Functional characterization and conformational analysis of the Herpesvirus saimiri Tip-C484 protein.

Tyrosine kinase interacting protein (Tip) of Herpesvirus saimiri (HVS) activates the lymphoid-specific member of the Src family kinase Lck. The Tip:Lck interaction is essential for transformation and oncogenesis in HVS-infected cells. As there are no structural data for Tip, hydrogen-exchange mass spectrometry was used to investigate the conformation of a nearly full-length form (residues 1-187) of Tip from HVS strain C484. Disorder predictions suggested that Tip would be mostly unstructured, so great care was taken to ascertain whether recombinant Tip was functional. Circular dichroism and gel-filtration analysis indicated an extended, unstructured protein. In vitro and in vivo binding and kinase assays confirmed that purified, recombinant Tip interacted with Lck, was capable of activating Lck kinase activity strongly and was multiply phosphorylated by Lck. Hydrogen-exchange mass spectrometry of Tip then showed that the majority of backbone amide hydrogen atoms became deuterated after only 10 s of labeling. Such a result suggested that Tip was almost totally unstructured in solution. Digestion of deuterium-labeled Tip revealed some regions with minor protection from exchange. Overall, it was found that, although recombinant Tip is still functional and capable of binding and activating its target Lck, it is largely unstructured.

Characterization of Lck-binding elements in the herpesviral regulatory Tip protein.

Herpesvirus saimiri encodes a tyrosine kinase interacting protein (Tip) that binds to T-cell-specific tyrosine kinase Lck via multiple sequence motifs and controls its activity. The regulation of Lck by Tip represents a key mechanism in the transformation of human T-lymphocytes during herpesviral infection. In this study, the interaction of Tip with the regulatory SH3 and SH2 domains of Lck was investigated by biophysical and computational techniques. NMR spectroscopy of isotopically labeled Tip(140-191) revealed that the interaction with the LckSH3 domain is not restricted to the classical proline-rich motif, but also involves the C-terminally adjacent residues which pack into a hydrophobic pocket on the surface of the SH3 domain, thus playing a likely role in mediating binding specificity. Fluorescence binding studies of Tip further demonstrate that Tyr127 in its phosphorylated form represents a strong ligand of the LckSH2 domain, indicating the presence of an additional Lck interaction motif. In contrast, Tyr114, known to be essential for STAT-3 binding, does not interact with the LckSH2 domain, showing that the tyrosines in Tip exhibit distinct binding specificity. The existence of numerous interaction sites between Tip and the regulatory domains of Lck implies a complex regulatory mechanism and may have evolved to allow a gradual regulation of Lck activity in different pathogenic states.

Structural investigation of the binding of a herpesviral protein to the SH3 domain of tyrosine kinase Lck.

Herpesvirus saimiri codes for a tyrosine kinase interacting protein (Tip) that interacts with both the SH3 domain and the kinase domain of the T-cell-specific tyrosine kinase Lck via two separate motifs. The activation of Lck by Tip is considered as a key event in the transformation of human T-lymphocytes during herpesviral infection. We investigated the interaction of proline-rich Tip peptides with the LckSH3 domain starting with the structural characterization of the unbound interaction partners. The solution structure of the LckSH3 was determined by heteronuclear multidimensional nuclear magnetic resonance (NMR) spectroscopy using 44 residual dipolar couplings in addition to the conventional experimental restraints. Circular dichroism spectroscopy proved that the polyproline helix of Tip is already formed prior to SH3 binding and is conformationally stable. NMR titration experiments point out three major regions of the Tip-Lck interaction comprising the RT loop, the n-src loop, and a helical turn preceding the last strand of the beta-sheet. Further changes of the chemical shifts were observed for the N- and C-terminal beta-strands of the SH3 domain, indicating additional contacts outside the proline-rich segment or subtle structural rearrangements transmitted from the binding site of the proline helix. Fluorescence spectroscopy shows that Tip binds to the SH3 domains of several Src kinases (Lck, Hck, Lyn, Src, Fyn, Yes), exhibiting the highest affinities for Lyn, Hck, and Lck.

A polycistronic transcript in transformed cells encodes the dihydrofolate reductase of herpesvirus saimiri.

Herpesvirus saimiri, an oncogenic gamma herpesvirus of primates, is the only eukaryotic virus that carries the entire metabolic gene set for a complex biochemical synthesis. Every element of the thymidine synthesis gene cascade is present in the virus, and their function is probably related to the uniquely high A + T content of the genome. Although one member of the gene set, dihydrofolate reductase (DHFR), is mapped in a region required for oncogenesis, very little is known of the expression and function of this gene in transformed cells. We report the expression of the DHFR sequence on a novel, unique tricistronic transcript in virally transformed tumor cells. The DHFR sequence is the first open reading frame on a 5.3 kb minor transcript. Alpha-amanitine sensitivity indicates that it is an RNA polymerase II transcript, and since it is also polyadenylated it appears to be a functional, relatively unstable (half-life 3 hr) mRNA. Initiation of transcription uniquely overlaps with the HSUR3 small RNA gene. Expression of the small transcript appears to be alpha-amanitine resistant, implicating polymerase III transcription. Together with the remarkably low-level expression of HSUR3 in tumor cells, the data may indicate transcription interference between two different RNA polymerases, with unusual overlapping regulation and initiation.

Analysis of nucleotide sequence of the rightmost 43 kbp of herpesvirus saimiri (HVS) L-DNA: general conservation of genetic organization between HVS and Epstein-Barr virus.

We present an analysis of 43,658 bp of contiguous nucleotide sequence comprising the right terminal region (conventional orientation) of the unique protein-coding component (L-DNA) of the herpesvirus saimiri (HVS) genome. Within this region lie the genes encoding the 160-kDa virion protein, which is homologous to the 140-kDa membrane antigen of Epstein-Barr virus (EBV), thymidylate synthase (TS), and the immediate-early (IE) 52-kDa protein which is homologous to the EBV BMLF1 product. The 160-kDa gene of HVS lies at the right terminus of HVS L-DNA, its homologue in EBV occurring at the left terminus of the EBV genome (conventional orientation). The TS gene of HVS occurs within a group of 5 genes that have no homologues in EBV. The translation product of one of these genes, ECRF3, shows amino acid sequence and hydrophobicity pattern similarities to the HCMV and cellular G-protein-coupled receptor family of proteins. Another, ECLF2, is homologous to the cyclin family of cellular proteins. The 5 nonconserved genes lie adjacent to the 160-kDa gene. In EBV, the region to the right of the 140-kDa gene (BNRF1) contains the latent replication origin (OriP) and the open reading frames BCRF1, BWRF1 (repeated 12 times), BYRF1, BHLF1, and BHRF1, counterparts of which are not present in this position in HVS. The subsequent 18 genes in EBV (BFLF2 to BLRF2, approximate positions 56,000-89,500) are represented in HVS, and the relative positions and orientations of these genes are directly comparable between the two viruses. There then occurs a nonhomologous gene in HVS, and genes BLLF2 to BZLF1 (positions 89,500 to 103,200) in EBV which are not present in this region of HVS, before collinearity resumes. Thus, the HVS sequence presented here shows general collinearity between conserved genes in the right terminal region of HVS and the left terminal region of EBV and reveals the presence of two sets of unique genes which occur in exactly analogous positions in HVS and EBV.

trans activation of the thymidylate synthase promoter of herpesvirus saimiri.

Herpesvirus saimiri has been shown to possess a thymidylate synthase (TS) gene that is unusual in its transcriptional regulation. Although TS is believed to be required for viral DNA synthesis, the TS-specific 2.5-kb mRNA was found most abundantly during the late phases of asynchronous virus replication in permissive cultures. To study the kinetics of gene activation, the TS promoter and regulatory sequences were cloned upstream of the chloramphenicol acetyltransferase (CAT) gene. No CAT expression or transcripts were found after transfection of fusion genes into permissive owl monkey kidney (OMK) cells. However, the promoter was strongly activated when CAT plasmids were cotransfected with intact herpesvirus saimiri virion DNA or were transferred to OMK cells that were lytically infected with herpesvirus saimiri or a related herpesvirus, herpesvirus ateles. CAT was expressed at reduced levels in cultures when viral DNA replication was inhibited by phosphonoacetic acid; this indicates that the gene is activated during the delayed-early phase. However, the highest amounts of mRNA were present in the late period of replication. Deletion analyses localized essential response elements for trans activation in the promoter upstream region between nucleotides -311 and -56; they consisted of related tandem repeats and perfect palindromes. A sequence with two overlapping palindromes of 16 and 18 bp was found to be a major target for activation of the herpesvirus saimiri TS promoter. These palindromes did not have any significant homologies with known sequences of herpesviruses or cellular DNA; the 18-bp palindrome had, however, a certain structural similarity with a conserved sequence of the E2-responsive cis sequence that is required for transcription regulation of early papillomavirus genes.

A comparative analysis of the sequence of the thymidine kinase gene of a gammaherpesvirus, herpesvirus saimiri.

We present the nucleotide sequence of a region from the genome of the A + T-rich gammaherpesvirus, herpesvirus saimiri (HVS), which includes the coding sequences for the viral thymidine kinase (TK) gene. The organization of genes in this region resembles the homologous region of the Epstein-Barr virus (EBV) genome and is very compact, using overlapping coding sequences and with nucleotides shared by initiation and termination codons of neighbouring reading frames. The HVS TK is predicted to contain a 527 residue polypeptide with the first part of the presumptive nucleotide-binding site [(L, I, V)(F, Y)(I, L)(D, E)(G)(X)(X)(G)(L, I, V, M)(G)(K)(T, S)(T, S)] located at residues 212 to 224. This motif is close to the amino terminus of the TK polypeptides of alphaherpesviruses and the polypeptides of the cellular and poxvirus-encoded enzymes. The corresponding reading frame of the human gammaherpesvirus (EBV) also has a long amino-terminal extension but significant amino acid sequence similarities between the HVS and EBV sequences are not observed until the region of the nucleotide-binding site. Comparisons of these homologous carboxy-terminal sequences of the HVS- and EBV-encoded proteins with those from six alphaherpes viruses and proteins encoded by Marek's disease virus (MDV) and the herpesvirus of turkeys (HVT) confirm that the HVS and EBV sequences are products of a distinct lineage. The sequences of alphaherpesvirus enzymes than to those of HVS and EBV. Comparison of these 10 highly divergent TK sequences extends and refines the identification of essential features of this family of herpesvirus enzymes and defines 19 positions at which all sequences have identical residues.

A gene for dihydrofolate reductase in a herpesvirus.

The enzyme dihydrofolate reductase (DHFR) is found ubiquitously in both prokaryotes and eukaryotes. It is essential for de novo synthesis of purines and of deoxythymidine monophosphate for DNA synthesis. Among viruses, however, only the T-even and T5 bacteriophage have been found to encode their own DHFR. In this study a gene for DHFR was found in a specific subgroup of the gamma or lymphotropic class of herpesviruses. DNA sequences for DHFR were found in herpesvirus saimiri and herpesvirus ateles but not in Epstein-Barr virus, Marek's disease virus, herpes simplex virus, varicella-zoster virus, herpesvirus tamarinus, or human cytomegalovirus. The predicted sequence of herpesvirus saimiri DHFR is 186 amino acids in length, the same length as human, murine, and bovine DHFR. The human and herpesvirus saimiri DHFRs share 83 percent positional identity in amino acid sequence. The herpesvirus saimiri DHFR gene is devoid of intron sequences, suggesting that it was acquired by some process involving reverse transcription. This is to our knowledge the first example of a mammalian virus with a gene for DHFR.