Toll样受体4表达的调节

Toll样受体4(TLR4)是最早发现的人类Toll样受体,主要表达于树突状细胞和巨噬细胞等免疫细胞表面,在免疫应答和炎症反应中起重要作用。本文综述了影响TLR4表达的包括上调因素和下调因素在内的一些主要调节因素。     

树突状细胞与Toll受体研究新进展

树突状细胞是最强的抗原提呈细胞,在免疫系统中发挥着重要作用。Toll样受体是表达在树突状细胞上的一种PRRs,主要功能是通过识别病原体微生物所携带的病原相关分子模式激活DC,使其分泌各种免疫调节细胞因子,从而启动免疫应答。在肠道免疫中TLR信号的激活为肠道提供保护作用。本文简述了树突状细胞的生物特性、不同亚型。重点阐述了Toll样受体在肠道免疫中的作用及益生菌对肠道Toll样受体表达的影响。     

Toll样受体4对动脉粥样硬化发生、发展的研究进展

动脉粥样硬化（atherosclerosis,AS）是多种细胞、炎性介质参与形成的慢性炎症性疾病。Toll样受体家族（Toll like receptors,TLRs）中的TLR4是机体重要的诱导分泌多种炎性因子的模式识别受体。现有证据表明,TLR4不仅产生多种炎性因子诱发血管炎症反应,而且促进AS斑块形成和发展,造成斑块不稳定,甚至破裂,对AS的发生、发展具有重要作用。因此,了解TLR4对AS的影响有助于发现新的治疗靶点和对策。主要对TLR4在AS发病机制和易损斑块发展中的作用进行综述。     

Toll样受体与肿瘤免疫

Toll样受体(Toll-like receptor)是天然免疫系统中最重要的模式识别受体,在病原体感染过程中对入侵病原体的识别,激活免疫应答起重要作用。近年发现Toll样受体在多种肿瘤的发生过程中起重要的调控作用。Toll样受体在肿瘤细胞中具有表达,并且Toll样受体信号诱导的促炎症反应是肿瘤发生的必要条件,但是有些Toll样受体的配体仍然表现出极强的抗肿瘤活性,目前,Toll样受体在肿瘤免疫中的机制研究已经成为Toll样受体作为药物靶点的临床应用的关键。本文对Toll样受体在肿瘤免疫中的机制进行综述。     

Toll样受体通路调节Tregs功能的研究进展

模式识别受体Toll样受体(Toll like receptors,TLRs)是固有免疫中免疫受体的代表,进化上十分保守,对生物体的生存极为重要。TLRs通过内源或外源的配体启动信号转导,激活下游一系列重要的基因表达与活化。研究表明调节性T细胞(Regulatory T cell,Treg)在维持机体外周免疫耐受和阻止移植排斥反应等方面发挥核心作用。Treg细胞表达某些TLRs,包括TLR2、TLR4、TLR5、TLR7、TLR8、TLR9等。TLRs的活化可能直接或间接地影响(主要是活化) Treg的增殖和免疫抑制功能,这种调节与感染、自身免疫病和癌症的发生密切相关。其中热休克蛋白作为TLRs配体分子对于Treg的调节发挥了重要的作用。因此,了解TLRs通路对研究Treg免疫调控机制、新药物研发和靶向治疗有重大意义。文中简要介绍了TLRs通路调节Treg免疫功能的相关研究进展。     

Toll样受体信号转导途径研究进展

Toll样受体(Toll-like receptors,TLRs)属于模式识别受体(pattern recognition receptors,PRRs)家族,识别高度保守的微生物组分-病原相关分子模式(pathogen-associated molecular pat-terns,PAMPS)。迄今为止,在人类基因组中已发现10个Toll样受体。这些受体通过感知不同的微生物刺激,招募特异接头蛋白,激活一系列信号级联反应,引发针对病原体的特异性免疫应答,是连接天然免疫和适应性免疫应答的桥梁。哺乳动物Toll样受体的发现引领天然免疫的研究进入飞速发展的时代。本文将对Toll样受体信号转导途径的最新进展作一综述,以便更好地理解Toll样受体介导的分子免疫机制,这将有助于研发免疫治疗的分子靶标,最终有效预防、控制Toll样受体介导的疾病。     

白假丝酵母相关Toll样受体的研究进展

白假丝酵母引起的疾病越来越多,其表现也多种多样,尤其是细胞免疫缺陷病人会产生威胁生命的系统性真菌病,其病死率为35%,天然免疫在抵御该菌感染方面具有特别重要的意义,宿主细胞通过模式识别受体识别各种微生物的病原体相关分子模式,而Toll样受体和Nod蛋白是两类参与天然免疫的模式识别受体,其中Toll样受体家族在抗真菌感染中起非常重要的作用.本文对人体中该受体的概况,以及与抗白假丝酵母紧密相关的Toll样受体2和Toll样受体4作一综述.     

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。     

髓样分化蛋白-2在天然免疫中的作用

Toll样受体 (Toll likereceptor ,TLR)家族作为模式识别受体 ,在天然免疫中具有重要作用。髓样分化蛋白 2 (myeloiddifferentialprotein 2 ,MD 2 )可能含有两个相对独立的功能结构域 ,既能与Toll样受体家族中的TLR4、TLR2结合 ,也能与多种配体结合 (包括lipopolysaccharide ,LPS)。这种特殊的结构可能与其三方面的主要功能有关 :(1)MD 2与TLR4结合 ,赋予TLR4对各种配体 (包括LPS)的反应性 ;(2 )MD 2与TLR2结合 ,赋予TLR2对LPS的反应性 ,并增强TLR2对细菌及其胞壁成分的反应性 ;(3)MD 2能促进TLR4和TLR2的表达 ,并且与TLR4在细胞内的分布密切相关。这表明MD 2可以通过两种方式直接或间接调控TLRs的功能 :与TLR2 /TLR4结合 ,或调控TLR2 /TLR4的表达与分布。因而MD 2不仅仅是TLR4的辅助分子 ,而且还是天然免疫中的调控分子 ,可能在感染、炎症、免疫等病理生理过程中具有更广泛的生物学功能     

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。     

Antiviral signaling through pattern recognition receptors

Viral infection is detected by the host innate immune system. Innate immune cells such as dendritic cells and macrophages detect nucleic acids derived from viruses through pattern recognition receptors (PRRs). Viral recognition by PRRs initiates the activation of signaling pathways that lead to production of type I interferon and inflammatory cytokines, which are important for the elimination of viruses. Two types of PRRs that recognize viral nucleic acids, Toll-like receptors (TLR) and RIG-I-like RNA helicases (RLH), have been identified. Of the TLRs, TLR3 recognizes viral double-stranded (ds) RNA, TLR7 and human TLR8 identify viral single-stranded (ss) RNA and TLR9 detects viral DNA. TLRs are located in endosomal compartments, whereas RLH are present in the cytoplasm where they detect viral dsRNA or ssRNA. Here we review the role of TLRs and RLHs in the antiviral innate immune response.     

Bacterial cell wall macroamphiphiles: Pathogen-/microbe-associated molecular patterns detected by mammalian innate immune system

Innate immune system is the first line of host defense against invading microorganisms. It relies on a limited number of germline-encoded pattern recognition receptors that recognize conserved molecular structures of microbes, referred to as pathogen-/microbe-associated molecular patterns (PAMPs/MAMPs). Bacterial cell wall macroamphiphiles, namely Gram-negative bacteria lipopolysaccharide (LPS), Gram-positive bacteria lipoteichoic acid (LTA), lipoproteins and mycobacterial lipoglycans, are important molecules for the physiology of bacteria and evidently meet PAMP/MAMP criteria. They are well suited to innate immune recognition and constitute non-self signatures detected by the innate immune system to signal the presence of an infective agent. They are notably recognized via their lipid anchor by Toll-like receptors (TLRs) 4 or 2. Here, we review our current knowledge of the molecular bases of macroamphiphile recognition by TLRs, with a special emphasis on mycobacterial lipoglycan detection by TLR2.     

Lipopolysaccharides from atherosclerosis-associated bacteria antagonize TLR4, induce formation of TLR2/1/CD36 complexes in lipid rafts and trigger TLR2-induced inflammatory responses in human vascular endothelial cells

Infection with bacteria such as Chlamydia pneumonia, Helicobacter pylori or Porphyromonas gingivalis may be triggering the secretion of inflammatory cytokines that leads to atherogenesis. The mechanisms by which the innate immune recognition of these pathogens could lead to atherosclerosis remain unclear. In this study, using human vascular endothelial cells or HEK-293 cells engineered to express pattern-recognition receptors (PRRs), we set out to determine Toll-like receptors (TLRs) and functionally associated PRRs involved in the innate recognition of and response to lipopolysaccharide (LPS) from H. pylori or P. gingivalis. Using siRNA interference or recombinant expression of cooperating PRRs, we show that H. pylori and P. gingivalis LPS-induced cell activation is mediated through TLR2. Human vascular endothelial cell activation was found to be lipid raft-dependent and to require the formation of heterotypic receptor complexes comprising of TLR2, TLR1, CD36 and CD11b/CD18. In addition, we report that LPS from these bacterial strains are able to antagonize TLR4. This antagonistic activity of H. pylori or P. gingivalis LPS, as well as their TLR2 activation capability may be associated with their ability to contribute to atherosclerosis.     

Toll-like receptor 9, CpG DNA and innate immunity

Innate immunity provides the first line of defense against invading pathogens and is essential for survival in the absence of adaptive immune responses. Innate immune recognition relies on a limited number of germ-line encoded receptors, such as Toll-like receptors (TLRs), that evolved to recognize conserved molecular patterns of microbial origin. To date, ten transmembrane proteins in the TLR family have been described. It is becoming increasingly clear that bacterial CpG DNA and synthetic oligodeoxynucleotides (ODN) containing unmethylated CpG are potent inducers of the innate immune system including dendritic cells (DCs), macrophages, and natural killer (NK) and NKT cells. Recent studies indicate that mucosal or systemic delivery of CpG DNA can act as a potent adjuvant in a vaccine combination or act alone as an anti-microbial agent. Recently, it was shown that TLR9 is essential for the recognition of unmethylated CpG DNA since cells from TLR9-deficient mice are unresponsive to CpG stimulation. Although the effects of CpG DNA on bone marrow-derived cells are beginning to unfold, there has been little or no information regarding the mechanisms of CpG DNA function on non-immune cells or tissues. This review focuses on the recent advances in CpG-DNA/TLR9 signaling effects on the activation of innate immunity.     

Toll-like receptors and innate immunity

Toll-like receptors (TLRs) are evolutionarily conserved innate receptors expressed in various immune and non-immune cells of the mammalian host. TLRs play a crucial role in defending against pathogenic microbial infection through the induction of inflammatory cytokines and type I interferons. Furthermore, TLRs also play roles in shaping pathogen-specific humoral and cellular adaptive immune responses. In this review, we describe the recent advances in pathogen recognition by TLRs and TLR signaling.     

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.     

Recognition of the fungal cell wall by innate immune receptors

Human cells have a variety of receptors that innately recognize conserved structures on the fungal cell wall. Major receptors include dectin-1, which recognizes β1,3-glucans; mannose receptors, which recognize mannans, and Toll-like receptors 2 and 4. The fungal cell wall is a potent activator of complement, which results in deposition of fragments of the third component of complement that serve as ligands for complement receptors. The nature of the innate immune response is dictated by the relative amount each of these receptors is stimulated. Innate recognition can lead to destruction of the invading fungus and/or initiation of an adaptive immune response. Fungi have a variety of strategies to avoid innate recognition, including masking of ligands and changing their surface properties by phase transition.     

Inflammasome activation and metabolic disease progression

Innate pattern recognition receptors NLRs are cytosolic sensors that detect endogenous metabolic stress and form a multiprotein complex called the inflammasome, that recruits and activates caspase enzymes mediating the activation of the cytokines IL-1β and IL-18. The innate immune system and metabolic system are evolutionarily conserved, intimately integrated, and functionally dependent. In recent decades, obesity-associated metabolic diseases have been become a worldwide epidemic. Here we review recent evidence that demonstrates the important roles of NLRs and inflammasomes in response to metabolic stress in different tissues.