Expression of the Totivirus Helminthosporium victoriae 190S Virus RNA-Dependent RNA Polymerase from Its Downstream Open Reading Frame in Dicistronic Constructs

doi:10.1128/JVI.74.2.997-1003.2000

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Soldevila, A. I.
	Articles by Ghabrial, S. A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Soldevila, A. I.
	Articles by Ghabrial, S. A.

Previous Article | Next Article

Journal of Virology, January 2000, p. 997-1003, Vol. 74, No. 2
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Expression of the Totivirus Helminthosporium victoriae 190S Virus RNA-Dependent RNA Polymerase from Its Downstream Open Reading Frame in Dicistronic Constructs

Ana I. Soldevila and Said A. Ghabrial^*

Department of Plant Pathology, University of Kentucky, Lexington, Kentucky 40546

Received 7 July 1999/Accepted 4 October 1999

	ABSTRACT

Top Abstract Text References

The undivided double-stranded RNA (dsRNA) genome of Helminthosporium victoriae 190S virus (Hv190SV) (genus Totivirus) consistsof two large overlapping open reading frames (ORFs). The 5'-proximalORF encodes a capsid protein (CP), and the downstream, 3'-proximalORF encodes an RNA-dependent RNA polymerase (RDRP). Unlike theRDRPs of some other totiviruses, which are expressed as a CP-RDRP(Gag-Pol-like) fusion protein, the Hv190SV RDRP is detected onlyas a separate, nonfused polypeptide. In this study, we examinedthe expression of the RDRP ORF fused in frame to the coding sequenceof the green fluorescent protein (GFP) in bacteria and Schizosaccharomycespombe cells. The GFP fusions were readily detected in bacteriatransformed with the monocistronic construct RDRP:GFP; expressionof the downstream RDRP:GFP from the dicistronic construct CP-RDRP:GFPcould not be detected. However, fluorescence microscopy and Westernblot analysis indicated that RDRP:GFP was expressed at low levelsfrom its downstream ORF in the dicistronic construct in S. pombecells. No evidence that the RDRP ORF was expressed from a transcriptshorter than the full-length dicistronic mRNA was found. A coupledtermination-reinitiation mechanism that requires host or eukaryoticcell factors is proposed for the expression of Hv190SVRDRP.

	TEXT

Top Abstract Text References

Helminthosporium victoriae 190S virus (Hv190SV) belongs to the genus Totivirus in the family Totiviridae. Members of the familyTotiviridae have undivided double-stranded RNA (dsRNA) genomespackaged in isometric particles 40 to 50 nm in diameter (7).Hv190SV infects the phytopathogenic fungus Helminthosporium victoriae,the causal agent of Victoria blight of oats. The virus and itsassociated satellite dsRNAs have been implicated in a debilitatingdisease of its fungal host (5). Purified Hv190SV virions, likethose of other dsRNA mycoviruses, are noninfectious in conventionalinfectivity assays. Therefore, studies on Hv190SV genome expressionand structure-function relationships have relied on the use ofheterologous systems, including bacterial and baculovirus expressionsystems (9, 10, 24).

Like those of other totiviruses, the genome of Hv190SV contains two large overlapping open reading frames (ORFs) coding fora capsid protein (CP) and an RNA-dependent RNA polymerase (RDRP).The 5' end of the positive strand of the dsRNA genome is uncappedand highly structured and contains a relatively long (289 nucleotides[nt]) 5' untranslated region (5' UTR) with two noninitiator AUGs.The 5' UTR is postulated to function as an internal ribosome entrysite (IRES) which directs the translation of the upstream ORF,encoding the CP, by a cap-independent internal initiation mechanism(9). Evidence that the 5' UTR of another totivirus, LeishmaniaRNA virus 1 (LRV1), contains an IRES element has been presented(20). The downstream ORF of the Hv190SV dsRNA genome, encodingthe RDRP, is in a $-$ 1 frame with respect to the CP ORF, and itstranslational start codon (nt 2605 to 2607) overlaps the stopcodon for the upstream CP ORF (nt 2606 to 2608) in the tetranucleotidesequence 2605-AUGA-2608. Hv190SV RDRP is detectable as a separate,nonfused virion-associated minor component (9). The RDRP ORFhas been expressed in bacteria from its initiator AUG at nt 2605to 2607, and the expression product has been shown to be indistinguishablein size and serological reactivity from the virion-associatedRDRP (9).

The mechanism by which the downstream RDRP is expressed from the dicistronic genome of Hv190SV has not been elucidated. Insome totiviruses, including those infecting yeast (Saccharomycescerevisiae L-A virus [ScV-L-A] and ScV-L-BC) and protozoa (Giardialamblia virus and Trichomonas vaginalis virus), RDRP is expressedonly as a CP-RDRP fusion protein via a $-$ 1 (or +1) ribosomal frameshiftmechanism (12, 17, 21, 28). The CP-RDRP fusion proteinis detectable as a virion-associated minor protein. Sequence analysisand secondary-structure predictions of the overlap region betweenthe CP and RDRP ORFs in the yeast and protozoan totiviruses indicatethe presence of a consensus heptameric slippery site and a pseudoknotstructure. Both the slippery site and pseudoknot have been shownto be essential for frameshifting in ScV-L-A, the type speciesof the genus Totivirus (2, 27). As for Hv190SV, previousstudies showed no evidence for the presence of the CP-RDRP fusionprotein in virions or infected fungal isolates (9). This observation,coupled with the lack of structures resembling the consensus ribosomalslippery site and predicted pseudoknot in the overlap region betweenthe two ORFs, suggests that Hv190SV RDRP may be expressed viaa mechanism different from that reported for the totiviruses infectingyeast andprotozoa.

In this study, we examined the expression of RDRP in two heterologous systems. Monocistronic constructs containing the CPor RDRP ORF fused in frame to the reporter gene encoding the greenfluorescent protein (GFP), as well as the dicistronic constructCP-RDRP:GFP, were generated for expression in bacteria and Schizosaccharomycespombe. We demonstrate that RDRP is expressed in S. pombe, butnot in bacteria, from the downstream ORF in the dicistronic constructas a separate nonfused polypeptide. We show that, similar to thatin the fungal host, the expression level of RDRP in S. pombe islow, and we discuss the mechanism(s) by which the downstream RDRPORF is expressed from the Hv190SV dicistronicgenome.

RDRP is expressed from monocistronic, but not dicistronic, constructs in bacteria. Constructs for bacterial expression of the GFP gene or in-frame fusions of the GFP gene to Hv190SV CP- and RDRP-coding sequenceswere generated in the expression vector pET 22(b)+ or pET 21(d)+(Novagen) (Fig. 1). Construct pETGFP was obtained by subcloningthe EcoRI-SstI fragment containing the entire GFP ORF (from plasmidpZ-GFP) in EcoRI- and SstI-digested vector pET 22(b). ConstructpETCP:GFP was produced by a two-step cloning procedure followingPCR amplification. A fragment of the CP ORF corresponding to theC terminus with an introduced EcoRI site for subcloning of theGFP ORF in frame with the CP-coding sequence was generated byPCR. The amplification product (400 bp) was gel purified and digestedwith SpeI and EcoRI and cloned at the SpeI- and EcoRI-digestedsites in the construct pZ-GFP to create a fragment of the CP-codingsequence fused in frame to the GFP ORF. The CP-GFP fused fragmentwas excised by digestion with SpeI and SstI and ligated to theSpeI-digested plasmid pETHV1 (nt 2204 [Fig. 1A]) containing Hv190SVcDNA sequences from nt 290 to 5178 (Fig. 1A) (9). ConstructpETRDRP:GFP was created by in-frame insertion of the EcoRI-SstIfragment containing the GFP ORF into a unique EcoRI site (at nt4276) in the RDRP ORF and the SstI site in the multiple cloningsequence of construct pETHV4 (9), previously generated forthe expression of the RDRP gene in pET 21(d)+ (starting at theinitiator AUG beginning at nt 2605). The dicistronic constructpETCP-RDRP:GFP was generated by insertion of the EcoRI-SstI fragmentcontaining the GFP ORF into the RDRP ORF at a unique EcoRI site(nt 4276 [Fig. 1A]) in the construct pETHV1 to create an in-framefusion of the GFP gene to the sequence corresponding to the Cterminus of RDRP. The CP ORF and the overlapping tetranucleotideATGA between the CP and RDRP ORFs were maintained in the dicistronicconstruct pETCP-RDRP:GFP. The monocistronic constructs containingthe coding sequences for the GFP fusions to CP and RDRP were usedas controls to verify the expression as well as the predictedsizes of the fusion products. Finally, the coding regions of allconstructs generated during the course of this study were confirmedby DNA sequence analysis.

View larger version (37K):
[in this window]
[in a new window]

FIG. 1. Bacterial expression of Hv190SV CP and RDRP ORFs. (A) Schematic representation of pET constructs used for expression of Hv190SV CP and RDRP ORFs. The coding sequence for GFP (750 bp) was fused in frame to the CP or RDRP ORF as a fragment corresponding to the C terminus. pETCP-RDRP:GFP consists of a dicistronic construct containing both the CP and RDRP ORFs with a configuration identical to that of the Hv190SV dicistronic genome; the overlap region (ATGA; nt 2605 to 2608) between the CP and RDRP ORFs was preserved. pETCP:GFP and pETRDRP:GFP represent monocistronic constructs for expression of fusions of the GFP gene to either the CP or RDRP ORF and were included for comparison. Nucleotide numbering in the constructs corresponds to nucleotide positions in Hv190SV cDNA (9); nt 290 and 2605 are the first nucleotides of the initiator codons for the CP and RDRP ORFs, respectively. Construct pETGFP, containing the GFP ORF (750 bp), provided a positive control for GFP expression. (B) Western blot analysis of the bacterial expression products of the Hv190SV dicistronic genome. Lysates from bacterial cells were analyzed following induction with isopropyl- $beta$ -D-thiogalactopyranoside (IPTG), by immunoblotting with antibodies against either CP or GFP by using a chemiluminescent detection kit (Phototope-HRP Western blot detection kit; New England Biolabs). Constructs pETCP:GFP and pETRDRP:GFP for expression of the respective GFP fusions generated predicted products of 120 and 90 kDa, respectively. Expression of the dicistronic construct pETCP-RDRP:GFP produced the expected CP product of 88 kDa, corresponding to the upstream CP ORF. The product from the downstream ORF (RDRP:GFP) in the dicistronic construct was not detected (even in overloaded wells) either as a putative CP-RDRP:GFP fusion protein (predicted size of approximately 180 kDa) or as a separate RDRP:GFP product with a predicted size of approximately 90 kDa that would comigrate with the expression product from construct pETRDRP:GFP.

We initially intended to monitor the expression of the GFP fusions by fluorescence microscopy. This was not possible, however,because the bacterial cells transformed with the GFP fusion constructswere nonfluorescent. The expressed CP:GFP and RDRP:GFP fusionproducts were largely present in an insoluble nonfluorescent formin inclusion bodies. This was determined by Western blot analysisof the soluble (supernatant) and insoluble (pellet) fractionsof the bacterial lysates. The pETGFP-transformed bacteria, onthe other hand, expressed soluble GFP and were brightly fluorescentwhen examined by fluorescence microscopy. We therefore reliedon Western blot analysis to examine the expression of fusion productsfrom the various constructs using polyclonal antisera specificto Hv190SV CP (anti-CP) or GFP (anti-GFP). Western blotting wasconducted as previously described (10, 24) except that immunodetectionwas performed with a chemiluminescence kit (Phototope-HRP Westernblot detection kit; New England Biolabs) and goat anti-rabbitimmunoglobulin G-horseradish peroxidase conjugate as the secondaryantibody. Both of the fusion products CP:GFP (predicted size of120 kDa) and RDRP:GFP (predicted size of 90 kDa), which were foundin the insoluble fraction of the bacterial lysates, were expressedat high levels from their respective monocistronic constructs(Fig. 1B, lanes pETCP:GFP and pETRDRP:GFP).

Although the CP, expressed from the upstream ORF in the dicistronic construct pETCP-RDRP:GFP, was readily detectable in immunoblotswith antibodies against CP (Fig. 1B), expression of the RDRP:GFPfusion from the downstream ORF in the same construct could notbe detected, even when concentrated bacterial lysates were used.The CP was detectable only as a protein band of approximately88 kDa that comigrated with virion p88. Thus, the downstream RDRPORF can be expressed from monocistronic, but not dicistronic,constructs in a prokaryoticsystem.

Hv190SV RDRP is expressed at low levels from the downstream ORF of dicistronic constructs in S. pombe. Constructs for S. pombe expression of GFP gene fusions to the coding sequences of Hv190SV CP and RDRP were generated in thetransformation vector pESP-2 (Stratagene) for ligation-independentcloning (LIC) (Fig. 2A). Bacterial constructs pETCP:GFP and pETCP-RDRP:GFPand construct pZ-CP-RDRP:GFPt (consisting of a truncatedRDRP ORF [nt 2605 to 2684] fused to the coding sequence for N-terminallytruncated GFP) were used as templates along with sequence-specificLIC primers for the 5' end of the CP ORF, starting at the CP initiationcodon (LIC-CPf; 5'-GACGACGACAAGATGTCTCACACCACGATC-3'), and theregion of the GFP-coding sequence corresponding to the C terminus(LIC-GFPr; 5'-CAGGACAGAGCATCATTTGTATAGTTCATCCATGCC-3') to amplifythe respective PCR products. The PCR products corresponding tothe coding sequences of the CP:GFP, CP-RDRP:GFPt, andCP-RDRP:GFP fusions (with approximate sizes of 3.0, 2.9, and 5.0kbp, respectively) were inserted via LIC into the vector pESP-2.Constructs ESPCP:GFP, ESPCP-RDRP:GFP, and ESPCP-RDRP:GFPtwere used to transform S. pombe and expression was analyzed 16to 18 h after induction of the nmt promoter.

View larger version (2474K):
[in this window]
[in a new window]

FIG. 2. Expression of Hv190SV CP and RDRP ORFs in S. pombe. (A) Schematic representation of constructs used for expression of Hv190SV ORFs in S. pombe. Constructs were generated in the transformation vector pESP-2 with gene transcription under the control of the inducible "no message in thiamine" (nmt) promoter. The GFP ORF (750 bp) was fused in frame to either the CP or RDRP ORF as described in the legend to Fig. 1. The CP ORF in all constructs is expressed as an in-frame fusion of the portion corresponding to the C terminus to the GST gene. Construct ESPCP-RDRP:GFP is a dicistronic construct containing both the CP and RDRP ORFs in a configuration identical to that of the Hv190SV dicistronic genome; the region of overlap between the CP start and RDRP stop codons (ATGA; nt 2605 to 2608) was preserved. ESPCP-RDRP:GFPt is likewise a dicistronic construct, but it contains only the first 79 nt of the RDRP ORF fused in frame to an ORF for an N-terminally truncated GFP. Nucleotide numbering in the constructs corresponds to their positions in the full-length cDNA clone of Hv190SV dsRNA (9); nt 290 and 2605 are the first nucleotides for the translation initiation codons of the CP and RDRP ORFs, respectively. (B) Detection of expression of fusions of the GFP gene to the Hv190SV CP or RDRP ORF by fluorescence microscopy. S. pombe cells transformed with construct ESPCP:GFP for expression of the upstream CP ORF were highly fluorescent (upper left). Cells transformed with construct ESPCP-RDRP:GFP showed a subtle and diffuse, but reproducible, fluorescence, indicating that translation from the downstream RDRP ORF occurred in yeast cells, albeit at a lower efficiency (lower left). Cells transformed with the ESPCP-RDRP:GFPt construct, which consists of the downstream ORF fusion to the gene for an N-terminal truncation of GFP (no chromophore formation is predicted), were nonfluorescent (viewed with transmitted light [upper right] and with fluorescence microscopy [lower right]). S. pombe cells were examined 18 h postinduction, after their transfer to thiamine-free culture medium, by epifluorescence microscopy with a fluorescein isothiocyanate filter (490 nm).

Expression was initially determined by visualization of GFP fluorescence with fluorescence microscopy. Yeast cells transformedwith the ESPCP:GFP construct showed bright GFP fluorescence indicatinghigh levels of expression, as would be expected to occur froman optimal translation initiation context in the glutathione S-transferase(GST)-CP:GFP fusion of this monocistronic construct (Fig. 2B).Interestingly, GFP fluorescence was also detectable in yeast cellstransformed with the dicistronic construct ESPCP-RDRP:GFP (Fig.2B). The intensity of fluorescence exhibited by those transformants,however, was markedly lower than that observed in cells transformedwith construct ESPCP:GFP (Fig. 2B). The fluorescence results neverthelessindicated that the RDRP:GFP fusion was indeed expressed from thedownstream ORF of the dicistronic construct. This subtle fluorescencewas consistently observed in cells transformed with the dicistronicconstruct in at least five independent expression experiments.No fluorescence was detected in cells transformed with the dicistronicconstruct ESPCP-RDRP:GPFt, encoding a truncated GFP (Fig.2B). ESPCP-RDRP:GPFt has a dicistronic organization similarto that of ESPCP-RDRP:GFP, but the RDRP ORF is translationallyfused to a truncated GFP ORF predicted to be incapable of chromophoreformation (26). Therefore, it served as a control for endogenous,nonspecific fluorescence. Similarly, no background fluorescencewas observed in S. pombe cells transformed with the parent plasmidpESP-2 (data notshown).

Expression of the RDRP:GFP fusion was further verified by Western blot analysis with S. pombe lysates and antibodies againstGFP. In agreement with our fluorescent microscopy observations,low levels of the RDRP:GFP fusion were detected in lysates fromESPCP-RDRP:GFP transformants by using GFP antibodies (Fig. 3,lane ESPCP-RDRP:GFP). The RDRP:GFP product was evident as a faintprotein band of approximately 90 kDa that comigrated with theproduct expressed from pETRDRP:GFP in bacteria. The size of theprotein band (90 kDa) is consistent with that predicted for aproduct translated from the initiator AUG codon of the downstreamORF starting at nt 2605 of the Hv190SV sequence in the dicistronicconstruct. The 90-kDa protein was detectable only in lysates fromESPCP-RDRP:GFP transformants. The additional protein bands visiblein blots probed with the antiserum to GFP represent nonspecificproducts cross-reacting to GFP antibodies; those are present inthe other samples, including lysates from S. pombe transformedwith the parent plasmid pESP-2 (Fig. 3, lane ESP-2).

View larger version (59K):
[in this window]
[in a new window]

FIG. 3. Western blot analysis of expression products of the Hv190SV CP and RDRP ORFs in S. pombe. Cell lysates were analyzed by immunoblotting with polyclonal antibodies against either CP or GFP by using a chemiluminescent detection kit (Phototope-HRP Western blot detection kit). A polypeptide product of approximately 140 kDa was obtained with construct ESPCP:GFP. Expression of the dicistronic construct ESPCP-RDRP:GFP generated the expected 120-kDa CP-derived GST fusion corresponding to the translation product of the upstream ORF. The RDRP:GFP product corresponding to the translation product of the downstream ORF was detectable as a faint band corresponding to a protein of approximately 90 kDa (predicted to comigrate with the pETRDRP:GFP product [Fig. 1]).

The expression of the CP-derived product as a GST-CP:GFP fusion (with a predicted size of approximately 140 kDa) was readilydetectable in lysates of S. pombe transformed with the monocistronicconstruct ESPCP:GFP with antibodies specific for either CP orGFP (Fig. 3, lanes ESPCP:GFP). The major product (approximately120 kDa) expressed from the dicistronic constructs ESPCP-RDRP:GFPtand ESPCP-RDRP:GFP was detected with the antibodies to CP, butnot with the GFP antibodies (lanes ESPCP-RDRP:GFPt andESPCP-RDRP:GFP). In each case, the size of products generatedwith these transformants was consistent with that predicted fromthe translation of the CP ORF fused to the GST-coding sequence(approximately 120kDa).

The possibility that RDRP was expressed from a shorter transcript rather than the dicistronic full-length transcript was investigatedby Northern hybridization analysis. For this purpose, total RNAwas isolated by the procedure of Chomczynski and Sacchi (1)from S. pombe cells transformed with various expression constructscontaining Hv190SV genes. The RNA samples were electrophoresedon 1% agarose-formaldehyde gels and transferred to a nylon membrane(Hybond N+; Amersham) by alkaline blot transfer (Transblot; Schleicher& Schuell). Blots were hybridized with [ $alpha$ -³²P]dCTP-random-primed (Megaprime; Amersham) probes for the Hv190SVCP-coding sequence (nt 234 to 2204) and the RDRP-coding sequence(nt 3735 to 4917) as well as for the GFP ORF (750 bp). The resultsindicated that a single major transcript of about 6.4 kb was generatedfrom the dicistronic construct ESPCP-RDRP:GFP and that this transcripthybridized with all three probes, indicating that RDRP was expressedfrom the full-length dicistronic mRNA and not from a shorter transcript(a subgenomic mRNA) (Fig. 4, lanes ESPCP-RDRP:GFP). The transcriptproduced from the construct ESPCP-RDRP:GFPt had a predictedsize of 4.5 kb and hybridized with the CP and GFP probes (Fig.4, lanes ESPCP-RDRP:GFPt). No hybridization was detectedwith the RDRP probe (nt 3735 to 4917) because the transcript containsonly RDRP-derived sequence from nt 2605 to 2684. The transcriptobtained from expression of ESPCP:GFP has a predicted size ofapproximately 4.7 kb and hybridized with both the CP and GFP probes;no hybridization signals were detected with the RDRP probe (Fig.4, lanes ESPCP:GFP). As expected, the full-length Hv190SV transcript(5.2 kb) hybridized with both the CP and RDRP sequence-specificprobes, but not with the GFP probe (Fig. 4, lanes PT7190SV-transcript).

View larger version (56K):
[in this window]
[in a new window]

FIG. 4. Northern analysis of transcripts generated in S. pombe expressing the Hv190SV CP and RDRP ORFs. Blots containing total RNA isolated from transformed S. pombe at 18 h postinduction were hybridized with [ $alpha$ -³²P]dCTP-random-primed probes generated from restriction fragments containing the CP and GFP ORFs and a PCR-amplified product corresponding to nt 3735 to 4917 of the RDRP ORF. The in vitro T7 RNA polymerase-synthesized transcript (approximately 5.2 kb) from a full-length cDNA clone of Hv190SV dsRNA (lanes PT7190SV-transcript), which hybridized to both CP and RDRP probes, was included for comparison. Single major transcripts of the predicted sizes (approximately 4.7, 4.5, and 6.4 kb) were generated following the expression of ESPCP:GFP, ESPCP-RDRP:GFPt, and ESPCP-RDRP:GFP, respectively.

Totiviruses that infect filamentous fungi express their RDRP independently from CP. The data presented in this study and previously (9) indicate that Hv190SV is distinct from other totiviruses in that itexpresses its RDRP as a separate nonfused polypeptide rather thana CP-RDRP fusion protein. Convincing evidence has been presentedthat the totiviruses infecting yeast and the protozoa G. lambliaand T. vaginalis express their RDRP only as a CP-RDRP fusion via $-$ 1 (or +1) ribosomal frameshifting and that the CP-RDRP fusionprotein is detectable as a virion-associated minor protein (12,17, 21, 28). Although Gag-Pol-like fusion proteins havenot been detected in Leishmania brasiliensis infected with thetotivirus LRV1, the presence of both a slippery site and a predictedpseudoknot structure in the overlap region supports the notionthat RDRP is expressed via a +1 translational frameshift (25).The recent report that two totiviruses (SsRV1 and SsRV2) infectingthe filamentous fungus Sphaeropsis sapinea are similar to Hv190SVin genome organization and predicted expression strategy is ofconsiderable interest (22). Like Hv190SV, SsRV1 and SsRV2 havea short overlapping region between the two ORFs that lacks botha slippery site and a predicted pseudoknot. Likewise, these twoviruses may not synthesize CP-RDRP fusion proteins. The totivirusesthat infect filamentous fungi thus appear to represent a distinctgroup of totiviruses that share the feature of expressing RDRPas a nonfused separate protein. In this regard, these totivirusesresemble the foamy viruses, a subgroup of retroviruses that breakthe general rule of expression of the pol gene as a Gag-Pol fusion(3).

The mechanism of expression of Hv190SV RDRP and how the level of expression is regulated are important questions that willbe addressed in future studies. The Gag-independent expressionof the foamy virus Pol protein, mentioned above, has been demonstratedto involve a spliced pol mRNA (13). There is no evidence, however,that Hv190SV RDRP is expressed from a transcript (subgenomic RNA)shorter than the full-length dicistronic mRNA. No transcript of2.3 or 2.4 kb was detected by Northern hybridization in lysatesof RDRP-expressing S. pombe cells transformed with the dicistronicCP-RDRP constructs (Fig. 4). Furthermore, no in vitro transcriptsthat can be translated to produce RDRP were generated in in vitrotranscription reactions with purified Hv190SV virions (6).The majority of transcripts that were produced in such reactionswere full-length single-stranded RNA transcripts (5.2 kb) thatdirected the synthesis of the CP polypeptide p88 (6). A reporton generating a short transcript via site-specific cleavage withinthe 5' UTR of the full-length mRNA of the totivirus LRV1 is ofinterest in this regard (19). Several viral and eukaryotic hostRNA polymerases are known to possess polymerase-associated endonucleaseactivities (14).

Expression of the downstream RDRP ORF from the Hv190SV dicistronic genome may occur by one of three mechanisms: leaky scanning,internal ribosome entry, and coupled termination-reinitiationof translation. A combination of more than one mechanism may beinvolved in the expression of such internal ORFs in eukaryotes(11). The fact that the initiation codon (ACAAUGA) of the downstreamRDRP cistron on the Hv190SV dicistronic genome is in a more favorablecontext than the initiator AUG codon (UCCAUGU) of the upstreamCP ORF may support the idea that translation of RDRP occurs byleaky scanning. This, however, seems unlikely because of the verylong distance (2,316 nt) separating the two start codons and thepresence of several AUGs in an optimal context (AXXAUGG) withinthe CP ORF upstream of the RDRP cistron. The distance betweenthe initiation codons of overlapping cistrons, as deduced fromwell-documented examples of translations by leaky scanning, isusually less than 150 nt, and in no case is it longer than 900nt (4, 8, 23). Furthermore, the structural features ofthe 5' UTR of Hv190SV positive-sense RNA (including its secondarystructure and the presence of two minicistrons with AUGs in favorablecontexts) predict that the upstream CP ORF (with its AUG presentin a suboptimal context) is translated via an internal ribosomeentry mechanism (9). It is of interest that for the two knownexamples for overlapping start and stop codons of the type AUGA(where the initiator AUG codon of the downstream cistron overlapsthe UGA stop codon of the upstream ORF), expression of the downstreamORF occurs by leaky scanning (4, 8). Those two virus systems(Rice tungro bacilliform virus and Peanut clump virus RNA-2),unlike Hv190SV (whose two ORFs also exhibit the AUGA overlappingfeature), contain no AUG codons within the sequence separatingthe upstream and downstream initiationcodons.

It is also unlikely that the downstream RDRP ORF of Hv190SV is expressed via IRES-mediated internal initiation since presentevidence suggests that the upstream CP ORF is expressed by sucha mechanism, as discussed earlier. As far as we know there areno examples of dicistronic viral genomes whose two overlappingORFs are both expressed by an internal ribosome binding mechanism.The molar ratio of RDRP in the virions is about 1 to 2%, and theefficiency of RDRP expression in infected cells relative to thatof CP is expected to be similarly low. Such very low levels ofexpression could conceivably be attained via a coupled termination-reinitiationmechanism. The efficiency of reinitiation on viral and eukaryoticdicistronic mRNAs has been reported to be inversely related tothe size of the upstream ORF and positively correlated with thelength of the intercistronic region (11, 15, 16, 18).The facts that the upstream CP ORF is relatively long (2,319 nt)and that the CP and RDRP ORFs have overlapping stop and startcodons of the AUGA type may explain the low frequency of reinitiationand RDRP expression. The finding that RDRP is expressed from itsdownstream ORF in dicistronic constructs in a heterologous eukaryoticsystem (S. pombe), but not in bacteria, suggests that a eukaryotichost factor(s) is required for regulating reinitiation of translationand expression of RDRP. The S. pombe expression system shouldprovide, in future studies, valuable information on viral sequencesand host factors required for expression of the RDRPORF.

In conclusion, we demonstrated the expression in S. pombe cells of the downstream RDRP ORF of Hv190SV from dicistronic constructs.Unlike the RDRPs of some other totiviruses, which are expressedas CP-RDRP fusion proteins, Hv190SV RDRP was detected only asa separate nonfused polypeptide. We found no evidence that RDRPis translated from a transcript shorter than the full-length dicistronicmRNA. Based on the known structural features of the genome ofHv190SV, we proposed that coupled termination-reinitiation oftranslation is the most likely mechanism for expression of RDRP.We explained the low efficiency of RDRP expression on the tightarrangement of the intercistronic region between the CP and RDRPORFs featuring the AUGA-type overlap between the start and stopcodons of the twoORFs.

	ACKNOWLEDGMENTS

We thank Wendy Havens for technicalsupport.

This work was supported by a grant from the USDA NRI Competitive Grants Program (agreement no. 96-35303-3240).

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Plant Pathology, University of Kentucky, S-305 Agriculture Science Building-North,Lexington, KY 40546-0091. Phone: (606) 257-5969. Fax: (606) 323-1961.E-mail: saghab00{at}pop.uky.edu.

Publication no. 99-12-92 of the Kentucky Agricultural ExperimentStation.

REFERENCES

Top
Abstract
Text
References

1. Chomczynski, P., and N. Sacchi. 1987. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal. Biochem. 162:156-159[Medline].

2. Dinman, J. D., T. Icho, and R. B. Wickner. 1991. A $-$ 1 ribosomal frameshift in a double-stranded RNA virus of yeast forms a gag-pol fusion protein. Proc. Natl. Acad. Sci. USA 88:174-178[Abstract/Free Full Text].

3. Enssle, J., I. Jordan, B. Mauer, and A. Rethwilm. 1996. Foamy virus reverse transcriptase is expressed independently from the Gag protein. Proc. Natl. Acad. Sci. USA 93:4137-4141[Abstract/Free Full Text].

4. Fütterer, J., H. M. Rothnie, T. Hohn, and I. Potrykus. 1997. Rice tungro bacilliform virus open reading frames II and III are translated from polycistronic pregenomic RNA by leaky scanning. J. Virol. 71:7984-7989[Abstract].

5. Ghabrial, S. A. 1994. New developments in fungal virology. Adv. Virus Res. 43:303-388[Medline].

6. Ghabrial, S. A., and W. M. Havens. 1989. Conservative transcription of Helminthosporium victoriae 190S virus double-stranded RNA in vitro. J. Gen. Virol. 70:1025-1035.

7. Ghabrial, S. A., J. A. Bruenn, K. W. Buck, R. B. Wickner, J. L. Patterson, K. D. Stuart, A. L. Wang, and C. C. Wang. 1995. Totiviridae, p. 245-252. In F. A. Murphy, C. M. Fauquet, D. H. L. Bishop, S. A. Ghabrial, A. W. Jarvis, G. P. Martelli, M. A. Mayo, and M. D. Summers (ed.), Virus taxonomy. Sixth report of the International Committee on Taxonomy of Viruses. Springer-Verlag, New York, N.Y.

8. Herzog, E., H. Guilley, and C. Fritsch. 1995. Translation of the second gene of peanut clump virus RNA 2 occurs by leaky scanning in vitro. Virology 208:215-225[CrossRef][Medline].

9. Huang, S., and S. A. Ghabrial. 1996. Organization and expression of the double-stranded RNA genome of Helminthosporium victoriae 190S virus, a totivirus infecting a plant pathogenic filamentous fungus. Proc. Natl. Acad. Sci. USA 93:12541-12546[Abstract/Free Full Text].

10. Huang, S., A. I. Soldevila, B. A. Webb, and S. A. Ghabrial. 1997. Expression, assembly, and proteolytic processing of Helminthosporium victoriae 190S totivirus capsid protein in insect cells. Virology 234:130-137[CrossRef][Medline].

11. Hwang, W.-L., and T.-S. Su. 1998. Translational regulation of hepatitis B virus polymerase gene by termination-reinitiation of an upstream minicistron in a length-dependent manner. J. Gen. Virol. 79:2181-2189[Abstract].

12. Icho, T., and R. B. Wickner. 1989. The double-stranded RNA genome of yeast virus L-A encodes its own putative RNA polymerase by fusing two open reading frames. J. Biol. Chem. 264:6716-6723[Abstract/Free Full Text].

13. Jordan, I., J. Enssle, E. Güttler, B. Mauer, and A. Rethwilm. 1996. Expression of human foamy virus reverse transcriptase involves a spliced pol mRNA. Virology 224:314-319[CrossRef][Medline].

14. Kassavetis, G. A., and E. P. Geiduschek. 1993. RNA polymerase marching backward. Science 259:944-945[CrossRef][Medline].

15. Kozak, M. 1987. Effects of intercistronic length on the efficiency of reinitiation by eucaryotic ribosomes. Mol. Cell. Biol. 7:3438-3445[Abstract/Free Full Text].

16. Kozak, M. 1989. The scanning model for translation: an update. J. Cell Biol. 108:229-235[Abstract/Free Full Text].

17. Liu, H.-W., Y. D. Chu, and J.-H. Tai. 1998. Characterization of Trichomonas vaginalis virus proteins in the pathogenic protozoan T. vaginalis. Arch. Virol. 143:963-970[CrossRef][Medline].

18. Luukkonen, B. G. M., W. Tan, and S. Schwartz. 1995. Efficiency of reinitiation of translation on human immunodeficiency virus type 1 mRNA is determined by the length of the upstream open reading frame and by intercistronic distance. J. Virol. 69:4086-4094[Abstract].

19. MacBeth, K. J., and J. L. Patterson. 1995. The short transcript of Leishmania RNA virus is generated by RNA cleavage. J. Virol. 69:3458-3464[Abstract].

20. Maga, J. A., G. Widmer, and J. H. LeBowitz. 1995. Leishmania RNA virus 1-mediated cap-independent translation. Mol. Cell. Biol. 15:4884-4889[Abstract].

21. Park, C.-M., J. D. Lopinski, J. Masuda, T.-H. Tzeng, and J. A. Bruenn. 1996. A second double-stranded RNA virus from yeast. Virology 216:451-454[CrossRef][Medline].

22. Preisig, O., B. D. Wingfield, and M. J. Wingfield. 1998. Coinfection of a fungal pathogen by two distinct double-stranded RNA viruses. Virology 252:399-406[CrossRef][Medline].

23. Sivakumaran, K., and D. L. Hacker. 1998. The 105-kDa polyprotein of Southern bean mosaic virus is translated by scanning ribosomes. Virology 246:34-44[CrossRef][Medline].

24. Soldevila, A. I., S. Huang, and S. A. Ghabrial. 1998. Assembly of the Hv190S totivirus capsid is independent of posttranslational modification of the capsid protein. Virology 251:327-333[CrossRef][Medline].

25. Stuart, K. D., R. Weeks, L. Guilbride, and P. J. Myler. 1992. Molecular organization of the Leishmania RNA virus LRV1. Proc. Natl. Acad. Sci. USA 89:8596-8600[Abstract/Free Full Text].

26. Tsien, R. Y. 1998. The green fluorescent protein. Annu. Rev. Biochem. 67:509-544[CrossRef][Medline].

27. Tzeng, T.-H., C.-L. Tu, and J. A. Bruenn. 1992. Ribosomal frameshifting requires a pseudoknot in the Saccharomyces cerevisiae double-stranded RNA virus. J. Virol. 66:999-1006[Abstract/Free Full Text].

28. Wang, A. L., H.-M. Yang, K. A. Shen, and C. C. Wang. 1993. Giardiavirus double-stranded RNA genome encodes a capsid polypeptide and a gag-pol-like fusion protein by a translation frameshift. Proc. Natl. Acad. Sci. USA 90:8595-8599[Abstract/Free Full Text].

This article has been cited by other articles:

Guo, L.-h., Sun, L., Chiba, S., Araki, H., Suzuki, N. (2009). Coupled termination/reinitiation for translation of the downstream open reading frame B of the prototypic hypovirus CHV1-EP713. Nucleic Acids Res 37: 3645-3659 [Abstract] [Full Text]
Suzuki, N., Geletka, L. M., Nuss, D. L. (2000). Essential and Dispensable Virus-Encoded Replication Elements Revealed by Efforts To Develop Hypoviruses as Gene Expression Vectors. J. Virol. 74: 7568-7577 [Abstract] [Full Text]
Soldevila, A. I., Ghabrial, S. A. (2001). A Novel Alcohol Oxidase/RNA-binding Protein with Affinity for Mycovirus Double-stranded RNA from the Filamentous Fungus Helminthosporium (Cochliobolus) victoriae. MOLECULAR AND FUNCTIONAL CHARACTERIZATION. J. Biol. Chem. 276: 4652-4661 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Soldevila, A. I.
	Articles by Ghabrial, S. A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Soldevila, A. I.
	Articles by Ghabrial, S. A.

1.	Chomczynski, P., and N. Sacchi. 1987. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal. Biochem. 162:156-159[Medline].
2.	Dinman, J. D., T. Icho, and R. B. Wickner. 1991. A $-$ 1 ribosomal frameshift in a double-stranded RNA virus of yeast forms a gag-pol fusion protein. Proc. Natl. Acad. Sci. USA 88:174-178[Abstract/Free Full Text].
3.	Enssle, J., I. Jordan, B. Mauer, and A. Rethwilm. 1996. Foamy virus reverse transcriptase is expressed independently from the Gag protein. Proc. Natl. Acad. Sci. USA 93:4137-4141[Abstract/Free Full Text].
4.	Fütterer, J., H. M. Rothnie, T. Hohn, and I. Potrykus. 1997. Rice tungro bacilliform virus open reading frames II and III are translated from polycistronic pregenomic RNA by leaky scanning. J. Virol. 71:7984-7989[Abstract].
5.	Ghabrial, S. A. 1994. New developments in fungal virology. Adv. Virus Res. 43:303-388[Medline].
6.	Ghabrial, S. A., and W. M. Havens. 1989. Conservative transcription of Helminthosporium victoriae 190S virus double-stranded RNA in vitro. J. Gen. Virol. 70:1025-1035.
7.	Ghabrial, S. A., J. A. Bruenn, K. W. Buck, R. B. Wickner, J. L. Patterson, K. D. Stuart, A. L. Wang, and C. C. Wang. 1995. Totiviridae, p. 245-252. In F. A. Murphy, C. M. Fauquet, D. H. L. Bishop, S. A. Ghabrial, A. W. Jarvis, G. P. Martelli, M. A. Mayo, and M. D. Summers (ed.), Virus taxonomy. Sixth report of the International Committee on Taxonomy of Viruses. Springer-Verlag, New York, N.Y.
8.	Herzog, E., H. Guilley, and C. Fritsch. 1995. Translation of the second gene of peanut clump virus RNA 2 occurs by leaky scanning in vitro. Virology 208:215-225[CrossRef][Medline].
9.	Huang, S., and S. A. Ghabrial. 1996. Organization and expression of the double-stranded RNA genome of Helminthosporium victoriae 190S virus, a totivirus infecting a plant pathogenic filamentous fungus. Proc. Natl. Acad. Sci. USA 93:12541-12546[Abstract/Free Full Text].
10.	Huang, S., A. I. Soldevila, B. A. Webb, and S. A. Ghabrial. 1997. Expression, assembly, and proteolytic processing of Helminthosporium victoriae 190S totivirus capsid protein in insect cells. Virology 234:130-137[CrossRef][Medline].
11.	Hwang, W.-L., and T.-S. Su. 1998. Translational regulation of hepatitis B virus polymerase gene by termination-reinitiation of an upstream minicistron in a length-dependent manner. J. Gen. Virol. 79:2181-2189[Abstract].
12.	Icho, T., and R. B. Wickner. 1989. The double-stranded RNA genome of yeast virus L-A encodes its own putative RNA polymerase by fusing two open reading frames. J. Biol. Chem. 264:6716-6723[Abstract/Free Full Text].
13.	Jordan, I., J. Enssle, E. Güttler, B. Mauer, and A. Rethwilm. 1996. Expression of human foamy virus reverse transcriptase involves a spliced pol mRNA. Virology 224:314-319[CrossRef][Medline].
14.	Kassavetis, G. A., and E. P. Geiduschek. 1993. RNA polymerase marching backward. Science 259:944-945[CrossRef][Medline].
15.	Kozak, M. 1987. Effects of intercistronic length on the efficiency of reinitiation by eucaryotic ribosomes. Mol. Cell. Biol. 7:3438-3445[Abstract/Free Full Text].
16.	Kozak, M. 1989. The scanning model for translation: an update. J. Cell Biol. 108:229-235[Abstract/Free Full Text].
17.	Liu, H.-W., Y. D. Chu, and J.-H. Tai. 1998. Characterization of Trichomonas vaginalis virus proteins in the pathogenic protozoan T. vaginalis. Arch. Virol. 143:963-970[CrossRef][Medline].
18.	Luukkonen, B. G. M., W. Tan, and S. Schwartz. 1995. Efficiency of reinitiation of translation on human immunodeficiency virus type 1 mRNA is determined by the length of the upstream open reading frame and by intercistronic distance. J. Virol. 69:4086-4094[Abstract].
19.	MacBeth, K. J., and J. L. Patterson. 1995. The short transcript of Leishmania RNA virus is generated by RNA cleavage. J. Virol. 69:3458-3464[Abstract].
20.	Maga, J. A., G. Widmer, and J. H. LeBowitz. 1995. Leishmania RNA virus 1-mediated cap-independent translation. Mol. Cell. Biol. 15:4884-4889[Abstract].
21.	Park, C.-M., J. D. Lopinski, J. Masuda, T.-H. Tzeng, and J. A. Bruenn. 1996. A second double-stranded RNA virus from yeast. Virology 216:451-454[CrossRef][Medline].
22.	Preisig, O., B. D. Wingfield, and M. J. Wingfield. 1998. Coinfection of a fungal pathogen by two distinct double-stranded RNA viruses. Virology 252:399-406[CrossRef][Medline].
23.	Sivakumaran, K., and D. L. Hacker. 1998. The 105-kDa polyprotein of Southern bean mosaic virus is translated by scanning ribosomes. Virology 246:34-44[CrossRef][Medline].
24.	Soldevila, A. I., S. Huang, and S. A. Ghabrial. 1998. Assembly of the Hv190S totivirus capsid is independent of posttranslational modification of the capsid protein. Virology 251:327-333[CrossRef][Medline].
25.	Stuart, K. D., R. Weeks, L. Guilbride, and P. J. Myler. 1992. Molecular organization of the Leishmania RNA virus LRV1. Proc. Natl. Acad. Sci. USA 89:8596-8600[Abstract/Free Full Text].
26.	Tsien, R. Y. 1998. The green fluorescent protein. Annu. Rev. Biochem. 67:509-544[CrossRef][Medline].
27.	Tzeng, T.-H., C.-L. Tu, and J. A. Bruenn. 1992. Ribosomal frameshifting requires a pseudoknot in the Saccharomyces cerevisiae double-stranded RNA virus. J. Virol. 66:999-1006[Abstract/Free Full Text].
28.	Wang, A. L., H.-M. Yang, K. A. Shen, and C. C. Wang. 1993. Giardiavirus double-stranded RNA genome encodes a capsid polypeptide and a gag-pol-like fusion protein by a translation frameshift. Proc. Natl. Acad. Sci. USA 90:8595-8599[Abstract/Free Full Text].