A 20 089 nucleotide (nt) sequence was determined for the 5h end of the (M)-ssRNA genome of gillassociated virus (GAV), a yellow head-like virus infecting Penaeus monodon prawns. Clones were generated from a " 22 kb dsRNA purified from lymphoid organ total RNA of GAV-infected prawns.
Sequence analysis of the " 20 kb 5h-terminal portion of the ssRNA genome of gill-associated virus (GAV) of Penaeus monodon prawns has previously established that it contains an ORF1a-1b replicase gene equivalent to those of the coronavirus and arterivirus members of the order Nidovirales. Sequence analysis of the remaining " 6n2 kb of the GAV genome downstream of ORF1a-1b to a 3h-poly(A) tail has identified two highly conserved intergenic sequences in which 29/32 nucleotides are conserved. Northern hybridization using probes to the four putative GAV ORFs and either total or poly(A)-selected RNA identified two 3h-coterminal subgenomic (sg) mRNAs of " 6 kb and " 5n5 kb. Primer extension and 5h-RACE analyses showed that the sgmRNAs initiate at the same 5h-AC positions in the central region of the two conserved intergenic sequences. Neither method provided any evidence that the GAV sgmRNAs are fused to genomic 5h-leader RNA sequences as is the case with vertebrate coronaviruses and arteriviruses. Intracellular doublestranded (ds)RNAs equivalent in size to the 26n2 kb genomic RNA and two sgRNAs were also identified by RNase/DNase digestion of total RNA from GAV-infected prawn tissue. The identification of only two sgmRNAs that initiate at the same position in conserved intergenic sequences and the absence of 5h-genomic leader sequences fused to these sgmRNAs confirms that GAV has few genes and suggests that it utilizes a transcription mechanism possibly similar to the vertebrate toroviruses but distinct from coronaviruses and arteriviruses.
A highly sensitive test based on reverse transcription followed by nested polymerase chain reaction (RT-nPCR) was developed to detect the Australian yellow-head-like viruses, gill-associated virus (GAV) and lymphoid organ virus (LOY) of Penaeus rnonodon. The RT-nPCR detected viral RNA in as little as 10 fg lymphoid organ total RNA isolated from GAV-infected P. monodon. Amplification of serial dilutions of a GAV cDNA clone showed that the nested PCR was sufficiently sensitive to detect a single genome equivalent using a DNA template. The specificity and sensitivity of the RTnPCR was also demonstrated using experimentally infected P. (Marsupenaeus) japonicus, where GAV sequences could be amplified from lymphoid organ and haemocyte RNA as early as 6 h post infection (p.i.), and from gills by 24 h p.i. In contrast, transmission electron microscopy (TEM) identified nucleocapsids and virions in lymphoid organ cells and haemocytes from Days 3 and 6 p i . , respectively, while there was no evidence of infection in gill cells at any time. The practical application of the RT-nPCR was demonstrated by screening healthy wild-caught P monodon broodstock. The high prevalence (>g8 % ) of broodstock that were positive by RT-nPCR suggests that LOV is endemic in northern Queensland. In addition, results with lymphoid organ, gill and haemocyte RNA suggest that small gill biopsies may be best suited to the non-sacrificial testing of valuable broodstock. The speed and sensitivity of the RTnPCR make it a useful adjunct to TEM for diagnosing LOV/GAV infection of P. monodon. with the additional benefit that screening of gill biopsies may facilitate selection of LOV-free broodstock.
Corresponding genomic regions of isolates of yellow head virus (YHV) from Thailand and gill-associated virus (GAV) from Australia were compared by RT-PCR and sequence analysis. PCR primers designed from sequences in the GAV ORFlb polyprotein gene amplified the corresponding 577 nucleotide region of the YHV genome. Comparison of the amplified region indicated 85.1 % nucleotide and 95.8% amino acid sequence identity. YHV PCR primers designed to amplify a 135 nucleotide product previously described as a YHV &agnostic probe failed to amplify the correspondmg product from GAV RNA. However, the cognate GAV sequence for this and another recently reported YHV sequence were located in an upstream region of the ORFlb gene. A comparison of these sequences indicated identities of 83.0 and 80.9% at the nucleotide level and 86.7 and 86.5% at the amino acid level, respectively. The data indicate that GAV and YHV are closely related but distinct viruses for whlch differential diagnostic probes can be applied.
Sugarcane accumulates high concentrations of sucrose in the mature stem and a number of physiological processes on-going in maturing stem tissue both directly and indirectly allow this process. To identify transcripts that are associated with stem maturation, we compared patterns of gene expression in maturing and immature stem tissue by expression profiling and bioinformatic analysis of sets of stem ESTs. This study complements a previous study of gene expression associated directly with sugar metabolism in sugarcane. A survey of sequences derived from stem tissue identified an abundance of several classes of sequence that are associated with fibre biosynthesis in the maturing stem. A combination of EST analyses and microarray hybridization revealed that genes encoding homologues of the dirigent protein, a protein that assists in the stereospecificity of lignin assembly, were the most abundant and most strongly differentially expressed transcripts in maturing stem tissue. There was also evidence of coordinated expression of other categories of fibre biosynthesis and putative defence- and stress-related transcripts in the maturing stem. This study has demonstrated the utility of genomic approaches using large-scale EST acquisition and microarray hybridization techniques to highlight the very significant transcriptional investment the maturing stem of sugarcane has placed in fibre biosynthesis and stress tolerance, in addition to its already well-documented role in sugar accumulation.
The ability of sugarcane to accumulate sucrose provides an experimental system for the study of gene expression determining carbohydrate partitioning and metabolism. A sequence survey of 7242 ESTs derived from the sucrose-accumulating, maturing stem revealed that transcripts for carbohydrate metabolism gene sequences (CMGs) are relatively rare in this tissue. However, within the CMG group, putative sugar transporter ESTs form one of the most abundant classes observed. A combination of EST analysis and microarray and northern hybridization revealed that one of the putative sugar transporter types, designated PST type 2a, was the most abundant and most strongly differentially expressed CMG in maturing stem tissue. PST type 2a is homologous to members of the major facilitator super-family of transporters, possessing 12 predicted transmembrane domains and a sugar transport conserved domain, interrupted by a large cytoplasmic loop. Its transcript was localized to phloem companion cells and associated parenchyma in maturing stem, suggesting a role in sugar translocation rather than storage. In addition, other categories of CMGs show evidence of coordinated expression, such as enzymes involved in sucrose synthesis and cleavage, and a majority of enzymes involved in glycolysis and the pentose phosphate pathway. This study demonstrates the utility of genomic approaches using large-scale EST acquisition and microarray hybridization techniques for studies of the developmental regulation of metabolic enzymes and potential transporters in sugarcane.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.