Nucleotide sequence and expression in Escherichia coli of the gene encoding the nonstructural protein NCVP2 of bovine rotavirus

Experimental pathways towards developing a rotavirus reverse genetics system: synthetic full length rotavirus ssRNAs are neither infectious nor translated in permissive cells

At present the ability to create rationally engineered mutant rotaviruses is limited because of the lack of a tractable helper virus-free reverse genetics system. Using the cell culture adapted bovine RV RF strain (G6P6 [1]), we have attempted to recover infectious RV by co-transfecting in vitro transcribed ssRNAs which are identical in sequence to the positive sense strand of each of the 11 dsRNA genomic segments of the RF strain. The RNAs were produced either from cDNAs cloned by a target sequence-independent procedure, or from purified double layered RV particles (DLPs). We have validated their translational function by in vitro synthesis of (35)S-labelled proteins in rabbit reticulocyte lysates; all 11 proteins encoded by the RV genome were expressed. Transfection experiments with DLP- or cDNA-derived ssRNAs suggested that the RNAs do not act independently as mRNAs for protein synthesis, once delivered into various mammalian cell lines, and exhibit cytotoxicity. Transfected RNAs were not infectious since a viral cytopathic effect was not observed after infection of MA104 cells with lysates from transfected cells. By contrast, an engineered mRNA encoding eGFP was expressed when transfected under identical conditions into the same cell lines. Co-expression of plasmids encoding NSP2 and NSP5 using a fowlpox T7 polymerase recombinant virus revealed viroplasm-like structure formation, but this did not enable the translation of transfected RV ssRNAs. Attempts to recover RV from ssRNAs transcribed intracellularly from transfected cDNAs were also unsuccessful and suggested that these RNAs were also not translated, in contrast to successful translation from a transfected cDNA encoding an eGFP mRNA.

Translational regulation of rotavirus gene expression

Rotavirus mRNAs are transcribed from 11 genomic dsRNA segments within a subviral particle. The mRNAs are extruded into the cytoplasm where they serve as mRNA for protein synthesis and as templates for packaging and replication into dsRNA. The molecular steps in the replication pathway that regulate the levels of viral gene expression are not well defined. We have investigated potential mechanisms of regulation of rotavirus gene expression by functional evaluation of two differentially expressed viral mRNAs. NSP1 (gene 5) and VP6 (gene 6) are expressed early in infection, and VP6 is expressed in excess over NSP1. We formulated the hypothesis that the amounts of NSP1 and VP6 were regulated by the translational efficiencies of the respective mRNAs. We measured the levels of gene 5 and gene 6 mRNA and showed that they were not significantly different, and protein analysis indicated no difference in stability of NSP1 compared with VP6. Polyribosome analysis showed that the majority of gene 6 mRNA was present on large polysomes. In contrast, sedimentation of more than half of the gene 5 mRNA was subpolysomal. The change in distribution of gene 5 mRNA in polyribosome gradients in response to treatment with low concentrations of cycloheximide suggested that gene 5 is a poor translation initiation template compared with gene 6 mRNA. These data define a regulatory mechanism for the difference in amounts of VP6 and NSP1 and provide evidence for post-transcriptional control of rotavirus gene expression mediated by the translational efficiency of individual viral mRNAs.

Interferon regulatory factor 3 is a cellular partner of rotavirus NSP1

The rotavirus nonstructural protein NSP1 is the least conserved protein in the rotavirus genome, and its function in the replication cycle is not known. We employed NSP1 as bait in the yeast two-hybrid interaction trap to identify candidate cellular partners of NSP1 that may provide clues to its function. Interferon regulatory factor 3 (IRF-3) was identified as an NSP1 interactor. NSP1 synthesized in rotavirus-infected cells bound IRF-3 in a glutathione S-transferase pull-down assay, indicating that the interaction was not unique to the two-hybrid system. NSP1 of murine rotavirus strain EW also interacted with IRF-3. NSP1 deletion and point mutants were constructed to map domains important in the interaction between NSP1 and IRF-3. The data suggest that a binding domain resides in the C terminus of NSP1 and that the N-terminal conserved zinc finger is important but not sufficient to mediate binding to IRF-3. We predict that a role for NSP1 in rotavirus-infected cells is to inhibit activation of IRF-3 and diminish the cellular interferon response.

Molecular characterization of human group C rotavirus genes 6, 7 and 9

Genes 6, 7 and 9 of human group C rotavirus 'Bristol' strain, encoding non-structural proteins (NSP) 3, 1 and 2, respectively, were cloned and sequenced. Human group C rotavirus genome segment 6 is 1350 bp and contains a single ORF of 1231 nucleotides (encoding 402 amino acids). Genome segment 7 is 1270 bp and encodes a protein of 394 amino acids and genome segment 9 is 1037 bp and encodes a 312 amino acid protein. The human group C rotavirus genes 6, 7 and 9 showed 78, 67 and 88% sequence identity, respectively, to the corresponding porcine group C rotavirus genes. The derived protein sequences were compared with those of the porcine 'Cowden' group C and mammalian group A rotavirus strains. The human group C rotavirus NSP1 protein sequence is one amino acid longer than the porcine group C equivalent. In common with group A and porcine group C rotaviruses, the human group C rotavirus NSP1 protein has a zinc finger motif. Human group C rotavirus NSP2 has two hydrophobic heptad repeat regions, a basic, RNA-binding domain and a basic, proline-rich region. Human group C rotavirus NSP3 has both single- and double-stranded RNA-binding domains and several hydrophobic heptad repeat regions, one of which forms a leucine zipper. This work completes the molecular characterization of the non-structural proteins of a human group C rotavirus. Phylogenetic analysis of all the non-structural genes of group A, B and C rotaviruses suggests that these viruses have diverged at a constant rate from a common ancestor.

Nondefective rotavirus mutants with an NSP1 gene which has a deletion of 500 nucleotides, including a cysteine-rich zinc finger motif-encoding region (nucleotides 156 to 248), or which has a nonsense codon at nucleotides 153-155

We isolated two nondefective bovine rotavirus mutants (A5-10 and A5-16 clones) which have nonsense mutations in the early portion of the open reading frame of the NSP1 gene. In the NSP1 gene (1,587 bases long) of A5-10, a nonsense codon is present at nucleotides 153 to 155 just upstream of the coding region (nucleotides 156 to 230) of a cysteine-rich Zn finger motif. A5-16 gene 5 (1,087 bases long) was found to have a large deletion of 500 bases corresponding to nucleotides 142 to 641 of a parent A5-10 NSP1 gene and to have a nonsense codon at nucleotides 183 to 185, which resulted from the deletion. Expression of gene 5-specific NSP1 could not be detected in MA-104 cells infected with the A5-10 or A5-16 clone or in an in vitro translation system using the plasmids with gene 5 cDNA from A5-10 or A5-16. Nevertheless, both A5-10 and A5-16 replicated well in cultured cells, although the plaque size of A5-16 was extremely small.

Structure and function of rotavirus NSP1

Studies on the structure and function of the nonstructural proteins (NSP1-NSP5) of rotaviruses are important for dissection of the morphogenesis and replication processes of rotavirus. Above all, NSP1, the product of gene 5, has several interesting features, such as extreme sequence diversity, a highly conserved cysteine-rich region, RNA-binding activity, accumulation on the cytoskeleton, and non-random segregation in reassortment. Recently, comparable NSP1 sequence analysis has been performed on a number of rotavirus strains from various species. Furthermore, characterization of mutants with rearranged NSP1 genes has helped to elucidate the structure-function interaction of NSP1. We isolated and characterized two interesting mutants which have a large deletion including the cysteine-rich region or a nonsense codon at the early portion in the open reading frame (ORF) of the NSP1 gene. In this report, we summarize the structure and function of NSP1.

Species-specific and interspecies relatedness of NSP1 sequences in human, porcine, bovine, feline, and equine rotavirus strains

We have sequenced gene 5 encoding NSP1 for three human, two porcine, two bovine, one feline, and five equine rotavirus strains, and compared the nucleotide and deduced amino acid sequences with the published sequences for other various strains. Subgroup I human strains L26, 69M, and DS-1 were found to have a similar NSP1 sequence despite their different G serotypes, VP4 genotypes, and RNA patterns. The NSP1 sequence of the human strain K8 showed a high degree of homology to those of porcine strains OSU and YM. A high degree of homology was found among three equine strains (H2, FI-14, and FI23), but they differed from the other equine strains L338 and H1. The strain H1 was similar to the porcine strains. The feline strain Cat2 showed a high homology to bovine strains UK, RF, and A44. Thus, species-specific and interspecies relatedness of NSP1 sequences among human, porcine, bovine, feline and equine rotaviruses was found. Overall genomic relatedness of strains L26 and YM to various human and animal strains was also examined by RNA-RNA hybridization assay. The present and previous hybridization results showed that there is a good correlation in most strains between overall genomic property (or genogroup) and NSP1 sequence homology.

Distinctness of NSP1 gene of human rotavirus AU-1 from NSP1 gene of other human genogroups

Human rotavirus strain AU-1 has a genomic RNA constellation distinct from that of either the Wa or DS-1 genogroup and thus, represents the third human rotavirus genogroup. Nucleotide sequence analysis of the non-structural protein 1 (NSP1) of AU-1 revealed that it was only 53-57% identical at the amino acid level with strains belonging to either the Wa or the DS-1 genogroup. This result confirmed and extended the earlier observation that the grouping based on the NSP1 sequence similarity is usually in good agreement with classification by genogroup. Phylogenetic analysis placed the AU-1 NSP1 gene on the bovine NSP1 branch, although more than 13% amino acid difference was observed.

Effect of the selection pressure with anti-VP7 and anti-VP4 neutralizing monoclonal antibodies on reassortant formation between two human rotaviruses

In order to study the effect of selection pressure of anti-VP4 and anti-VP7 neutralizing monoclonal antibodies(N-MAbs) on reassortant formation, 424 reassortant clones were produced from mixed cultures of human rotavirus strains Wa and HN126 and their genotypes were analysed. Reassortant selection was done with four types of N-MAb: anti-VP4 MAb to Wa and anti-VP7 MAb to HN126(selection A); anti-VP4 MAb to HN126 and anti-VP7 MAb to Wa(selection B); anti-VP7 MAb to Wa(selection C); and anti-VP4 MAb to Wa(selection D). In each selection experiment, more than 100 clones were isolated, and the parental origin of RNA segments was identified by polyacrylamide gel electrophoresis. All clones isolated by selections A and B were found to be antigenic mosaic reassortants with the VP4 gene of HN126 and the VP7 gene of Wa and antigenic mosaic reassortants with the VP4 gene of Wa and the VP7 gene of HN126, respectively. Although in reassortants of both selections, RNA segments 2, 3, 5 and 6 were selected from strain Wa at considerably high rates, selection rates of RNA segments 1, 7, 8, and 11 were significantly different between selection A and B. In reassortants from selection C and D, selection rates of RNA segments 1, 3, 6, 7, 8, and 11 from Wa were significantly lower than those in selection A and B, whereas RNA segments 2 and 5 were almost exclusively selected from Wa as observed in selection A and B. These results indicated the presence of two types of nonrandom gene selection in reassortant formation, one strongly dependent on, and another irrespective of, the selection pressure with N-MAbs.

Sequence analysis of three non structural proteins of a porcine group C (Cowden strain) rotavirus

Sequences of three gene products of a group C (Cowden strain) rotavirus are presented and compared with the sequences of the corresponding group A (SA11) proteins. The degree of similarity for gene 7, 9, and 10 is respectively 34%, 58%, and 45%. Comparison of these 2 viruses allowed to identify several regions well conserved. In the protein coded by Cowden segment 7 (NS 53) only a short cystein and histidine rich region, presenting the zinc finger consensus motif, is common to group A (segment 5) and group C sequences. Conversely the protein coded by segment 9 (NS 35) presented marked homology with group A NS 35. The protein coded by segment 10 (NS 26) is serine rich and presents an accumulation of charged residues near the carboxy terminus, like group A counterpart. This genomic segment presented a single large open reading frame, that contrasts with the group A counterpart for which a second out of phase ORF is used in rotavirus infected MA 104 cells.

Sequence analysis of the gene (6) encoding the major capsid protein (VP6) of group C rotavirus: higher than expected homology to the corresponding protein from group A virus

Two overlapping c-DNA clones, which hybridized in Northern blots to RNA segment 6 of the prototype strain (Cowden) of group C rotavirus, were selected from a c-DNA library in pBR322 and sequenced. The gene 6 sequence obtained was 1349 nucleotides and contained a single long open reading frame encoding a protein of 394 amino acids (total MW, 44,479) which is in line with the size of the major capsid protein VP6. Comparison of the group C sequence with that of the corresponding group A rotavirus gene revealed homology levels of 55 and 42% for nucleotides and amino acids, respectively. These values were surprisingly high in view of previous immunological and nucleic acid hybridization data which failed to show any cross-reaction between group A and non-group A rotaviruses. The epidemiological implications of these observations are discussed.

Identification of the gene encoding the group B rotavirus VP7 equivalent: primary characterization of the ADRV segment 9 RNA

Gene segment 9 of the adult diarrheal rotavirus, ADRV, has been cloned, and the full-length gene 9 cDNA has been sequenced. Sequences at the 5' and 3' termini of the gene 9 double-stranded RNA were confirmed by direct RNA sequencing. The ninth RNA segment is 814 bases in length with a single open reading frame beginning at base 10 and terminating at base 757. The encoded polypeptide contains 249 amino acids with a calculated molecular weight of 28.5 kDa. The protein contains three potential N-linked glycosylation sites and a hydrophobic signal-like sequence at its amino terminus. A search of the NBRF protein data base with the encoded polypeptide revealed extensive similarities with VP7 proteins from a number of group A rotaviruses. Direct comparisons of the ADRV gene 9 polypeptide and the group A rotavirus VP7 demonstrate that the two proteins share 78% amino acid similarity and 28% identity as well as predicted secondary structure similarities. These findings suggest that the ADRV gene segment 9 encodes the VP7 polypeptide equivalent of group A rotaviruses.

cDNA cloning of each genomic segment of the group B rotavirus ADRV: molecular characterization of the 11th RNA segment

The group B noncultivatable rotavirus, ADRV, was purified from infected stool specimens. Double-stranded RNA was extracted, polyadenylated, reverse transcribed into cDNA, and cloned into plasmid vector pAT153. Each cDNA clone hybridized to a single ADRV RNA segment and cDNA clones of each genomic RNA segment were identified. Sequencing of genomic RNA and a full-length cDNA clone (AD63) determined that ADRV RNA segment 11 is 631 bases in length and contains a single open reading frame of 170 amino acids with a calculated molecular weight of 19.9 kDa and a pl of 6.2. The RNA 5'- and 3'-termini contain untranslated regions of 58 and 63 bases, respectively, and are complementary to each other. A comparison of encoded ADRV gene 11 amino acids with the NS26 protein of group A rotaviruses demonstrates a distant similarity between the two proteins. Further analysis and use of these ADRV clones should aid in determining the gene coding assignments for group B proteins as well as for diagnostic detection of group B or ADRV-specific nucleic acids in specimens.

Conservation of a potential metal binding motif despite extensive sequence diversity in the rotavirus nonstructural protein NS53

The nucleotide sequence for the simian rotavirus SA11 gene segment 5 has been determined. The gene is 1611 nucleotides in length and contains a single open reading frame of 1485 nucleotides. The segment codes for the nonstructural protein NS53 which is predicted to be a polypeptide of 495 amino acids with a molecular weight of 58,484. When compared to the sequence of bovine RF gene segment 5 there are homologies of only 49 and 36% at the nucleotide and amino acid levels, respectively. This is in marked contrast to the situation with other rotavirus nonstructural proteins which are highly conserved between isolates. Nevertheless, there is a conserved region between amino acids 37-81 which contains a generalized motif for a metal binding domain. All eight cysteine and two histidine residues in this short sequence are conserved between the simian and bovine NS53 proteins. The conservation of this domain despite extensive sequence diversity in the remainder of the protein suggests that this region is functionally important.

Rotavirus gene structure and function

Knowledge of the structure and function of the genes and proteins of the rotaviruses has expanded rapidly. Information obtained in the last 5 years has revealed unexpected and unique molecular properties of rotavirus proteins of general interest to virologists, biochemists, and cell biologists. Rotaviruses share some features of replication with reoviruses, yet antigenic and molecular properties of the outer capsid proteins, VP4 (a protein whose cleavage is required for infectivity, possibly by mediating fusion with the cell membrane) and VP7 (a glycoprotein), show more similarities with those of other viruses such as the orthomyxoviruses, paramyxoviruses, and alphaviruses. Rotavirus morphogenesis is a unique process, during which immature subviral particles bud through the membrane of the endoplasmic reticulum (ER). During this process, transiently enveloped particles form, the outer capsid proteins are assembled onto particles, and mature particles accumulate in the lumen of the ER. Two ER-specific viral glycoproteins are involved in virus maturation, and these glycoproteins have been shown to be useful models for studying protein targeting and retention in the ER and for studying mechanisms of virus budding. New ideas and approaches to understanding how each gene functions to replicate and assemble the segmented viral genome have emerged from knowledge of the primary structure of rotavirus genes and their proteins and from knowledge of the properties of domains on individual proteins. Localization of type-specific and cross-reactive neutralizing epitopes on the outer capsid proteins is becoming increasingly useful in dissecting the protective immune response, including evaluation of vaccine trials, with the practical possibility of enhancing the production of new, more effective vaccines. Finally, future analyses with recently characterized immunologic and gene probes and new animal models can be expected to provide a basic understanding of what regulates the primary interactions of these viruses with the gastrointestinal tract and the subsequent responses of infected hosts.

Nucleotide sequence of gene segment 1 of a porcine rotavirus strain

The nucleotide sequence of gene segment 1, which encodes VP1 of porcine rotavirus strain Gottfried, was determined. VP1 is associated with single-shelled rotavirus particles and has been linked to virus transcriptase and replicase enzymatic activities. Gene segment 1 is 3302 nucleotides long with a single open reading frame capable of coding for a protein of 1088 amino acids (calculated mol wt 125 kDa). The predicted amino acid sequence revealed that VP1 is basic, with a net positive charge of 18 at pH 7.0. It shares five consensus sequences with several well-characterized RNA-dependent RNA polymerases. Gottfried VP1 also shares consensus sequences with certain GTP-binding proteins; however, we could not detect any GTP-binding activity in VP1. Our preliminary experiments suggest that VP3, another polypeptide located in single-shelled rotavirus particles, possesses GTP-binding activity. These results suggest that mRNA synthesis and capping enzyme activities are related to VP1 and VP3, respectively.

Naturally occurring serotype 2/subgroup II rotavirus reassortants in northern Brazil

Nine serotype 2 human rotavirus strains were isolated in a community-based longitudinal study in Northern Brazil. Five of these strains had a 'long' RNA electrophoretic pattern and all five strains were determined to belong to subgroup II by ELISA assay, in contrast to properties common to serotype 2 human rotaviruses previously characterized. Hybridization studies of one of these unusual strains with 32P-labelled mRNAs derived from the prototype human strains Wa (serotype 1, subgroup II) and S2 (serotype 2, subgroup I) suggested that it was generated by a reassortment event in nature, in which a subgroup II, 'long' electropherotype rotavirus exchanged its serotype-specific gene and gene number 10 for the equivalent genes from a serotype 2, 'short' electropherotype virus.

Nucleotide sequence of bovine rotavirus gene 1 and expression of the gene product in baculovirus

The nucleotide sequence of the gene that encodes for the structural viral protein VP1 of bovine rotavirus (RF strain) has been determined. The sequence data indicate that segment 1 contains 3302 bp and is A + T rich (65.3%). The positive strand of segment 1 contains a single open reading frame that extends 1088 codons and possesses 5'- and 3'-terminal untranslated regions of 18 and 20 bp, respectively. The first AUG conforms to the Kozak consensus sequence and if utilized, would yield a protein having a calculated molecular weight of 124,847, very close to the apparent molecular weight of VP1 (M.W. 125,000). The deduced amino acid sequence presents significant similarities with RNA-dependent RNA polymerase of several RNA viruses. VP1 was also synthesized in baculovirus using two transfer vecors: pAC461 and pVL941. Following infection of Sf9 cells with a recombinant baculovirus, a full-length nonfusion protein was synthesised which shares properties with authentic VP1 made in monkey kidney cells. The level of VP1 synthesis was about 10-fold higher when the baculovirus recombinant was derived from the pVL941 transfer vector. In that case, VP1 was expressed in yields approximately equivalent to 10% of the cellular protein. The recombinant protein was immunoprecipitated by hyperimmune serum raised against purified rotavirus. It also was immunogenic; a hyperimmune serum made in guinea pigs reacted with VP1 using immunoprecipitation and Western blot. This serum did not possess neutralization activity.

Synthesis of the major inner capsid protein VP6 of the human rotavirus Wa in Escherichia coli

The gene for the major inner capsid protein VP6 of human rotavirus strain Wa has been cloned and placed into a bacterial expression vector under the control of the inducible hybrid trp-lac (tac) promoter. Recombinant VP6 was produced at low levels in a cell-free Escherichia coli transcription-translation system programmed with this expression plasmid. The yield of VP6 synthesized in the extract could be increased several-fold by introduction of point mutations upstream and downstream from the start codon. Upon induction with IPTG, E. coli JM105 cells harboring the mutated expression plasmid produced VP6 as shown by immunoblotting of proteins from bacterial lysates with anti-Wa antiserum. Recombinant VP6 appeared to inhibit the growth of E. coli and did not accumulate in the cells to high levels. Conformational analysis with a monoclonal antibody suggested that bacterially produced VP6 adopted an oligomeric structure characteristic for native VP6.