Identification of a minimal hydrophobic domain in the herpes simplex virus type 1 scaffolding protein which is required for interaction with the major capsid protein

Structure of the scaffolding protein and portal within the bacteriophage P22 procapsid provides insights into the self-assembly process

In the assembly pathway of tailed double-stranded DNA (dsDNA) bacteriophages and herpesviruses, a procapsid with a dodecameric portal for DNA delivery at a unique vertex is initially formed. Appropriate procapsid assembly requires the transient presence of multiple copies of a scaffolding protein (SP), which is absent in the mature virion. However, how the SP contributes to dodecameric portal formation, facilitates portal and coat protein incorporation, and is subsequently released remains unclear because of a lack of structural information. Here, we present the structure of the SP-portal complex within the procapsid of bacteriophage P22 at 3-9 Å resolutions. The AlphaFold2-predicted SP model fits well with the density map of the complex. The SP forms trimers and tetramers that interact to yield a dome-like complex on the portal. Two SP domains mediate multimerization. Each trimer interacts with two neighboring portal subunits. The SP has a loop-hook-like structure that aids in coat protein recruitment during viral assembly. The loops of those SP subunits on the portal are positioned in clefts between adjacent portal subunits. Conformational changes in the portal during phage maturation may trigger the disassembly and release of the SP complex. Our findings provide insights into SP-assisted procapsid assembly in bacteriophage P22 and suggest that this strategy is also implemented by other dsDNA viruses, including herpesviruses.

The autophagy machinery interacts with EBV capsids during viral envelope release

Autophagy serves as a defense mechanism against intracellular pathogens, but several microorganisms exploit it for their own benefit. Accordingly, certain herpesviruses include autophagic membranes into their infectious virus particles. In this study, we analyzed the composition of purified virions of the Epstein-Barr virus (EBV), a common oncogenic γ-herpesvirus. In these, we found several components of the autophagy machinery, including membrane-associated LC3B-II, and numerous viral proteins, such as the capsid assembly proteins BVRF2 and BdRF1. Additionally, we showed that BVRF2 and BdRF1 interact with LC3B-II via their common protein domain. Using an EBV mutant, we identified BVRF2 as essential to assemble mature capsids and produce infectious EBV. However, BdRF1 was sufficient for the release of noninfectious viral envelopes as long as autophagy was not compromised. These data suggest that BVRF2 and BdRF1 are not only important for capsid assembly but together with the LC3B conjugation complex of ATG5-ATG12-ATG15L1 are also critical for EBV envelope release.

Cryo-electron microscopy structures of capsids and in situ portals of DNA-devoid capsids of human cytomegalovirus

The portal-scaffold complex is believed to nucleate the assembly of herpesvirus procapsids. During capsid maturation, two events occur: scaffold expulsion and DNA incorporation. The portal-scaffold interaction and the conformational changes that occur to the portal during the different stages of capsid formation have yet to be elucidated structurally. Here we present high-resolution structures of the A- and B-capsids and in-situ portals of human cytomegalovirus. We show that scaffolds bind to the hydrophobic cavities formed by the dimerization and Johnson-fold domains of the major capsid proteins. We further show that 12 loop-helix-loop fragments-presumably from the scaffold domain-insert into the hydrophobic pocket of the portal crown domain. The portal also undergoes significant changes both positionally and conformationally as it accompanies DNA packaging. These findings unravel the mechanism by which the portal interacts with the scaffold to nucleate capsid assembly and further our understanding of scaffold expulsion and DNA incorporation.

Cryo-Electron Tomography of the Herpesvirus Procapsid Reveals Interactions of the Portal with the Scaffold and a Shift on Maturation

Herpes simplex virus 1 (HSV-1) infects a majority of humans, causing mostly mild disease but in some cases progressing toward life-threatening encephalitis. Understanding the life cycle of the virus is important to devise countermeasures.

Herpes simplex virus 1 (HSV-1) requires seven proteins to package its genome through a vertex in its capsid, one of which is the portal protein, pUL6. The portal protein is also thought to facilitate assembly of the procapsid. While the portal has been visualized in mature capsids, we aimed to elucidate its role in the assembly and maturation of procapsids using cryo-electron tomography (cryoET). We identified the portal vertex in individual procapsids, calculated a subtomogram average, and compared that with the portal vertex in empty mature capsids (A-capsids). The resulting maps show the portal on the interior surface with its narrower end facing outwards, while maintaining close contact with the capsid shell. In the procapsid, the portal is embedded in the underlying scaffold, suggesting that assembly involves a portal-scaffold complex. During maturation, the capsid shell angularizes with a corresponding outward movement of the vertices. We found that in A-capsids, the portal translocates outward further than the adjacent capsomers and strengthens its contacts with the capsid shell. Our methodology also allowed us to determine the number of portal vertices in each capsid, with most having one per capsid, but some none or two, and rarely three. The predominance of a single portal per capsid supports facilitation of the assembly of the procapsid.

Kaposi's sarcoma-associated herpesvirus ORF17 plays a key role in capsid maturation

Kaposi's sarcoma-associated herpesvirus is a human rhadinovirus of the gammaherpesvirus sub-family. Although herpesviruses are well-studied models of capsid formation and its processes, those of KSHV remain unknown. KSHV ORF17 encoding the viral protease precursor (ORF17-prePR) is thought to contribute to capsid formation; however, functional information is largely unknown. Here, we evaluated the role of ORF17 during capsid formation by generating ORF17-deficient and ORF17 protease-dead KSHV. Both mutants showed a decrease in viral production but not DNA replication. ORF17 R-mut, with a point-mutation at the restriction or release site (R-site) by which ORF17-prePR can be functionally cleaved into a protease (ORF17-PR) and an assembly region (ORF17-pAP/-AP), failed to play a role in viral production. Furthermore, wild type KSHV produced a mature capsid, whereas ORF17-deficient and protease-dead KSHV produced a B-capsid, (i.e., a closed body possessing a circular inner structure). Therefore, ORF17 and its protease function are essential for appropriate capsid maturation.

Structures and Divergent Mechanisms in Capsid Maturation and Stabilization Following Genome Packaging of Human Cytomegalovirus and Herpesviruses

Herpesviruses are the causative agents of several diseases. Infections are generally mild or asymptomatic in immunocompetent individuals. In contrast, herpesvirus infections continue to contribute to significant morbidity and mortality in immunocompromised patients. Few drugs are available for the treatment of human herpesvirus infections, mainly targeting the viral DNA polymerase. Moreover, no successful therapeutic options are available for the Epstein–Barr virus or human herpesvirus 8. Most licensed drugs share the same mechanism of action of targeting the viral polymerase and thus blocking DNA polymerization. Resistances to antiviral drugs have been observed for human cytomegalovirus, herpes simplex virus and varicella-zoster virus. A new terminase inhibitor, letermovir, recently proved effective against human cytomegalovirus. However, the letermovir has no significant activity against other herpesviruses. New antivirals targeting other replication steps, such as capsid maturation or DNA packaging, and inducing fewer adverse effects are therefore needed. Targeting capsid assembly or DNA packaging provides additional options for the development of new drugs. In this review, we summarize recent findings on capsid assembly and DNA packaging. We also described what is known about the structure and function of capsid and terminase proteins to identify novels targets for the development of new therapeutic options.

The Apical Region of the Herpes Simplex Virus Major Capsid Protein Promotes Capsid Maturation

The herpesvirus capsid assembles in the nucleus as an immature procapsid precursor built around viral scaffold proteins. The event that initiates procapsid maturation is unknown, but it is dependent upon activation of the VP24 internal protease. Scaffold cleavage triggers angularization of the shell and its decoration with the VP26 and pUL25 capsid-surface proteins. In both the procapsid and mature angularized capsid, the apical region of the major capsid protein (VP5) is surface exposed. We investigated whether the VP5 apical region contributes to intracellular transport dynamics following entry into primary sensory neurons and also tested the hypothesis that conserved negatively charged amino acids in the apical region contribute to VP26 acquisition. To our surprise, neither hypothesis proved true. Instead, mutation of glutamic acid residues in the apical region delayed viral propagation and induced focal capsid accumulations in nuclei. Examination of capsid morphogenesis based on epitope unmasking, capsid composition, and ultrastructural analysis indicated that these clusters consisted of procapsids. The results demonstrate that, in addition to established events that occur inside the capsid, the exterior capsid shell promotes capsid morphogenesis and maturation.IMPORTANCE Herpesviruses assemble capsids and encapsidate their genomes by a process that is unlike those of other mammalian viruses but is similar to those of some bacteriophage. Many important aspects of herpesvirus morphogenesis remain enigmatic, including how the capsid shell matures into a stable angularized configuration. Capsid maturation is triggered by activation of a protease that cleaves an internal protein scaffold. We report on the fortuitous discovery that a region of the major capsid protein that is exposed on the outer surface of the capsid also contributes to capsid maturation, demonstrating that the morphogenesis of the capsid shell from its procapsid precursor to the mature angularized form is dependent upon internal and external components of the megastructure.

Visualizing Herpesvirus Procapsids in Living Cells

A complete understanding of herpesvirus morphogenesis requires studies of capsid assembly dynamics in living cells. Although fluorescent tags fused to the VP26 and pUL25 capsid proteins are available, neither of these components is present on the initial capsid assembly, the procapsid. To make procapsids accessible to live-cell imaging, we made a series of recombinant pseudorabies viruses that encoded green fluorescent protein (GFP) fused in frame to the internal capsid scaffold and maturation protease. One recombinant, a GFP-VP24 fusion, maintained wild-type propagation kinetics in vitro and approximated wild-type virulence in vivo The fusion also proved to be well tolerated in herpes simplex virus. Viruses encoding GFP-VP24, along with a traditional capsid reporter fusion (pUL25/mCherry), demonstrated that GFP-VP24 was a reliable capsid marker and revealed that the protein remained capsid associated following entry into cells and upon nuclear docking. These dual-fluorescent viruses made possible the discrimination of procapsids during infection and monitoring of capsid shell maturation kinetics. The results demonstrate the feasibility of imaging herpesvirus procapsids and their morphogenesis in living cells and indicate that the encapsidation machinery does not substantially help coordinate capsid shell maturation.

IMPORTANCE

The family Herpesviridae consists of human and veterinary pathogens that cause a wide range of diseases in their respective hosts. These viruses share structurally related icosahedral capsids that encase the double-stranded DNA (dsDNA) viral genome. The dynamics of capsid assembly and maturation have been inaccessible to examination in living cells. This study has overcome this technical hurdle and provides new insights into this fundamental stage of herpesvirus infection.

Dimerization-Induced Allosteric Changes of the Oxyanion-Hole Loop Activate the Pseudorabies Virus Assemblin pUL26N, a Herpesvirus Serine Protease

Herpesviruses encode a characteristic serine protease with a unique fold and an active site that comprises the unusual triad Ser-His-His. The protease is essential for viral replication and as such constitutes a promising drug target. In solution, a dynamic equilibrium exists between an inactive monomeric and an active dimeric form of the enzyme, which is believed to play a key regulatory role in the orchestration of proteolysis and capsid assembly. Currently available crystal structures of herpesvirus proteases correspond either to the dimeric state or to complexes with peptide mimetics that alter the dimerization interface. In contrast, the structure of the native monomeric state has remained elusive. Here, we present the three-dimensional structures of native monomeric, active dimeric, and diisopropyl fluorophosphate-inhibited dimeric protease derived from pseudorabies virus, an alphaherpesvirus of swine. These structures, solved by X-ray crystallography to respective resolutions of 2.05, 2.10 and 2.03 Å, allow a direct comparison of the main conformational states of the protease. In the dimeric form, a functional oxyanion hole is formed by a loop of 10 amino-acid residues encompassing two consecutive arginine residues (Arg136 and Arg137); both are strictly conserved throughout the herpesviruses. In the monomeric form, the top of the loop is shifted by approximately 11 Å, resulting in a complete disruption of the oxyanion hole and loss of activity. The dimerization-induced allosteric changes described here form the physical basis for the concentration-dependent activation of the protease, which is essential for proper virus replication. Small-angle X-ray scattering experiments confirmed a concentration-dependent equilibrium of monomeric and dimeric protease in solution.

Herpesviruses encode a unique serine protease, which is essential for herpesvirus capsid maturation and is therefore an interesting target for drug development. In solution, this protease exists in an equilibrium of an inactive monomeric and an active dimeric form. All currently available crystal structures of herpesvirus proteases represent complexes, particularly dimers. Here we show the first three-dimensional structure of the native monomeric form in addition to the native and the chemically inactivated dimeric form of the protease derived from the porcine herpesvirus pseudorabies virus. Comparison of the monomeric and dimeric form allows predictions on the structural changes that occur during dimerization and shed light onto the process of protease activation. These new crystal structures provide a rational base to develop drugs preventing dimerization and therefore impeding herpesvirus capsid maturation. Furthermore, it is likely that this mechanism is conserved throughout the herpesviruses.

DNA methyltransferase DNMT3A associates with viral proteins and impacts HSV-1 infection

Viral infections can alter the cellular epigenetic landscape, through modulation of either DNA methylation profiles or chromatin remodeling enzymes and histone modifications. These changes can act to promote viral replication or host defense. Herpes simplex virus type 1 (HSV-1) is a prominent human pathogen, which relies on interactions with host factors for efficient replication and spread. Nevertheless, the knowledge regarding its modulation of epigenetic factors remains limited. Here, we used fluorescently-labeled viruses in conjunction with immunoaffinity purification and MS to study virus-virus and virus-host protein interactions during HSV-1 infection in primary human fibroblasts. We identified interactions among viral capsid and tegument proteins, detecting phosphorylation of the capsid protein VP26 at sites within its UL37-binding domain, and an acetylation within the major capsid protein VP5. Interestingly, we found a nuclear association between viral capsid proteins and the de novo DNA methyltransferase DNA (cytosine-5)-methyltransferase 3A (DNMT3A), which we confirmed by reciprocal isolations and microscopy. We show that drug-induced inhibition of DNA methyltransferase activity, as well as siRNA- and shRNA-mediated DNMT3A knockdowns trigger reductions in virus titers. Altogether, our results highlight a functional association of viral proteins with the mammalian DNA methyltransferase machinery, pointing to DNMT3A as a host factor required for effective HSV-1 infection.

Highly specific salt bridges govern bacteriophage P22 icosahedral capsid assembly: identification of the site in coat protein responsible for interaction with scaffolding protein

Icosahedral virus assembly requires a series of concerted and highly specific protein-protein interactions to produce a proper capsid. In bacteriophage P22, only coat protein (gp5) and scaffolding protein (gp8) are needed to assemble a procapsid-like particle, both in vivo and in vitro. In scaffolding protein's coat binding domain, residue R293 is required for procapsid assembly, while residue K296 is important but not essential. Here, we investigate the interaction of scaffolding protein with acidic residues in the N-arm of coat protein, since this interaction has been shown to be electrostatic. Through site-directed mutagenesis of genes 5 and 8, we show that changing coat protein N-arm residue 14 from aspartic acid to alanine causes a lethal phenotype. Coat protein residue D14 is shown by cross-linking to interact with scaffolding protein residue R293 and, thus, is intimately involved in proper procapsid assembly. To a lesser extent, coat protein N-arm residue E18 is also implicated in the interaction with scaffolding protein and is involved in capsid size determination, since a cysteine mutation at this site generated petite capsids. The final acidic residue in the N-arm that was tested, E15, is shown to only weakly interact with scaffolding protein's coat binding domain. This work supports growing evidence that surface charge density may be the driving force of virus capsid protein interactions.

IMPORTANCE

Bacteriophage P22 infects Salmonella enterica serovar Typhimurium and is a model for icosahedral viral capsid assembly. In this system, coat protein interacts with an internal scaffolding protein, triggering the assembly of an intermediate called a procapsid. Previously, we determined that there is a single amino acid in scaffolding protein required for P22 procapsid assembly, although others modulate affinity. Here, we identify partners in coat protein. We show experimentally that relatively weak interactions between coat and scaffolding proteins are capable of driving correctly shaped and sized procapsids and that the lack of these proper protein-protein interfaces leads to aberrant structures. The present work represents an important contribution supporting the hypothesis that virus capsid assembly is governed by seemingly simple interactions. The highly specific nature of the subunit interfaces suggests that these could be good targets for antivirals.

A herpes simplex virus scaffold peptide that binds the portal vertex inhibits early steps in viral replication

Previous experiments identified a 12-amino-acid (aa) peptide that was sufficient to interact with the herpes simplex virus 1 (HSV-1) portal protein and was necessary to incorporate the portal into capsids. In the present study, cells were treated at various times postinfection with peptides consisting of a portion of the Drosophila antennapedia protein, previously shown to enter cells efficiently, fused to either wild-type HSV-1 scaffold peptide (YPYYPGEARGAP) or a control peptide that contained changes at positions 4 and 5. These 4-tyrosine and 5-proline residues are highly conserved in herpesvirus scaffold proteins and were previously shown to be critical for the portal interaction. Treatment early in infection with subtoxic levels of wild-type peptide reduced viral infectivity by over 1,000-fold, while the mutant peptide had little effect on viral yields. In cells infected for 3 h in the presence of wild-type peptide, capsids were observed to transit to the nuclear rim normally, as viewed by fluorescence microscopy. However, observation by electron microscopy in thin sections revealed an aberrant and significant increase of DNA-containing capsids compared to infected cells treated with the mutant peptide. Early treatment with peptide also prevented formation of viral DNA replication compartments. These data suggest that the antiviral peptide stabilizes capsids early in infection, causing retention of DNA within them, and that this activity correlates with peptide binding to the portal protein. The data are consistent with the hypothesis that the portal vertex is the conduit through which DNA is ejected to initiate infection.

Release of the herpes simplex virus 1 protease by self cleavage is required for proper conformation of the portal vertex

We identify an NLS within herpes simplex virus scaffold proteins that is required for optimal nuclear import of these proteins into infected or uninfected nuclei, and is sufficient to mediate nuclear import of GFP. A virus lacking this NLS replicated to titers reduced by 1000-fold, but was able to make capsids containing both scaffold and portal proteins suggesting that other functions can complement the NLS in infected cells. We also show that Vp22a, the major scaffold protein, is sufficient to mediate the incorporation of portal protein into capsids, whereas proper portal immunoreactivity in the capsid requires the larger scaffold protein pU(L)26. Finally, capsid angularization in infected cells did not require the HSV-1 protease unless full length pU(L)26 was expressed. These data suggest that the HSV-1 portal undergoes conformational changes during capsid maturation, and reveal that full length pU(L)26 is required for this conformational change.

Decoding bacteriophage P22 assembly: identification of two charged residues in scaffolding protein responsible for coat protein interaction

Proper assembly of viruses must occur through specific interactions between capsid proteins. Many double-stranded DNA viruses and bacteriophages require internal scaffolding proteins to assemble their coat proteins into icosahedral capsids. The 303 amino acid bacteriophage P22 scaffolding protein is mostly helical, and its C-terminal helix-turn-helix (HTH) domain binds to the coat protein during virion assembly, directing the formation of an intermediate structure called the procapsid. The interaction between coat and scaffolding protein HTH domain is electrostatic, but the amino acids that form the protein-protein interface have yet to be described. In the present study, we used alanine scanning mutagenesis of charged surface residues of the C-terminal HTH domain of scaffolding protein. We have determined that P22 scaffolding protein residues R293 and K296 are crucial for binding to coat protein and that the neighboring charges are not essential but do modulate the affinity between the two proteins.

Functional characterization of Kaposi's sarcoma-associated herpesvirus small capsid protein by bacterial artificial chromosome-based mutagenesis

A systematic investigation of interactions amongst KSHV capsid proteins was undertaken in this study to comprehend lesser known KSHV capsid assembly mechanisms. Interestingly the interaction patterns of the KSHV small capsid protein, ORF65 suggested its plausible role in viral capsid assembly pathways. Towards further understanding this, ORF65-null recombinant mutants (BAC-∆65 and BAC-stop65) employing a bacterial artificial chromosome (BAC) system were generated. No significant difference was found in both overall viral gene expression and lytic DNA replication between stable monolayers of 293T-BAC36 (wild-type) and 293T-BAC-ORF65-null upon induction with 12-O-tetradecanoylphorbol-13-acetate, though the latter released 30-fold fewer virions to the medium than 293T-BAC36 cells. Sedimentation profiles of capsid proteins of ORF65-null recombinant mutants were non-reflective of their organization into the KSHV capsids and were also undetectable in cytoplasmic extracts compared to noticeable levels in nuclear extracts. These observations collectively suggested the pivotal role of ORF65 in the KSHV capsid assembly processes.

Tryptophan residues in the portal protein of herpes simplex virus 1 critical to the interaction with scaffold proteins and incorporation of the portal into capsids

Incorporation of the herpes simplex virus 1 (HSV-1) portal vertex into the capsid requires interaction with a 12-amino-acid hydrophobic domain within capsid scaffold proteins. The goal of this work was to identify domains and residues in the UL6-encoded portal protein pUL6 critical to the interaction with scaffold proteins. We show that whereas the wild-type portal and scaffold proteins readily coimmunoprecipitated with one another in the absence of other viral proteins, truncation beyond the first 18 or last 36 amino acids of the portal protein precluded this coimmunoprecipitation. The coimmunoprecipitation was also precluded by mutation of conserved tryptophan (W) residues to alanine (A) at positions 27, 90, 127, 163, 241, 262, 532, and 596 of UL6. All of these W-to-A mutations precluded the rescue of a viral deletion mutant lacking UL6, except W163A, which supported replication poorly, and W596A, which fully rescued replication. A recombinant virus bearing the W596A mutation replicated and packaged DNA normally, and scaffold proteins readily coimmunoprecipitated with portal protein from lysates of infected cells. Thus, viral functions compensated for the W596A mutation's detrimental effects on the portal-scaffold interaction seen during transient expression of portal and scaffold proteins. In contrast, the W27A mutation precluded portal-scaffold interactions in infected cell lysates, reduced the solubility of pUL6, decreased incorporation of the portal into capsids, and abrogated viral-DNA cleavage and packaging.

Proline and tyrosine residues in scaffold proteins of herpes simplex virus 1 critical to the interaction with portal protein and its incorporation into capsids

Previous results showed that amino acids 449 to 457 of pU(L)26, a component of the scaffold of herpes simplex virus 1 capsids, were critical for interaction with the portal protein encoded by U(L)6 and for incorporation of the portal into capsids. To identify residues in this scaffold domain critical for the interaction with pU(L)6, the two proteins were coexpressed in the absence of other viral proteins and subjected to immunoprecipitation with scaffold-specific antibody. Coimmunoprecipitation of pU(L)6 was precluded by pU(L)26 mutations Y451A, P452A, and E454A but not by P449A, R456A, or Y450A. In infected cells, Y451A and P452A diminished solubilization of pU(L)6, reduced incorporation of the portal into the capsid, and precluded viral replication and DNA packaging. In contrast, E454A did not affect these parameters despite the fact that E454 is invariant in a number of different alphaherpesvirus scaffold proteins. These data suggest that the interaction between the scaffold E454A mutant and portal protein is rescued by other viral functions. Finally, we show that amino acids 448 to 459 of pU(L)26 are sufficient to interact with pU(L)6 in a glutathione S-transferase pulldown assay in the absence of other viral proteins and that this interaction is inhibited with excess peptide containing pU(L)26 amino acids 443 to 462. Together, these observations suggest that a direct interaction between this scaffold domain and portal protein mediates incorporation of the portal into the capsid.

Cryo-electron tomography of Kaposi's sarcoma-associated herpesvirus capsids reveals dynamic scaffolding structures essential to capsid assembly and maturation

Kaposi's sarcoma-associated herpesvirus (KSHV) is a recently discovered DNA tumor virus that belongs to the gamma-herpesvirus subfamily. Though numerous studies on KSHV and other herpesviruses, in general, have revealed much about their multilayered organization and capsid structure, the herpesvirus capsid assembly and maturation pathway remains poorly understood. Structural variability or irregularity of the capsid internal scaffolding core and the lack of adequate tools to study such structures have presented major hurdles to earlier investigations employing more traditional cryo-electron microscopy (cryoEM) single particle reconstruction. In this study, we used cryo-electron tomography (cryoET) to obtain 3D reconstructions of individual KSHV capsids, allowing direct visualization of the capsid internal structures and systematic comparison of the scaffolding cores for the first time. We show that B-capsids are not a structurally homogenous group; rather, they represent an ensemble of "B-capsid-like" particles whose inner scaffolding is highly variable, possibly representing different intermediates existing during the KSHV capsid assembly and maturation. This information, taken together with previous observations, has allowed us to propose a detailed pathway of herpesvirus capsid assembly and maturation.

Structural features of the scaffold interaction domain at the N terminus of the major capsid protein (VP5) of herpes simplex virus type 1

Protein-protein interactions drive the assembly of the herpes simplex virus type 1 capsid. A key interaction occurs between the C terminus of the scaffold protein and the N terminus of the major capsid protein (VP5). Results from alanine-scanning mutagenesis of hydrophobic residues in the N terminus of VP5 revealed seven residues (I27, L35, F39, L58, L65, L67, and L71) that reside in two predicted alpha helices (helix 1(22-42) and helix 2(58-72)) that are important for this bimolecular interaction. The goal of the present study was to further characterize the VP5 scaffold interaction domain (SID). Amino acids at the seven positions were replaced with L, M, V or P (I27); I, M, V, or P (L35, L58, L65, L67, and L71); and H, W, Y, or L (F39). Replacement with a hydrophobic side chain did not affect the interaction with scaffold protein in yeast cells or the ability of a virus specifying the mutation from replicating in cells. The mutation to the proline side chain abolished the interaction in all cases and was lethal for virus replication. Mutant viruses with proline substitutions in helix 1(22-42) at positions 27 and 35 assembled large open capsid shells that did not attain closure. Proline substitutions in helix 2(58-72) at either position 59, 65, or 67 abolished the accumulation of VP5 protein, and, at 58 and 71, although VP5 did accumulate, capsid shells were not assembled. Thus, the second SID, SID2, is highly structured, and this alpha helix (helix 2(58-72)) is likely involved in capsomere-capsomere interactions during shell accretion. Conserved glycine G59 in helix 2(58-72) was also mutated. G59 may act as a flexible "hinge" in helix 2(58-72) because decreasing the movement of this side chain by replacement with valine impaired capsid assembly. Thus, the N terminus of VP5 and the alpha helices embedded in this domain, as in the capsid shell proteins of some double-stranded DNA phages, are a key regulator of shell accretion and stabilization.

Cleavage of human cytomegalovirus protease pUL80a at internal and cryptic sites is not essential but enhances infectivity

The cytomegalovirus (CMV) maturational protease, assemblin, contains an "internal" (I) cleavage site absent from its homologs in other herpesviruses. Blocking this site for cleavage did not prevent replication of the resulting I(-) mutant virus. However, cells infected with the I(-) virus showed increased amounts of a fragment produced by cleavage at the nearby "cryptic" (C) site, suggesting that its replication may bypass the I-site block by using the C site as an alternate cleavage pathway. To test this and further examine the biological importance of these cleavages, we constructed two additional virus mutants-one blocked for C-site cleavage and another blocked for both I- and C-site cleavage. Infectivity comparisons with the parental wild-type virus showed that the I(-) mutant was the least affected for virus production, whereas infectivity of the C(-) mutant was reduced by approximately 40% and when both sites were blocked virus infectivity was reduced by nearly 90%, providing the first evidence that these cleavages have biological significance. We also present and discuss evidence suggesting that I-site cleavage destabilizes assemblin and its fragments, whereas C-site cleavage does not.

Molecular genetics of bacteriophage P22 scaffolding protein's functional domains

The assembly intermediates of the Salmonella bacteriophage P22 are well defined but the molecular interactions between the subunits that participate in its assembly are not. The first stable intermediate in the assembly of the P22 virion is the procapsid, a preformed protein shell into which the viral genome is packaged. The procapsid consists of an icosahedrally symmetric shell of 415 molecules of coat protein, a dodecameric ring of portal protein at one of the icosahedral vertices through which the DNA enters, and approximately 250 molecules of scaffolding protein in the interior. Scaffolding protein is required for assembly of the procapsid but is not present in the mature virion. In order to define regions of scaffolding protein that contribute to the different aspects of its function, truncation mutants of the scaffolding protein were expressed during infection with scaffolding deficient phage P22, and the products of assembly were analyzed. Scaffolding protein amino acids 1-20 are not essential, since a mutant missing them is able to fully complement scaffolding deficient phage. Mutants lacking 57 N-terminal amino acids support the assembly of DNA containing virion-like particles; however, these particles have at least three differences from wild-type virions: (i) a less than normal complement of the gene 16 protein, which is required for DNA injection from the virion, (ii) a fraction of the truncated scaffolding protein was retained within the virions, and (iii) the encapsidated DNA molecule is shorter than the wild-type genome. Procapsids assembled in the presence of a scaffolding protein mutant consisting of only the C-terminal 75 amino acids contained the portal protein, but procapsids assembled with the C-terminal 66 did not, suggesting portal recruitment function for the region about 75 amino acids from the C terminus. Finally, scaffolding protein amino acids 280 through 294 constitute its minimal coat protein binding site.

Identification of a region in the herpes simplex virus scaffolding protein required for interaction with the portal

The herpes simplex virus type 1 capsid is a protective shell that acts as a container for the genetic material of the virus. After assembly of the capsid, the viral DNA is translocated into the capsid interior through a channel formed by the portal. The portal is composed of a dodecamer of UL6 molecules which form a ring-like structure found at a single vertex within the icosahedron. Formation of portal-containing capsids minimally requires the four structural proteins (VP5, VP19C, VP23, and UL6) and a scaffolding protein (UL26.5). Recently, an interaction between UL26.5 and the portal has been identified, suggesting the scaffold functions by delivering the portal to the growing capsid shell. The aim of this study was to identify regions within UL26.5 required for its interaction with the portal. A specific region was identified by mutational analysis. Deletion of scaffold amino acids (aa) 143 to 151 was found to be sufficient to inhibit formation of the scaffold-portal complex as assayed in vitro. The aa 143 to 151 contain the sequence YYPGE, which is highly conserved among alpha herpesviruses. Although it did not bind to the portal, the Delta143-151 mutant was found to retain the ability to support assembly of morphologically normal capsids in vitro. Such capsids, however, did not contain the portal. The results suggest assembly of portal-containing capsids requires formation of a scaffold-portal complex in which intermolecular contact is dependent on scaffold aa 143 to 151.

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.

Assembly of Marek's disease virus (MDV) capsids using recombinant baculoviruses expressing MDV capsid proteins

The genes UL18, UL19, UL26, UL26.5, UL35 and UL38 of Marek's disease virus 1 (MDV-1) strain RB1B, encoding the homologues of herpes simplex virus type 1 (HSV-1) capsid proteins VP23, VP5, VP21-VP24, preVP22a, VP26 and VP19C, were identified and sequenced. Recombinant baculoviruses were used to express the six capsid genes in insect cells. Coexpression of the six genes or of UL18, UL19, UL26.5 and UL38 in insect cells resulted in the formation of capsids with a large core. In addition, electron microscopy of thin sections clearly revealed the presence of large numbers of small spherical particles. Experimental coinfection demonstrated that these small particles were associated with production of the preVP22a protein.

Three-dimensional structures of the A, B, and C capsids of rhesus monkey rhadinovirus: insights into gammaherpesvirus capsid assembly, maturation, and DNA packaging

Rhesus monkey rhadinovirus (RRV) exhibits high levels of sequence homology to human gammaherpesviruses, such as Kaposi's sarcoma-associated herpesvirus, and grows to high titers in cell cultures, making it a good model system for studying gammaherpesvirus capsid structure and assembly. We have purified RRV A, B, and C capsids, thus for the first time allowing direct structure comparisons by electron cryomicroscopy and three-dimensional reconstruction. The results show that the shells of these capsids are identical and are each composed of 12 pentons, 150 hexons, and 320 triplexes. Structural differences were apparent inside the shells and through the penton channels. The A capsid is empty, and its penton channels are open. The B capsid contains a scaffolding core, and its penton channels are closed. The C capsid contains a DNA genome, which is closely packaged into regularly spaced density shells (25 A apart), and its penton channels are open. The different statuses of the penton channels suggest a functional role of the channels during capsid maturation, and the overall structural similarities of RRV capsids to alphaherpesvirus capsids suggest a common assembly and maturation pathway. The RRV A capsid reconstruction at a 15-A resolution, the best achieved for gammaherpesvirus particles, reveals overall structural similarities to alpha- and betaherpesvirus capsids. However, the outer regions of the capsid, including densities attributed to the Ta triplex and the small capsomer-interacting protein (SCIP or ORF65), exhibit prominent differences from their structural counterparts in alphaherpesviruses. This structural disparity suggests that SCIP and the triplex, together with tegument and envelope proteins, confer structural and potentially functional specificities to alpha-, beta-, and gammaherpesviruses.

Assembly of the herpes simplex virus capsid: identification of soluble scaffold-portal complexes and their role in formation of portal-containing capsids

The herpes simplex virus type 1 (HSV-1) portal complex is a ring-shaped structure located at a single vertex in the viral capsid. Composed of 12 U(L)6 protein molecules, the portal functions as a channel through which DNA passes as it enters the capsid. The studies described here were undertaken to clarify how the portal becomes incorporated as the capsid is assembled. We tested the idea that an intact portal may be donated to the growing capsid by way of a complex with the major scaffolding protein, U(L)26.5. Soluble U(L)26.5-portal complexes were found to assemble when purified portals were mixed in vitro with U(L)26.5. The complexes, called scaffold-portal particles, were stable during purification by agarose gel electrophoresis or sucrose density gradient ultracentrifugation. Examination of the scaffold-portal particles by electron microscopy showed that they resemble the 50- to 60-nm-diameter "scaffold particles" formed from purified U(L)26.5. They differed, however, in that intact portals were observed on the surface. Analysis of the protein composition by sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrated that portals and U(L)26.5 combine in various proportions, with the highest observed U(L)6 content corresponding to two or three portals per scaffold particle. Association between the portal and U(L)26.5 was antagonized by WAY-150138, a small-molecule inhibitor of HSV-1 replication. Soluble scaffold-portal particles were found to function in an in vitro capsid assembly system that also contained the major capsid (VP5) and triplex (VP19C and VP23) proteins. Capsids that formed in this system had the structure and protein composition expected of mature HSV-1 capsids, including U(L)6, at a level corresponding to approximately 1 portal complex per capsid. The results support the view that U(L)6 becomes incorporated into nascent HSV-1 capsids by way of a complex with U(L)26.5 and suggest further that U(L)6 may be introduced into the growing capsid as an intact portal.

Mutation of single hydrophobic residue I27, L35, F39, L58, L65, L67, or L71 in the N terminus of VP5 abolishes interaction with the scaffold protein and prevents closure of herpes simplex virus type 1 capsid shells

Protein-protein interactions drive the assembly of the herpes simplex virus type 1 (HSV-1) capsid. A key interaction occurs between the C-terminal tail of the scaffold protein (pre-22a) and the major capsid protein (VP5). Previously (Z. Hong, M. Beaudet-Miller, J. Durkin, R. Zhang, and A. D. Kwong, J. Virol. 70:533-540, 1996) it was shown that the minimal domain in the scaffold protein necessary for this interaction was composed of a hydrophobic amphipathic helix. The goal of this study was to identify the hydrophobic residues in VP5 important for this bimolecular interaction. Results from the genetic analysis of second-site revertant virus mutants identified the importance of the N terminus of VP5 for the interaction with the scaffold protein. This allowed us to focus our efforts on a small region of this large polypeptide. Twenty-four hydrophobic residues, starting at L23 and ending at F84, were mutated to alanine. All the mutants were first screened for interaction with pre-22a in the yeast two-hybrid assay. From this in vitro assay, seven residues, I27, L35, F39, L58, L65, L67, and L71, that eliminated the interaction when mutated were identified. All 24 mutants were introduced into the virus genome with a genetic marker rescue/marker transfer system. For this system, viruses and cell lines that greatly facilitated the introduction of the mutants into the genome were made. The same seven mutants that abolished interaction of VP5 with pre-22a resulted in an absolute requirement for wild-type VP5 for growth of the viruses. The viruses encoding these mutations in VP5 were capable of forming capsid shells comprised of VP5, VP19C, VP23, and VP26, but the closure of these shells into an icosahedral structure was prevented. Mutation at L75 did not affect the ability of this protein to interact with pre-22a, as judged from the in vitro assay, but this mutation specified a lethal effect for virus growth and abolished the formation of any detectable assembled structure. Thus, it appears that the L75 residue is important for another essential interaction of VP5 with the capsid shell proteins. The congruence of the data from the previous and present studies demonstrates the key roles of two regions in the N terminus of this large protein that are crucial for this bimolecular interaction. Thus, residues I27, L35, and F39 comprise the first subdomain and residues L58, L65, L67 and L71 comprise a second subdomain of VP5. These seven hydrophobic residues are important for the interaction of VP5 with the scaffold protein and consequently the formation of an icosahedral shell structure that encloses the viral genome.

pH reduction as a trigger for dissociation of herpes simplex virus type 1 scaffolds

Assembly of the infectious herpes simplex virus type 1 virion is a complex, multistage process that begins with the production of a procapsid, which is formed by the condensation of capsid shell proteins around an internal scaffold fashioned from multiple copies of the scaffolding protein, pre-VP22a. The ability of pre-VP22a to interact with itself is an essential feature of this process. However, this self-interaction must subsequently be reversed to allow the scaffolding proteins to exit from the capsid to make room for the viral genome to be packaged. The nature of the process by which dissociation of the scaffold is accomplished is unknown. Therefore, to investigate this process, the properties of isolated scaffold particles were investigated. Electron microscopy and gradient sedimentation studies showed that the particles could be dissociated by low concentrations of chaotropic agents and by moderate reductions in pH (from 7.2 to 5.5). Fluorescence spectroscopy and circular dichroism analyses revealed that there was relatively little change in tertiary and secondary structures under these conditions, indicating that major structural transformations are not required for the dissociation process. We suggest the possibility that dissociation of the scaffold may be triggered by a reduction in pH brought about by the entry of the viral DNA into the capsid.

Recombinant full-length human cytomegalovirus protease has lower activity than recombinant processed protease domain in purified enzyme and cell-based assays

Herpesviruses encode a protease that is essential for virus replication. The protease undergoes cleavage to a processed form during capsid maturation. A recombinant 75 kDa form of the protease from human cytomegalovirus was purified and compared with the recombinant 29 kDa processed form. Modification with an active site titrant suggested that most of each recombinant protease preparation was active (66 and 86%, respectively). Protease activity was compared using a low-molecular weight peptide substrate and the native substrate, capsid assembly protein. In addition, a cell-based assay for both enzymes was developed in which the target sequence of the protease has been fused inframe into the herpes simplex virus VP16 molecule. Cleavage of the fusion protein by the protease releases the carboxyl terminal transactivation domain, resulting in a decrease in the ability of the fusion molecule to transactivate a target promoter linked to a reporter gene in mammalian cells. Results suggest that the 75 kDa form of the enzyme is significantly less active than the 29 kDa form by all criteria.

Regions of the herpes simplex virus scaffolding protein that are important for intermolecular self-interaction

The herpes simplex virus type 1 (HSV-1) scaffolding protein encoded by gene UL26.5 promotes the formation of the icosahedral capsid shell through its association with the major capsid protein VP5 and through intermolecular interactions with itself. Inside the capsid shell, the UL26.5 product together with the maturational protease, a minor protein, form a spherical structure which is broken down and released from the capsid during packaging of the viral genome. Selected residues from four internal regions of the HSV-1 scaffolding protein that have significant conservation of amino acids within the scaffolding proteins of alphaherpesviruses were mutated, and the properties of the proteins were examined. Only the HSV-1 scaffolding protein with mutations in the conserved N-terminal domain showed reduced interaction with the varicella-zoster virus homologue in a cell-based immunofluorescence assay, providing the first evidence that this domain in the HSV-1 protein is likely to be involved in intermolecular self-interaction. Scaffolding protein with mutations in this domain or in either of two other domains failed to assemble into scaffold-like particles but retained the ability to self-interact, although the aggregates were significant smaller than most of the aggregates formed by the wild-type protein. These results suggest that there are multiple domains involved in the intermolecular self-association of the HSV-1 scaffolding protein that can act independently of one another. This conclusion was supported by the observation that none of the mutant proteins with lesions in an individual domain, including a protein with mutations in a central region previously implicated in self-interaction (A. Pelletier, F. Dô, J. J. Brisebois, L. Lagacé, and M. G. Cordingley, J. Virol. 71:5197-5208, 1997), interfered with capsid assembly in a baculovirus expression system. A protein mutated in the central region and another conserved domain, both of which had been predicted to form coiled coils, was impaired for capsid formation but still retained the capacity to interact with VP5.

Mutations in the N-terminus of VP5 alter its interaction with the scaffold proteins of herpes simplex virus type 1

During the assembly process of herpes simplex virus type 1 capsids, there is an essential interaction between the C-terminal tail of the scaffold proteins (22a and 21) and the major capsid protein (VP5). Recent studies of spontaneous revertant viruses that overcome a blocked maturation cleavage site of the scaffold proteins have shown that the N-terminus of VP5 is important for this interaction. One of the revertant viruses, PR7, encodes a second-site mutation at residue 69 of VP5 which unlike wild-type VP5 fails to interact with 22a and thus gives white colonies in the yeast two-hybrid assay. In the present study a small DNA fragment, encoding residues 1 to 85 of wild-type and PR7 VP5, was mutagenized using error-prone PCR. Mutagenized DNA was used in the yeast two-hybrid assay to identify mutations in wild-type VP5 that resulted in loss of 22a binding (white colonies), or in PR7 VP5 that resulted in a gain of function (blue colonies). For the loss of function experiments, using KOS VP5, a row of eight thymidine nucleotides (codons 37-40) resulted in many frameshift mutations, which led us to terminate the study without reaching a statistically significant result. For the PR7 experiment, 30 clones were identified that had single amino acid substitutions, and these mutations were localized to amino acids 27-45 and 63-84 of VP5. The most frequent mutation was a reversion back to wild-type. The next most frequent were E28K and N63S, and these gave the highest beta-galactosidase enzyme activities (indicative of PR7VP5-22a interaction), 30 and 20% of wild-type, respectively. When E28K and N63S were transferred into the wild-type VP5 background, that is, in the absence of the PR7 mutation, they gave rise to different phenotypes. The E28K mutation lost its ability to interact with the scaffold proteins as judged by this assay. Therefore, it may be acting as a compensatory mutation whose phenotype is only expressed in the presence of the original PR7 mutation. However, the N63S mutation in the wild-type VP5 background increased the interaction, as judged by the beta-galactosidase activity, by a factor of 9 relative to when the PR7 mutation was present. Even more surprising, in the absence of the PR7 mutation the enzyme activity was still greater, by a factor of 2, than that observed for wild-type VP5. This study provides further evidence that the N-terminus of VP5 is in intimate association with the C-terminus of the scaffold proteins.

Herpes simplex virus DNA cleavage and packaging proteins associate with the procapsid prior to its maturation

Packaging of DNA into preformed capsids is a fundamental early event in the assembly of herpes simplex virus type 1 (HSV-1) virions. Replicated viral DNA genomes, in the form of complex branched concatemers, and unstable spherical precursor capsids termed procapsids are thought to be the substrates for the DNA-packaging reaction. In addition, seven viral proteins are required for packaging, although their individual functions are undefined. By analogy to well-characterized bacteriophage systems, the association of these proteins with various forms of capsids, including procapsids, might be expected to clarify their roles in the packaging process. While the HSV-1 UL6, UL15, UL25, and UL28 packaging proteins are known to associate with different forms of stable capsids, their association with procapsids has not been tested. Therefore, we isolated HSV-1 procapsids from infected cells and used Western blotting to identify the packaging proteins present. Procapsids contained UL15 and UL28 proteins; the levels of both proteins are diminished in more mature DNA-containing C-capsids. In contrast, UL6 protein levels were approximately the same in procapsids, B-capsids, and C-capsids. The amount of UL25 protein was reduced in procapsids relative to that in more mature B-capsids. Moreover, C-capsids contained the highest level of UL25 protein, 15-fold higher than that in procapsids. Our results support current hypotheses on HSV DNA packaging: (i) transient association of UL15 and UL28 proteins with maturing capsids is consistent with their proposed involvement in site-specific cleavage of the viral DNA (terminase activity); (ii) the UL6 protein may be an integral component of the capsid shell; and (iii) the UL25 protein may associate with capsids after scaffold loss and DNA packaging, sealing the DNA within capsids.

In Vitro Assembly of the Herpes Simplex Virus Procapsid: Formation of Small Procapsids at Reduced Scaffolding Protein Concentration

The herpes simplex virus 1 capsid is formed in the infected cell nucleus by way of a spherical, less robust intermediate called the procapsid. Procapsid assembly requires the capsid shell proteins (VP5, VP19C, and VP23) plus the scaffolding protein, pre-VP22a, a major component of the procapsid that is not present in the mature virion. Pre-VP22a is lost as DNA is packaged and the procapsid is transformed into the mature, icosahedral capsid. We have employed a cell-free assembly system to examine the role of the scaffolding protein in procapsid formation. While other reaction components (VP5, VP19C, and VP23) were held constant, the pre-VP22a concentration was varied, and the resulting procapsids were analyzed by electron microscopy and SDS-polyacrylamide gel electrophoresis. The results demonstrated that while standard-sized (T = 16) procapsids with a measured diameter of approximately 100 nm were formed above a threshold pre-VP22a concentration, at lower concentrations procapsids were smaller. The measured diameter was approximately 78 nm and the predicted triangulation number was 9. No procapsids larger than the standard size or smaller than 78-nm procapsids were observed in appreciable numbers at any pre-VP22a concentration tested. SDS-polyacrylamide gel analyses indicated that small procapsids contained a reduced amount of scaffolding protein compared to the standard 100-nm form. The observations indicate that the scaffolding protein concentration affects the structure of nascent procapsids with a minimum amount required for assembly of procapsids with the standard radius of curvature and scaffolding protein content.

Second-site mutations encoding residues 34 and 78 of the major capsid protein (VP5) of herpes simplex virus type 1 are important for overcoming a blocked maturation cleavage site of the capsid scaffold proteins

During assembly of the herpes simplex type 1 capsid, the major capsid protein VP5 interacts with the C-terminal residues of the scaffold proteins encoded by UL26 and UL26.5. Subsequent to capsid assembly the scaffold proteins are cleaved at the maturation site by a serine protease also encoded by UL26, thereby enabling the bulk of the scaffold proteins to be released from the capsid. Previously, a mutant virus (KUL26-610/611) was isolated in which this maturation cleavage site was blocked by replacing the Ala/Ser at the 610/611 cleavage site by Glu/Phe. This mutation was lethal and required a transformed cell line expressing wild-type UL26 gene products for growth. Although the mutation was lethal, spontaneous reversions occurred at a high frequency. Previously, a small number of revertants were isolated and all were found to have second-site mutations in VP5. The purpose of the present study was to do a comprehensive determination of the sites altered in VP5 by the second-site mutations. To do this, an additional 25 independent spontaneous revertants were characterized. Seven of the 25 arose by GC --> GT changes in codon 78, giving rise to an alanine to valine substitution. Four were the result of base changes at codon 34 but two different amino acids were produced as the changes were at different positions in the codon. Two mutations were detected at position 41 and mutations that occurred once were found at codons 69 and 80. Thus, 15 of the 25 second-site mutants were localized to codons 34 to 80 of VP5, which contains 1374 amino acids. The remaining 10 revertants had codon changes at nine different sites, of which the most N-terminal was altered at codon 187 and the most C-terminal at codon 1317. As noted in the much smaller study a preponderance of the second-site mutants in VP5 were altered in codons at the extreme N-terminus of VP5. It is especially noteworthy that 11 out of 25 of the mutations occurred at codons 34 and 78. As expected, all of the revertants isolated were shown to retain the original KUL26-610/611 mutation, and the scaffold proteins remain uncleaved. All showed decreased retention of VP24 in the B capsids compared to the wild-type KOS, but more than the KUL26-610/611 parental virus. The revertants all had decreased growth rates of 2 to 18% compared to that of KOS and showed varying degrees of sensitivity when grown at 39.5 degrees C. The mutations in VP5 of three of the previously isolated viruses (PR5, PR6, and PR7) were transferred into a wild-type background, i.e., a virus encoding wild-type UL26 and UL26.5 gene products. All replicated in nonpermissive (Vero) cells and cleaved scaffold proteins. PR5 and PR6 in the wild-type background gave wild-type burst sizes and gave C-capsids that retained VP24 at approximately wild-type levels. The third revertant, PR7, in the wild-type background showed only a twofold increase of burst size (to 20% of wild-type) and the capsids showed little or no increase of VP24 retention. Therefore, the second-site mutations of PR7 (R69C) by itself had a negative effect on virus replication. By contrast the temperature sensitivity of PR6 and PR7 remained unchanged in the wild-type background. Thus the temperature sensitivity of PR6 and PR7 resides in VP5 independently of the mutation in the UL26 cleavage site.

Evidence for controlled incorporation of herpes simplex virus type 1 UL26 protease into capsids

Herpes simplex virus type 1 (HSV-1) capsids are initially assembled with an internal protein scaffold. The scaffold proteins, encoded by overlapping in-frame UL26 and UL26.5 transcripts, are essential for formation and efficient maturation of capsids. UL26 encodes an N-terminal protease domain, and its C-terminal oligomerization and capsid protein-binding domains are identical to those of UL26.5. The UL26 protease cleaves itself, releasing minor scaffold proteins VP24 and VP21, and the more abundant UL26.5 protein, releasing the major scaffold protein VP22a. Unlike VP21 and VP22a, which are removed from capsids upon DNA packaging, we demonstrate that VP24 (containing the protease domain) is quantitatively retained. To investigate factors controlling UL26 capsid incorporation and retention, we used a mutant virus that fails to express UL26.5 (DeltaICP35 virus). Purified DeltaICP35 B capsids showed altered sucrose gradient sedimentation and lacked the dense scaffold core seen in micrographs of wild-type B capsids but contained capsid shell proteins in wild-type amounts. Despite C-terminal sequence identity between UL26 and UL26.5, DeltaICP35 capsids lacking UL26.5 products did not contain compensatory high levels of UL26 proteins. Therefore, HSV capsids can be maintained and/or assembled on a minimal scaffold containing only wild-type levels of UL26 proteins. In contrast to UL26.5, increased expression of UL26 did not compensate for the DeltaICP35 growth defect. While indirect, these findings are consistent with the view that UL26 products are restricted from occupying abundant UL26.5 binding sites within the capsid and that this restriction is not controlled by the level of UL26 protein expression. Additionally, DeltaICP35 capsids contained an altered complement of DNA cleavage and packaging proteins, suggesting a previously unrecognized role for the scaffold in this process.

Structure of the coat protein-binding domain of the scaffolding protein from a double-stranded DNA virus

Scaffolding proteins are required for high fidelity assembly of most high T number dsDNA viruses such as the large bacteriophages, and the herpesvirus family. They function by transiently binding and positioning the coat protein subunits during capsid assembly. In both bacteriophage P22 and the herpesviruses the extreme scaffold C terminus is highly charged, is predicted to be an amphipathic alpha-helix, and is sufficient to bind the coat protein, suggesting a common mode of action. NMR studies show that the coat protein-binding domain of P22 scaffolding protein exhibits a helix-loop-helix motif stabilized by a hydrophobic core. One face of the motif is characterized by a high density of positive charges that could interact with the coat protein through electrostatic interactions. Results from previous studies with a truncation fragment and the observed salt sensitivity of the assembly process are explained by the NMR structure.

The rice tungro bacilliform virus gene II product interacts with the coat protein domain of the viral gene III polyprotein

Rice tungro bacilliform virus (RTBV) is a plant pararetrovirus whose DNA genome contains four genes encoding three proteins and a large polyprotein. The function of most of the viral proteins is still unknown. To investigate the role of the gene II product (P2), we searched for interactions between this protein and other RTBV proteins. P2 was shown to interact with the coat protein (CP) domain of the viral gene III polyprotein (P3) both in the yeast two-hybrid system and in vitro. Domains involved in the P2-CP association have been identified and mapped on both proteins. To determine the importance of this interaction for viral multiplication, the infectivity of RTBV gene II mutants was investigated by agroinoculation of rice plants. The results showed that virus viability correlates with the ability of P2 to interact with the CP domain of P3. This study suggests that P2 could participate in RTBV capsid assembly.

HSV-1-based vectors for gene therapy of neurological diseases and brain tumors: part I. HSV-1 structure, replication and pathogenesis

The design of effective gene therapy strategies for brain tumors and other neurological disorders relies on the understanding of genetic and pathophysiological alterations associated with the disease, on the biological characteristics of the target tissue, and on the development of safe vectors and expression systems to achieve efficient, targeted and regulated, therapeutic gene expression. The herpes simplex virus type 1 (HSV-1) virion is one of the most efficient of all current gene transfer vehicles with regard to nuclear gene delivery in central nervous system-derived cells including brain tumors. HSV-1-related research over the past decades has provided excellent insight into the structure and function of this virus, which, in turn, facilitated the design of innovative vector systems. Here, we review aspects of HSV-1 structure, replication and pathogenesis, which are relevant for the engineering of HSV-1-based vectors.

Second site mutations in the N-terminus of the major capsid protein (VP5) overcome a block at the maturation cleavage site of the capsid scaffold proteins of herpes simplex virus type 1

VP5, the major capsid protein of herpes simplex virus type 1 (HSV-1), interacts with the C-terminal residues of the scaffold molecules encoded by the overlapping UL26 and UL26.5 open reading frames. Scaffold molecules are cleaved by a UL26 encoded protease (VP24) as part of the normal capsid assembly process. In this study, residues of VP5 have been identified that alter its interaction with the C-terminal residues of the scaffold proteins. A previously isolated virus (KUL26-610/611) was used that encoded a lethal mutation in the UL26 and UL26.5 open reading frames and required a transformed cell line that expresses these proteins for virus growth. The scaffold maturation cleavage site between amino acids 610 and 611 was blocked by changing Ala-Ser to Glu-Phe, which generated a new EcoRI restriction site. Revertant viruses, that formed small plaques on nontransformed cells, were detected at a frequency of 1:3800. Nine revertants were isolated, and all of them retained the EcoRI site and therefore were due to mutations at a second site. The second site mutations were extragenic. Using marker-transfer techniques, the mutation in one of the revertants was mapped to the 5' region of the gene encoding VP5. DNA sequence analysis was performed for the N-terminal 571 codons encoding VP5 for all of the revertant viruses. Six of the nine revertants showed a single base pair change that caused an amino acid substitution between residues 30 and 78 of VP5. Three of these were identical and changed Ala to Val at residue 78. The data provide a partial map of residues of VP5 that alter its interaction with scaffold proteins blocked at their normal cleavage site. The yeast two-hybrid system was used as a measure of the interaction between mutant VP5 and scaffold molecules and varied from 11% to nearly 100%, relative to wild-type VP5. One revertant gave no detectable interaction by this assay. The amount of UL26 encoded protease (VP24) in B capsids for KUL26-610/611 and for revertants was 7% and 25%, respectively, relative to the amount in capsids for wild-type virus. The lack of retention of the viral protease in the mutant virus and a fourfold increase for the revertants suggest an additional essential function for VP24 in capsid maturation, and a role in DNA packaging is indicated.

Roles of triplex and scaffolding proteins in herpes simplex virus type 1 capsid formation suggested by structures of recombinant particles

Typical herpes simplex virus (HSV) capsids contain seven proteins that form a T=16 icosahedron of 1,250-A diameter. Infection of cells with recombinant baculoviruses expressing two of these proteins, VP5 (which forms the pentons and hexons in typical HSV capsids) and VP19C (a component of the triplexes that connect adjacent capsomeres), results in the formation of spherical particles of 880-A diameter. Electron cryomicroscopy and computer reconstruction revealed that these particles possess a T=7 icosahedral symmetry, having 12 pentons and 60 hexons. Among the characteristic structural features of the particle are the skewed appearance of the hexons and the presence of intercapsomeric mass densities connecting the middle domain of one hexon subunit to the lower domain of a subunit in the adjacent hexon. We interpret these connecting masses as being formed by VP19C. Comparison of the connecting masses with the triplexes, which occupy equivalent positions in the T=16 capsid, reveals the probable locations of the single VP19C and two VP23 molecules that make up the triplex. Their arrangement suggests that the two triplex proteins have different roles in controlling intercapsomeric interactions and capsid stability. The nature of these particles and of other aberrant forms made in the absence of scaffold demonstrates the conformational adaptability of the capsid proteins and illustrates how VP23 and the scaffolding protein modulate the nature of the VP5-VP19C network to ensure assembly of the functional T=16 capsid.

Identification and sequence analysis of the Marek's disease virus serotype 2 homologous genes of the herpes simplex virus type 1 UL25, UL26 and UL26.5 genes

We identified and determined the nucleotide sequence of Marek's disease virus serotype 2 (MDV2) UL25, UL26 and UL26.5 homologous genes of herpes simplex virus type 1 (HSV-1). The UL25, UL26 and UL26.5 genes of HSV-1 encode virion proteins (UL25 and UL26.5) and serine protease (UL26). The deduced amino acid sequences of the three proteins show a high degree of homology to counterparts of HSV-1. By northern blot analyses we found that four transcripts whose sizes are 4.9, 3.9, 2.0 and 1.3 kb are transcribed from the domains of MDV2 genome containing the three genes. This is the first report dealing with UL25, UL26 and UL26.5 homologues of HSV-1 in MDV serotypes.

In vitro unfolding/refolding of wild type phage P22 scaffolding protein reveals capsid-binding domain

The scaffolding proteins of double-stranded DNA viruses are required for the polymerization of capsid subunits into properly sized closed shells but are absent from the mature virions. Phage P22 scaffolding subunits are elongated 33-kDa molecules that copolymerize with coat subunits into icosahedral precursor shells and subsequently exit from the precursor shell through channels in the procapsid lattice to participate in further rounds of polymerization and dissociation. Purified scaffolding subunits could be refolded in vitro after denaturation by high temperature or guanidine hydrochloride solutions. The lack of coincidence of fluorescence and circular dichroism signals indicated the presence of at least one partially folded intermediate, suggesting that the protein consisted of multiple domains. Proteolytic fragments containing the C terminus were competent for copolymerization with capsid subunits into procapsid shells in vitro, whereas the N terminus was not needed for this function. Proteolysis of partially denatured scaffolding subunits indicated that it was the capsid-binding C-terminal domain that unfolded at low temperatures and guanidinium concentrations. The minimal stability of the coat-binding domain may reflect its role in the conformational switching needed for icosahedral shell assembly.

Assembly of the herpes simplex virus procapsid from purified components and identification of small complexes containing the major capsid and scaffolding proteins

An in vitro system is described for the assembly of herpes simplex virus type 1 (HSV-1) procapsids beginning with three purified components, the major capsid protein (VP5), the triplexes (VP19C plus VP23), and a hybrid scaffolding protein. Each component was purified from insect cells expressing the relevant protein(s) from an appropriate recombinant baculovirus vector. Procapsids formed when the three purified components were mixed and incubated for 1 h at 37 degrees C. Procapsids assembled in this way were found to be similar in morphology and in protein composition to procapsids formed in vitro from cell extracts containing HSV-1 proteins. When scaffolding and triplex proteins were present in excess in the purified system, greater than 80% of the major capsid protein was incorporated into procapsids. Sucrose density gradient ultracentrifugation studies were carried out to examine the oligomeric state of the purified assembly components. These analyses showed that (i) VP5 migrated as a monomer at all of the protein concentrations tested (0.1 to 1 mg/ml), (ii) VP19C and VP23 migrated together as a complex with the same heterotrimeric composition (VP19C1-VP232) as virus triplexes, and (iii) the scaffolding protein migrated as a heterogeneous mixture of oligomers (in the range of monomers to approximately 30-mers) whose composition was strongly influenced by protein concentration. Similar sucrose gradient analyses performed with mixtures of VP5 and the scaffolding protein demonstrated the presence of complexes of the two having molecular weights in the range of 200,000 to 600,000. The complexes were interpreted to contain one or two VP5 molecules and up to six scaffolding protein molecules. The results suggest that procapsid assembly may proceed by addition of the latter complexes to regions of growing procapsid shell. They indicate further that procapsids can be formed in vitro from virus-encoded proteins only without any requirement for cell proteins.

Capsid structure of simian cytomegalovirus from cryoelectron microscopy: evidence for tegument attachment sites

We have used cryoelectron microscopy and image reconstruction to study B-capsids recovered from both the nuclear and the cytoplasmic fractions of cells infected with simian cytomegalovirus (SCMV). SCMV, a representative betaherpesvirus, could thus be compared with the previously described B-capsids of the alphaherpesviruses, herpes simplex virus type 1 (HSV-1) and equine herpesvirus 1 (EHV-1), and of channel catfish virus, an evolutionarily remote herpesvirus. Nuclear B-capsid architecture is generally conserved with SCMV, but it is 4% larger in inner radius than HSV-1, implying that its approximately 30% larger genome should be packed more tightly. Isolated SCMV B-capsids retain a relatively well preserved inner shell (or "small core") of scaffolding-assembly protein, whose radial-density profile indicates that this protein is approximately 16-nm long and consists of two domains connected by a low-density linker. As with HSV-1, the hexons but not the pentons of the major capsid protein (151 kDa) bind the smallest capsid protein (approximately 8 kDa). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed cytoplasmic B-capsid preparations to contain proteins similar in molecular weight to the basic phosphoprotein (approximately 119 kDa) and the matrix proteins (65 to 70 kDa). Micrographs revealed that these particles had variable amounts of surface-adherent material not present on nuclear B-capsids that we take to be tegument proteins. Cytoplasmic B-capsids were classified accordingly as lightly, moderately, or heavily tegumented. By comparing the three corresponding density maps with each other and with the nuclear B-capsid, two interactions were identified between putative tegument proteins and the capsid surface. One is between the major capsid protein and a protein estimated by electron microscopy to be 50 to 60 kDa; the other involves an elongated molecule estimated to be 100 to 120 kDa that is anchored on the triplexes, most likely on its dimer subunits. Candidates for the proteins bound at these sites are discussed. This first visualization of such linkages makes a step towards understanding the organization and functional rationale of the herpesvirus tegument.

Characterization of soluble hepatitis C virus RNA-dependent RNA polymerase expressed in Escherichia coli

Production of soluble full-length nonstructural protein 5B (NS5B) of hepatitis C virus (HCV) has been shown to be problematic and requires the addition of salts, glycerol, and detergents. In an effort to improve the solubility of NS5B, the hydrophobic C terminus containing 21 amino acids was removed, yielding a truncated NS5B (NS5BDeltaCT) which is highly soluble and monodispersed in the absence of detergents. Fine deletional analysis of this region revealed that a four-leucine motif (LLLL) in the hydrophobic domain is responsible for the solubility profile of the full-length NS5B. Enzymatic characterization revealed that the RNA-dependent RNA polymerase (RdRp) activity of this truncated NS5B was comparable to those reported previously by others. For optimal enzyme activity, divalent manganese ions (Mn2+) are preferred rather than magnesium ions (Mg2+), whereas zinc ions (Zn2+) inhibit the RdRp activity. Gliotoxin, a known poliovirus 3D RdRp inhibitor, inhibited HCV NS5B RdRp in a dose-dependent manner. Kinetic analysis revealed that HCV NS5B has a rather low processivity compared to those of other known polymerases.

How do animal DNA viruses get to the nucleus?

Genome and pre-genome replication in all animal DNA viruses except poxviruses occurs in the cell nucleus (Table 1). In order to reproduce, an infecting virion enters the cell and traverses through the cytoplasm toward the nucleus. Using the cell's own nuclear import machinery, the viral genome then enters the nucleus through the nuclear pore complex. Targeting of the infecting virion or viral genome to the multiplication site is therefore an essential process in productive viral infection as well as in latent infection and transformation. Yet little is known about how infecting genomes of animal DNA viruses reach the nucleus in order to reproduce. Moreover, this nuclear locus for viral multiplication is remarkable in that the sizes and composition of the infectious particles vary enormously. In this article, we discuss virion structure, life cycle to reproduce infectious particles, viral protein's nuclear import signal, and viral genome nuclear targeting.

Electrostatic interactions drive scaffolding/coat protein binding and procapsid maturation in bacteriophage P22

The first step in assembly of the bacteriophage P22 is the formation of a T=7 icosahedral "procapsid," the major components of which are the coat protein and an inner core composed of the scaffolding protein. Although not present in the mature virion, the scaffolding protein is required for procapsid assembly. Eleven amino-acid residues at the extreme carboxyl terminus of the scaffolding protein are required for binding to the coat protein, and upon deletion of these residues, approximately 20 additional residues become disordered. Sequence analysis and NMR data suggest that the 30 residues at the carboxyl terminus form a helix-loop-helix motif which is stabilized by interhelical hydrophobic interactions. This "coat protein recognition domain" presents an unusually high number of positively charged residues on one face, suggesting that electrostatic interactions between this domain and the coat protein may contribute to recognition and binding. We report here that high ionic strength (1 M NaCl) completely inhibited procapsid assembly in vitro. When scaffolding protein was added to empty procapsid "shells" of coat protein, 1 M NaCl partially inhibited the binding of scaffolding protein to the shells. This suggests that the positively charged coat protein recognition domain at the carboxyl terminus of the scaffolding protein binds to a negatively charged region on the coat protein. During DNA packaging, the scaffolding protein exits the procapsid; scaffolding protein exit is followed by the expansion of the procapsid into a mature capsid. Procapsid shells can be induced to undergo a similar expansion reaction in vitro by heating (45-70 degreesC); this process was also inhibited by 1 M NaCl. These results are consistent with a model in which negatively charged scaffold protein-binding domains in the coat proteins move apart during procapsid expansion; this relief of electrostatic repulsion could provide a driving force for expansion and subsequent maturation. High-salt concentrations would screen this repulsion, while packaging of DNA (a polyanion) in vivo may increase the instability of the procapsid enough to trigger its expansion.

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.

Functional domains of bacteriophage P22 scaffolding protein

Assembly of the bacteriophage P22 requires a 303 amino acid residue scaffolding protein. Two scaffolding protein deletion mutants, consisting of residues 141 to 303 and 141 to 292, have been described. We report here that the 141-303 fragment, but not the 141-292 fragment, promoted procapsid assembly in vitro, bound to preformed shells of coat protein, and bound to a coat protein affinity column. These findings suggest that the carboxyl-terminal half of the scaffolding protein is sufficient for promoting assembly, and that the 11 amino acid residues at the extreme carboxyl terminus are required for binding to the coat protein. Analysis of the products of in vitro assembly reactions suggests that the maximum amount of scaffolding protein that can pack into a procapsid is dictated by the internal volume of the procapsid rather than by a finite number of binding sites. However, when the amount of scaffolding protein was reduced to limiting values, both the wild-type protein and the 141-303 fragment assembled procapsids with the same number, rather than the same mass, of scaffolding protein molecules. When the 141-292 fragment was added to a mixture of coat and scaffolding proteins, the initial phase of procapsid assembly was inhibited, but the final yield and composition of the procapsids were not affected. Assembly by a covalent dimeric mutant scaffolding protein (R74C/L177I) was not inhibited by the 141-292 fragment, which suggests that the inhibition is due to the formation of inactive heterodimers between the 141-292 fragment and the monomeric scaffolding protein. The 141-303 fragment, which has less tendency to self-associate than the wild-type protein, formed aberrant species as well as normal procapsid-like particles when the rate of assembly was high, suggesting that scaffolding protein dimerization may play a role in ensuring fidelity of assembly. Alternatively, residues 1 to 140 may play a direct structural role in preventing inappropriate scaffolding/coat protein interactions.