Gregory John Hafner

Nucleotide sequence of one component of the banana bunchy top virus genome contains a putative replicase gene

One DNA component of the banana bunchy top virus (BBTV) genome was cloned and sequenced. This component is present as a circular, ssDNA in the virions and consists of 1111 nucleotides. It contains one large open reading frame (ORF) of 858 nucleotides in the virion sense; this ORF encodes a putative replicase based on the presence of a dNTP-binding motif (GGEGKT). Two smaller ORFs (249 and 366 nucleotides), in the complementary orientation, could not be assigned any obvious function. Neither of these ORFs had significant sequence homology with any known DNA plant virus gene or gene product. Computer analysis of this component-predicted a strong stem-loop structure in the virion sense putative untranslated region; a nonanucleotide sequence in the loop was nearly identical to the nonanucleotide invariant loop sequence of geminiviruses and coconut foliar decay virus. There is strong evidence that the genome of BBTV consists of more than one component because no ORF was found that would encode a protein the size of the BBTV coat protein. BBTV has some characteristics in common with geminiviruses but cannot be classified as one. Rather, BBTV probably belongs to an undescribed plant virus group which could also include subterranean clover stunt virus and coconut foliar decay virus.

Sequence diversity of South Pacific isolates of Taro bacilliform virus and the development of a PCR-based diagnostic test

Summary. We have analysed the sequence variability in the putative reverse transcriptase (RT)/ribonuclease H (RNaseH) and the C-terminal coat protein (CP)-coding regions from Taro bacilliform virus (TaBV) isolates collected throughout the Pacific Islands. When the RT/RNaseH-coding region of 22 TaBV isolates from Fiji, French Polynesia, New Caledonia, Papua New Guinea (PNG), Samoa, Solomon Islands and Vanuatu was examined, maximum variability at the nucleotide and amino acid level was 22.9% and 13.6%, respectively. Within the CP-coding region of 13 TaBV isolates from Fiji, New Caledonia, PNG, Samoa and the Solomon Islands, maximum variability at the nucleotide and amino acid level was 30.7% and 19.5%, respectively. Phylogenetic analysis showed that TaBV isolates from the Solomon Islands showed greatest variability while those from New Caledonia and PNG showed least variability. Based on the sequences of the TaBV RT/RNaseH-coding region, we have developed a PCR-based diagnostic test that specifically detects all known TaBV isolates. Preliminary indexing has revealed that TaBV is widespread throughout Pacific Island countries. A sequence showing approximately 50% nucleotide identity to TaBV in the RT/RNaseH-coding region was also detected in all taro samples tested. The possibility that this may represent either an integrated sequence or the genome of an additional badnavirus infecting taro is discussed.

Functional analysis of proteins encoded by banana bunchy top virus DNA-4 to -6.

Green fluorescent protein (GFP)-tagging was used to determine the intracellular localization pattern of the proteins encoded by banana bunchy top virus (BBTV) DNA-3, -4 and -6. The protein encoded by BBTV DNA-4, which possesses a hydrophobic N terminus, was found to localize exclusively to the cell periphery while the proteins encoded by BBTV DNA-3 and -6 were found in both the nucleus and the cytoplasm. Co-expression of the DNA-4 protein and the proteins encoded by BBTV DNA-3 and -6 revealed that the DNA-4 protein was able to re-locate the DNA-6 protein, but not the DNA-3 protein, to the cell periphery. The 29 amino acid N-terminal hydrophobic region of the DNA-4 gene product appeared to be essential for specific localization of this protein since deletion of this region abolished its ability to localize to the cell periphery. These results indicate that BBTV may utilize a system analogous to that of the begomoviruses with the BBTV DNA-6 protein acting as a nuclear shuttle protein (NSP) while the DNA-4 protein transports the NSP-DNA complexes to the cell periphery for intercellular transport. The protein encoded by BBTV DNA-5 was found to contain an LXCXE motif and yeast two-hybrid analysis revealed that the DNA-5 protein has retinoblastoma (Rb)-binding activity. This activity was dependent on an intact LXCXE motif since specific mutations to either the C or E residue completely abolished Rb-binding activity. These results indicate that the gene product of BBTV DNA-5 is an Rb-binding-like protein and may play an important role in host-cell cycle manipulation.

Genomic characterisation of taro bacilliform virus

Summary. Taro bacilliform virus (TaBV) has been classified as a putative badnavirus based on its non-enveloped, bacilliform virion morphology and transmission by mealybugs. The complete nucleotide sequence of a Papua New Guinea isolate of TaBV has now been determined and comprises 7458 bp. The genome contains four open reading frames (ORFs) on the plus-strand that potentially encode proteins of 17, 16, 214 and 13 kDa. The size and organisation of TaBV ORFs 1–3 is similar to that of most other badnaviruses, while the location of ORF 4 is similar to that of ORF 4 and ORF X of the atypical badnaviruses Citrus yellow mosaic virus and Cacao swollen shoot virus, respectively. The putative amino acid sequence of TaBV ORF 3 contained motifs that are conserved amongst badnavirus proteins including aspartic protease, reverse transcriptase (RT) and ribonuclease H (RNase H). The highly conserved putative plant tRNAmet-binding site was also present in the 935 bp intergenic region of TaBV. Phylogenetic analysis using the amino acid sequence of ORF 3 showed that TaBV branched most closely to Dioscorea bacilliform virus. These results confirm that TaBV is a pararetrovirus of the genus Badnavirus, family Caulimoviridae.

Movement and transmission of banana bunchy top virus DNA component one in bananas

The systemic movement and replication of banana bunchy top virus (BBTV) DNA component one were investigated. Strand-specific RNA probes and PCR were used to indicate the presence of the virus in various parts of infected banana plants during infection on the basis of dsDNA replicative intermediates of BBTV. The strand-specific probes were not only able to detect the presence of the virus but also gave an indication of where the virus replicated. The results using both the virion sense and complementary to virion sense specific probes were essentially the same indicating that BBTV initially replicated for a short period at the site of inoculation, and subsequently moved down the pseudostem to the basal meristematic region and ultimately into the roots and newly formed leaves. The virus was detected in the leaves formed prior to inoculation after 21 days using PCR but was not detected by the RNA probes. This indicated that the virus had the ability to move into these leaves but may not have replicated or accumulated to significant levels. The appearance of multimeric forms of BBTV suggested that the virus may have replicated via a rolling circle mechanism. Additionally, BBTV DNA component one did not appear to replicate in its aphid vector, Pentalonia nigronervosa.

Incidence and distribution of viruses of Taro (Colocasia esculenta) in Pacific Island countries

Four viruses have been reported from taro; Dasheen mosaic virus (DsMV), Taro bacilliform virus (TaBV) and two putative rhabdoviruses, Colocasia bobone disease virus (CBDV) and Taro vein chlorosis virus (TaVCV). A fifth virus, tentatively named Taro reovirus (TaRV), has also been recently identified. The distribution of these viruses throughout the Pacific Islands, and the symptoms associated with their infection, are unknown in many cases due to a lack of sensitive diagnostic tests. We have used recently developed PCR-based diagnostic tests to survey taro growing in 11 Pacific Island countries for the presence of known viruses. DsMV and TaBV were widespread, whereas TaVCV and TaRV were more restricted in their distribution. CBDV was restricted to PNG and Solomon Islands and was always associated with the two most serious viral diseases of taro; alomae disease and bobone disease, but the causal agent of these two diseases remains unclear.

Investigations into the seed and mealybug transmission of Taro bacilliform virus

Investigations were conducted into the transmission of Taro bacilliform badnavirus (TaBV) by seed and mealybugs. Seed transmission was investigated by artificially pollinating TaBV-infected taro. Seeds derived from four successfully pollinated plants tested positive for TaBV by PCR. Twenty seeds derived from each pollinated plant were also germinated; 2/80 seedlings showed TaBV-like symptoms and tested positive for TaBV by PCR. Pollen samples taken from TaBV-infected plants also tested positive for the virus. Mealybug transmission was investigated by exposing 51 healthy taro plants to Pseudococcus solomonensis that had been reared on TaBV-infected taro plants. Typical virus symptoms developed on 17 plants between 24 and 36 days after feeding; all these plants, in addition to 13 symptomless plants, tested positive for TaBV by PCR. This is the first report of TaBV transmission by P. solomonensis and the first report of P. solomonensis in Samoa.