A review of genetic differences between limited and extensively passaged human cytomegalovirus strains.

The complete genetic content of human cytomegalovirus (HCMV) has been difficult to determine, since most strains studied in the laboratory have been extensively passaged in human fibroblast cultures which can change the genetic content as well as the biological properties of the virus. Approximately 13 kb of novel DNA sequences located near the right edge of the unique long (UL) component of the genome has been discovered in Toledo, clinical isolates and certain stocks of Towne. This region of novel sequence, designated the UL/b' region, encodes several interesting proteins including vCXC-1, a potent IL-8 homologue, and UL144, a member of the TNF receptor family. This region is missing from the prototypic laboratory variants of Towne and AD169. In contrast to Toledo and other low passage isolates which have relatively small repeats bracketing the UL component, the Towne and AD169 laboratory variants contain large (>10 kb) b/b' repeats. The large size of these repeats in AD169 and Towne appear to have arisen as compensation for the loss of sequences from the UL/b' region that existed in less passaged variants of these strains. Consequently, many of the haploid genes at the left edge of the prototypic wild-type (wt) UL component are diploid in AD169 and Towne. We hypothesise that this plasticity of the genome at the right edge of the UL component results from extensive passage and adaptation to replication in fibroblasts in vitro. Further work will be required to understand the complete genetic content of wt HCMV.

Cytomegalovirus encodes a potent alpha chemokine.

Cytomegalovirus is a widespread opportunistic pathogen affecting immunocompromised individuals in whom neutrophils may mediate virus dissemination and contribute to progression of disease. Recent sequence analysis suggests that genes absent or altered in attenuated strains may influence pathogenesis. We have found two genes, UL146 and UL147, whose products have sequence similarity to alpha (CXC) chemokines. UL146 encodes a protein, designated vCXC-1, that is a 117-aa glycoprotein secreted into the culture medium as a late gene product, where its presence correlates with the ability to attract human neutrophils. Recombinant vCXC-1 is a fully functional chemokine, inducing calcium mobilization, chemotaxis, and degranulation of neutrophils. High-affinity vCXC-1 binding is shown to be mediated via CXCR2, but not CXCR1. vCXC-1 exhibits a potency approaching that of human IL-8. As the first example of a virus-encoded alpha chemokine, vCXC-1 may ensure the active recruitment of neutrophils during cytomegalovirus infection, thereby providing for efficient dissemination during acute infection and accounting for the prominence of this leukocyte subset in cytomegalovirus disease.

Human cytomegalovirus uracil DNA glycosylase is required for the normal temporal regulation of both DNA synthesis and viral replication.

Human cytomegalovirus (CMV) encodes a gene, UL114, whose product is homologous to the uracil DNA glycosylase and is highly conserved in all herpesviruses. This DNA repair enzyme excises uracil residues in DNA that result from the misincorporation of dUTP or spontaneous deamination of cytosine. We constructed a recombinant virus, RC2620, that contains a large deletion in the UL114 open reading frame and carries a 1.2-kb insert containing the Escherichia coli gpt gene. RC2620 retains the capacity to replicate in primary human fibroblasts and reaches titers that are similar to those produced by the parent virus but exhibits a significantly longer replication cycle. Although the rate of expression of alpha and beta gene products appears to be unaffected by the mutation, DNA synthesis fails to proceed normally. Once initiated, DNA synthesis in mutant virus-infected cells proceeds at the same rate as with wild-type virus, but initiation is delayed by 48 h. The mutant virus also exhibits two predicted phenotypes: (i) hypersensitivity to the nucleoside analog 5-bromodeoxyuridine and (ii) retention of more uracil residues in genomic DNA than the parental virus. Together, these data suggest UL114 is required for the proper excision of uracil residues from viral DNA but in addition plays some role in establishing the correct temporal progression of DNA synthesis and viral replication. Although such involvement has not been previously observed in herpesviruses, a requirement for uracil DNA glycosylase in DNA replication has been observed in poxviruses.

Mutational analysis of the mengovirus poly(C) tract and surrounding heteropolymeric sequences.

Previously, we described three mengovirus mutants derived from cDNA plasmids, containing shortened poly(C) tracts (C8, C12, and C13UC10), that exhibited strong attenuation for virulence in mice yet grew like wild-type virus in HeLa cells. Thirteen additional mutants hav now been constructed and characterized. Five of these differ only in poly(C) length, including one with a precise deletion of the tract. The other mutants bear deletions into the regions juxtaposing poly(C). Studies with HeLa cells confirm the essential dispensability of mengovirus's poly(C) tract but reveal a subtle, measurable correlation between poly(C) length and plaque diameter. Virulence studies with mice also revealed a strong correlation between poly(C) length and virulence. For the poly(C)-flanking mutations, the 15 bases directly 5' of the tract proved dispensable for virus viability, whereas the 20 to 30 bases 3' of poly(C) were critical for growth, thus implicating this region in the basal replication of the virus.

Human cytomegalovirus clinical isolates carry at least 19 genes not found in laboratory strains.

Nucleotide sequence comparisons were performed on a highly heterogeneous region of three human cytomegalovirus strains, Toledo, Towne, and AD169. The low-passage, virulent Toledo genome contained a DNA segment of approximately 13 kbp that was not found in the Towne genome and a segment of approximately 15 kbp that was not found in the AD169 genome. The Towne strain contained approximately 4.7 kbp of DNA that was absent from the AD169 genome, and only about half of this segment was present, arranged in an inverted orientation, in the Toledo genome. These additional sequences were located at the unique long (UL)/b' (IRL) boundary within the L component of the viral genome. A region representing nucleotides 175082 to 178221 of the AD169 genome was conserved in all three strains; however, substantial reduction in the size of the adjacent b' sequence was found. The additional DNA segment within the Toledo genome contained 19 open reading frames not present in the AD169 genome. The additional DNA segment within the Towne genome contained four new open reading frames, only one of which shared homology with the Toledo genome. This comparison was extended to five additional clinical isolates, and the additional Toledo sequence was conserved in all. These findings reveal a dramatic level of genome sequence complexity that may explain the differences that these strains exhibit in virulence and tissue tropism. Although the additional sequences have not altered the predicted size of the viral genome (230 to 235 kbp), a total of 22 new open reading frames (denoted UL133 to UL154), many of which have sequence characteristics of glycoproteins, are now defined as cytomegalovirus specific. Our work suggests that wild-type virus carries more than 220 genes, some of which are lost by large-scale deletion and rearrangement of the UL/b' region during laboratory passage.

Sequence and structural elements that contribute to efficient encephalomyocarditis virus RNA translation.

The nucleotide sequence of the 5' nontranslated region of encephalomyocarditis virus (EMCV-Rueckert) was determined, and a consensus RNA structural model for this sequence (850 bases) and three other poly(C)-containing cardioviruses (mengovirus, EMCV-B, and EMCV-D) was created through reiterative use of a minimum-free-energy folding algorithm. The RNA elements within this region which contribute to translation of EMCV proteins were mapped in cell-free reactions programmed with cDNA-derived RNA transcripts. The data provide evidence that stem-loop motifs I, J and K, formed by viral bases 451 to 785, are important components of cap-independent translation. In contrast to other reports, a minimal role for stem-loop H (bases 406 to 444) in translational activity is indicated. Small 5' nontranslated region fragments (bases 667 to 797) containing the J and K motifs proved strong competitive inhibitors when added to cell-free reactions programmed with exogenous capped or uncapped mRNAs. The putative sequestering of required translational factors by this segment clearly contributes to translational activity, but also suggests a possible competitive mechanism for the down regulation of host protein synthesis during viral infection.

Attenuation of Mengo virus through genetic engineering of the 5' noncoding poly(C) tract.

The murine cardioviruses, such as the Mengo and encephalomyocarditis viruses, and the bovine aphthoviruses, such as foot-and-mouth disease virus, are distinguished among positive-strand RNA viruses by the presence of long homopolymeric poly(C) tracts within their 5' noncoding sequences. Although the specific lengths (60-350 bases) and sequence discontinuities (for example, uridine residues) that sometimes disrupt the homopolymer have served to characterize natural viral isolates, the biological function of the poly(C) region has never been clear. We now report that complementary DNA-mediated truncation of the Mengo virus poly(C) tract dramatically attenuates the pathogenicity of the virus in mice. Animals injected with viruses with short tracts not only survived inoculation of up to 50 micrograms live virus (10(11) plaque-forming units) but consistently produced high titres of neutralizing antibodies, which conferred long-term immunogenic protection from (normally) lethal virus challenge. We propose that analogous synthetic strains of foot and mouth disease virus could serve as the basis for new attenuated vaccines.

Cloning and synthesis of infectious cardiovirus RNAs containing short, discrete poly(C) tracts.

Mengovirus RNA transcripts with 5' noncoding poly(C) tracts of C8, C12, and C13UC10 have been synthesized in vitro from cDNA clones and shown to be infectious to HeLa cells. A chimeric clone has also been constructed which links the 5' end from one mengovirus clone (299 nucleotides, containing C13UC10) to a 7,424-base fragment derived from the 3' end of encephalomyocarditis (EMC) virus. Progeny virus isolated after transfection with the clone-derived RNAs had the same poly(C) tracts, mengovirus-specific sequences, or EMC virus-specific sequences as the transcript from which it was derived. Although the cloned poly(C) tracts were considerably shorter than those found in viral RNA from mengovirus (C50UC10) or EMC virus (C115UCUC3UC10), the growth characteristics of the progeny viruses in HeLa cells were indistinguishable from those of the parental viruses, indicating the length of this tract does not play a significant restrictive role for cardiovirus infectivity in tissue culture.

A segment of the 5' nontranslated region of encephalomyocarditis virus RNA directs internal entry of ribosomes during in vitro translation.

Picornavirus RNAs are uncapped messengers and have unusually long 5' nontranslated regions (5'NTRs) which contain many noninitiating AUG triplets. The translational efficiency of different picornavirus RNAs varies between different cell-free extracts and even in the same extract, such as micrococcal nuclease-treated rabbit reticulocyte lysates. The effect of the poliovirus 5'NTR on in vitro translation was compared with that of the 5'NTR of encephalomyocarditis virus by the use of synthetic mRNAs, micrococcal nuclease-treated HeLa cell extracts, and rabbit reticulocyte lysates. Artificial mono- and dicistronic mRNAs synthesized with T7 RNA polymerase were used to investigate whether the 5'NTR of encephalomyocarditis virus RNA contains a potential internal ribosomal entry site. The sequence between nucleotides 260 and 484 in the 5'NTR of encephalomyocarditis RNA was found to play a critical role in the efficient translation in both mono- and dicistronic mRNAs. Our data suggest that an internal ribosomal entry site resides in this region.

The atomic structure of Mengo virus at 3.0 A resolution.

The structure of Mengo virus, a representative member of the cardio picornaviruses, is substantially different from the structures of rhino- and polioviruses. The structure of Mengo virus was solved with the use of human rhinovirus 14 as an 8 A resolution structural approximation. Phase information was then extended to 3 A resolution by use of the icosahedral symmetry. This procedure gives promise that many other virus structures also can be determined without the use of the isomorphous replacement technique. Although the organization of the major capsid proteins VP1, VP2, and VP3 of Mengo virus is essentially the same as in rhino- and polioviruses, large insertions and deletions, mostly in VP1, radically alter the surface features. In particular, the putative receptor binding "canyon" of human rhinovirus 14 becomes a deep "pit" in Mengo virus because of polypeptide insertions in VP1 that fill part of the canyon. The minor capsid peptide, VP4, is completely internal in Mengo virus, but its association with the other capsid proteins is substantially different from that in rhino- or poliovirus. However, its carboxyl terminus is located at a position similar to that in human rhinovirus 14 and poliovirus, suggesting the same autocatalytic cleavage of VP0 to VP4 and VP2 takes place during assembly in all these picornaviruses.

Encephalomyocarditis virus 3C protease: efficient cell-free expression from clones which link viral 5' noncoding sequences to the P3 region.

All picornaviral peptides are derived by progressive posttranslational cleavage of a giant precursor polyprotein. Translation of encephalomyocarditis virus (EMC) RNA in rabbit reticulocyte extracts produces active viral peptides, including protease 3C, which is responsible for many cleavage reactions within the processing cascade. DNA plasmids containing 5' noncoding sequences of EMC linked to other portions of the viral genome were constructed and transcribed into RNA. Like virion RNA, the clone-derived transcripts directed efficient protein translation in vitro. The 5'-linked constructions may represent examples of a general method for cell-free expression of any cloned gene segment. One construction produced a self-cleaving P3 region precursor, which contained active 3C protease. A genetically engineered insertion within the 3C sequences eliminated endogenous self-cleavage activity without altering the ability of the P3 peptide to serve as substrate in bimolecular reactions with added 3C. Another plasmid encoding the L-VP0 portion of the capsid region was used to demonstrate that scission between the leader peptide (L) and capsid protein VP0 can be catalyzed by 3C. The enzyme responsible for this step was previously unidentified. A rapid purification scheme for isolation of 3C from EMC-infected HeLa cells is also presented.

The nucleotide and deduced amino acid sequences of the encephalomyocarditis viral polyprotein coding region.

The nucleotide sequence of 7200 bases of encephalomyocarditis (EMC) viral RNA, including the complete polyprotein-coding region, was determined. The polyprotein is encoded within a unique translational reading frame, 6870 bases in length. Protein synthesis begins with the sequence Met-Ala-Thr, and ends with the sequence Leu-Phe-Trp, 126 bases from the 3' end of the RNA. Viral capsid and noncapsid proteins were aligned with the deduced amino acid sequence of the polyprotein. The proteolytic processing map follows the standard 4-3-4 picornaviral pattern except for a short leader peptide (8 kd), which precedes the capsid proteins. Identification of the proteolytic cleavage sites showed that EMC viral protease, p22, has cleavage specificity for gln-gly or gln-ser sequences with adjacent proline residues. The cleavage specificity of the host-coded protease(s) includes both tyr-pro and gln-gly sequences.