The complexities of eukaryotic transcription initiation: regulation of preinitiation complex assembly.

Individual steps in the assembly of RNA polymerase II and general initiation factors into a preinitiation complex serve as points of control for activators, whose functions require additional cofactors. The full range of induction by activators appears to involve both the reversal of negative constraints and net positive effects on promoter interactions with general factors.     

基于microRNA共调控网络的microRNA调控机制研究

已有研究通过计算和实验的手段,证明了不同的microRNA(miRNA)通过相互之间的合作,来共同调控它们所共有的靶基因。对miRNA之间这种合作行为的特性的研究,能够帮助我们更好的理解miRNA的调控机理。本文建立了一个网络来描述miRNA之间的合作关系,并通过对该网络的分析,得出了四点关于miRNA调控机制的性质。第一,基因靶标数目越多的miRNA倾向于与越多的miRNA伙伴进行合作。第二,进化上保守的miRNA所具有的共调控伙伴的数目显著多于非保守的miRNA。第三,以上的性质是跨物种的存在的(人与小鼠)。第四,miRNA与蛋白质在系统层面性质存在一定的相似。     

microRNA155在动脉粥样硬化发生过程中的网络调控机制

动脉粥样硬化(atherosclerosis,AS)是一种慢性进行性的血管炎症性疾病,其发病机制主要包括内皮细胞损伤,脂质浸润及炎症介质分泌等。microRNA155(miR-155)是参与AS炎性调控、免疫和自噬信号等通路的微小非编码RNA。系统性研究miR-155及其靶基因的网络调控机制,能全面理解miR-155在AS中的作用,促进其在临床诊断中的应用开发。利用miRNA靶基因预测数据库miRDB、miRmap和Starbase获取miR-155的靶基因集。R语言分析基因表达综合数据库(gene expression omnibus,GEO)共享平台动脉粥样硬化斑块差异表达基因(GSE24702),筛选出18 076个差异表达基因。利用基因集富集分析(gene set enrichment analysis,GSEA)分析,观察这些差异表达基因共同富集在IL6-JAK-STAT3信号通路、炎症反应和TNFα等炎症信号通路。与miR-155靶基因交叉匹配得到371个交集mRNA,其中159个在动脉粥样硬化斑块中上调,212个在动脉粥样硬化斑块中下调。基因本体(gene ontology,GO)及基因组数据库(kyoto encyclopedia of genes and genomes,KEGG)分析研究基因功能,GO富集分析371个差异基因主要富集炎症和凋亡信号通路的负调控等功能,KEGG分析371个差异基因主要富集TGFβ等炎症信号通路。蛋白相互作用网络(protein-protein interaction networks,PPI)分析获得关键节点基因是ARRB2、FBXO11、SOCS1、FBXO22、FBXO30、KRAS、RNF19A、TRIM32、HERC4、PJA1、RCHY1和DET1。本研究表明,miR-155主要通过调控炎症反应等相关信号通路影响斑块细胞炎症、自噬及凋亡等功能,进而影响动脉粥样硬化的各个进程。     

The role of microRNA in the delayed negative feedback regulation of gene expression

Oscillatory gene expression plays an important role in somite segmentation during the early developmental stages of vertebrates. Recent experimental studies have shown that microRNA can regulate gene expression by stimulating degradation of mRNA and/or repression of translation. In this communication, we incorporate miRNA into a previous mathematical model of gene expression with delayed negative feedback and demonstrate how this modified model can elucidate the possible effect of miRNA on the oscillatory gene expression. Our finding suggests that miRNA maybe a destabilizing or stabilizing factor in the dynamics of gene expression depending on the severity of its effect on mRNA degradation. Our finding provides testable hypothesis for experimental biologists to further investigate miRNA's increasing functional roles in regulating cellular processes and development.     

MicroRNA在自然杀伤细胞发育分化及功能调控过程中的作用

自然杀伤(natural killer, NK)细胞是固有免疫系统中重要的效应细胞,在宿主抗感染、抗肿瘤中发挥重要作用,并参与免疫调节。NK细胞主要由骨髓造血干细胞发育分化而来,NK细胞的发育、成熟及功能依赖于微环境、胞内转录因子及转录后水平的调节。MicroRNA作为一种小非编码RNA,主要在转录后水平上调节靶基因的表达,在NK细胞的生命过程中发挥重要作用。研究发现年龄会影响NK细胞的miRNA表达谱,进而影响NK细胞的发育与功能。基于miRNA对NK细胞发育及功能的调节作用,miRNA可能作为潜在的靶标来保护或恢复患者NK细胞功能,从而治疗相关疾病。为此,文中将对microRNA在NK细胞发育分化及功能调控过程中的研究进展做初步概述。     

The complexities of dystroglycan

The notion of dystroglycan as a simple laminin-binding receptor is increasingly being challenged. New roles and new binding partners are continually emerging. Recent structural advances have provided exciting new insights into the precise molecular interactions between dystroglycan and other key components of the dystroglycan complex. Coupled with an increasing understanding of dystroglycan function at the molecular level, we are finally beginning to probe the complexities of dystroglycan, not only in disease, but in development, adhesion and signalling.     

MiRNA在TLR信号通路中的负性调控作用

TLR信号是生物体重要的病原体模式识别信号,在免疫识别和炎症反应中具有重要作用,其信号异常会导致许多免疫和炎症相关疾病的发生,因此探讨和明确TLR信号通路的调控机制具有非常重要的意义。近年来研究发现,作为重要的基因表达调控的小分子RNA,微RNA(microRNA,miRNA)能与TLR信号通路中众多靶基因mRNA的3’UTR区结合,从而抑制翻译过程或降解mRNA来发挥负性调控作用。本文就miRNA对TLR信号通路中的一些受体、信号分子、调节因子和细胞因子的负性调控作用方面进行阐述。