炎症小体信号通路的负调控

炎症小体(inflammasomes)活化后产生的IL-1β和IL-18等促炎因子对天然免疫和适应性免疫具有重要作用.炎症小体持续活化可引起促炎因子过度表达,导致慢性炎症和自身免疫疾病的发生.正常生理状态下,机体存在多种炎症小体负调机制,以维持免疫反应平衡.病理状态下,感染机体的病原微生物通过多种途径抑制炎症小体信号通路的活化及促炎因子的产生,以利于免疫逃逸.本文综述了机体和病原微生物对炎症小体信号通路的负调控机理.阐明炎症小体信号通路负调控机制将为感染性疾病及其他炎症小体相关炎症性疾病的治疗提供策略.     

NLRP3炎症小体活化、调控机制及相关疾病机制

炎症作为机体的一种自我保护机制有助于清除感染或者有害物质,但是炎症反应失调也会导致疾病发生.NLRP3炎症小体是由胞内模式识别受体NOD样受体家族成员NLRP3形成的一个胞内蛋白复合物,能够诱导IL-1β和IL-18等促炎因子的成熟和分泌,从而促进炎症反应的发生.NLRP3炎症小体可以被多种病原微生物和危险信号活化,并且参与多种人类重大疾病的发生过程,因而NLRP3炎症小体近年来受到了极大的关注.本文就NLRP3炎症小体的活化和调控机制、NLRP3炎症小体在疾病中的作用及靶向NLRP3炎症小体进行相关疾病干预的研究进展进行简要综述.     

病毒感染激活和抑制炎症小体的研究进展

促炎细胞因子白细胞介素1β(IL-1β)和白细胞介素18(IL-18)主要由巨噬细胞和树突细胞产生,是宿主针对各种侵入病原体产生先天免疫应答的重要介质。这些促炎细胞因子从病毒感染的细胞中分泌,被称为炎症小体的多蛋白复合物严格调控。根据炎症小体识别蛋白的种类,炎症小体主要分为两类,即核苷酸结合寡聚结构域样受体(NOD-like receptors,NLRs)和黑色素瘤缺乏因子2样受体(Absent in melanoma 2,AIM2)炎症小体。与其他宿主防御机制不同,炎症小体活化后,会诱导促炎细胞因子IL-1β、IL-18的成熟及分泌。适量的促炎细胞因子有利于控制病理性感染,但如果过量,则会对机体造成一定免疫损伤。本文主要对近几年有关病毒感染对炎症小体的激活和抑制机制进行了综述,总结分析了炎症小体在参与天然免疫反应及病毒感染致病过程中具有的重要作用。     

抗病毒免疫中干扰素与炎症信号通路的交互调控：防御反应与维持稳态

天然免疫是机体通过识别自身或外部危险信号后,为维持体内稳态而逐步建立起来的一系列防御反应,当宿主细胞内的模式识别受体识别胞内病原相关分子模式后激活干扰素(interferon, IFN)、核因子-kappa B (nuclear factor-kappa B, NF-κB)和炎性小体等信号通路。IFNs在天然免疫应答中发挥重要作用,它诱导的抗病毒基因能够通过多种方式抵御病毒的感染,炎症反应则是机体自动的防御反应,能够在病毒感染机体时释放促炎性细胞因子以调控机体的免疫反应,进而发挥抗病毒作用。在病毒感染过程中,IFN信号通路与炎症反应调控网络中的关键分子如NF-κB/RelA、PKR等存在一定的交互作用,此外,IFN信号通路及其产生的细胞因子又影响其他信号通路的活化,进而调控机体的免疫应答以维持自身稳态,它们之间的交互调控失衡将会引起过度炎症反应,导致组织器官的免疫病理损伤,例如SARS-CoV-2感染机体时产生的过度炎症反应。本文综述了机体抗病毒免疫过程中干扰素信号通路与炎症反应之间的交互调控,为研发抗病毒策略提供新思路。     

炎症小体在对抗微生物感染中的作用

炎症小体(inflammasomes)是由胞浆内模式识别受体(PRRs)参与组装的多蛋白复合物,是天然免疫系统的重要组成部分。炎症小体能够识别病原相关分子模式(PAMPs)或者宿主来源的危险信号分子(DAMPs),招募和激活促炎症蛋白酶Caspase-1。活化的Caspase-1切割IL-1β和IL-18的前体,产生相应的成熟细胞因子。炎症小体的活化还能够诱导细胞的炎症坏死(pyroptosis)。目前已经确定多种炎症小体参与了针对多种病原体的宿主防御反应,病原体也已经进化出多种相应的机制来抑制炎症小体的活化。该文总结了炎症小体在抗感染免疫研究领域的最新进展,重点讨论了炎症小体对细菌、病毒、真菌和寄生虫的识别,以及炎症小体的活化在宿主抗感染过程中所发挥的作用。     

Toll样受体信号通路的负调控

综述了Toll样受体(Toll-like receptors,TLRs)介导炎症反应信号通路的负调控机理．TLRs可以被病原体激活并迅速启动炎症反应,对先天性和获得性免疫反应起着重要调节作用．TLRs介导的免疫反应必须受到严格的调控,持续激活状态可长时间高表达炎症因子,导致机体产生慢性炎症、自身免疫紊乱和其他TLRs相关疾病．正常生理状态下,机体存在着多种TLRs的负调控机制,以维持免疫反应的平衡．该领域的研究近年来取得了重要进展,为许多免疫相关疾病的治疗提供了线索．     

NLRP3炎症小体的负向调控机制

NLRP3炎症小体是由NOD样受体(NOD-like receptor, NLR) NLRP3、接头蛋白ASC和胱冬肽酶-1(Caspase-1)所形成的多聚蛋白复合体,能够感受来自病原微生物的病原相关分子模式(pathogen-associated molecular patterns, PAMPs)和胞内自身危险信号-危险相关分子模式(danger-associated molecular patterns, DAMPs),促进细胞因子IL-1β和IL-18的成熟和分泌、引起细胞焦亡,从而在多种生理、病理过程中发挥重要作用. NLRP3炎症小体是目前研究最深入的炎症小体,其表达水平和活化强度与多种疾病的发生、发展密切相关,如感染性疾病、痛风、Ⅱ型糖尿病、动脉粥样硬化、阿尔兹海默症及癌症等.因此,阐明NLRP3炎症小体活化的调控机制,对于揭示这些疾病发生、发展的机理,寻找免疫调节治疗的新途径具有重要意义.本文详细介绍了NLRP3炎症小体的负向调控机制.     

MAPK/ERK 和 MAPK/P38 信号通路的活化参与沙眼衣原体诱导前炎因子的产生

沙眼衣原体感染可导致沙眼、性传播性疾病、不孕症等疾病,主要病理表现是炎症反应引起的组织损伤和瘢痕.因此,沙眼衣原体诱导产生的炎症因子是导致疾病的关键,沙眼衣原体可直接感染内皮细胞产生各种前炎因子,但其机制目前还不清楚.通过ELISA和免疫印迹等方法,检测到沙眼衣原体感染HeLa229细胞可产生IL-8,IL-1α,IL-1β,IL-6等前炎因子,并且沙眼衣原体感染可以主要激活宿主细胞MAPK/ERK和MAPK/P38信号通路.抑制MAPK/ERK和MAPK/P38信号通路显示,两条通路在沙眼衣原体感染过程中参与调节不同的炎症因子产生.MAPK/P38信号通路的活化参与调控IL-1α,IL-6的产生,而IL-8则同时受MAPK/ERK和MAPK/P38两条通路的调控.     

NLRP3 炎性小体研究新进展

NLRP3 炎性小体是一种分子量约为700Kda 的大分子多蛋白复合体,能被多种病原相关的分子模式或损伤相关的分子模式 活化,对固有免疫系统免疫功能的发挥具有极其重要的作用。但如果其被过度激活则可通过活化的半胱天冬酶-1 持续地将 pro-IL-1茁和pro-IL-18 剪切为成熟的IL-1茁和IL-18,进而激活下游信号转导通路,产生大量的炎性介质,引起机体发生严重的炎 症反应,最终促进多种炎症性疾病的发生与发展,如Muckle-Wells综合征、2 型糖尿病、非酒精性脂肪肝、动脉粥样硬化、炎症性肠 病和阿尔兹海默病等。因此,对NLRP3 炎性小体进行深入的研究不仅有助于阐释固有免疫系统如何有效地发挥其免疫功能,而 且作为系列炎症反应的核心,NLRP3 炎性小体还可能成为多种炎症性疾病防治的新靶点。我们就NLRP3 炎性小体的结构与功 能,激活与调控,分布与疾病的近期研究作一综述。     

NLRP3炎症小体在真菌感染中的作用机制研究进展

炎症小体(Inflammasome)是细胞内识别危险信号的多蛋白复合体,是固有免疫的重要组成部分,NOD样受体家族含热蛋白结构域蛋白3炎症小体(NLRP3)是目前研究最多的一种炎症小体。真菌感染中,NLRP3炎症小体通路募集半胱天冬蛋白酶的前体半胱氨酸天冬氨酸蛋白酶1(pro-caspase-1)自身剪切活化,活化后的半胱天冬蛋白酶(Caspase-1),通过对促炎因子IL-1β(interleukin-1β, IL-1β)和IL-18(interleukin-18, IL-18)的激活,引起宿主的炎症反应,在宿主免疫应答中发挥了重要作用。     

Recent advances in the study of Kaposi's sarcoma-associated herpesvirus replication and pathogenesis

It has now been over twenty years since a novel herpesviral genome was identified in Kaposi's sarcoma biopsies. Since then, the cumulative research effort by molecular biologists, virologists, clinicians, and epidemiologists alike has led to the extensive characterization of this tumor virus, Kaposi's sarcoma-associated herpesvirus(KSHV; also known as human herpesvirus 8(HHV-8)), and its associated diseases. Here we review the current knowledge of KSHV biology and pathogenesis, with a particular emphasis on new and exciting advances in the field of epigenetics. We also discuss the development and practicality of various cell culture and animal model systems to study KSHV replication and pathogenesis.     

The structure, reproduction and taxonomy of Vidalia and Osmundaria (Rhodophyta, Rhodomelaceae)

Comprises species occurring mostly in subtidal habitats in tropical, subtropical and warm-temperate areas of the world. An analysis of the type species, V. spiralis (Sonder) Lamouroux ex J. Agardh, a species from Australia, establishes basic characters for distinguishing species in the genus. These characters are (1) branching patterns of thalli, (2) flat blades that may be spiralled on their axis, (3) width of the blade, (4) primary or secondary derivation of sterile and fertile branchlets and (5) position of sterile and fertile branchlets on the thalli. Application of the latter two characters provides an important basic method for separation of species into three major groups. Osmundaria , a genus known only in southern Australia, was studied in relation to Vidalia , and its separation from the Vidalia assemblage is not accepted. Species of Vidalia therefore are transferred to the older genus name, Osmundaria. Two new species, Osmundaria papenfussii and Osmundaria oliveae are described from Natal. Confusion in the usage of the epithet, Vidalia fimbriala Brown ex Turner has been clarified, and Vidalia gregaria Falkenberg, described as an epiphyte on Osmundaria pro/ifera Lamouroux, is revealed to be young branches of the host, Osmundaria prolifera.     

New or rare chromosome counts in Artemisia L. (Asteraceae, Anthemideae) and related genera from Kazakhstan

Fifteen chromosome counts of six Artemisia taxa and one species of each of the genera Brachanthemum, Hippolytia, Kaschgaria, Lepidolopsis and Turaniphytum are reported from Kazakhstan. Three of them are new reports, two are not consistent with previous counts and the remainder are confirmations of very scarce (one to four) earlier records. All the populations studied have the same basic chromosome number, x = 9, with ploidy levels ranging from 2x to 6x. Some correlations between ploidy level, morphological characters and distribution are noted.     

肝癌中HBV和HCV基因和抗原的分布及意义

采用原位分子杂交方法检测HCV RNA及HBV X基因;采用免疫组织化学方法研究HCV核心抗原,非结构区C33c抗原及HBxAg在肝细胞肝癌中的定位及分布.结果表明(1)HCV RNA、HBV X基因在肝细胞肝癌组织检出率分别为40%(55/136)和82%(112/136).HCV RNA定位于癌细胞的胞浆内,阳性细胞呈散在、灶状及弥漫分布三种形式;HBV X基因在肝癌细胞中的分布呈胞浆型、核型及核浆型,阳性细胞也呈上述三种分布形式;(2)HCV C33c抗原、核心抗原在肝细胞肝癌中的阳性率为81%(133/164)及86%(141/164).C33c抗原定位于癌细胞及肝细胞的胞浆内;核心抗原既定位于癌细胞核中,又可定位于胞浆中.C33c抗原阳性细胞以灶状分布为主;而核心抗原阳性细     

Selection with two alleles and complete dominance

For a plant selection model with frequency-independent viabilities, fertilities and selfing rates, it is shown that apart from global fixation, for certain parameter combinations a protected polymorphism and facultative fixation (either allele may become fixed according to initial frequencies) may both occur. Facultative fixation requires different selling rates for the dominant and recessive type. Protection of the polymorphism requires resource allocation for male and female function. In this connection the problem of purely genetically caused population extinction is discussed.
For general frequency dependence and regular segregation, the chances for establishment of a completely recessive gene are compared to those of a completely dominant gene. It is proven that the process of establishment of the recessive gene, despite a fitness advantage, may be considerably endangered by drift effects if random mating prevails. The recessive gene may reach the same effectivity in establishment as a dominant gene, only if the recessive homozygote mates exclusively with its own type during the period of establishment.