Herpes simplex virus type 1 variant a sequence generated by recombination and breakage of the a sequence in defined regions, including the one involved in recombination

Complete Genome Sequence of Herpes Simplex Virus 1 Strain McKrae

Herpes simplex virus 1 (HSV-1) strain McKrae is highly virulent and relatively neuroinvasive in animal models compared with other wild-type HSV-1 strains. To identify the genetic determinants that lead to the unique phenotypes of the McKrae strain, we sequenced its genome with PacBio single-molecule real-time (SMRT) technology and resolved the complete sequence.

Complete Genome Sequence of Herpes Simplex Virus 1 Strain MacIntyre

Herpes simplex virus type 1 (HSV-1) strain MacIntyre has a severe defect in the anterograde spread after replication in the nucleus. To better understand and identify the genetic determinants that lead to the unique phenotypes of the MacIntyre strain, we sequenced its genome with PacBio single-molecule real-time sequencing technology and resolved the complete sequence.

Sequence and comparative analysis of the genome of HSV-1 strain McKrae

Ocular infection by HSV-1 strain McKrae is neurovirulent in both mice and rabbits and causes fatal encephalitis in approximately 50% of animals. In addition, it spontaneously reactivates with high frequency relative to other HSV-1 strains in rabbits. We sequenced the McKrae strain genome and compared its coding protein sequences with those of six other HSV-1 strains. Most of the 74 predicted protein sequences are conserved; only eleven are less than 98% conserved. Eight proteins were identified to be unique for McKrae based on sequence homology bit score ratio (BSR). These include five proteins showing significant variations (RL1, RS1, UL49A, US7 and US11), two truncated proteins (UL36 and UL56) and one (US10) containing an extended open reading frame. The McKrae strain also has unique features in its 'a' sequence and non-coding sequences, such as LAT and miRNA. These data are indicative of strain variation but need further work to connect observed differences with phenotype effects.

Diversity of the a sequence of herpes simplex virus type 1 developed during evolution

Herpes simplex virus type 1 (HSV-1) is a ubiquitous human pathogen. The a sequence of HSV-1 is the cis-acting site required for the cleavage and encapsidation of unit-length HSV-1 DNA from concatemeric forms. The consensus a sequence consists of (i) DR1 (direct repeat 1), (ii) Ub, (iii) a DR2 array [a repeat of various copy numbers of DR2 elements (11 or 12 bp)], (iv) a DR4 stretch and (v) Uc. In the present study, the nucleotide sequences of the a sequences of 26 HSV-1 isolates were determined and the DR4 stretches were classified into three groups. The state of a set of 20 DNA polymorphisms in the genomes of these HSV-1 isolates was determined previously. A correct classification rate of 100 % was achieved when discriminant analysis was performed between the DR4 stretch (criterion variable) and the set of 20 DNA polymorphisms (predictor variables), suggesting a close association of the DR4 stretch with HSV-1 diversification. DR2 elements of 9, 13 and 14 bp were detected in addition to those of 11 and 12 bp, and a correct classification rate of 93 % was achieved when discriminant analysis was performed between the DR2 array and the set of 20 DNA polymorphisms. Some DR2 elements of one HSV-1 isolate had the same nucleotide sequences as part of the adjacent DR4 stretch, and these variations were adequately explained by postulating recombination involving DR2 elements; hence, the DR2 array was deduced to be prone to recombination.

Cleavage in and around the DR1 element of the A sequence of herpes simplex virus type 1 relevant to the excision of DNA fragments with length corresponding to one and two units of the A sequence

The A sequence of herpes simplex virus type 1 (HSV-1) is a region bracketed by two direct repeats named DR1. Concatemeric HSV-1 DNA, the product of DNA replication, is cleaved at a specific site on the second DR1 distal from the S component (authentic cleavage) to yield unit-length linear HSV-1 DNA prior to or during packaging of HSV-1 DNA. The presence of two DNA bands, of 0.25 kb (shorter band) and 0.5 kb (longer band), the lengths of which correspond to one and two units of the A sequence, was identified using acrylamide gel electrophoresis of HSV-1 DNA preparations extracted by the method of Hirt. Twelve DNA fragments from each band were molecularly cloned, and nucleotide sequences were determined. Both termini of eight (67%) DNA clones from the shorter band corresponded to the specific cleavage site on DR1. Five (41%) DNA clones from the longer band had a terminus corresponding to the specific cleavage site on DR1 on one side, but not on the opposite side. Thirteen (54%) of 24 termini of 12 analyzed DNA clones from the longer band were in and around DR1. Thus, cleavage events of DR1 can be classified into three categories: (i) authentic cleavage; (ii) site-specific cleavage on the third DR1 distal from the S component (secondary site-specific cleavage), which is related to the generation of the shorter DNA band in combination with authentic cleavage; and (iii) less-specific cleavage events in and around other DR1 elements which relate to the generation of the longer DNA band.

Mechanism and application of genetic recombination in herpesviruses

Herpes simplex virus type 1 (HSV-1) is a ubiquitous human pathogen that latently infects sensory ganglia and encodes over 80 genes in a 152 kbp DNA genome. This well characterised virus provides a model for analysing genetic recombination in herpesviruses, a fundamental biological process by which new combinations of genetic materials are generated. The frequency of homologous recombination was estimated to be 0.0048-0.007 (0.48%-0.7%)/kb of the HSV-1 genome, determined using physical markers. The double-strand break repair model, the current model of homologous recombination, adequately explains L-S inversion of herpesvirus genomes and the recombinogenicity of the a sequence. Several herpesvirus genomes, including HSV-1 consist of a unique sequence bracketed by a pair of inverted repeat sequences. This arrangement is attributed to illegitimate recombination between molecules arranged in an inverse orientation. Junctions of unique and repeated sequences that correspond to the crossover site of illegitimate recombination are recombinogenic. Recombination is important for virus evolution, construction of mutated virus, gene therapy and vaccination in which the potential for recombination between engineered input virus and wild type virus has to be considered.

Functional identification and analysis of cis-acting sequences which mediate genome cleavage and packaging in human herpesvirus 6

Sequences present at the genomic termini of herpesviruses become linked during lytic-phase replication and provide the substrate for cleavage and packaging of unit length viral genomes. We have previously shown that homologs of the consensus herpesvirus cleavage-packaging signals, pac1 and pac2, are located at the left and right genomic termini of human herpesvirus 6 (HHV-6), respectively. Immediately adjacent to these elements are two distinct arrays of human telomeric repeat sequences (TRS). We now show that the unique sequence element formed at the junction of HHV-6B genome concatemers (pac2-pac1) is necessary and sufficient for virally mediated cleavage of plasmid DNAs containing the HHV-6B lytic-phase origin of DNA replication (oriLyt). The concatemeric junction sequence also allowed for the packaging of these plasmid molecules into intracellular nucleocapsids as well as mature, infectious viral particles. In addition, this element significantly enhanced the replication efficiency of oriLyt-containing plasmids in virally infected cells. Experiments revealed that the concatemeric junction sequence possesses an unusual, S1 nuclease-sensitive conformation (anisomorphic DNA), which might play a role in this apparent enhancement of DNA replication--although additional studies will be required to test this hypothesis. Finally, we also analyzed whether the presence of flanking viral TRS had any effect on the functional activity of the minimal concatemeric junction (pac2-pac1). These experiments revealed that the TRS motifs, either alone or in combination, had no effect on the efficiency of virally mediated DNA replication or DNA cleavage. Taken together, these data show that the cleavage and packaging of HHV-6 DNA are mediated by cis-acting consensus sequences similar to those found in other herpesviruses, and that these sequences also influence the efficiency of HHV-6 DNA replication. Since the adjacent TRS do not influence either viral cleavage and packaging or viral DNA replication, their function remains uncertain.

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.

Excision of DNA fragments corresponding to the unit-length a sequence of herpes simplex virus type 1 and terminus variation predominate on one side of the excised fragment

DNA fragments corresponding to the unit-length a sequence of herpes simplex virus type 1 (HSV-1) were identified in HSV-1 DNA preparations extracted by the method of Hirt. The DNA fragments were molecularly cloned, and nucleotide sequences were determined. Most termini of the fragments were at sites on DR1 corresponding to the termini of linear HSV-1 DNA generated by the cleavage-packaging system. In one-step growth experiments, DNA fragments of the unit-length a sequence appeared simultaneously with the termini of linear HSV-1 DNAs produced by cleavage of circular and concatemeric DNAs. Therefore, excision of the unit-length a sequence appeared closely related to the cleavage-packaging system. Termini of the excised DNA fragments of the variant a sequence with two DR2 arrays varied on the L-component side, while termini on the S-component side were at the site on DR1 corresponding to the authentic cleavage site. It is thus assumed that the cleavage-packaging system functions adequately on the DR1 second distal from the S component, and cleavages of other DR1 are rare and less accurate. If this notion is tenable, then most termini on the S-component side of the excised DNA fragments are derived from the second DR1 properly cleaved and should be constant, while termini on the L-component side are from regions on and around the DR1 third distal from the S component and may be variable. Cleavage of DR1 is likely to be affected by the topological relationship with the S component.