Structure and function of herpesvirus genomes. II. EcoRl, Sbal, and HindIII endonuclease cleavage sites on herpes simplex virus

Viral forensic genomics reveals the relatedness of classic herpes simplex virus strains KOS, KOS63, and KOS79

Herpes simplex virus 1 (HSV-1) is a widespread global pathogen, of which the strain KOS is one of the most extensively studied. Previous sequence studies revealed that KOS does not cluster with other strains of North American geographic origin, but instead clustered with Asian strains. We sequenced a historical isolate of the original KOS strain, called KOS63, along with a separately isolated strain attributed to the same source individual, termed KOS79. Genomic analyses revealed that KOS63 closely resembled other recently sequenced isolates of KOS and was of Asian origin, but that KOS79 was a genetically unrelated strain that clustered in genetic distance analyses with HSV-1 strains of North American/European origin. These data suggest that the human source of KOS63 and KOS79 could have been infected with two genetically unrelated strains of disparate geographic origins. A PCR RFLP test was developed for rapid identification of these strains.

Physical Map of the Channel Catfish Virus Genome: Location of Sites for Restriction Endonucleases EcoRI, HindIII, HpaI, and XbaI

The overall arrangement of nucleotide sequences in the DNA of channel catfish virus has been studied by cleavage with four restriction endonucleases. Physical maps have been developed for the location of sites for EcoRI, HindIII, HpaI, and XbaI. The sum of the molecular weights of fragments generated by each restriction enzyme indicates a molecular weight of approximately 86 x 10(6) for the channel catfish virus genome. Fragments corresponding to the molecular ends of channel catfish virus DNA have been identified by their sensitivity to exonuclease treatment. The distribution of restriction sites in the genome shows that sequences included in a 12 x 10(6)-molecular weight region at one end are repeated with direct polarity at the other end, and that the overall genomic sequence order is nonpermuted.

A human cytomegalovirus deleted of internal repeats replicates with near wild type efficiency but fails to undergo genome isomerization

The class E genome of human cytomegalovirus (HCMV) contains long and short segments that invert due to recombination between flanking inverted repeats, causing the genome to isomerize into four distinct isomers. To determine if isomerization is important for HCMV replication, one copy of each repeat was deleted. The resulting virus replicated in cultured human fibroblasts with only a slight growth impairment. Restriction and Southern analyses confirmed that its genome is locked in the prototypic arrangement and unable to isomerize. We conclude that efficient replication of HCMV in fibroblasts does not require (i) the ability to undergo genome isomerization, (ii) genes that lie partially within the deleted repeats, or (iii) diploidy of genes that lie wholly within repeats. The simple genomic structure of this virus should facilitate studies of genome circularization, latency or persistence, and concatemer packaging as such studies are hindered by the complexities imposed by isomerization.

Machinery to support genome segment inversion exists in a herpesvirus which does not naturally contain invertible elements

In many herpesviruses, genome segments flanked by inverted repeats invert during DNA replication. It is not known whether this inversion is a consequence of an inherently recombinagenic replicative mechanism common to all herpesviruses or whether the replication enzymes of viruses with invertible segments have specifically evolved additional enzymatic activities to drive inversion. By artificially inserting a fusion of terminal sequences into the genome of a virus which normally lacks invertible elements (murine cytomegalovirus), we created a genome composed of long and short segments flanked by 1,359- and 543-bp inverted repeats. Analysis of genomic DNA from this virus revealed that inversion of both segments generates equimolar amounts of four isomers during the viral propagation necessary to produce DNA for analysis from a single viral particle. We conclude that a herpesvirus which naturally lacks invertible elements is able to support efficient segment inversion. Thus, the potential to invert is probably inherent in the replication machinery of all herpesviruses, irrespective of genome structure, and therefore genomes with invertible elements could have evolved simply by acquisition of inverted repeats and without concomitant evolution of enzymatic activities to mediate inversion. Furthermore, the recombinagenicity of herpesvirus DNA replication must have some importance independent of genome segment inversion.

Transcriptional targeting of herpes simplex virus for cell-specific replication

Tissue- or cell-specific targeting of vectors is critical to the success of gene therapy. We describe a novel approach to virus-mediated gene therapy, where viral replication and associated cytotoxicity are limited to a specific cell type by the regulated expression of an essential immediate-early viral gene product. This is illustrated with a herpes simplex virus type 1 (HSV-1) vector (G92A) whose growth is restricted to albumin-expressing cells. G92A was constructed by inserting an albumin enhancer/promoter-ICP4 transgene into the thymidine kinase gene of mutant HSV-1 d120, deleted for both copies of the ICP4 gene. This vector also contains the Escherichia coli lacZ gene under control of the thymidine kinase promoter, a viral early promoter, to permit easy detection of infected cells containing replicating vector. In the adult, albumin is expressed uniquely in the liver and in hepatocellular carcinoma and is transcriptionally regulated. The plaquing efficiency of G92A is > 10(3) times higher on human hepatoma cells than on non-albumin-expressing human cells. The growth kinetics of G92A in albumin-expressing cells is delayed compared with that of wild-type HSV-1, likely due to aberrant expression of ICP4 protein. Cells undergoing a productive infection expressed detectable levels of ICP4 protein, as well as the reporter gene product beta-galactosidase. Confining a productive, cytotoxic viral infection to a specific cell type should be useful for tumor therapy and the ablation of specific cell types for the generation of animal models of disease.

Inhibition of generation of authentic genomic termini of herpes simplex virus type 1 DNA in temperature-sensitive mutant BHK-21 cells with a mutated CCG1/TAF(II)250 gene

A temperature-sensitive (ts) mutant from the BHK-21 hamster cell line, tsBN462, has a defect in progression of the G1 phase at the nonpermissive temperature of 39.5 degrees C. The ts mutation in tsBN462 is located in the CCG1 gene, encoding the general transcription factor TAF(II)250. In tsBN462 at 39.5 degrees C, infectious progeny of herpes simplex virus type 1 (HSV-1) was not produced and generation of authentic genomic termini of HSV-1 was inhibited. HSV-1 concatemers containing L components in two possible orientations were produced in tsBN462 at 39.5 degrees C; hence, the generation of authentic genomic termini seemed to be dispensable for inversion of the L component. As production of mRNAs of HSV-1 genes of three kinetic classes in the tsBN462 at 39.5 degrees C was comparable to findings under permissive conditions, the sequential and regulated manner in which HSV-1 gene expression is processed is likely to be maintained in the nonpermissive condition.

Two open reading frames (ORF1 and ORF2) within the 2.0-kilobase latency-associated transcript of herpes simplex virus type 1 are not essential for reactivation from latency

The herpes simplex virus type 1 (HSV-1) latency-associated transcripts (LATs) are dispensable for establishment and maintenance of latent infection. However, the LATs have been implicated in reactivation of the virus from its latent state. Since the reported LAT deletion and/or insertion variants that are reactivation impaired contain deletions in the putative LAT promoter, it is not known which LAT sequences are involved in reactivation. To examine the role of the 2.0-kb LAT in the process of reactivation and the functional importance of the putative open reading frames (ORF1 and ORF2) contained within the 2.0-kb LAT, we have constructed an HSV-1 variant that contains a precise deletion and insertion within the LAT-specific DNA sequences using site-directed mutagenesis. The HSV-1 variant FS1001K contains an 1,186-bp deletion starting precisely from the 5' end of the 2.0-kb LAT and, for identification, a XbaI restriction endonuclease site insertion. The FS1001K genome contains no other deletions and/or insertions as analyzed by a variety of restriction endonucleases. The deletion in FS1001K removes the entire 556-bp intron within the 2.0-kb LAT, the first 229 nucleotides of ORF1, and the first 159 nucleotides of ORF2 without having an affect on the RL2 (ICP0) gene. Explant cocultivation reactivation assays indicated that this deletion had a minimal effect on reactivation of the variant FS1001K compared with the parental wild-type virus using a mouse eye model. As expected, Northern (RNA) blot analyses have shown that the variant virus (FS1001K) does not produce the 2.0-kb LAT or the 1.45- to 1.5-kb LAT either in vitro or in vivo; however, FS1001K produces an intact RL2 transcript in tissue culture. These data suggest that the 2.0-kb LAT putative ORF1 and ORF2 (or the first 1,186 bp of the 2.0-kb LAT) are dispensable for explant reactivation of latent HSV-1.

Herpes simplex virus type 1 gene expression and reactivation of latent infection in the central nervous system

Restricted gene expression takes place during latent infection of herpes simplex virus type 1 (HSV-1) in the human peripheral nervous system and has been linked with viral reactivation. The state of HSV-1 gene expression in the central nervous system (CNS) during latency is unclear and we, therefore, examined gene expression in the brainstem of experimental mice and normal humans. Only part of the transcription pattern present during latent infection in peripheral sensory ganglia (PSG) was identified in the human brainstem by in situ hybridization and Northern blot analysis for HSV-1-specific transcripts. Instead of three HSV-1 latency-associated transcripts (LATs) present in PSG and demonstrated by Northern blot analysis, only one was identified in mouse brainstem and none was detected in human brainstem. These findings might be attributed to the relatively low amounts of HSV-1-specific latency-associated RNAs in brainstem tissue. Combined with our inability to reactivate HSV-1 from explanted mouse brainstem, these findings suggest that tissue levels of latency-associated gene expression play a role in HSV-1 reactivation and have relevance to the very low incidence of HSV-1-induced CNS disease compared with peripheral mucocutaneous disease.

Preparation of herpes simplex virus type 1 genomic markers to differentiate strains of predominant genotypes

Analyses of restriction fragment length polymorphism (RFLP) of herpes simplex virus type 1 (HSV-1) isolated in Japan using restriction endonucleases recognizing 6-base pairs revealed the presence of two predominant genotypes of F1 and F35. Therefore, the possibility that the two predominant genotypes may differ in clinical manifestations had to be considered. To address the question of whether differences in genotype would reflect clinical presentations of HSV-1 infection, RFLP markers to differentiate strains of predominant genotypes are required. In the present work, DNAs of 66 HSV-1 strains were analyzed, using restriction endonucleases recognizing 4-base pairs of HaeIII, HhaI, and MboI, the objective being to detect a large number of RFLP. The relationship between the 154 identified RFLPs and each predominant genotype of F1 and F35 was traced. RFLPs closely related to each predominant genotype were manifested, as the first case of a set of RFLPs diagnostic for the predominant genotypes. These diagnostic RFLPs will facilitate knowledge on association of predominant genotypes with clinical manifestations by efficiently identifying HSV-1 strains of a genotype, and, in addition, HSV-1 strains of a predominant genotype derived from a common ancestor.

The herpes simplex virus type 1 (HSV-1) a sequence serves as a cleavage/packaging signal but does not drive recombinational genome isomerization when it is inserted into the HSV-2 genome

We inserted the terminal repeat (a sequence) of herpes simplex virus type 1 (HSV-1) strain KOS into the tk gene of HSV-2 strain HG52 in order to assess the ability of the HSV-1 a sequence to provoke genome isomerization events in an HSV-2 background. We found that the HSV-1 a sequence was cleaved by the HSV-2 cleavage/packaging machinery to give rise to novel genomic termini. However, the HSV-1 a sequence did not detectably recombine with the HSV-2 a sequence. These results demonstrate that the viral DNA cleavage/packaging system contributes to a subset of genome isomerization events and indicate that the additional recombinational inversion events that occur during infection require sequence homology between the recombination partners.

[Herpesviridae: classification and structure in 1991]

In 1981, herpesviruses were classified by the International Committee of Taxonomy of Viruses (ICTV, 1) inside the herpesviridae family. Progress in biotechnology and molecular biology during the last 10 yr, has permitted the characterization of new viruses and genomic structures. The objective of this paper is to collect the data found in the literature since 1981, to actualize the description of herpesviridae family.

The ability of pseudorabies virus to grow in different hosts is affected by the duplication and translocation of sequences from the left end of the genome to the UL-US junction

Pseudorabies virus is a herpesvirus which has a class 2 genome. However, under certain growth conditions it acquires a genome with class 3-like characteristics. In these variants, the leftmost sequences of the long (L) component of the viral genome have been duplicated and translocated to the right of the L component next to the short (S) component, resulting in an L component that is bracketed by inverted repeats. Consequently, the L component can invert and is found in two orientations relative to the S component. The translocation is accompanied invariably by a deletion of sequences that are normally present in the wild-type genome at the right end of the L component. The virion variants with an invertible L component have a growth advantage over wild-type virus in chicken embryo fibroblasts and chickens; they also have a growth disadvantage in mice or rabbit kidney cells. The changed growth characteristics of the variants reside entirely in the changed structure of the junction between the S and L components. Replacement of that region of the DNA with wild-type sequences restores the wild-type phenotype. To determine whether the modified growth characteristics of the variants are related to the translocation or to the deletion, mutants that have a deletion or that have a deletion as well as a translocation similar to those observed in the variants were constructed, and the growth characteristics of these mutants were determined. We show that the modified growth characteristics of the mutants with an invertible L component can be attributed to the translocation of the leftmost terminal sequences of the genome next to the inverted repeat; they are not related to the deletion of the sequences normally present at the right end of the L component. The translocation of the leftmost 325 bp of the genome is sufficient to confer upon the virus the modified cell-type-specific growth characteristics. Furthermore, the modified growth characteristics are contingent upon the presence of 68 bp spanning the internal junction between the L and S components.

Sequence requirements for DNA rearrangements induced by the terminal repeat of herpes simplex virus type 1 KOS DNA

We investigated the sequence requirements for the site-specific DNA cleavages and recombinational genome isomerization events driven by the terminal repeat or a sequence of herpes simplex virus type 1 KOS DNA by inserting a series of mutated a sequences into the thymidine kinase locus in the intact viral genome. Our results indicate that sequences located at both extremities of the a sequence contribute to these events. Deletions entering from the Ub side of the a sequence progressively reduced the frequency of DNA rearrangements, and further deletion of the internal DR2 repeat array had an additional inhibitory effect. This deletion series allowed us to map the pac1 site-specific DNA cleavage signal specifying the S-terminal cleavage to a sequence that is conserved among herpesvirus genomes. Constructs lacking this signal were unable to directly specify the S-terminal cleavage event but retained a reduced ability to give rise to S termini following recombination with intact a sequences. Deletions entering from the Uc side demonstrated that the copy of direct repeat 1 located adjacent to the Uc region plays an important role in the DNA rearrangements induced by the a sequence: mutants lacking this sequence displayed a reduced frequency of novel terminal and recombinational inversion fragments, and further deletions of the Uc region had a relatively minor additional effect. By using a construct in which site-specific cleavage was directed to heterologous DNA sequences, we found that the recombination events leading to genome segment inversion did not occur at the sites of DNA cleavage used by the cleavage-packaging machinery. This observation, coupled with the finding that completely nonoverlapping portions of the a sequence retained detectable recombinational activity, suggests that inter-a recombination does not occur by cleavage-ligation at a single specific site in herpes simplex virus type 1 strain KOS. The mutational sensitivity of the extremities of the a sequence leads us to hypothesize that the site-specific DNA breaks induced by the cleavage-packaging system stimulate the initiation of recombination.

DNA polymorphism among isolates from multiple sites of a patient with chronic herpes simplex virus, type 1 infection

DNA polymorphisms among independent isolates of herpes simplex virus (HSV) type 1 were studied from a 7-year-old male patient with recurrent infections of the skin and internal organs. In the patient's serum, HSV antibodies could not be detected by complement fixation, enzyme-linked immunosorbent assay (ELISA), or neutralization tests. ELISA tests for the presence of antibodies to human immunodeficiency virus were also negative. One HSV isolate was obtained from mesenteric nodes biopsied in 1983; one from skin in 1984; and three (postmortem) from brain, lungs, and liver in 1985. Restriction enzymes Eco RI, Bgl II, Hind III, Kpn I, and Bam H1 digestion patterns of the five isolates were similar. However, Sal I digests of isolates from skin, mesenteric nodes, lungs, and liver showed variations that were distinct from that of the brain isolate. Although Sal I digests of skin, mesenteric nodes, lungs, and liver isolates share a common variation in lacking F and G, the liver isolate can be further differentiated because of the gain of a restriction site on the H fragment. Thus, the three distinct variants observed were the isolates from brain (variant 1); from skin, mesenteric nodes, and lungs (variant 2); and from liver (variant 3). The fragments involved in variations among these isolates (presence or absence of Sal, G and H) are from the unique short and long regions (invariable regions) of the genome and therefore do not show heterogeneity in size. The extent of variation among these isolates is less than that seen among epidemiologically unrelated strains, suggesting that they originated from a single infecting strain, probably the brain isolate.

Physical mapping and nucleotide sequence of a herpes simplex virus type 1 gene required for capsid assembly

In this report, we describe some phenotypic properties of a temperature-sensitive mutant of herpes simplex type 1 (HSV-1) and present data concerning the physical location and nucleotide sequence of the genomic region harboring the mutation. The effect of shifts from the permissive to the nonpermissive temperature on infectious virus production by the mutant A44ts2 indicated that the mutated function is necessary throughout, or late in, the growth cycle. At the nonpermissive temperature, no major differences were detected in viral DNA or protein synthesis with respect to the parent A44ts+. On the other hand, electron microscopy of mutant-infected cells revealed that neither viral capsids nor capsid-related structures were assembled at the nonpermissive temperature. Additional analyses employing the Hirt extraction procedure showed that A44ts2 is also unable to mature replicated viral DNA into unit-length molecules under nonpermissive conditions. The results of marker rescue experiments with intact A44ts2 DNA and cloned restriction fragments of A44ts+ placed the lesion in the coordinate interval 0.553 to 0.565 (1,837 base pairs in region UL) of the HSV-1 physical map. No function has previously been assigned to this region, although it is known to be transcribed into two 5' coterminal mRNAs which code in vitro for a 54,000-molecular-weight polypeptide (K. P. Anderson, R. J. Frink, G. B. Devi, B. H. Gaylord, R. H. Costa, and E. K. Wagner, J. Virol. 37:1011-1027, 1981). We sequenced the interval 0.551 to 0.565 and found an open reading frame (ORF) for a 50,175-molecular-weight polypeptide. The predicted product of this ORF exhibits strong homology with the product of varicella-zoster virus ORF20 and lower, but significant, homology with the product of Epstein-Barr virus BORF1. For the three viruses, the corresponding ORFs lie just upstream of the gene coding for the large subunit of viral ribonucleotide reductase. The ORF described here corresponds to the ORF designated UL38 in the recently published nucleotide sequence of the HSV-1 UL region (D. J. McGeoch, M. A. Dalrymple, A. J. Davison, A. Dolan, M. C. Frame, D. McNab, L. J. Perry, J. E. Scott, and P. Taylor, J. Gen. Virol. 69:1531-1574, 1988).

Latent herpes simplex virus type 1 transcription in human trigeminal ganglia

We studied latent herpes simplex virus type 1 gene expression in human trigeminal ganglia. Two transcripts were mapped to a 3.0-kilobase region within the long repeat region and appeared to be located in neuronal nuclei. These viral RNAs were not abundant during lytic replication and may represent an alternative pattern of herpes simplex virus type 1 gene expression involved in the pathogenesis of latent infection.

Restriction endonucleases recognizing DNA sequences of four base pairs facilitate differentiation of herpes simplex virus type 1 strains

Variation of restriction endonuclease cleavage patterns between herpes simplex virus type 1 (HSV-1) strains was investigated using restriction endonucleases recognizing DNA sequences of four base pairs (4-bp enzymes) (HaeIII, HhaI, Sau3AI). The analysis made feasible identification of variations not heretofore detectable, using enzymes recognizing DNA sequences of six base pairs (BamHI, KpnI, SalI), and proved to be most useful for distinction and classification of HSV-1 strains. Ten of the fifteen strains analysed using 4-bp enzymes were closely related, and were put into group 1, and the other five not so related strains were classed into the non-group 1. The observations suggested a possible common ancestor from which group 1 strains had derived.

Restriction enzyme maps of the macropodid herpesvirus 2 genome

The DNA of macropodid herpesvirus 2 (dorcopsis wallaby herpesvirus) was analysed using restriction enzymes and molecular cloning techniques. Sets of EcoRI and SalI clones were prepared which represented approximately 85 per cent of the genome, and these clones were used to map the DNA by double-digestion and hybridization experiments. Data on uncloned regions were obtained by analysing fragments excised from agarose gels, and terminal fragments were identified by exonuclease III digestion. The genome was shown to be approximately 135 kilobases (kb) long. It has a long unique sequence (95 kb) bounded by repeat sequences (5.5 kb) and joined at one end to a short unique sequence (15 kb) also bounded by repeat sequences (7.0 kb) in a manner similar to that of herpes simplex viruses 1 and 2.

Transition from a heterozygous to a homozygous state of a pair of loci in the inverted repeat sequences of the L component of the herpes simplex virus type 1 genome

The behavior of herpes simplex virus type 1 heterozygous isolates, in which the two inverted repeats of the L component (RL) were differentiated by a polymorphism marker (the presence [type B] or absence [type A] of a SalI site), was investigated. The progeny viruses derived from the heterozygote (A/B) consisted of heterozygotes (A/B), type A homozygotes (A/A), and type B homozygotes (B/B). The heterology between RL, albeit tolerated, was unstable, as is the case with heterology between the repeats of the S component. The two repeats TRL (terminal) and IRL (internal) were equipotent in generating homozygotes from a heterozygote. Data obtained from an analysis of 426 progeny viruses derived from heterozygous clones supported the hypothesis that the two loci in RL of a herpes simplex virus type 1 genome are determined as a random combination of the corresponding two loci in RL of the parent virus and that the ratio of heterozygotes/type A homozygotes/type B homozygotes in the progeny viruses from a heterozygote is expected to be 2:1:1. An ephemeral dominance of one type of homozygote over the other was observed in subclones from several heterozygous clones.

A method for identifying the viral genes required for herpesvirus DNA replication

Several laboratories have shown that transfected plasmid DNAs containing either of the two known origins of herpes simplex virus (HSV) DNA replication, oriS or oriL, are replicated in HSV-1-infected cells or in cells cotransfected with virion DNA. I have found that HSV-1 (KOS) DNA digested to completion with the restriction enzyme Xba I is as efficient as intact viral DNA in supporting the in vivo replication of cotransfected plasmids containing oriS. On the basis of this result, several of the Xba I restriction fragments of HSV-1 DNA were cloned into the plasmid vector pUC19, and combinations of cloned DNAs were tested for their ability to supply the trans-acting functions required for HSV origin-dependent replication. A combination of five cloned fragments of HSV-1 can supply all of the necessary functions: Xba I C (coordinates 0.074-0.294), Xba I F (coordinates 0.294-0.453), Xba I E (coordinates 0.453-0.641), Xba I D (coordinates 0.641-0.830), and EcoRI JK (coordinates 0.0-0.086; 0.830-0.865). Transient plasmid replication in this system is dependent on the presence of either oriS or oriL in cis. The plasmid containing Xba I F can be replaced by two smaller plasmids, one of which contains only the gene for the HSV-encoded DNA polymerase, and the other of which contains only the gene for the major DNA binding protein (ICP8). Thus, plasmid DNA replication in this system depends on two of the genes known from genetic studies to be essential for viral DNA replication in infected cells. This system defines a simple complementation assay for cloned fragments of HSV DNA that contain other genes involved in viral DNA replication and should lead to the rapid identification of all such genes.

Establishment of a rat cell line inducible for the expression of human cytomegalovirus immediate-early gene products by protein synthesis inhibition

Upon transfection of Rat-2-TK- cells with plasmid pES, containing the cloned 7.0-kilobase (kb) EcoRI-SalI fragment (0.063 to 0.089 map units) of the human cytomegalovirus genome, major immediate-early antigen expression was obtained in 1 to 2% of the nuclei of the transfected cells, as determined by immunofluorescence with the E3 monoclonal antibody. Cotransfection of pES with the cloned herpes simplex virus type 1 thymidine kinase gene resulted in the establishment of a hypoxanthine-aminopterin-thymidine-resistant cell line which expressed a major immediate-early antigen in approximately 1% of the cells at early passages, with expression gradually declining to less than 0.1% upon subculturing. Southern blot analysis of DNA extracted from this cell line revealed the presence of multiple integration events of pES DNA sequences into cellular DNA, including a head-to-tail tandem array of approximately 10 copies of pES. The integration pattern was stable for at least 80 passages. Metaphase chromosomes prepared from this cell line showed, upon in situ hybridization, a strong hybridization signal in both sister chromatids of a large submetacentric chromosome which is considered to have harbored the tandemly integrated pES molecules. Whereas in most cells of the population, immediate-early expression seemed to be repressed, this repression could be overcome by protein synthesis inhibition, resulting in a massive induction of human-cytomegalovirus-specific transcripts of 2.1 and 1.9 kb and a minor species of 2.9 kb. After release from protein synthesis inhibition, approximately 20% of the cells showed nuclear fluorescence when the E3 monoclonal antibody was used.

Possible relationship between antigenic properties and isolation history of HSV-1 strains

29 monoclonal anti-herpes simplex virus (HSV)-1 antibodies were produced and characterized with regard to virus neutralizing activity, intracellular or cell-surface location of viral antigens and, where possible, molecular weight of the viral protein recognized. 13 antibodies recognized viral antigens expressed on the surface of infected cells and 16 were directed to intracellular viral components. Only two antibodies exhibited virus neutralizing activity. Application of these antibodies to an antigenic comparison of standard laboratory HSV-1 strains F, HFEM, mP, Glasgow-17 and MAC revealed unique antigenic differences among these strains. The antibodies were further used in an antigenic comparison of 45 human HSV-1 isolates with defined isolation history. Except for two paired isolates from left and right trigeminal ganglia of two human cadavers, the antibody panel revealed antigenic differences among all isolates, including paired isolates from three additional cadavers. Overall, isolates from different human donors showed greater antigenic dissimilarity from each other in cell-surface associated than in intracellular antigens. The data suggest the possibility of a correlation between antigenic and biologic properties of HSV-1.

Comparison of the DNA sequence and secondary structure of the herpes simplex virus L/S junction and the adeno-associated virus terminal repeat

The defective parvovirus Adeno-associated virus (AAV) is absolutely dependent upon coinfection with either Adenovirus or Herpes Simplex Virus (HSV) for its multiplication. We have compared the terminal repeats of HSV-1F strain DNA with the terminal 200 nucleotides of AAV DNA. Our findings demonstrate similarities between portions of the HSV inverted repeats found at the L/S junction and the termini of AAV. By computer analysis we have determined potential secondary folding patterns for both genomes. The following points can be made about the a, b, and c repeats in HSV: (1) Regions b and c are complementary over a significant portion of their length. (2) The ends of a can fold back on themselves to form large secondary structures. Moreover, when the b and c homology is used to align the ends of a, the b/a and c/a junctions are within 1 base of each other. (3) The short direct repeats within a are essentially a large loop with little secondary structure. The potential implications of this structure are discussed and a model for HSV DNA replication is presented.

Hybridization of herpes simplex virus DNA and human ribosomal DNA and RNA

A small DNA segment from the inverted repeats at the termini of the unique long sequence region of herpes simplex virus DNA was found to hybridize with human 28 S ribosomal DNA and RNA but not 18 S ribosomal DNA and RNA. The hybridization occurred under stringent conditions and was not blocked by nucleic acids high in guanine plus cytosine content. These data strongly suggest that the hybridization represented authentic base sequence homology.

Signals for site-specific cleavage of HSV DNA: maturation involves two separate cleavage events at sites distal to the recognition sequences

Mature Herpes Simplex Virus (HSV) genomes are cleaved from concatemeric precursors by a site-specific mechanism. These cleavage events are probably coupled to the encapsidation process. Sequences within the terminal repeat of HSV DNA are necessary for the cleavage and packaging reactions, and are also thought to be responsible for high frequency genome isomerization events. Here we present evidence to show that two viral DNA cleavage and packaging signals reside within a 250 bp subfragment of the terminal repeat, that the termini of mature viral DNA are generated by a process involving two separate DNA cleavages at sites distal to the cleavage signals, and that the sequences between these two cleavage sites are duplicated by the DNA maturation system.

Novel rearrangements of herpes simplex virus DNA sequences resulting from duplication of a sequence within the unique region of the L component

We constructed insertion mutants of herpes simplex virus type 1 that contained a duplication of DNA sequences from the BamHI-L fragment (map units 0.706 to 0.744), which is located in the unique region of the L component (UL) of the herpes simplex virus type 1 genome. The second copy of the BamHI-L sequence was inserted in inverted orientation into the viral thymidine kinase gene (map units 0.30 to 0.32), also located within UL. A significant fraction of the progeny produced by these insertion mutants had genomes with rearranged DNA sequences, presumably resulting from intramolecular or intermolecular recombination between the BamHI-L sequences at the two different genomic locations. The rearranged genomes either had an inversion of the DNA sequence flanked by the duplication or were recombinant molecules in which different regions of the genome had been duplicated and deleted. Genomic rearrangements similar to those described here have been reported previously but only for herpes simplex virus insertion mutants containing an extra copy of the repetitive a sequence. Such rearrangements have not been reported for insertion mutants that contain duplications of herpes simplex virus DNA sequences from largely unique regions of the genome. The implications of these results are discussed.

Herpes simplex virus type 1 restriction fragment polymorphism determined using southern hybridization

Regions of herpes simplex virus type 1 (HSV-1) DNA with variation in the size of restriction endonuclease fragments were identified by comparison of the BamHI, KpnI or SalI restriction endonuclease digestion patterns among 15 HSV-1 isolates after hybridization with specific 32P-labeled cloned HSV-1 DNA fragments. Of the types of restriction fragment polymorphism identified, one was a strain with a distinctly different restriction fragment than the prototype (loss or gain of restriction sites). Another type, the specific fragment varied only in size among strains. Thirteen distinct variations were identified. Ten were mapped to the unique sequence of the L component; two to the inverted repeat of the L component and one to the inverted repeat of the S component. The presence of a common ancestor from which some isolates of HSV-1 might derive was deduced from an analysis of the distribution of the thirteen variations among the 15 HSV-1 isolates.

Isolation of human DNAs homologous to the BamHI-Z fragment of herpes simplex virus type 1 DNA

Human DNA hybridizes with the BamHI-Z fragment (map coordinates 0.936 to 0.949) of Herpes simplex virus type 1 (HSV-1) DNA. To characterize the BamHI-Z homologue of human DNA, we isolated six independent hybrid phages with a sequence homologous to the BamHI-Z fragment from a human genomic DNA library. Three of the six had a common 1.2-kb BamHI-EcoRI fragment homologous to the BamHI-Z, and this fragment existed as 10-60 copies per human haploid genome. A 0.29-kb MboII segment of the BamHI-Z fragment was found to be responsible for the homology with the 1.2-kb BamHI-EcoRI fragment.

Characterization of the guinea pig cytomegalovirus genome by molecular cloning and physical mapping

Fragments of guinea pig cytomegalovirus (GPCMV) DNA produced by HindIII or EcoRI restriction endonuclease digestion were cloned into vectors pBR322 and pACYC184, and recombinant fragments representing ca. 97% of the genome were constructed. Hybridization of 32P-labeled cloned and gel-purified HindIII, EcoRI, and XbaI fragments to Southern blots of HindIII-, EcoRI-, and XbaI-cleaved GPCMV DNA verified the viral origin of cloned fragments and allowed construction of HindIII, EcoRI, and XbaI restriction maps. On the basis of the cloning and mapping experiments, the size of GPCMV DNA was calculated to include 239 kilobase pairs, corresponding to a molecular weight of 158 X 10(6). No cross-hybridization between any internal fragments was seen. We conclude that the GPCMV genome consists of a long unique sequence with terminal repeat sequences but without internal repeat regions. In addition, GPCMV DNA molecules exist in two forms. In the predominant form, the molecules demonstrate sequence homology between the terminal fragments; in the minor population, one terminal fragment is smaller by 0.7 X 10(6) daltons and is not homologous with the fragment at the other end of the physical map. The structural organization of GPCMV DNA is unique for a herpesvirus DNA, similar in its simplicity to the structure reported for murine cytomegalovirus DNA and quite dissimilar from that of human cytomegalovirus DNA.

DNA labeled during phosphonoacetate inhibition and following its reversal in herpesvirus infected cells

Human embryonic lung cells were pre-equilibrated with phosphonoacetate and 32P orthophosphate label, then infected with phosphonoacetate-sensitive herpes simplex virus (HSV) type 1. Analyses of viral DNA produced in these cells showed the following. i) Viral DNA was synthesized in infected cells exposed to 100 micrograms of the drug per ml of medium but not in cells exposed to four-fold higher concentrations of the drug. ii) At 300 micrograms/ml a region of the DNA between 0.58 and 0.69 map units became transiently labeled, but the restriction endonuclease fragment containing these sequences migrated more slowly than the corresponding fragment from virion DNA. iii) Viral DNA extracted from infected cells 1.5 hours post drug withdrawal (300 micrograms/ml) was preferentially labeled in 2 regions of the genome mapping between 0.17 and 0.23 and 0.58-0.69 map units. This finding is in agreement with a report of FRIEDMAN et al. (8) suggesting that HSV DNA contains two different sites of initiation. In addition a 4.8 X 10(6) molecular weight fragment was also preferentially labeled. This fragment could represent a smaller, aberrantly migrating fragment from the 0.17-0.27 map unit region of the DNA. (iv) Viral DNA extracted from infected cells at longer intervals after drug withdrawal showed an increasing gradient of radioactivity progressively labeling the genome. These results are consistent with the hypothesis that viral DNA has at least two sites of initiation of DNA synthesis and that both sites are within the L component of the DNA. Alternatively, the results could be interpreted as two sites of localized synthesis (repair) that are detected at high concentrations of phosphonoacetate and immediately following reversal of inhibition of DNA synthesis. The results do not exclude the possibility that secondary sites in both L and S are utilized late in infection or in untreated cells.

Structural organization of human herpesvirus DNA molecules

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

Detection of herpes simplex virus intertypic recombinant genomes in infected cell DNA

Intertypic recombination between herpes simplex virus types 1 and 2 (HSV-1 and HSV-2) was detected using DNA from mixedly infected cells. Because HSV-1 and HSV-2 share a 50% base sequence homology along the genome but have markedly different DNA restriction enzyme cleavage patterns, recombination events can be detected and quantified by analysis of restriction endonuclease digests for the presence of novel DNA fragments. We have used this technique to quantify the degree of interference by HSV-2 on HSV-1 replication as well as the effect of limiting the availability of one genome on the frequency of intertypic recombination. Because this technique does not require production of viable progeny virions, it should also be useful for studying early recombination events.

Unstable heterozygosity in a diploid region of herpes simplex virus DNA

We have examined the behavior of a herpes simplex virus strain KOS isolate in which the two inverted repeats flanking the short segment of viral DNA differ in length by approximately 60 base pairs. We find that individual viral DNA molecules exist which contain the two distinguishable repeats, demonstrating that heterology between the repeats is tolerated. However, viruses heterozygous for the two different repeats are unstable, segregating both classes of homozygotes at a high frequency. We propose that this segregation is a consequence of the high-frequency recombination events which also result in genome segment inversion.

Fine structure physical map locations of alterations that affect cell fusion in herpes simplex virus type 1

Fine structure physical map locations were determined for syncytial mutants (MP, syn-20, syn-102, syn-103, and syn-105) of Herpes Simplex Virus type 1 (HSV-1). All except MP were derived from the KOS strain. MP contains multiple mutations, including one that leads to the loss of accumulation of glycoprotein gC (Ruyechan et al., J. Virol. 29, 677-697, 1979). Overlapping DNA subclones within the prototypic map coordinates 0.707 to 0.810 were constructed from a library of KOS fragments. These were used along with intact mutant DNA to rescue the syn marker. Mutations in all of the mutants were rescued by KOS DNA sequences between 0.732 and 0.745. This cell-dependent syn mutation is the only lesion in the KOS-derived mutants. A second syn mutation in MP was mapped at coordinates 0.745 to 0.753. This lesion produces less fusion and is also cell-type dependent for the fusion phenotype. Cell-type independent fusion requires the presence of both mutations. The locus determining glycoprotein C (gC) production in strain MP was also mapped, using indirect immunofluorescence, to coordinates 0.745 to 0.753. Nucleotide sequences for ICP-27, an immediate early or alpha protein of unknown function, are within these coordinates. Since gC production and the syn phenotype are separable by recombination, they must be caused by independent mutations.

Analysis of the herpes simplex virus genome during in vitro latency in human diploid fibroblasts and rat sensory neurons

We have previously designed in vitro model systems to characterize the herpes simplex virus type 1 (HSV-1) genome during in vitro virus latency. Latency was established by treatment of infected human embryo lung fibroblast (HEL-F) cells or rat fetal neurons with (E)-5-(2-bromovinyl)-2'-deoxyuridine and human leukocyte interferon and was maintained by increasing the incubation temperature after inhibitor removal. Virus was reactivated by reducing the incubation temperature. We have now examined the HSV-1-specific DNA content of latently infected HEL-F cells and rat fetal neurons treated with (E)-5-(2-bromovinyl)-2'-deoxyuridine and human leukocyte interferon and increased temperature. The HEL-F cell population contained, on an average, between 0.25 and 0.5 copies of most, if not all, HSV-1 HindIII and XbaI DNA fragments per haploid cell genome equivalent. In contrast, the latently infected neurons contained, on an average, 8 to 10 copies per haploid cell genome equivalent of most HSV-1 BamHI DNA fragments. There was no detectable alteration in size or molarity of the HSV-1 terminal or junction DNA fragments obtained by HindIII, XbaI, or BamHI digestion of the latently infected neuron or HEL-F cell DNA, as compared with digestion of a reconstruction mixture of purified HSV-1 virion and HEL-F cell DNAs. These data suggest that the predominant form of the HSV-1 genome in either latently infected cell population is nonintegrated, linear, and nonconcatameric.

Specious hybridization between herpes simplex virus DNA and human cellular DNA

Apparent hybridization between human cellular DNA and herpes simplex virus DNA was blocked by the presence of guanine-rich ribo- and deoxyribonucleic acid polymers. The data indicate that the apparent hybridization may very well be artifactual and not represent long stretches of authentic base sequence homology.

Genetic analysis of temperature-sensitive mutants of HSV-1: the combined use of complementation and physical mapping for cistron assignment

To date, mutations in mutants representing 19 of the 33 recognized HSV-1 complementation groups have been mapped. The physical map locations of mutations in 10 ts mutants of HSV-1 strain KOS representing 8 of the 19 complementation groups are reported herein. The mutations in three mutants were found to lie between coordinates 0.086 and 0.194--two of these were mapped finely to between coordinates 0.095 and 0.108--and in seven mutants, between 0.301 and 0.448. The mutation in 1 of the 10 mutants, tsQ26, was mapped finely to a sequence between 500 and 1000 base pairs to the left of the 3' end of the TK gene (0.301-0.304). The availability of physical mapping data has (1) confirmed the usefulness of the complementation test as a means of identifying viral gene functions, (2) facilitated the rapid assignment of mutants to new and recognized cistrons, and (3) prompted a reevaluation of previously ambiguous complementation for mutants in 2 complementation groups. Thus, the 10 mutants whose ts mutations were mapped in this study had been assigned previously to 8 complementation groups based on the assumption that complementation indices of 2 or greater signified that 2 mutants were in different genes. Combined with physical mapping data, however, the results of complementation tests now indicate that indices between 2 and 10 may reflect either inter- or intragenic complementation. Thus, the 10 mutants have now been assigned to 7 complementation groups. Although physical mapping data have confirmed the results of previous complementation tests for 6 of 8 groups analyzed, reevaluation of complementation data in the light of physical mapping data has resulted in a more precise genetic definition of the locus for viral DNA polymerase and of a locus (represented by mutants in complementation group 1-10) which maps in the left hand portion of UL.

A lambda library of Herpes simplex virus type 1 (KOS) DNA fragments obtained by partial digestion with Sau3A

Large fragments of Herpes simplex virus type 1 (HSV-1, strain KOS) DNA were produced by partial cleavage with Sau3A and inserted into a phage lambda BamHI vector. Recombinant phage (lambda KOS) DNA molecules were isolated and characterised. The final collection of phage recombinants contains partially overlapping inserts, which represent most of the HSV-1 genome. Restriction enzyme analysis of many independent clones containing Us sequences revealed sequence polymorphism in two specific regions.

Genetic and phenotypic analysis of herpes simplex virus type 1 mutants conditionally resistant to immune cytolysis

Nine temperature-sensitive (ts) mutants of herpes simplex virus type 1 selected for their inability to render cells susceptible to immune cytolysis after infection at the nonpermissive temperature have been characterized genetically and phenotypically. The mutations in four mutants were mapped physically by marker rescue and assigned to functional groups by complementation analysis. In an effort to determine the molecular basis for cytolysis resistance, cells infected with each of the nine mutants were monitored for the synthesis of viral glycoprotein in total cell extracts and for the presence of these glycoproteins in plasma membranes. The four mutants whose ts mutations were mapped were selected with polypeptide-specific antiserum to glycoproteins gA and gB; however, three of the four mutations mapped to DNA sequences outside the limits of the structural gene specifying these glycoproteins. Combined complementation and phenotypic analysis indicates that the fourth mutation also lies elsewhere. The ts mutations in five additional cytolysis-resistant mutants could not be rescued with single cloned DNA fragments representing the entire herpes simplex virus type 1 genome, suggesting that these mutants may possess multiple mutations. Complementation tests with the four mutants whose ts lesions had been mapped physically demonstrated that each represents a new viral gene. Examination of mutant-infected cells at the nonpermissive temperature for the presence of viral glycoproteins in total cell extracts and in membranes at the cell surface demonstrated that (i) none of the five major viral glycoproteins was detected in extracts of cells infected with one mutant, suggesting that this mutant is defective in a very early function; (ii) cells infected with six of the nine mutants exhibited greatly reduced levels of all the major viral glycoproteins at the infected cell surface, indicating that these mutants possess defects in the synthesis or processing of viral glycoproteins; and (iii) in cells infected with one mutant, all viral glycoproteins were precipitable at the surface of the infected cell, despite the resistance of these cells to cytolysis. This mutant is most likely mutated in a gene affecting a late stage in glycoprotein processing, leading to altered presentation of glycoproteins at the plasma membrane. The finding that the synthesis of both gB and gC was affected coordinately in cells infected with six of the nine mutants suggests that synthesis of these two glycoproteins, their transport to the cell surface, or their insertion into plasma membranes is coordinately regulated.

Localization of the regions of homology between the genomes of herpes simplex virus, type 1, and pseudorabies virus

Only 8% of the sequences of the genomes of pseudorabies (PRV) and herpes simplex (type 1) (HSV) viruses are homologous. These homologous sequences have been shown previously to be distributed throughout most of the genomes of the two viruses. By means of blot hybridization of restriction fragments of HSV-1 DNA to cloned, nick-translated restriction fragments of PRV DNA, it was possible to compare the location on the genomes of these viruses of the homologous regions. The results showed that the genome of PRV is, for the most part, colinear with the IL arrangement of the genome of HSV-1. An inversion or translocation of sequences mapping on the PRV genome between 0.07 and 0.39 map units was observed on the genome of one of these viruses. A comparison of the map positions of five genes with known functions confirmed these findings. The genes coding for the major immediate-early protein, the major capsid protein, and the thymidine kinase occupy similar positions on the genome of PRV and on the genome of HSV-1 in the IL arrangement. However, the genes for DNA polymerase and for the major DNA binding protein appear to be inverted relative to one another on the genomes of the two viruses.

Restriction endonuclease mapping of the frog virus 3 genome

A physical map for the frog virus 3 (FV 3) genome was constructed after digestion with the following restriction endonucleases: EcoRI, HindIII, KpnI, and XbaI. Mapping of the DNA was accomplished by partial digestion and recutting, double-digestion, and Southern blot hybridization with deduction of overlaps. Although the virion DNA is physically linear, the restriction map was circular, supporting the data that the FV 3 genome is circularly permuted (Goorha and Murti, Proc. Nat. Acad. Sci USA 79, 248-252, 1982), a unique feature among eukaryotic viruses.

Genetic analysis of temperature-sensitive mutants which define the gene for the major herpes simplex virus type 1 DNA-binding protein

We have assigned eight temperature-sensitive mutants of herpes simplex virus type 1 to complementation group 1-1. Members of this group fail to complement mutants in herpes simplex virus type 2 complementation group 2-2. The mutation of one member of group 1-1, tsHA1 of strain mP, has been shown to map in or near the sequence which encodes the major herpes simplex virus type 1 DNA-binding protein (Conley et al., J. Virol. 37:191-206, 1981). The mutations of five other members of group 1-1 map in or near the sequence in which the tsHA1 mutation maps, a sequence which lies near the center of UL between the genes for the viral DNA polymerase and viral glycoprotein gAgB. These mutants can be divided into two groups; the mutations of one group map between coordinates 0.385 and 0.398, and the mutations of the other group map between coordinates 0.398 and 0.413. At the nonpermissive temperature mutants in group 1-1 are viral DNA negative, and mutant-infected cells fail to react with monoclonal antibody to the 130,000-dalton DNA-binding protein. Taken together, these data indicate that mutants in complementation groups 1-1 and 2-2 define the gene for the major herpes simplex virus DNA-binding protein, an early gene product required for viral DNA synthesis.

Herpesvirus-dependent amplification and inversion of cell-associated viral thymidine kinase gene flanked by viral a sequences and linked to an origin of viral DNA replication

The genome of herpes simplex virus 1 or 2 consists of two components, L and S, which invert relative to each other during infection. As a result, viral DNA consists of four equimolar populations of molecules differing solely in the relative orientations of the L and S components. Previous studies have shown that the a sequences, located in the same orientation at the genomic termini and in inverted orientation at the L-S junction, play a key role in the inversion of L and S components. In this report we describe a virus-dependent system designed to allow identification of the viral genes capable of acting in trans to invert DNA flanked by inverted copies of a sequences. In this system, cells are converted to the thymidine kinase-positive phenotype with a chimeric plasmid carrying the thymidine kinase gene flanked by inverted copies of the a sequence and linked to an origin of viral DNA replication derived from the S component. The DNA introduced into the cells is retained and propagated in its original sequence arrangement as head-to-tail concatemers. Infection of these cells with herpes simplex virus 1 or 2 results in as much as 100-fold amplification of the plasmid sequences and inversion of the DNA flanked by copies of the a sequence. In infected cells, the amplified resident DNA accumulates in head-to-tail concatemers and no rearrangement other than the inversions could be detected. These results suggest that the a sequence-dependent inversions required trans-acting viral gene products.

Methylation of the viral genome in an in vitro model of herpes simplex virus latency

An in vitro model of latency of herpes simplex virus type 1 (HSV-1) in a lymphoid cell line has been developed recently. CEM cells persistently infected with HSV-1 transiently ceased to produce virus for 24 days. This nonproductive state could either be reversed with phytohemagglutinin or maintained with concanavalin A. This system was used to study the relationship between DNA methylation and HSV-1 latency. DNA was probed for methylation by comparing the cleavage patterns generated by two pairs of restriction endonucleases (Sma I vs. Xma I and Hpa II vs. MspI); these enzymes show differential activity reflecting methylation of the recognition sequences. Viral DNA in the concanavalin A-treated cells (not producing virus) was found to be extensively methylated. By contrast, no methylated copies were detected in viral DNA from producer cells. About 800 days after the initial infection, the productive culture once again became nonproductive. Viral sequences in the latter cells were also methylated. Reconstitution experiments revealed 1-2 copies of viral DNA in cells from the latent stages and 40-80 copies in cells from productive stages. Most (if not all) of the viral genome is present in cells from various productive and latent stages. No differences in sequence arrangement were detected (although a terminal fragment of intracellular HSV-1 DNA appeared to be under-represented in latent cells). These results suggest a role for DNA methylation in the mechanism of HSV-1 latency in this system.

Varicella zoster virus DNA exists as two isomers

Fragments of varicella zoster virus DNA produced by EcoRI endonuclease cleavage were cloned in vector pACYC 184 and those produced by HindIII cleavage were cloned in pBR322. Restriction enzyme cleavage maps established by double digestion and blot hybridization showed that varicella zoster virus DNA has a Mr of 80 +/- 3 x 10(6) and exists as a population of two isomers.