Seeing the portal in herpes simplex virus type 1 B capsids.

Resolving the nonicosahedral components in large icosahedral viruses remains a technical challenge in structural virology. We have used the emerging technique of Zernike phase-contrast electron cryomicroscopy to enhance the image contrast of ice-embedded herpes simplex virus type 1 capsids. Image reconstruction enabled us to retrieve the structure of the unique portal vertex in the context of the icosahedral capsid and, for the first time, show the subunit organization of a portal in a virus infecting eukaryotes. Our map unequivocally resolves the 12-subunit portal situated beneath one of the pentameric vertices, thus removing uncertainty over the location and stoichiometry of the herpesvirus portal.

Seeing the herpesvirus capsid at 8.5 A.

Human herpesviruses are large and structurally complex viruses that cause a variety of diseases. The three-dimensional structure of the herpesvirus capsid has been determined at 8.5 angstrom resolution by electron cryomicroscopy. More than 30 putative alpha helices were identified in the four proteins that make up the 0.2 billion-dalton shell. Some of these helices are located at domains that undergo conformational changes during capsid assembly and DNA packaging. The unique spatial arrangement of the heterotrimer at the local threefold positions accounts for the asymmetric interactions with adjacent capsid components and the unusual co-dependent folding of its subunits.

Manipulation of herpes simplex virus type 1 by dielectrophoresis.

The frequency-dependent dielectrophoretic behaviour of an enveloped mammalian virus, herpes simplex virus type 1 is described. It is demonstrated that over the range 10 kHz-20 MHz, these viral particles, when suspended in an aqueous medium of conductivity 5 mS m(-1), can be manipulated by both positive and negative dielectrophoresis using microfabricated electrode arrays. The observed transition from positive to negative dielectrophoresis at frequencies around 4.5 MHz is in qualitative agreement with a simple model of the virus as a conducting particle surrounded by an insulating membrane.

Cryomicroscopy of human cytomegalovirus virions reveals more densely packed genomic DNA than in herpes simplex virus type 1.

All members of the herpesvirus family have a characteristic virion structure, comprising a DNA containing, icosahedral capsid, embedded in a proteinaceous layer (tegument) and surrounded by a lipid envelope. Human cytomegalovirus (HCMV, the prototypic beta-herpesvirus) has a genome that is significantly larger (>50 %) than that of the alpha-herpesvirus HSV-1. Although the internal volume of the HCMV capsid is approximately 17 % larger than that of HSV-1, this slight increase in volume does not provide adequate space to encapsidate the full length HCMV genome at the same packing density as HSV-1. We have investigated the nature of DNA packing in HCMV and HSV-1 virions by electron-cryomicroscopy and image processing. Radial density profiles calculated from projection images of HCMV and HSV-1 capsids suggest that there is no increase in the volume of the HCMV capsid upon DNA packaging. Packing density of the viral DNA was assessed for both HCMV and HSV-1 by image analysis of both full and empty particles. Our results for packing density in HSV-1 are in good agreement with previously published measurements, showing an average inter-layer spacing of approximately 26 A. Measurements taken from our HCMV images, however, suggest that the viral genomic DNA is more densely packed, with an average inter-layer spacing of approximately 23 A. We propose therefore, that the combination of greater volume in HCMV capsids and increased packing density of viral DNA accounts for its ability to encapsidate a large genome.

Sequence determination and genetic content of the short unique region in the genome of herpes simplex virus type 1.

We have determined the complete DNA sequence of the short unique region in the genome of herpes simplex virus type 1, strain 17, and have interpreted it in terms of messenger RNAs and encoded proteins. The sequence contains variable regions whose length differs between DNA clones. The clones used for most of the analysis gave a short unique length of 12,979 base-pairs. We consider that this region contains 12 genes, which are expressed by mRNAs which have separate promoters, but may share 3'-termination sites, so that all but two mRNAs belong to one of four 3'-coterminal "families": 79% of the sequence is considered to be polypeptide coding. One pair of genes has an extensive out-of-frame overlap of coding sequences. The proteins encoded in the short unique region include two immediate-early species, two virion surface glycoproteins, and a DNA-binding species. Six of the genes have little or no previous characterization. From the nature of the amino acid sequences predicted for their encoded proteins, we deduce that several of these proteins may be membrane-associated.

Protein subunit structures in the herpes simplex virus A-capsid determined from 400 kV spot-scan electron cryomicroscopy.

The three-dimensional structure of the A-capsid of herpes simplex virus type-1 has been determined to a resolution of approximately 26 A by using 400 kV spot-scan electron cryomicroscopy and computer image reconstruction techniques. The density map of the capsid has revealed several new structural details in the protein subunits of pentons, hexons, and triplexes. Our structural analysis has provided further evidence for the assignment of the four major capsid proteins to these various subunits. VP5, a 150 kDa major capsid protein that makes up both the penton and the bulk of the hexon subunits, has three domains: an upper diamond-shaped domain, a middle stem-like domain, and a lower anchoring domain. Structural differences are noticeable between the VP5 subunits in various quasi-equivalent environments. A horn-shaped mass density present at the distal end of each hexon subunit but missing from the penton subunit has been assigned to VP26, a minor 12 kDa protein. The six types of triplexes have similar, but not identical, features that include two legs and an upper domain that has a tail, which are interpreted to be formed from two copies of VP23 (36 kDa) and one copy of VP19c (57 kDa), respectively. Each triplex has two arms that interact with the adjacent VP5 subunits, and the modes of interaction vary among the quasi-equivalent triplexes. The 25 A-thick floor of the capsid is formed by the close association of the lower domains of subunits from the hexons, pentons, and triplexes. The interior of the capsid is accessible through the trans-capsomeric channels and the holes at the base of each triplex. These openings may play a role in the transport of genomic DNA and scaffolding proteins during capsid morphogenesis.

Analysis of sequences important for herpes simplex virus type 1 latency-associated transcript promoter activity during lytic infection of tissue culture cells.

We describe the analysis of the herpes simplex virus type 1 (HSV-1) latency-associated transcript (LAT) promoter using an HSV-1-based vector system. Sequences under investigation for LAT promoter activity were analysed for their ability to direct chloramphenicol acetyltransferase gene expression, either in transfection assays or following their insertion into an HSV-1 vector from which the endogenous LAT promoter sequences had been removed. The analysis mapped the main determinants of LAT promoter activity during lytic infection of tissue culture cells to a 277 bp region between -279 and -2 relative to the recognized 5' end of the primary 8.3 kb transcript. The LAT promoter constructs behaved similarly in the context of the virus genome and in the plasmid-based transfection assays. Comparison of the relative activities following infection of fibroblast and neuroblastoma cell lines indicates that sequences upstream from -279 are important for LAT promoter activity in neurons.

Characterization of enveloped tegument structures (L particles) produced by alphaherpesviruses: integrity of the tegument does not depend on the presence of capsid or envelope.

Recent studies have shown that infection with herpes simplex virus type 1 (HSV-1) strain 17 generates in addition to virions a novel type of non-infectious particle. These particles, termed L particles, lack capsids and viral DNA, and consist predominantly of tegument and envelope proteins. We show that L particle production is not restricted to one strain of HSV-1, and that pseudorabies virus and equine herpesvirus type 1 also release particles which are similar in composition to and morphologically indistinguishable from HSV-1 L particles. Data obtained from monoclonal antibody analysis revealed that Vmw175, an immediate early HSV-1 polypeptide which had been previously identified as a virion component, is located predominantly in L particles and not in virions. Following removal of the envelope from L particles, the remaining tegument material largely retained its structural integrity, indicating that the structure of the tegument does not depend on the presence of the capsid or envelope.

Detailed analysis of the mRNAs mapping in the short unique region of herpes simplex virus type 1.

We have analysed the mRNAs which map within the short unique (US) region of the herpes simplex virus type 1 (HSV-1) genome. US has a total length of 12979 base pairs (1) and is extensively transcribed with approximately 94% of the total sequence present in cytoplasmic mRNAs and 79% of the total sequence considered to be protein coding. There are several examples of overlapping functions and multiple use of DNA sequence within this region. US contains 12 genes (1) which are expressed as 13 mRNAs. Two of these mRNAs are thought to arise from the same gene since they differ only slightly in the positions of their 5' ends and probably specify the same polypeptide. 11 of the 13 mRNAs are arranged into four nested families with unique 5' ends and common 3' co-termini. The other two mRNAs have unique 5' and 3' ends.

A 3' co-terminal family of mRNAs from the herpes simplex virus type 1 short region: two overlapping reading frames encode unrelated polypeptide one of which has highly reiterated amino acid sequence.

We have used DNA sequencing, mRNA mapping and in vitro translation to characterise three partially overlapping genes in the genome of herpes simplex virus (HSV) type 1. These genes specify three mRNAs with distinct 5' termini but a common 3' terminus, the longest of which is immediate-early (IE) mRNA-5. The 12,000 MW (12K) IE polypeptide encoded by IEmRNA-5 is translated from an 88 codon open reading frame, leaving a 1200 base 3' non-translated region. The second mRNA (mRNA-B) is initiated within the coding sequence of IEmRNA-5, and encodes a 21K polypeptide. The 12K and 21K polypeptide coding regions do not overlap. The third mRNA (mRNA-C) is initiated within the coding region of mRNA-B, and encodes a 33K polypeptide. The reading frame for 33K has a 110 codon out-of-frame overlap with the 21K reading frame. This is the first instance of overlapping genes described for HSV. The 21K polypeptide is thought to be a DNA binding protein and is remarkable for an array of 24 tandem repeats of the sequence X/Pro/Arg (where X represents predominantly Glu, Asp, Thr, Ser or Val) in its C-terminal portion. This array, which occupies most of the region of overlap with 33K, can vary in repeat number between virus strains.

Detailed structural analysis of two spliced HSV-1 immediate-early mRNAs.

The structures of two HSV-1 immediate-early mRNAs have been determined by nuclease-digestion procedures using 5' and 3' end-labelled DNA probes. These mRNAs, which map across the junctions between the short unique (US) and short repeat (IRS and TRS) genome regions, have common 5' portions located in IRS and TRS. The 3' portions, which extend into opposite ends of US, and unique. The DNA sequence encoding the common 5' portions largely comprises a 247 base pair (bp) leader region and a single intron of variable size. The variation in intron length is due to different copy numbers of a 22 bp tandem reiteration. A small proportion of the mRNA population is unspliced, but otherwise is identical to the more abundant spliced species.

Packaging-competent capsids of a herpes simplex virus temperature-sensitive mutant have properties similar to those of in vitro-assembled procapsids.

Newcomb and coworkers (W. W. Newcomb, F. L. Homa, D. R. Thomsen, F. P. Booy, B. L. Trus, A. C. Steven, J. V. Spencer, and J. C. Brown, J. Mol. Biol. 263:432-446, 1996; W. W. Newcomb, F. L. Homa, D. R. Thomsen, Z. Ye, and J. C. Brown, J. Virol. 68:6059-6063, 1994) have recently described an in vitro herpes simplex virus (HSV) capsid assembly product which, because of certain parallels between its properties and those of bacteriophage proheads, they have designated the procapsid. As in their bacteriophage counterparts, there are marked differences between the structures of the two types of particle, and conversion from the procapsid to the capsid form requires extensive reconfiguration of the subunits. This reconfiguration occurs spontaneously upon extended in vitro incubation. One of the distinctive features of the HSV procapsids is that, unlike mature capsids, they are unstable and disassemble upon storage at 2 degrees C. Using a mutant of HSV type 1 (ts1201), which has a lesion in the protease responsible for maturational cleavage of the scaffolding protein, we have demonstrated that capsids present within cells infected at nonpermissive temperatures are also cryosensitive and disappear if the cells are incubated at 0 degrees C. This suggests that ts1201 capsids may resemble procapsids in structure. However, ts1201 capsids remain cryosensitive following extended incubation at an elevated temperature and, therefore, do not appear to undergo the spontaneous reconfiguration seen with in vitro-assembled procapsids. The lesion in ts1201 is reversible, and capsids formed at the nonpermissive temperature can undergo maturational cleavage and go on to form infectious virions following downshift to permissive temperatures. The sensitivity of ts1201 capsids to low temperatures is closely correlated with the cleavage status of the scaffolding protein, suggesting that proteolysis may act to trigger their conversion to the stable form. The experiments described here provide the firmest evidence yet that the procapsid has a biologically relevant role in the virus life cycle.

Insertion of DNA sequences at a unique restriction enzyme site engineered for vector purposes into the genome of herpes simplex virus type 1.

We describe the construction of a novel herpes simplex virus (HSV) vector containing a unique XbaI restriction enzyme cloning site in an intergenic position in the short unique genome region. Sequences can be inserted at this site with high efficiency by ligation with XbaI-digested vector DNA. A series of plasmids has been designed for use with this vector. These allow protein coding sequences to be placed under the control of various transcriptional regulation signals and then isolated as XbaI fragments ready for insertion into the vector. The XbaI fragments also contain the beta-galactosidase gene thereby facilitating selection of recombinant virus by screening for blue plaques. A variant of the vector has been made based on the temperature-sensitive (ts) mutant tsK, which expresses only immediate early (IE) genes at non-permissive temperatures. Chloramphenicol acetyltransferase was used as a reporter gene to assess the fidelity of expression of sequences cloned into this position. Under these circumstances IE and early HSV promoters were shown to behave as expected in both wild-type and ts vectors.

Identification of genes encoding two capsid proteins (VP24 and VP26) of herpes simplex virus type 1.

The capsid of herpes simplex virus type 1 is composed of seven proteins. VP5, VP19C, VP22a and VP23 have been shown previously to be the products of genes UL19, UL38, UL26.5 and UL18, respectively. The genes encoding VP21, VP24 and VP26 have not been identified to date. We have determined amino acid sequences of fragments of isolated capsid proteins generated by partial cleavage with CNBr. The results confirm the gene assignments for VP5, VP19C and VP23. They also show that VP26 is the product of gene UL35 and that VP24 contains the protease domain present in the N-terminal portion of the UL26-encoded protein. VP21 was not investigated, but we suggest that it is the C-terminal portion of the UL26-encoded protein remaining after release of VP24 and that it thus corresponds to a form of VP22a extended at the N terminus.

Characterization of the genome of equine herpesvirus 1 subtype 2.

The genome structure of equine herpesvirus 1 (EHV-1) subtype 2 was shown by electron microscopic studies and restriction endonuclease site mapping to comprise two covalently linked segments (L, 109 kbp; S, 35 kbp). The S segment contains a unique sequence (US) flanked by a substantial inverted repeat (TRS/IRS). Thus, the genome structure of EHV-1 subtype 2 is similar to that published previously for EHV-1 subtype 1, but the two subtypes differ in the occurrences of EcoRI and BamHI restriction sites. Hybridization studies using cloned EHV-1 DNA showed that the genome of EHV-1 subtype 2 is colinear with the genomes of EHV-1 subtype 1 and herpes simplex virus type 1. DNA sequence data for four EHV-1 subtype 2 genes, including one potentially encoding a glycoprotein, were obtained by sequencing a 4574 bp BamHI fragment containing the junction between US and TRS. The genome structure, hybridization and sequence data confirm that EHV-1 subtype 2 is of the alphaherpesvirus lineage.

Kinetics of expression of the gene encoding the 65-kilodalton DNA-binding protein of herpes simplex virus type 1.

The 65-kilodalton DNA-binding protein (65KDBP) of herpes simplex virus type 1, encoded by gene UL42, is required for herpes simplex virus origin-dependent DNA replication (C.A. Wu, N.J. Nelson, D.J. McGeoch, and M.D. Challberg, J. Virol. 62:435-443, 1988). We found by indirect immunofluorescence with monoclonal antibody to 65KDBP that the protein was first detectable at 3 h postinfection. It localized first to the inner periphery of the nucleus, but accumulated in large globular compartments within the nucleus by 6 h postinfection in a pattern similar to that displayed by the major DNA-binding protein ICP8. Immune electron microscopy revealed that 65KDBP was associated with the marginated heterochromatin at the early times, but migrated further into the nucleus at late times when the only discernible areas devoid of 65KDBP were the nucleoli and heterochromatin. The 65KDBP gene is a member of the beta kinetic class as determined by the ability of the mRNA to be expressed at significant levels even in the absence of viral DNA synthesis. Furthermore, in the presence or absence of the DNA polymerase inhibitor phosphonoacetic acid, the patterns of accumulation of protein as well as mRNA were virtually indistinguishable from those displayed by the model beta genes encoding ICP8 and thymidine kinase. Nuclear run-on experiments demonstrated that maximum rates of 65KDBP gene transcription occurred prior to the maximum rate of progeny viral DNA synthesis and confirmed that the expression of the 65KDBP gene is regulated at the level of transcriptional initiation.

Assembly of enveloped tegument structures (L particles) can occur independently of virion maturation in herpes simplex virus type 1-infected cells.

Cells infected with a number of alphaherpesviruses produce non-infectious virion-related particles, termed L particles, in addition to infectious virions. L particles consist of the tegument and envelope components, but lack the virus capsid and DNA. Using a herpes simplex virus type 1 (HSV-1) temperature-sensitive mutant, ts1201, which fails to produce mature virions, we show that L particle production is independent of virion formation. Moreover, the quantity and protein composition of L particles generated by this mutant at the non-permissive temperature are indistinguishable from those produced in wild-type HSV-1 infections. Electron microscopy studies suggest that the processes governing the assembly of tegument and envelope components into L particles are similar to those involved in virion maturation.

The products of gene US11 of herpes simplex virus type 1 are DNA-binding and localize to the nucleoli of infected cells.

We have used antisera raised against synthetic oligopeptides to characterize the protein products from herpes simplex virus type 1 gene US11. These antisera recognized predominantly polypeptides of apparent molecular weight 21,000 and 22,000, but also polypeptides of apparent molecular weight 17,500, 15,000, 14,000 and 11,000. Tryptic peptide fingerprint analysis confirmed that these polypeptides were all closely related. The 21,000 and 22,000 molecular weight polypeptides were shown to be DNA-binding proteins, and immune electron microscopy demonstrated their strong localization within nucleoli of infected cells.

Intranuclear distribution of herpes simplex virus type 2 DNA synthesis: examination by light and electron microscopy.

Uptake of [3H]thymidine by serum-starved baby hamster kidney cells infected with herpes simplex virus type 2 was investigated by light microscopic and electron microscopic autoradiography. The distribution of incorporated label altered throughout the period of viral DNA synthesis. It was restricted initially to a few well-defined sites within the nucleus which increased in size and spread as infection proceeded until the entire nucleus was involved. The label was not associated with any identifiable subnuclear structure although there was a high degree of association with the nuclear membrane at early times post-infection.