Reconstitution of herpes simplex virus type 1 nuclear capsid egress in vitro

Newly assembled herpesvirus capsids travel from the nucleus to the plasma membrane by a mechanism that is poorly understood. Furthermore, the contribution of cellular proteins to this egress has yet to be clarified. To address these issues, an in vitro nuclear egress assay that reproduces the exit of herpes simplex virus type 1 (HSV-1) capsids from nuclei isolated from infected cells was established. As expected, the assay has all the hallmarks of intracellular transport assays, namely, a dependence on time, energy, and temperature. Surprisingly, it is also dependent on cytosol and was slightly enhanced by infected cytosol, suggesting an implication of both host and viral proteins in the process. The capsids escaped these nuclei by budding through the inner nuclear membrane, accumulated as enveloped capsids between the two nuclear membranes, and were released in cytosol exclusively as naked capsids, exactly as in intact cells. This is most consistent with the view that the virus escapes by crossing the two nuclear membranes rather than through nuclear pores. Unexpectedly, nuclei isolated at the nonpermissive temperature from cells infected with a U(L)26 thermosensitive protease mutant (V701) supported capsid egress. Although electron microscopy, biochemical, and PCR analyses hinted at a likely reconstitution of capsid maturation, DNA encapsidation could not be confirmed by a traditional SQ test. This assay should prove very useful for identification of the molecular players involved in HSV-1 nuclear egress.     

Small capsid protein pORF65 is essential for assembly of Kaposi's sarcoma-associated herpesvirus capsids

Kaposi's sarcoma-associated herpesvirus (KSHV) is the etiologic agent for KS tumors, multicentric Castleman's disease, and primary effusion lymphomas. Like other herpesvirus capsids, the KSHV capsid is an icosahedral structure composed of six proteins. The capsid shell is made up of the major capsid protein, two triplex proteins, and the small capsid protein. The scaffold protein and the protease occupy the internal space. The assembly of KSHV capsids is thought to occur in a manner similar to that determined for herpes simplex virus type 1 (HSV-1). Our goal was to assemble KSHV capsids in insect cells using the baculovirus expression vector system. Six KSHV capsid open reading frames were cloned and the proteins expressed in Sf9 cells: pORF25 (major capsid protein), pORF62 (triplex 1), pORF26 (triplex 2), pORF17 (protease), pORF17.5 (scaffold protein), and also pORF65 (small capsid protein). When insect cells were coinfected with these baculoviruses, angular capsids that contained internal core structures were readily observed by conventional electron microscopy of the infected cells. Capsids were also readily isolated from infected cells by using rate velocity sedimentation. With immuno-electron microscopy methods, these capsids were seen to be reactive to antisera to pORF65 as well as to KSHV-positive human sera, indicating the correct conformation of pORF65 in these capsids. When either virus expressing the triplex proteins was omitted from the coinfection, capsids did not assemble; similar to observations made in HSV-1-infected cells. If the virus expressing the scaffold protein was excluded, large open shells that did not attain icosahedral structure were seen in the nuclei of infected cells. The presence of pORF65 was required for capsid assembly, in that capsids did not form if this protein was absent as judged by both by ultrastructural analysis of infected cells and rate velocity sedimentation experiments. Thus, a novel outcome of this study is the finding that the small capsid protein of KSHV, like the major capsid and triplex proteins, is essential for capsid shell assembly.     

Cytochemical analysis of DNA organization during encapsidation in herpes simplex virus

The organization of intranuclear Herpes simplex virus DNA in rabbit fibroblast cells infected for 7 hr with HSV type 1 was examined before and during encapsidation by electron microscopic cytochemistry. Most non-encapsidated viral deoxyribonucleoprotein fibers exhibited a non-nucleosomal configuration. Empty capsids within the virus-specific regions of infected nuclei were wrapped with portions of the viral genome which adhered tightly to their surfaces even under conditions that loosened and spread apart other nucleoprotein fibers. During encapsidation, the internal surface of the capsid shell also appeared to bind a part of the viral genome, specifically the outer cage portion, which is detectable in methanol-dehydrated cells. Variations in the amount of DNA within the capsids indicated that the insertion of HSV genome into the capsid is a progressive process. The cage and core cylinder portions of the viral nucleoid appear to form and develop simultaneously. We propose that there may be binding sites on both the external and internal surfaces of the capsid shells which might play a role in the encapsidation process.     

Proteins Specified by Herpes Simplex Virus VIII. Characterization and Composition of Multiple Capsid Forms of Subtypes 1 and 2

Two classes of herpesvirus capsids, designated A and B, were isolated from the nuclei of human cells infected with herpes simplex virus (HSV). A and B capsids share in common four structural proteins, i.e., no. 5, 19, 23, and 24. B capsids contain 7.7 to 9.7 times more deoxyribonucleic acid than A capsids; moreover, they contain proteins no. 21 and 22a in addition. All of the proteins contained in the capsid except no. 22a are present in the enveloped nucleocapsids (virions) in approximately the same molar ratios. The capsid proteins of HSV-1 cannot be differentiated from their HSV-2 counterparts with respect to electrophoretic mobility. A third class of capsids, designated C capsids, was isolated from virions contained in the cytoplasm of infected cells by the same procedure used to obtain A and B capsids. The C capsids contain all of the proteins present in A capsids plus proteins 1 to 3 and 21.     

Native hepatitis B virions and capsids visualized by electron cryomicroscopy

Hepatitis B virus (HBV) infects more than 350 million people, of which one million will die every year. The infectious virion is an enveloped capsid containing the viral polymerase and double-stranded DNA genome. The structure of the capsid assembled in vitro from expressed core protein has been studied intensively. However, little is known about the structure and assembly of native capsids present in infected cells, and even less is known about the structure of mature virions. We used electron cryomicroscopy (cryo-EM) and image analysis to examine HBV virions (Dane particles) isolated from patient serum and capsids positive and negative for HBV DNA isolated from the livers of transgenic mice. Both types of capsids assembled as icosahedral particles indistinguishable from previous image reconstructions of capsids. Likewise, the virions contained capsids with either T = 3 or T = 4 icosahedral symmetry. Projections extending from the lipid envelope were attributed to surface glycoproteins. Their packing was unexpectedly nonicosahedral but conformed to an ordered lattice. These structural features distinguish HBV from other enveloped viruses.     

New endogenous herpesvirus of guinea pigs: biological and molecular characterization.

Two known guinea pig herpesviruses, guinea pig cytomegalovirus (GPCMV) and guinea pig herpes-like virus (GPHLV), and well characterized. A third herpesvirus (GPXV) was originally isolated from leukocytes of healthy strain 2 guinea pigs. Growth of GPXV in guinea pig embryo fibroblastic cells produced a characteristic cytopathic effect. Electron microscopy of guinea pig cells infected with GPXV revealed the morphological development of a herpesvirus. Cross-neutralization tests and immunoferritin electron microscopy demonstrated that GPXV, GPCMV, and GPHLV were serologically distinct herpeviruses of guinea pigs. To confirm the distinction between these three herpesviruses, DNA genomes were compared by CsCl equilibrium buoyant density measurements and restriction endonuclease cleavage analysis. 32P-labeled viral DNA ws obtained from nucleocapsids isolated from virus-infected cells, and the buoyant density of GPXV DNA differed from that of GPCMV and GPHLV. Cleavage of viral DNAs with restriction endonucleases followed by gel electrophoresis revealed distinct patterns for each virus.     

A null mutation in the gene encoding the herpes simplex virus type 1 UL37 polypeptide abrogates virus maturation

The tegument is an integral and essential structural component of the herpes simplex virus type 1 (HSV-1) virion. The UL37 open reading frame of HSV-1 encodes a 120-kDa virion polypeptide which is a resident of the tegument. To analyze the function of the UL37-encoded polypeptide a null mutation was generated in the gene encoding this protein. In order to propagate this mutant virus, transformed cell lines that express the UL37 gene product in trans were produced. The null mutation was transferred into the virus genome using these complementing cell lines. A mutant virus designated KDeltaUL37 was isolated based on its ability to form plaques on the complementing cell line but not on nonpermissive (noncomplementing) Vero cells. This virus was unable to grow in Vero cells; therefore, UL37 encodes an essential function of the virus. The mutant virus KDeltaUL37 produced capsids containing DNA as judged by sedimentation analysis of extracts derived from infected Vero cells. Therefore, the UL37 gene product is not required for DNA cleavage or packaging. The UL37 mutant capsids were tagged with the smallest capsid protein, VP26, fused to green fluorescent protein. This fusion protein decorates the capsid shell and consequently the location of the capsid and the virus particle can be visualized in living cells. Late in infection, KDeltaUL37 capsids were observed to accumulate at the periphery of the nucleus as judged by the concentration of fluorescence around this organelle. Fluorescence was also observed in the cytoplasm in large puncta. Fluorescence at the plasma membrane, which indicated maturation and egress of virions, was observed in wild-type-infected cells but was absent in KDeltaUL37-infected cells. Ultrastructural analysis of thin sections of infected cells revealed clusters of DNA-containing capsids in the proximity of the inner nuclear membrane. Occasionally enveloped capsids were observed between the inner and outer nuclear membranes. Clusters of unenveloped capsids were also observed in the cytoplasm of KDeltaUL37-infected cells. Enveloped virions, which were observed in the cytoplasm of wild-type-infected cells, were never detected in the cytoplasm of KDeltaUL37-infected cells. Crude cell fractionation of infected cells using detergent lysis demonstrated that two-thirds of the UL37 mutant particles were associated with the nuclear fraction, unlike wild-type particles, which were predominantly in the cytoplasmic fraction. These data suggest that in the absence of UL37, the exit of capsids from the nucleus is slowed. UL37 mutant particles can participate in the initial envelopment at the nuclear membrane, although this process may be impaired in the absence of UL37. Furthermore, the naked capsids deposited in the cytoplasm are unable to progress further in the morphogenesis pathway, which suggests that UL37 is also required for egress and reenvelopment. Therefore, the UL37 gene product plays a key role in the early stages of the maturation pathway that give rise to an infectious virion.     

Characterization of Polyoma DNA-Protein Complexes I. Electrophoretic Identification of the Proteins in a Nucleoprotein Complex Isolated from Polyoma-Infected Cells

A study was undertaken to examine polyoma DNA-protein complexes. A biophysical characterization of the complexes was made, and the proteins found in such complexes were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A comparison was made between a 52S nucleoprotein complex isolated from nuclei of 26-h polyoma-infected cells and a 28S virion core complex ejected out of mature virus particles. It was found that both complexes were reduced to a 20S viral DNA component plus free protein after incubation in 1 M NaCl or Sarkosyl. Treatment of the complexes with either Pronase or 0.5 M NaCl resulted in only partial removal of proteins from the viral DNA. After fixation in formaldehyde, the 52S nucleoprotein complex had a buoyant density of 1.45 g/cm³, and the virion core complex had a buoyant density of 1.59 g/cm³. Sodium dodecyl sulfate-polyacrylamide gel profiles of purified polyoma virion proteins, used as a reference marker, demonstrated three capsid proteins, V1 to V3, as well as four histones, V4 to V7, which constituted about 7% of the total virion protein. Electrophoretic analysis of the proteins comprising the 52S nucleoprotein complex revealed that the same seven proteins present in the mature virion were also found in this complex. However, the ratios of the proteins in the complex were quite different from that of the mature virion, with the four histones comprising 48% of the total complex protein. A pulse-chase experiment of the nucleoprotein complex demonstrated that the 26-h complex was chased into mature virions.     

Structure and Development of Viruses as Observed in the Electron Microscope: XI. Entry and Uncoating of Herpes Simplex Virus

Two morphologically distinct types of capsids are described. The dense capsid appeared to be disrupted near the cellular membrane with release of core material. The light capsid was more stable and was frequently encountered close to the nucleus, where empty capsids were also found. Pretreatment of cells before infection with either puromycin or actinomycin D markedly decreased the percentage of empty capsids. It is suggested that the two types of capsids play different roles in the process of initiating infection. One (the dense capsid) releases deoxyribonucleic acid (DNA) shortly after entry. This DNA is transcribed into a virus-specific ribonucleic acid, which codes for an enzyme capable of altering the permeability of the second type of capsid (the light capsid). In proximity to the nucleus, the infectious DNA then escapes without gross disruption of the capsid.     

Unique features of hepatitis C virus capsid formation revealed by de novo cell-free assembly

The assembly of hepatitis C virus (HCV) is poorly understood, largely due to the lack of mammalian cell culture systems that are easily manipulated and produce high titers of virus. This problem is highlighted by the inability of the recently established HCV replicon systems to support HCV capsid assembly despite high levels of structural protein synthesis. Here we demonstrate that up to 80% of HCV core protein synthesized de novo in cell-free systems containing rabbit reticulocyte lysate or wheat germ extracts assembles into HCV capsids. This contrasts with standard primate cell culture systems, in which almost no core assembles into capsids. Cell-free HCV capsids, which have a sedimentation value of approximately 100S, have a buoyant density (1.28 g/ml) on cesium chloride similar to that of HCV capsids from other systems. Capsids produced in cell-free systems are also indistinguishable from capsids isolated from HCV-infected patient serum when analyzed by transmission electron microscopy. Using these cell-free systems, we show that HCV capsid assembly is independent of signal sequence cleavage, is dependent on the N terminus but not the C terminus of HCV core, proceeds at very low nascent chain concentrations, is independent of intact membrane surfaces, and is partially inhibited by cultured liver cell lysates. By allowing reproducible and quantitative assessment of viral and cellular requirements for capsid formation, these cell-free systems make a mechanistic dissection of HCV capsid assembly possible.     

Incorporation of the Green Fluorescent Protein into the Herpes Simplex Virus Type 1 Capsid

The herpes simplex virus type 1 (HSV-1) UL35 open reading frame (ORF) encodes a 12-kDa capsid protein designated VP26. VP26 is located on the outer surface of the capsid specifically on the tips of the hexons that constitute the capsid shell. The bioluminescent jellyfish (Aequorea victoria) green fluorescent protein (GFP) was fused in frame with the UL35 ORF to generate a VP26-GFP fusion protein. This fusion protein was fluorescent and localized to distinct regions within the nuclei of transfected cells following infection with wild-type virus. The VP26-GFP marker was introduced into the HSV-1 (KOS) genome resulting in recombinant plaques that were fluorescent. A virus, designated K26GFP, was isolated and purified and was shown to grow as well as the wild-type virus in cell culture. An analysis of the intranuclear capsids formed in K26GFP-infected cells revealed that the fusion protein was incorporated into A, B, and C capsids. Furthermore, the fusion protein incorporated into the virion particle was fluorescent as judged by fluorescence-activated cell sorter (FACS) analysis of infected cells in the absence of de novo protein synthesis. Cells infected with K26GFP exhibited a punctate nuclear fluorescence at early times in the replication cycle. At later times during infection a generalized cytoplasmic and nuclear fluorescence, including fluorescence at the cell membranes, was observed, confirming visually that the fusion protein was incorporated into intranuclear capsids and mature virions.     

Activation of Guinea Pig Herpesvirus Antigen in Leukemic Lymphoblasts of Guinea Pig

Herpesvirus (GPHV) antigen is either present in very small amounts, or absent in leukemic lymphoblasts taken directly from strain 2 guinea pigs. However, after maintenance in tissue culture for 72 hr, almost 100% of these lymphoblasts contained GPHV antigen. The expression of GPHV antigen could be demonstrated by indirect immunofluorescent technique as well as by the direct (125)I labeled antibody technique. However, infectious virus or virus capsids could not be detected in these cells either by infectivity tests or electron microscopy.     

Differences in the subpopulations of the structural proteins of polyoma virions and capsids: biological functions of the multiple VP1 species.

The structural proteins of polyoma virions and capsids were analyzed by isoelectric focusing and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Polyoma virion VP1 was found to be composed of six distinct species which had pI's between pH 6.75 and 5.75. Polyoma capsid VP1 was found to contain four species with pI's between pH 6.60 and 5.75. The different forms of virion and capsid VP1 appeared to be generated by modifications (phosphorylation and acetylation) of the initial translation product. The most basic of the virion VP1 species (pI, pH 6.75) was absent in capsids and was found to be exclusively associated with the viral nucleoprotein complex. Three of the virion VP1 species and three of the capsid VP1 species were found in capsomere preparations enriched for hexon subunits. Two VP1 species were specifically immune precipitated from virions with hemagglutination-inhibiting antibodies. These two VP1 species were common to both virions and capsids. Polyoma virions, but not capsids, possessed a single VP1 species which was immune precipitated with neutralizing antibodies. Both virion and capsid VP2 were found to have pI's of approximately pH 5.50. Virion VP3 had a pI of approximately pH 7.00, whereas capsid VP3 had a pI of approximately pH 6.50.     

Characterization of post-translational products of herpes simplex virus gene 35 proteins binding to the surfaces of full capsids but not empty capsids.

We report on the properties of a genetically and immunologically related family of structural (gamma) polypeptides of herpes simplex virus 1 designated as infected cell polypeptides (ICP) 35. The members of this family were identified and studied with the aid of a panel of monoclonal antibodies exemplified by H745. This monoclonal antibody reacted with six bands (ICP35a to 35f) formed by ICPs contained in either HEp-2 or Vero cell lysates electrophoretically separated in denaturing gels and transferred to nitrocellulose sheets. The six bands had apparent molecular weights in the range 39,000 to 50,000. Traces of ICP35 with apparent molecular weights of 37,000 were also observed in some preparations. On two-dimensional separation ICP35 family members formed at least 20 spots reactive with H745. These differed in both isoelectric properties and electrophoretic mobility in denaturing gels. Pulse-chase experiments, together with results published earlier, indicate that ICP35a to 35d are cytoplasmic precursors to nuclear products. One of these corresponds to virion protein 22a, a component of capsids containing DNA accumulating in the nuclei of infected cells. ICP35 was labeled by 32Pi added to the medium, but the extent of phosphorylation varied and may be a determinant of isoelectric properties. Iodination studies indicate that ICP35e and 35f are the predominant forms of ICP35 present on the surface of full, nuclear capsids containing DNA. None of the members of the ICP35 family were detected in empty capsids. Surface iodination labeled the major capsid protein (ICP5) of empty capsids, but not of full capsids, indicating that ICP35e and 35f coat the surface of the viral capsid and block access to sites for iodination of ICP5, the major capsid protein.     

Hepatitis B virus core gene mutations which block nucleocapsid envelopment

Recently we generated a panel of hepatitis B virus core gene mutants carrying single insertions or deletions which allowed efficient expression of the core protein in bacteria and self-assembly of capsids. Eleven of these mutations were introduced into a eukaryotic core gene expression vector and characterized by trans complementation of a core-negative HBV genome in cotransfected human hepatoma HuH7 cells. Surprisingly, four mutants (two insertions [EFGA downstream of A11 and LDTASALYR downstream of R39] and two deletions [Y38-R39-E40 and L42]) produced no detectable capsids. The other seven mutants supported capsid formation and pregenome packaging/viral minus- and plus-strand-DNA synthesis but to different levels. Four of these seven mutants (two insertions [GA downstream of A11 and EHCSP downstream of P50] and two deletions [S44 and A80]) allowed virion morphogenesis and secretion. The mutant carrying a deletion of A80 at the tip of the spike protruding from the capsid was hepatitis B virus core antigen negative but wild type with respect to virion formation, indicating that this site might not be crucial for capsid-surface protein interactions during morphogenesis. The other three nucleocapsid-forming mutants (one insertion [LS downstream of S141] and two deletions [T12 and P134]) were strongly blocked in virion formation. The corresponding sites are located in the part of the protein forming the body of the capsid and not in the spike. These mutations may alter sites on the particle which contact surface proteins during envelopment, or they may block the appearance of a signal for the transport or the maturation of the capsid which is linked to viral DNA synthesis and required for envelopment.     

Herpes-Type Virus of the Frog Renal Adenocarcinoma: I. Virus Development in Tumor Transplants Maintained at Low Temperature

Development of the herpes-type virus of the frog kidney tumor was investigated by electron microscopy and high-resolution autoradiography in eyechamber transplants of tumor maintained at 7.5 C for up to 27 weeks. Virus particles were first detected at 10 weeks in nuclei containing aggregates of dense granular material. The initial incorporation of a pulse of (3)H-thymidine into these aggregates indicated that they contained newly synthesized viral deoxyribonucleic acid. Capsids enclosing doubleshelled cores were labeled with (3)H-thymidine before capsids with dense cores, and intermediate core forms were observed, suggesting that the double-shelled core transforms into the dense core. Particles with dense cores were observed while being enveloped by budding through the inner membrane of the nuclear envelope, and subsequently while being unenveloped in passing through the outer membrane into the cytoplasm. Virus particles within the cytoplasm acquired fibrillar coats and budded into vesicles, from which they were released, in enveloped form, at the cell surface. Tubular forms and particles considerably smaller than virus particles were regularly encountered in infected nuclei, and the relationship of these forms to virus replication is discussed.     

Temperature-sensitive BC mutants of simian virus 40: block in virion assembly and accumulation of capsid-chromatin complexes.

We examined the morphology, protein composition, and stability of the nucleoprotein complexes assembled in cells infected with simian virus 40 mutants belonging to the BC complementation group (tsBC11, tsBC208, tsBC214, tsB216, tsBC217, tsBC248, tsBC223, and tsBC274). We found that the 220S virions were not assembled in tsBC-infected cells under restrictive conditions. This block in assembly resulted in the accumulation of 75S chromatin in tsBC11-infected cells, as previously observed by Garber et al. (E.A. Garber, M.M. Seidman, and A.J. Levine, Virology 107:389-401, 1980). In cells infected with any other mutant listed above, the block in assembly resulted in the accumulation of 75S chromatin as well as nucleoprotein complexes sedimenting from 90 to 140S. Biochemical analysis revealed that these latter complexes contained the capsid proteins in addition to simian virus 40 DNA and the cellular core histones. Electron microscopic analysis clearly showed the association of the capsid proteins with the viral chromatin. Our results suggest that these proteins interact with simian virus 40 chromatin in the course of virion maturation and may thus play an active role in controlling simian virus 40 functions.     

Electron microscopic studies of tumor viruses. II. Entry and uncoating of Epstein-Barr virus.

Entry of Epstein-Barr virus into human lymphoblastoid cells (Daudi cells) was studied by electron microscopy. At the site of viral attachment, two distinct interactions conducive to penetration of the virus occurred between the viral envelope and cell membrane, namely, (i) simultaneous dissolution of both the envelope and cell membrane, presumably resulting in passage of viral capsids into the cytoplasm and (ii) dissolution confined to the cell membrane with resulting penetration of enveloped virus. In the latter case envelope dissolution appears to occur subsequently in the cytoplasm with release of capsids. Fusion of the viral envelope with the cell membrane was not observed. The capsids exhibited two distinct structural forms--one dense, the other translucent or light in appearance. The former disrupted near the cell membrane with release of viral cores into the cytoplasm whereas the light capsids containing dense cores migrated toward the nucleus and accumulated in the perinuclear region. Apparently the process of releasing deoxyribonucleic acid (DNA) from the light capsid is slowed down or prevented in Daudi cells. A hypothesis is presented concerning the manner in which these two types of capsids initiate infection.     

Herpes simplex virus type 1 entry into host cells: reconstitution of capsid binding and uncoating at the nuclear pore complex in vitro

During entry, herpes simplex virus type 1 (HSV-1) releases its capsid and the tegument proteins into the cytosol of a host cell by fusing with the plasma membrane. The capsid is then transported to the nucleus, where it docks at the nuclear pore complexes (NPCs), and the viral genome is rapidly released into the nucleoplasm. In this study, capsid association with NPCs and uncoating of the viral DNA were reconstituted in vitro. Isolated capsids prepared from virus were incubated with cytosol and purified nuclei. They were found to bind to the nuclear pores. Binding could be inhibited by pretreating the nuclei with wheat germ agglutinin, anti-NPC antibodies, or antibodies against importin beta. Furthermore, in the absence of cytosol, purified importin beta was both sufficient and necessary to support efficient capsid binding to nuclei. Up to 60 to 70% of capsids interacting with rat liver nuclei in vitro released their DNA if cytosol and metabolic energy were supplied. Interaction of the capsid with the nuclear pore thus seemed to trigger the release of the viral genome, implying that components of the NPC play an active role in the nuclear events during HSV-1 entry into host cells.