泡沫逆转录病毒Bet蛋白的研究进展

泡沫逆转录病毒能长期感染哺乳动物宿主而不引发疾病,这一特点引起研究者们极大兴趣。有研究发现,泡沫逆转录病毒的辅助蛋白Bet不仅能调控病毒的基因表达和感染周期,对病毒慢性感染的建立有重要作用;还能阻止宿主细胞防御因子APOBEC3对病毒复制产生干扰,与病毒持续性感染的维持有关。为了阐明Bet在病毒复制和感染时所发挥的作用,本文对近年来有关Bet蛋白功能的研究进行了分析和总结。     

马传染性贫血病毒Gag p9蛋白功能研究进展

对病毒复制机制研究的一个重要方面是病毒的组装和从细胞表面出芽。过去的 2 0年大量研究证实反转录病毒Gag蛋白对病毒的组装和出芽起着决定性作用。Gag蛋白的多个功能域已经被证明在病毒组装的不同时期发挥作用。马传染性贫血病毒 (equineinfectiousanemiavirus,EIAV)p9是Gag蛋白C端的一个小蛋白 ,在其之上的L域是与病毒释放直接相关的蛋白功能区域 ,L域的核心基序YPDL可与特异的病毒或细胞蛋白相互作用共同介导病毒粒子的组装和出芽作用 ,核心基序YPDL对病毒的复制能力有一定的影响。就近年来对p9功能区与病毒组装和释放关系的研究进展进行综述。     

乙型肝炎病毒多聚酶末端蛋白的结构和功能研究

乙肝病毒蛋白结构和功能是当前研究乙肝病毒的热点之一。HBV多聚酶的末端蛋白在病毒复制过程中起重要作用,主要包括前基因组RNA包装和DNA合成的蛋白引发等,并可抑制细胞对干扰素的反应。本文综述了乙肝病毒多聚酶末端蛋白的结构和功能,还比较了乙肝病毒与逆转录病毒多聚酶结构和功能的异同。     

天然免疫抗病毒效应分子Mx蛋白的结构与功能研究进展

Mx蛋白是很多物种中干扰素诱导的抗病毒状态的关键成分.它们是一类动素样GTPase,具有类似动素的结构和功能特点,例如自我组装以及和细胞内膜结合.Mx蛋白独特的性质使其具有广泛的抗病毒活性,它们作用于病毒进入细胞后不久、病毒基因组复制之前,抑制病毒复制周期的早期阶段.已知一些Mx蛋白识别病毒的核衣壳成分,干扰病毒基因组的复制.动素家族某些成员的晶体结构已经得到解析,解析Mx蛋白的晶体结构对理解其抗病毒机制以及防治新生突发病毒有重要意义.     

本期重点推介

正内源性逆转录病毒(ERVs)是一类在宿主基因组中世代留存的有类似病毒结构的序列元件。ERVs基因组两端有与外源逆转录病毒类似的长末端重复序列(LTRs),中间有1～3个主要的开放阅读框(gag,pol和env)编码病毒复制所需的结构和功能蛋白,其中env的表达与ERVs的侵染能力有关。福建农林大学应用生态研究所王月和尤民生等在通过     

逆转录病毒基因组RNA的二聚作用

逆转录病毒科(Retroviridae)是一成员众多、易变异的RNA病毒科.在逆转录病毒复制周期内,所有逆转录病毒均将两拷贝的单股正链RNA带入病毒粒子[1,2].在此过程中,遗传物质--基因组RNA能顺利包装入病毒粒子是病毒复制与繁衍的关键,而基因组RNA通过二聚作用(Dimer-ization)形成二聚体(Dimer)是包装逆转录病毒的前提.     

HIV-1 Gag蛋白的高效表达调控研究

LTR位于HIV前病毒同DNA基因组的两末端,Gag基因位于5′端LTR的下游。LTR对转录的调控作用主要是由5′端LTR进行的。LTR具有启动子的作用,在结构上具有真核启动子的典型特征。另外,HIV-1 Gag蛋白还有能够自我装配成病毒样粒子(virus like particle,VLP)并从细胞中释放出来的重要特性。 我们利用痘苗病毒表达系统,探索了在细胞质环境中LTR中的多种功能结构对Gag蛋     

甲型流感病毒非结构蛋白的研究进展

PA、PB1和PB2以及NS1蛋白作为甲型流感病毒的非结构蛋白,虽然不直接参与病毒颗粒的组装,但是在病毒的复制周期中起到非常重要的调控作用.由PA、PB1和PB2组成的RNA聚合酶主要参与病毒mRNA的合成以及病毒基因组RNA的复制,而NS1蛋白则通过抑制宿主细胞的干扰素应激系统来拮抗宿主的抗病毒反应.通过研究甲型流感病毒非结构蛋白的结构与功能,对了解流感病毒复制及开发新型抗流感病毒药物有重要意义.     

寨卡病毒蛋白结构与功能研究进展

2015年以来,南美暴发大规模寨卡疫情,因其与新生儿小头症等严重神经发育疾病密切相关,被世界卫生组织列为国际关注的突发公共卫生事件。与其他虫媒黄病毒类似,寨卡病毒为单股正链RNA病毒,其基因组编码的3种结构蛋白构成病毒颗粒,7种非结构蛋白参与病毒复制生活周期的调控。在全球科学家的共同努力下,寨卡病毒蛋白结构与功能的研究取得了突破性进展,极大地促进研究者对病毒复制与致病机制的认识,也为疫苗和药物研发提供了重要科学依据和潜在靶标。本文将对寨卡病毒蛋白的结构与功能的最新研究进展作一综述,并讨论当前面临的挑战和机遇。     

HIV-1整合酶单链抗体的构建及表达

病毒DNA整合到被感染的宿主细胞的染色体上需要逆转录病毒基因组的有效复制,而这一反应是由病毒编码的酶——整合酶(Inte-grase,IN)调节的。由于IN在逆转录病毒生命周期的早期阶段起着关键的作用,所以它已经成了对HIV-1基因治疗的一个非常吸引人的靶蛋白。由于对这个酶缺少有效的抑制剂,人们开始探讨新的抑制其活性的方法,包括抗体的使     

Protease-dependent uncoating of a complex retrovirus

Although retrovirus egress and budding have been partly unraveled, little is known about early stages of the replication cycle. In particular, retroviral uncoating, a process during which incoming retroviral cores are altered to allow the integration of the viral genome into host chromosomes, is poorly understood. To get insights into these early events of the retroviral cycle, we have used foamy complex retroviruses as a model. In this report, we show that a protease-defective foamy retrovirus is noninfectious, although it is still able to bud and enter target cells efficiently. Similarly, a retrovirus mutated in an essential viral protease-dependent cleavage site in the central part of Gag is noninfectious. Following entry, wild-type and mutant retroviruses are able to traffic along microtubules towards the microtubule-organizing center (MTOC). However, whereas nuclear import of Gag and of the viral genome was observed for the wild-type virus as early as 8 hours postinfection, incoming capsids and genome from mutant viruses remained at the MTOC. Interestingly, a specific viral protease-dependent Gag cleavage product was detected only for the wild-type retrovirus early after infection, demonstrating that cleavage of Gag by the viral protease at this stage of the virus life cycle is absolutely required for productive infection, an unprecedented observation among retroviruses.     

Characterization of the genome of feline foamy virus and its proteins shows distinct features different from those of primate spumaviruses.

The genome of the feline foamy virus (FeFV) isolate FUV was characterized by molecular cloning and nucleotide sequence analysis of subgenomic proviral DNA. The overall genetic organization of FeFV and protein sequence comparisons of different FeFV genes with their counterparts from other known foamy viruses confirm that FeFV is a complex foamy virus. However, significant differences exist when FeFV is compared with primate foamy viruses. The FeFV Gag protein is smaller than that of the primate spumaviruses, mainly due to additional MA/CA sequences characteristic of the primate viruses only. Gag protein sequence motifs of the NC domain of primate foamy viruses assumed to be involved in genome encapsidation are not conserved in FeFV. FeFV Gag and Pol proteins were detected with monospecific antisera directed against Gag and Pol domains of the human foamy virus and with antisera from naturally infected cats. Proteolytic processing of the FeFV Gag precursor was incomplete, whereas more efficient proteolytic cleavage of the pre125Pro-Pol protein was observed. The active center of the FeFV protease contains a Gln that replaces an invariant Gly residue at this position in other retroviral proteases. Functional studies on FeFV gene expression directed by the promoter of the long terminal repeat showed that FeFV gene expression was strongly activated by the Bell/Tas transactivator protein. The FeFV Bell/Tas transactivator is about one-third smaller than its counterpart of primate spumaviruses. This difference is also reflected by a limited sequence similarity and only a moderate conservation of structural motifs of the different foamy virus transactivators analyzed.     

Cytoplasmic utilization of human immunodeficiency virus type 1 genomic RNA is not dependent on a nuclear interaction with gag

In some retroviruses, such as Rous sarcoma virus and prototype foamy virus, Gag proteins are known to shuttle between the nucleus and the cytoplasm and are implicated in nuclear export of the viral genomic unspliced RNA (gRNA) for subsequent encapsidation. A similar function has been proposed for human immunodeficiency virus type 1 (HIV-1) Gag based on the identification of nuclear localization and export signals. However, the ability of HIV-1 Gag to transit through the nucleus has never been confirmed. In addition, the lentiviral Rev protein promotes efficient nuclear gRNA export, and previous reports indicate a cytoplasmic interaction between Gag and gRNA. Therefore, functional effects of HIV-1 Gag on gRNA and its usage were explored. Expression of gag in the absence of Rev was not able to increase cytoplasmic gRNA levels of subgenomic, proviral, or lentiviral vector constructs, and gene expression from genomic reporter plasmids could not be induced by Gag provided in trans. Furthermore, Gag lacking the reported nuclear localization and export signals was still able to mediate an efficient packaging process. Although small amounts of Gag were detectable in the nuclei of transfected cells, a Crm1-dependent nuclear export signal in Gag could not be confirmed. Thus, our study does not provide any evidence for a nuclear function of HIV-1 Gag. The encapsidation process of HIV-1 therefore clearly differs from that of Rous sarcoma virus and prototype foamy virus.     

Functional surfaces of the human immunodeficiency virus type 1 capsid protein

The human immunodeficiency virus type 1 initially assembles and buds as an immature particle that is organized by the viral Gag polyprotein. Gag is then proteolyzed to produce the smaller capsid protein CA, which forms the central conical capsid that surrounds the RNA genome in the mature, infectious virus. To define CA surfaces that function at different stages of the viral life cycle, a total of 48 different alanine-scanning surface mutations in CA were tested for their effects on Gag protein expression, processing, particle production and morphology, capsid assembly, and infectivity. The 27 detrimental mutations fall into three classes: 13 mutations significantly diminished or altered particle production, 9 mutations failed to assemble normal capsids, and 5 mutations supported normal viral assembly but were nevertheless reduced more than 20-fold in infectivity. The locations of the assembly-defective mutations implicate three different CA surfaces in immature particle assembly: one surface encompasses helices 4 to 6 in the CA N-terminal domain (NTD), a second surrounds the crystallographically defined CA dimer interface in the C-terminal domain (CTD), and a third surrounds the loop preceding helix 8 at the base of the CTD. Mature capsid formation required a distinct surface encompassing helices 1 to 3 in the NTD, in good agreement with a recent structural model for the viral capsid. Finally, the identification of replication-defective mutants with normal viral assembly phenotypes indicates that CA also performs important nonstructural functions at early stages of the viral life cycle.     

Chromatin tethering of incoming foamy virus by the structural Gag protein

Retroviruses hijack cellular machineries to productively infect their hosts. During the early stages of viral replication, proviral integration relies on specific interactions between components of the preintegration complex and host chromatin-bound proteins. Here, analyzing the fate of incoming primate foamy virus, we identify a short domain within the C-terminus of the structural Gag protein that efficiently binds host chromosomes, by interacting with H2A/H2B core histones. While viral particle production, virus entry and intracellular trafficking are not affected by mutation of this domain, chromosomal attachment of incoming subviral complexes is abolished, precluding proviral integration. We thus highlight a new function of the structural foamy Gag protein as the main tether between incoming subviral complexes and host chromatin prior to integration.     

Preparation of BFV Gag antiserum and preliminary study on cellular distribution of BFV

Viruses (e.g. Human immunodeficiency virus, Human simplex virus and Prototype foamy virus) are obligate intracellular parasites and therefore depend on the cellular machinery for cellular trafficking. Bovine foamy virus (BFV) is a member of the Spumaretrovirinae subfamily of Retroviruses, however, details of its cellular trafficking remain unknown. In this study, we cloned the BFV gag gene into prokaryotic expression vector pET28a and purified the denaturalized Gag protein. The protein was used to immunize BALB/c mouse to produce antiserum, which could specifically recognize the BFV Gag protein in BFV-infected cells through western blot assay. Additionally, these results demonstrated that both the optimal and suboptimal cleavage of Gag protein occur in BFV-infected cells. Subsequently, the Gag antiserum was used to investigate subcellular localization of BFV. In immunofluorescence microscopy assays, colocalization microtubules (MTs) and assembling viral particles were clearly observed, which implied that BFV may transport along cellular MTs in host cells. Furthermore, MTs-depolymerizing assay indicated MTs were required for the efficient replication of BFV. In conclusion, our study suggests that BFV has evolved the mechanism to hijack the cellular cytoskeleton for its replication.     

The DEAD-box RNA helicase DDX6 is required for efficient encapsidation of a retroviral genome

Viruses have to encapsidate their own genomes during the assembly process. For most RNA viruses, there are sequences within the viral RNA and virion proteins needed for high efficiency of genome encapsidation. However, the roles of host proteins in this process are not understood. Here we find that the cellular DEAD-box RNA helicase DDX6 is required for efficient genome packaging of foamy virus, a spumaretrovirus. After infection, a significant amount of DDX6, normally concentrated in P bodies and stress granules, re-localizes to the pericentriolar site where viral RNAs and Gag capsid proteins are concentrated and capsids are assembled. Knockdown of DDX6 by siRNA leads to a decreased level of viral nucleic acids in extracellular particles, although viral protein expression, capsid assembly and release, and accumulation of viral RNA and Gag protein at the assembly site are little affected. DDX6 does not interact stably with Gag proteins nor is it incorporated into particles. However, we find that the ATPase/helicase motif of DDX6 is essential for viral replication. This suggests that the ATP hydrolysis and/or the RNA unwinding activities of DDX6 function in moderating the viral RNA conformation and/or viral RNA-Gag ribonucleoprotein complex in a transient manner to facilitate incorporation of the viral RNA into particles. These results reveal a unique role for a highly conserved cellular protein of RNA metabolism in specifically re-locating to the site of viral assembly for its function as a catalyst in retroviral RNA packaging.     

Expression and maturation of human foamy virus Gag precursor polypeptides.

In this report, we address the processing of the Gag polypeptides of human foamy virus previously reported to be atypical. In the cytoplasm or the nucleus of infected cells as well as in free virus particles, two Gag precursor polypeptides were identified at approximately 72 and 68 kDa, p72 giving rise to p68 by a maturation process. Efficient maturation of Gag precursors was observed only in two situations: (i) during the early steps of virus adsorption and (ii) under experimental conditions, including treatment with DNase I, known to dissociate actin polymers associated with high ionic strength and ionic detergents. Rather than being a defective viral protease function, an association of Gag precursors with a cytoskeleton network might be responsible for the low rate of Gag protein maturation through inhibition of their cleavage by the protease.     

Intra- and intercellular trafficking of the foamy virus auxiliary bet protein

The Bet protein of foamy viruses (FVs) is an auxiliary protein encoded by the 3' end of the viral genome. Although its function during the viral replication cycle is still unknown, Bet seems to play a key role in the establishment and/or maintenance of viral persistence, representing the predominant viral protein detected during chronic infection. To clarify the function of this viral protein, the subcellular distribution of Bet from the prototypic human foamy virus (HFV) was examined. We report here that this protein is distributed in both the cytoplasm and the nucleus of HFV-infected or Bet-transfected cells. The nuclear targeting results from the presence of a bipartite nuclear localization signal at the C-terminal region, sufficient to direct heterologous reporter proteins to the nucleus. Since HFV Bet spreads between cells, we show here that the secreted protein targets the nuclei of recipient cells. HFV Bet follows an unconventional route to exit the cell since its secretion is not affected by brefeldin A, a drug which disrupts the trafficking between the endoplasmic reticulum and the Golgi complex. Finally, these inter- and intracellular movements were also observed for the equine foamy virus Bet protein, strongly suggesting that these remarkable features are conserved among FVs.