Stimulation of expression of a herpes simplex virus DNA-binding protein by two viral functions.

We examined the expression and localization of herpesvirus proteins in monkey cells transfected with recombinant plasmids containing herpes simplex virus (HSV) DNA sequences. Low levels of expression of the major HSV DNA-binding protein ICP8 were observed when ICP8-encoding plasmids were introduced into cells alone. ICP8 expression was greatly increased when a recombinant plasmid encoding the HSV alpha (immediate-early) ICP4 and ICP0 genes was transfected with the ICP8 gene. Deletion and subcloning analysis indicated that two separate functions capable of stimulating ICP8 expression were encoded on the alpha gene plasmid. One mapped in or near the ICP4 gene, and one mapped in or near the ICP0 gene. Their stimulatory effects were synergistic when introduced on two separate plasmids. Thus, two separate viral functions can activate herpesvirus early gene expression in transfected cells.     

DNA-binding properties of a herpes simplex virus immediate early protein

The herpes simplex virus alpha, or immediate early, protein ICP4 has been shown to be central to the control of the early stages of virus replication. The detailed mechanism of this control is unknown. In this communication we show that purified ICP4 was unable to bind to DNA even though the protein was capable of such activity in a crude extract. Addition of either infected- or uninfected-cell extracts to the purified protein restored its DNA-binding activity. These results suggest that ICP4 binds to DNA only via a component of uninfected cells.     

In vitro characterization of a thermolabile herpes simplex virus DNA-binding protein.

The major herpes simplex virus DNA-binding protein, ICP8, was purified from cells infected with the herpes simplex virus type 1 temperature-sensitive strain tsHA1. tsHA1 ICP8 bound single-stranded DNA in filter binding assays carried out at room temperature and exhibited nonrandom binding to single-stranded bacteriophage fd DNA circles as determined by electron microscopy. The filter binding assay results and the apparent nucleotide spacing of the DNA complexed with protein were identical, within experimental error, to those observed with wild-type ICP8. Thermal inactivation assays, however, showed that the DNA-binding activity of tsHA1 ICP8 was 50% inactivated at approximately 39 degrees C as compared with 45 degrees C for the wild-type protein. Both wild-type and tsHA1 ICP8 were capable of stimulating viral DNA polymerase activity at permissive temperatures. The stimulatory effect of both proteins was lost at 39 degrees C.     

DNA-binding protein associated with herpes simplex virus DNA polymerase.

Purified preparations of herpes simplex virus type 2 DNA polymerase made by many different laboratories always contain at least two polypeptides. The major one, of about 150,000 molecular weight, has been associated with the polymerase activity. The second protein, of about 54,000 molecular weight, which we previously designated ICSP 34, 35, has now been purified. The purified protein has been used to prepare antisera (both polyclonal rabbit serum and monoclonal antibodies). These reagents have been used to characterize the protein, to demonstrate its quite distinct map location from that of the DNA polymerase on the herpes simplex virus genome, and to demonstrate the close association between the two polypeptides.     

Intragenic complementation of herpes simplex virus ICP8 DNA-binding protein mutants.

The major DNA-binding protein, or infected-cell protein 8 (ICP8), of herpes simplex virus is required for viral DNA synthesis and normal regulation of viral gene expression. Previous genetic analysis has indicated that the carboxyl-terminal 28 residues are the only portion of ICP8 capable of acting independently as a nuclear localization signal. In this study, we constructed a mutant virus (n11SV) in which the carboxyl-terminal 28 residues of ICP8 were replaced by the simian virus 40 large-T-antigen nuclear localization signal. The n11SV ICP8 localized into the nucleus and bound to single-stranded DNA in vitro as tightly as wild-type ICP8 did but was defective for viral DNA synthesis and viral growth in Vero cells. Two mutant ICP8 proteins (TL4 and TL5) containing amino-terminal alterations could complement the n11SV mutant but not ICP8 gene deletion mutants. Cell lines expressing TL4 and TL5 ICP8 were isolated, and in these cells, complementation of n11SV was observed at the levels of both viral DNA replication and viral growth. Therefore, complementation between n11SV ICP8 and TL4 or TL5 ICP8 reconstituted wild-type ICP8 functions. Our results demonstrate that (i) the carboxyl-terminal 28 residues of ICP8 are required for a function(s) involved in viral DNA replication, (ii) this function can be supplied in trans by another mutant ICP8, and (iii) ICP8 has multiple domains possessing different functions, and at least some of these functions can complement in trans.     

The major herpes simplex virus type-1 DNA-binding protein is a zinc metalloprotein.

The primary amino acid sequence of the major herpes simplex virus type 1 (HSV-1)-infected cell polypeptide 8 (ICP8) deduced from the DNA sequence of the unique long open reading frame 29 (UL29 ORF) contains a potential metal-binding domain of the form Cys-X2-5-Cys-X2-15-A-X2-4-A where A may be either histidine or cysteine and X is any amino acid. The putative metal-binding sequence in ICP8 encompasses residues 499-512 as follows: C-N-L-C-T-F-D-T-R-H-A-C-V-H-. Atomic absorption analysis of several preparations of ICP8 indicates the presence of 1 mol of zinc/mol of protein. The zinc is resistant to removal by dialysis against concentrations of EDTA which deplete zinc from alcohol dehydrogenase. The bound zinc can be removed by reaction with the reversible sulfhydryl reagent p-hydroxymercurimethylsulfonate and the zinc-depleted protein transiently retains DNA binding activity. Digestion of both native and zinc-depleted ICP8 with V8 protease indicates that the bound zinc is required for the structural integrity of the protein.     

Association between the herpes simplex virus major DNA-binding protein and alkaline nuclease.

Herpes simplex virus encodes seven proteins which have been shown to be both necessary and sufficient for in vitro replication of origin-containing plasmids. We have shown previously that one of these proteins, the major DNA-binding protein mDBP, forms a complex with alkaline nuclease, which is not one of the seven essential proteins. In this study, we have employed immunological reagents and a series of deletion mutants to investigate this complex further. We have determined the regions of mDBP which are important in the formation of this complex, and we have shown that the intranuclear locations of alkaline nuclease and major DNA-binding protein overlap.     

N-ethylmaleimide inhibition of the DNA-binding activity of the herpes simplex virus type 1 major DNA-binding protein.

The major herpes simplex virus DNA-binding protein, designated ICP8, binds tightly to single-stranded DNA and is required for replication of viral DNA. The sensitivity of the DNA-binding activity of ICP8 to the action of the sulfhydryl reagent N-ethylmaleimide has been examined by using nitrocellulose filter-binding and agarose gel electrophoresis assays. Incubation of ICP8 with N-ethylmaleimide results in a rapid loss of DNA-binding activity. Preincubation of ICP8 with single-stranded DNA markedly inhibits this loss of binding activity. These results imply that a free sulfhydryl group is involved in the interaction of ICP8 with single-stranded DNA and that this sulfhydryl group becomes less accessible to the environment upon binding. Agarose gel electrophoretic analysis of the binding interaction in the presence and absence of N-ethylmaleimide indicates that the cooperative binding exhibited by ICP8 is lost upon treatment with this reagent but that some residual noncooperative binding may remain. This last result was confirmed by equilibrium dialysis experiments with the 32P-labeled oligonucleotide dT10 and native and N-ethylmaleimide-treated ICP8.     

An immunoassay for the study of DNA-binding activities of herpes simplex virus protein ICP8.

An immunoassay was used to examine the interaction between a herpes simplex virus protein, ICP8, and various types of DNA. The advantage of this assay is that the protein is not subjected to harsh purification procedures. We characterized the binding of ICP8 to both single-stranded (ss) and double-stranded (ds) DNA. ICP8 bound ss DNA fivefold more efficiently than ds DNA, and both binding activities were most efficient in 150 mM NaCl. Two lines of evidence indicate that the binding activities were not identical: (i) ds DNA failed to complete with ss DNA binding even with a large excess of ds DNA; (ii) Scatchard plots of DNA binding with various amounts of DNA were fundamentally different for ss DNA and ds DNA. However, the two activities were related in that ss DNA efficiently competed with the binding of ds DNA. We conclude that the ds DNA-binding activity of ICP8 is probably distinct from the ss DNA-binding activity. No evidence for sequence-specific ds DNA binding was obtained for either the entire herpes simplex virus genome or cloned viral sequences.     

A new microplate neutralization test for typing of herpes simplex virus.

A microplate serum neutralization test for estimation of complement-requiring neutralizing (CRN) antibody was established as the first step for simplification of typing of herpes simplex virus (HSV). When guinea pigs were immunized with type 2 HSV, the late sera could mostly differentiate the types of HSV better than hyperimmune rabbit sera, the CRN titer against the heterologous type 1 HSV being much lower than the homologous titer. Sera of guinea pigs immunized with type 1 HSV showed about the same level of cross reaction against type 2 HSV as did rabbit antisera. Guinea pig sera having minimal levels of cross reaction were selected, and their high dilution (1:160) and complement were added to serial 10-fold dilutions of virus in the microplate titration of virus infectivity. Selective reduction of virus titer by either antiserum could determine the type of HSV. No equivocal intermediate case was found among a number of stock strains including many fresh isolates. The typing result coincided with that determined by a modification of Yang et al's method based on virus titers obtained with Vero and primary chick embryo cells. The typing based on plaquing in chick embryo cells sometimes failed to identify type 1 HSV.     

Genetic evidence for multiple nuclear functions of the herpes simplex virus ICP8 DNA-binding protein

We have isolated several mutant herpes simplex viruses, specifically mutated in the infected cell protein 8 (ICP8) gene, to define the functional domains of ICP8, the major viral DNA-binding protein. To facilitate the isolation of these mutants, we first isolated a mutant virus, HD-2, with the lacZ gene fused to the ICP8 gene so that an ICP8-beta-galactosidase fusion protein was expressed. This virus formed blue plaques on ICP8-expressing cell lines in the presence of 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside. Mutated ICP8 gene plasmids cotransfected with HD-2 DNA yielded recombinant viruses with the mutant ICP8 gene incorporated into the viral genome. These recombinants were identified by formation of white plaques. Four classes of mutants were defined: (i) some expressed ICP8 that could bind to DNA but could not localize to the cell nucleus; (ii) some expressed ICP8 that did not bind to DNA but localized to the nucleus; (iii) some expressed ICP8 that neither bound to DNA nor localized to the nucleus; and (iv) one expressed ICP8 that localized to the cell nucleus and bound to DNA in vitro, but the mutant virus did not replicate its DNA. These classes of mutants provide genetic evidence that DNA binding and nuclear localization are distinct functions of ICP8 and that ICP8 has nuclear functions other than binding to DNA. Furthermore, the portion of ICP8 needed for a nuclear function(s) distinct from DNA binding is the part of ICP8 showing sequence similarity to that of the cellular protein cyclin or proliferating cell nuclear antigen.     

Characterization of a major DNA-binding domain in the herpes simplex virus type 1 DNA-binding protein (ICP8).

We have studied the major DNA-binding protein (ICP8) from herpes simplex virus type 1 to identify its DNA-binding site. Since we obtained our protein from a cell line carrying multiple chromosomally located copies of the ICP8 gene, we first analyzed this protein to assess its similarity to the corresponding viral protein. Our protein resembled the viral protein by molecular weight, response to antibody, preference for binding single-stranded DNA, and ability to lower the melting temperature of poly(dA-dT). To define the DNA-binding domain, we subjected the protein to limited trypsin digestion and separated the peptide products on a sodium dodecyl sulfate-polyacrylamide gel. These fragments were then transferred to a nitrocellulose membrane, renatured in situ, and tested for their ability to bind DNA. From this assay, we identified four fragments which both bound DNA and exhibited the expected binding preference for single-stranded DNA. The sequence of the smallest of these fragments was determined and corresponds to a polypeptide spanning residues 300 to 849 in the intact protein. This peptide contains several regions which may be important for DNA binding based on sequence similarities in single-stranded DNA-binding proteins from other herpesviruses and, in one case, on a conserved sequence found in more distant procaryotic and eucaryotic proteins.     

The essential 65-kilodalton DNA-binding protein of herpes simplex virus stimulates the virus-encoded DNA polymerase.

The 65-kilodalton DNA-binding protein (65KDBP) of herpes simplex virus type 1 (HSV-1), the product of the UL42 gene, is required for DNA replication both in vitro and in vivo, yet its actual function is unknown. By two independent methods, it was shown that the 65KDBP stimulates the activity of the HSV-1-encoded DNA polymerase (Pol). When Pol, purified from HSV-1-infected cells, was separated from the 65KDBP, much of its activity was lost. However, addition of the 65KDBP, purified from infected cells, stimulated the activity of Pol 4- to 10-fold. The ability of a monoclonal antibody to the 65KDBP to remove the Pol-stimulating activity from preparations of the 65KDBP confirmed that the activity was not due to a trace contaminant. Furthermore, the 65KDBP did not stimulate the activity of other DNA polymerases derived from T4, T7, or Escherichia coli. The 65KDBP gene transcribed in vitro from cloned DNA and translated in vitro in rabbit reticulocyte lysates also was capable of stimulating the product of the pol gene when the RNAs were cotranslated. The product of a mutant 65KDBP gene missing the carboxy-terminal 28 amino acids exhibited wild-type levels of Pol stimulation, while the products of two large deletion mutants of the gene could not stimulate Pol activity. These experiments suggest that the 65KDBP may be an accessory protein for the HSV-1 Pol.     

Thermolabile in vivo DNA-binding activity associated with a protein encoded by mutants of herpes simplex virus type 1.

The major DNA-binding protein encoded by several temperature-sensitive mutants of herpes simplex virus type 1 was thermolabile for binding to intracellular viral DNA. The ability of DNase I to release this protein from isolated nuclei was used as a measure of the amount of protein bound to viral DNA. This assay was based upon our previous observation that the fraction of herpesviral DNA-binding protein which can be eluted from nuclei with DNase I represents proteins associated with progeny viral DNA (D. M. Knipe and A. E. Spang, J. Virol. 43:314-324, 1982). In this study, we found that several temperature-sensitive mutants encoded proteins which rapidly chased from a DNase I-sensitive to a DNase I-resistant nuclear form upon shift to the nonpermissive temperature. We interpret this change in DNase I sensitivity to represent the denaturation of the DNA-binding site at the nonpermissive temperature and the association with the nuclear framework via a second site on the protein. The DNA-binding activity measured by the DNase I sensitivity assay represents an important function of the protein in viral replication because three of five mutants tested were thermolabile for this activity. A fourth mutant encoded a protein which did not associate with the nucleus at the nonpermissive temperature and therefore would not be available for DNA binding in the nucleus. We also present supportive evidence for the binding of the wild-type protein to intracellular viral DNA by showing that a monoclonal antibody coprecipitated virus-specific DNA sequences with the major DNA-binding protein.