The genetic content of wild-type human cytomegalovirus was investigated by sequencing the 235 645 bp genome of a low passage strain (Merlin). Substantial regions of the genome (genes RL1-UL11, UL105-UL112 and UL120-UL150) were also sequenced in several other strains, including two that had not been passaged in cell culture. Comparative analyses, which employed the published genome sequence of a high passage strain (AD169), indicated that Merlin accurately reflects the wild-type complement of 165 genes, containing no obvious mutations other than a single nucleotide substitution that truncates gene UL128. A sizeable subset of genes exhibits unusually high variation between strains, and comprises many, but not all, of those that encode proteins known or predicted to be secreted or membrane-associated. In contrast to unpassaged strains, all of the passaged strains analysed have visibly disabling mutations in one or both of two groups of genes that may influence cell tropism. One comprises UL128, UL130 and UL131A, which putatively encode secreted proteins, and the other contains RL5A, RL13 and UL9, which are members of the RL11 glycoprotein gene family. The case in support of a lack of protein-coding potential in the region between UL105 and UL111A was also strengthened.
The gene complement of wild-type human cytomegalovirus (HCMV) is incompletely understood, on account of the size and complexity of the viral genome and because laboratory strains have undergone deletions and rearrangements during adaptation to growth in culture. We have determined the sequence (241 087 bp) of chimpanzee cytomegalovirus (CCMV) and have compared it with published HCMV sequences from the laboratory strains AD169 and Toledo, with the aim of clarifying the gene content of wild-type HCMV. The HCMV and CCMV genomes are moderately diverged and essentially collinear. On the basis of conservation of potential proteincoding regions and other sequence features, we have discounted 51 previously proposed HCMV ORFs, modified the interpretations for 24 (including assignments of multiple exons) and proposed ten novel genes. Several errors were detected in the published HCMV sequences. We presently recognize 165 genes in CCMV and 145 in AD169; this compares with an estimate of 189 unique genes for AD169 made in 1990. Our best estimate for the complement of wild-type HCMV is 164 to 167 genes. INTRODUCTIONHuman cytomegalovirus (HCMV; human herpesvirus 5) is ubiquitous and largely inapparent, but poses a risk of serious disease to those lacking a competent immune system, such as neonates, transplant patients and sufferers from AIDS (reviewed in Pass, 2001). HCMV is the prototype of subfamily Betaherpesvirinae, and is the most complex of the eight human herpesvirus species. HCMV is isolated routinely on human fibroblast cell lines, and several strains in common laboratory use, such as AD169 and Towne, were derived by multiple passages on such cells (reviewed in Mocarski & Tan Courcelle, 2001).The linear, double-stranded DNA genome of AD169 comprises two covalently linked segments (L and S), each consisting of a unique region (U L and U S ) flanked by an inverted repeat (TR L and IR L , TR S and IR S ), yielding the overall genome configuration TR L -U L -IR L -IR S -U S -TR S (reviewed in Mocarski & Tan Courcelle, 2001). In addition, the genome is terminally redundant, possessing a short region (the a sequence) as a direct repeat at the termini and also in inverse orientation at the IR L -IR S junction. Some genomes contain tandemly reiterated copies of the a sequence at these locations. U L and U S can invert relative to each other by recombination between inverted repeats in replicating DNA, resulting in four equimolar genome arrangements in virion DNA. The complete DNA sequence of AD169 was published in a seminal paper by Chee et al. (1990), and at that time was the largest viral genome sequence available. The total genome size was 229 354 bp, with U L being 166 972 bp, U S 35 418 bp, R L (a collective term for TR L and IR L ) 11 247 bp, R S (TR S and IR S ) 2524 bp and the a sequence (part of R L and R S in the sizes given above) 578 bp.As a primary criterion for identifying protein-coding regions, Chee et al. (1990) focused on open reading frames (ORFs) of 100 or more contiguous amino acidencoding codons that ov...
Two novel spliced genes (UL131A and UL128) flanking UL130 were predicted from sequence comparisons between human cytomegalovirus (HCMV) and its closest known relative, chimpanzee cytomegalovirus (CCMV), and the splicing patterns were confirmed by mRNA mapping experiments. Both genes were transcribed with late kinetics and shared a polyadenylation site. Comparisons with wild-type HCMV in infected human tissues showed that three of five isolates passaged in cell culture contained disruptions of UL128, one was frameshifted in UL131A and one exhibited a deletion affecting UL131A and UL130. CCMV and the Colburn strain of simian cytomegalovirus, which have been passaged in cell culture, also exhibit disruptions of UL128. These observations indicate that expression of either one of UL128 and UL131A is deleterious to growth of primate cytomegaloviruses in cell culture. Although the functions of these genes are unknown, sequence comparisons suggest that UL128 encodes a b-chemokine.The genome of the AD169 strain of human cytomegalovirus (HCMV; human herpesvirus 5) was characterized by Chee et al. (1990) as containing 189 putative protein-coding open reading frames (ORFs), some duplicated in an inverted repeat. An additional genome region was subsequently discovered in the Toledo strain (Cha et al., 1996). A recent comparison of these sequences with that of chimpanzee cytomegalovirus (CCMV) indicated that wild-type HCMV has 166-169 genes (Davison et al., 2003a, b). The present work concerns two of the eleven newly predicted genes in this redefined set.The upper part of Fig. 1(A) depicts the arrangement of ORFs UL131-UL128 as predicted by Chee et al. (1990), and the lower parts show alternative predictions based on comparisons between the AD169 and CCMV sequences. UL130 is unaltered, while spliced genes replace UL131 upstream and UL129 plus UL128 downstream. One of these genes is named UL131A because it occupies the same region as UL131 but does not share any encoded amino acid sequence, since the first exon is in a different reading frame from UL131. The other spliced gene retains the designation UL128 because it shares amino acid sequence with the original UL128 but not with UL129. Fig. 1(B, C) shows detailed alignments of the AD169 and CCMV sequences in these regions. Protein-coding regions were proposed from conservation of encoded amino acid sequences, and conceptually linked together via candidate splice donor and acceptor sites. This led to the hypothesis that UL131A and UL128 comprise two and three exons, respectively.In order to sustain this interpretation, it is necessary to propose that AD169 has a frameshift mutation (an additional residue making a tract of eight A residues) in UL131A exon 1 (Fig. 1B) and that CCMV has a frameshift mutation (an additional residue making a tract of eight C residues) in UL128 exon 1 (Fig. 1C). Davison et al. (2003a) confirmed the former lesion by resequencing the relevant AD169 region and comparing it with sequence obtained directly from clinical material. The proposed mutation in...
Two Epstein-Barr virus (EBV) types are known, EBV1 and EBV2, which possess substantially diverged alleles for latency genes EBNA-2, EBNA-3A, EBNA-3B and EBNA-3C but are thought to be otherwise similar. We report the first complete EBV2 genome sequence, for strain AG876, as 172,764 bp. The sequence was interpreted as containing at least 80 protein coding genes. Comparison with the published EBV1 sequence demonstrated that the two sequences are collinear and, outside the known diverged alleles, generally very close. The EBNA-1 gene was identified as another diverged locus, although its variation is believed not to correlate with EBV type. Patterns of substitution between the two genomes presented a wide spectrum of classes of change. No evidence was seen for involvement of B-cell-specific hypermutation systems in generation of the diverged alleles. Overall, genomic comparisons indicated that the two EBV types should be regarded as belonging to the same virus species.
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