The 45-kilodalton protein of cytomegalovirus (Colburn) B-capsids is an amino-terminal extension form of the assembly protein

Protease Inhibitors as Ad-hoc Antibiotics

Background:

Proteases are important enzymes that can degrade proteins and are found in animals, plants, bacteria, fungi and viruses. The action of proteases can be controlled by Protease Inhibitors (PIs), chemical or proteinaceous in nature that can block the active site of protease. Since the step catalyzed by proteases may play important role in life cycle of microbes, hindering the action of proteases by PIs may act as therapeutic intervention for microbial infection.

Material and Methods:

A thorough study was performed and wide range of literature was surveyed to confirm our results of PIs showing antibacterial activity.

Results:

PIs have shown to be effective drugs against bacterial pathogens, pathogenic viruses- Human Immunodeficiency Virus (HIV), Herpes virus, Hepatitis Virus. PIs have recently been investigated for controlling protozoan parasites. Clinical value of proteases and their inhibitors has been studied inHelicobacter pyloriwhich is the etiologic agent of gastritis.

Conclusion:

This review is intended to highlight the role of PIs in the Battle against Microbial Pathogens.

Recovery of an HMWP/hmwBP (pUL48/pUL47) complex from virions of human cytomegalovirus: subunit interactions, oligomer composition, and deubiquitylase activity

We report that the human cytomegalovirus (HCMV) high-molecular-weight tegument protein (HMWP, pUL48; 253 kDa) and the HMWP-binding protein (hmwBP, pUL47; 110 kDa) can be recovered as a complex from virions disrupted by treatment with 50 mM Tris (pH 7.5), 0.5 M NaCl, 0.5% NP-40, and 10 mM dithiothreitol [DTT]. The subunit ratio of the complex approximates 1:1, with a shape and structure consistent with an elongated heterodimer. The HMWP/hmwBP complex was corroborated by reciprocal coimmunoprecipitation experiments using antipeptide antibodies and lysates from both infected cells and disrupted virus particles. An interaction of the amino end of pUL48 (amino acids [aa] 322 to 754) with the carboxyl end of pUL47 (aa 693 to 982) was identified by fragment coimmunoprecipitation experiments, and a head-to-tail self-interaction of hmwBP was also observed. The deubiquitylating activity of pUL48 is retained in the isolated complex, which cleaves K11, K48, and K63 ubiquitin isopeptide linkages.

IMPORTANCE

Human cytomegalovirus (HCMV, or human herpesvirus 5 [HHV-5]) is a large DNA-containing virus that belongs to the betaherpesvirus subfamily and is a clinically important pathogen. Defining the constituent elements of its mature form, their organization within the particle, and the assembly process by which it is produced are fundamental to understanding the mechanisms of herpesvirus infection and developing drugs and vaccines against them. In this study, we report isolating a complex of two large proteins encoded by HCMV open reading frames (ORFs) UL47 and UL48 and identifying the binding domains responsible for their interaction with each other and of pUL47 with itself. Our calculations indicate that the complex is a rod-shaped heterodimer. Additionally, we determined that the ubiquitin-specific protease activity of the ORF UL48 protein was functional in the complex, cleaving K11-, K48-, and K63-linked ubiquitin dimers. This information builds on and extends our understanding of the HCMV tegument protein network that is required to interface the HCMV envelope and capsid.

Enzymatic activities of human cytomegalovirus maturational protease assemblin and its precursor (pPR, pUL80a) are comparable: [corrected] maximal activity of pPR requires self-interaction through its scaffolding domain

Herpesviruses encode an essential, maturational serine protease whose catalytic domain, assemblin (28 kDa), is released by self-cleavage from a 74-kDa precursor (pPR, pUL80a). Although there is considerable information about the structure and enzymatic characteristics of assemblin, a potential pharmacologic target, comparatively little is known about these features of the precursor. To begin studying pPR, we introduced five point mutations that stabilize it against self-cleavage at its internal (I), cryptic (C), release (R), and maturational (M) sites and at a newly discovered "tail" (T) site. The resulting mutants, called ICRM-pPR and ICRMT-pPR, were expressed in bacteria, denatured in urea, purified by immobilized metal affinity chromatography, and renatured by a two-step dialysis procedure and by a new method of sedimentation into glycerol gradients. The enzymatic activities of the pPR mutants were indistinguishable from that of IC-assemblin prepared in parallel for comparison, as determined by using a fluorogenic peptide cleavage assay, and approximated rates previously reported for purified assemblin. The percentage of active enzyme in the preparations was also comparable, as determined by using a covalent-binding suicide substrate. An unexpected finding was that, in the absence of the kosmotrope Na2SO4, optimal activity of pPR requires interaction through its scaffolding domain. We conclude that although the enzymatic activities of assemblin and its precursor are comparable, there may be differences in how their catalytic sites become fully activated.

The amino-conserved domain of human cytomegalovirus UL80a proteins is required for key interactions during early stages of capsid formation and virus production

Assembly of many spherical virus capsids is guided by an internal scaffolding protein or group of proteins that are often cleaved and eliminated in connection with maturation and incorporation of the genome. In cytomegalovirus there are at least two proteins that contribute to this scaffolding function; one is the maturational protease precursor (pUL80a), and the other is the assembly protein precursor (pUL80.5) encoded by a shorter genetic element within UL80a. Yeast GAL4 two-hybrid assays established that both proteins contain a carboxyl-conserved domain that is required for their interaction with the major capsid protein (pUL86) and an amino-conserved domain (ACD) that is required for their self-interaction and for their interaction with each other. In the work reported here, we demonstrate that when the ACD is deleted (deltaACD) or disrupted by a point mutation (L47A), the bacterially expressed mutant protein sediments as a monomer during rate-velocity centrifugation, whereas the wild-type protein sediments mainly as oligomers. We also show that the L47A mutation reduces the production of infectious virus by at least 90%, results in the formation of irregular nuclear capsids, gives rise to tube-like structures in the nucleus that resemble the capsid core in cross-section and contain UL80 proteins, slows nuclear translocation of the major capsid protein, and may slow cleavage by the maturational protease. We provide physical corroboration that mutating the ACD disrupts self-interaction of the UL80 proteins and biological support for the proposal that the ACD has a critical role in capsid assembly and production of infectious virus.

The chemokine receptor homologue encoded by US27 of human cytomegalovirus is heavily glycosylated and is present in infected human foreskin fibroblasts and enveloped virus particles

Human cytomegalovirus (HCMV), a member of the beta-herpesvirus family, encodes four homologues of cellular G protein-coupled receptors (GPCRs). One of these, the protein product of HCMV open reading frame (ORF) UL33, has been identified in HCMV-infected cells and virus particles and shown to be heat-aggregatable and N-glycosylated. Another, the product of ORF US28, has been functionally characterized as a beta-chemokine receptor. Here we report the use of RT-PCR, coupled in vitro transcription-translation, immunoprecipitation, and Western immunoassays to (i) show that RNA from the open reading frame US27 appears predominantly during the late phase of replication; (ii) identify the protein encoded by HCMV US27 in infected cells and enveloped virus particles; (iii) demonstrate that the US27-encoded protein is heterogeneously N-glycosylated and resolves as two species following treatment with peptide N-glycosidase F; and (iv) show that both the recombinant and deglycoylated infected cell US27 protein aggregate when heated in the presence of SDS prior to electrophoresis in polyacrylamide gels, a property which is abrogated with the addition of urea to sample buffer.

Chemical Rescue of I-site Cleavage in Living Cells and in Vitro Discriminates between the Cytomegalovirus Protease, Assemblin, and Its Precursor, pUL80a

Chemical rescue is an established approach that offers a directed strategy for designing mutant enzymes in which activity can be restored by supplying an appropriate exogenous compound. This method has been used successfully to study a broad range of enzymes in vitro, but its application to living systems has received less attention. We have investigated the feasibility of using chemical rescue to make a conditional-lethal mutant of the cytomegalovirus (CMV) maturational protease. The 28-kDa CMV serine protease, assemblin, has a Ser-His-His catalytic triad and an internal (I) cleavage site near its midpoint. We found that imidazole can restore I-site cleavage to mutants inactivated by replacing the critical active site His with Ala or with Gly, which rescued better. Comparable rescue was observed for counterpart mutants of the human and simian CMV assemblin homologs and occurred in both living cells and in vitro. Cleavage was established to be at the correct site by amino acid sequencing and proceeded at approximately 11%/h in bacteria and approximately 30%/h in vitro. The same mutations were unresponsive to chemical rescue in the context of the assemblin precursor, pUL80a. This catalytic difference distinguishes the two forms of the CMV protease.

Assembly protein precursor (pUL80.5 homolog) of simian cytomegalovirus is phosphorylated at a glycogen synthase kinase 3 site and its downstream "priming" site: phosphorylation affects interactions of protein with itself and with major capsid protein

Capsid assembly among the herpes-group viruses is coordinated by two related scaffolding proteins. In cytomegalovirus (CMV), the main scaffolding constituent is called the assembly protein precursor (pAP). Like its homologs in other herpesviruses, pAP is modified by proteolytic cleavage and phosphorylation. Cleavage is essential for capsid maturation and production of infectious virus, but the role of phosphorylation is undetermined. As a first step in evaluating the significance of this modification, we have identified the specific sites of phosphorylation in the simian CMV pAP. Two were established previously to be adjacent serines (Ser156 and Ser157) in a casein kinase II consensus sequence. The remaining two, identified here as Thr231 and Ser235, are within consensus sequences for glycogen synthase kinase 3 (GSK-3) and mitogen-activated protein kinase, respectively. Consistent with Thr231 being a GSK-3 substrate, its phosphorylation required a downstream "priming" phosphate (i.e., Ser235) and was reduced by a GSK-3-specific inhibitor. Phosphorylation of Ser235 converts pAP to an electrophoretically slower-mobility isoform, pAP*; subsequent phosphorylation of pAP* at Thr231 converts pAP* to a still-slower isoform, pAP**. The mobility shift to pAP* was mimicked by substituting an acidic amino acid for either Thr231 or Ser235, but the shift to pAP** required that both positions be phosphorylated. Glu did not substitute for pSer235 in promoting phosphorylation of Thr231. We suggest that phosphorylation of Thr231 and Ser235 causes charge-driven conformational changes in pAP, and we demonstrate that preventing these modifications alters interactions of pAP with itself and with major capsid protein, suggesting a functional significance.

Cytomegalovirus basic phosphoprotein (pUL32) binds to capsids in vitro through its amino one-third

The cytomegalovirus (CMV) basic phosphoprotein (BPP) is a component of the tegument. It remains with the nucleocapsid fraction under conditions that remove most other tegument proteins from the virion, suggesting a direct and perhaps tight interaction with the capsid. As a step toward localizing this protein within the molecular structure of the virion and understanding its function during infection, we have investigated the BPP-capsid interaction. In this report we present evidence that the BPP interacts selectively, through its amino one-third, with CMV capsids. Radiolabeled simian CMV (SCMV) BPP, synthesized in vitro, bound to SCMV B-capsids, and C-capsids to a lesser extent, following incubation with either isolated capsids or lysates of infected cells. Human CMV (HCMV) BPP (pUL32) also bound to SCMV capsids, and SCMV BPP likewise bound to HCMV capsids, indicating that the sequence(s) involved is conserved between the two proteins. Analysis of SCMV BPP truncation mutants localized the capsid-binding region to the amino one-third of the molecule--the portion of BPP showing the greatest sequence conservation between the SCMV and HCMV homologs. This general approach may have utility in studying the interactions of other proteins with conformation-dependent binding sites.

Phosphorylation of simian cytomegalovirus assembly protein precursor (pAPNG.5) and proteinase precursor (pAPNG1): multiple attachment sites identified, including two adjacent serines in a casein kinase II consensus sequence

The assembly protein precursor (pAP) of cytomegalovirus (CMV), and its homologs in other herpesviruses, functions at several key steps during the process of capsid formation. This protein, and the genetically related maturational proteinase, is distinguished from the other capsid proteins by posttranslational modifications, including phosphorylation. The objective of this study was to identify sites at which pAP is phosphorylated so that the functional significance of this modification and the enzyme(s) responsible for it can be determined. In the work reported here, we used peptide mapping, mass spectrometry, and site-directed mutagenesis to identify two sets of pAP phosphorylation sites. One is a casein kinase II (CKII) consensus sequence that contains two adjacent serines, both of which are phosphorylated. The other site(s) is in a different domain of the protein, is phosphorylated less frequently than the CKII site, does not require preceding CKII-site phosphorylation, and causes an electrophoretic mobility shift when phosphorylated. Transfection/expression assays for proteolytic activity showed no gross effect of CKII-site phosphorylation on the enzymatic activity of the proteinase or on the substrate behavior of pAP. Evidence is presented that both the CKII sites and the secondary sites are phosphorylated in virus-infected cells and plasmid-transfected cells, indicating that these modifications can be made by a cellular enzyme(s). Apparent compartmental differences in phosphorylation of the CKII-site (cytoplasmic) and secondary-site (nuclear) serines suggest the involvement of more that one enzyme in these modifications.

Protease inhibitors as antiviral agents

Currently, there are a number of approved antiviral agents for use in the treatment of viral infections. However, many instances exist in which the use of a second antiviral agent would be beneficial because it would allow the option of either an alternative or a combination therapeutic approach. Accordingly, virus-encoded proteases have emerged as new targets for antiviral intervention. Molecular studies have indicated that viral proteases play a critical role in the life cycle of many viruses by effecting the cleavage of high-molecular-weight viral polyprotein precursors to yield functional products or by catalyzing the processing of the structural proteins necessary for assembly and morphogenesis of virus particles. This review summarizes some of the important general features of virus-encoded proteases and highlights new advances and/or specific challenges that are associated with the research and development of viral protease inhibitors. Specifically, the viral proteases encoded by the herpesvirus, retrovirus, hepatitis C virus, and human rhinovirus families are discussed.

Cytomegalovirus assembly protein precursor and proteinase precursor contain two nuclear localization signals that mediate their own nuclear translocation and that of the major capsid protein

The cytomegalovirus (CMV) assembly protein precursor (pAP) interacts with the major capsid protein (MCP), and this interaction is required for nuclear translocation of the MCP, which otherwise remains in the cytoplasm of transfected cells (L. J. Wood et al., J. Virol. 71:179-190, 1997). We have interpreted this finding to indicate that the CMV MCP lacks its own nuclear localization signal (NLS) and utilizes the pAP as an NLS-bearing escort into the nucleus. The CMV pAP amino acid sequence has two clusters of basic residues (e.g., KRRRER [NLS1] and KARKRLK [NLS2], for simian CMV) that resemble the simian virus 40 large-T-antigen NLS (D. Kalderon et al., Cell 39:499-509, 1984) and one of these (NLS1) has a counterpart in the pAP homologs of other herpesviruses. The work described here establishes that NLS1 and NLS2 are mutually independent NLS that can act (i) in cis to translocate pAP and the related proteinase precursor (pNP1) into the nucleus and (ii) in trans to transport MCP into the nucleus. By using combinations of NLS mutants and carboxy-terminal deletion constructs, we demonstrated a self-interaction of pAP and cytoplasmic interactions of pAP with pNP1 and of pNP1 with itself. The relevance of these findings to early steps in capsid assembly, the mechanism of MCP nuclear transport, and the possible cytoplasmic formation of protocapsomeric substructures is discussed.

Herpesvirus proteases: targets for novel antiviral drugs

Herpesvirus proteases have emerged as targets for the development of novel antiviral drugs. These enzymes, which are necessary for the replication of all herpesviruses, are serine proteases, but possess a unique structure as revealed by solution of the crystal structure of human cytomegalovirus protease. Many of the biochemical properties of these enzymes are now explained by the structure. Conventional serine protease inhibitors are not potent inhibitors of these enzymes and therefore the search for potent inhibitors possessing necessary features of an effective antiviral will require novel approaches. The three-dimensional structure serves as a milestone for continued endeavors towards this goal.

Comparison of human cytomegalovirus (HCMV) protease sequences among laboratory strains and seven clinical isolates

The nucleotide sequence of the human cytomegalovirus (HCMV) protease gene from two laboratory strains and seven clinical isolates, both ganciclovir-sensitive and -resistant, was examined to determine the genetic variability of the HCMV protease catalytic domain and to identify changes that may alter the efficacy of designed protease inhibitors. The Towne strain varied from AD169 at 12 nucleotides and led to one amino acid change at position 12 (Ala to Thr). The clinical isolates had amino acid substitutions relative to the laboratory strains, with a Ser to Pro change at position 8, a His to Tyr change at position 44 and s Gly to Ser change at position 47. None of these changes occurred in any of the conserved domains of the protease, nor do they appear necessary to confer ganciclovir resistance in the isolates. These findings suggest that no changes exist in the protease of the clinical isolates examined that may diminish the effectiveness of a drug targeting the HCMV protease. 1977 Elsevier Science B.V. All rights reserved.

Independently cloned halves of cytomegalovirus assemblin, An and Ac, can restore proteolytic activity to assemblin mutants by intermolecular complementation

Herpesviruses encode an essential serine proteinase called assemblin that is responsible for cleaving the precursor assembly protein during the process of capsid formation. In cytomegalovirus (CMV), assemblin undergoes autoproteolysis at an internal (I) site located near the middle of the molecule. I-site cleavage converts the enzyme to an active two-chain form consisting of the subunits An and Ac. We have recently shown that the recombinant An and Ac subunits can spontaneously associate within eukaryotic cells to yield active two-chain proteinase. This finding indicates that the subunits are able to independently assume their correct functional conformations and led us to test whether they are capable of intermolecular complementation. This was done by coexpressing inactive mutant (point, deletion, and insertion) forms of assemblin together with the wild-type subunit (either An or Ac) corresponding to the domain of assemblin that was mutated. Results of these experiments showed that both An and Ac are able to rescue the enzymatic activity of assemblin mutants. I-site cleavage of the mutated assemblin occurred during complementation but was not absolutely required, as shown by effective complementation of inactive assemblins with noncleavable I sites. We have also shown that intermolecular complementation can rescue the activity of an inactive mutant full-length proteinase precursor and can occur between different species of CMV (e.g., human CMV subunit can rescue activity of mutant simian CMV assemblin). These results indicate that assemblin is able to form active multimeric structures that may be of functional importance.

Human cytomegalovirus capsid assembly protein precursor (pUL80.5) interacts with itself and with the major capsid protein (pUL86) through two different domains

We have used the yeast GAL4 two-hybrid system to examine interactions between the human cytomegalovirus (HCMV) major capsid protein (MCP, encoded by UL86) and the precursor assembly protein (pAP, encoded by UL80.5 and cleaved at its carboxyl end to yield AP) and found that (i) the pAP interacts with the MCP through residues located within the carboxy-terminal 21 amino acids of the pAP, called the carboxyl conserved domain (CCD); (ii) the pAP interacts with itself through a separate region, called the amino conserved domain (ACD), located between amino acids His34 and Arg52 near the amino end of the molecule; (iii) the simian CMV (SCMV) pAP and AP can interact with or replace their HCMV counterparts in these interactions, whereas the herpes simplex virus pAP and AP homologs cannot; and (iv) the HCMV and SCMV maturational proteinase precursors (ACpra, encoded by UL80a and APNG1, respectively) can interact with the pAP and MCP. The ACD and CCD amino acid sequences are highly conserved among members of the betaherpesvirus group and appear to have counterparts in the alpha- and gammaherpesvirus pAP homologs. Deleting the ACD from the HCMV pAP, or substituting Ala for a conserved Leu in the ACD, eliminated detectable pAP self-interaction and also substantially reduced MCP binding in the two-hybrid assay. This finding indicates that the pAP self-interaction influences the pAP-MCP interaction. Immunofluorescence studies corroborated the pAP-MCP interaction detected in the GAL4 two-hybrid experiments and showed that nuclear transport of the MCP was mediated by pAP but not AP. We conclude that the pAP interacts with the MCP, that this interaction is mediated by the CCD and is influenced by pAP self-interaction, and that one function of the pAP-MCP interaction may be to provide a controlled mechanism for transporting the MCP into the nucleus.

Cytomegalovirus "missing" capsid protein identified as heat-aggregable product of human cytomegalovirus UL46

Capsids of human and simian strains of cytomegalovirus (HCMV and SCMV, respectively) have identified counterparts for all but one of the protein components of herpes simplex virus (HSV) capsids. The open reading frames (ORFs) for the CMV and HSV counterpart proteins are positionally homologous in the two genomes. The HSV capsid protein without a recognized counterpart in CMV is VP19c, a 50-kDa element of the intercapsomeric "triplex." VP19c is encoded by HSV ORF UL38, whose positional homolog in the HCMV genome is UL46. The predicted protein product of HCMV UL4A6, however, has essentially no amino acid sequence similarity to HSV VP19c, is only two-thirds as long, and was not recognized as a component of CMV capsids. To identify and learn more about the protein encoded by HCMV UL46, we have expressed it in insect cells from a recombinant baculovirus and tested for its presence in CMV-infected human cells and virus particles with two UL4A6-specific antipeptide antisera. Results presented here show that this HCMV protein (i) has a size of approximately 30 kDa as expressed in both recombinant baculovirus-infected insect cells and HCMV-infected human cells; (ii) has a homolog in SCMV; (iii) is a capsid component and is present in a 1:2 molar ratio with the minor capsid protein (mCP), encoded by UL85; and (iv) interacts with the mCP, which is also shown to interact with itself as demonstrated by the GAL4 two-hybrid system; and (v) aggregates when heated and does not enter the resolving gel during sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), a characteristic that accounts for it eluding detection until now. We call this protein the mCP-binding protein, and on the basis of the characteristics that it shares with HSV VP19c, we conclude that the HCMV mCP-binding protein is the functional as well as genetic homolog of HSV VP19c.

Identification of the human cytomegalovirus G protein-coupled receptor homologue encoded by UL33 in infected cells and enveloped virus particles

Human cytomegalovirus (HCMV), strain AD169, contains four genes (US27, US28, UL33, and UL78) that encode putative homologues of cellular G protein-coupled receptors (GCRs). GCRs transduce extracellular signals to alter intracellular processes, and there is evidence that HCMV may elicit such changes at early times following infection. The US27, US28, and UL33 genes are transcribed during infection, and the US28 gene product has been found to be a functional receptor for the beta-chemokine class of immune modulators. The US27, UL33, and UL78 gene products have not been described and we have concentrated on identifying the UL33 protein because it is the most highly conserved of the GCR homologues among the human beta and gamma herpesviruses. We report here cloning UL33 into a recombinant baculovirus (rBV) and expressing it in insect cells; constructing a mutant HCMV with a disrupted UL33 gene; and identifying the UL33 protein in HCMV-infected cells and virus particles. Our results demonstrate that the UL33 protein (i) is expressed as a approximately 36-kDa, heat-aggregatable protein in rBV-infected cells, (ii) is modified heterogeneously by asparagine-linked glycosylation and expressed as a > or = 58-kDa glycoprotein that is present in the region of the cytoplasmic inclusions in HCMV-infected fibroblasts, (iii) is present in virions and two other enveloped virus particles, and (iv) is not essential for growth of HCMV in human foreskin fibroblast cultures.

Human cytomegalovirus (HCMV) smallest capsid protein identified as product of short open reading frame located between HCMV UL48 and UL49

The capsid of cytomegalovirus contains an abundant, low-molecular-weight protein whose coding sequence within the viral genome had not been identified. We have used a combination of biochemical and immunological techniques to demonstrate that this protein, called the smallest capsid protein in human cytomegalovirus, is encoded by a previously unidentified 225-bp open reading frame (ORF) located between ORFs UL48 and UL49. This short ORF, called UL48/49, is the positional homolog of herpes simplex virus ORF UL35 (encoding capsid protein VP26) and shows partial amino acid sequence identity to positional homologs in human herpes viruses 6 and 7.

Cytomegalovirus assemblin: the amino and carboxyl domains of the proteinase form active enzyme when separately cloned and coexpressed in eukaryotic cells

The cytomegalovirus (CMV) serine proteinase assemblin is synthesized as a precursor that undergoes three principal autoproteolytic cleavages. Two of these are common to the assemblin homologs of all herpes group viruses: one at the maturational site near the carboxyl end of the precursor and another at the release site near the midpoint of the precursor. Release-site cleavage frees the proteolytic amino domain, assemblin, from the nonproteolytic carboxyl domain of the precursor. In CMV, a third autoproteolytic cleavage at an internal site divides assemblin into an amino subunit (An) and a carboxyl subunit (Ac) of approximately the same size that remain associated as an active "two-chain" enzyme. We have cloned the sequences encoding An and Ac as separate genes and expressed them by transfecting human cells with recombinant plasmids and by infecting insect cells with recombinant baculoviruses. When An and Ac from either simian CMV or human CMV were coexpressed in human or insect cells, active two-chain assemblin was formed. This finding demonstrates that An and Ac do not require synthesis as single-chain assemblin to fold and associate correctly in these eukaryotic systems, and it suggests that they may be structurally, if not functionally, distinct domains. An interaction between the independently expressed An and Ac subunits was demonstrated by coimmunoprecipitation experiments, and efforts to disrupt the complex indicate that the subunit interaction is hydrophobic. Cell-based cleavage assays of the two-chain assemblin formed from independently expressed An and Ac also indicate that (i) its specificity for both CMV and herpes simplex virus native substrates is similar to that of single-chain assemblin, (ii) R-site cleavage is not essential for the activity of two-chain recombinant assemblin, and (iii) the human CMV and simian CMV An and Ac recombinant subunits are functionally interchangeable.

Single-chain recombinant human cytomegalovirus protease. Activity against its natural protein substrate and fluorogenic peptide substrates

We report here the production of active recombinant single-chain human cytomegalovirus protease in Escherichia coli and development of a continuous assay for this protease. In order to produce the human cytomegalovirus (HCMV) protease for structural studies and accurate kinetic analysis, mutation of alanine 143 at an internal cleavage site was introduced to prevent auto-proteolysis. The resulting soluble 29-kDa A143Q protease was purified to homogeneity as a stable single-chain protein by hydrophobic interaction and ionic-exchange chromatography. The in vivo protein substrate, assembly protein precursor, was also expressed and purified for activity studies. To develop a continuous protease assay, fluorescent synthetic peptide substrates similar to the cleavage sequence P5 to P5' of the maturation site containing anthranilic acid and nitrotyrosine as a resonance energy transfer donor-acceptor pair were designed. Purified HCMV A143Q protease cleaved the recombinant assembly protein precursor with Km and kcat values of 3.0 +/- 1.0 microM and 13.3 +/- 1.6 min-1. The Km for peptide substrates is at least 45-fold higher than for the natural protein substrate, but the kcat values are similar. A sensitive assay was developed using fluorescent peptide substrates, which can detect nM HCMV protease activity.

The effect of internal autocleavage on kinetic properties of the human cytomegalovirus protease catalytic domain

The 28-kilodalton (kDa) catalytic domain of the human cytomegalovirus (HCMV) protease undergoes autoproteolytic cleavage at an internal site (I site), yielding amino-terminal 15-kDa (N15) and carboxyl-terminal 13-kDa (C13) fragments. I site autocleavage has been postulated to inactivate the protease and provide a mechanism for the negative regulation of enzyme activity during viral infection. We purified recombinant enzymes to demonstrate I site autocleavage in vitro and used site-directed mutagenesis of the I site to stabilize the protease. No difference in the kinetic properties of wild type and stabilized mutant proteases were observed in an in vitro peptide cleavage assay. The consequences of I site cleavage on enzyme activity were investigated two ways. First, autodigestion of the wild type enzyme converted the intact protease to N15 and C13 autocleavage products without a corresponding loss in enzyme activity. Second, genetic constructs encoding the N15 and C13 autocleavage products were generated and expressed separately in Escherichia coli, and each fragment was purified. An active enzyme was reconstituted by refolding a mixture of the purified fragments in vitro to form a noncovalent complex. The kinetic properties of this complex were very similar to the wild type and stabilized enzymes under optimal reaction conditions. We concluded from these studies that I site cleavage does not inactivate the HCMV protease, in the absence of other virally induced factors, and that limited potential exists for the regulation of catalytic activity by I site cleavage.

Cytomegalovirus protein substrates are not cleaved by the herpes simplex virus type 1 proteinase

The herpesvirus maturational proteinase, assemblin, is made as a precursor that undergoes at least two autoproteolytic cleavages--one in a sequence toward its carboxyl end, called the maturational (M) site, and one in a sequence toward its midpoint, called the release (R) site. The M- and R-site sequences are both well conserved among the herpesvirus proteinase homologs, suggesting that the proteinase of one herpesvirus might be able to cleave the substrates of another. To test this possibility, we cloned and expressed in human cells the long (i.e., full-length open reading frame of proteinase gene) and short (i.e., proteolytic domain, assemblin) forms of the proteinase from human and simian cytomegalovirus (HCMV and SCMV, respectively) and from herpes simplex virus type 1 (HSV-1), as well as the genes for their respective assembly protein precursor substrates. Data from cotransfections of these proteinase genes with appropriate homologous and heterologous substrates showed that although the SCMV and HCMV enzymes cleaved the M-sites of the assembly protein substrates of all three viruses and an SCMV R-site substrate, the HSV-1 proteinase cleaved only its own substrate. This finding demonstrates that the substrate specificity properties of the HSV-1 enzyme differ from those of the two CMV enzymes.

The size and symmetry of B capsids of herpes simplex virus type 1 are determined by the gene products of the UL26 open reading frame

Herpes simplex virus type 1 (HSV-1) B capsids are composed of seven proteins, designated VP5, VP19C, 21, 22a, VP23, VP24, and VP26 in order of decreasing molecular weight. Three proteins (21, 22a, and VP24) are encoded by a single open reading frame (ORF), UL26, and include a protease whose structure and function have been studied extensively by other investigators. The protease encoded by this ORF generates VP24 (amino acids 1 to 247), a structural component of the capsid and mature virions, and 21 (residues 248 to 635). The protease also cleaves C-terminal residues 611 to 635 of 21 and 22a, during capsid maturation. Protease activity has been localized to the N-terminal 247 residues. Protein 22a and probably the less abundant protein 21 occupy the internal volume of capsids but are not present in virions; therefore, they may form a scaffold that is used for B capsid assembly. The objective of the present study was to isolate and characterize a mutant virus with a null mutation in UL26. Vero cells were transformed with plasmid DNA that encoded ORF UL25 through UL28 and screened for their ability to support the growth of a mutant virus with a null mutation in UL27 (K082). Four of five transformants that supported the growth of the UL27 mutant also supported the growth of a UL27-UL28 double mutant. One of these transformants (F3) was used to isolate a mutant with a null mutation in UL26. The UL26 null mutation was constructed by replacement of DNA sequences specifying codons 41 through 593 with a lacZ reporter cassette. Permissive cells were cotransfected with plasmid and wild-type virus DNA, and progeny viruses were screened for their ability to grow on F3 but not Vero cells. A virus with these growth characteristics, designated KUL26 delta Z, that did not express 21, 22a, or VP24 during infection of Vero cells was isolated. Radiolabeled nuclear lysates from infected nonpermissive cells were layered onto sucrose gradients and subjected to velocity sedimentation. A peak of radioactivity for KUL26 delta Z that sedimented more rapidly than B capsids from wild-type-infected cells was observed. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the gradient fractions showed that the peak fractions contained VP5, VP19C, VP23, and VP26. Analysis of sectioned cells and of the peak fractions of the gradients by electron microscopy revealed sheet and spiral structures that appear to be capsid shells.(ABSTRACT TRUNCATED AT 400 WORDS)

Proteolytic activity of human cytomegalovirus UL80 protease cleavage site mutants

The human cytomegalovirus UL80 open reading frame encodes protease and assembly protein from its N- and C-terminal regions, respectively. We reported previously that a 30-kDa protease is derived by autoproteolytic processing of a polyprotein which is the translation product of the entire UL80 open reading frame (E. Z. Baum, G. A. Bebernitz, J. D. Hulmes, V. P. Muzithras, T. R. Jones, and Y. Gluzman, J. Virol. 67:497-506, 1993). Three autoproteolytic cleavage sites within the UL80 polyprotein were characterized; site 143 is within the protease domain and inactivates the protease. In this article, we report (i) expression analyses of UL80 in infected cells, including the processing kinetics of the UL80 polyprotein; (ii) the existence of an additional cleavage site (site 209) within the protease domain of the UL80 polyprotein; and (iii) the effect of mutagenesis at each of the cleavage sites upon proteolytic activity and steady-state levels of the UL80 processing products. During the course of infection, UL80 polyprotein processing begins at cleavage site 643 and follows at sites 256 and 143. Cleavage at site 643 and/or 256 within the polyprotein is not a prerequisite for efficient protease activity, since all three proteases (85-, 80-, and 30-kDa proteins) were equally active in cleaving the assembly protein precursor to its mature form. Inhibition of cleavage at site 143 resulted in a three- to sixfold increase in the steady-state level of the 30-kDa protease, supporting the hypothesis that cleavage at this site may represent a mechanism by which cytomegalovirus regulates the level of active protease.

Human cytomegalovirus maturational proteinase: expression in Escherichia coli, purification, and enzymatic characterization by using peptide substrate mimics of natural cleavage sites

The proteolytic processing of the human cytomegalovirus (HCMV) assembly protein, resulting in truncation of its C terminus, is an essential step in virion maturation. The proteinase responsible for this cleavage is the amino-terminal half of the protein encoded by the UL80a open reading fame. We have obtained high expression levels of this 256-amino-acid HCMV proteinase, assemblin, in Escherichia coli. In addition to the 28-kDa proteinase, a 15-kDa protein comprising the first 143 amino acids and a 13-kDa protein comprising the last 113 amino acids of the 28-kDa HCMV proteinase were present. Both the 28-kDa proteinase and the 15-kDa protein were purified by a two-step chromatographic procedure utilizing anion exchange in urea and dithiothreitol and size exclusion in NaSCN and dithiothreitol. Activation of the purified 28-kDa proteinase required denaturation in urea as well as complete reduction of all five cysteine residues in the molecule. Removal of the urea by dialysis with retention of the reducing agent yielded an active proteinase. Addition of glycerol to 50% enhanced the activity. The HCMV proteinase cleaved the peptides RGVVNASSRLAK and SYVKASVSPE, which are mimics of the maturational (M)- and release (R)-site sequences, respectively, in the UL80a-encoded protein. The cleavage site in the peptides was at the same Ala-Ser scissile bond as observed in the UL80a protein. The Km value for the cleavage of RGVVNASSRLAK (M-site mimic) by the proteinase was similar to that for SYVKASVSPE (R-site mimic), but the turnover (kcat) of the M-site peptide mimic substrate by the proteinase was six to eight times faster. The peptide homologs of the herpes simplex virus type 1 M- and R-site sequences in the UL26-encoded protein were also cleaved by the HCMV proteinase, although at rates slower than those for the HCMV substrates. The HCMV proteinase was inhibited by Zn2+ and by alkylating agents, but only at very high inhibitor concentrations. The purified 15-kDa protein, subjected to the same activation conditions as the 28-kDa proteinase, had no enzymatic activity against the HCMV M- and R-site peptide substrates.

The effects of cytomegalovirus on human immunodeficiency virus replication in brain-derived cells correlate with permissiveness of the cells for each virus

Human cytomegalovirus (HCMV) is commonly found in the brains of patients with AIDS and in some cases can be detected in the same cells as can human immunodeficiency virus type 1 (HIV-1). In this study, we analyzed the patterns of replication of HIV-1 and HCMV in singly infected cells and the effects of dual infection in human brain-derived cell lines of three different origins: neuroblastoma cell lines SK-N-MC and SY5Y; astrocytoma/glioblastoma cell lines U373-MG and Hs 683; and undifferentiated glioblastoma cell lines A172 and T98G. To bypass the restriction at the adsorption/penetration step in these CD4-negative cells, we used HIV-1 (amphotropic retrovirus) pseudotypes. These HIV-1 pseudotypes infected the majority of the cells in the cultures and expressed high levels of HIV-1 gene products in all except the SY5Y cells. The cell lines differed in the ability to support HCMV infection, but coinfection with HIV-1 had no effect on HCMV replication. The A172 cells were completely nonpermissive for HCMV gene expression, while HCMV replication in the singly infected T98G and SK-N-MC cell lines was restricted at the level of some early gene products. This resulted in complete and partial inhibition, respectively, of viral DNA synthesis. Dual infection of the A172, T98G, and SK-N-MC cells had no effect on HIV-1 replication. The other three cell lines, U373-MG, Hs 683, and SY5Y, were fully permissive for HCMV replication. In the U373-MG and Hs 683 cells, HCMV markedly inhibited the synthesis of HIV-1 gene products. In contrast, a transient stimulation of HIV-1 production followed by a repression was observed in the dually infected SY5Y cells. We conclude from these results that under conditions in which both HIV-1 and HCMV can undergo fully permissive infection, HCMV can repress HIV-1 gene expression. In cells in which HCMV replication is limited but HIV-1 replicates well, there is no effect on HIV-1 gene expression. However, activation of HIV-1, at least transiently, may occur in cells in which HIV-1 gene expression is limited. These studies suggest that a threshold level of some HIV-1 gene product(s) may obscure activation or promote repression of HIV replication by HCMV.

Herpesvirus proteinase: site-directed mutagenesis used to study maturational, release, and inactivation cleavage sites of precursor and to identify a possible catalytic site serine and histidine

The cytomegalovirus maturational proteinase is synthesized as a precursor that undergoes at least three processing cleavages. Two of these were predicted to be at highly conserved consensus sequences--one near the carboxyl end of the precursor, called the maturational (M) site, and the other near the middle of the precursor, called the release (R) site. A third less-well-conserved cleavage site, called the inactivation (I) site, was also identified near the middle of the human cytomegalovirus 28-kDa assemblin homolog. We have used site-directed mutagenesis to verify all three predicted sequences in the simian cytomegalovirus proteinase, and have shown that the proteinase precursor is active without cleavage at these sites. We have also shown that the P4 tyrosine and the P2 lysine of the R site were more sensitive to substitution than the other R- and M-site residues tested: substitution of alanine for P4 tyrosine at the R site severely reduced cleavage at that site but not at the M site, and substitution of asparagine for lysine at P2 of the R site reduced M-site cleavage and nearly eliminated I-site cleavage but had little effect on R-site cleavage. With the exception of P1' serine, all R-site mutations hindered I-site cleavage, suggesting a role for the carboxyl end of assemblin in I-site cleavage. Pulse-chase radiolabeling and site-directed mutagenesis indicated that assemblin is metabolically unstable and is degraded by cleavage at its I site. Fourteen amino acid substitutions were also made in assemblin, the enzymatic amino half of the proteinase precursor. Among those tested, only 2 amino acids were identified as essential for activity: the single absolutely conserved serine and one of the two absolutely conserved histidines. When the highly conserved glutamic acid (Glu22) was substituted, the proteinase was able to cleave at the M and I sites but not at the R site, suggesting either a direct (e.g., substrate recognition) or indirect (e.g., protein conformation) role for this residue in determining substrate specificity.

Expression and analysis of the human cytomegalovirus UL80-encoded protease: identification of autoproteolytic sites

The 45-kDa assembly protein of human cytomegalovirus is encoded by the C-terminal portion of the UL80 open reading frame (ORF). For herpes simplex virus, packaging of DNA is accompanied by cleavage of its assembly protein precursor at a site near its C terminus, by a protease encoded by the N-terminal region of the same ORF (F. Liu and B. Roizman, J. Virol. 65:5149-5156, 1991). By analogy with herpes simplex virus, we investigated whether a protease is contained within the N-terminal portion of the human cytomegalovirus UL80 ORF. The entire UL80 ORF was expressed in Escherichia coli, under the control of the phage T7 promoter. UL80 should encode a protein of 85 kDa. Instead, the wild-type construct produces a set of proteins with molecular masses of 50, 30, 16, 13, and 5 kDa. In contrast, when mutant UL80 is deleted of the first 14 amino acids, it produces only an 85-kDa protein. These results suggest that the UL80 polyprotein undergoes autoproteolysis. We demonstrate by deletional analysis and by N-terminal sequencing that the 30-kDa protein is the protease and that it originates from the N terminus of UL80. The UL80 polyprotein is cleaved at the following three sites: (i) at the C terminus of the assembly protein domain, (ii) between the 30- and 50-kDa proteins, and (iii) within the 30-kDa protease itself, which yields the 16- and 13-kDa proteins and may be a mechanism to inactivate the protease.

Processing of the herpes simplex virus assembly protein ICP35 near its carboxy terminal end requires the product of the whole of the UL26 reading frame

The herpes simplex virus (HSV) type 1 assembly protein ICP35 consists of a family of polypeptides, ranging in molecular weight from about 45,000-39,000. The lower molecular weight forms of ICP35 are derived from the higher molecular weight species by slow post-translational modification. The reading frame of gene UL26 and the region within this gene which exhibited homology to the cytomegalovirus assembly protein, the analogous protein to ICP35, were expressed separately under immediate-early (IE) gene regulation in a HSV vector containing a temperature-sensitive mutation in the major transcriptional regulator Vmw175. Monoclonal antibody specific for ICP35 immunoprecipitated several polypeptides with molecular weights around 75,000 from extracts of cells infected with a recombinant expressing the IE gene UL26 at the nonpermissive temperature (NPT). These results suggested that the UL26 gene specified a protein distinct from ICP35 but which had some antigenic sites in common with ICP35. In extracts of cells infected at the NPT with a recombinant expressing only the carboxy terminal half of UL26 coding sequences, the monoclonal antibody immunoprecipitated large amounts of the high molecular weight forms of ICP35. The lower molecular weight processed forms of ICP35, however, were not detectable. When cells were coinfected with both recombinants ICP35 was processed to its lower molecular weight forms. This processing step, which occurred near the carboxy terminus of ICP35, was not dependent on capsid formation. The work, together with previous information on the processing of the CMV assembly protein, suggests that UL26 product may be a protease.

A herpesvirus maturational proteinase, assemblin: identification of its gene, putative active site domain, and cleavage site

A herpesvirus proteinase activity has been identified and partially characterized by using the cloned enzyme and substrate genes in transient transfection assays. Evidence is presented that the proteinase gene of cytomegalovirus strain Colburn encodes a 590-amino acid protein whose N-terminal 249 residues contain the proteolytic activity and two domains that are highly conserved in the homologous protein of other herpesviruses. Insertion of a short amino acid sequence between these domains abolished proteinase activity, suggesting that this region constitutes part or all of the enzyme active site. Plasma desorption mass spectrometry was used to identify the C terminus of the mature assembly protein as alanine, enabling the recognition of a consensus proteinase cleavage sequence of V/L-X-A decreases S/V, near the C-terminal end of all herpesvirus assembly protein homologs. Interestingly, the proteinase and its substrate, the assembly protein precursor, are encoded by opposite halves of the same open reading frame.

The herpes simplex virus 1 gene encoding a protease also contains within its coding domain the gene encoding the more abundant substrate

The herpes simplex virus 1 open reading frames UL26 and UL26.5 are 3' coterminal. The larger, UL26 open reading frame encodes a protein approximately 80,000 in apparent molecular weight and contains the promoter and coding sequence of the UL26.5 gene, which specifies a capsid protein designated infected cell protein 35. The larger product contains in its entirety the amino acid sequence of the smaller protein. We report that the UL26 gene encodes a protease which catalyzes its own cleavage and that of the more abundant product of UL26.5. By inserting the coding sequence of an epitope to a cytomegalovirus monoclonal antibody and homologs of the immunoglobulin G binding domain of staphylococcal protein A into the 3' termini of the coding domains of the two open reading frames, we identified both products of the cleavage and determined that the cleavage site is approximately 20 amino acids from the carboxyl termini of both proteins.

Cytomegalovirus assembly protein nested gene family: four 3'-coterminal transcripts encode four in-frame, overlapping proteins

The genomic region encoding the assembly protein of simian cytomegalovirus (CMV) strain Colburn has been cloned, sequenced, and found to be organized as a nested set of four in-frame, 3'-coterminal genes, each with its own TATA promoter element and translational start codon, and all using a single 3' polyadenylation signal. The 3' end of the longest open reading frame (1.770 bp) was identical to the 930-bp sequence coding for the assembly protein precursor, as determined from a cDNA clone. The assembly protein coding region of human CMV strain AD169 was similarly organized, suggesting that both viral genomes could give rise to four independently transcribed 3'-coterminal RNAs coding for four overlapping, in-frame, carboxy-coterminal proteins. These predictions were tested and confirmed. Four mRNAs corresponding in size and sequence to those predicted were identified in both human and simian CMV-infected cells by using transcript-specific antisense oligonucleotide probes in Northern (RNA blot) assays. The 5' ends of the three largest of these Colburn transcripts were determined by S1 nuclease protection assays and found to map between the anticipated TATA sequences and corresponding translational start codons. The four predicted overlapping proteins were identified by immunoassays in lysates of simian and human CMV-infected cells by using an antiserum specific for the carboxyl end of the assembly protein precursor. The structural relationship of both sets of proteins was verified by comparing their peptide patterns following protein cleavage at tryptophan residues by N-chlorosuccinimide. The similar organization of the homologous coding regions in other herpesviruses into at least two nested, in-frame, 3'-coterminal genes is discussed.