Alfalfa mosaic virus temperature-sensitive mutants. V. The nucleotide sequence of TBTS 7 RNA 3 shows limited nucleotide changes and evidence for heterologous recombination

Evidence that the linker between the methyltransferase and helicase domains of potato virus X replicase is involved in homologous RNA recombination

Recombination in RNA viruses, one of the main factors contributing to their genetic variability and evolution, is a widespread phenomenon. In this study, an in vivo assay to characterize RNA recombination in potato virus X (PVX), under high selection pressure, was established. Agrobacterium tumefaciens was used to express in Nicotiana benthamiana leaf tissue both a PVX isolate labeled with green fluorescent protein (GFP) containing a coat protein deletion mutation (DeltaCP) and a transcript encoding a functional coat protein +3'-ntr. Coexpression of the constructs led to virus movement and systemic infection; reconstituted recombinants were observed in 92% of inoculated plants. Similar results were obtained using particle bombardment, demonstrating that recombination mediated by A. tumefaciens was not responsible for the occurrence of PXC recombinants. The speed of recombination could be estimated by agroinfection of two PVX mutants lacking the 3' and 5' halves of the genome, respectively, with an overlap in the triple gene block 1 gene, allowing GFP expression only in the case of recombination. Ten different pentapeptide insertion scanning replicase mutants with replication abilities comparable to wild-type virus were applied in the different recombination assays. Two neighboring mutants affecting the linker between the methyltransferase and helicase domains were shown to be strongly debilitated in their ability to recombine. The possible functional separation of replication and recombination in the replicase molecule supports the model that RNA recombination represents a distinct function of this protein, although the underlying mechanism still needs to be investigated.

Efficient in vitro system of homologous recombination in brome mosaic bromovirus

Recent in vivo studies have revealed that the subgenomic promoter (sgp) in brome mosaic bromovirus (BMV) RNA3 supports frequent homologous recombination events (R. Wierzchoslawski, A. Dzianott, and J. Bujarski, J. Virol. 78:8552-8564, 2004). In this paper, we describe an sgp-driven in vitro system that supports efficient RNA3 crossovers. A 1:1 mixture of two (-)-sense RNA3 templates was copied with either a BMV replicase (RdRp) preparation or recombinant BMV protein 2a. The BMV replicase enzyme supported a lower recombination frequency than 2a, demonstrating a role of other viral and/or host factors. The described in vitro system will allow us to study the mechanism of homologous RNA recombination.

In vitro characterization of late steps of RNA recombination in turnip crinkle virus. I. Role of motif1-hairpin structure

Molecular mechanisms of RNA recombination were studied in turnip crinkle carmovirus (TCV), which has a uniquely high recombination frequency and nonrandom crossover site distribution among the recombining TCV-associated satellite RNAs. An in vitro system has been developed that includes a partially purified TCV replicase preparation (RdRp) and chimeric RNAs that resemble the putative in vivo recombination intermediates (Nagy, P. D., Zhang, C., and Simon, A. E. EMBO J. 17, 2392-2403, 1998). This system generates 3'-terminal extension products, which are analogous to the recombination end products. Efficient generation of 3'-terminal extension products depends on the presence of a hairpin structure (termed the motif1-hairpin) that possibly binds to the RdRp. Replacement of the motif1-hairpin with two separate randomized sequences resulted in a basal level of 3'-terminal extension. By using three separate constructs, each carrying similar mutations in the motif1-hairpin, we demonstrate that the role of the motif1-hairpin in 3'-terminal extension is complex and its function is influenced by flanking sequences. In addition to the mutagenesis approach, competition experiments between wild-type and mutated motif1-hairpin constructs suggest that the TCV RdRp likely recognizes the secondary and/or tertiary structure of the motif1-hairpin, while individual nucleotides play a less important role. Overall, the data shed new light into the mechanism of 3'-terminal extension by a viral RdRp that is analogous to the late steps of RNA recombination in TCV.

Dissecting RNA recombination in vitro: role of RNA sequences and the viral replicase

Molecular mechanisms of RNA recombination were studied in turnip crinkle carmovirus (TCV), which has a uniquely high recombination frequency and non-random crossover site distribution among the recombining TCV-associated satellite RNAs. To test the previously proposed replicase-driven template-switching mechanism for recombination, a partially purified TCV replicase preparation (RdRp) was programed with RNAs resembling the putative in vivo recombination intermediates. Analysis of the in vitro RdRp products revealed efficient generation of 3'-terminal extension products. Initiation of 3'-terminal extension occurred at or close to the base of a hairpin that was a recombination hotspot in vivo. Efficient generation of the 3'-terminal extension products depended on two factors: (i) a hairpin structure in the acceptor RNA region and (ii) a short base-paired region formed between the acceptor RNA and the nascent RNA synthesized from the donor RNA template. The hairpin structure bound to the RdRp, and thus is probably involved in its recruitment. The probable role of the base-paired region is to hold the 3' terminus near the RdRp bound to the hairpin structure to facilitate 3'-terminal extension. These regions were also required for in vivo RNA recombination between TCV-associated sat-RNA C and sat-RNA D, giving crucial and direct support for a replicase-driven template-switching mechanism of RNA recombination.

Comparison of the role of 5' terminal sequences of alfalfa mosaic virus RNAs 1, 2, and 3 in viral RNA replication

The 5' untranslated regions (UTRs) of the genomic RNAs 1, 2, and 3 of alfalfa mosaic virus (AMV) are 100, 54, and 345 nucleotides (nt) long, respectively, and lack extensive sequence similarity to each other. RNA 3 encodes the movement protein P3 and the coat protein and can be replicated in transgenic tobacco plants expressing the replicase proteins P1 and P2 (P12 plants). 5' Cis-acting sequences involved in RNA 3 replication have been shown to be confined to the 5' UTR. When the 5' UTR of RNA 3 was replaced by the 5' UTRs of RNAs 1 or 2, the recombinant RNA was not infectious to P12 plants. Also, when the P3 gene in RNA 3 was put under the control of a subgenomic promoter and the 5' UTR of this RNA was replaced by 5' terminal RNA 1 sequences of 103 to 860 nt long or RNA 2 sequences of 57 to 612 nt long, no accumulation of the hybrid RNAs was observed. Deletion of the 5' 22 nucleotides of RNA 3 resulted in the accumulation of a major progeny that lacked the 5' 79 nt. However, when the 5' 22 nucleotides of RNA 3 were replaced by the complete 5' UTR of RNA 1 or 5' sequences of RNAs 1, 2, or 3 with a length of 5 to 15 nt, accumulation of the full-length mutant RNAs was observed. The effect of mutations in the 5' viral sequences of 5 to 15 nt was analyzed. It is concluded that although elements within nucleotides 80-345 of the 5' UTR of RNA 3 are sufficient for replication, a specific sequence of 3 to 5 nt is required to target the replicase to an initiation site corresponding to the 5' end of the RNA.

Molecular studies of genetic RNA-RNA recombination in brome mosaic virus

It is well known that DNA-based organisms rearrange and repair their genomic DNA through recombination processes, and that these rearrangements serve as a powerful source of variability and adaptation for these organisms. In RNA viruses' genetic recombination is defined as any process leading to the exchange of information between viral RNAs. There are two types of recombination events: legitimate and illegitimate. While legitimate (homologous) recombination occurs between closely related sequences at corresponding positions, illegitimate (nonhomologous) recombination could happen at any position among the unrelated RNA molecules. In order to differentiate between the symmetrical and asymmetrical homologous crosses, Lai defined the former as homologous recombination and the latter as aberrant homologous recombination. This chapter uses brome mosaic virus (BMV), a multicomponent plant RNA virus, as an example to discuss the progress in studying the mechanism of genetic recombination in positive-stranded RNA viruses. Studies described in this chapter summarize the molecular approaches used to increase the frequency of recombination among BMV RNA segments and, more importantly, to target the sites of crossovers to specific BMV RNA regions. It demonstrates that the latter can be accomplished by introducing local complementarities to the recombining substrates.

Structural requirements for efficient translational frameshifting in the synthesis of the putative viral RNA-dependent RNA polymerase of potato leafroll virus

The putative RNA-dependent RNA polymerase of potato leafroll luteovirus (PLRV) is expressed by -1 ribosomal frameshifting in the region where the open reading frames (ORF) of proteins 2a and 2b overlap. The signal responsible for efficient frameshift is composed of the slippery site UUUAAAU followed by a sequence that has the potential to adopt two alternative folding patterns, either a structure involving a pseudoknot, or a simple stem-loop structure. To investigate the structure requirements for efficient frameshifting, mutants in the stem-loop or in the potential pseudoknot regions of a Polish isolate of PLRV (PLRV-P) have been analyzed. Mutations that are located in the second stem (S2) of the potential pseudoknot structure, but are located in unpaired regions of the alternative stem-loop structure, reduce frameshift efficiency. Deletion of the 3' end sequence of the alternative stem-loop structure does not reduce frameshift efficiency. Our results confirm that -1 frameshift in the overlap region depends on the slippery site and on the downstream positioned sequence, and propose that in PLRV-P a pseudoknot is required for efficient frameshifting. These results are in agreement with those recently published for the closely related beet western yellows luteovirus (BWYV).

Genetic recombination in brome mosaic virus: effect of sequence and replication of RNA on accumulation of recombinants

In order to facilitate the isolation of recombinants in brome mosaic virus, a series of duplication mutants with alterations in the RNA3 3' noncoding region has been engineered. The distribution of crossovers, which was observed to be dependent on the parental RNA3 sequence, supported the role of RNA structure in recombination. However, a negative correlation between replication of the parental RNA3 constructs and the accumulation of recombinant progeny confirmed the role of selection.

RNA recombination in animal and plant viruses

An increasing number of animal and plant viruses have been shown to undergo RNA-RNA recombination, which is defined as the exchange of genetic information between nonsegmented RNAs. Only some of these viruses have been shown to undergo recombination in experimental infection of tissue culture, animals, and plants. However, a survey of viral RNA structure and sequences suggests that many RNA viruses were derived form homologous or nonhomologous recombination between viruses or between viruses and cellular genes during natural viral evolution. The high frequency and widespread nature of RNA recombination indicate that this phenomenon plays a more significant role in the biology of RNA viruses than was previously recognized. Three types of RNA recombination are defined: homologous recombination; aberrant homologous recombination, which results in sequence duplication, insertion, or deletion during recombination; and nonhomologous (illegitimate) recombination, which does not involve sequence homology. RNA recombination has been shown to occur by a copy choice mechanism in some viruses. A model for this recombination mechanism is presented.

Generation and analysis of nonhomologous RNA-RNA recombinants in brome mosaic virus: sequence complementarities at crossover sites

All three single-stranded RNAs of the brome mosaic virus (BMV) genome contain a highly conserved, 193-base 3' noncoding region. To study the recombination between individual BMV RNA components, barley plants were infected with a mixture of in vitro-transcribed wild-type BMV RNAs 1 and 2 and an RNA3 mutant that carried a deletion near the 3' end. This generated a population of both homologous and nonhomologous 3' recombinant BMV RNA3 variants. Sequencing revealed that these recombinants were derived by either single or double crossovers with BMV RNA1 or RNA2. The primary sequences at recombinant junctions did not show any similarity. However, they could be aligned to form double-stranded heteroduplexes. This suggested that local hybridizations among BMV RNAs may support intermolecular exchanges.

Role of alfalfa mosaic virus coat protein gene in symptom formation

On Samsun NN tobacco plants strains 425 and YSMV of alfalfa mosaic virus (AIMV) cause mild chlorosis and local necrotic lesions, respectively. DNA copies of RNA3 of both strains were transcribed in vitro into infectious RNA molecules. When the 425 and YSMV transcripts were inoculated to tobacco plants transformed with DNA copies of AIMV RNAs 1 and 2, they induced symptoms indistinguishable from those of the corresponding parent strains. Exchange of restriction fragments between the infectious clones showed that symptom expression was determined by the coat protein gene in RNA3. The sequence of YSMV RNA3 was determined and compared with the known sequence of 425 RNA3. When the codon for Gln-29 in the coat protein of strain 425 was mutated into the Arg codon present at this position in strain YSMV, the symptoms induced by the transcript on inoculated leaves changed from chlorosis to necrosis. Genetic determinants for the systemic response were more complex.

Relationships among the positive strand and double-strand RNA viruses as viewed through their RNA-dependent RNA polymerases

The sequences of 50 RNA-dependent RNA polymerases (RDRPs) from 43 positive strand and 7 double strand RNA (dsRNA) viruses have been compared. The alignment permitted calculation of distances among the 50 viruses and a resultant dendrogram based on every amino acid, rather than just those amino acids in the conserved motifs. Remarkably, a large subgroup of these viruses, including vertebrate, plant, and insect viruses, forms a single cluster whose only common characteristic is exploitation of insect hosts or vectors. This similarity may be due to molecular constraints associated with a present and/or past ability to infect insects and/or to common descent from insect viruses. If common descent is important, as it appears to be, all the positive strand RNA viruses of eucaryotes except for the picornaviruses may have evolved from an ancestral dsRNA virus. Viral RDRPs appear to be inherited as modules rather than as portions of single RNA segments, implying that RNA recombination has played an important role in their dissemination.