Laboratory of Virology, Istituto Superiore di Sanità, Viale Regina Elena 299, 00161 Rome, Italy1
Groupes des Bunyaviridés, Unité des Arbovirus et virus des Fièvres Haemorragiques, Institut Pasteur, 75724 Paris Cedex, France2
Author for correspondence: Colomba Giorgi. Fax +39 06 49902082. e-mail giorgi{at}iss.it
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Abstract |
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Introduction |
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An in vivo system that allowed the transcription of cDNA-derived RNA templates was established previously for RVFV (Lopez et al., 1995 ). This system was based on an S-like genomic RNA molecule containing the chloramphenicol acetyltransferase (CAT) reporter gene in the antisense orientation flanked by the 3' and 5' non-coding regions of the genomic S segment. Transcription was monitored by assaying CAT activity in cells that were infected with vaccinia viruses expressing the viral proteins and transfected with the S-like RNA genome. A similar system was also developed successfully for Bunyamwera virus (Dunn et al., 1995
). In both these systems, only the N and L proteins were necessary to form a functional transcriptase complex. The NSs protein had neither an inhibitory nor a stimulating effect on transcriptase activity.
In this study, we used ribozymes to cleave RNA in vivo (Pattnaik et al., 1992 ) in order to obtain the correct 5' and 3' extremities of the RNA molecule, which is directly released in the infected cell. The antisense CAT gene flanked by RVFV S-terminal genomic sequences (MP12 strain) derived from the pCAT-RVF-Sg vector (Lopez et al., 1995
) was cloned into the pBluescript KS vector (Stratagene) between two ribozyme sequences, i.e. the hammerhead and the antigenomic hepatitis delta ribozymes (Haseloff & Gerlach, 1988
; Perrotta & Been, 1991
), which are under the control of the T7 promoter. The resultant clone was designated pCP-S (Fig. 1a
). An in vivo transcription system was then constructed by transfecting Vero-E6 cells, which had been pre-infected with a T7 polymerase-expressing recombinant vaccinia virus (vTF7-3, kindly provided by B. Moss, NIH, USA), with plasmids carrying the RVFV L and N sequences (pBS-Lc and pRVF-N) (Lopez et al., 1995
) and with pCP-S in vitro-transcribed RNA. The RVFV N and L proteins expressed in this T7-driven vaccinia virus system were revealed by Western blotting using RVFV anti-N monoclonal antibodies and TOSV anti-L polyclonal antibodies, respectively (Fig. 1b
). The CAT activity that was revealed in cell extracts (Fig. 2
, lane 4) showed the reliability of this assay.
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A plasmid containing only the N coding sequence (p4N) was also constructed in order to avoid the possibility of annealing that might occur between the complementary sequences at the 5' end of the N mRNA and at the 3' end of the S-like RNA.
The TOSV genomic S-like plasmid p4.4 was then constructed. It was obtained by replacing the RVFV terminal genomic sequences with those from TOSV by two successive steps of PCR using the Ex-site system (Promega). The primer pairs used were H (hammerhead, 5'GACCTAGGGAAACACACCC 3') and 5'TOS-3'CAT (5'ACACAAAGACCTCCCGTATTGCTAAACCAGAGGCTAGTAATAGACTTCTA GACAGCCCTCGAGAAGCTTCGACGAAT3', TOSV sequence is underlined), and D (delta, 5' GGGTCGGCATGGCATCTCCA 3') and 3'TOS-5'CAT (5'ACACAGAGATTCCCGTGTATTAAACAAAAGCTATCAACATGGAGAAAAAAATCACTGG3', TOSV sequence is underlined) (Fig. 1a).
The three plasmids expressing TOSV proteins were transfected into vTF7-3-infected Vero-E6 cells and cell lysates were then analysed for protein expression by Western blot analysis, as described by Di Bonito et al. (1999) . The mono-specific TOSV polyclonal anti-L, -N and -NSs antibodies identified three proteins with the electrophoretic mobilities that were expected for L, N and NSs proteins, respectively. The electrophoretic mobility of the recombinant L protein was compared with that of the native L protein from TOSV-infected cells (Fig. 1b
). The low expression of the recombinant L protein observed is a feature which is shared by all Bunyaviridae L polymerases that are expressed either by recombinant vaccinia viruses or by T7-driven expression plasmids (Elliott, 1996
; Lopez et al., 1995
; Dunn et al., 1995
; Jin & Elliott, 1991
).
To assay TOSV transcriptase activity, vTF7-3-infected Vero-E6 cells were cotransfected with the TOSV L and N expression plasmids using a transfection reagent of non-liposomal formulation, Fugene 6 (Roche), according to the manufacturer's recommendations. Cells were transfected 3 h later with TOSV S-like RNA, which was in vitro-transcribed from p4.4. Cell extracts were prepared 48 h post-infection and assayed for CAT activity as described previously (Ausubel et al., 1995 ).
Under these conditions, CAT activity was detected (Fig. 2, lane 1), indicating that the S-like RNA had been transcribed into mRNA. No CAT activity was detected either in infected cells transfected with only TOSV S-like RNA (Fig. 2
, lane 10) or in cells transfected with both TOSV S-like RNA and one of the expression plasmids (data not shown). In each experiment, the efficiency of plasmid transfection was tested by monitoring N protein expression by immunofluorescence (data not shown). CAT assays were performed only when transfection efficiencies were above 60%.
In this system, no significant improvement of CAT activity was obtained when cells were transfected with pNSs (data not shown), indicating that NSs has neither a stimulating nor an inhibitory effect upon transcription. Recently, evidence was obtained that showed that RVFV and Bunyamwera virus NSs proteins are involved in the IFN response in infected cells (Bouloy et al., 2001 ; Weber et al., 2000
). Although the function of TOSV NSs is not yet determined, it might play a similar role in IFN response in infected cells. These results provide evidence that L and N proteins form the active TOSV transcription complex.
Viruses with multipartite genomes can exchange their genomic segments, giving rise to heterotypic viruses. RNA segment reassortment among viruses with multipartite genomes belonging to the same genus or serogroup has been shown in members of the Bunyaviridae family both in vivo and in vitro (reviewed by Pringle, 1996 ; Sall et al., 1999
). TOSV and RVFV are circulating in the Mediterranean regions and, although they are not transmitted by the same vector, dual heterologous infection of vertebrate hosts cannot be excluded. Moreover, the similarities between their nucleotide sequences (Accardi et al., 1993
; Giorgi et al., 1991
) suggest that the two phleboviruses are phylogenetically related, in spite of the differences in their ecology and pathogenesis (Nicoletti et al., 1996
; Peters & Meegan, 1989
; Sall et al., 1998
).
To address the molecular basis of reassortment between TOSV and RVFV, we investigated whether or not their transcription complexes would be active with the S-like RNA genome of the heterologous virus.
vTF7-3-infected Vero-E6 cells were either cotransfected with TOS-N and -L expression plasmids and transfected with the RVFV S-like RNA genome, or cotransfected with RVF-N and -L expression plasmids and transfected with TOSV S-like RNA genome. In both cases, CAT activity was detected (Fig. 2, lanes 2 and 3), indicating that the transcription complex of both viruses can recognize the heterologous terminal genomic sequences and therefore transcribe the heterologous S-like RNA genome.
We also investigated whether or not a transcriptase complex that was artificially derived from both viruses would be active with the respective S-like RNA genomes. CAT activity was detected when TOS-N in association with RVF-L was tested on the RVFV S-like RNA genome (Fig. 2, lane 6), but not when tested on the TOSV S-like genomic RNA (Fig. 2
, lane 8). No CAT activity was detected when RVF-N in association with TOS-L was tested on either RVFV or TOSV S-like genomic RNAs (Fig. 2
, lanes 5 and 7). Therefore, the combination of TOS-N + RVF-L proteins works in this assay and is active only on the RVFV S-like genomic RNA, highlighting the importance of the template sequences in transcription. In this context, some role could be played by the nucleotide differences observed at the 3' ends of the genomic sequences of the two viruses (see below) in combination with other factors, for example, interactions between the L and N proteins.
The sequence that is recognized by the RVFV transcription complex at the 3' end of its viral ambisense S segment has been determined previously (Prehaud et al., 1997 ). The minimal sequence that is required for transcription resides in the first 3'-terminal 13 nucleotides of both genomic and antigenomic RNAs, but the first seven or eight nucleotides are not themselves sufficient for initiating transcription.
Alignments of the 3'-terminal 13 nucleotides of TOSV and RVFV S segments show a high degree of identity in either the genomic or the antigenomic sequences (Fig. 3). Genomic sequences show mismatches at residues 6, 9 and 11, whereas the antigenomic sequences show full nucleotide identity except at residue 12. Interestingly, the same positions that are mismatched between the genomes are identical to each other in the antigenomes and vice versa. Moreover, residue 10 shows identity between the strands of the same polarity (residue A on the genomic RNAs and residue G on the antigenomic RNAs). These observations and our results suggest that the two viruses could be considered to be virus variants: the nucleotide differences between their 3'-terminal genomic sequences result in silent mutations with respect to transcription. Since the first 13 nucleotides at the ends of both S genomic segments are nearly perfectly matched in the two viruses (Fig. 3
), we can expect that the respective polymerase complexes could also be active on the viral antigenomic RNAs from which the mRNAs of the NSs proteins are transcribed.
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Acknowledgments |
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Footnotes |
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References |
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Received 23 October 2000;
accepted 9 January 2001.