单纯疱疹病毒致病模型的研究

对单纯疱疹病毒（HSV）感染小白鼠致病特点进行了观察。小白鼠感染HSV第4天后开始发病,感染后2h血液内可分离出病毒,第48小时病毒血症水平和病毒检出率较高。不同组织病毒分布不同,脑、神经节在感染后第72小时病毒滴度较高,心、肝组织在第5天达到高峰。结果说明所建立的HSV致病模型可用于评价抗HSV药物。     

Studies on the Neutralization of Herpes Simplex Virus

Millipore-filtered herpes virus and a hyperimmune rabbit serum were reacted to analyze the unneutralizable persistent fraction (PF). When the PF was serially diluted with antibody-containing diluent, the plaque-formers reduced in number. When the serial dilutions were made with antibody-free diluent, plaque numbers were disproportionately smaller in lower dilutions. The PF filtered through a 0.22μ Millipore membrane showed only a slight loss of infectivity, but a further incubation of the filtrate at 37 C resulted in a marked reduction of titer. This effect was less pronounced when the membrane porosity was larger. Additional virus given to the PF was quickly neutralized by excess antibody. On the other hand, dilution of the virus–serum mixture followed by incubation at 37 C or sonication did not further reactivate the virus. When neutral complexes were sedimented by ultra-centrifugation and resuspended in antibody-free diluent, a partial reactivation slightly exceeding the usual PF level occurred with a concomitant release of antibody. It is proposed that the PF may be free virus resulting from reversible virus-antibody reaction.     

Studies on the Neutralization of Herpes Simplex Virus

Herpes virus was reacted with an early rabbit antiserum containing predominantly complement-requiring neutralizing (CRN) antibody to produce CRN-antibody-sensitized virus (SV), and the action of complement (C') upon SV was studied. Reduction of infectivity due to C' was about equal with undiluted and 1000-fold diluted SV. Even higher dilutions which contained about 10 to 100 infectious units per 0.05 ml were also completely inactivated by C'. Kinetic experiments revealed that the velocity of titer reduction in the presence of C' of 100-fold diluted SV was not slower than that of undiluted SV. When SV was first treated with C' and then diluted 100-fold, the surviving virus showed but a slightly reduced efficiency of filtration through the 0.45 μ Millipore membrane as compared with SV first diluted 1: 100 and then treated with C'. The titer reduction of SV–C'1 complexes in the presence of C'4 followed a one-hit curve. These results indicated that the reduction of infectivity of SV due to C' was not a result of immunoaggregation of infectious SV. Alternative possible mechanisms of the action of C' are discussed.     

Studies on the Neutralization of Herpes Simplex Virus

A portion of the seed virus remained active even in the presence of excess antibody. With an early serum or relatively low concentrations of a hyperimmune serum, the presence of such unneutralizable virus was uncovered by the addition of complement. This unneutralizable persistent fraction (PF) was distinguished from sensitized virus surviving in insufficient antibody, because the latter was inactivated by a high concentration of antibody as quickly as the control virus. The level of the PF was constant regardless of the serum species, serum lot, dilution of serum, antibody class and complement requirement of antibody, being approximately 0.1% of the seed virus. Millipore filtration of the seed virus lowered this PF level to varying degrees depending upon the porosity. However, when filtered virus-serum mixtures were incubated at 37 C for a sufficient time and then filtered again, a portion of the unneutralized virus did pass a 0.22 μ membrane. Furthermore, virus sensitized with insufficient antibody showed no increase in resistance to complement after 10 hr incubation at 4 C. These results proved that viral aggregation was not the essential cause of the PF. It was confirmed, on the other hand, that the neutralization of virus by hyperimmune IgG followed a one-hit curve. Analysis of these data appeared to support Rappaport's postulation that the PF represented antibody-coated virus whose critical antigenic sites were all left unbound.     

Inactivation of Herpes Simplex Virus by Concanavalin A

The infectivity of herpes simplex virus type 1 (HSV-1) was inactivated after treatment with either concanavalin A (ConA) or periodate. Phytohemagglutinin, wheat germ agglutinin, pokeweed mitogen, and neuraminidase failed to inactivate the virus. The effect of ConA could be specifically inhibited or reversed by the addition of α-methyl-d-glucoside or α-methyl-d-mannoside. Evidence was obtained that HSV-1 inactivated by ConA could adsorb to host cells. Viral aggregation was not a major mechanism in the inactivation of HSV-1 by ConA. Under the experimental conditions employed, inactivation of HSV-1 was faster by ConA than by antiserum and less temperature dependent. A ConA-resistant fraction was detected which appeared to adsorb less quickly than untreated virus, and penetration of ConA-resistant fraction was strikingly slow. The presence of aggregates in the virus preparation did not appear to account for the ConA-resistant fraction. Inactivation of viral infectivity by ConA was obtained only with enveloped viruses, since HSV-1, HSV-2, pseudorabies, and vesicular stomatitis virus were inactivated and vaccinia and echovirus type 6 were not.     

Preparation of Type 2 Herpes Simplex Virus Complement-Fixing Antigen

Comparable complement-fixing antigens of type 1 and type 2 herpes simplex virus were produced by extraction of infected African green monkey cells with 0.85% NaCl which was buffered at pH 9.0 with 0.05 m glycine-NaOH. The optimal antigen dilutions were higher in titrations against hyperimmune animal sera than in titrations against human sera. Complement-fixing antibody to type 2 herpes antigen was detected in 5 of 17 sera from healthy humans.     

The Genome Sequence of Herpes Simplex Virus Type 2

The genomic DNA sequence of herpes simplex virus type 2 (HSV-2) strain HG52 was determined as 154,746 bp with a G+C content of 70.4%. A total of 74 genes encoding distinct proteins was identified; three of these were each present in two copies, within major repeat elements of the genome. The HSV-2 gene set corresponds closely with that of HSV-1, and the HSV-2 sequence prompted several local revisions to the published HSV-1 sequence (D. J. McGeoch, M. A. Dalrymple, A. J. Davison, A. Dolan, M. C. Frame, D. McNab, L. J. Perry, J. E. Scott, and P. Taylor, J. Gen. Virol. 69:1531–1574, 1988). No compelling evidence for the existence of any additional protein-coding genes in HSV-2 was identified.The complete 152-kbp genomic DNA sequence of herpes simplex virus type 1 (HSV-1) was published in 1988 (56) and since then has been very widely employed in a great range of research on HSV-1. Additionally, results from this most studied member of the family Herpesviridae have fed powerfully into research on other herpesviruses. In contrast, although a substantial number of individual gene sequences have been determined for the other HSV serotype, HSV-2, the complete genome sequence for this virus has not been available hitherto. In this paper we report the sequence of the genome of HSV-2, strain HG52.At a gross level the 155-kbp genome of HSV-2 is viewed as consisting of two extended regions of unique sequence (U_L and U_S), each of which is bounded by a pair of inverted repeat elements (TR_L-IR_L and IR_S-TR_S) (17, 66) (Fig. ​(Fig.1).1). There is a directly repeated sequence of some 254 bp at the genome termini (the a sequence), with one or more copies in the opposing orientation (the a′ sequence) at the internal joint between IR_L and IR_S (21). U_L plus its flanking repeats is termed the long (L) region, and U_S with its flanking repeats is termed the short (S) region. In individual molecules of HSV-2 DNA, the L and S components may be linked with each in either orientation, so that DNA preparations contain four sequence-orientation isomers, one of which is defined as the prototype (66). The sequences of the terminal and internal copies of R_L and of R_S are considered to be indistinguishable. Open in a separate windowFIG. 1Overall organization of the genome of HSV-2. The linear double-stranded DNA is represented, with the scale at the top. The unique portions of the genome (U_L and U_S) are shown as heavy solid lines, and the major repeat elements (TR_L, IR_L, IR_S, and TR_S) are shown as open boxes. For each pair of repeats the two copies are in opposing orientations. As indicated, TR_L, U_L, and IR_L are regarded as comprising the L region, and IR_S, U_S, and TR_S are regarded as comprising the S region. Plasmid-cloned fragments used for sequence determination are indicated at the bottom: BamHI and HindIII fragments are indicated by B and H, respectively, followed by individual fragment designations in lowercase; KH and HK indicate KpnI/HindIII fragments as described in the text.This paper presents properties of the HSV-2 DNA sequence and our present understanding of its content of protein-coding genes and other elements. We are also interested in comparative analysis of the HSV-1 and HSV-2 genomes to examine processes of molecular evolution which have occurred since the two species diverged, and we intend to pursue this topic in a separate paper.     

Suppression of Herpes Simplex Virus Infection by Phosphonoacetic Acid

Disodium phosphonoacetate when administered orally or topically to mice experimentally infected with herpes simplex virus was able to significantly reduce the mortality associated with the agent. In addition, this compound was able to reduce herpesvirus lesions on the corneas of infected rabbits.     

PKR-Dependent Xenophagic Degradation of Herpes Simplex Virus Type 1

The lysosomal pathway of autophagy is the major catabolic mechanism for degrading long-lived cellular proteins and cytoplasmic organelles. Recent studies have also shown that autophagy (xenophagy) may be used to degrade bacterial pathogens that invade intracellularly. However, it is not yet known whether xenophagy is a mechanism for degrading viruses. Previously, we showed that autophagy induction requires the antiviral eIF2alpha kinase signaling pathway (including PKR and eIF2alpha) and that this function ofeIF2alpha kinase signaling is antagonized by the herpes simplex virus (HSV-1) neurovirulence gene product, ICP34.5. Here, we show quantitative morphologic evidence of PKR-dependent xenophagic degradation of herpes simplex virions and biochemical evidence of PKR and eIF2alpha-dependent degradation of HSV-1 proteins, both of which are blocked by ICP34.5. Together, these findings indicate that xenophagy degrades HSV-1 and that this cellular function is antagonized by the HSV-1 neurovirulence gene product, ICP34.5. Thus, autophagy-related pathways are involved in degrading not only cellular constituents and intracellular bacteria, but also viruses.     

Genome Sequence of Herpes Simplex Virus 1 Strain McKrae

The herpes simplex virus 1 (HSV-1) strain McKrae is highly virulent compared to other wild-type strains of HSV-1. To help us better understand the genetic determinants that lead to differences in the pathogenicity of McKrae and other HSV-1 strains, we sequenced its genome. Comparing the sequence of McKrae's genome to that of strain 17 revealed that the genomes differ by at least 752 single nucleotide polymorphisms (SNPs) and 86 insertion/deletion events (indels). Although the majority of these polymorphisms reside in noncoding regions, 241 SNPs and 10 indels alter the protein-coding sequences of 58 open reading frames. Some of these variations are expected to contribute to the pathogenic phenotype of McKrae.