N addition frequencies affect soil microbial biomass.By independently manipulating the frequencies(2 times vs.12 times N addition yr^(–1))and the rates(0–50 g N m^(−2) yr^(−1))of N addition,our study aimed to examine the response of soil microbial biomass C(MBC)to different N addition frequencies with increasing N addition rates.Soil MBC gradually decreased with increasing N addition rates under both N addition frequencies,while the soil MBC decreased more at low frequency of N addition,suggesting that traditional studies have possibly overestimated the effects of N deposition on soil microbial biomass.The greater soil microbial biomass loss with low N frequency resulted from the intensifed soil acidifcation,higher soil inorganic N,stronger soil C and N imbalance,less net primary production allocated to belowground and lower fungi to bacteria ratio.To reliably predict the effects of atmospheric N deposition on soil microbial functioning and C cycling of grassland ecosystems in future studies,it is necessary to employ both the dosage and the frequency of N addition.