Two types of non-homologous RNA recombination in brome mosaic virus

Non-homologous RNA recombination is a process enabling the exchange of genetic material between various (related or unrelated) RNA-based viruses. Despite extensive investigations its molecular mechanism remains unclear. Studies on genetic recombination in brome mosaic virus (BMV) have shown that local hybridization between genomic RNAs induces frequent non-homologous crossovers. A detailed analysis of recombinant structures suggested that local complementary regions might be involved in two types of non-homologous recombination in BMV: site-specific and heteroduplex-mediated. To verify the above hypothesis and better recognize the mechanism of the phenomenon studied we have tested how the putative types of recombination are affected by a specific mutation in the BMV polymerase gene or by changes in RNA structure. The experiments undertaken revealed substantial differences between site-specific and heteroduplex-mediated recombination, indicating that they occur according to different mechanisms. The former can be classified as homology-assisted, and the latter as homology-independent. In addition to local RNA/RNA hybridization, short regions of homology are required for site-specific crossovers to occur. They are most efficiently mediated if one homologous sequence is located at the beginning of and the second just before a double-stranded region. At present it is difficult to state what is the mechanism of heteroduplex-mediated recombination. Earlier it was postulated that strong RNA/RNA interaction enforces template switching by the viral replicase. There are, however, several observations questioning this model and indicating that some other factors, which are still unknown, may influence heteroduplex-mediated crossovers.     

RNA recombination in brome mosaic virus: effects of strand-specific stem-loop inserts

A model system of a single-stranded trisegment Brome mosaic bromovirus (BMV) was used to analyze the mechanism of homologous RNA recombination. Elements capable of forming strand-specific stem-loop structures were inserted at the modified 3' noncoding regions of BMV RNA3 and RNA2 in either positive or negative orientations, and various combinations of parental RNAs were tested for patterns of the accumulating recombinant RNA3 components. The structured negative-strand stem-loops that were inserted in both RNA3 and RNA2 reduced the accumulation of RNA3-RNA2 recombinants to a much higher extent than those in positive strands or the unstructured stem-loop inserts in either positive or negative strands. The use of only one parental RNA carrying the stem-loop insert reduced the accumulation of RNA3-RNA2 recombinants even further, but only when the stem-loops were in negative strands of RNA2. We assume that the presence of a stable stem-loop downstream of the landing site on the acceptor strand (negative RNA2) hampers the reattachment and reinitiation processes. Besides RNA3-RNA2 recombinants, the accumulation of nontargeted RNA3-RNA1 and RNA3-RNA3 recombinants were observed. Our results provide experimental evidence that homologous recombination between BMV RNAs more likely occurs during positive- rather than negative-strand synthesis.     

Homologous RNA recombination in brome mosaic virus: AU-rich sequences decrease the accuracy of crossovers.

Brome mosaic virus, a tripartite positive-stranded RNA virus of plants, was used for the determination of sequence requirements of imprecise (aberrant) homologous recombination. A 23-nucleotide (nt) region that included a 6-nt UUAAAA sequence (designated the AU sequence) common between wild-type RNA2 and mutant RNA3 supported both precise and imprecise homologous recombination, though the latter occurred with lower frequency. Doubling the length of the 6-nt AU sequence in RNA3 increased the incidence of imprecise crossovers by nearly threefold. Duplication or triplication of the length of the AU sequence in both RNA2 and RNA3 further raised the frequency of imprecise crossovers. The majority of imprecise crosses were located within or close to the extended AU sequence. Imprecise recombinants contained either nucleotide substitutions, nontemplated nucleotides, small deletions, or small sequence duplications within the region of crossovers. Deletion of the AU sequence from the homologous region in RNA3 resulted in the accumulation of only precise homologous recombinants. Our results provide experimental evidence that AU sequences can facilitate the formation of imprecise homologous recombinants. The generation of small additions or deletions can be explained by a misannealing mechanism within the AU sequences, while replicase errors during RNA copying might explain the occurrence of nucleotide substitutions or nontemplated nucleotides.     

Role of RNA structure in non-homologous recombination between genomic molecules of brome mosaic virus

Brome mosaic virus (BMV) is a tripartite genome, positive-sense RNA virus of plants. Previously it was demonstrated that local hybridization between BMV RNAs (RNA–RNA heteroduplex formation) efficiently promotes non-homologous RNA recombination. In addition, studies on the role of the BMV polymerase in RNA recombination suggested that the location of non-homologous crossovers depends mostly on RNA structure. As a result, a detailed analysis of a large number of non-homologous recombinants generated in the BMV-based system was undertaken. Recombination hot-spots as well as putative elements in RNA structure enhancing non-homologous crossovers and targeting them in a site-specific manner were identified. To verify these observations the recombinationally active sequence in BMV RNA3 derivative was modified. The results obtained with new RNA3 mutants suggest that the primary and secondary structure of the sequences involved in a heteroduplex formation rather than the length of heteroduplex plays the most important role in the recombination process. The presented data indicate that the sequences proximal to the heteroduplex may also affect template switching by BMV replicase. Moreover, it was shown that both short homologous sequences and a hairpin structure have to accompany a double-stranded region to target non-homologous crossovers in a site-specific manner.     

Engineering of homologous recombination hotspots with AU-rich sequences in brome mosaic virus.

Previously, we observed that crossovers sites of RNA recombinants clustered within or close to AU-rich regions during genetic recombination in brome mosaic bromovirus (BMV) (P. D. Nagy and J. J. Bujarski. J. Virol. 70:415-426, 1996). To test whether AU-rich sequences can facilitate homologous recombination, AU-rich sequences were introduced into parental BMV RNAs (RNA2 and RNA3). These insertions created a homologous RNA2-RNA3 recombination hotspot. Two other AU-rich sequences also supported high-frequency homologous recombination if a common sequence with high or average G/C content was present immediately upstream of the AU-rich element. Homologous RNA recombination did not require any additional sequence motifs or RNA structures and was position nonspecific within the 3' noncoding region. These results suggest that nucleotide content (i.e., the presence of common 5' GC-rich or moderately AU-rich and 3' AU-rich regions) is the important factor that determines the sites of homologous recombination. A mechanism that involves replicase switching during synthesis of positive-sense RNA strands is presented to explain the observed results.     

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.     

Mutational analysis of the sequence and structural requirements in brome mosaic virus RNA for minus strand promoter activity

An RNA-dependent RNA polymerase (replicase) activity that specifically copies brome mosaic virus (BMV) RNAs in vitro can be prepared from BMV-infected barley leaves. The signals directing complementary (minus) strand synthesis reside within the 3' 134-nucleotide-long tRNA-like structure that is common to each of the virion RNAs. By studying the influence of minus strand synthesis of numerous mutations introduced throughout this region of the RNA, we have mapped in detail the sequence and structural elements necessary for minus strand promoter activity. Sequence alterations (either substitutions or small, structurally discrete deletions) in most parts of the tRNA-like structure resulted in decreased minus strand synthesis. This suggests that BMV replicase is a large enzyme, possibly composed of several subunits. The lowest activities, 5 to 8% of wild type, were observed for mutants with substitutions at three separate loci, identifying one structural and two sequence-specific elements essential for optimal promoter activity. (1) Destabilization of the pseudoknot structure in the aminoacyl acceptor stem resulted in low promoter activity, demonstrating the importance of a tRNA-like conformation. (2) Substitution of the C residue adjacent to the 3' terminus resulted in low promoter activity, probably by interfering with strand initiation. (3) The low activities resulting from substitutions and a small deletion in arm C suggest this region of the RNA to be a major feature involved in replicase binding. In particular, nucleotides within the loop of arm C appear to be involved in a sequence-specific interaction with the replicase.     

Efficient system of homologous RNA recombination in brome mosaic virus: sequence and structure requirements and accuracy of crossovers.

Brome mosaic virus (BMV), a tripartite positive-stranded RNA virus of plants engineered to support intersegment RNA recombination, was used for the determination of sequence and structural requirements of homologous crossovers. A 60-nucleotide (nt) sequence, common between wild-type RNA2 and mutant RNA3, supported efficient repair (90%) of a modified 3' noncoding region in the RNA3 segment by homologous recombination with wild-type RNA2 3' noncoding sequences. Deletions within this sequence in RNA3 demonstrated that a nucleotide identity as short as 15 nt can support efficient homologous recombination events, while shorter (5-nt) sequence identity resulted in reduced recombination frequency (5%) within this region. Three or more mismatches within a downstream portion of the common 60-nt RNA3 sequence affected both the incidence of recombination and the distribution of crossover sites, suggesting that besides the length, the extent of sequence identity between two recombining BMV RNAs is an important factor in homologous recombination. Site-directed mutagenesis of the common sequence in RNA3 did not reveal a clear correlation between the stability of predicted secondary structures and recombination activity. This indicates that homologous recombination does not require similar secondary structures between two recombining RNAs at the sites of crossovers. Nearly 20% of homologous recombinants were imprecise (aberrant), containing either nucleotide mismatches, small deletions, or small insertions within the region of crossovers. This implies that homologous RNA recombination is not as accurate as proposed previously. Our results provide experimental evidence that the requirements and thus the mechanism of homologous recombination in BMV differ from those of previously described heteroduplex-mediated nonhomologous recombination (P. D. Nagy and J. J. Bujarski, Proc. Natl. Acad. Sci. USA 90:6390-6394, 1993).     

Cucumber mosaic virus, a model for RNA virus evolution

Taxonomic relationships: Cucumber mosaic virus (CMV) is the type member of the Cucumovirus genus, in the family Bromoviridae . Additional members of the genus are Peanut stunt virus (PSV) and Tomato aspermy virus (TAV). The RNAs 3 of all members of the genus can be exchanged and still yield a viable virus, while the RNAs 1 and 2 can only be exchanged within a species.
Physical properties: The virus particles are about 29 nm in diameter, and are composed of 180 subunits (T = 3 icosahedral symmetry). The particles sediment with an s value of approximately 98. The virions contain 18% RNA, and are highly labile, relying on RNA–protein interactions for their integrity. The three genomic RNAs, designated RNA 1 (3.3 kb in length), RNA 2 (3.0 kb) and RNA 3 (2.2 kb) are packaged in individual particles; a subgenomic RNA, RNA 4 (1.0 kb), is packaged with the genomic RNA 3, making all the particles roughly equivalent in composition. In some strains an additional subgenomic RNA, RNA 4A is also encapsidated at low levels. The genomic RNAs are single stranded, plus sense RNAs with 5' cap structures, and 3' conserved regions that can be folded into tRNA-like structures.
Satellite RNAs: CMV can harbour molecular parasites known as satellite RNAs (satRNAs) that can dramatically alter the symptom phenotype induced by the virus. The CMV satRNAs do not encode any proteins but rely on the RNA for their biological activity.
Hosts: CMV infects over 1000 species of hosts, including members of 85 plant families, making it the broadest host range virus known. The virus is transmitted from host to host by aphid vectors, in a nonpersistent manner.
Useful web sites: http://mmtsb.scripps.edu/viper/1f15.html (structure); http://www.ncbi.nlm.nih.gov/ICTVdb/ICTVdB/10040001.htm (general information)     

Packaging of brome mosaic virus RNA3 is mediated through a bipartite signal

The three genomic and a single subgenomic RNA of brome mosaic virus (BMV), an RNA virus infecting plants, are packaged by a single-coat protein (CP) into three morphologically indistinguishable icosahedral virions with T = 3 quasi-symmetry. Genomic RNAs 1 and 2 are packaged individually into separate particles whereas genomic RNA3 and subgenomic RNA4 (coat protein mRNA) are copackaged into a single particle. We report here that packaging of dicistronic RNA3 requires a bipartite signal. A highly conserved 3' tRNA-like structure postulated to function as a nucleating element (NE) for CP subunits (Y. G. Choi, T. W. Dreher, and A. L. N. Rao, Proc. Natl. Acad. Sci. USA 99:655-660, 2002) and a cis-acting, position-dependent packaging element (PE) of 187 nt present in the nonstructural movement protein gene are the integral components of the packaging core. Efficient incorporation into BMV virions of nonviral RNA chimeras containing NE and the PE provides confirmatory evidence that these two elements are sufficient to direct packaging. Analysis of virion RNA profiles obtained from barley protoplasts transfected with a RNA3 variant lacking the PE provides the first genetic evidence that de novo synthesized RNA4 is incompetent for autonomous assembly whereas prior packaging of RNA3 is a prerequisite for RNA4 to copackage.     

Different mechanisms of homologous and nonhomologous recombination in brome mosaic virus: role of RNA sequences and replicase proteins

Brome mosaic bromovirus, a tripartite, positive-stranded RNA virus of plants, can generate both homologous and nonhomologous recombinantsin vivo. Recombination signals in the RNAs were different for these two recombination types. Nonhomologous recombination requires the formation of local double-stranded regions between the RNA templates. In contrast, homologous recombination is facilitated by AU-rich sequences and upstream GC-rich regions common in the recombining RNAs. Mutations within the replicase proteins affect homologous and nonhomologous recombination in different ways, confirming the involvement of BMV replicase proteins in both types of events as well as the differences in their pathways. Replicase-driven template-switching models are discussed in relation to supporting evidences.     

Selective repression of translation by the brome mosaic virus 1a RNA replication protein

Differential expression of viral replication proteins is essential for successful infection. We report here that overexpression of the brome mosaic virus (BMV) 1a protein can repress viral RNA replication in a dosage-dependent manner. Using RNA replication-incompetent reporter constructs, repression of translation from BMV RNA1 and RNA2 was observed, suggesting that the effect on translation of the BMV RNA replication proteins is responsible for the decrease in RNA levels. Furthermore, repression of translation by 1a required the B box in the 5'-untranslated region (5' UTR); BMV RNA3 that lacks a B box in its 5' UTR is not subject to 1a-mediated translational inhibition. Mutations in either the methyltransferase or the helicase-like domains of 1a reduced the repression of replication and translation. These results suggest that in addition to its known functions in BMV RNA synthesis, 1a also regulates viral gene expression.     

Stable RNA structures can repress RNA synthesis in vitro by the brome mosaic virus replicase

A 15-nucleotide (nt) unstructured RNA with an initiation site but lacking a promoter could direct the initiation of RNA synthesis by the brome mosaic virus (BMV) replicase in vitro. However, BMV RNA with a functional initiation site but a mutated promoter could not initiate RNA synthesis either in vitro or in vivo. To explain these two observations, we hypothesize that RNA structures that cannot function as promoters could prevent RNA synthesis by the BMV RNA replicase. We documented that four different nonpromoter stem-loops can inhibit RNA synthesis from an initiation-competent RNA sequence in vitro. Destabilizing these structures increased RNA synthesis. However, RNA synthesis was restored in full only when a BMV RNA promoter element was added in cis. Competition assays to examine replicase-RNA interactions showed that the structured RNAs have a lower affinity for the replicase than do RNAs lacking stable structures or containing a promoter element. The results characterize another potential mechanism whereby the BMV replicase can specifically recognize BMV RNAs.     

Pressure-induced dissociation of brome mosaic virus

Brome mosaic virus reversibly dissociates into subunits in the pressure range of 600 x 10(5) to 1600 x 10(5) Pa, as demonstrated by studies of the spectral shift of intrinsic fluorescence, of filtration chromatography and of electron microscopy of samples fixed under pressure. Smaller shell particles (T = 1) were detected as intermediates in the dissociation pathway. Dissociation was facilitated by decreasing the concentration, as expected for a multimolecular reaction. The estimated change in volume upon dissociation into 90 dimer particles was -2960 ml/mol. Large increases in the intrinsic fluorescence intensity and in the binding of bis(8-anilinonaphthalene-1-sulfonate) occurred at pressures higher than 1400 x 10(5) Pa. The pressure-dependence profile of the different spectral properties shifted to lower pressures when 5 mM-MgCl2 was included in the buffer or when the pH was raised from 5.5 to 5.9. When the pressure was progressively increased above 1400 x 10(5) Pa, a value that led to 75% dissociation, the capsid subunits lost the ability to reassociate into regular shells and only amorphous aggregates were formed after decompression, as evidenced by both electron microscopy and gel filtration chromatography. The formation of these random aggregates of brome mosaic virus can be explained by a conformational drift of the separated subunits, similar in nature to that found in simpler oligomeric proteins.     

Evolutionary relationship of alfalfa mosaic virus with cucumber mosaic virus and brome mosaic virus

The amino acid sequences of the non-structural protein (molecular weight 35,000; 3a protein) from three plant viruses — cucumber mosaic, brome mosaic and alfalfa mosaic have been systematically compared using the partial genomic sequences for these three viruses already available. The 3a protein of cucumber mosaic virus has an amino acid sequence homology of 33.7% with the corresponding protein of brome mosaic virus. A similar protein from alfalfa mosaic virus has a homology of 18.2% and 14.2% with the protein from brome mosaic virus and cucumber mosaic virus, respectively. These results suggest that the three plant viruses are evolutionarily related, although, the evolutionary distance between alfalfa mosaic virus and cucumber mosaic virus or brome mosaic virus is much larger than the corresponding distance between the latter two viruses.