抗菌肽及其功能研究

抗菌肽是近年来发现的广泛存在于自然界的一类阳离子抗菌活性肽,越来越多的证据表明它们在宿主先天性免疫和适应性免疫中有着重要的作用。对抗菌肽的研究正不断深入。本文先从抗菌肽研究的历史背景出发,简要介绍了抗菌肽的一般特性;然后从抗菌肽的直接抗菌活性和免疫调节功能这两个方面重点阐述其在宿主防御过程中的作用,最后对抗菌肽的临床应用及前景做了一个概述。     

New insights into innate immunity in Arabidopsis

The term innate immunity has been described as '. . . the surveillance system that detects the presence and nature of the infection and provides the first line of host defense . . .' (Medzhitov, 2001; Nat Rev Immunol 1: 135-145). The strategy of innate immunity is based on the recognition of constitutive and conserved molecules from pathogens by specific receptors, triggering defence responses (Medzhitov and Janeway, 2002; Science 296: 298-300). It has been only within the past few years that studies of plant innate immunity, especially in Arabidopsis, have provided important insights into molecular details that define innate immunity in plants. Here we review the innate immune response in Arabidopsis, where leucine-rich repeat (LRR) cell surface receptors play central roles in monitoring the presence of pathogen (microbe) associated molecules to initiate the rapid expression of defence genes. The PAMPS also activate the expression of genes encoding a family of endogenous peptides (AtPep1 paralogues) and their receptor (PEPR1) that amplify defence signalling through a feedback loop initiated by PAMPS. The concept of innate immunity has provided a valuable framework for researchers to re-evaluate the roles of exogenous and endogenous signals that regulate the expression of plant defensive genes.     

Innate immunity effectors and virulence factors in symbiosis

Rhizobium-legume symbiosis has been considered as a mutually favorable relationship for both partners. However, in certain phylogenetic groups of legumes, the plant directs the bacterial symbiont into an irreversible terminal differentiation. This is mediated by the actions of hundreds of symbiosis-specific plant peptides resembling antimicrobial peptides, the effectors of innate immunity. The bacterial BacA protein, associated in animal pathogenic bacteria with the maintenance of chronic intracellular infections, is also required for terminal differentiation of rhizobia. Thus, a virulence factor of pathogenesis and effectors of the innate immunity were adapted in symbiosis for the benefit of the plant partner.     

Autophagy and plant innate immunity

Plant innate immunity is often associated with specialized programmed cell death at or near the site of pathogen infection. Despite the isolation of several lesion mimic mutants, the molecular mechanisms that regulate cell death during an immune response remain obscure. Recently, autophagy, an evolutionarily conserved process of bulk protein and organelle turnover, was shown to play an important role in limiting cell death initiated during plant innate immune responses. Consistent with its role in plants, several studies in animals also demonstrate that the autophagic machinery is involved in innate as well as adaptive immunities. Here, we review the role of autophagy in plant innate immunity. Because autophagy is observed in healthy and dying plant cells, we will also examine whether autophagy plays a protective or a destructive role during an immune response.     

Antimicrobial peptides: properties and applicability

All organisms need protection against microorganisms, e. g. bacteria, viruses and fungi. For many years, attention has been focused on adaptive immunity as the main antimicrobial defense system. However, the adaptive immune system, with its network of humoral and cellular responses is only found in higher animals, while innate immunity is encountered in all living creatures. The turning point in the appreciation of the innate immunity was the discovery of antimicrobial peptides in the early eighties. In general these peptides act by disrupting the structural integrity of the microbial membranes. It has become clear that membrane-active peptides and proteins play a crucial role in both the innate and the adaptive immune system as antimicrobial agents. This review is focused on the functional and structural features of the naturally occurring antimicrobial peptides, and discusses their potential as therapeutics.     

NOD1和NOD2：介导天然免疫的两种胞浆蛋白

NOD1和NOD2是新发现的一类参与天然免疫的胞浆蛋白质家族—核苷酸结合寡聚域样受体（the nucleotide bindingolig omerization domain-like receptor,NLRs）中的两个重要蛋白受体,它们通过识别外源病原菌的模式抗原分子而激活NF-κB等核转录因子,启动相关细胞因子的基因表达,释放炎性因子和抗菌肽等,其介导的信号通路在宿主抵御病原体感染的天然免疫中发挥着重要作用。     

Plant immune system: Basal immunity

Plants have an efficient system of innate immunity that is based on the effective detection of potentially harmful microorganisms and rapid induction of defense responses. The first level of plant immunity is basal immunity, which is induced by the conserved molecular structures of microbes, such as bacterial flagellins or fungal chitin, or molecules that result from the interaction of plants with pathogens, for example oligosaccharides and peptides (“danger signals”). Plants recognize these inducers through receptors localized to the plasma membrane, represented mainly by receptor-like protein kinases or receptor-like proteins. Activation of the receptor by a ligand triggers a complex network of signaling events, which eventually cause an array of plant defense responses to prevent further spread of the pathogen.     

The immunomodulatory effect of plant lectins: a review with emphasis on ArtinM properties

Advances in the glycobiology and immunology fields have provided many insights into the role of carbohydrate-protein interactions in the immune system. We aim to present a comprehensive review of the effects that some plant lectins exert as immunomodulatory agents, showing that they are able to positively modify the immune response to certain pathological conditions, such as cancer and infections. The present review comprises four main themes: (1) an overview of plant lectins that exert immunomodulatory effects and the mechanisms accounting for these activities; (2) general characteristics of the immunomodulatory lectin ArtinM from the seeds of Artocarpus heterophyllus; (3) activation of innate immunity cells by ArtinM and consequent induction of Th1 immunity; (4) resistance conferred by ArtinM administration in infections with intracellular pathogens, such as Leishmania (Leishmania) major, Leishmania (Leishmania) amazonensis, and Paracoccidioides brasiliensis. We believe that this review will be a valuable resource for more studies in this relatively neglected area of research, which has the potential to reveal carbohydrate targets for novel prophylactic and therapeutic strategies.     

Tool developments for structure-function studies of host defense peptides

Antimicrobial peptides, or host defense peptides, are universal signaling and effector molecules in host defense and innate immunity. This article highlights various tools developed for cathelicidins and defensins, ranging from peptide identification, production, and structural biology, including the eight databases for antimicrobial peptides. Novel peptides can be identified from natural sources at both gene and protein levels. Solid-phase synthesis and bacterial expression are the two important methods for peptide production. Three-dimensional structures of antimicrobial peptides, primarily determined by solution NMR techniques, are essential for an in-depth understanding of the mode of action. The introduction of octanoyl phosphatidylglycerol as a bacterial membrane-mimetic model provides new insights into peptide-lipid interactions. The incorporation of structure and activity data into the antimicrobial peptide database (http://aps.unmc.edu/AP/main.html) will lead to an integrated understanding of these peptides via structural bioinformatics.     

Host defense peptides and the new line of defence against multiresistant infections

Increasing antibiotic resistance has led to an urgent need for new therapeutic approaches. Host defense peptides are known to be antimicrobial and have revealed broad immunomodulatory functions for both innate and adaptive immunity. This review will focus on the role of host defense peptides in infection and immune response and discuss its potential and limitations as a future therapeutical agent.     

The circular RNA circBCL2L1 regulates innate immune responses via microRNA-mediated downregulation of TRAF6 in teleost fish

Growing numbers of studies have shown that circular RNAs (circRNAs) can function as regulatory factors to regulate the innate immune response, cell proliferation, cell migration, and other important processes in mammals. However, the function and regulatory mechanism of circRNAs in lower vertebrates are still unclear. Here, we discovered a novel circRNA derived from the gene encoding Bcl-2-like protein 1 (BCL2L1) gene, named circBCL2L1, which was related to the innate immune responses in teleost fish. Results indicated that circBCL2L1 played essential roles in host antiviral immunity and antibacterial immunity. Our study also identified a microRNA, miR-30c-3-3p, which could inhibit the innate immune response by targeting inflammatory mediator TRAF6. And TRAF6 is a key signal transduction factor in innate immune response mediated by TLRs. Moreover, we also found that the antiviral and antibacterial effects inhibited by miR-30c-3-3p could be reversed with the expression of circBCL2L1. Our data revealed that circBCL2L1 functioned as a competing endogenous RNA (ceRNA) of TRAF6 by competing for binding with miR-30c-3-3p, leading to activation of the NF-κB/IRF3 inflammatory pathway and then enhancing the innate immune responses. Our results suggest that circRNAs can play an important role in the innate immune response of teleost fish.     

Toll样受体信号传导途径的研究进展

Toll样受体家族（Toll-like receptors,TLRs）成员在固有免疫反应,尤其是调节吞噬细胞（如巨噬细胞等）特异性识别微生物病原体抗原,分泌促炎细胞因子,上调共刺激分子,并诱导机体适应性免疫反应抗微生物病原体感染中发挥重要调控作用,被称为机体固有免疫和适应性免疫调节中的辅助受体（adjuvant receptor）。目前,对Toll样受体家族成员调控免疫反应信号传导途径的研究已成为分子免疫学领域的研究热点,认为主要存在髓样分化蛋白88（MyD88,是一种转接蛋白）依赖性和MyrD88非依赖性两条主要调控途径。本文仅就Toll样受体信号传导途径的研究进展作以简要综述。     

How chronic inflammation can affect the brain and support the development of Alzheimer's disease in old age: the role of microglia and astrocytes

A huge amount of evidence has implicated amyloid beta (A beta) peptides and other derivatives of the amyloid precursor protein (beta APP) as central to the pathogenesis of Alzheimer's disease (AD). It is also widely recognized that age is the most important risk factor for AD and that the innate immune system plays a role in the development of neurodegeneration. Little is known, however, about the molecular mechanisms that underlie age-related changes of innate immunity and how they affect brain pathology. Aging is characteristically accompanied by a shift within innate immunity towards a pro-inflammatory status. Pro-inflammatory mediators such as tumour necrosis factor-alpha or interleukin-1 beta can then in combination with interferon-gamma be toxic on neurons and affect the metabolism of beta APP such that increased concentrations of amyloidogenic peptides are produced by neuronal cells as well as by astrocytes. A disturbed balance between the production and the degradation of A beta can trigger chronic inflammatory processes in microglial cells and astrocytes and thus initiate a vicious circle. This leads to a perpetuation of the disease.     

Mutualism versus pathogenesis: the give-and-take in plant–bacteria interactions

Pathogenic bacteria and mutualistic rhizobia are able to invade and establish chronic infections within their host plants. The success of these plant–bacteria interactions requires evasion of the plant innate immunity by either avoiding recognition or by suppressing host defences. The primary plant innate immunity is triggered upon recognition of common microbe-associated molecular patterns. Different studies reveal striking similarities between the molecular bases underlying the perception of rhizobial nodulation factors and microbe-associated molecular patterns from plant pathogens. However, in contrast to general elicitors, nodulation factors can control plant defences when recognized by their cognate legumes. Nevertheless, in response to rhizobial infection, legumes show transient or local defence-like responses suggesting that Rhizobium is perceived as an intruder although the plant immunity is controlled. Whether these responses are involved in limiting the number of infections or whether they are required for the progression of the interaction is not yet clear. Further similarities in both plant–pathogen and Rhizobium –legume associations are factors such as surface polysaccharides, quorum sensing signals and secreted proteins, which play important roles in modulating plant defence responses and determining the outcome of the interactions.     

Endogenous peptide elicitors in higher plants

Plant defense responses against invading organisms are initiated through the perception of molecules associated with attacking microbes and herbivores by pattern recognition receptors. In addition to elicitor molecules derived from attacking organisms, plants recognize host-derived molecules. These endogenous elicitors induce and amplify the defense responses against invading organisms both locally and systemically. Several classes of plant-derived molecules elicit defense, including cell wall fragments and peptides. Endogenous peptide elicitors have been discovered in species across the plant kingdom, and their role regulating immunity to both herbivores and pathogens is becoming increasingly appreciated. In this review, we will focus on the five known endogenous peptide elicitor families, summarize their properties, and discuss research goals to further understanding of plant innate immunity.     

Toll样受体与树突状细胞介导的天然免疫和获得性免疫

树突状细胞(dendritic cells,DCs)作为迄今所发现的抗原提呈功能最强的一类抗原提呈细胞,是联结天然免疫和获得性免疫的桥梁。Toll样受体(Toll-like receptors,TLRs)是一类进化保守的胚系编码的模式识别受体,在DCs的抗原识别、递呈及激活T细胞等方面具有重要作用,是机体受外来抗原入侵后作出适当免疫反应的调控点。现就TLRs在不同DCs亚群中的分布、与DCs介导的天然免疫和获得性免疫的关系及DCs功能可塑性的分子基础作一综述。