Requirements for brome mosaic virus subgenomic RNA synthesis in vivo and replicase-core promoter interactions in vitro.

Based solely on in vitro results, two contrasting models have been proposed for the recognition of the brome mosaic virus (BMV) subgenomic core promoter by the replicase. The first posits that the replicase recognizes at least four key nucleotides in the core promoter, followed by an induced fit, wherein some of the nucleotides base pair prior to the initiation of RNA synthesis (S. Adkins and C. C. Kao, Virology 252:1-8, 1998). The second model posits that a short RNA hairpin in the core promoter serves as a landing pad for the replicase and that at least some of the key nucleotides help form a stable hairpin (P. C. J. Haasnoot, F. Brederode, R. C. L. Olsthoorn, and J. Bol, RNA 6:708-716, 2000; P. C. J. Haasnoot, R. C. L. Olsthoorn, and J. Bol, RNA 8:110-122, 2002). We used transfected barley protoplasts to examine the recognition of the subgenomic core promoter by the BMV replicase. Key nucleotides required for subgenomic initiation in vitro were found to be important for RNA4 levels in protoplasts. In addition, additional residues not required in vitro and the formation of an RNA hairpin within the core promoter were correlated with wild-type RNA4 levels in cells. Using a template competition assay, the core promoter of ca. 20 nucleotides was found to be sufficient for replicase binding. Mutations of the key residues in the core promoter reduced replicase binding, but deletions that disrupt the predicted base pairing in the proposed stem retained binding at wild-type levels. Together, these results indicate that key nucleotides in the BMV subgenomic core promoter direct replicase recognition but that the formation of a stem-loop is required at a step after binding. Additional functional characterization of the subgenomic core promoter was performed. A portion of the promoter for BMV minus-strand RNA synthesis could substitute for the subgenomic core promoter in transfected cells. The comparable sequence from Cowpea Chlorotic Mottle Virus (CCMV) could also substitute for the BMV subgenomic core promoter. However, nucleotides in the CCMV core required for RNA synthesis are not identical to those in BMV, suggesting that the subgenomic core promoter can induce the BMV replicase in interactions needed for subgenomic RNA transcription in vivo.

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.

Brome mosaic virus RNA syntheses in vitro and in barley protoplasts.

The RNA replicase extracted from Brome mosaic virus (BMV)-infected plants has been used to characterize the cis-acting elements for RNA synthesis and the mechanism of RNA synthesis. Minus-strand RNA synthesis in vitro requires a structure named stem-loop C (SLC) that contains a clamped adenine motif. In vitro, there are several specific requirements for SLC recognition. We examined whether these requirements also apply to BMV replication in barley protoplasts. BMV RNA3s with mutations in SLC were transfected into barley protoplasts, and the requirements for minus- and plus-strand replication were found to correlate well with the requirements in vitro. Furthermore, previous analysis of replicase recognition of the Cucumber mosaic virus (CMV) and BMV SLCs indicates that the requirements in the BMV SLC are highly specific. In protoplasts, we found that BMV RNA3s with their SLCs replaced with two different CMV SLCs were defective for replication. In vitro results generated with the BMV replicase and minimal-length RNAs generally agreed with those of in vivo BMV RNA replication. To extend this conclusion, we determined that, corresponding with the process of infection, the BMV replicases extracted from plants at different times after infection have different levels of recognition of the minimal promoters for plus- and minus-strand RNA syntheses.

Core promoter for initiation of Cucumber mosaic virus subgenomic RNA4A.

summary The core subgenomic promoter for the initiation of Cucumber mosaic virus (CMV) RNA4A was characterized in vitro using a template-dependent RNA synthesis assay and variants of the core promoter RNAs. The minimal sequence required for specific initiation from the cytidylate (T1) used in vivo consists of 31-nucleotides (nt) 3' of T1 and a 13 nt template sequence. This 44 nt RNA was found to provide three elements that contribute to efficient initiation of RNA4A synthesis by the CMV replicase: a stem-loop secondary structure 3' of T1, a template sequence that is rich in adenylates and uridylates, and T1 in an unbase-paired sequence.

Recognition of the core RNA promoter for minus-strand RNA synthesis by the replicases of Brome mosaic virus and Cucumber mosaic virus.

Replication of viral RNA genomes requires the specific interaction between the replicase and the RNA template. Members of the Bromovirus and Cucumovirus genera have a tRNA-like structure at the 3' end of their genomic RNAs that interacts with the replicase and is required for minus-strand synthesis. In Brome mosaic virus (BMV), a stem-loop structure named C (SLC) is present within the tRNA-like region and is required for replicase binding and initiation of RNA synthesis in vitro. We have prepared an enriched replicase fraction from tobacco plants infected with the Fny isolate of Cucumber mosaic virus (Fny-CMV) that will direct synthesis from exogenously added templates. Using this replicase, we demonstrate that the SLC-like structure in Fny-CMV plays a role similar to that of BMV SLC in interacting with the CMV replicase. While the majority of CMV isolates have SLC-like elements similar to that of Fny-CMV, a second group displays sequence or structural features that are distinct but nonetheless recognized by Fny-CMV replicase for RNA synthesis. Both motifs have a 5'CA3' dinucleotide that is invariant in the CMV isolates examined, and mutational analysis indicates that these are critical for interaction with the replicase. In the context of the entire tRNA-like element, both CMV SLC-like motifs are recognized by the BMV replicase. However, neither motif can direct synthesis by the BMV replicase in the absence of other tRNA-like elements, indicating that other features of the CMV tRNA can induce promoter recognition by a heterologous replicase.

Brome mosaic virus, good for an RNA virologist's basic needs.

Abstract Taxonomic relationship: Type member of the Bromovirus genus, family Bromoviridae. A member of the alphavirus-like supergroup of positive-sense single-stranded RNA viruses. Physical properties: Virions are nonenveloped icosahedrals made up of 180 coat protein subunits (Fig. 1). The particles are 26 nm in diameter and contain 22% nucleic acid and 78% protein. The BMV genome is composed of three positive-sense, capped RNAs: RNA1 (3.2 kb), RNA2 (2.9 kb), RNA3 (2.1 kb) (Fig. 2). Viral proteins: RNA1 encodes protein 1a, containing capping and putative RNA helicase activities. RNA2 encodes protein 2a, a putative RNA-dependent RNA polymerase. RNA3 codes for two proteins: 3a, which is required for cell-to-cell movement, and the capsid protein. The capsid is translated from a subgenomic RNA, RNA4 (1.2 kb). Hosts: Monocots in the Poacea family, including Bromus inermis, Zea mays and Hordeum vulgare, in which BMV causes brown streaks. BMV can also infect the dicots Nicotiana benthamiana and several Chenopodium species. In N. benthamiana, the infection is asymptomatic while infection of Chenopodium can cause either necrotic or chlorotic lesions. Useful website:http://www4.ncbi.nlm.nih.gov/ICTVdb/ICTVdB/10030001.htm.

Genomic plus-strand RNA synthesis by the brome mosaic virus (BMV) RNA replicase requires a sequence that is complementary to the binding site of the BMV helicase-like protein.

Summary Initiation of genomic plus-strand RNA synthesis by the brome mosaic virus (BMV) replicase in vitro requires a 26-nucleotide (nt) RNA sequence at the 3' end of the minus-strand RNA and a nontemplated nucleotide 3' of the initiation cytidylate [Sivakumaran, K. and Kao, C.C. (1999)J. Virol.64, 6415-6423]. At the 5' end of this RNA is a 9-nt sequence called the cB box, the complement of the previously defined B box. The cB box can not be functionally replaced by the B box and has specific positional and sequence requirements. The portion of the cB box that is required for RNA synthesis in vitro is well-conserved in species in the Bromoviridae family. An equivalent RNA from Cucumber mosaic virus was unable to direct efficient RNA synthesis by the BMV replicase until the cB box was positioned at the same site relative to the BMV RNA and guanylates were present at positions +6 and +7 from the initiation cytidylate. These results further define the elements required for the recognition and initiation of viral genomic plus-strand RNA synthesis and suggest that a sequence important for minus-strand RNA synthesis is also required for plus-strand RNA synthesis.

RNA sequence and secondary structural determinants in a minimal viral promoter that directs replicase recognition and initiation of genomic plus-strand RNA synthesis.

Viral RNA replication provides a useful system to study the structure and function of RNAs and the mechanism of RNA synthesis from RNA templates. Previously we demonstrated that a 27 nt RNA from brome mosaic virus (BMV) can direct correct initiation of genomic plus-strand RNA synthesis by the BMV replicase. In this study, using biochemical, nuclear magnetic resonance, and thermodynamic analyses, we determined that the secondary structure of this 27 nt RNA can be significantly altered and retain the ability to direct RNA synthesis. In contrast, we find that position-specific changes in the RNA sequence will affect replicase recognition, modulate the polymerization process, and contribute to the differential accumulation of viral RNAs. These functional results are in agreement with the phylogenetic analysis of BMV and related viral sequences and suggest that a similar mechanism of RNA synthesis takes place for members of the alphavirus superfamily.

Initiation of genomic plus-strand RNA synthesis from DNA and RNA templates by a viral RNA-dependent RNA polymerase.

In contrast to the synthesis of minus-strand genomic and plus-strand subgenomic RNAs, the requirements for brome mosaic virus (BMV) genomic plus-strand RNA synthesis in vitro have not been previously reported. Therefore, little is known about the biochemical requirements for directing genomic plus-strand synthesis. Using DNA templates to characterize the requirements for RNA-dependent RNA polymerase template recognition, we found that initiation from the 3' end of a template requires one nucleotide 3' of the initiation nucleotide. The addition of a nontemplated nucleotide at the 3' end of minus-strand BMV RNAs led to initiation of genomic plus-strand RNA in vitro. Genomic plus-strand initiation was specific since cucumber mosaic virus minus-strand RNA templates were unable to direct efficient synthesis under the same conditions. In addition, mutational analysis of the minus-strand template revealed that the -1 nontemplated nucleotide, along with the +1 cytidylate and +2 adenylate, is important for RNA-dependent RNA polymerase interaction. Furthermore, genomic plus-strand RNA synthesis is affected by sequences 5' of the initiation site.

The N-terminal half of the brome mosaic virus 1a protein has RNA capping-associated activities: specificity for GTP and S-adenosylmethionine.

The N-terminal half of the brome mosaic virus (BMV) 1a replication-associated protein contains sequence motifs found in RNA methyltransferases. We demonstrate that recombinant BMV methyltransferase-like (MT) domain expressed in Escherichia coli forms an adduct with a guanine nucleotide in a reaction that requires S-adenosylmethionine (AdoMet) and divalent cations. Moieties in GTP and AdoMet required for adduct formation were determined using a competition assay and chemical analogues. In the guanine nucleotide the ribose 2' hydroxyl, the triphosphates, the base C6 keto group, and possibly the N1 imine are required. In AdoMet, the methyl group and the ability to transfer a methyl group to guanine nucleotide were demonstrated to be required for adduct formation. The effects of methyltransferase inhibitors on viral RNA synthesis was determined using an in vitro RNA synthesis assay. These results are consistent with the previously reported activities of alphaviral nsP1 methyltransferase protein and identify the chemical moieties required for the BMV methyltransferase activity.

The 105-kDa polyprotein of southern bean mosaic virus is translated by scanning ribosomes.

The cowpea strain of southern bean mosaic virus (SBMV-C) is a positive-sense RNA virus. Three open reading frames (ORF-1, ORF2, and ORF3) are expressed from the genomic RNA. The ORF1 and ORF2 initiation codons are located at nucleotide (nt) positions 49 and 570, respectively. ORF1 is expressed by a 5' end-dependent scanning mechanism, but it is not known how ribosomes gain access to the ORF2 initiation codon. In experiments described here, it was demonstrated that the translation of ORF2 was sensitive to cap analog in a cell-free extract. In vitro and in vivo studies showed that the addition of one or more AUG codons between the 5' end of the SBMV-C RNA and the ORF2 initiation codon reduced ORF2 expression and that elimination of the ORF1 initiation codon increased ORF2 expression. Altering the sequence context of the ORF1 initiation codon to one more favorable for translation initiation also reduced ORF2 expression in vivo. Nucleotide deletions and insertions between SBMV-C nt 218-520 did not abolish ORF2 expression. In most cases, these mutations resulted in reduced expression of both ORF1 and ORF2. These results are consistent with translation of ORF2 by leaky scanning.

Identification of viral genes required for cell-to-cell movement of southern bean mosaic virus.

Inoculation of Vigna unguiculata (cowpea) with transcripts synthesized in vitro from a genome-length cDNA clone of the cowpea strain of southern bean mosaic virus (SBMV-C) resulted in a systemic SBMV-C infection of this host. Capped RNA was about five times more infectious than uncapped RNA as determined by a local lesion assay. The SBMV-C cDNA clone was also used for mutagenesis of the four SBMV-C open reading frames (ORFs). ORF1, ORF3, and coat protein (CP) mutants were not infectious in cowpea. Electroporation of cowpea protoplasts with mutant transcripts demonstrated that the ORF1, ORF3, and CP gene products were not required for SBMV-C RNA synthesis, and the ORF1 and ORF3 gene products were not required for SBMV-C assembly. From these results, it was concluded that the ORF1 and ORF3 proteins and the CP are required for SBMV-C cell-to-cell movement. One of the ORF3 mutants pSBMV2-UAA1833 contained a nonsense codon between the predicted -1 ribosomal frameshift site (SBMV-C nucleotides 1796-1802) and a potential ORF3 translation initiation codon at SBMV-C nucleotide 1895. The lack of infectivity of this mutant suggested that ORF3 was expressed by a -1 ribosomal frameshift in ORF2 rather than by initiation of translation at nucleotide 1895.

Mapping and expression of southern bean mosaic virus genomic and subgenomic RNAs.

The coat protein of the cowpea strain of southern bean mosaic sobemovirus (SBMV-C) is translated from a subgenomic RNA (sgRNA) that is synthesized in the virus-infected cell. Like the SBMV-C genomic RNA, the sgRNA has a viral protein (VPg) covalently bound to its 5' end. The mechanism(s) by which ribosomes initiate translation on the SBMV-C RNAs is not known. To begin to characterize the translation of the sgRNA it was first necessary to precisely map its 5' end. Primer extension was used to identify SBMV-C nucleotide (nt) 3241 as the transcription start site. As a control, the 5' end of the genomic RNA was also mapped. Surprisingly, the 5' terminal nt of this RNA was identified as SBMV-C nt 2. The primary structure of the 5' ends of these two RNAs is therefore expected to be VPg-ACAAAA. Precise mapping of the 5' end of the sgRNA of the bean strain of SBMV (SBMV-B) demonstrated that it has these same elements. Translation of coat protein from the SBMV-C sgRNA and p21 from the SBMV-C genomic RNA was compared using a cell-free system. The results of these experiments were consistent with translation of these proteins by a 5' end-dependent scanning mechanism rather than by internal ribosome binding.

Binding of the anti-human sperm monoclonal antibody HS-11 to bull spermatozoa is correlated with fertility in vitro.

The present study aimed to determine if there is bull to bull variation in the binding of the anti-human sperm monoclonal antibody (MAb) HS-11 to bull spermatozoa, and to investigate if there is any correlation between HS-11 binding to spermatozoa and in vitro fertility of the bulls tested. Semen samples of a single collection (split frozen in 0.5-ml straws) from 8 dairy bulls were used. Swim-up separated motile spermatozoa were incubated in 90-microl drops of capacitation medium (TALP+10 microg/ml heparin) at 39 degrees C, 5% CO2, 95% air. At 0, 2, 4 and 6 h of incubation HS-11 was added (1:1000 final concentration), and the MAb binding was assessed by indirect immunofluorescence assay (IIFA). The HS-11 binding was indicated by a bright green fluorescence of the sperm acrosome region. In vitro-matured, good quality bovine oocytes were randomly allocated to spermatozoa of each bull for in vitro fertilization. Sperm samples of 2 to 3 bulls were used in each trial until 4 replicates per bull were attained for IVF (n approximately 100 oocytes/bull) and IIFA experiments. Sperm capacitation status was assessed simultaneously using an egg yolk lysophosphatidylcholine- (LC) induced acrosome reaction assay. The binding of HS-11 to spermatozoa was maximum at 4 h of incubation in most (6/8) of the bull semen samples. Significant (P < 0.01) differences were observed between bulls in the binding of HS-11 to their spermatozoa (range 22 +/- 8 to 52 +/- 5%) at 4 h, but not within replicates. Similarly, variations (P < 0.05) in the cleavage rate were also seen (range 22 +/- 9 to 58 +/- 7%) between bulls. The HS-11 binding and cleavage were significantly correlated (r = 0.43; n = 32; P < 0.05). The highest percentage of spermatozoa underwent acrosome reaction in response to LC treatment at the 4-h incubation period. This and the linear relationship between HS-11 binding and the cleavage rate observed in the present study together strengthen our earlier suggestion that the binding of the monoclonal antibody HS-11 to bull spermatozoa on a time-dependent manner, may indicate capacitation changes. We conclude that 1) between-bull differences exist in HS-11 binding to spermatozoa, and in the cleavage rate, and 2) HS-11 binding to spermatozoa is correlated with fertility, as determined by the cleavage of bovine oocytes matured and fertilized in vitro.