CpG DNA特异性识别的关键蛋白Toll样受体-9

Toll样受体在对抗外来病原微生物的天然免疫应答中发挥中心作用。新发现的一种分子识别模型受体Toll样受体-9（TLR9）,能特异性识别CpG DNA并起动信号转导级联反应,在不同种类中的TLR9具有对序列识别的特异性。本文概述国外在TLR9识别作用机制和生物学活性研究中已取得的进展,并提出了今后研究的发展方向。     

MyD88依赖的TLR4信号通路在无症状HIV阳性患者肺泡巨噬细胞中的选择性损伤

肺泡巨噬细胞（AMS）是肺部主要的效应细胞,可通过模式识别受体如Toll样受体4（TLR4）识别病原微生物,从而发挥关键的第1道防线作用。在人类免疫缺陷病毒（HIV）阳性的巨噬细胞中,     

Toll样受体在抗感染免疫中的作用

目前已确认的人类Toll样受体有10个,它们分别识 病原微生物不同的病原体相关分子特式结构,其中TLR9与细菌CpG-DNA关系的发现,受到人们普遍的重视和关注,本文简要地介绍细菌CpG基序与TLR9,鞭毛蛋白与TLR5和病毒与TLR5等的相互关系及其意义。     

Toll样受体4与病毒感染的研究进展

Toll样受体4（TLR4）是固有免疫系统中能够识别病原相关分子模式的受体家族成员,可识别革兰氏阴性菌的脂多糖（LPS）而在细菌感染性疾病的发生中起重要作用。近年来越来越多的研究发现,TLR4还广泛参与病毒感染性疾病的发生和病毒的免疫逃逸,由于其信号转导通路的独特性和细胞定位的可变性,再次引起人们极大的研究兴趣。该文将介绍TLR4的生物学特性、信号转导通路及TLR4与病毒感染的最新研究进展。     

天然免疫进化中的无脊椎动物Toll样受体

Toll样受体（Toll-like receptors,TLR）（或Toll）通过与各种病原相关分子模式（pathogen associated molecular patterns,PAMP）的识别和特异结合,广泛参与各种天然免疫应答,目前已在线虫类、软体动物、节肢动物、棘皮动物及低等脊索类的后口动物等多种无脊椎动物中发现大量的TLR及同源蛋白.TLR在进化中高度保守,其功能随着动物进化中免疫机能的复杂化而多样化.这些研究成果将会不断加深对无脊椎动物天然免疫系统的起源、进化路线及其信号转导机制的认识.     

TLR9的生物学特性及其在心血管疾病中的研究进展

Toll样受体(toll-like receptors,TLRs)是一类保守的介导固有免疫的跨膜信号传递受体家族,是一种I型跨膜蛋白受体,是模式识别受体(pattern recognition receptor,PRR)中的一员,在识别和抵御各种病原微生物及其产物的过程中发挥重要作用。病原微生物呈现多种真核细胞不具备的特殊的保守结构,称为病原相关分子模式(pathogen associated molecular patterns,PAMPs),这种结构可被PRR所识别,并通过下游的接头蛋白引发转录因子的激活和炎症因子的产生。不同的TLR分子具有各自特异的PAMPs识别谱,其中Toll样受体9(TLR9)是识别细菌来源的非甲基化CpG DNA等PAMPs的受体。TLRs在固有免疫和适应性免疫中发挥着重要作用,并参与多种心血管疾病的发病过程。本文就TLR9的生物学特性及其在心血管疾病中的研究进展进行综述。     

Toll样受体识别机制及其生物学意义

Toll样受体介导的信号转导通路在对抗外来病原体的天然免疫应答中起重要作用。Toll样受体是一个天然模板识别受体家族,能识别固有性模板(微生物和哺乳动物所共有的病原相联的分子模板PAMPs)。Toll样受体通过巨噬细胞和其他免疫细胞来识别,其中TLR4识别内毒素、TLR2识别肽聚糖、TLR9识别细菌DNA、TLR5识别鞭毛蛋白、TLR3识别双链RNA等。本探讨了多种Toll受体家族成员在动物体内识别机理及功能,概述了其应用研究进展。     

TOLL样受体9在动脉粥样硬化中的作用研究进展

动脉粥样硬化是一种慢性免疫炎症性疾病,它与自身的先天性免疫和适应性免疫密切相关。Toll样受体(Toll-like receptors,TLR)作为激活非特异性免疫的重要受体蛋白,可以识别病原微生物,激活免疫反应。Toll样受体9是TLR家族中的重要一员,是先天免疫系统中识别细菌和病毒Cp G DNA的重要受体,其与动脉粥样硬化(atherosclerosis,AS)的发生发展紧密相关。研究发现,TLR9与动脉粥样硬化的发生、发展(内皮受损和泡沫化细胞形成)密切相关,但也有研究发现TLR9在AS进程中具有潜在的保护效应。本文对Toll样受体9与动脉粥硬化疾病之间关系做一个简要的阐述,简明的总结了TLR9与树突细胞及自噬之间的联系,并为其作为靶点治疗动脉粥样硬化提供新的思路。     

TLR4及其作用的研究进展

Toll样受体(toll-like receptors,TLRs)因其积极的研究成果而成为近年来广受关注的一种病原体识别受体,TLRs分布相对比较广泛,不但在小肠上皮、呼吸上皮细胞表达,同时也在血管内皮细胞、树突状细胞[1]、大鼠脾及心肌细胞[2]等细胞中表达.研究证实,它属于模式识别受体(pattern recognition receptors,PRRs),病原相关分子模式(pathogen-associated molecule pattern,PAMPs)可被其辨别,然后引发一系列的信号转导,TLRs 是备受关注的一种PRRs.Toll样受体4(toll-like receptor 4,TLR4)是TLRs家族中极为重要的成员,是天然免疫系统识别病原微生物的主要受体,在天然免疫反应中扮演着关键性作用.细菌脂多糖(lipopolysaccharide,LPS)作为一类受体,主要作用是介导信号跨膜转导,尤其对革兰氏阴性菌所引起的感染性炎症起着极为关键的作用.由于近年来对TLR4介导的信号转导及TLR4与疾病的关系研究成为热点,本文就TLR4的信号转导、TLR4与LPS的关系及TLR4信号通路调节进行综述如下.     

鱼类模式识别受体的研究进展

天然免疫（innate immunity）是基于对病原微生物成分的非克隆性识别而启动的快速防御反应。天然免疫系统可通过胚系编码的模式识别受体（pattern-recognition receptors,PRR）识别恒定不变的病原基元,即病原相关分子模式（pathogen-associated molecular patterns,PAMPs）,启动信号级联转导,最终PRRs信号激活宿主免疫和前炎性基因的表达,引发针对所识别病原的免疫反应。目前PRRs主要分为5类,即C-型Lectins、Toll样受体（Toll-like receptors,TLRs）、视黄酸诱导基因I样受体（retinoic acid inducible gene I-like receptors,RLRs）、包含核苷酸结合区和亮氨酸富集区蛋白（the nucleotide-binding domain,leucine-rich repeatcontaining proteins,NLRs,也称NOD样受体）和最近发现的AIM样受体（absent in melanoma（AIM）-like receptors,ALRs）。近年来,随着5种鱼类基因组序列草图的完成,大量鱼类PRRs基因被发现,一些PRRs的配体特异性及其相关信号途径正在逐渐明晰。为此,将对鱼类Toll样受体（TLRs）、视黄酸诱导基因I样受体（RLRs）和NOD样受体（NLRs）的研究进展进行综述。     

Toll样受体（TLR）介导的天然免疫间的相互调节

模式识别受体（PRR）在宿主细胞识别与抵御微生物病原体中起到了重要作用。Toll样受体（TLR）是研究比较清楚的一类PRR,可以识别多种病原体成份,启动天然免疫反应。此外,近来发现了几类其他模式识别受体,如C型凝集素受体（CLR）,核苷酸寡聚结合域（NOD）样受体（NLR）和视黄酸诱导基因I（RIG—I）样受体（RLR）,表明机体的天然免疫反应受到多种机制的精密调控。本文着重综述TLR与其他PRR在识别病原体和介导天然免疫信号通路间的相互关系。     

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。     

Suppression of TLR9 immunostimulatory motifs in the genome of a gammaherpesvirus

Multiple receptors within the innate immune system have evolved to recognize nucleic acids as signatures of viral infection. It is believed that this specificity is essential for viral detection, as viruses often lack other invariant features that can serve as suitable targets for innate receptors. One such innate receptor, TLR9, has been implicated in the detection of many dsDNA viruses. In this study, we investigate the detection of murine gammaherpesvirus 68 (MHV68) by TLR9. We find that the genomic DNA of the murine CMV, a very potent inducer of innate responses. Genome-wide analysis of the number of stimulatory versus nonstimulatory CpG motifs present in the genome of each virus reveals that the MHV68 genome contains only a fraction of the number of immunostimulatory motifs present in murine CMV. Notably, MHV68 appears to have selectively suppressed the number of stimulatory motifs through cytosine to thymine conversion. These data suggest that certain viruses may have evolved and modified their genomic content to avoid recognition by nucleic acid-sensing receptors of the innate immune system.     

The biology of Toll-like receptors

In 1997, a human homologue of the Drosophila Toll protein was described, a protein later to be designated Toll-like receptor 4 (TLR4). Since that time, additional human and murine TLR proteins have been identified. Mammalian TLR proteins appear to represent a conserved family of innate immune recognition receptors. These receptors are coupled to a signaling pathway that is conserved in mammals, insects, and plants, resulting in the activation of genes that mediate innate immune defenses. Numerous studies have now identified a wide variety of chemically-diverse bacterial products that serve as putative ligands for TLR proteins. More recent studies have identified the first endogenous protein ligands for TLR proteins. TLR signaling represents a key feature of innate immune response to pathogen invasion.     

Structure and function of Toll-like receptor proteins

Beginning in 1997 with the identification of the first human homologue of the Drosophila protein Toll, a family of related molecules have been identified in both humans and other mammals. These Toll-like receptor (TLR) proteins appear to represent a conserved family of innate immune recognition receptors. TLR proteins share extended homology with receptors for the cytokines interleukin 1 (IL-1) and interleukin 18 (IL-18). These receptors are coupled to a signaling pathway that is conserved in mammals, insects, and plants, resulting in cellular activation, thereby stimulating innate immune defenses. A variety of bacterial and fungal products have been identified that serve as TLR ligands, and more recent studies have identified the first endogenous protein ligands for TLR proteins. While TLR signaling is likely to be a key feature of innate immune responses, these proteins may also regulate homeostasis via interaction with endogenous protein ligands.     

The role of innate immune receptors in the control of Brucella abortus infection: toll-like receptors and beyond

Research into intracellular sensing of microbial products is an up and coming field in innate immunity. Toll-like receptors (TLRs) recognize Brucella spp. and bacterial components and initiate mononuclear phagocyte responses that influence both innate and adaptive immunity. Recent studies have revealed the intracellular signaling cascades involved in the TLR-initiated immune response to Brucella infection. TLR2, TLR4 and TLR9 have been implicated in host interactions with Brucella; however, TLR9 has the most prominent role. Further, the relationship between specific Brucella molecules and various signal transduction pathways needs to be better understood. MyD88-dependent and TRIF-independent signaling pathways are involved in Brucella activation of innate immune cells through TLRs. We have recently reported the critical role of MyD88 molecule in dendritic cell maturation and interleukin-12 production during B. abortus infection. This article discusses recent studies on TLR signaling and also highlights the contribution of NOD and type I IFN receptors during Brucella infection. The better understanding of the role by such innate immune receptors in bacterial infection is critical in host-pathogen interactions.     

高速泳动族蛋白1的致炎症作用机制

高速泳动族蛋白1(high-mobility group box 1,HMGB1)是一种高度保守的DNA结合蛋白,具有维持核小体结构和调节基因转录的功能,近来发现它是炎性反应强有力的促炎因子。在大多炎性疾病,特别是脓毒症病例中,HMGB1的血清和组织水平均显著升高,而且它与其受体如糖基化终末产物受体(receptor for advanced glycation end products,RAGE)、Toll样受体4(toll-like receptor,TLR4)、Toll样受体2(TLR2)等相互作用促进炎性疾病的发展。为了进一步了解HMGB1,本文就HMGB1的结构、生物学活性、与免疫细胞相互作用、细胞表面受体、以及拮抗HMGB1的药物等进行综述。     

Toll样受体直接调节Treg细胞抑制功能的研究进展

Treg细胞具有维持自身免疫耐受,调节免疫应答的作用。Toll样受体（Toll-like receptors,TLRs）家族可识别病原相关分子模式或内源性配体,启动固有和适应性免疫应答。Treg细胞选择性表达某些TLRs,TLRs活化可能直接增强或降低Treg的免疫抑制功能,这种调节可以影响对感染和肿瘤的免疫监视、移植免疫排斥和自身免疫病发生的进程。因此,了解两者的关系对发现新的治疗靶点和对策有重要的作用。简要综述TLRs对Treg细胞抑制功能直接调节作用的研究进展。     

Polyinosinic acid is a ligand for toll-like receptor 3

Innate immune responses are critical in controlling viral infections. Viral proteins and nucleic acids have been shown to be recognized by pattern recognition receptors of the Toll-like receptor (TLR) family, triggering downstream signaling cascades that lead to cellular activation and cytokine production. Viral DNA is sensed by TLR9, and TLRs 3, 7, and 8 have been implicated in innate responses to RNA viruses by virtue of their ability to sense double-stranded (ds) RNA (TLR3) or single-stranded RNA (murine TLR7 and human TLR8). Viral and synthetic dsRNAs have also been shown to be a potent adjuvant, promoting enhanced adaptive immune responses, and this property is also dependent on their recognition by TLR3. It has recently been shown that mRNA that is largely single-stranded is a ligand for TLR3. Here we have investigated the ability of single-stranded homopolymeric nucleic acids to induce innate responses by murine immune cells. We show for the first time that polyinosinic acid (poly(I)) activates B lymphocytes, dendritic cells, and macrophages and that these responses are dependent on the expression of both TLR3 and the adaptor molecule, Toll/IL-1 receptor domain-containing adaptor inducing IFN-beta (TRIF). We therefore conclude that TLR3 is able to sense both single-stranded RNA and dsRNA.