Comparison of transverse facial venous sinus and jugular blood values in healthy and critically ill horses.

REASONS FOR PERFORMING STUDY: The transverse facial venous sinus (TFVS) can be used for blood collection in horses, but information on the validity of blood values from this site is limited. OBJECTIVES: To determine if packed cell volume (PCV), total solids (TS) and blood lactate concentrations in blood drawn simultaneously from a TFVS and jugular vein of critically ill horses are correlated and determine the effect of serial TFVS sampling on the same parameters in healthy horses. STUDY DESIGN: Prospective observational study. METHODS: Critically ill horses had simultaneous blood samples drawn from a TFVS and jugular vein. Blood was also drawn from the left TFVS and jugular vein from 6 healthy, adult horses q. 6 h for 24 h, then q. 24 h for 72 h. Blood was drawn from the right TFVS and jugular vein q. 24 h for 96 h. All samples were analysed for PCV, TS and blood lactate concentration. Data were analysed with 2-way repeated measures ANOVA. Significance was set at P≤0.05. RESULTS: There were no significant differences in PCV, TS or blood lactate concentrations of TFVS samples compared with jugular blood in critically ill horses. Serial TFVS sampling in healthy horses had no significant effect on TS or blood lactate concentrations. Although PCV in the TFVS was significantly lower than in jugular blood on serial sampling, the difference was not considered clinically relevant. CONCLUSIONS: Packed cell volume, TS and blood lactate concentrations were comparable between the TFVS and jugular vein.

Elongation factor 1 alpha concentration is highly correlated with the lysine content of maize endosperm.

Lysine is the most limiting essential amino acid in cereals, and for many years plant breeders have attempted to increase its concentration to improve the nutritional quality of these grains. The opaque2 mutation in maize doubles the lysine content in the endosperm, but the mechanism by which this occurs is unknown. We show that elongation factor 1 alpha (EF-1 alpha) is overexpressed in opaque2 endosperm compared with its normal counterpart and that there is a highly significant correlation between EF-1 alpha concentration and the total lysine content of the endosperm. This relationship is also true for two other cereals, sorghum and barley. It appears that genetic selection for genotypes with a high concentration of EF-1 alpha can significantly improve the nutritional quality of maize and other cereals.

Structure of the gene encoding the M1 protein of sonchus yellow net virus.

The gene encoding the M1 protein of sonchus yellow net virus (SYNV), a plant rhabdovirus, has been sequenced and identified by Western blot analysis of SYNV proteins using antibodies directed against a fusion protein derived from a portion of the sequenced gene. The M1 gene is positioned between nucleotides 4039 and 5109 relative to the 3' end of the viral RNA and is the fourth gene from the 3' end of the genome. The 1071-nucleotide (nt) M1 gene lies between a putative nonstructural gene of unknown function and the gene encoding the glycoprotein and is bordered on either side by the same GG intergenic dinucleotide that separates other genes in the SYNV genome. The M1 mRNA (scRNA 6) consists of a 71-nt untranslated region at the 5' terminus followed by an 858-nt open reading frame (ORF) capable of encoding a protein with a calculated molecular weight of 31,779. The amino acid sequence deduced from this ORF is not highly homologous to those of other rhabdovirus matrix proteins, but has some localized regions of similarity. The UGA codon that terminates the M1 ORF is followed by a 3' untranslated region of 142 nt. The viral RNA (minus-sense) sequence corresponding to the extreme 3' end of the mRNA contains a 9-nt tract (3'-AUUGUUUUU-5') that is identical to the sequences at the termini of other SYNV genes.

Physical map of the genome of sonchus yellow net virus, a plant rhabdovirus with six genes and conserved gene junction sequences.

We provide evidence that a plant rhabdovirus, sonchus yellow net virus (SYNV), is similar to most animal rhabdoviruses in the order of structural genes and in the nucleotide sequences at the gene junctions but that it differs in the presence and location of a putative nonstructural gene. From the patterns of hybridization of a library of recombinant DNA clones, we have shown that the SYNV genome is transcribed into a short 3'-terminal "leader RNA" and six mRNAs. The proteins encoded by the SYNV mRNAs, in order of the appearance of their genes in the SYNV genome, are designated 3'-N-M2-sc4-M1-G-L-5' (N, nucleoprotein; M, matrix protein; sc, protein encoded by SYNV complementary RNA; G, glycoprotein; L, large protein). The intergenic and flanking gene sequences are conserved and consist of a central core of 14 nucleotides (3'-UUCUUUUUGGUUGU/A-5') whose sequence is similar to the sequence at the gene junctions of vesicular stomatitis and rabies viruses. The SYNV core consists of an 8-nucleotide (3'-UUCUUUUU-5') transcription termination signal at the 5' terminus of each gene, a dinucleotide (GG) spacer whose complement does not appear in mRNA, and a tetranucleotide (3'-UUGU/A-5') that is complementary to the first four nucleotides at the 5' terminus of the SYNV mRNAs. These results, when compared with structural information available on animal rhabdoviruses, suggest that organization of structural genes and maintenance of signals thought to play important roles in regulation of transcription have been conserved during evolution in plant, insect, and vertebrate hosts. However, differences in number and location of putative nonstructural genes reveal some flexibility in genome organization that may be important in deducing taxonomic and evolutionary relationships among viruses causing diseases in phylogenetically diverse hosts.

Infectious barley stripe mosaic virus RNA transcribed in vitro from full-length genomic cDNA clones.

Full-length genomic cDNA clones of the Type and ND18 strains of barley stripe mosaic virus (BSMV) were transcribed in vitro using T7 RNA polymerase. The combination of RNAs alpha, beta, and gamma synthesized in the presence of 5' cap analogs was infectious after inoculation onto barley plants, conclusively demonstrating the tripartite nature of the BSMV genome. Transcripts synthesized in the absence of cap analogs were not infectious. A gamma-specific subgenomic RNA which is normally present in BSMV virions was not required to establish a systemic infection. In vitro transcripts of variant cDNA clones which were isolated from the ND18 strain, containing either a simple nucleotide substitution or a 372-nucleotide duplication similar to one found in the genome of the Type strain, were also found to be biologically active. Two dicotyledonous hosts which have a differential response to infection with the Type and ND18 strains of BSMV were identified and these phenotypes were shown to be faithfully reproduced by inoculation with in vitro transcripts derived from the appropriate full-length cDNA clones.

Relationship of lychnis ringspot virus to barley stripe mosaic virus and poa semilatent virus.

Barley stripe mosaic virus (BSMV), poa semilatent virus (PSLV), and lychnis ringspot virus (LRSV) have previously been assigned to the hordeivirus group because of similarities in their particle morphology, physicochemical properties and serological analyses. However, the serological relationships of the three viruses have not been determined by direct comparison. The present study evaluated the relatedness of these viruses by Western and dot immunoblotting and by nucleic acid hybridizations. Serological analyses of the coat proteins separated by gel electrophoresis and of intact virus particles bound to nitrocellulose membranes revealed that BSMV and PSLV are distantly related, but that they are more closely related to each other than to LRSV. The genomic RNAs of the viruses failed to cross-hybridize in northern hybridization tests conducted at different temperatures. These comparisons showed that BSMV, PSLV and LRSV are distinct viruses with little nucleotide sequence relatedness. Thus our data provide additional support for their inclusion as separate members of the hordeivirus group.

A novel strategy for one-step cloning of full-length cDNA and its application to the genome of barley stripe mosaic virus.

We have devised a novel vector-primer strategy for cloning of full-length (FL) cDNA which can be applied to non-polyadenylated RNA species. Single-stranded plasmid DNA is used to prime first-strand synthesis by reverse transcriptase, and plasmids covalently linked to FL cDNA are then circularized by the annealing of a specific oligodeoxyribonucleotide (band-aid oligo). Only limited nucleotide sequence data are required from the termini of each RNA species to be cloned to design the plasmid primer and band-aid oligo. The band-aid strategy has been applied to the cloning of barley stripe mosaic virus genomic RNAs, and found to be both rapid and efficient. A strategy for the preparation of linear double-stranded plasmid DNA templates (suitable for run-off in vitro transcription) which is independent of restriction sites present within the cloned cDNA is also described.

Analysis of the genome of satellite panicum mosaic virus.

The relatedness of the genomes of satellite panicum mosaic virus (SPMV) and its helper virus, panicum mosaic virus (PMV), were investigated by nucleic acid hybridization. The results show that the satellite and helper virus RNAs have no appreciable homology or complementarity as assessed by hybridization with cDNA probes derived from the genomes of PMV and SPMV and with a probe complementary to the 3' terminus of SPMV RNA. The complete nucleotide sequence of SPMV RNA reveals that the genome is 826 nucleotides (nt) long. The ability to label SPMV RNA with polynucleotide kinase only after phosphatase treatment suggests that the 5' terminus is phosphorylated, but the extent of phosphorylation was not determined. The first open reading frame (ORF), encountered after an 88-nt 5'-untranslated region, encodes a 17,000 mol wt protein of a size and amino acid composition that are consistent with analysis of SPMV coat protein. An additional short ORF, located near the 3' end of the RNA, could encode a 6300 mol wt polypeptide. The minus strand also contains two ORFs that could potentially encode polypeptides of 7100 and 11,000 mol wt. No evidence is available to determine whether the second positive-strand ORF or the two minus-strand ORFs are expressed. The data presented here clearly show the SPMV RNA is distinct from the RNAs of other satellite viruses, in both size and nucleotide sequence. However, the 5'-untranslated portions of SPMV and satellite tobacco mosaic virus RNAs share some structural features that may be important in initiation of translation.