核糖核酸酶5在宿主防御中的作用及机制

抗菌肽是机体天然免疫的重要组成部分。核糖核酸酶5（ribonuclease5,RNASE5;又名angiogenin）属于核糖核酸酶A超家族,是一个分泌型小分子蛋白质,广泛分布于机体需要抵御外界病原微生物的组织中。RNASE5对病毒、细菌以及真菌都存在抑制效应,具有广谱抗菌特点,但其表达和活性受到宿主生理状态和外界环境多层次的调控。RNASE5存在多样的抗微生物作用机制,其带正电荷的理化特性破坏微生物细胞壁,而其核糖核酸酶活性则是杀伤真菌所必须的。除了直接作用于微生物外,RNASE5还可作为重要因子调节宿主免疫功能,参与多种病理过程。本文综述了RANSE5的结构、生物活性与功能、作用特点与机制,并讨论了在其研究中存在的问题,以期为今后的研究提供新思路和新方向。     

禽流感病毒宿主范围限制的分子机制研究进展

禽流感病毒感染人类已经成为全球性的社会公共问题。病毒通过禽类直接感染人的机制目前尚不清楚。本文主要综述了国内外近年来在禽流感病毒宿主范围限制性方面的研究进展,并藉此来探讨AIV跨种属感染人类的可能机制。     

流感病毒感染机制的研究进展

流感发病率高,流行广,是目前较为严重的传染病,现有防治手段为减毒活疫苗和化学药物治疗。提高治疗和预防效果急需加强流感感染机制的研究,本文探讨了糖链在流感病毒侵袭中的作用。流感病毒在细胞中的复制过程,流感病毒抑制宿主细胞蛋白表达过程及诱导细胞凋亡作用和机体天然抗病毒机制,提示了加强流感预防,治疗的途径。     

抗菌肽在宿主防御中作用

抗菌肽广泛地存在于自然界中,其中许多抗菌肽具有直接抗微生物活性,能作用于G-、 G+细菌、真菌、寄生虫甚至是包膜病毒,并且在宿主先天免疫和适应性反应中有重要的调节作用。近来,越来越多的证据表明抗菌肽是有效的免疫辅助因子,能够与其他的众多免疫效应子协同作用,从而起始适应性免疫,促进伤口愈合,抑制前炎症反应以及诱导和调节细胞因子和趋化因子的产生。另外,随着抗菌肽作用机理逐渐被揭开,将这些内源性肽及其衍生物制成抗感染治疗药剂将会有广阔的应用前景。     

流感病毒诱导的糖皮质激素损害宿主针对继发细菌性感染的天然免疫防御

多细胞生物体持续暴露在多种不同的病原体下。由于不同类型的病原体需要不同类型的免疫反应,所以理解针对一种类型感染的免疫反应如何影响宿主针对另外一种类型病原体的反应是全面认识宿主一病原体相互作用的必要一环。本研究利用一个共感染的鼠模型以了解流感病毒感染对随后系统性细菌性感染的影响。研究发现流感病毒感染可以触发一般性的应激反应,造成血液中糖皮质激素水平持续性升高,从而导致系统性的机体免疫反应抑制。     

病原菌逃避宿主细胞防御的策略

病原菌对宿主致病是病原菌与宿主复杂相互作用的结果。病原菌与宿主相互作用可造成宿主在细胞、组织及器官不同水平的损伤。病原菌对宿主的致病性及毒力,一方面在于病原菌,另一方面在于宿主因素以及宿主与病原菌的相互作用。病原菌-宿主在细胞水平的相互作用是病原菌感染致病的重要环节。结合本课题组对猪链球菌的研究,从黏附与定殖、侵袭、逃避与扩散等方面概述病原菌逃避宿主细胞防御的机制。     

动物宿主microRNAs抗病毒作用机制研究进展

microRNAs(miRNAs)是一种长度为22nt的非编码RNA分子,能够结合mRNA,影响翻译效率,调控蛋白的表达。近来多项研究表明,动物宿主miRNAs通过多种机制抑制病毒的复制,如直接靶向病毒基因、干扰病毒复制所需因子、调节先天性免疫、调节细胞凋亡、调节细胞免疫,发挥抗病毒效应。本文归纳总结宿主miRNAs对病毒复制的调控机制,讨论miRNAs类抗病毒药物的应用情况,并展望该类药物的发展趋势。     

防御素的研究进展

哺乳动物防御素为机体表达的抗微生物短肽,分α、β和θ 3类,均具有直接杀菌/抑菌或抵抗某些有包膜病毒的活性,参与机体的免疫.它的发现为临床寻求新型抗微生物制剂提供了思路.     

抗菌肽作用机制的研究进展

抗菌肽是一类来源于多种生物、能有效杀灭病原体的小分子多肽,具有活性谱广、作用强且迅速、不易产生耐药等众多优点.作为新一代抗感染候选药物,抗菌肽的作用机制还未完全清楚,但目前有两种观点已得到公认,即胞膜渗透作用破坏胞膜结构完整性和作用于胞内不同靶点干扰细菌生长及代谢平衡.本文主要就抗菌肽理化性质、二级结构、作用机制以及后两者间的关系做一总结,以便更好的理解抗菌肽的构效关系,为合理设计抗菌肽提供理论基础.     

Lactoferrin: Role in iron homeostasis and host defense against microbial infection

The transferrin family of non-heme iron binding glycoproteins are believed to play a central role in iron metabolism and have been implicated in iron transport, cellular iron delivery and control of the level of free iron in external secretions. Lactoferrin (LF) is a member of this family that is widely localized in external fluids including milk and mucosal secretions, in addition to being a prominent component of the secondary granules of neutrophils. Although structurally related to transferrin, LF appears to have a broader functional role mediated by both iron dependent and iron independent mechanisms. In this review, we will focus on our current understanding on the role of LF in regulating iron homeostasis and its role in host protection against microbial infection at the mucosal surface. In addition, recent insights obtained from analyzing the phenotypic consequences of LF ablation in lactoferrin knockout mice (LFKO), which challenge the long held dogma that LF is required for intestinal iron absorption in the neonate, are summarized.     

Structural determinants of host defense peptides for antimicrobial activity and target cell selectivity

Antimicrobial host defense peptides (HDPs) are a critical component of the innate immunity with microbicidal, endotoxin-neutralizing, and immunostimulatory properties. HDPs kill bacteria primarily through non-specific membrane lysis, therefore with a less likelihood of provoking resistance. Extensive structure–activity relationship studies with a number of HDPs have revealed that net charge, amphipathicity, hydrophobicity, and structural propensity are among the most important physicochemical and structural parameters that dictate their ability to interact with and disrupt membranes. A delicate balance among these factors, rather than a mere alteration of a single factor, is critically important for HDPs to ensure the antimicrobial potency and target cell selectivity. With a better understanding of the structural determinants of HDPs for their membrane-lytic activities, it is expected that novel HDP-based antimicrobials with minimum toxicity to eukaryotic cells can be developed for resistant infections, which have become a global public health crisis.     

Toward insights on antimicrobial selectivity of host defense peptides via machine learning model interpretation

Host defense peptides are promising candidates for the development of novel antibiotics. To realize their therapeutic potential, high levels of target selectivity is essential. This study aims to identify factors governing selectivity via the use of the random forest algorithm for correlating peptide sequence information with their bioactivity data. Satisfactory predictive models were achieved from out-of-bag prediction that yielded accuracies and Matthew's correlation coefficients in excess of 0.80 and 0.57, respectively. Model interpretation through the use of variable importance metrics and partial dependence plots indicated that the selectivity was heavily influenced by the composition and distribution patterns of molecular charge and solubility related parameters. Furthermore, the three investigated bacterial target species (Escherichia coli, Pseudomonas aeruginosa and Staphylococcus aureus) likely had a significant influence on how selectivity was realized as there appears to be a similar underlying selectivity mechanism on the basis of charge-solubility properties (i.e. but which is tailored according to the target in question).     

Bacterial resistance to antimicrobial peptides

Antimicrobial peptides (AMPs) or host defense peptides (HDPs) are vital components of human innate defense system targeting human‐related bacteria. Many bacteria have various mechanisms interfering with AMP activity, causing resistance to AMPs. Since AMPs are considered as potential novel antimicrobial drugs, understanding the mechanisms of bacterial resistance to direct killing of AMPs is of great significance. In this review, a comparative overview of bacterial strategies for resistance to direct killing of various AMPs is presented. Such strategies include bacterial cell envelope modification, AMP degradation, sequestration, expelling, and capsule.     

The role of non-chromosomal histones in the host defense system

Histone H1 is located at the inter-nucleosome and more correctly at both ends of the double-stranded DNA that protrude from the nucleosome unit. It has long been recognized to be localized only inside the nuclei as a constituent for packaging nucleosome into chromatin. Thus, it could be hardly believed that detatched or solubilized histone H1 plays the role of a host defense molecule. Given the old reports on histone-like basic proteins that show bacteriostatic functions, I herein chose some recent related articles and tried review them. Recent advances in research on the cell death mechanism makes it possible to understand that programmed cell death, (i.e. apoptosis) could serve as a good source of soluble histones. Some forms of them are highly probable to be bacteriostatic.     

Epithelial antimicrobial peptides in host defense against infection

One component of host defense at mucosal surfaces seems to be epithelium-derived antimicrobial peptides. Antimicrobial peptides are classified on the basis of their structure and amino acid motifs. Peptides of the defensin, cathelicidin, and histatin classes are found in humans. In the airways, α-defensins and the cathelicidin LL-37/hCAP-18 originate from neutrophils. β-Defensins and LL-37/hCAP-18 are produced by the respiratory epithelium and the alveolar macrophage and secreted into the airway surface fluid. Beside their direct antimicrobial function, antimicrobial peptides have multiple roles as mediators of inflammation with effects on epithelial and inflammatory cells, influencing such diverse processes as proliferation, immune induction, wound healing, cytokine release, chemotaxis, protease-antiprotease balance, and redox homeostasis. Further, antimicrobial peptides qualify as prototypes of innovative drugs that might be used as antibiotics, anti-lipopolysaccharide drugs, or modifiers of inflammation.     

Small RNAs in viral infection and host defense

Small RNAs are the key mediators of RNA silencing and related pathways in plants and other eukaryotic organisms. Silencing pathways couple the destruction of double-stranded RNA with the use of the resulting small RNAs to target other nucleic acid molecules that contain the complementary sequence. This discovery has revolutionized our ideas about host defense and genetic regulatory mechanisms in eukaryotes. Small RNAs can direct the degradation of mRNAs and single-stranded viral RNAs, the modification of DNA and histones, and the inhibition of translation. Viruses might even use small RNAs to do some targeting of their own to manipulate host gene expression. This review highlights the current understanding and new insights concerning the roles of small RNAs in virus infection and host defense in plants.     

蜜蜂抗菌肽研究及其应用进展

抗菌肽是一类由特定基因编码的小分子多肽,广泛分布于各种生物中,是生物天然免疫的重要效应分子,其对缺乏获得性免疫系统的昆虫尤为重要。蜜蜂是一种对环境极其重要的社会性模式昆虫,又有着极高的经济价值,因此蜜蜂抗菌肽有着较大的研究意义。本文对蜜蜂4种天然免疫抗菌肽(Apidaecin、Abaecin、Hymenoptaecin和Defensin)和蜂产品中的抗菌肽(Jelleines、Melittin和Apamin)研究进展进行了综述,介绍了它们的功能、作用机制及其应用,提出了蜜蜂抗菌肽未来可行的研究方向,旨在推动蜜蜂抗菌肽的研究。     

ToCV单独侵染和TYLCV&ToCV复合侵染番茄植株上烟粉虱寄主适应性及寄主植物营养成分含量和防御反应变化

[目的]本研究以番茄褪绿病毒(tomato chlorosis virus,ToCV)和番茄黄化曲叶病毒(tomato yellow leaf curl virus,TYLCV)为主体,旨在明确ToCV单独侵染及TYLCV&ToCV复合侵染对烟粉虱Bemisia tabaci MED隐种寄主适应性的影响,并从寄主植物营...