Genetic and phenotypic studies on Ross River virus variants of enhanced virulence selected during mouse passage.

We have passaged Ross River virus (RRV) in mice to generate variants with increased mouse virulence and attempted to relate changes in virulence to genome sequence changes. RRV NBO (zero passage in mice) is a plaque-purified clone of the mouse-avirulent strain RRV NB5092, and is of low virulence for day-old mice. During RRV NBO replication in infant mice, its virulence for day-old mice increased markedly with time. By 7 days postinfection the LD50 value of harvested virus (passage level one) was congruent to 10(4)-fold less than that of the parental virus. No further decrease in LD50 followed 10 serial passages in infant mice. However, 10th passage level virus showed increased clinical effects in week-old mice by comparison with virus from passage levels one and two. The growth kinetics of RRV variants in mice suggested that the rate and extent of RRV replication in the brain tissue determined the enhanced mouse virulence of serially passaged virus. Seven out of eight independently passaged, 10th passage level variants had changes in the E2 gene leading to one or two amino acid substitutions. The changes were at residues 212, 232, 234, 251, 341, 27 and 172, and 72 and 134 in these variants; all changes except two were nonconservative. Residues 212, 234, and 251 form part of a neutralization determinant in RRV. Changes in epitope b2 (which includes amino acids 246, 248, and 251) alter the kinetics of RRV entry into cells (P. Kerr, R. C. Weir, and L. Dalgarno, unpublished data). First and second passage level virus of enhanced virulence was unchanged in E2 or E1 gene sequences from RRV NBO. However, 1st, 2nd, and 10th passage level virus induced higher levels of virus-specific RNA synthesis than did RRV NBO in cultured BHK cells. We propose a model for the mechanism of virulence enhancement on passaging RRV NBO in mice.

Genetic stability of Ross River virus during epidemic spread in nonimmune humans.

We have examined the rate of evolution of Ross River virus, a mosquito-borne RNA virus, during epidemic spread through tens of thousands of nonimmune humans over a period of 10 months. Two regions of the Ross River virus genome were sequenced: the E2 gene (1.2 kb in length), which encodes the major neutralization determinant of the virus, and 0.4 kb of the 3'-untranslated region. In the E2 gene, a single nucleotide change was selected which led to a predicted amino acid change at residue 219. No changes were selected in the 3'-untranslated region. By comparison with rates of evolution reported for non-arthropod-borne RNA viruses, the rate for Ross River virus is surprisingly low. We identify three features of the Ross River virus replication and transmission cycle which may limit the rate of evolution of arthropod-borne viruses in the field.

Genome sequences of a mouse-avirulent and a mouse-virulent strain of Ross River virus.

The nucleotide sequence of the genomic RNA of a mouse-avirulent strain of Ross River virus, RRV NB5092 (isolated in 1969), has been determined and the corresponding sequence for the prototype mouse-virulent strain, RRV T48 (isolated in 1959), has been completed. The RRV NB5092 genome is approximately 11,674 nucleotides in length, compared with 11,853 nucleotides for RRV T48. RRV NB5092 and RRV T48 have the same genome organization. For both viruses an untranslated region of 80 nucleotides at the 5' end of the genome is followed by a 7440-nucleotide open reading frame which is interrupted after 5586 nucleotides by a single opal termination codon. By homology with other alphaviruses, the 5586-nucleotide open reading frame encodes the nonstructural proteins nsP1, nsP2, and nsP3; a fourth nonstructural protein, nsP4, is produced by read-through of the opal codon. The RRV nonstructural proteins show strong homology with the corresponding proteins of Sindbis virus and Semliki Forest virus in terms of size, net charge, and hydropathy characteristics. However, homology is not uniform between or within the proteins; nsP1, nsP2, and nsP4 contain extended domains which are highly conserved between alphaviruses, while the C-terminal region of nsP3 shows little conservation in sequence or length between alphaviruses. An untranslated "junction" region of 44 nucleotides (for RRV NB5092) or 47 nucleotides (for RRV T48) separates the nonstructural and structural protein coding regions. The structural proteins (capsid-E3-E2-6K-E1) are translated from an open reading frame of 3762 nucleotides which is followed by a 3'-untranslated region of approximately 348 nucleotides (for RRV NB5092) or 524 nucleotides (for RRV T48). Excluding deletions and insertions, the genomes of RRV NB5092 and RRV T48 differ at 284 nucleotides, representing a sequence divergence of 2.38%. Sequence deletions or insertions were found only in the noncoding regions and include a 173-nucleotide deletion in the 3'-untranslated region of RRV NB5092, compared with RRV T48. In the coding regions, most of the nucleotide differences are silent; there are 36 amino acid differences in the nonstructural proteins and 12 in the structural proteins. The distribution of amino acid differences between the two RRV strains correlates with the location of domains which are poorly conserved in sequence between alphaviruses. The possible role of amino acid differences in envelope glycoproteins E1 and E2 in determining the different antigenic and biological properties of RRV NB5092 and RRV T48 is discussed.

Regions of conservation and divergence in the 3' untranslated sequences of genomic RNA from Ross River virus isolates.

The 3' untranslated (UT) sequences of the genomic RNAs of five geographic variants of the alphavirus Ross River virus (RRV) were determined and compared with the 3' UT sequence of RRV T48, the prototype strain. Part of the 3' UT region of Getah virus, a close serological relative of RRV, was also sequenced. The RRV 3' UT region varies markedly in length between variants. Large deletions or insertions, sequence rearrangements and single nucleotide substitutions are observed. A sequence tract of 49 to 58 nucleotides, which is repeated as four blocks in the RRV T48 3' UT region, occurs only once in the 3' UT region of one RRV strain (NB5092), indicating that the existence of repeat sequence blocks is not essential for RRV replication. However, the precise sequence of the 3' proximal copy of the repeat block and its position relative to the poly(A) tail were identical in all RRV isolates examined, suggesting that it has an important role in RRV replication. Nucleotide substitutions between RRV variants are distributed non-randomly along the length of the 3' UT region. The sequence of 120 to 130 nucleotides adjacent to the poly(A) tail is strongly conserved. Getah virus RNA contains three repeat sequence blocks in the 3' UT region. These are similar in sequence to those in RRV RNA but differ in their arrangement. Homology between the RRV and Getah 3' UT sequences is greatest in the 3' proximal repeat sequence block that shows three differences in 49 nucleotides. The 3' proximal repeat in Getah RNA occurs at the same position, relative to the poly(A) tail, as in all RRV variants. The RRV and Getah virus 3' UT sequences show extensive homology in the region between the 3' proximal repeat and the poly(A) tail but, apart from the repeat blocks themselves, they show no significant homology elsewhere.

Ross River virus mutant with a deletion in the E2 gene: properties of the virion, virus-specific macromolecule synthesis, and attenuation of virulence for mice.

A mutant of RRV T48 the prototype strain of Ross River virus has been isolated with a 21-nucleotide deletion in the gene coding for the envelope glycoprotein E2. Direct sequencing of the 26 S subgenomic RNA, together with HaeIII and TaqI restriction digest analysis of cDNA to RNAs from cells infected with the mutant virus (RRV dE2) and with RRV T48, were consistent with the deletion being the only major alteration in the mutant genome. The E2 protein of RRV dE2 virions had a higher electrophoretic mobility than that of RRV T48 E2 protein. Neither RRV dE2 nor RRV T48 virions contained more than trace amounts of E3, the small envelope glycoprotein found in Semliki Forest virus. RRV dE2 generated small plaques on Vero cell monolayers; plaque formation was not temperature-sensitive between 32 and 41 degrees. By comparison with RRV T48 the infectivity of RRV dE2 virions was thermolabile at 50 degrees. In BHK cells RRV dE2 grew with similar kinetics to RRV T48. Rates of synthesis of 26 S RNA and 49 S RNA were higher in cells infected with RRV dE2 than in cells infected with RRV T48. Virus-specific protein synthesis and shut-down of host protein synthesis occurred 2-3 hr earlier in RRV dE2-infected cells than in cells infected with RRV T48. Minor differences between the two viruses were observed in the profiles of virus-specific proteins generated in infected cells. In day-old mice RRV dE2 induced less severe symptoms of hind leg paralysis than did RRV T48. A small increase in LD50 and average survival time was observed in RRV dE2-infected mice by comparison with RRV T48 infected mice. Peak titers reached by RRV dE2 in the hind leg muscle, brain, and blood of day-old mice were 3-4 log units less than the titers reached during infection with RRV T48. In week-old mice the differences in virulence between the two strains were magnified: RRV dE2 induced no detectable symptoms even when injected at high doses (8 X 10(6) PFU) whereas the LD50 and average survival time for RRV T48 were unchanged from those in day-old mice. Peak RRV dE2 titers in hind leg muscle, brain, and blood, respectively, were 2, 5, and 5 log units less than the corresponding titers for RRV T48. Peak muscle titers reached by RRV dE2 were similar (approximately 10(8) PFU/g tissue) in day-old mice where lethality was high and in week-old mice where the virus was avirulent.(ABSTRACT TRUNCATED AT 400 WORDS)

Ross River virus genetic variants in Australia and the Pacific Islands.

HaeIII and TaqI restriction digest profiles of cDNA to infected cell RNA or virion RNA were used as a guide to genetic relationships between fourteen isolates of Ross River virus (RRV) obtained from mosquitoes collected in various localities in eastern Australia where the virus is endemic. RRV isolates from Fiji, American Samoa, the Cook Islands and the Wallis Islands where major outbreaks of epidemic polyarthritis took place in 1979-1980 were also examined. Among these RRV isolates we have identified three genetic types (I-III) on the basis of differences between their restriction digest profiles. We estimate that 1.5-5% nucleotide sequence diversity exists between genetic types. Within each genetic type strain differentiation gave rise to small but significant differences in restriction digest profiles. No clear pattern of geographic distribution of RRV genetic types could be established from the limited number of RRV isolates examined. Genetic types I, II and III, respectively, were isolated from three, three and one different mosquito species, indicating there is no strong association between genetic type and the species of mosquito vector. HaeIII restriction digest analysis did not detect any genetic difference between the four Pacific Island isolates, suggesting that a single RRV variant was involved in the epidemics. Genetically, this variant was closely related to isolates of genetic type II. Virtually identical HaeIII restriction digest profiles were observed for isolates obtained at various stages of the Pacific Island epidemics, suggesting that extensive sequence evolution did not accompany Ross River virus spread.

Analysis of Ross River virus genomic RNA using HaeIII digests of single-stranded cDNA to infected-cell RNA and virion RNA.

To study genetic relationships between isolates of Ross River virus (RRV), an alphavirus with a chromosome of approximately 12,000 nucleotides, total high-molecular-weight RNA from RRV-infected baby hamster kidney (BHK) cells was transcribed into 32P-labeled, complementary DNA using reverse transcriptase and random calf-thymus DNA primers. The cDNA was digested with HaeIII or TaqI (restriction nucleases which cleave single-stranded DNA), and the restriction fragments separated on a standard DNA sequencing gel. The resulting HaeIII or TaqI restriction digest profiles mainly comprised virus-specific bands; cell RNAs were transcribed poorly. In reconstruction experiments, purified 49 S RRV genomic RNA and a 10-fold mass excess of mock-infected-cell RNA were reverse transcribed in the same reaction mix. Under these conditions there was no interference with the transcription of viral RNA sequences. When the level of viral RNA was lowered to one-hundredth that of cell RNA in the reaction mix, there was no qualitative change in restriction digest profiles. The procedure is rapid, simple, uses small amounts of 32P, does not require purification of virus or viral RNA, and permits cross-comparison between several virus strains on a single one-dimensional gel. The method should be applicable to other single-stranded RNA viruses of moderate genome complexity.