A novel viral RNA species in Sindbis virus-infected cells

De-Coding the Contributions of the Viral RNAs to Alphaviral Pathogenesis

Alphaviruses are positive-sense RNA arboviruses that are capable of causing severe disease in otherwise healthy individuals. There are many aspects of viral infection that determine pathogenesis and major efforts regarding the identification and characterization of virulence determinants have largely focused on the roles of the nonstructural and structural proteins. Nonetheless, the viral RNAs of the alphaviruses themselves play important roles in regard to virulence and pathogenesis. In particular, many sequences and secondary structures within the viral RNAs play an important part in the development of disease and may be considered important determinants of virulence. In this review article, we summarize the known RNA-based virulence traits and host:RNA interactions that influence alphaviral pathogenesis for each of the viral RNA species produced during infection. Overall, the viral RNAs produced during infection are important contributors to alphaviral pathogenesis and more research is needed to fully understand how each RNA species impacts the host response to infection as well as the development of disease.

Purification of Highly Active Alphavirus Replication Complexes Demonstrates Altered Fractionation of Multiple Cellular Membranes

Positive-strand RNA viruses replicate their genomes in membrane-associated structures; alphaviruses and many other groups induce membrane invaginations called spherules. Here, we established a protocol to purify these membranous replication complexes (RCs) from cells infected with Semliki Forest virus (SFV). We isolated SFV spherules located on the plasma membrane and further purified them using two consecutive density gradients. This revealed that SFV infection strongly modifies cellular membranes. We removed soluble proteins, the Golgi membranes, and most of the mitochondria, but plasma membrane, endoplasmic reticulum (ER), and late endosome markers were retained in the membrane fraction that contained viral RNA synthesizing activity, replicase proteins, and minus- and plus-strand RNA. Electron microscopy revealed that the purified membranes displayed spherule-like structures with a narrow neck. This membrane enrichment was specific to viral replication, as such a distribution of membrane markers was only observed after infection. Besides the plasma membrane, SFV infection remodeled the ER, and the cofractionation of the RC-carrying plasma membrane and ER suggests that SFV recruits ER proteins or membrane to the site of replication. The purified RCs were highly active in synthesizing both genomic and subgenomic RNA. Detergent solubilization destroyed the replication activity, demonstrating that the membrane association of the complex is essential. Most of the newly made RNA was in double-stranded replicative molecules, but the purified complexes also produced single-stranded RNA as well as released newly made RNA. This indicates that the purification established here maintained the functionality of RCs and thus enables further structural and functional studies of active RCs.IMPORTANCE Similar to all positive-strand RNA viruses, the arthropod-borne alphaviruses induce membranous genome factories, but little is known about the arrangement of viral replicase proteins and the presence of host proteins in these replication complexes. To improve our knowledge of alphavirus RNA-synthesizing complexes, we isolated and purified them from infected mammalian cells. Detection of viral RNA and in vitro replication assays revealed that these complexes are abundant and highly active when located on the plasma membrane. After multiple purification steps, they remain functional in synthesizing and releasing viral RNA. Besides the plasma membrane, markers for the endoplasmic reticulum and late endosomes were enriched with the replication complexes, demonstrating that alphavirus infection modified cellular membranes beyond inducing replication spherules on the plasma membrane. We have developed here a gentle purification method to obtain large quantities of highly active replication complexes, and similar methods can be applied to other positive-strand RNA viruses.

Polyprotein Processing as a Determinant for in Vitro Activity of Semliki Forest Virus Replicase

Semliki Forest virus (SFV) is an arthropod-borne alphavirus that induces membrane invaginations (spherules) in host cells. These harbor the viral replication complexes (RC) that synthesize viral RNA. Alphaviruses have four replicase or nonstructural proteins (nsPs), nsP1-4, expressed as polyprotein P1234. An early RC, which synthesizes minus-strand RNA, is formed by the polyprotein P123 and the polymerase nsP4. Further proteolytic cleavage results in a late RC consisting of nsP1-4 and synthesizing plus strands. Here, we show that only the late RCs are highly active in RNA synthesis in vitro. Furthermore, we demonstrate that active RCs can be isolated from both virus-infected cells and cells transfected with the wild-type replicase in combination with a plasmid expressing a template RNA. When an uncleavable polyprotein P123 and polymerase nsP4 were expressed together with a template, high levels of minus-strand RNA were produced in cells, but RCs isolated from these cells were hardly active in vitro. Furthermore, we observed that the uncleavable polyprotein P123 and polymerase nsP4, which have previously been shown to form spherules even in the absence of the template, did not replicate an exogenous template. Consequently, we hypothesize that the replicase proteins were sequestered in spherules and were no longer able to recruit a template.

Alphavirus RNA synthesis and non-structural protein functions

The members of the genus Alphavirus are positive-sense RNA viruses, which are predominantly transmitted to vertebrates by a mosquito vector. Alphavirus disease in humans can be severely debilitating, and depending on the particular viral species, infection may result in encephalitis and possibly death. In recent years, alphaviruses have received significant attention from public health authorities as a consequence of the dramatic emergence of chikungunya virus in the Indian Ocean islands and the Caribbean. Currently, no safe, approved or effective vaccine or antiviral intervention exists for human alphavirus infection. The molecular biology of alphavirus RNA synthesis has been well studied in a few species of the genus and represents a general target for antiviral drug development. This review describes what is currently understood about the regulation of alphavirus RNA synthesis, the roles of the viral non-structural proteins in this process and the functions of cis-acting RNA elements in replication, and points to open questions within the field.

An in vitro assay to study chikungunya virus RNA synthesis and the mode of action of inhibitors

Chikungunya virus (CHIKV) is a re-emerging mosquito-borne alphavirus that causes severe persistent arthralgia. To better understand the molecular details of CHIKV RNA synthesis and the mode of action of inhibitors, we have developed an in vitro assay to study CHIKV replication/transcription complexes isolated from infected cells. In this assay (32)P-CTP was incorporated into the CHIKV genome, subgenomic (sg) RNA and into a ~7.5 kb positive-stranded RNA, termed RNA II. We mapped RNA II, which was also found in CHIKV-infected cells, to the 5' end of the genome up to the start of the sgRNA promoter region. Most of the RNA-synthesizing activity, negative-stranded RNA and a relatively large proportion of nsP1 and nsP4 were recovered from a crude membrane fraction obtained by pelleting at 15,000 G: . Positive-stranded RNA was mainly found in the cytosolic S15 fraction, suggesting it was released from the membrane-associated replication/transcription complexes (RTCs). The newly synthesized RNA was relatively stable and remained protected from cellular nucleases, possibly by encapsidation. A set of compounds that inhibit CHIKV replication in cell culture was tested in the in vitro RTC assay. In contrast to 3'dNTPs, chain terminators that acted as potent inhibitors of RTC activity, ribavirin triphosphate and 6-aza-UTP did not affect the RNA-synthesizing activity in vitro. In conclusion, this in vitro assay for CHIKV RNA synthesis is a useful tool for mechanistic studies on the RTC and mode of action studies on compounds with anti-CHIKV activity.

Production of virus-derived ping-pong-dependent piRNA-like small RNAs in the mosquito soma

The natural maintenance cycles of many mosquito-borne pathogens require establishment of persistent non-lethal infections in the invertebrate host. The mechanism by which this occurs is not well understood, but we have previously shown that an antiviral response directed by small interfering RNAs (siRNAs) is important in modulating the pathogenesis of alphavirus infections in the mosquito. However, we report here that infection of mosquitoes with an alphavirus also triggers the production of another class of virus-derived small RNAs that exhibit many similarities to ping-pong-dependent piwi-interacting RNAs (piRNAs). However, unlike ping-pong-dependent piRNAs that have been described previously from repetitive elements or piRNA clusters, our work suggests production in the soma. We also present evidence that suggests virus-derived piRNA-like small RNAs are capable of modulating the pathogenesis of alphavirus infections in dicer-2 null mutant mosquito cell lines defective in viral siRNA production. Overall, our results suggest that a non-canonical piRNA pathway is present in the soma of vector mosquitoes and may be acting redundantly to the siRNA pathway to target alphavirus replication.

Mosquitoes defend themselves against viral infection with an innate immune response. Thus, mosquito-borne viral diseases like West Nile fever, dengue fever, and chikungunya fever are transmitted to humans only when the pathogen overcomes these defenses. Despite this, relatively little is known about the immune pathways of the mosquito. We have previously shown that an antiviral response directed by small interfering RNAs (siRNAs) is present in culicine mosquito vectors. However, we show here that another class of virus-derived small RNAs, exhibiting many similarities with ping-pong-dependent piwi-interacting RNAs (piRNAs), is also produced in the soma of culicine mosquitoes. We also show that these piRNA-like small RNAs are capable of mounting an antiviral defense in mosquito cell lines with defective siRNA-based immunity, suggesting that mosquitoes possess redundant RNA-based antiviral responses. This study provides new insights into how a mosquito's immune defenses restrict virus replication and the transmission of mosquito-borne viruses.

In vitro synthesis of Sindbis virus genomic and subgenomic RNAs: influence of nsP4 mutations and nucleoside triphosphate concentrations

Two positive-strand mRNAs are made in Sindbis virus-infected cells, the genomic (G) RNA and the subgenomic (SG) RNA. In mosquito cells infected with wild-type (wt) Sindbis virus, the latter is made in excess over the former; however, in cells infected with SVpzf or SVcpc more G RNA is made than SG RNA. Use was made of in vitro systems to investigate the effects of the SVpzf and SVcpc mutations on the synthesis of SG and G RNAs. Our findings indicate that under standard reaction conditions, the SG/G RNA ratio in vitro reflects the ratio of SG to G RNA made in infected mosquito cells. We observed further that the RNA patterns seen in vitro are affected not only by the SVpzf and SVcpc mutations but also by the nucleoside triphosphate concentrations in the reaction mixtures and that introduction of these mutations into nsP4 and the promoter/template change the relative amounts of SG and G RNAs that are made, likely through the choice of promoter. We conclude that with respect to the SVpzf and SVcpc mutations, it is mainly the nucleotide changes in the SG promoter, not the amino acid changes in nsP4, that determine the SG/G RNA ratio that results. Further, it was observed that the SVpzf mutations enhance the in vitro synthesis of SG RNA at the lowest concentrations of UTP/CTP and that the single SVcpc mutation enhances the synthesis of G RNA at the lowest concentrations of CTP tested. We also identified three Arg residues in nsP4, R545, R546, and R547, that are needed for the synthesis of G RNA but not SG RNA.

Origins of alphavirus-derived small RNAs in mosquitoes

The continual transmission in nature of many arthropod-borne viruses depends on the establishment of a persistent, nonpathogenic infection in a mosquito vector. The importance of antiviral immunity directed by small RNAs in the mechanism by which alphaviruses establish a persistent, nonpathogenic infection in the mosquito vector has recently been demonstrated. The origin of the small RNAs central to this RNA silencing response has recently been the subject of debate. Here we briefly summarize what is known about the mechanism of small RNA-directed immunity in invertebrates, and discuss current models for the viral triggers of this response. Finally, we summarize evidence indicating that alphavirus double-stranded replicative intermediates trigger an exogenous-siRNA pathway in mosquitoes resulting in the biogenesis of virus-derived siRNAs.

The 5'UTR-specific mutation in VEEV TC-83 genome has a strong effect on RNA replication and subgenomic RNA synthesis, but not on translation of the encoded proteins

Venezuelan equine encephalitis virus (VEEV) is one of the most pathogenic members of the Alphavirus genus in the Togaviridae family. Viruses in the VEEV serocomplex continuously circulate in the Central and South America. The only currently available attenuated strain VEEV TC-83 is being used only for vaccination of at-risk laboratory workers and military personnel. Its attenuated phenotype was shown to rely only on two point mutations, one of which, G3A, was found in the 5' untranslated region (5'UTR) of the viral genome. Our data demonstrate that the G3A mutation strongly affects the secondary structure of VEEV 5'UTR, but has only a minor effect on translation. The indicated mutation increases replication of the viral genome, downregulates transcription of the subgenomic RNA, and, thus, affects the ratio of genomic and subgenomic RNA synthesis. These findings and the previously reported G3A-induced, higher sensitivity of VEEV TC-83 to IFN-alpha/beta suggest a plausible explanation for its attenuated phenotype.

Characterization of the 5'- and 3'-terminal subgenomic RNAs produced by a capillovirus: Evidence for a CP subgenomic RNA

The members of Capillovirus genus encode two overlapping open reading frames (ORFs): ORF1 encodes a large polyprotein containing the replication-associated proteins plus a coat protein (CP), and ORF2 encodes a movement protein (MP), located within ORF1 in a different reading frame. Organization of the CP sequence as part of the replicase ORF is unusual in capilloviruses. In this study, we examined the capillovirus genome expression strategy by characterizing viral RNAs produced by Citrus tatter leaf virus (CTLV), isolate ML, a Capillovirus. CTLV-ML produced a genome-length RNA of approximately 6.5-kb and two 3'-terminal sgRNAs in infected tissue that contain the MP and CP coding sequences (3'-sgRNA1), and the CP coding sequence (3'-sgRNA2), respectively. Both 3'-sgRNAs initiate at a conserved octanucleotide (UUGAAAGA), and are 1826 (3'-sgRNA1) and 869 (3'-sgRNA2) nts with 119 and 15 nt leader sequences, respectively, suggesting that these two 3'-sgRNAs could serve to express the MP and CP. Additionally, accumulation of two 5'-terminal sgRNAs of 5586 (5'-sgRNA1) and 4625 (5'-sgRNA2) nts was observed, and their 3'-termini mapped to 38-44 nts upstream of the transcription start sites of 3'-sgRNAs. The presence of a separate 3'-sgRNA corresponding to the CP coding sequence and its cognate 5'-terminal sgRNA (5'-sgRNA1) suggests that CTLV-ML produces a dedicated sg mRNA for the expression of its CP.

Seco-pregnane steroids target the subgenomic RNA of alphavirus-like RNA viruses

Plants have evolved multiple mechanisms to selectively suppress pathogens by production of secondary metabolites with antimicrobial activities. Therefore, direct selections for antiviral compounds from plants can be used to identify new agents with potent antiviral activity but not toxic to hosts. Here, we provide evidence that a class of compounds, seco-pregnane steroid glaucogenin C and its monosugar-glycoside cynatratoside A of Strobilanthes cusia and three new pantasugar-glycosides of glaucogenin C of Cynanchum paniculatum, are effective and selective inhibitors to alphavirus-like positive-strand RNA viruses including plant-infecting tobacco mosaic virus (TMV) and animal-infecting Sindbis virus (SINV), eastern equine encephalitis virus, and Getah virus, but not to other RNA or DNA viruses, yet they were not toxic to host cells. In vivo administration of the compounds protected BALB/c mice from lethal SINV infection without adverse effects on the mice. Using TMV and SINV as models, studies on the action mechanism revealed that the compounds predominantly suppress the expression of viral subgenomic RNA(s) without affecting the accumulation of viral genomic RNA. Our work suggested that the viral subgenomic RNA could be a new target for the discovery of antiviral drugs, and that seco-pregnane steroid and its four glycosides found in the two medicinal herbs have the potential for further development as antiviral agents against alphavirus-like positive-strand RNA viruses.

Characterization of a novel 5' subgenomic RNA3a derived from RNA3 of Brome mosaic bromovirus

The synthesis of 3' subgenomic RNA4 (sgRNA4) by initiation from an internal sg promoter in the RNA3 segment was first described for Brome mosaic bromovirus (BMV), a model tripartite positive-sense RNA virus (W. A. Miller, T. W. Dreher, and T. C. Hall, Nature 313:68-70, 1985). In this work, we describe a novel 5' sgRNA of BMV (sgRNA3a) that we propose arises by premature internal termination and that encapsidates in BMV virions. Cloning and sequencing revealed that, unlike any other BMV RNA segment, sgRNA3a carries a 3' oligo(A) tail, in which respect it resembles cellular mRNAs. Indeed, both the accumulation of sgRNA3a in polysomes and the synthesis of movement protein 3a in in vitro systems suggest active functions of sgRNA3a during protein synthesis. Moreover, when copied in the BMV replicase in vitro reaction, the minus-strand RNA3 template generated the sgRNA3a product, likely by premature termination at the minus-strand oligo(U) tract. Deletion of the oligo(A) tract in BMV RNA3 inhibited synthesis of sgRNA3a during infection. We propose a model in which the synthesis of RNA3 is terminated prematurely near the sg promoter. The discovery of 5' sgRNA3a sheds new light on strategies viruses can use to separate replication from the translation functions of their genomic RNAs.

Mutual interference between genomic RNA replication and subgenomic mRNA transcription in brome mosaic virus

Replication by many positive-strand RNA viruses includes genomic RNA amplification and subgenomic mRNA (sgRNA) transcription. For brome mosaic virus (BMV), both processes occur in virus-induced, membrane-associated compartments, require BMV replication factors 1a and 2a, and use negative-strand RNA3 as a template for genomic RNA3 and sgRNA syntheses. To begin elucidating their relations, we examined the interaction of RNA3 replication and sgRNA transcription in Saccharomyces cerevisiae expressing 1a and 2a, which support the full RNA3 replication cycle. Blocking sgRNA transcription stimulated RNA3 replication by up to 350%, implying that sgRNA transcription inhibits RNA3 replication. Such inhibition was independent of the sgRNA-encoded coat protein and operated in cis. We further found that sgRNA transcription inhibited RNA3 replication at a step or steps after negative-strand RNA3 synthesis, implying competition with positive-strand RNA3 synthesis for negative-strand RNA3 templates, viral replication factors, or common host components. Consistent with this, sgRNA transcription was stimulated by up to 400% when mutations inhibiting positive-strand RNA3 synthesis were introduced into the RNA3 5'-untranslated region. Thus, BMV subgenomic and genomic RNA syntheses mutually interfered with each other, apparently by competition for one or more common factors. In plant protoplasts replicating all three BMV genomic RNAs, mutations blocking sgRNA transcription often had lesser effects on RNA3 accumulation, possibly because RNA3 also competed with RNA1 and RNA2 replication templates and because any increase in RNA3 replication at the expense of RNA1 and RNA2 would be self-limited by decreased 1a and 2a expression from RNA1 and RNA2.

cis-acting elements at opposite ends of the Citrus tristeza virus genome differ in initiation and termination of subgenomic RNAs

Citrus tristeza virus (CTV), a member of the Closteroviridae with a plus-stranded genomic RNA of approximately 20 kb, produces 10 3'-coterminal subgenomic (sg) RNAs that serve as messenger (m)RNAs for its internal genes. In addition, a population of 5'-terminal sgRNAs of approximately 700 nts are highly abundant in infected cells. Previous analysis demonstrated that the controller elements (CE) are responsible for the 3'-terminal mRNAs and the small 5'-terminal sgRNAs differ in the number of additional sgRNAs produced. A feature of both types of CE is production of 5'- and 3'-terminal positive-stranded sgRNAs, but the 3' CEs additionally produce a negative-stranded complement of the 3'-terminal mRNAs. Here, we found that the termination (for 5'-terminal sgRNAs) and initiation (for 3'-terminal sgRNAs) sites of the 5' vs. the 3' CEs occur at opposite ends of the respective minimal active CEs. The initiation site for the 3' CE of the major coat protein gene, and probably those of the p20 and p23 genes, was outside (3' in terms of the genomic RNA) the minimal unit, whereas the termination sites were located within the minimal CE, 30-50 nts upstream of the initiation site (referring to the positive-strand sequence). In contrast, the initiation site for the 5' CE was in the 5' region of the minimal unit, with the termination sites 20-35 nts downstream (referring to the positive-strand sequence). Furthermore, the CEs differ in initiation nucleotide and response to mutagenesis of that nucleotide. The 3' CE initiates sgRNA synthesis from a uridylate, whereas the 5' CE initiates from a cytidylate. We previously found that the 3' CEs were unusually tolerant to mutagenesis of the initiation sites, with initiation proceeding from alternative sites. Mutagenesis of the initiation site of the 5' CE prevented synthesis of either the 5'- or 3'-terminal sgRNAs. Thus, the cis-acting elements at opposite ends of the genome are remarkably different, perhaps having arisen from different origins and or with different functions in the life cycle of this virus.

Two classes of subgenomic RNA of grapevine virus A produced by internal controller elements

Grapevine virus A (GVA), a species of the recently established genus Vitivirus, consists of an approximately 7.3-kb single-stranded RNA genome of positive polarity, organized into five open reading frames (ORFs). The virus, which is closely associated with the grapevine rugose wood disease complex, has been poorly investigated genetically. We explored the production of viral RNAs in a GVA-infected Nicotiana benthamiana herbaceous host and characterized one nested set of three 5'-terminal sgRNAs of 5.1, 5.5, and 6.0 kb, and another, of three 3'-terminal sgRNAs of 2.2, 1.8, and 1.0 kb that could serve for expression of ORFs 2-3, respectively. Neither 3'- nor 5'-terminal sgRNAs, which would correspond to ORF5, was detected, suggesting that expression of this ORF occurs via a bi- or polycistronic mRNA. The 5'-terminal sgRNAs were abundant in dsRNA-enriched extracts. Cloning and sequence analysis of the 3' end of 5.5-kb 5'-terminal sgRNA and the 5' end of the 1.8-kb 3'-terminal sgRNA suggested that a mechanism other than specific cleavage was involved in production of these sgRNAs. Apparently, the production of the 5'- and 3'-terminal sgRNAs was controlled by sequences upstream of the 5'-terminus of each of ORFs 2-4. Detection of both plus and minus strands of the 5'- and 3'-terminal sgRNAs, though in different levels of accumulation, suggested that each of these cis-acting elements is involved in production of four RNAs: a 3'-terminal plus-strand sgRNA which could act as an mRNA, the corresponding 3'-terminal minus-strand RNA, a 5'-terminal plus-strand sgRNA, and the corresponding 5'-terminal minus-strand RNA.

Transcription strategy in a Closterovirus: a novel 5'-proximal controller element of Citrus Tristeza Virus produces 5'- and 3'-terminal subgenomic RNAs and differs from 3' open reading frame controller elements

Citrus tristeza virus (CTV) produces more than thirty 3'- or 5'-terminal subgenomic RNAs (sgRNAs) that accumulate to various extents during replication in protoplasts and plants. Among the most unusual species are two abundant populations of small 5'-terminal sgRNAs of approximately 800 nucleotides (nt) termed low-molecular-weight tristeza (LMT1 and LMT2) RNAs. Remarkably, CTV replicons with all 10 3' genes deleted produce only the larger LMT1 RNAs. These 5'-terminal positive-sense sgRNAs do not have corresponding negative strands and were hypothesized to be produced by premature termination during plus-strand genomic RNA synthesis. We characterized a cis-acting element that controls the production of the LMT1 RNAs. Since manipulation of this cis-acting element in its native position (the L-ProI region of replicase) was not possible because the mutations negatively affect replication, a region (5'TR) surrounding the putative termination sites (nt approximately 550 to 1000) was duplicated in the 3' end of a CTV replicon to allow characterization. The duplicated sequence continued to produce a 5'-terminal plus-strand sgRNA, here much larger ( approximately 11 kb), apparently by termination. Surprisingly, a new 3'-terminal sgRNA was observed from the duplicated 5'TR. A large 3'-terminal sgRNA resulting from the putative promoter activity of the native 5'TR was not observed, possibly because of the down-regulation of a promoter approximately 19 kb from the 3' terminus. However, we were able to observe a sgRNA produced from the native 5'TR of a small defective RNA, which placed the native 5'TR closer to the 3' terminus, demonstrating sgRNA promoter activity of the native 5'TR. Deletion mutagenesis mapped the promoter and the terminator activities of the 5'TR (in the 3' position in the CTV replicon) to a 57-nt region, which was folded by the MFOLD computer program into two stem-loops. Mutations in the putative stem-loop structures equally reduced or prevented production of both the 3'- and 5'-terminal sgRNAs. These mutations, when introduced in frame in the native 5'TR, similarly abolished the synthesis of the LMT1 RNAs and presumably the large 3'-terminal sgRNA while having no impact on replication, demonstrating that neither 5'- nor 3'-terminal sgRNA is necessary for replication of the replicon or full-length CTV in protoplasts. Differences between the 5'TR, which produced two plus-strand sgRNAs, and the cis-acting elements controlling the 3' open reading frames, which produced additional minus-strand sgRNAs corresponding to the 3'-terminal mRNAs, suggest that the different sgRNA controller elements had different origins in the modular evolution of closteroviruses.

Characterization of two kinds of subgenomic RNAs produced by citrus leaf blotch virus

Citrus leaf blotch virus (CLBV) has a single-stranded, positive-sense, genomic RNA (gRNA) organized in three ORFs, which encode a polyprotein involved in replication (RP), a potential movement protein (MP), and coat protein (CP). Northern blot hybridization of total, virion, or double-stranded RNA with probes of different gRNA regions revealed that CLBV produces two 3'-coterminal and two 5'-coterminal subgenomic RNAs (sgRNAs). The 3'-coterminal sgRNAs contain the MP (3'MP sgRNA) and CP (3'CP sgRNA) genes and untranslated regions (UTRs) of 123 and 284 nt, respectively, at their 5' end. These sgRNAs start with a hexanucleotide which is also present at the 5' terminus of the gRNA. The 5'-coterminal sgRNAs have 6795 and 5798 nt, colinear with the gRNA, and contain ORF1 and most MP gene (5'RPMP sgRNA) and most ORF1 (5'RP sgRNA), respectively. Their 3' termini map 35 and 40 nt upstream of the transcription initiation of the 3'CP and 3'MP sgRNAs, respectively, next to a potential promoter element. Our results suggest that, as in alphaviruses, CLBV internal genes are expressed via 3'-coterminal sgRNAs transcribed from the minus gRNA strand. The 5'-coterminal sgRNAs may result from early termination of the gRNA during the plus-strand synthesis.

Characterization of the cis-acting elements controlling subgenomic mRNAs of citrus tristeza virus: production of positive- and negative-stranded 3'-terminal and positive-stranded 5'-terminal RNAs

Citrus tristeza virus (CTV), a member of the Closteroviridae, has an approximately 20-kb positive-sense RNA genome with two 5' ORFs translated from the genomic RNA and 10 3' genes expressed via nine or ten 3'-terminal subgenomic (sg) RNAs. The expression of the 3' genes appears to have properties intermediate between the smaller viruses of the "alphavirus supergroup" and the larger viruses of the Coronaviridae. The sgRNAs are contiguous with the genome, without a common 5' leader, and are associated with large amounts of complementary sgRNAs. Production of the different sgRNAs is regulated temporally and quantitatively, with the highly expressed genes having noncoding regions (NCR) 5' of the ORFs. The cis-acting elements that control the highly expressed major coat protein (CP) gene and the intermediately expressed minor coat protein (CPm) gene were mapped and compared. Mutational analysis showed that the CP sgRNA controller element mapped within nts -47 to -5 upstream of the transcription start site, entirely within the NCR, while the CPm control region mapped within a 57 nt sequence within the upstream ORF. Although both regions were predicted to fold into two stem-loop structures, mutagenesis suggested that primary structure might be more important than the secondary structure. Because each controller element produced large amounts of 3'-terminal positive- and negative-stranded sgRNAs, we could not differentiate whether the cis-acting element functioned as a promoter or terminator, or both. Reversal of the control element unexpectedly produced large amounts of a negative-stranded sgRNA apparently by termination of negative-stranded genomic RNA synthesis. Further examination of controller elements in their native orientation showed normal production of abundant amounts of positive-stranded sgRNAs extending to near the 5'-terminus, corresponding to termination at each controller element. Thus, each controller element produced three sgRNAs, a 5'-terminal positive strand and both positive- and negative-stranded 3'-terminal RNAs. Therefore, theoretically CTV could produce 30-33 species of RNAs in infected cells.

5'-coterminal subgenomic RNAs in citrus tristeza virus-infected cells

Three unusual 5' coterminal positive-stranded subgenomic (sg) RNAs, two of about 0.8 kb and one of 10 kb (designated LMT1, LMT2, and LaMT, respectively), from Citrus spp. plants and Nicotiana benthamiana protoplasts infected with Citrus tristeza virus (CTV) were characterized. The 5' termini of the LMT RNAs were mapped by runoff reverse transcription and found to correspond with the 5' terminus of the genomic RNA. The LMT 5'-coterminal sgRNAs consisted of two modal lengths of 744--746 and 842--854 nts. The 3' of the LaMT RNAs terminated near the junction of ORF 1b and ORF 2 (p33). None of the 5' sgRNAs had detectable amounts of corresponding negative-sense RNAs, as occurs with the genomic and 3' coterminal subgenomic RNAs of CTV. The abundance of the short and long 5' sgRNAs differed considerably in infected cells. The LMT RNAs were considerably more abundant than the genomic RNAs, while the larger LaMT RNA accumulated to much lower levels. The kinetics of accumulation of LMT1 and LMT2 in synchronously infected protoplasts differed. The larger RNA, LMT1, accumulated earlier with a strong hybridization signal at 2 days postinfection, a time when only traces of genomic and 3' sgRNAs were detected. The lack of corresponding RNAs, that could be 3' cleavage products corresponding to the 5' coterminal sgRNAs and the lack of complementary negative strands, suggest that these sgRNAs were produced by termination during the synthesis of the genomic positive strands.

Sequence requirements for Sindbis virus subgenomic mRNA promoter function in cultured cells

The Sindbis virus minimal subgenomic mRNA promoter (spanning positions -19 to +5 relative to the subgenomic mRNA start site) is approximately three- to sixfold less active than the fully active -98 to +14 promoter region. We identified two elements flanking the -19 to +5 region which increase its transcription to levels comparable to the -98 to +14 region. These elements span positions -40 to -20 and +6 to +14 and act synergistically to enhance transcription. Nine different virus libraries were constructed containing blocks of five randomized nucleotides at various positions in the -40 to +14 region. On passaging these libraries in mosquito cells, a small subset of the viruses came to dominate the population. Sequence analysis at the population level and for individual clones revealed that in general, wild-type bases were preferred for positions -15 to +5 of the minimal promoter. Base mutagenesis experiments indicated that the selection of wild-type bases in this region was primarily due to requirements for subgenomic mRNA transcription. Outside of the minimal promoter, the -35 to -29 region contained four positions which also preferred wildtype bases. However, the remaining positions generally preferred non-wild-type bases. On passaging of the virus libraries on hamster cells, the -15 to +5 region again preferred the wild-type base but most of the remaining positions exhibited almost no base preference. The promoter thus consists of an essential central region from -15 to +5 and discrete flanking sites that render it fully active, depending on the host environment.