Rescue of bovine respiratory syncytial virus from cloned cDNA: entire genome sequence of BRSV strain A51908.

Infectious bovine respiratory syncytial virus (BRSV) was produced by intracellular co-expression of five plasmid borne cDNAs, each under the control of a T7 RNA polymerase promoter. These separately encoded a full-length, genetically-marked copy of BRSV antigenome along with either BRSV or human respiratory syncytial virus (HRSV) support plasmids, which express N, P, L and M2-1 proteins. HEp2 cells were used in transfection and recombinant vaccinia virus (MVA-T7) provided T7 RNA polymerase to drive the transcription. The recovery of recombinant BRSV (rBRSV) was confirmed by immunological staining of plaques, restriction enzyme digestion and nucleotide sequencing of PCR fragments carrying the genetic markers from the rescued virus. The rBRSV was indistinguishable from its parental wild-type virus in its growth characteristics in cell culture. The present work has completed the entire genome sequence of BRSV strain A51908 (15,140 nt) and has also identified changes in sequence and growth characteristics in cell culture from the original BRSV strain A51908 laboratory isolate.

Bovine respiratory syncytial virus can induce apoptosis in MDBK cultured cells.

Bovine respiratory syncytial virus (BRSV) is a major cause of respiratory disease in calves. BRSV infection is associated with epithelial cell death and inflammation. Over the past few years, a growing number of viruses have been found to induce apoptosis. In order to determine the ability of BRSV to induce apoptosis, we studied the effect of BRSV infection in cultured MDBK cells. We used ligation-mediated PCR assay to detect specific blunt-end cellular DNA fragments produced by cellular endonucleases cleaving the genomic DNA between the nucleosomes during apoptosis. We found that BRSV infection resulted in apoptosis in MDBK cells. This data demonstrates for the first time that BRSV can induce apoptosis. This data also may contribute to delineate the mechanisms that regulate tissue injury and potential lung repair following BRSV infection.

Deletion and substitution analysis defines regions and residues within the phosphoprotein of bovine respiratory syncytial virus that affect transcription, RNA replication, and interaction with the nucleoprotein.

The phosphoprotein (P) of bovine respiratory syncytial virus (BRSV) is a multifunctional protein that plays a central role in transcription and replication of the viral genomic RNA. To investigate the domains and specific residues involved in different activities of the P protein, we generated a total of 22 deletion and 17 point mutants of the P protein. These mutants were characterized using an intracellular BRSV-CAT minigenome replication system for the ability to (1) direct minigenome transcription, (2) direct minigenome replication, and (3) form complexes with nucleocapsid protein (N) and large polymerase protein (L). These studies revealed that all the regions of P protein except amino acids 41-80 are essential for minigenome transcription and replication. Interestingly, amino acids 41-60 appeared to contain sequences that negatively regulate transcription and replication. Analysis of the N- or C-terminal ends indicated that deletion of up to 3 amino acids from the N- or C-terminus completely ablated the replication, while leaving substantial residual transcription. Single amino acid substitutions within the N-terminal 4 or C-terminal 13 amino acids showed that substitution at position 2, 4, 234, 236, 238, 240, or 241 was highly inhibitory to both transcription and replication, whereas substitution at position 3 was highly inhibitory to replication while leaving substantial residual transcription. Substitution of serine residues at the C-terminus indicated that loss of phosphorylation sites did not appear to have any effect on transcription and replication. Coimmunoprecipitation of P-N and P-L complexes with P-specific antiserum revealed that substitution mutations at the N- or C-terminus did not affect binding to N and L proteins, except that substitution mutation at C-terminus position 234, 236, 238, 240, or 241 affected binding to N protein by 10-fold.

Bovine respiratory syncytial virus: first serological evidence in Uruguay.

Bovine respiratory syncytial virus (BRSV) is a major cause of respiratory disease in calves resulting in a substantial economic loss for the cattle industry worldwide. In order to determine the presence of BRSV in Uruguay, an immunoenzymatic test was set up, using a recombinant BRSV nucleocapsid (N) protein as the antigen. The N protein was produced in Sf9 insect cells by a recombinant baculovirus expressing the N protein. Serum samples collected from one hundred cattle from four different geographic regions of Uruguay were analyzed. Antibodies against the N protein of BRSV were detected in 95% of the serum samples analyzed. These results show for the first time the presence of BRSV antibodies and suggest a widespread BRSV infection in the cattle population of Uruguay.

Mutational analysis of the bovine respiratory syncytial virus nucleocapsid protein using a minigenome system: mutations that affect encapsidation, RNA synthesis, and interaction with the phosphoprotein.

The nucleocapsid (N) protein of bovine respiratory syncytial virus (BRSV) is a multifunctional protein that plays a central role in transcription and replication of viral genomic RNA. To investigate the domains and specific residues involved in different N activities, we generated a total of 27 deletion and 12 point mutants of the N protein. These mutants were characterized using an intracellular BRSV-CAT minigenome replication system for the ability to (1) direct minigenome RNA synthesis, (2) direct minigenome encapsidation, and (3) form a complex with the phosphoprotein (P). The mutations tested were defective in synthesis of RNA from the BRSV-CAT minigenome template with the exception of the following: a deletion involving the first N-terminal amino acid and mutations involving conservative substitution at the second amino acid and at certain internal cysteine residues. Micrococcal nuclease enzyme protection assays showed that mutations involving amino acids 1-364 of the 391-amino-acid N protein prevented minigenome encapsidation. Thus the BRSV N protein has a C-terminal, 27-amino-acid tail that is not required for encapsidation. Interestingly, two of the mutations that ablated encapsidation did not greatly affect RNA synthesis; the mutant involving deletion of the N-terminal amino acid and the mutant involving a substitution at position 2. This finding indicates that the formation of a nucleocapsid sufficient to protect the RNA from nuclease is not required for template function. Coimmunoprecipitation of N and P using N- or P-specific antiserum revealed two regions of the N protein that are important for association with the P protein: a central portion of 244-290 amino acids and a C-terminal portion of 338-364 amino acids.

Rescue of a bovine respiratory syncytial virus genomic RNA analog by bovine, human and ovine respiratory syncytial viruses confirms the "functional integrity" and "cross-recognition" of BRSV cis-acting elements by HRSV and ORSV.

The nucleotide sequences of the 3' leader and 5' trailer regions were determined for genomic RNA of bovine respiratory syncytial virus (BRSV) strain A-51908. The leader and trailer sequences are '45' and '161' nucleotides in length, respectively. The functionality of BRSV leader and trailer sequences and their recognition by HRSV and ovine respiratory syncytial virus (ORSV) proteins were examined with a in vitro transcribed BRSV genomic RNA analog carrying the bacterial chloramphenicol acetyl transferase (CAT) gene under the control of BRSV transcription signals. Upon transfection into BRSV, HRSV or ORSV infected cells, the BRSV minireplicons were 'rescued' such that the reporter gene was expressed, the minigenome was replicated and packaged into micrococcal nuclease resistant-infectious minireplicons. The passage of infectious minireplicons could be blocked by a polyclonal BRSV neutralizing antiserum. Bovine parainfluenza virus-3, a heterologous paramyxovirus was inactive in rescuing BRSV genomic RNA analog. Mutational substitution of the G residue at position 4 of leader sequence in the BRSV genomic RNA analog, with an A or U residue inhibited its transcription and replication, while replacement with a C residue had no significant effect on rescue. These results show that the cis-acting elements of BRSV are functional and are also recognized by the proteins of HRSV and ORSV. The helper virus complemented rescue system developed here will be useful for characterizing the cis-acting elements of BRSV.

Genetic analysis of the G and P genes in ungulate respiratory syncytial viruses by RNase A mismatch cleavage method.

The G and P genes of bovine, ovine and caprine respiratory syncytial (RS) viruses were analyzed by RNase A one-dimensional fingerprinting, using A 51908 as the reference strain. Antisense G or P RNA probes of bovine RS virus strain A 51908 were hybridized to total RNA extracted from bovine turbinate cells infected with bovine, ovine or caprine RS virus strains. The RNA:RNA heteroduplexes were digested with RNase A and the resistant products were analyzed by gel electrophoresis. Comparative analysis of the cleavage patterns revealed heterogeneity among bovine, ovine and caprine RS virus isolates. Ovine RS virus strains generated RNA cleavage patterns more distantly related to the bovine or caprine RS virus strains, particularly in the G gene. Statistical analysis of the results obtained indicated that genetic differences between bovine and ovine viruses were larger, compared with the ones among bovine strains themselves. The same analysis also revealed a close genetic relation among bovine and caprine strains. These results are discussed in terms of ungulate RS virus genetic variation and vaccine development.

Sequence analysis of a functional polymerase (L) gene of bovine respiratory syncytial virus: determination of minimal trans-acting requirements for RNA replication.

The complete nucleotide sequence of a functional clone of the large polymerase (L) gene of bovine respiratory syncytial virus (BRSV) strain A51908 was determined by analysis of cloned cDNAs obtained from genomic and mRNAs. The BRSV L gene is 6573 nt in length and the derived polypeptide has 2162 aa. Alignment of the sequences of the BRSV L gene, and its encoded protein, with sequences of the L gene and protein of human respiratory syncytial virus strain A2 showed 77% identity at the nucleotide level and 84% identity at the amino acid level. By comparison, the L gene and protein of avian pneumovirus showed only 50% identity at the nucleotide level and 64% identity at the amino acid level. A minigenome was constructed to encode a BRSV vRNA analogue containing the gene for chloramphenicol acetyltransferase (CAT) under the control of putative BRSV transcription motifs and flanked by the BRSV genomic termini. Transfection of plasmids encoding the BRSV minigenome, nucleocapsid protein (N), phosphoprotein (P) and L protein, each under the control of T7 promoter, into cells infected with a vaccinia virus recombinant expressing the T7 RNA polymerase gave rise to CAT activity and progeny with the minigenome. This result indicates that the N, P and L proteins are necessary and sufficient for transcription and replication of the BRSV minigenome and are functional. Further, inclusion of small amounts of the M2 protein along with the N, P and L proteins greatly augmented minigenome transcription.