Anne Cross

A novel ubiquitin‐specific protease is dynamically associated with the PML nuclear domain and binds to a herpesvirus regulatory protein

Herpes simplex virus type 1 immediate‐early protein Vmw110 is a non‐specific activator of gene expression and is required for efficient initiation of the viral lytic cycle. Since Vmw110‐deficient viruses reactivate inefficiently in mouse latency models it has been suggested that Vmw110 plays a role in the balance between the latent and lytic states of the virus. The mechanisms by which Vmw110 achieves these functions are poorly understood. Vmw110 migrates to discrete nuclear structures (ND10) which contain the cellular PML protein, and in consequence PML and other constituent proteins are dispersed. In addition, Vmw110 binds to a cellular protein of ∼135 kDa, and its interactions with the 135 kDa protein and ND10 contribute to its ability to stimulate gene expression and viral lytic growth. In this report we identify the 135 kDa protein as a novel member of the ubiquitin‐specific protease family. The protease is distributed in the nucleus in a micropunctate pattern with a limited number of larger discrete foci, some of which co‐localize with PML in ND10. At early times of virus infection, the presence of Vmw110 increases the proportion of ND10 which contain the ubiquitin‐specific protease. These results identify a novel, transitory component of ND10 and implicate a previously uncharacterized ubiquitin‐dependent pathway in the control of viral gene expression.

Localization of the herpes simplex virus type 1 major capsid protein VP5 to the cell nucleus requires the abundant scaffolding protein VP22a

The intracellular distributions of three herpes simplex virus type 1 (HSV-1) capsid proteins, VP23, VP5 and VP22a, were examined using vaccinia virus and plasmid expression systems. During infection of cells with HSV-1 wild-type virus, all three proteins were predominantly located in the nucleus, which is the site of capsid assembly. However, when expressed in the absence of any other HSV-1 proteins, although VP22a was found exclusively in the nucleus as expected, VP5 and VP23 were distributed throughout the cell. Thus nuclear localization is not an intrinsic property of these proteins but must be mediated by one or more HSV-1-induced proteins. Co-expression experiments demonstrated that VP5 was efficiently transported to the nucleus in the presence of VP22a, but the distribution of VP23 was unaffected by the presence of either or both of the other two proteins.

The products of Herpes Simplex virus type 1 gene UL26 which are involved in DNA packaging are strongly associated with empty but not with full capsids

We report on the properties of a family of related herpes simplex virus type 1 polypeptides (designated p40) of Mr around 40,000. The intracellular localization of these polypeptides has been examined using monoclonal antibodies and their association with viral capsids within the nuclei of infected cells has been demonstrated directly by immunoelectron microscopy. Specific DNA staining and the use of mutants defective for DNA packaging has revealed, in contrast to earlier findings, that p40 is present in empty capsids. Protein p40 is not present as a major component of full capsids or of mature virions indicating that it is transiently associated with capsids and that its removal from capsids is linked with the process of DNA packaging.

An epitope within the DNA-binding domain of the herpes simplex virus immediate early protein Vmw175 is conserved in the varicella-zoster virus gene 62 protein

We have isolated a panel of monoclonal antibodies that recognize the DNA-binding domain of the herpes simplex virus type 1 (HSV-1) immediate early polypeptide Vmw175. The mice used for the fusions had been immunized with the isolated Vmw175 DNA-binding domain. This had been purified from bacteria that carried a phage T7 expression plasmid with the DNA-binding domain coding region. The epitopes recognized by the monoclonal antibodies were mapped by using a family of truncated versions of the DNA-binding domain, which had also been expressed in the bacterial expression system. The monoclonal antibodies divided into at least four different groups according to this mapping. Several of the monoclonal antibodies recognized Vmw175 expressed in infected BHK cells by HSV-1 strain 17 in Western blots. One of them also recognized the corresponding protein of varicella-zoster virus gene 62. This is further illustration of the relatedness of the two polypeptides.

Identification of structural domains within the large subunit of herpes simplex virus ribonucleotide reductase

The large subunit (R1) of herpes simplex virus (HSV) ribonucleotide reductase is a bifunctional protein consisting of a unique N-terminal protein kinase domain and a ribonucleotide reductase domain. Previous studies showed that the two functional domains are linked by a protease sensitive site. Here we provide evidence for two subdomains, of 30K and 53K, within the reductase domain. The two fragments, which were produced by limited proteolysis and were resistant to further degradation, remained tightly associated in a complex containing two molecules of each. They were capable of binding the R2 subunit of HSV ribonucleotide reductase with approximately the same affinity as the intact protein but the complex did not complement the small subunit (R2) to give an active enzyme. At low concentrations (0.4 micrograms/ml) of trypsin or V8 protease, cleavage between the subdomains was prevented by the presence of the N-terminal protein kinase domain. At higher protease concentrations (1 micrograms/ml) the N-terminal domain is extensively proteolysed and the 30K and 53K domains were generated. Identical results were obtained using purified R1 isolated from infected cell extracts or following expression in Escherichia coli. The origin of the two domains was investigated by N-terminal sequencing of the 53K fragment and by examining their reactivity with a panel of R1-specific monoclonal antibodies which we isolated and epitope mapped for that purpose. The trypsin cleavage site was found to lie between arginine 575 and asparagine 576, and proteolysis in this region was not prevented by the presence of R2 or the nonapeptide YAGAVVNDL. We propose that the ribonucleotide reductase region of HSV R1 exists in a two domain structure, and that the interdomain linking region is protected by the unique N terminus.

A single amino acid substitution in the large subunit of herpes simplex virus type 1 ribonucleotide reductase which prevents subunit association

The herpes simplex virus type 1 temperature-sensitive (ts) mutant ts1207 does not induce detectable levels of ribonucleotide reductase activity at the non-permissive temperature (NPT, 39.5 degrees C). The ts lesion prevents the association of the enzymes large (RR1) and small (RR2) subunits to give an active holoenzyme and maps within the gene specifying RR1. Here, it is shown that the ts mutant phenotype is due to the substitution of an asparagine for the wild-type (wt) serine at RR1 position 961, which is located within a region highly conserved between herpesviral and cellular RR1 subunit polypeptides. This ts1207 asparagine is predicted to alter a wt alpha-helix to a beta-strand. We have used synthetic oligopeptides, corresponding to the wt amino acid sequence of the mutation site, and antisera raised against them to determine whether this region is involved in subunit association. Neither the oligopeptides nor the antisera inhibit the enzyme activity, or the reconstituted activity formed by mixing intact RR2 and RR1 subunits present in partially purified extracts of cells infected at the NPT with ts1207 or ts1222 (an HSV-1 mutant with a lesion in the RR2 subunit), respectively. We infer from these results that the site of the mutation is unlikely to be positioned at the surface of RR1 and hence is probably not directly involved in subunit association. We suggest that the mutation site identifies an important RR1 region whose alteration in ts1207 changes the structure of a contact region(s) positioned at the RR1/RR2 interface.

Epitope mapping identifies an exposed loop between the unique amino- and conserved carboxy-domains of the large subunit of herpes simplex virus type 1 ribonucleotide reductase

The large subunits of herpes simplex virus types 1 and 2 ribonucleotide reductases contain unique amino-terminal regions comprising 311 and 318 residues respectively, which are not found in ribonucleotide reductases from other sources. We report the mapping of the epitope recognized by monoclonal antibody 1026, which is specific for the large subunit (R1) of HSV-1, and then deduce the structural relationship of the amino-terminal region of R1 with the rest of the protein. A panel of 10 fusion proteins containing sequences spanning the entire R1 subunit were constructed. They were used together with proteolytic fragments of R1 and several synthetic peptides to show that the epitope is discontinuous and appears to be a loop structure centered on a previously located trypsin-sensitive site at residue 305. The existence of the loop was suggested by the observation that reactivity of the antibody with R1 could be blocked by peptides corresponding to residues 289 to 303 and 308 to 313 which flank the trypsin-sensitive site. Our results suggest that the unique amino-terminal region of R1 consists of a structurally distinct domain which is linked to the conserved carboxy region by an exposed loop.