Differential Transcription Attenuation of Rabies Virus Genes by Intergenic Regions: Generation of Recombinant Viruses Overexpressing the Polymerase Gene

doi:10.1128/JVI.74.16.7261-7269.2000

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Journal of Virology, August 2000, p. 7261-7269, Vol. 74, No. 16
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Differential Transcription Attenuation of Rabies Virus Genes by Intergenic Regions: Generation of Recombinant Viruses Overexpressing the Polymerase Gene

Stefan Finke,¹ James H. Cox,² and Karl-Klaus Conzelmann¹^,^*

Max von Pettenkofer Institute and Gene Center, Ludwig Maximilians University Munich, Munich,¹ and Department of Clinical Virology, Federal Research Center for Virus Diseases of Animals, Tübingen,² Germany

Received 23 December 1999/Accepted 17 May 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Gene expression of nonsegmented negative-sense RNA viruses involves sequential synthesis of monocistronic mRNAs and transcriptionalattenuation at gene borders resulting in a transcript gradient.To address the role of the heterogeneous rabies virus (RV) intergenicregions (IGRs) in transcription attenuation, we constructed bicistronicmodel RNAs in which two reporter genes are separated by the RVN/P gene border. Replacement of the 2-nucleotide (nt) N/P IGRwith the 5-nt IGRs from the P/M or M/G border resulted in attenuationof downstream gene transcription to 78 or 81%, respectively. Asevere attenuation to 11% was observed for the 24-nt G/L border.This indicated that attenuation in RV is correlated with the lengthof the IGR, and, in particular, severe downregulation of the L(polymerase) gene by the 24 nt IGR. By reverse genetics, we recoveredviable RVs in which the strongly attenuating G/L gene border ofwild-type (wt) RV (SAD L16) was replaced with N/P-derived geneborders (SAD T and SAD T2). In these viruses, transcription ofL mRNA was enhanced by factors of 1.8 and 5.1, respectively, resultingin exaggerated general gene expression, faster growth, highervirus titers, and induction of cytopathic effects in cell culture.The major role of the IGR in attenuation was further confirmedby reintroduction of the wt 24-nt IGR into SAD T, resulting ina ninefold drop of L mRNA. The ability to modulate RV gene expressionby altering transcriptional attenuation is an advantage in thestudy of virus protein functions and in the development of genedeliveryvectors.

	INTRODUCTION

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The major element of transcriptional regulation in nonsegmented negative-strand RNA viruses (Mononegavirales), which includethe families Filoviridae, Paramyxoviridae, Rhabdoviridae, andBornaviridae, is the gene order. The viral RNA polymerase is assumedto enter the genome at the 3' end and to sequentially transcribea leader RNA and up to 10 mostly monocistronic mRNAs (1, 2,14). Due to dissociation of the polymerase at each gene bordera progressive loss toward the template 5' end is observed, resultingin a gradient of transcripts following the gene order (20).Invariably, the 5'-terminal gene of Mononegavirales is the polymerasegene (L; large), so that L mRNAs are the least abundant viraltranscripts in infected cells (10, 29).

The gene borders of Mononegavirales are defined by conserved sequences. Colinear transcription of a gene proceeds to a shortU stretch, which is reiteratively copied to form the mRNA's poly(A)tail. The polymerase then is thought to reinitiate transcriptionat a consensus start signal, which is usually located downstreamof the polyadenylation signal. The nucleotides separating thetwo signals are apparently not transcribed and are known as theintergenic region IGR (3). Once recombinant systems allowingthe experimental modification of cis-acting sequences became available(reviewed in reference 10), the functions of the conserved stop/polyadenylationand restart signals were rapidly verified (4, 24, 32).However, functions of IGRs are not well understood sofar.

IGRs may be highly variable in sequence and length, suggesting regulatory functions in virus transcription. In the prototyperhabdovirus, vesicular stomatitis virus (VSV), the five protein-encodinggenes (3'-N-P-M-G-L-5') are usually separated by a conserved IGRconsisting of the dinucleotide GA (31). At each gene borderof VSV, approximately one-third of the polymerases that terminatedan upstream mRNA fail to initiate transcription of the downstreamgene (20). In contrast, in the closely related rabies virus(RV) (Lyssavirus genus), the four IGRs comprise different numbersof nucleotides, namely, 2 (N/P), 5 (P/M), 5 (M/G), and 24 to 29(G/L) (11, 39). This suggests differential attenuation, whichwould provide a more refined means for regulation of transcription.In particular, RV L seems to be severely downregulated, with LmRNA (and L protein) hardlydetectable.

The apparent correlation of IGR length and attenuation prompted us to analyze whether transcription of recombinant RV couldbe modified by exchanging particular IGRs and how this would affectvirus phenotype. In particular, one aim was to exaggerate RV geneexpression. We first analyzed transcription from bicistronic reportergene model genome analogs that contained either the authenticN/P gene junction or gene junctions that had been altered to containthe different intergenic sequences. Indeed, the 2-nucleotide (nt)N/P IGR was superior to others in supporting transcription ofthe downstream reporter gene, whereas a significantly reducedtranscription was mediated by the 24-nt G/L IGR. A series of recombinantRV mutants could be generated by exchange of the 24-nt G/L IGRwith the 2-nt IGR derived from the N/P gene border. Most interestingly,these mutants grew better than wild-type (wt) virus in cell cultureand showed cytopathic phenotypes, raising the question of whyL is downregulated in natural viruses. Viruses overexpressingL protein might be very well suited for vector purposes, especiallywhen the addition of multiple genes into the virus genome is requiredand where low expression of L protein due to additional transcriptionattenuation by extra gene borders may belimiting.

	MATERIALS AND METHODS

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Cells, viruses, and cDNA rescue experiments. Viruses were grown on BHK-21 clone BSR cell monolayers. Minigenome particles were recovered from pSDI-CL(NP) or its derivativesas described previously (13) by coexpression of minigenome cDNAand virus proteins N, P, M, G, and L in vaccinia virus vTF7-3-infectedcells (17). Cell culture supernatants were harvested 3 daysafter transfection, partially cleared of vaccinia virus by centrifugation,and then transferred on fresh BSR cells. One hour after passage,cells were superinfected with recombinant helper virus SAD Ambi(15, 16), which allows selective amplification of minigenomeRNA. Mutagenesis of pSDI-CL(NP) was performed as described previously(33) using primers igPM (5'-CATCATGAAAAAAACAGGCAACACCCCTCCTTTCG-3'),igMG (5'-CATCATGAAAAAAACTATTAACACCCCTCCTTTCG-3') and igGL (5'-CATCATGAAAAAAACATTAGATCAGAAGAACAACTGGCAACACCCCTCCTTTCG-3').

Recombinant viruses SAD T and SAD TigGL were recovered as described previously (34) after coexpression of the full-lengthantigenome sense RNA from plasmid-encoded cDNA and of plasmidsencoding RV proteins N, P, and L (13) in BSR cells expressingT7 RNA polymerase from recombinant vTF7-3. SAD T2 was recoveredin BSR T7/5 cells constitutively expressing T7 RNA polymerase(6, 16). For virus recovery, 10 µg of full-length cDNA andplasmids pTIT-N (5 µg), pTIT-P (2.5 µg), and pTIT-L (2.5 µg) werecotransfected in ~10⁶ BSR T7/5 cells grown in 8-cm² culture dishes after CaPO₄ precipitation (mammalian transfectionkit; Stratagene). Three days posttransfection, fresh culture mediumwas added, and after another 3 days, cell culture supernatantswere harvested and transferred on BSR cells. Two days after passage,infectious virus was detected by immunostaining against RV N protein(34).

Immunoblotting. Proteins were resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred to nitrocellulose membranes(Schleicher and Schuell) in a semidry transfer apparatus (OWLScientific). After incubation with blocking solution (2.5% drymilk and 0.05% Tween 20 in phosphate-buffered saline [PBST]) atroom temperature for 1 h, membranes were incubated overnight withrabbit serum raised against purified RV ribonucleoprotein (S50;1:20,000) in PBST. The blot was then incubated for 2 h with peroxidase-conjugatedgoat anti-rabbit immunoglobulin G (Dianova) diluted 1:10,000 inPBST. Proteins were visualized by chemifluorescence (Renaissance;NEN).

Construction of RV full-length cDNA clones. For modification of the SAD L16 G/L gene border, a 2.8-kb subclone of pSAD L16 spanning the 3'-terminal part of the G geneand 5'-terminal part of the L gene (pPsiX8 $Delta$ BEH; SAD L16 positions3823 to 6668) was added (34). A 0.6-kb HindIII/NsiI fragmentof pPsiX8 $Delta$ BEH containing the G/L gene border sequence was replacedwith a HindIII/NsiI fragment of pT7T-L (13) after Klenow fragmentfill-in resulting in deletion of the gene border sequence andgeneration of an NheI site at the former HindIII location (pPsiX8GL).The N/P gene border was inserted into the new NheI recognitionsite as a 121-bp XbaI/SpeI DNA fragment from pSKNP (16). A 2.4-kbStuI fragment from the resulting pPsiGNPL was exchanged with thecorresponding fragment of the full-length cDNA clone pSAD L16,resulting in pSAD T. For construction of pSAD TigGL, the G/L geneborder of pSAD T was excised with HpaI and NheI and was replacedwith the HpaI/NheI fragment containing the modified N/P gene borderof pSDI-CL(igGL).

SAD T2 was combined from several plasmids containing modified virus cDNA. The remainder of the L 5'-noncoding region was exchangedwith that of the P gene by PCR using the primers 6410M (5'-AAGTTGACTAACTTGTCTTTT-3'),and S-Turbo-L (5'-GCCTTTCGAACCATCCCAAACATGCTCGATCCTGGAGAGGTC-3').The latter contained an AsuII site (italics) upstream of the initiationcodon (bold) for joining of the PCR product to the N/P gene bordersequence present in a pBluescript vector (pSK9). The resultantplasmid, pPCR-L, containing the modified 5'-terminal part of theL gene was used to replace the original 5'-terminal part of theL gene of the full-length pSAD L16 as well as the entire upstreamhalf of the genome cDNA spanning the N, P, M, and G genes (PstIin the upstream multiple cloning site and BsgI in the L codingregion). The resulting plasmid, pSAD LPCR, (organization: T7 promoter-N/Pgene border-L gene-trailer-hepatitis D virus ribozyme) was completedto a full-length cDNA (pSAD ST) by reinsertion of a fragment containingthe 3'-terminal half of the genome and in which the P/M and M/Ggene borders were exchanged with the N/P gene border (pSK-NPMG;see below). This procedure resulted also in the deletion of partof the G 3'-noncoding region ( $Psi$ gene) in pSAD ST. For generationof pSAD TB and pSAD T2, a cDNA fragment from SAD L16 spanningthe N, P, and M genes and part of the G gene and a cDNA fragmentfrom SAD L16 spanning the N and P genes and part of the M gene,respectively, were used to replace the corresponding sequencesof pSADST.

The intermediate plasmid pSK-NPMG, in which the P/M and the M/G gene borders are replaced by the N/P gene border, was assembledfrom three plasmids, namely, pSAD L16 (N and P genes), pSK9M,which contained an N/P border (109-bp MaeIII/BglII cDNA fragmentof pSAD L16, positions 1412 to 1521) upstream of the M gene, andpSK9G, which contained the N/P border upstream of the G gene.Plasmids pSK9M and pSK9G were used to generate pSK9MG by insertionof a SalI/BglII fragment from pSK9G in pSK9M. A fragment frompSK9MG spanning the M and G genes was then ligated to a fragmentfrom pSAD L16 comprising the RV N and P genes to give rise topSK-NPMG. The final sequences of the full-length clones can beobtained from the authors by e-mail.

RNA analysis. Total RNA from cells was isolated 2 days after infection with the RNeasy minikit (Qiagen), and mRNA was enriched by usingthe Oligotex mRNA purification kit (Qiagen) according to the supplier'sinstructions. Agarose gel electrophoresis and Northern blottingwere performed as described previously (11). cDNA fragmentswere labeled with [ $alpha$ -³²P]dCTP (3,000 Ci/mmol; Amersham) by nick translation (nick translationkit; Amersham). Hybridization signals were quantitated by phosphorimaging(Storm; MolecularDynamics).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

IGRs modulate transcription restart. In contrast to the prototype rhabdovirus VSV, in which all IGRs usually consist of a conserved dinucleotide (31), the fourIGRs separating RV genes contain 2, 5, 5, and 24 nt (11, 39)(Fig. 1A). Both the different lengths and different nucleotidesequences might contribute to differential transcription attenuation.To analyze the effect of the different RV IGRs on transcriptionof mRNAs, we used the bicistronic model RNA SDI-CL(NP) (16).In SDI-CL(NP) the upstream chloramphenicol acetyltransferase (CAT)reporter gene and the downstream firefly luciferase gene are separatedby the RV N/P gene border sequence (Fig. 1A). By site-directedmutagenesis, the N/P IGR dinucleotide was exchanged with the 5-and 24-nt IGRs of the P/M, M/G, and G/L gene borders.

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FIG. 1. (A) Sequences of transcription signals and IGRs from the four RV gene borders and organization of the minigenome used for analysis of IGRs. Consensus sequences for stop/polyadenylation and transcription reinitiation are indicated in plus strand orientation. The bicistronic minigenome SDI-CL(NP) contains the full N/P gene border between the CAT and firefly luciferase reporter genes. The indicated N/P signal sequences were flanked upstream by 71 nt derived from the 3'-terminal part of the N gene. The 55-nt 5'-noncoding sequence (ncds) of the luciferase mRNA comprised 16 nt derived from the 5' ncds of the RV P mRNA, including the 9-nt start signal, followed by 39 nonviral nucleotides. SDI-CL(NP) was used to derive mutants in which the 2-nt IGR was replaced with the 5-, 5-, and 24-nt IGRs from other gene borders. (B) Transcription of indicated model genomes in cells coinfected with a helper RV. Poly(A)⁺ RNA was isolated 2 days postinfection and analyzed by Northern hybridization and phosphorimaging with CAT gene- and luciferase gene-specific probes. The locations of monocistronic mRNAs and bicistronic CAT/luciferase mRNA (CAT/luci) are indicated. The relative levels of downstream luciferase mRNA were calculated after normalizing with CAT mRNA and defining the SDI-CL(NP) luciferase mRNA level as 100%. Transcriptional readthrough is given as the percentage of bicistronic CAT/luciferase mRNA to CAT mRNA.

The resulting model RNAs were rescued from cDNA after transfection of cells by complementation with RV N, P, M, G, and L proteinsas described previously (34). Virus-like particles releasedinto the supernatants were transferred onto fresh BSR cell culturesafter 3 days. One hour later, cells were superinfected with RVSAD Ambi helper virus at a multiplicity of infection (MOI) of1. SAD Ambi is a recombinant ambisense gene expression RV thatpreferentially supports replication of SDI-like minigenome RNPs(15, 16). Two additional passages, each including superinfectionwith additional SAD Ambi helper virus at an MOI of 1, were performedin order to allow maximal minigenome amplification. Total RNAwas isolated from cells 2 days after the third passage, and polyadenylatedmRNA was enriched. After agarose gel electrophoresis and Northernblotting, poly(A)⁺ RNAs were analyzed by hybridization with CAT gene- and luciferasegene-specific DNA probes (Fig. 1B). Transcription from SDI-CL(NP),which comprises the authentic N/P gene border sequence, yieldedabundant amounts of monocistronic CAT and luciferase mRNA. Transcriptiontermination at the gene border was highly efficient, as only minorlevels of bicistronic CAT/luciferase readthrough mRNAs were presentin infected cells, amounting to 1.3% of monocistronic CAT mRNA.Reinitiation of luciferase mRNA transcription occurred efficiently.After replacement of the authentic N/P intergenic dinucleotidewith the IGR nucleotides of the P/M, M/G, and G/L gene borders,transcription of the upstream CAT gene remained comparable tothat of SDI-CL(NP). Only moderate increases of readthrough transcriptsto levels of 3.0, 2.8, and 2.4%, respectively, of monocistronicCAT mRNAs were observed. This indicated that the efficiency oftranscription termination was not markedly affected by exchangeof theIGRs.

An obvious effect, however, was obtained on reinitiation of transcription of the downstream luciferase gene. With the amountof luciferase mRNA from SDI-CL(NP)-infected cells defined as 100%,the amounts of luciferase mRNA in SDI-CL(igPM)- and SDI-CL(igMG)-infectedcells decreased to similar levels of 78 and 81%, respectively.In cells infected with SDI-CL(igGL) containing the 24-nt IGR,luciferase gene transcription dramatically decreased to 11% (Fig.1B). This is reminiscent of the steep gradient step that is observedat the RV G/L gene border. These data indicated that the lengthsof nontranscribed IGRs constitute an important factor in regulatingRV gene transcription and that the 24-nt G/L IGR is a criticalfactor in the downregulation of RV L genetranscription.

Exchange of gene borders in recombinant RV. To confirm that transcription of the RV RNA polymerase gene is attenuated by the 24-nt G/L IGR sequence, we constructed afull-length RV cDNA, pSAD T, in which the complete G/L gene borderof RV SAD L16 was replaced with a copy of the N/P gene bordersequence which had proved optimal in the minigenome transcriptionassay (Fig. 2A). On the basis of pSAD T another construct wasmade by replacing the 2-nt IGR from the new gene border with the24-nt G/L IGR nucleotides (pSAD TigGL). The resulting gene bordercorresponded to that of SDI-CL(igGL), which performed worst inthe minigenome assays. Both full-length cDNA constructs were successfullyrescued into viable recombinant virus. Virus stock solutions wereprepared after three passages following rescue as described previously(34). In the third passage, SAD T already reached a titer of4 × 10⁸ focus forming units (FFU) per ml of cell culture supernatant.In contrast, two independent clones of SAD TigGL yielded titersof only 10⁶ and 2.5 × 10⁶ FFU/ml, indicating a reduced ability to propagate. This was confirmedby infections at defined MOIs and analysis of growth curves (Fig.2C). Compared with the wt virus SAD L16, SAD TigGL was attenuatedin growth, and maximum virus yield remained below 10⁶ FFU/ml. To exclude the possibility that the poor growth of thetwo SAD TigGL isolates was due to incidental damages introducedinto the genome, revertants were generated by reexchanging theG/L IGR nucleotides. Both revertants were indistinguishable ingrowth and RNA synthesis from SAD T, confirming that the 24-ntIGR was responsible for the strikingly reduced L gene transcriptionand the extremely poor growth of SAD TigGL.

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FIG. 2. (A) Genome organization of wt RV (SAD L16) and recombinant viruses. In SAD T, 52 nt of the wt G/L gene border comprising the authentic signal sequences were replaced with 145 nt encoding the N/P gene border. The new 53-nt 5'-noncoding sequence (ncds) of the L mRNA consists of 16 nt derived from the 5' ncds of P mRNA, followed by 17 nonviral nucleotides and 20 nt from the authentic 30-nt L ncds. In SAD TigGL the N/P gene border copy was modified to contain the 24-nt IGR derived from the SAD L16 G/L gene border. Due to replacement of a 510-nt sequence comprising the complete pseudogene region $Psi$ and the 5' ncds of the L mRNA with a 145-nt sequence comprising the N stop and P start signals, in SAD T2 the entire 29-nt 5' noncoding region of the L gene is derived from the P gene. In addition, 152 nt of the M/G gene border were replaced with an additional copy of the N/P gene border, resulting in a 35-nt G mRNA 5' ncds consisting of 18 nt derived from the P mRNA 5' ncds followed by 11 nonviral nucleotides and 6 nt of the authentic G mRNA 5' ncds. (B) Detailed sequence of the novel G/L gene borders. Shaded boxes, nucleotides derived from the authentic G/L gene border; black boxes, nucleotides derived from the RV N/P gene border. All nonviral sequences are in lowercase. The L initiation codon is underlined. (C) Single-step growth curve of wt RV SAD L16, SAD T, and SAD TigGL. BSR cells were infected at an MOI of 1, and cell culture supernatants were collected at 12-h intervals. Infectious virus titers were determined as FFU by end point dilutions and titration on BSR cells. (D) Single-step growth curves of SAD L16, SAD T, and SAD T2. BSR cells were infected with viruses, and cell culture supernatants were collected at 12-h intervals. Infectious virus titers were determined as described for panel B.

Thus, the 24-nt IGR flanked by the N/P-derived transcription signals resulted in a considerable attenuation of virus growth,presumably by limiting L gene transcription. In contrast, SADT containing the authentic 2-nt N/P gene border with 2 IGR nucleotidesgrew faster than the parental SAD L16, presumably by enhancedL gene expression. Indeed, infectious titers of SAD T exceededthose of SAD L16 by factors of 3.3, 9.0, and 2.5 at 26, 38, and50 h postinfection, respectively. As the recombinant virus SADL16 corresponds to SAD B19, which is widely used as a live vaccineand which is very well adapted to optimal growth in BSR cell culture,the improved growth characteristics of SAD T werenotable.

To further enhance L expression, which was assumed to be responsible for the improved growth rate, additional recombinantRVs were generated. The introduction of the N/P gene border copyinto SAD T resulted in a chimeric L gene in which the transcriptionstart signal and a few nucleotides derived from the P gene werefused to L 5'-noncoding sequences (Fig. 2A and B). As the chimericgene border of SAD TigGL resulted in even slower growth than thewt G/L border, we constructed a virus in which the entire 5'-noncodingL sequence exactly matched the 29-nt 5'-noncoding region of theP gene (SAD TB; not shown). In this virus, part of the 3'-noncodingregion of the SAD L16 G mRNA, which is known as pseudogene $Psi$ ,was also deleted. This modification, however, was previously shownnot to have an effect on L gene transcription and virus growth(7, 26, 34). In addition, the M/G gene border of SAD TBwas replaced by a copy of the N/P gene border to give rise toSAD T2. The recombinant RVs SAD TB and SAD T2 (Fig. 2A) were recoveredfrom cDNA in a vaccinia virus-free T7 expression system (16)using cell line BSR T7/5, which constitutively expresses T7 RNApolymerase (6). No differences in growth characteristics betweenSAD TB and SAD T2 were observed, so only SAD T2 was used for furthercomparison with the previously rescued constructs. After infectionof BSR cells at an MOI of 1, SAD T2 titers were 12- and 14-foldhigher than those of SAD L16 and SAD T at 28 h postinfection,indicating very rapid replication of the virus (Fig. 2D). Maximumtiters of SAD T2 were reached at 52 h and exceeded those of SADT and SAD L16 by 1.8- and 4-fold,respectively.

RNA synthesis of recombinant viruses. To investigate whether the accelerated growth of SAD T and SAD T2 correlated with enhanced L transcription and L protein expression,BSR cells were infected with the recombinant viruses or SAD L16at an MOI of 1. RNA was isolated from infected cells 24 h postinfectionand analyzed by Northern hybridization with RV-specific DNA probes(Fig. 3). Hybridizations with an RV L gene-specific probe confirmedthat monocistronic L mRNA was most abundant in SAD T2-infectedcells, followed by SAD T-infected cells. Compared to results forSAD L16-infected cells, 5.1- and 1.8-fold increases, respectively,were determined by phosphorimaging. In contrast, the poorly growingSAD TigGL yielded fivefold-smaller amounts of L mRNA than SADL16. This strongly suggested that limiting amounts of polymeraseare indeed responsible for the observed attenuated phenotype ofSAD TigGL. Comparing SAD TigGL and SAD T, which differed exclusivelyin the G/L intergenic sequence, the L mRNA amount was ninefoldhigher in SAD T-infected cells than in SAD TigGL-infected cells.Thus, the 24-nt IGR in SAD TigGL alone caused strong attenuationof downstream L gene transcription.

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FIG. 3. RNA synthesis from recombinant RV. Total RNA from cells infected with the viruses indicated was analyzed 1 day postinfection by Northern hybridization with nick-translated DNA probes recognizing RV N, G, and L. The positions of mRNAs and full-length virus RNA (vRNA) are indicated. RNA was quantified by phosphorimaging, and relative values are given with respect to SAD L16 RNAs (1.0) at the bottom. Most important is the increase of L mRNA in SAD T and SAD T2 by factors of 1.8 and 5.1, respectively, and the decrease of L mRNA in SAD TigGL to 20% of SAD L16 levels, which is accompanied by augmented G/L readthrough. Reinitiation of L transcription was calculated as the ratio of L/G transcripts, defining SAD L16 reinitiation as 100%. Readthrough is given as the percentage of bicistronic G/L transcripts with respect to the sum of monocistronic G and bicistronic M/G transcripts. For details see the text.

Most of the effect was due to altered reinitiation of L transcription. We compared the amounts of monocistronic L mRNA tothe amounts of upstream G transcripts, including G mRNA and bicistronicM-plus-G RNA, and defined the L/G transcript ratio of SAD L16as 100%. Increased L reinitiations of 136 and 112% were determinedfor SAD T2 and SAD T, respectively. In contrast, a remarkablyreduced reinitiation of 24% was measured for SAD TigGL. Alteredreadthrough leading to bicistronic G-plus-L transcripts also slightlycontributed to the different L mRNA amounts. Compared to the 2.8%readthrough transcripts produced by SAD L16, reductions to 0.9and 1.6% were observed in SAD T and SAD T2, respectively. In contrast,an increased readthrough rate of 5.9% was determined for SAD TigGL(Fig. 3). Thus, replacement of the 2-nt IGR of SAD T with the24-nt IGR resulted in a 6.5-fold increase of readthrough transcriptionin SAD TigGL-infectedcells.

Not only L gene transcription but also general RNA synthesis was exaggerated in SAD T- and SAD T2-infected cells, as illustratedby RV G and N gene-specific hybridization experiments. MonocistronicN and G mRNA levels in SAD T2 were 2.2- and 3.6-fold higher, respectively,than those of SAD L16. Also, in SAD T-infected cells, a 1.4-foldincrease of G mRNA was observed. As could be expected, the smallamounts of L polymerase in SAD TigGL-infected cells led to reducedlevels of N and G mRNAs, each approaching 80% of SAD L16levels.

Protein synthesis from recombinant viruses. The higher transcript levels in SAD T- and SAD T2-infected cells resulted in larger amounts of virus proteins in infectedcells as determined by Western blot analyses. N and P proteinswere detected with a serum raised against RV ribonucleoproteincomplexes (Fig. 4). Calnexin, visualized by a monoclonal antibody,was used as an internal cellular marker protein. Both N- and P-specificsignals were more intense in SAD T- and SAD T2-infected cells,indicating that the additional mRNAs were being translated intoproteins. Interestingly, marked increases were observed only forthe small forms of N and P proteins, while the signals representingthe higher-molecular-weight forms were quite constant. The low-molecular-weightforms probably represent immature or N-terminally truncated virusproteins (8, 22), whereas the higher-molecular-weight formsrepresent the proteins which are incorporated into RNPs (unpublisheddata). The apparent bias toward increase of the shorter proteinsmay reflect slow processing or intracellular inactivation of theseforms, while mature proteins are rapidly assembled into RNPs andvirions and are thus rapidly exported into the supernatant.

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FIG. 4. Exaggerated protein expression from recombinant RV. Extracts from BSR cells infected with the indicated viruses at an MOI of 1 were analyzed 1 day postinfection by Western blotting. RV N and P proteins were visualized by using the polyclonal rabbit serum S50. Increasing amounts of N and P proteins are observed in SAD T- and SAD T2-infected cells, whereas protein expression of SAD TigL is reduced. Calnexin was used as a loading control. mock, noninfected cells.

Growth of SAD T and SAD T2 induces CPE. The general increase of RNA synthesis and protein expression in SAD T and SAD T2 not only resulted in higher virus titersbut also had obvious effects on the infected cells. In contrastto SAD L16, which grows in BSR cell culture without exhibitingobvious cytopathic effects (CPE), SAD T and SAD T2 induced a strongCPE (Fig. 5). Three days after infection with SAD T2 at an MOIof 1 the cell monolayer was widely destroyed and large syncytiaand cell aggregates were predominant. Interestingly, SAD T, witha less vigorous gene expression than SAD T2, caused less damagebut still was clearly more cytopathic than SAD L16. Thus, thegrade of CPE appears to directly correlate with the level of virusgene expression. As indicated by terminal deoxynucleotidyltransferase-mediateddUTP-biotin nick end labeling assays (ApopTaq; Intergen), inductionof apoptosis in BSR cells was not involved.

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FIG. 5. Induction of CPE by recombinant RVs. Monolayers of BSR cells were infected with wt RV (SAD L16) and recombinant viruses SAD T and SAD T2 at an MOI of 1. Three days postinfection cells were analyzed by phase-contrast microscopy. The severity of CPE was roughly correlated with the enhancement of gene expression.

Pathogenicity of SAD T2 and SAD L16 in mice. Notably, in spite of heavily damaging cells, both SAD T and SAD T2 yielded higher virus titers than SAD L16 during the courseof infection of the cell culture. Under the assumption that levelsof gene expression, speed of replication, and quantity of virionproduction are important for virus evolution in cell culture,the wt SAD L16 is obviously a suboptimal virus. To investigatethe behavior of the recombinant viruses in vivo, 3 × 10⁴ FFU of SAD L16, SAD T, or SAD T2 were injected in the footpadsof 3-week-old CD-1 mice. After 10 and 11 days two of five miceinoculated with SAD T2 showed paralysis of both hindlimbs. Incontrast, SAD L16- and SAD T-infected mice exhibited no clinicalsigns even 6 weeks after inoculation. Mice with clinical symptomswere killed, and brain material was screened for the presenceof virus; from both mouse brains virus could be isolated, indicatingthat the virus reached the central nervous system. In a secondexperiment, a higher virus dose of 1.2 × 10⁶ FFU/mouse was used to inoculate footpads of 3-week old CD-1 mice.Again, two of five mice inoculated with SAD T2 showed paralysisof hindlimbs at days 7 and 9. In both cases, virus isolation frombrains at day 9 after inoculation was positive. In contrast, allfive mice inoculated with SAD L16 showed nosymptoms.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Sequential synthesis of mRNAs according to the stop/start mechanism is a common feature of all nonsegmented negative-strandRNA viruses and provides a unique, efficient, and simple mechanismto differentially express individual genes from a contiguous virusgenome. The major determinant of gene expression is the relativedistance of a gene from the single 3'-terminal promoter (40).The second determinant is the steepness of the transcript gradient,which is a result of attenuation at gene borders. Some viruses,such as members of the Paramyxovirinae subfamily and the rhabdovirusVSV, have nearly identical gene borders suggesting rather eventranscript gradients. The gene borders in others, however, mayvary considerably, for example, in pneumoviruses, such as humanrespiratory syncytial virus (HSRV) and bovine respiratory syncytialvirus, in paramyxoviruses such as simian virus 5 (SV5), and inthe rhabdovirus RV. Obviously, variable gene borders can providemeans for a more refined regulation of gene expression. We showhere that the different RV IGRs profoundly differ in supportingtranscription reinitiation. By manipulating gene borders, thebalanced expression of the five virus proteins could be alteredand novel viruses with distinct phenotypes were generated. Mostremarkably, it was possible to create viruses superior to parentalviruses in terms of growth kinetics and virusyield.

As demonstrated by reporter gene RNA assays, the RV IGRs have a considerable effect on the synthesis of downstream gene transcripts.Compared to the N/P intergenic dinucleotide, the 5-, 5-, and 24-ntintergenic nucleotides from the P/M, M/G, and G/L gene borders,respectively, caused a decrease of downstream luciferase geneexpression. Although a slight increase in readthrough transcriptswas observed, this was due not to a failure of the polymerasein correct termination of the upstream CAT gene mRNA but ratherto a failure in recognizing the downstream transcription initiationsignal. The synthesis of downstream RNAs was reduced to levelsof 78, 81, and 11% of that obtained with the N/P intergenic dinucleotide.These values appear to directly correlate with increasing lengthof the IGRs of 5, 5, and 24 nt, respectively. The similar reinitiationrates of the P/M and M/G IGRs, which only differ in nucleotidesequence, indicated that the major regulatory factor in RV transcriptionattenuation is the lengths of the IGRs, i.e., the distance fromthe stop/polyadenylation signal to the restart signal. However,at this point we are not excluding a minor influence of the specificsequence of the 5-nt RV IGRs on polymeraseactivities.

The function of the IGR as a necessary spacer between the stop and the restart signals is emphasized by the previous findingthat gene borders lacking any intergenic nucleotide result inabrogation of reinitiation, whereas termination occurs quite efficiently,both in RV and in VSV (5, 15). In both systems reinitiationis only partially restored when a single nucleotide is introducedbetween the A stretch of the polyadenylation signal and the consensusrestart signal (5, 36). Thus, the length of the RV IGR isa major determinant in transcription attenuation, and a lengthof 2 nt, as found in the N/P gene border, appears to be optimal.This can also be concluded from studies of VSV minigenomes. Afterelongation of the VSV consensus IGR dinucleotide up to 21 nt,a decrease in reinitiation was observed, partially due to abortiveattempts of reinitiation at inappropriate sequences within thelong IGR (37, 38). In addition, the identity of added nucleotideshad some effect on reinitiation efficiency, although no obvioussequence pattern could be correlated (4, 37). In contrastto these observations with rhabdoviruses, a less important rolefor the IGR length is suggested for several paramyxoviruses. IGRsof HRSV of the Pneumovirinae subfamily are highly variable inlength but did not differ in reinitiation of transcription inan artificial minigenome assay (23). Also, in the rubulavirusSV5 the lengths of IGRs alone did not correlate with attenuation(19).

As anticipated from the weak downstream transcription in the RV minigenome, the 24-nt G/L IGR of the wt RV SAD L16 shouldbe responsible for attenuating transcription of the L gene ininfected cells. To address this hypothesis and to see whetherRVs that overexpress L can be generated, we exchanged the G/Lgene border with the N/P gene border, which caused the least attenuationin the reporter gene RNA assays. Indeed, SAD T and SAD T2 producedmore translatable L mRNA than wt virus SAD L16. This resultedin a general increase of RNA synthesis and virus protein expression.More surprisingly, the recombinant viruses grew faster and yieldedhigher infectious titers than the parental SAD L16, although thelatter is considered to be very well adapted to growth in BSRcellcultures.

Exaggerated L mRNA transcription, polymerase expression, and gain of fitness were already observed for SAD T. As SAD T andSAD TigGL differ only in having 2 and 24 IGR nucleotides, respectively,the long 24-nt IGR is the crucial factor in the observed ninefolddifference in L mRNA transcription. However, L mRNA levels forSAD L16, which also has a 24-nt IGR, were fivefold higher thanthose for SAD TigGL. Obviously, the combination of N/P transcriptionsignals and the G/L intergenic sequence is less efficient thanthe authentic G/L gene border, both in reinitiation (24% of SADL16 level) and in termination (twofold-increased readthrough).Apparently, the individual nontranscribed RV IGR has to fit somehowinto its sequence environment for optimal function. This was alsoreported to apply in other viruses, such as HRSV (18), VSV (37),and SV5 (30).

These considerations were taken into account in the design of SAD T2, in which the remainder of the L-derived 5'-nontranslatedsequence of SAD T was replaced with the corresponding sequenceof the P gene. In addition, the M/G gene border sequence was exchangedwith the N/P gene border fragment to enhance G gene transcriptionand thereby also transcription of the downstream L gene. The deletionof the G pseudogene sequence was not considered important in thisrespect, as it was previously shown that it has no detectableeffect on transcription and growth of SAD L16 (7, 26, 34).

Indeed, the modifications introduced in SAD T2 resulted in a further-improved virus growth and an overall increase of RNAsynthesis. A marked upregulation of G mRNA transcription by theN/P gene border introduced upstream of the G gene could not bedemonstrated. Moreover, a recombinant RV that was identical withSAD T2 but that contained the wt M/G gene border sequence showednearly the same growth characteristics and mRNA levels as SADT2 (not shown). Thus, we conclude that the higher gene expressionfrom SAD T2 than from SAD T is caused mainly by the P gene-derived5'-noncoding region. Indeed, compared to the situation in SADT, 2.8-fold-higher levels of L mRNA were present in SAD T2. Assumingequal stability of the L mRNAs, the reinitiation rate for theSAD T2 G/L gene border was increased by 24%.

The RV N/P gene border fragment promoted highly efficient synthesis of a downstream gene in the reporter minigenome system.It does so also in the context of full-length RV vectors, whereit has been repeatedly used to express additional genes introduceddownstream of G (7, 26) (unpublished experiments). In allthese cases with different sequence environments the downstreamgene mRNA levels were not much reduced compared to the upstreamG mRNA levels. As found here with the L gene, the N/P gene borderwas also able to enhance L mRNA synthesis, but not nearly to theapproximately 10-fold-higher levels that could be expected fromexperiments with the minigenomes or with the expression of foreigngenes from RV vectors. This indicates that, besides downregulationof transcription reinitiation, other mechanisms are active inkeeping L expression low, such as the slow processivity of thepolymerase on the L gene template or the short half-life of LmRNA. Studies on recombinant SV5 showed also that L mRNA upregulationwas very limited, and the authors also argue in favor of othermechanisms being involved (19).

Attenuation of L gene expression seems to be a common feature of many nonsegmented negative-strand RNA viruses. A strikingway to achieve L downregulation has been identified in respiratorysyncytial virus: the M2 and L genes overlap such that the M2 stop/polyadenylationsignal is located downstream of the L start signal (9). A longnonconserved G/L IGR of more than 20 nt is a common feature ofall RV isolates and also of more distantly related Lyssavirusserotypes, such as Mokola and Lagos Bat viruses (25). In cellculture-adapted RV strains ERA and PV additional stop/polyadenylationsignal-like sequences within the long G 3'-noncoding sequence,which direct the termination of approximately 50% of G transcripts,have been identified (12, 27, 39). It can be concluded thatpolymerases terminating at this site are not able to reinitiateat the L transcription restart signal which is located approximately400 nt downstream, leading to further reduction of L mRNA. Expressionexperiments with VSV and analysis of recombinant SV5 have indicatedthat overexpression of L polymerase inhibits virus replication(28, 35). In contrast, and similar to our results, increasedexpression of downstream genes after modification of the Sendaivirus M/F gene border resulted in faster replication in cell culture(21).

An explanation for maintenance of L gene downregulation in RV strains well adapted to cell culture, such as SAD, is not closeat hand, since mutated viruses expressing more L have clear advantagesin cell culture. However, L attenuation in street viruses mayoffer a considerable advantage. In contrast to the parental virus,SAD L16, the recombinant viruses SAD T and SAD T2 showed CPE increasingwith the level of gene expression and replication. It is unlikelythat a pronounced CPE is an advantage for RV dissemination inthe field, although virus replication is faster and yields highervirus titers. Mouse footpad injection experiments showed thatSAD T2 is able to cause symptoms in 40% of injected mice, whileSAD L16 is not. SAD T2 virus could be isolated from brains ofthese animals. Thus, although overexpression of virus antigensand cytopathogenicity might provoke a more pronounced immune reaction,the virus was able to reach the central nervous system. Fastergrowth and the induction of a CPE in a pathogenic street viruscould therefore result in a very rapid course of disease and killingof the animal prior to virus transmission to a new host. Thismay also apply to Sendai virus, as overexpressing recombinantswere found more pathogenic for mice than standard virus (21).

In the past, the function of RV gene borders in transcription regulation was only deduced from sequence comparisons. The availabilityof recombinant RV with upregulated gene expression provided evidencethat, beside the prime factor of transcription regulation, namely,the well-conserved gene order, a second factor, namely, the well-conservedgene order, a second factor, namely, the attenuation by specificgene border sequences, considerably contributes to regulationof RV gene expression. With regard to our special interest inthe development of RV vectors for gene delivery, the possibilityto increase virus gene expression by upregulating L gene transcriptionoffers the opportunity to create novel virus vectors which areoptimized for high gene expression and virus production. In particular,upregulated L gene transcription may compensate for attenuatingeffects caused by insertion of multiple foreign cistrons intothe virus genome. It was previously shown that the coding capacityof RV vectors can be increased by using ambisense RV or preferentiallyreplicating model genomes similar to defective interfering particles(15, 16). Overexpression of the viral polymerase offers anadditional way to create optimized high-capacity rhabdovirusvectors.

	ACKNOWLEDGMENT

This work was supported by the Deutsche Forschungsgemeinschaft (SFB 455-A3).

	FOOTNOTES

^* Corresponding author. Mailing address: Max von Pettenkofer Institute and Gene Center, Feodor-Lynen-Str. 25, D-81377 Munich,Germany. Phone: 49 89 2180 6851. Fax: 49 89 2180 6899. E-mail:conzelma{at}lmb.uni-muenchen.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Abraham, G., and A. K. Banerjee. 1976. Sequential transcription of the genes of vesicular stomatitis virus. Proc. Natl. Acad. Sci. USA 73:1504-1508[Abstract/Free Full Text].

2. Ball, L. A., and C. N. White. 1976. Order of transcription of genes of vesicular stomatitis virus. Proc. Natl. Acad. Sci. USA 73:442-446[Abstract/Free Full Text].

3. Banerjee, A. K. 1987. Transcription and replication of rhabdoviruses. Microbiol. Rev. 51:66-87[Free Full Text]. (Erratum, 51:299.)

4. Barr, J. N., S. P. Whelan, and G. W. Wertz. 1997. cis-Acting signals involved in termination of vesicular stomatitis virus mRNA synthesis include the conserved AUAC and the U7 signal for polyadenylation. J. Virol. 71:8718-8725[Abstract].

5. Barr, J. N., S. P. Whelan, and G. W. Wertz. 1997. Role of the intergenic dinucleotide in vesicular stomatitis virus RNA transcription. J. Virol. 71:1794-1801[Abstract].

6. Buchholz, U. J., S. Finke, and K. K. Conzelmann. 1999. Generation of bovine respiratory syncytial virus (BRSV) from cDNA: BRSV NS2 is not essential for virus replication in tissue culture, and the human RSV leader region acts as a functional BRSV genome promoter. J. Virol. 73:251-259[Abstract/Free Full Text].

7. Ceccaldi, P. E., J. Fayet, K. K. Conzelmann, and H. Tsiang. 1998. Infection characteristics of rabies virus variants with deletion or insertion in the pseudogene sequence. J. Neurovirol. 4:115-119[Medline].

8. Chenik, M., K. Chebli, and D. Blondel. 1995. Translation initiation at alternate in-frame AUG codons in the rabies virus phosphoprotein mRNA is mediated by a ribosomal leaky scanning mechanism. J. Virol. 69:707-712[Abstract].

9. Collins, P. L., R. A. Olmsted, M. K. Spriggs, P. R. Johnson, and A. J. Buckler-White. 1987. Gene overlap and site-specific attenuation of transcription of the viral polymerase L gene of human respiratory syncytial virus. Proc. Natl. Acad. Sci. USA 84:5134-5138[Abstract/Free Full Text].

10. Conzelmann, K. K. 1998. Nonsegmented negative-strand RNA viruses: genetics and manipulation of viral genomes. Annu. Rev. Genet. 32:123-162[CrossRef][Medline].

11. Conzelmann, K. K., J. H. Cox, L. G. Schneider, and H. J. Thiel. 1990. Molecular cloning and complete nucleotide sequence of the attenuated rabies virus SAD B19. Virology 175:485-499[CrossRef][Medline].

12. Conzelmann, K. K., J. H. Cox, and H. J. Thiel. 1991. An L (polymerase)-deficient rabies virus defective interfering particle RNA is replicated and transcribed by heterologous helper virus L proteins. Virology 184:655-663[CrossRef][Medline].

13. Conzelmann, K. K., and M. Schnell. 1994. Rescue of synthetic genomic RNA analogs of rabies virus by plasmid-encoded proteins. J. Virol. 68:713-719[Abstract/Free Full Text].

14. Emerson, S. U. 1982. Reconstitution studies detect a single polymerase entry site on the vesicular stomatitis virus genome. Cell 31:635-642[CrossRef][Medline].

15. Finke, S., and K. K. Conzelmann. 1997. Ambisense gene expression from recombinant rabies virus: random packaging of positive- and negative-strand ribonucleoprotein complexes into rabies virions. J. Virol. 71:7281-7288[Abstract].

16. Finke, S., and K. K. Conzelmann. 1999. Virus promoters determine interference by defective RNAs: selective amplification of mini-RNA vectors and rescue from cDNA by a 3' copy-back ambisense rabies virus. J. Virol. 73:3818-3825[Abstract/Free Full Text].

17. Fuerst, T. R., E. G. Niles, F. W. Studier, and B. Moss. 1986. Eukaryotic transient-expression system based on recombinant vaccinia virus that synthesizes bacteriophage T7 RNA polymerase. Proc. Natl. Acad. Sci. USA 83:8122-8126[Abstract/Free Full Text].

18. Hardy, R. W., S. B. Harmon, and G. W. Wertz. 1999. Diverse gene junctions of respiratory syncytial virus modulate the efficiency of transcription termination and respond differently to M2-mediated antitermination. J. Virol. 73:170-176[Abstract/Free Full Text].

19. He, B., and R. A. Lamb. 1999. Effect of inserting paramyxovirus simian virus 5 gene junctions at the HN/L gene junction: analysis of accumulation of mRNAs transcribed from rescued viable viruses. J. Virol. 73:6228-6234[Abstract/Free Full Text].

20. Iverson, L. E., and J. K. Rose. 1981. Localized attenuation and discontinuous synthesis during vesicular stomatitis virus transcription. Cell 23:477-484[CrossRef][Medline].

21. Kato, A., K. Kiyotani, M. K. Hasan, T. Shioda, Y. Sakai, T. Yoshida, and Y. Nagai. 1999. Sendai virus gene start signals are not equivalent in reinitiation capacity: moderation at the fusion protein gene. J. Virol. 73:9237-9246[Abstract/Free Full Text].

22. Kawai, A., H. Toriumi, T. S. Tochikura, T. Takahashi, Y. Honda, and K. Morimoto. 1999. Nucleocapsid formation and/or subsequent conformational change of rabies virus nucleoprotein (N) is a prerequisite step for acquiring the phosphatase-sensitive epitope of monoclonal antibody 5-2-26. Virology 263:395-407[CrossRef][Medline].

23. Kuo, L., R. Fearns, and P. L. Collins. 1996. The structurally diverse intergenic regions of respiratory syncytial virus do not modulate sequential transcription by a dicistronic minigenome. J. Virol. 70:6143-6150[Abstract].

24. Kuo, L., H. Grosfeld, J. Cristina, M. G. Hill, and P. L. Collins. 1996. Effects of mutations in the gene-start and gene-end sequence motifs on transcription of monocistronic and dicistronic minigenomes of respiratory syncytial virus. J. Virol. 70:6892-6901[Abstract/Free Full Text].

25. Mebatsion, T., J. H. Cox, and K.-K. Conzelmann. 1993. Molecular analysis of rabies related viruses from Ethiopia. Onderstepoort J. Vet. Res. 60:289-294[Medline].

26. Mebatsion, T., M. J. Schnell, J. H. Cox, S. Finke, and K. K. Conzelmann. 1996. Highly stable expression of a foreign gene from rabies virus vectors. Proc. Natl. Acad. Sci. USA 93:7310-7314[Abstract/Free Full Text].

27. Morimoto, K., A. Ohkubo, and A. Kawai. 1989. Structure and transcription of the glycoprotein gene of attenuated HEP-Flury strain of rabies virus. Virology 173:465-477[CrossRef][Medline].

28. Pattnaik, A. K., and G. W. Wertz. 1990. Replication and amplification of defective interfering particle RNAs of vesicular stomatitis virus in cells expressing viral proteins from vectors containing cloned cDNAs. J. Virol. 64:2948-2957[Abstract/Free Full Text].

29. Pringle, C. R., and A. J. Easton. 1997. Monopartite negative strand RNA genomes. Semin. Virol. 8:49-57.

30. Rassa, J. C., and G. D. Parks. 1999. Highly diverse intergenic regions of the paramyxovirus simian virus 5 cooperate with the gene end U tract in viral transcription termination and can influence reinitiation at a downstream gene. J. Virol. 73:3904-3912[Abstract/Free Full Text].

31. Rose, J. K. 1980. Complete intergenic and flanking gene sequences from the genome of vesicular stomatitis virus. Cell 19:415-421[CrossRef][Medline].

32. Schnell, M. J., L. Buonocore, M. A. Whitt, and J. K. Rose. 1996. The minimal conserved transcription stop-start signal promotes stable expression of a foreign gene in vesicular stomatitis virus. J. Virol. 70:2318-2323[Abstract].

33. Schnell, M. J., and K. K. Conzelmann. 1995. Polymerase activity of in vitro mutated rabies virus L protein. Virology 214:522-530[CrossRef][Medline].

34. Schnell, M. J., T. Mebatsion, and K. K. Conzelmann. 1994. Infectious rabies viruses from cloned cDNA. EMBO J. 13:4195-4203[Medline].

35. Schubert, M., G. G. Harmison, C. D. Richardson, and E. Meier. 1985. Expression of a cDNA encoding a functional 241-kilodalton vesicular stomatitis virus RNA polymerase. Proc. Natl. Acad. Sci. USA 82:7984-7988[Abstract/Free Full Text].

36. Stillman, E. A., and M. A. Whitt. 1997. Mutational analyses of the intergenic dinucleotide and the transcriptional start sequence of vesicular stomatitis virus (VSV) define sequences required for efficient termination and initiation of VSV transcripts. J. Virol. 71:2127-2137[Abstract].

37. Stillman, E. A., and M. A. Whitt. 1998. The length and sequence composition of vesicular stomatitis virus intergenic regions affect mRNA levels and the site of transcript initiation. J. Virol. 72:5565-5572[Abstract/Free Full Text].

38. Stillman, E. A., and M. A. Whitt. 1999. Transcript initiation and 5'-end modifications are separable events during vesicular stomatitis virus transcription. J. Virol. 73:7199-7209[Abstract/Free Full Text].

39. Tordo, N., O. Poch, A. Ermine, G. Keith, and F. Rougeon. 1986. Walking along the rabies genome: is the large G-L intergenic region a remnant gene? Proc. Natl. Acad. Sci. USA 83:3914-3918[Abstract/Free Full Text].

40. Wertz, G. W., V. P. Perepelitsa, and L. A. Ball. 1998. Gene rearrangement attenuates expression and lethality of a nonsegmented negative strand RNA virus. Proc. Natl. Acad. Sci. USA 95:3501-3506[Abstract/Free Full Text].

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1.	Abraham, G., and A. K. Banerjee. 1976. Sequential transcription of the genes of vesicular stomatitis virus. Proc. Natl. Acad. Sci. USA 73:1504-1508[Abstract/Free Full Text].
2.	Ball, L. A., and C. N. White. 1976. Order of transcription of genes of vesicular stomatitis virus. Proc. Natl. Acad. Sci. USA 73:442-446[Abstract/Free Full Text].
3.	Banerjee, A. K. 1987. Transcription and replication of rhabdoviruses. Microbiol. Rev. 51:66-87[Free Full Text]. (Erratum, 51:299.)
4.	Barr, J. N., S. P. Whelan, and G. W. Wertz. 1997. cis-Acting signals involved in termination of vesicular stomatitis virus mRNA synthesis include the conserved AUAC and the U7 signal for polyadenylation. J. Virol. 71:8718-8725[Abstract].
5.	Barr, J. N., S. P. Whelan, and G. W. Wertz. 1997. Role of the intergenic dinucleotide in vesicular stomatitis virus RNA transcription. J. Virol. 71:1794-1801[Abstract].
6.	Buchholz, U. J., S. Finke, and K. K. Conzelmann. 1999. Generation of bovine respiratory syncytial virus (BRSV) from cDNA: BRSV NS2 is not essential for virus replication in tissue culture, and the human RSV leader region acts as a functional BRSV genome promoter. J. Virol. 73:251-259[Abstract/Free Full Text].
7.	Ceccaldi, P. E., J. Fayet, K. K. Conzelmann, and H. Tsiang. 1998. Infection characteristics of rabies virus variants with deletion or insertion in the pseudogene sequence. J. Neurovirol. 4:115-119[Medline].
8.	Chenik, M., K. Chebli, and D. Blondel. 1995. Translation initiation at alternate in-frame AUG codons in the rabies virus phosphoprotein mRNA is mediated by a ribosomal leaky scanning mechanism. J. Virol. 69:707-712[Abstract].
9.	Collins, P. L., R. A. Olmsted, M. K. Spriggs, P. R. Johnson, and A. J. Buckler-White. 1987. Gene overlap and site-specific attenuation of transcription of the viral polymerase L gene of human respiratory syncytial virus. Proc. Natl. Acad. Sci. USA 84:5134-5138[Abstract/Free Full Text].
10.	Conzelmann, K. K. 1998. Nonsegmented negative-strand RNA viruses: genetics and manipulation of viral genomes. Annu. Rev. Genet. 32:123-162[CrossRef][Medline].
11.	Conzelmann, K. K., J. H. Cox, L. G. Schneider, and H. J. Thiel. 1990. Molecular cloning and complete nucleotide sequence of the attenuated rabies virus SAD B19. Virology 175:485-499[CrossRef][Medline].
12.	Conzelmann, K. K., J. H. Cox, and H. J. Thiel. 1991. An L (polymerase)-deficient rabies virus defective interfering particle RNA is replicated and transcribed by heterologous helper virus L proteins. Virology 184:655-663[CrossRef][Medline].
13.	Conzelmann, K. K., and M. Schnell. 1994. Rescue of synthetic genomic RNA analogs of rabies virus by plasmid-encoded proteins. J. Virol. 68:713-719[Abstract/Free Full Text].
14.	Emerson, S. U. 1982. Reconstitution studies detect a single polymerase entry site on the vesicular stomatitis virus genome. Cell 31:635-642[CrossRef][Medline].
15.	Finke, S., and K. K. Conzelmann. 1997. Ambisense gene expression from recombinant rabies virus: random packaging of positive- and negative-strand ribonucleoprotein complexes into rabies virions. J. Virol. 71:7281-7288[Abstract].
16.	Finke, S., and K. K. Conzelmann. 1999. Virus promoters determine interference by defective RNAs: selective amplification of mini-RNA vectors and rescue from cDNA by a 3' copy-back ambisense rabies virus. J. Virol. 73:3818-3825[Abstract/Free Full Text].
17.	Fuerst, T. R., E. G. Niles, F. W. Studier, and B. Moss. 1986. Eukaryotic transient-expression system based on recombinant vaccinia virus that synthesizes bacteriophage T7 RNA polymerase. Proc. Natl. Acad. Sci. USA 83:8122-8126[Abstract/Free Full Text].
18.	Hardy, R. W., S. B. Harmon, and G. W. Wertz. 1999. Diverse gene junctions of respiratory syncytial virus modulate the efficiency of transcription termination and respond differently to M2-mediated antitermination. J. Virol. 73:170-176[Abstract/Free Full Text].
19.	He, B., and R. A. Lamb. 1999. Effect of inserting paramyxovirus simian virus 5 gene junctions at the HN/L gene junction: analysis of accumulation of mRNAs transcribed from rescued viable viruses. J. Virol. 73:6228-6234[Abstract/Free Full Text].
20.	Iverson, L. E., and J. K. Rose. 1981. Localized attenuation and discontinuous synthesis during vesicular stomatitis virus transcription. Cell 23:477-484[CrossRef][Medline].
21.	Kato, A., K. Kiyotani, M. K. Hasan, T. Shioda, Y. Sakai, T. Yoshida, and Y. Nagai. 1999. Sendai virus gene start signals are not equivalent in reinitiation capacity: moderation at the fusion protein gene. J. Virol. 73:9237-9246[Abstract/Free Full Text].
22.	Kawai, A., H. Toriumi, T. S. Tochikura, T. Takahashi, Y. Honda, and K. Morimoto. 1999. Nucleocapsid formation and/or subsequent conformational change of rabies virus nucleoprotein (N) is a prerequisite step for acquiring the phosphatase-sensitive epitope of monoclonal antibody 5-2-26. Virology 263:395-407[CrossRef][Medline].
23.	Kuo, L., R. Fearns, and P. L. Collins. 1996. The structurally diverse intergenic regions of respiratory syncytial virus do not modulate sequential transcription by a dicistronic minigenome. J. Virol. 70:6143-6150[Abstract].
24.	Kuo, L., H. Grosfeld, J. Cristina, M. G. Hill, and P. L. Collins. 1996. Effects of mutations in the gene-start and gene-end sequence motifs on transcription of monocistronic and dicistronic minigenomes of respiratory syncytial virus. J. Virol. 70:6892-6901[Abstract/Free Full Text].
25.	Mebatsion, T., J. H. Cox, and K.-K. Conzelmann. 1993. Molecular analysis of rabies related viruses from Ethiopia. Onderstepoort J. Vet. Res. 60:289-294[Medline].
26.	Mebatsion, T., M. J. Schnell, J. H. Cox, S. Finke, and K. K. Conzelmann. 1996. Highly stable expression of a foreign gene from rabies virus vectors. Proc. Natl. Acad. Sci. USA 93:7310-7314[Abstract/Free Full Text].
27.	Morimoto, K., A. Ohkubo, and A. Kawai. 1989. Structure and transcription of the glycoprotein gene of attenuated HEP-Flury strain of rabies virus. Virology 173:465-477[CrossRef][Medline].
28.	Pattnaik, A. K., and G. W. Wertz. 1990. Replication and amplification of defective interfering particle RNAs of vesicular stomatitis virus in cells expressing viral proteins from vectors containing cloned cDNAs. J. Virol. 64:2948-2957[Abstract/Free Full Text].
29.	Pringle, C. R., and A. J. Easton. 1997. Monopartite negative strand RNA genomes. Semin. Virol. 8:49-57.
30.	Rassa, J. C., and G. D. Parks. 1999. Highly diverse intergenic regions of the paramyxovirus simian virus 5 cooperate with the gene end U tract in viral transcription termination and can influence reinitiation at a downstream gene. J. Virol. 73:3904-3912[Abstract/Free Full Text].
31.	Rose, J. K. 1980. Complete intergenic and flanking gene sequences from the genome of vesicular stomatitis virus. Cell 19:415-421[CrossRef][Medline].
32.	Schnell, M. J., L. Buonocore, M. A. Whitt, and J. K. Rose. 1996. The minimal conserved transcription stop-start signal promotes stable expression of a foreign gene in vesicular stomatitis virus. J. Virol. 70:2318-2323[Abstract].
33.	Schnell, M. J., and K. K. Conzelmann. 1995. Polymerase activity of in vitro mutated rabies virus L protein. Virology 214:522-530[CrossRef][Medline].
34.	Schnell, M. J., T. Mebatsion, and K. K. Conzelmann. 1994. Infectious rabies viruses from cloned cDNA. EMBO J. 13:4195-4203[Medline].
35.	Schubert, M., G. G. Harmison, C. D. Richardson, and E. Meier. 1985. Expression of a cDNA encoding a functional 241-kilodalton vesicular stomatitis virus RNA polymerase. Proc. Natl. Acad. Sci. USA 82:7984-7988[Abstract/Free Full Text].
36.	Stillman, E. A., and M. A. Whitt. 1997. Mutational analyses of the intergenic dinucleotide and the transcriptional start sequence of vesicular stomatitis virus (VSV) define sequences required for efficient termination and initiation of VSV transcripts. J. Virol. 71:2127-2137[Abstract].
37.	Stillman, E. A., and M. A. Whitt. 1998. The length and sequence composition of vesicular stomatitis virus intergenic regions affect mRNA levels and the site of transcript initiation. J. Virol. 72:5565-5572[Abstract/Free Full Text].
38.	Stillman, E. A., and M. A. Whitt. 1999. Transcript initiation and 5'-end modifications are separable events during vesicular stomatitis virus transcription. J. Virol. 73:7199-7209[Abstract/Free Full Text].
39.	Tordo, N., O. Poch, A. Ermine, G. Keith, and F. Rougeon. 1986. Walking along the rabies genome: is the large G-L intergenic region a remnant gene? Proc. Natl. Acad. Sci. USA 83:3914-3918[Abstract/Free Full Text].
40.	Wertz, G. W., V. P. Perepelitsa, and L. A. Ball. 1998. Gene rearrangement attenuates expression and lethality of a nonsegmented negative strand RNA virus. Proc. Natl. Acad. Sci. USA 95:3501-3506[Abstract/Free Full Text].