Characterization of a soluble stable human cytomegalovirus protease and inhibition by M-site peptide mimics.

The human cytomegalovirus (HCMV) protease is a potential target for antiviral chemotherapeutics; however, autoprocessing at internal sites, particularly at positions 143 and 209, hinders the production of large quantities of stable enzyme for either screening or structural studies. Using peptides encompassing the sequence of the natural M-site substrate (P5-P5', GVVNA/SCRLA), we previously demonstrated that substitution of glycine for valine at the P3 position in the substrate abrogates processing by the recombinant protease in vitro. We now demonstrate that introduction of the V-to-G substitution in the P3 positions of the two major internal processing sites, positions 143 and 209, in the mature HCMV protease renders the enzyme stable to autoprocessing. When expressed in Escherichia coli, the doubly substituted protease was produced almost exclusively as the 30-kDa full-length protein. The full-length V141G, V207G (V-to-G changes at positions 141 and 207) protease was purified as a soluble protein by a simple two-step procedure, ammonium sulfate precipitation followed by DEAE ion-exchange chromatography, resulting in 10 to 15 mg of greater than 95% pure enzyme per liter. The stabilized enzyme was characterized kinetically and was indistinguishable from the wild-type recombinant protease, exhibiting Km and catalytic constant values of 0.578 mM and 13.18/min, respectively, for the maturation site (M-site) peptide substrate, GVVNASCRLARR (underlined residues indicate additions to or substitutions from peptides derived from the wild-type substrate). This enzyme was also used to perform inhibition studies with a series of truncated and/or substituted maturation site peptides. Short nonsubstrate M-site-derived peptides were demonstrated to be competitive inhibitors of cleavage in vitro, and these analyses defined amino acids VVNA, P4 through P1 in the substrate, as the minimal substrate binding and recognition sequence for the HCMV protease.

Inhibition of human immunodeficiency virus integrase by bis-catechols.

The human immunodeficiency virus type 1 (HIV-1) integrase protein is required for the productive infection of T-lymphoid cells in culture (R. L. LaFemina, C. L. Schneider, H. L. Robbins, P. L. Callahan, K. LeGrow, E. Roth, W. A. Schleif, and E. A. Emini, J. Virol. 66:7414-7419, 1992). This observation suggests that chemical inhibitors of integrase may prevent the spread of HIV in infected individuals. In our search for such potential chemotherapeutic agents, we observed that beta-conidendrol inhibits both the sequence-dependent and sequence-independent endonucleolytic activities of integrase with comparable potencies in vitro (50% inhibitory concentration, 500 nM). Structurally related compounds tested for their abilities to inhibit integrase generated a limited structure-activity analysis which demonstrated that potency is associated with the bis-catechol structure: two pairs of adjacent hydroxyls on separate benzene rings. beta-Conidendrol did not inhibit several other endonucleases and/or phosphoryltransferases. Although beta-conidendrol was not effective in preventing HIV-1 infection in cell culture, the in vitro data demonstrate that it is possible to identify selective agents targeted against this essential HIV-1 function.

Purification of active herpes simplex virus-1 protease expressed in Escherichia coli.

Assembly of viral capsids for replication of herpes simplex virus requires the proteolytic processing of the assembly protein ICP35. The protease responsible for this process is encoded within the 635-amino acid open reading frame of the UL26 gene of the virus. A simple purification scheme is given in this report for the native, mature form of the protease expressed in Escherichia coli. The scheme allows the preparation of milligram quantities of purified enzyme for elucidation of kinetic mechanism as well as for structural studies. Utilizing a 13-residue peptide substrate representing the natural cleavage site that releases the protease, kcat and Km values of the purified native enzyme are 2.0 min-1 and 0.88 mM, respectively. Thus, peptide cleavage is less efficient than reported for other viral proteases. The possibility exists that viral or cellular factors are involved in vivo for activation of the protease for herpes capsid maturation.

Peptide substrate cleavage specificity of the human cytomegalovirus protease.

The human cytomegalovirus UL80 gene encodes an 80-kDa precursor polyprotein whose N-terminal 256-amino acid domain is a protease. This enzyme cleaves a specific peptide bond that results in its own release from the precursor, as well as a peptide bond near the C terminus of the viral assembly protein. The latter cleavage is apparently required for encapsidation of the viral genomic DNA and maturation of the viral capsid. A series of peptide substrates, representing the assembly protein cleavage site, was used to study the enzyme's substrate requirements and specificity. It was found that efficient cleavage minimally required the amino acid residues spanning the P4 to P4' positions. Substitution at any of these residues adversely affected the reaction. Conservation of the hydrophobic residues at P3 and P4 was essential. In addition, cleavage of a peptide representing the protease domain release site was reduced almost 100-fold relative to cleavage of the assembly protein maturation site peptide substrate.

Human immunodeficiency virus type 1 protease inhibitors: evaluation of resistance engendered by amino acid substitutions in the enzyme's substrate binding site.

The human immunodeficiency virus type 1 (HIV-1) protease is a homodimeric aspartyl endopeptidase that is required for virus replication. A number of specific, active-site inhibitors for this enzyme have been described. Many of the inhibitors exhibit significant differences in activity against the HIV-1 and HIV type 2 (HIV-2) enzymes. An initial study was conducted to ascertain the HIV-1 protease's potential to lose sensitivity to several test inhibitors while retaining full enzymatic activity. The substrate binding sites of the HIV-1 and HIV-2 enzymes are almost fully conserved, except for four amino acid residues at positions 32, 47, 76, and 82. Accordingly, recombinant mutant type 1 proteases were constructed that contained the cognate type 2 residue at each of these four positions. The substitution at position 32 resulted in a significant adverse effect on inhibitor potency. However, this substitution also mediated a noted increase in the Km of the substrate. Individual substitutions at the remaining three positions, as well as a combination of all four substitutions, had very little effect on enzyme activity or inhibitor susceptibility. Hence, the four studied active site residues are insufficient to be responsible for differences in inhibitor sensitivity between the HIV-1 and HIV-2 proteases and are unlikely to contribute to the generation of inhibitor-resistant mutant HIV-1 protease.

Viral long terminal repeat substrate binding characteristics of the human immunodeficiency virus type 1 integrase.

A DNA binding assay was developed for the human immunodeficiency virus type 1 (HIV-1) integrase. The assay was capable of defining discrete complexes between the enzyme and the viral long terminal repeat (LTR) substrate. DNA binding reflected the sequence requirements previously demonstrated for the enzyme's 3'-end processing activity. Binding exhibited a nonlinear dependence on integrase concentration, suggesting that the enzyme functions as a multimer. The oligomeric state was investigated by UV-photo-cross-linking of integrase-LTR oligonucleotide complexes using DNA substrates substituted with 5-bromo-2'-deoxycytidine within the integrase recognition sequence. In the absence of divalent cation, integrase cross-linked to the LTR oligonucleotide as a single species whose mobility by SDS-polyacrylamide gel electrophoresis was consistent with the formation of tetramers. Using these techniques, analysis of the binding properties of integrase mutants demonstrated that the catalytic and sequence-specific DNA binding activities of the enzyme are distinct, involving residues within the conserved "DD(35)E" and zinc finger motifs, respectively.

Requirement of active human immunodeficiency virus type 1 integrase enzyme for productive infection of human T-lymphoid cells.

The human immunodeficiency virus type 1 (HIV-1) integrase enzyme exhibits significant amino acid sequence conservation with integrase proteins of other retroviruses. We introduced specific amino acid substitutions at a number of the conserved residue positions of recombinant HIV-1 integrase. Some of these substitutions resulted in proteins which were not able to be purified in the same manner as the wild-type enzyme, and these were not studied further. The remaining mutant enzymes were assessed for their abilities to perform functions characteristic of the integrase protein. These included specific removal of the terminal dinucleotides from oligonucleotide substrates representative of the viral U5-long terminal repeat, nonspecific cleavage of oligonucleotide substrates, and mediation of the strand transfer (integration) reaction. Substitution at position 43, within the protein's zinc finger motif region, resulted in an enzyme with reduced specificity for cleavage of the terminal dinucleotide. In addition, a double substitution of aspartic acid and glutamine for valine and glutamic acid, respectively, at positions 151 and 152 within the D,D(35)E motif region rendered the integrase protein inactive for all of its functions. The introduction of this double substitution into an infectious HIV-1 provirus yielded a mutant virus that was incapable of productively infecting human T-lymphoid cells in culture.

Structural implications of spectroscopic characterization of a putative zinc finger peptide from HIV-1 integrase.

The N-terminal domain of human immunodeficiency virus (HIV-1) integrase (IN) contains the sequence motif His-Xaa3-His-Xaa23-Cys-Xaa2-Cys, which is strongly conserved in all retroviral and retrotransposon IN proteins. This structural motif constitutes a putative zinc finger in which a metal ion may be coordinately bound by the His and Cys residues. A recombinant peptide, IN(1-55), composed of the N-terminal 55 amino acids of HIV-1 IN was expressed in Escherichia coli and purified. Utilizing a combination of techniques including UV-visible absorption, circular dichroism, Fourier transform infrared, and fluorescence spectroscopies, we have demonstrated that metal ions (Zn2+, Co2+, and Cd2+) are bound with equimolar stoichiometry by IN(1-55). The liganded peptide assumes a highly ordered structure with increased alpha-helical content and exhibits remarkable thermal stability. UV-visible difference spectra of the peptide-Co2+ complexes directly implicate thiols in metal coordination, and Co2+ d-d transitions in the visible range indicate that Co2+ is tetrahedrally coordinated. Mutant peptides containing conservative substitutions of one of the conserved His or either of the Cys residues displayed no significant Zn(2+)-induced conformational changes as monitored by CD and fluorescence spectra. We conclude that the N terminus of HIV-1 IN contains a metal-binding domain whose structure is stabilized by tetrahedral coordination of metal by histidines 12 and 16 and cysteines 40 and 43. A preliminary structural model for this zinc finger is presented.

Substrate specificity of recombinant human immunodeficiency virus integrase protein.

Recombinant human immunodeficiency virus type 1 (HIV-1) integrase (IN) produced in Escherichia coli efficiently cleaves two nucleotides from the 3' end of synthetic oligonucleotide substrates which mimic the termini of HIV-1 proviral DNA. Efficient cleavage was restricted to HIV-1 substrates and did not occur with substrates derived from other retroviruses. Mutagenesis of the U5 long terminal repeat (LTR) terminus revealed only moderate effects of mutations outside the terminal four bases of the U5 LTR and highlighted the critical nature of the conserved CA dinucleotide motif shared by all retroviral termini. Integration of the endonuclease cleavage products occurs subsequent to cleavage, and evidence that the cleavage and integration reactions may be uncoupled is presented. Competition cleavage reactions demonstrated that IN-mediated processing of an LTR substrate could be inhibited by competition with LTR and non-LTR oligonucleotides.

Sequence-specific interaction of Tat protein and Tat peptides with the transactivation-responsive sequence element of human immunodeficiency virus type 1 in vitro.

Bacterially expressed Tat protein of human immunodeficiency virus type 1 binds selectively to short RNA transcripts containing the viral transactivation-responsive element (TAR). Sequences sufficient for Tat interaction map to the distal portion of the TAR stem-loop. We show that critical sequences for Tat binding are located in the single-stranded "bulge," but no requirement for specific "loop" sequences could be demonstrated. TAR RNA competed for complex formation, and TAR mutants exhibited up to 10-fold reduced affinity for Tat. Synthetic peptides containing the basic region of Tat bound selectively to TAR RNA and exhibited the same sequence requirements and similar relative affinities for mutant TAR RNA as the intact protein. These results suggest that Tat contains a small RNA-binding domain capable of recognizing TAR and implicate functional relevance for direct Tat-TAR interaction in transactivation.

Expression of the acidic nuclear immediate-early protein (IE1) of human cytomegalovirus in stable cell lines and its preferential association with metaphase chromosomes.

Stable DNA-transfected Vero cell lines that express the major immediate-early nuclear antigen (IE68) of HCMV-(Towne) have been established. Immunofluorescence staining with monoclonal antibodies revealed that the protein was distributed either in a uniform diffuse nuclear pattern or as punctate nuclear granules in up to 80% of the cells in these cultures. In addition, 1 to 2% of the positive nuclei gave a distinctive staining pattern suggesting an association with the chromosomes of mitotic cells. Colcemid-blocking studies confirmed that most of the IE antigen was localized in the vicinity of condensed chromosomes in all metaphase cells after methanol fixation. In contrast, the SV40 large T-antigen protein was found to be preferentially excluded from metaphase chromosomes in a similar colcemid-treated human cell line. In transient expression assays, 1 to 2% of IE antigen-positive Vero, 293, or Balb/c3T3 cells also displayed a metaphase chromosome association pattern. Mapping studies using deletion and truncation mutants revealed that the monoclonal antibodies recognized epitopes encoded within the small NH2-terminal exons that are common to both the IE1 and IE2 gene products. However, an intact exon-4 (IE1) region, but not the exon-5 (IE2) region of the HCMV IE gene complex, was required for conferring both the normal diffuse nuclear localization pattern and the chromosome-association properties. Furthermore, removal of the glutamic acid-rich COOH-terminal coding portions of exon-4 resulted in aberrant staining patterns with production of large, phase-dense nuclear globules in all positive cells. An association between the IE68 IE1 protein and metaphase chromosomes was also detected after HCMV-(Towne) infection in a small proportion of both nonpermissive Balb/c3T3 cells and permissive HF cells. We conclude that the IE1 acidic nuclear phosphoprotein displays some properties similar to those of the EBNA-1 protein of Epstein-Barr virus and suggest that it may potentially play a role in maintenance of the latent state of HCMV DNA.

trans-activation and autoregulation of gene expression by the immediate-early region 2 gene products of human cytomegalovirus.

The major immediate-early (IE) gene region mapping at coordinates 0.71 to 0.74 in the genome of human cytomegalovirus (HCMV) gives rise to a series of overlapping spliced IE mRNAs that are all under the transcriptional control of the complex IE68 promoter-enhancer region. We show here that one of the phosphorylated nuclear proteins encoded by this region behaves as a powerful but nonspecific trans-activator of gene expression. In transient chloramphenicol acetyltransferase (CAT) assay experiments with Vero cells all relatively weak heterologous target promoters tested, including those of herpes simplex virus IE175 and delayed-early genes, adenovirus E3, the enhancerless simian virus 40 early gene, and the human beta interferon gene, were stimulated between 30- and 800-fold by cotransfection with the HindIII C fragment of HCMV (Towne) DNA. In contrast, expression of the homologous HCMV IE68-CAT gene but not SV2-CAT was specifically repressed. Inactivation mapping studies of the effector DNA, together with dose-response comparisons with subclones from the region, revealed that an intact 7.1-kilobase sequence encompassing both the IE1 and IE2 coding regions (exons 1 to 5) in the major IE transcription complex was required for both the nonspecific trans-activation and autoregulatory responses. The IE1 coding region alone (exons 1 to 4) was inactive, but both functions were restored by insertion of the IE2 coding region (exon 5) in the correct orientation downstream from the IE1 coding region. Internal deletions or inserted terminator codons in IE1 (exon 4) still gave efficient trans-activation and autoregulation, whereas the insertion of terminator codons in IE2 (exon 5) abolished both activities. Finally, IE2 (exon 5) sequences only (under the direct transcriptional control of the strong simian CMV IE94 promoter) were still able to specifically down regulate IE68-CAT expression but failed to exhibit trans-activation properties. Therefore, the IE2 gene product(s) of HCMV appear likely to be key control proteins involved in gene regulation during HCMV infection.

Differences in cell-type-specific blocks to immediate early gene expression and DNA replication of human, simian and murine cytomegalovirus.

We have previously described blocks to the viral lytic cycle at two different levels in cytomegalovirus (CMV)-infected non-permissive cells. BALB/c-3T3 cells express only the predominant immediate early (IE) nuclear phosphoproteins (IE68 or IE94) of human CMV (HCMV) or simian CMV (SCMV) and do not replicate the input viral genomes. However, in human teratocarcinoma stem cells and 293 cells, expression of the HCMV IE68 gene (but not the SCMV IE94 gene) is blocked at the transcriptional level. Here we report the results of an extensive comparison of the level of permissiveness for HCMV, SCMV and murine CMV (MCMV) in a variety of additional cell types of human, monkey and mouse origin. We also describe a subtle change in the tryptic peptide pattern of the IE68 polypeptide produced in BALB/c-3T3 cells compared to permissive human foreskin fibroblasts. Neither the IE68 nor IE94 proteins could be detected by biochemical labelling procedures in infected mouse Ltk- or F9 teratocarcinoma stem cells, although IE94 was synthesized after retinoic acid-induced differentiation of the F9 cells. Synthesis of [35S]methionine-labelled IE94 protein, but not that of HCMV IE68, was detected in infected Vero cells and in human peripheral blood leukocyte cultures. The failure to synthesize detectable IE68 protein in infected Vero cells appeared to be unrelated to a lack of entry of viral DNA and to a lack of appropriate transcription factors. Indeed, immunofluorescence assays showed that the IE68 antigen was expressed efficiently in DNA-transfected Vero cells and in a small fraction of infected Vero cells. Overall, two clear host range trends emerged. First, whilst all three viruses showed a tendency for repression of IE expression in transformed cell lines, the effect was severe for HCMV and only minimal for SCMV. Secondly, progression of infection to the viral DNA synthesis level in non-transformed fibroblast cell types occurred in a much wider range of host species cell types for SCMV and MCMV than for HCMV.

Structural organization of human herpesvirus DNA molecules.

The herpesviruses are among the largest and most complex of all DNA viruses, and their genomes display an astonishing diversity in size, structure, and organization. In 1974, the features of large inverted repeats and structural isomerization were first discovered, and these proved to be characteristic properties of many herpesvirus genomes. Since then, research using the powerful techniques of modern molecular biology has revealed a great deal of comparative structural information about the arrangement of repetitive sequences and the location, structure, and primary nucleotide sequences of the genes for several easily assayed or abundantly expressed gene products. Extensive restriction enzyme cleavage maps and complete sets of cloned DNA fragments have been constructed for each of the five human herpesviruses, HSV-1, HSV-2, CMV, EBV, and VZV, and the entire 175,000-bp nucleotide sequence of EBV DNA has been determined. Based on these maps and reagents, the procedures of "DNA fingerprinting" and "dot hybridization" are proving useful at a clinical level for characterization of isolates and studying herpesvirus epidemiology. Strain differences, localized heterogeneity, tandem-repeat-defective genomes, and sites of cell-virus DNA homology have been described in some detail. The attention of basic researchers is now turning to equating structure with function, and rapid progress is expected in studies aimed at a better understanding of the mechanisms of viral DNA replication, maintenance of the latent state, reactivation, transformation, packaging, and regulation of the lytic cycle, etc using cloned functionally active DNA fragments, isolated intact genes and promoters, and DNA transfection and in vitro expression systems.