Transport Media for Herpes Simplex Virus Types 1 and 2

An evaluation was made of the recovery rate of herpes simplex virus (HSV) type 1 or 2 from 197 clinical specimens obtained in two or three charcoal transport media: Leibovitz viral transport medium, a modified Leibovitz-Emory medium (LEM), in which agarose was used instead of agar, and Amies bacterial transport medium. The specimens were stored and shipped for 1 to 19 days in these media at ambient temperature or in Hanks buffered-salt solution in dry ice. The results indicate that the LEM was most effective, particularly in the recovery of HSV type 2 from clinical specimens held at ambient temperature. In vitro and in vivo studies in genitally infected mice corroborated the observations obtained with human clinical specimens. The availability of transport media which can be used for shipment at ambient temperature offers clinicians easier accessibility to laboratory confirmation and antigenic typing of HSV from suspect herpetic infections.     

Inhibition of Herpes Simplex Virus Type 2 Replication by Thymidine

Replication of herpes simplex virus type 2 (HSV-2) was impeded in KB cells which were blocked in their capacity to synthesize DNA by 2 mM thymidine (TdR). The degree of inhibition was dependent upon the concentration of TdR. In marked contrast, HSV-1 is able to replicate under these conditions. The failure of HSV-2 to replicate is probably due to the inhibition of viral DNA synthesis; there was a marked reduction in the rate of DNA synthesis as well as the total amount of HSV-2 DNA made in the presence of 2 mM TdR. We postulated that the effect of TdR on viral replication occurs at the level of ribonucleotide reductase in a manner similar to KB cells. However, unlike KB cells, an altered ribonucleotide reductase activity, highly resistant to thymidine triphosphate inhibition, was found in extracts of HSV-2-infected KB cells. This activity was present in HSV-2-infected cells incubated in the presence or absence of TdR. Ribonucleotide reductase activity in extracts of HSV-1-infected KB cells showed a similar resistance to thymidine triphosphate inhibition. These results suggest that the effect of TdR on HSV-2 replication occurs at a stage of DNA synthesis other than reduction of cytidine nucleotides to deoxycytidine nucleotides.     

Biological Characteristics of Cloned Populations of Herpes Simplex Virus Types 1 and 2

By using cloned types 1 and 2 herpes simplex virus, obtained by selecting large and small plaques produced by material from human lesions, studies were performed to compare properties between preparations of each type. Regarding the rate of inactivation by ultraviolet light, no differences were found between the two antigenic types and none between the preparations obtained from either type. In contrast, type 1 preparations were found to be more readily inactivated at 45 C than type 2. Plaque size of cloned preparations changed by passage in cell culture. A broader range of plaque sizes was obtained, and average plaque size was larger. After 20 passages, preparations obtained from different types gave rise to one of three kinds of cytopathic effect. The cytopathic effect produced by type 1 preparations remained as before 20 passages and consisted of round cells in a compact central mass. For type 2, two kinds of cytopathic effect were seen in cloned preparations. This consisted of aggregates of round cells (seen in preparations before 20 passages) or of large, loose aggregates of round cells of various sizes. Results from neutralization studies using virus before and after 20 passages in cell culture versus antisera prepared against live or ultraviolet-inactivated virus showed no differences between cloned preparations obtained from a given type.     

Efficient Herpes Simplex Virus 1 Replication Requires Cellular ATR Pathway Proteins

Herpes simplex virus 1 (HSV-1) is a double-stranded DNA virus that replicates in the nucleus of the host cell and is known to interact with several components of the cellular DNA-damage-signaling machinery. We have previously reported that the DNA damage response kinase, ATR, is specifically inactivated in HSV-1-infected cells. On the other hand, we have also shown that ATR and its scaffolding protein, ATRIP, are recruited to viral replication compartments, where they play beneficial roles during HSV-1 replication. In order to better understand this apparent discrepancy, we tested the hypothesis that some of the components of the ATR pathway may exert an antiviral effect on infection. In fact, we learned that all 10 of the canonical ATR pathway proteins are stable in HSV-infected cells and are recruited to viral replication compartments; furthermore, short hairpin RNA (shRNA) knockdown shows that several, including ATRIP, RPA70, TopBP1, Claspin, and CINP, are required for efficient HSV-1 replication. We also determined that activation of the ATR kinase prior to infection did not affect virus yield but did result in reduced levels of recombination between coinfecting viruses. Together, these data suggest that ATR pathway proteins are not antiviral per se but that activation of ATR signaling may have negative consequences during viral replication, such as inhibiting recombination.     

Virus Type-Specific Thymidine Kinase in Cells Biochemically Transformed by Herpes Simplex Virus Types 1 and 2

Transformation of mouse cells (Ltk(-)) and human cells (HeLa Bu) from a thymidine kinase (TK)-minus to a TK(+) phenotype (herpes simplex virus [HSV]-transformed cells) has been induced by infection with ultraviolet-irradiated HSV type 2 (HSV-2), as well as by HSV type 1 (HSV-1). Medium containing methotrexate, thymidine, adenine, guanosine, and glycine was used to select for cells able to utilize exogenous thymidine. We have determined the kinetics of thermal inactivation of TK from cells lytically infected with HSV-1 or HSV-2 and from HSV-1- and HSV-2-transformed cells. Three hours of incubation at 41 C produces a 20-fold decrease in the TK activity of cell extracts from HSV-2-transformed cells and Ltk(-) cells lytically infected with HSV-2. The same conditions produce only a twofold decrease in the TK activities from HSV-1-transformed cells and cells lytically infected with HSV-1. This finding supports the hypothesis that an HSV structural gene coding for TK has been incorporated in the HSV-transformed cells.     

Glycopeptides of the Type-Common Glycoprotein gD of Herpes Simplex Virus Types 1 and 2

We have carried out detailed structural studies of the glycopeptides of glycoprotein gD of herpes simplex virus types 1 and 2. We first examined and compared the number of N-asparagine-linked oligosaccharides present in each glycoprotein. We found that treatment of either pgD-1 or pgD-2 with endo-β-N-acetylglucosaminidase H (Endo H) generated three polypeptides which migrated more rapidly than pgD on gradient sodium dodecyl sulfate-polyacrylamide gels. Two of the faster-migrating polypeptides were labeled with [³H]mannose, suggesting that both pgD-1 and pgD-2 contained three N-asparagine-linked oligosaccharides. Second, we characterized the [³H]mannose-labeled tryptic peptides of pgD-1 and pgD-2. We found that both glycoproteins contained three tryptic glycopeptides, termed glycopeptides 1, 2, and 3. Gel filtration studies indicated that the molecular weights of these three peptides were approximately 10,000, 3,900, and 1,800, respectively, for both pgD-1 and pgD-2. Three methods were employed to determine the size of the attached oligosaccharides. First, the [³H]mannose-labeled glycopeptides were treated with Endo H, and the released oligosaccharide was chromatographed on Bio-Gel P6. The size of this molecule was estimated to be approximately 1,200 daltons. Second, Endo H treatment of [³⁵S]methionine-labeled glycopeptide 2 reduced the molecular size of this peptide from approximately 3,900 to approximately 2,400 daltons. Third, glycopeptide 2 isolated from the gD-like molecule formed in the presence of tunicamycin was approximately 2,200 daltons. From these experiments, the size of each N-asparagine-linked oligosaccharide was estimated to be approximately 1,400 to 1,600 daltons. Our experiments indicated that glycopeptides 2 and 3 each contained one N-asparagine-linked oligosaccharide chain. Although glycopeptide 1 was large enough to accommodate more than one oligosaccharide chain, the experiments with Endo H treatment of the glycoprotein indicated that there were only three N-asparagine-linked oligosaccharides present in pgD-1 and pgD-2. Further studies of the tryptic glycopeptides by reverse-phase high-performance liquid chromatography indicated that all of the glycopeptides were hydrophobic in nature. In the case of glycopeptide 2, we observed that when the carbohydrate was not present, the hydrophobicity of the peptide increased. The properties of the tryptic glycopeptides of pgD-1 were compared with the properties predicted from the deduced amino acid sequence of gD-1. The size and amino acid composition compared favorably for glycopeptides 1 and 2. Glycopeptide 3 appeared to be somewhat smaller than would be predicted from the deduced sequence of gD-1. It appears that all three potential glycosylation sites predicted by the amino acid sequence are utilized in gD-1 and that a similar number of glycosylation sites are present in gD-2.     

Identification of Rep-Associated Factors in Herpes Simplex Virus Type 1-Induced Adeno-Associated Virus Type 2 Replication Compartments

Adeno-associated virus (AAV) is a human parvovirus that replicates only in cells coinfected with a helper virus, such as adenovirus or herpes simplex virus type 1 (HSV-1). We previously showed that nine HSV-1 factors are able to support AAV rep gene expression and genome replication. To elucidate the strategy of AAV replication in the presence of HSV-1, we undertook a proteomic analysis of cellular and HSV-1 factors associated with Rep proteins and thus potentially recruited within AAV replication compartments (AAV RCs). This study resulted in the identification of approximately 60 cellular proteins, among which factors involved in DNA and RNA metabolism represented the largest functional categories. Validation analyses indicated that the cellular DNA replication enzymes RPA, RFC, and PCNA were recruited within HSV-1-induced AAV RCs. Polymerase δ was not identified but subsequently was shown to colocalize with Rep within AAV RCs even in the presence of the HSV-1 polymerase complex. In addition, we found that AAV replication is associated with the recruitment of components of the Mre11/Rad50/Nbs1 complex, Ku70 and -86, and the mismatch repair proteins MSH2, -3, and -6. Finally, several HSV-1 factors were also found to be associated with Rep, including UL12. We demonstrated for the first time that this protein plays a role during AAV replication by enhancing the resolution of AAV replicative forms and AAV particle production. Altogether, these analyses provide the basis to understand how AAV adapts its replication strategy to the nuclear environment induced by the helper virus.Adeno-associated virus (AAV) is a human parvovirus that is currently used as a gene transfer vector (14). AAV particles consist of a small icosahedral capsid protecting a single 4.7-kb single-stranded DNA (ssDNA) genome with two open reading frames, rep and cap, surrounded by inverted terminal repeats (ITRs). The ITRs are the only sequences required in cis for genome replication and packaging. The rep gene encodes four nonstructural Rep proteins: Rep78, -68, -52, and -40. The two larger isoforms, Rep78 and -68, have origin binding, helicase, and site-specific endonuclease activities and are involved in AAV gene expression and genome processing, including replication and site-specific integration (39). The two smaller Rep isoforms are not required for AAV DNA replication but are involved in the control of viral gene expression and packaging of viral DNA (30).When wild-type (wt) AAV infects a cell in the absence of a helper virus, it enters latency. Latent AAV genomes persist in cells either as episomes or as integrated genomes, preferentially at a specific locus (named AAVS1) on human chromosome 19. In most instances, no detectable viral gene expression or genome replication occurs unless the cell is co- or superinfected by a helper virus, such as adenovirus, herpes simplex virus type 1 (HSV-1), or HSV-2. Under these conditions, AAV replication and assembly take place in large intranuclear domains called replication compartments (RCs) that frequently colocalize with replication domains formed by the helper virus itself (81). The viral genome replicates by leading-strand synthesis and generates new ssDNA molecules by a strand displacement mechanism that occurs after strand- and site-specific cleavage of viral DNA by Rep78/68 within the ITRs (39).Studies conducted on the relationship between AAV and its helper viruses are important not only to identify helper activities that can be used to produce recombinant AAV vectors but also to understand how AAV adapts its replication strategy to the helper virus and to the nuclear environment in general. Adenovirus helper functions have historically been the first and most extensively studied functions. These studies have shown that adenovirus helps AAV by stimulating viral gene expression and by enhancing AAV genome replication, mostly indirectly (19). Indeed, early studies showed that the adenovirus polymerase (E2b) is dispensable for AAV replication (8) and that the viral DNA-binding protein (DBP), the product of the E2a gene, is able to modestly enhance the processivity of AAV genome replication in vitro (77). More recently, the adenovirus proteins E1b55k and E4orf6 were shown to stimulate AAV genome replication by degrading the cellular Mre11/Rad50/Nbs1 (MRN) complex that restricts AAV genome replication during adenovirus coinfection (32). The concept that AAV genome replication can rely mostly, if not uniquely, on direct help from cellular factors was further strengthened by the demonstration that purified proteins such as replication protein A (RPA), replication factor C (RFC), proliferating cell nuclear antigen (PCNA), minichromosome maintenance (MCM) proteins, and DNA polymerase δ (Pol δ) were sufficient to replicate the AAV genome in vitro in the presence of Rep (40-41, 43). The involvement of these cellular proteins during AAV genome replication was also confirmed by the proteomic analysis of factors associated with Rep proteins during adenovirus-induced AAV replication (42).Interestingly, studies conducted on HSV-1 helper activities suggest that the strategy of AAV replication may vary depending on the helper virus. Indeed, previous studies showed that the HSV-1 helicase-primase (HP) complex (UL5/8/52) and DBP (ICP8) could replicate transfected AAV-2 plasmids (80) and that the helicase activity, but not primase activity, of the HP complex was required for this effect (62, 66). More recently, a comprehensive study of HSV-1 helper activities demonstrated that the HSV-1 immediate-early proteins ICP0, ICP4, and ICP22 could stimulate rep gene expression, probably by diminishing intrinsic antiviral effects (1, 18). In addition, the HSV-1 DNA polymerase encoded by UL30, along with its associated processivity factor (UL42), although not strictly required, was demonstrated to significantly increase AAV replication levels induced in the presence of the HP complex and ICP8. Interestingly, the HSV-1 HP complex, DBP, and polymerase were also shown to be sufficient to replicate AAV DNA in vitro in the presence of Rep proteins without any cellular protein (78). Altogether, these observations indicate that in the context of an HSV-1 coinfection, AAV relies extensively on viral activities provided by the helper that directly participate in AAV genome replication.To further elucidate the strategy of AAV replication in the presence of HSV-1, we undertook a proteomic analysis to identify the cellular and HSV-1 factors associated with Rep proteins and, consequently, potentially recruited within AAV RCs. To analyze Rep-associated proteins in the presence and absence of HSV-1 DNA replication, this analysis was performed using wt HSV-1 and an HSV-1 mutant in which the DNA polymerase encoded by the UL30 gene is absent (HSVΔUL30). This study resulted in the identification of approximately 60 cellular proteins, among which the largest functional categories corresponded to factors involved in DNA and RNA metabolism. Immunofluorescence analyses confirmed that in the presence of HSV-1, a basal set of cellular DNA replication enzymes, including RPA, RFC, and PCNA, was recruited within AAV RCs, with the exception of the MCM helicases. The cellular DNA polymerases, in particular Pol δ, were not identified by this analysis but subsequently were shown to be recruited in AAV RCs even in the presence of the HSV-1 polymerase complex. In addition, our results indicate that AAV replication induced by HSV-1 is associated with the recruitment of DNA repair factors, including components of the MRN complex, the Ku proteins, PARP-1, and factors of the mismatch repair (MMR) pathway. Finally, several HSV-1 proteins, most notably the UL12 protein, were also identified within AAV RCs. Our analyses confirmed the association between UL12 and Rep and demonstrated for the first time that this viral exonuclease plays a critical role during AAV replication by enhancing the formation of discrete AAV replicative forms and the production of AAV particles.Altogether, these results indicate that in the presence of HSV-1, AAV may replicate by using a basal set of cellular DNA replication enzymes but also relies extensively on HSV-1-derived proteins for its replication, including UL12, a newly discovered helper factor. These results suggest that AAV may be able to differentially adapt its replication strategy to the nuclear environment induced by the helper virus.     

格尔德霉素抗病毒作用的相关基因研究

格尔德霉素(Geldanamycin,GA)作为一种苯醌安莎霉素类抗生素,能与热休克蛋白90特异性结合,具有广谱的抗病毒作用.为了从转录水平上研究GA抗病毒的分子机制,本研究以单纯疱疹病毒Ⅰ型(Herpes simplex vi-rus type 1,HSV-1)为对象,在确定药物有效抗病毒作用的基础上,采用基因芯片技术分析了在HeLa细胞中病毒感染和药物处理对细胞表达谱的影响,并筛选出GA抗病毒作用的可能相关基因.同时用半定量RT-PCR方法对GA诱导上调、HSV-1诱导下调的基因(ACTG1、RAN、SODl)以及GA诱导下调、HSV-1诱导上调的基因(HYALl)进行了验证.研究GA抗病毒作用对细胞表达谱的影响,有利于深入理解药物的抗病毒机制.     

MEK1-ERKs级联激活方式是调控单纯疱疹病毒Ⅱ型复制的重要机制

本研究通过阐明MEK1和MEK2亚型在单纯疱疹病毒Ⅱ型(herpes simplex virus type 2,HSV2)复制中介导的Raf/MEK/ERK(简称ERK)通路活化中的作用,以期进一步阐明该通路调控病毒复制的机制.研究中应用了MEK抑制剂U0126、针对MEK1和MEK2的特异性小干扰RNA(small ...     

Rapid Identification and Typing of Herpes Simplex Virus Types 1 and 2 by a Direct Immunofluorescence Technique

An immunofluorescence (FA) technique has been developed which can identify herpes simplex virus (HSV) in clinical specimens and also type the virus directly as type 1 or type 2. This test, first applied to cervicovaginal specimens obtained from 80 mice genitally inoculated with HSV, indicated a sensitivity approaching 80% in comparison to standard viral isolation methods. A similar sensitivity was found when the test was applied to 185 clinical specimens with adequate cells for staining, which were obtained from a variety of sites of patients with suspect herpetic infection. In only 1 of 6 specimens positive by both FA and culture methods was the HSV type wrongly identified by the FA technique. There were also six specimens which were negative by culture methods but positive by the FA test, indicating a specificity of 91%. It is likely that these are not instances of false-positive tests but of other factors which may have resulted in negative viral isolations by culture methods. As more specific reagents become available, it is anticipated that the FA technique will have wider usage in diagnostic laboratories for the identification and typing of HSV types 1 and 2.     

Herpes Simplex Virus 1 VP22 Inhibits AIM2-Dependent Inflammasome Activation to Enable Efficient Viral Replication

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细胞周期蛋白依赖性蛋白激酶2在单纯疱疹病毒复制中的作用

细胞周期蛋白依赖性蛋白激酶(CDK)与单纯疱疹病毒(HSV)等多种重要人类疾病病毒的复制密切相关.但具体哪种CDK是病毒复制所必需的还不清楚.本文用不同剂量的HSV-1-KOS株(以下简称HSV)感染CDK2功能缺陷型宿主细胞,结果发现HSV在CDK2功能缺陷型宿主细胞中的复制具有感染剂量依赖性;一步生长曲线分析结果表明其在CDK2功能缺陷型宿主细胞中的复制较在正常细胞延迟3h;感染6h时CDK2活性被诱导,9h时活性最大;CDK2活性增加后HSV-1即进入快速的裂解性复制.提示CDK2可能在HSV复制的启动中起着某种重要作用.