Herpes simplex virus induces the replication of foreign DNA

Temperature-sensitive origin-binding protein as a tool for investigations of herpes simplex virus activities in vivo

While it is fairly clear that herpes simplex virus (HSV) DNA replication requires at least seven virus-encoded proteins in concert with various host cell factors, the mode of this process in infected cells is still poorly understood. Using HSV-1 mutants bearing temperature-sensitive (ts) lesions in the UL9 gene, we previously found that the origin-binding protein (OBP), a product of the UL9 gene, is only needed in the first 6 hours post-infection. As this finding was just a simple support for the hypothesis of a biphasic replication mode, we became convinced through these earlier studies that the mutants tsR and tsS might represent suitable tools for more accurate investigations in vivo. However, prior to engaging in highly sophisticated research projects, knowledge of the biochemical features of the mutated versions of OBP appeared to be essential. The results of our present study demonstrate that (i) tsR is most appropriate for cell biological studies, where only immediate early and early HSV gene products are being expressed without the concomital viral DNA replication, and (ii) tsS is a prime candidate for the analysis of HSV DNA replication processes because of its reversibly thermosensitive OBP-ATPase, which allows one to switch on the initiation of DNA synthesis precisely.

Structure of simian virus 40 DNA replicated by herpes simplex virus type 1

Replicating herpes simplex virus type 1 (HSV-1) DNA is known to form large branched structures. The aim of this study was to define whether HSV-1-specific DNA elements in cis play a critical role in formation of this structure. We did this by investigating the structure of heterologous simian virus 40 (SV40) DNA, which is replicated in HSV-infected cells by SV40 large T-antigen and defined HSV-encoded replication factors (e.g., DNA polymerase, single-stranded DNA-binding protein, and helicase-primase). During this process, extrachromosomal concatemeric DNA replication products are formed, indicating a herpesvirus-specific replication mode. In this study, we found that the replicating SV40 DNA consisted of a complex branched structure indistinguishable from that of replicating HSV DNA. Thus, no HSV-specific DNA element is necessary in cis for the formation of the large branched structure during HSV DNA replication. The trans-acting HSV DNA replication proteins seem to be sufficient to generate these complex structures. Moreover, replicating SV40 DNA showed a high frequency of homologous recombination events, which is typical for HSV DNA replication. However, in contrast to HSV origin-bearing amplicon plasmids, SV40 plasmids bearing the HSV cleavage-packaging signal were not efficiently processed to linear 150-kb DNA packaged into HSV capsids. This indicates that initiation of DNA synthesis on HSV-ori determines some, yet undefined, property of replicating HSV DNA, which is crucial for regular processing of the replication intermediates to daughter genomes.

Sequence elements of the adeno-associated virus rep gene required for suppression of herpes-simplex-virus-induced DNA amplification

Herpes simplex virus (HSV) has been shown to induce DNA amplification in the host cell genome, which can be suppressed by the adeno-associated virus type 2 (AAV-2) rep gene (Heilbronn et al., 1990, J. Virol. 64, 3012-3018). In an attempt to define domains of Rep which are required for this effect a set of expression constructs was generated for Rep mutants with either N-terminal and/or C-terminal truncations, with small internal deletions, or with point mutations. In transient cotransfection assays these mutants were tested for the inhibition of HSV-induced DNA amplification and in parallel for DNA replication of a rep-defective AAV genome. Our data show that the C-terminal region of Rep where spliced and unspliced proteins differ is dispensable for both AAV DNA replication and inhibition of HSV-induced DNA amplification. The N-terminus of Rep is required for AAV DNA replication, whereas the first 174 amino acids can be deleted without loss of function for the inhibition of DNA amplification. Rep52 which starts at methionine 225 is neither sufficient, nor required for this effect. We further analyzed the region between amino acids 174 and 225: A stretch of 16 highly hydrophilic amino acids is dispensable for the inhibition of DNA amplification, but it is required for AAV DNA replication. Deletion of two short motifs spanning putative protein kinase C phosphorylation sites each strongly reduce both AAV DNA replication and inhibition of DNA amplification, whereas a single amino acid substitution of one of these sites abolished AAV DNA replication with no effect on the inhibition of DNA amplification. Our data show that most, but not all, of the sequence elements within the N-terminus of Rep78 required for AAV DNA replication coincide with those required for the inhibition of HSV-induced DNA amplification. A replication-negative version of Rep78 comprising the internal 60% of the protein still carry the entire inhibitory function for HSV-induced DNA amplification.

Herpes simplex virus induces unscheduled DNA synthesis in virus-infected cervical cancer cell lines

We evaluated herpes-simplex-virus-type-2(HSV2)-induced unscheduled DNA synthesis in virus-infected cervical cancer (HeLa, CaSki, C-33A, and SiHa) cells. HSV2 replication was approximately 100-fold more efficient in the HeLa cells than in less susceptible C-33A and SiHa cells. In dual parameter flow cytometric analysis of bromodeoxyuridine (BrdU) incorporation, HSV2-infected HeLa cells showed a rapid increase in the proportions of DNA-synthesizing G1- and S-phase cells, whereas in C-33A and SiHa cells, the proportions of DNA-synthesizing G1- and early S-phase cells were increased late in the infection. Blocking of HSV2 replication by phosphonoformate inhibited virus-induced changes in HeLa cells, but not in C-33A and SiHa cells. Anti-BrdU antibodies exhibited a coarse globular nuclear staining pattern in the C-33A cells, while the other cells showed speckled and/or fine globular nuclear fluorescence. Anti-ICP8 (HSV-specified major DNA-binding protein) antibodies revealed that, in C-33A cells, ICP8 remained in the cytoplasm, whereas in the other cells, speckled or globular nuclear fluorescence was found. Our results showed that HSV2 induced the unscheduled synthesis of cellular DNA, which was host-cell-dependent, and in virus infected C-33A cells, it may be attributable to both viral and cellular proteins.

DNA sequence of mutations induced in cells by herpes simplex virus type-1

The shuttle vector plasmid pZ189 was used to find the kinds of mutations that are induced in cells by herpes simplex virus type-1 (HSV-1). A significant increase in mutation frequency was detected as early as 2 hr after infection, and reached a peak of two- to sevenfold over background at 4 hr after infection. Several differences were detected between spontaneous mutants and those induced by HSV-1 when they were analyzed by gel electrophoresis and DNA sequencing. Point mutations accounted for 63% of spontaneous mutants but for only 44% of HSV-1-induced mutants (P less than 0.05). In each case the predominant type of point mutation was the G:C to A:T transition, which comprised 51% of point mutations induced by HSV-1, and 32% of spontaneous point mutations. Deletions of DNA were seen in HSV-1-induced mutants at a frequency of 44%, compared with only 29% in spontaneous mutants. HSV-1-induced deletions were less than half the length of spontaneous deletions, and 3 contained short filler sequences. An increase in size was seen in 13% of HSV-1-induced mutants and was due either to duplication of plasmid DNA, or, in 8 instances, to insertion of sequences derived from cellular DNA. Among spontaneous mutants, only 8% were increased in size and none of them had inserted cellular DNA. The proportion of complex mutants increased as infection by the virus progressed and they accounted for 79% of mutants at 24 hr after infection. The observed mutations have implications for understanding the "hit and run" mechanism of malignant transformation of cells by HSV-1.

Herpes simplex virus-induced "rolling circle" amplification of SV40 DNA sequences in a transformed hamster cell line correlates with tandem integration of the SV40 genome

Infection with herpes simplex virus leads to amplification of SV40 DNA in various SV40-transformed cells. In earlier studies with the SV40-transformed hamster cell line Elona two different types of DNA amplification could be identified: (i) Bidirectional overreplication of chromosomally integrated SV40 DNA expanding into the flanking cellular sequences ("onion skin" type) and (ii) highly efficient synthesis of extremely large head-to-tail concatemers containing exclusively SV40 DNA ("rolling circle" type). These investigations have indicated that the chromosomally integrated form of SV40 might be the substrate for both types of overreplication. There still had been uncertainties as to whether and how these events were connected. A hypothetical assumption of a recombinational event leading to the excision of SV40 DNA molecules is supported by the results presented here: In this study cloned Elona cell lines were investigated for their ability to amplify SV40 sequences and for the mechanism of amplification utilized. SV40 integration in a partial tandem manner correlates with a strong rolling circle amplification. In contrast, in one cell line harboring a truncated SV40 genome, amplification appears mainly restricted to intrachromosomal bidirectional overreplication. Possible implications for HSV functions involved in the amplification process will be discussed.

The role of viral and cellular nuclear proteins in herpes simplex virus replication

Following infection of cells by herpes simplex virus, the cell nucleus is subverted for transcription and replication of the viral genome and assembly of progeny nucleocapsids. The transition from host to viral transcription involves viral proteins that influence the ability of the cellular RNA polymerase II to transcribe a series of viral genes. The regulation of RNA polymerase II activity by viral gene products seems to occur by several different mechanisms: (1) viral proteins complex with cellular proteins and alter their transcription-promoting activity (e.g., alpha TIF), (2) viral proteins bind to specific DNA sequences and alter transcription (e.g., ICP4), and (3) viral proteins affect the posttranslational modification of viral or cellular transcriptional regulatory proteins (e.g., possibly ICP27). Thus, HSV may utilize several different approaches to influence the ability of host-cell RNA polymerase II to transcribe viral genes. Although it is known that viral transcription uses the host-cell polymerase II, it is not known whether viral infection causes a change in the structural elements of the nucleus that promote transcription. In contrast, HSV encodes a new DNA polymerase and accessory proteins that complex with and reorganize cellular proteins to form new structures where viral DNA replication takes place. HSV may encode a large number of DNA replication proteins, including a new polymerase, because it replicates in resting cells where these cellular gene products would never be expressed. However, it imitates the host cell in that it localizes viral DNA replication proteins to discrete compartments of the nucleus where viral DNA synthesis takes place. Furthermore, there is evidence that at least one specific viral gene protein can play a role in organizing the assembly of the DNA replication structures. Further work in this system may determine whether assembly of these structures is essential for efficient viral DNA replication and if so, why assembly of these structures is necessary. Thus, the study of the localization and assembly of HSV DNA replication proteins provides a system to examine the mechanisms involved in morphogenesis of the cell nucleus. Therefore, several critical principles are apparent from these discussions of the metabolism of HSV transcription and DNA replication. First, there are many ways in which the activity of RNA polymerase II can be regulated, and HSV proteins exploit several of these in controlling the transcription of a single DNA molecule. Second, the interplay of these multiple regulatory pathways is likely to control the progress of the lytic cycle and may play a role in determining the lytic versus latent infection decision.(ABSTRACT TRUNCATED AT 400 WORDS)