ABSTRACT
Papaya ringspot virus (PRSV) is a significant threat to global papaya cultivation, causing ringspot disease, and it belongs to the species Papaya ringspot virus, genus Potyvirus, and family Potyviridae. This study aimed to assess the occurrence and severity of papaya ringspot disease (PRSD) in major papaya-growing districts of Karnataka, India, from 2019 to 2021. The incidence of disease in the surveyed districts ranged from 50.5 to 100.0 percent, exhibiting typical PRSV symptoms. 74 PRSV infected samples were tested using specific primers in RT-PCR, confirming the presence of the virus. The complete genome sequence of a representative isolate (PRSV-BGK: OL677454) was determined, showing the highest nucleotide identity (nt) (95.8%) with the PRSV-HYD (KP743981) isolate from Telangana, India. It also shared an amino acid (aa) identity (96.5%) with the PRSV-Pune VC (MF405299) isolate from Maharashtra, India. Based on phylogenetic and species demarcation criteria, the PRSV-BGK isolate was considered a variant of the reported species and designated as PRSV-[IN:Kar:Bgk:Pap:21]. Furthermore, recombination analysis revealed four unique recombination breakpoint events in the genomic region, except for the region from HC-Pro to VPg, which is highly conserved. Interestingly, more recombination events were detected within the first 1710 nt, suggesting that the 5' UTR and P1 regions play an essential role in shaping the PRSV genome. To manage PRSD, a field experiment was conducted over two seasons, testing various treatments, including insecticides, biorationals, and a seaweed extract with micronutrients, alone or in combination. The best treatment involved eight sprays of insecticides and micronutrients at 30-day intervals, resulting in no PRSD incidence up to 180 days after transplanting (DAT). This treatment also exhibited superior growth, yield, and yield parameters, with the highest cost-benefit ratio (1:3.54) and net return. Furthermore, a module comprising 12 sprays of insecticides and micronutrients at 20-day intervals proved to be the most effective in reducing disease incidence and enhancing plant growth, flowering, and fruiting attributes, resulting in a maximized yield of 192.56 t/ha.
ABSTRACT
The incidence and severity of begomovirus diseases have been increasing around the world recently, and the ridge gourd [Luffa acutangula (Roxb.) L.] is the latest example of a crop that has become highly susceptible to the outbreak of the tomato leaf curl New Delhi virus (ToLCNDV, genus Begomovirus) in India. Accurate diagnosis of causal agents is important in designing disease management strategies. In this study the coat protein (CP) gene from a ToLCNDV-Rg ridge gourd isolate was used to produce polyclonal antibodies (ToLCNDV-Rg-CP-PAb) in a rabbit. The antibodies successfully detected a 30.5 kDa ToLCNDV-Rg-CP in extracts of symptomatic ridge gourd leaf samples by several assays, such as Western Blotting (WB), Dot Immuno Binding Assay (DIBA), Direct Antigen Coating Enzyme Linked Immuno Sorbent Assay (DAC-ELISA), Immuno Capture Polymerase Chain Reaction (IC-PCR), and Immuno Capture Loop-Mediated Isothermal Amplification (IC-LAMP) assays. However, none of the negative samples tested positive in either of the detection methods. Among all the methods tested, the immunocapture assay, IC-LAMP, was the most sensitive in detecting ToLCNDV-Rg. Furthermore, antibodies generated in this study also detected other commonly occurring begomoviruses in South India, such as tomato leaf curl Palampur virus and squash leaf curl China virus in cucurbits. Together, ToLCNDV-Rg-CP-PAb can be used for detecting at least three species of begomoviruses infecting cucurbits. The obtained antibodies will contribute to monitoring disease outbreaks in multiple crops.
ABSTRACT
Gerbera is the most popular cut flower known for its variety of colors and is grown across the world. Its production is challenged by numerous diseases affecting production and quality. During our survey, ten samples from the gerbera plants exhibiting phyllody disease symptoms were collected from Bangalore Rural District, Karnataka, India. The association of phytoplasma with the gerbera phyllody samples was confirmed by PCR using 16SrRNA, SecY, Ribosomal protein (rp) and SecA gene-specific primers. PCR products were amplified from all ten gerbera plants using phytoplasma-specific primers. The amplified PCR products were cloned and sequenced; the sequences of the ten clones were identical. Therefore, representative isolate (GePP1, Gerbera phyllody phytoplasma) was selected for further analysis. The sequence analysis showed that GePP1 shared maximum nucleotide (nt) identity of 97.1% (16SrRNA) with Eggplant big bud, 98.7 to 98.8% (SecY gene) with Tomato big bud, 99.2 to 99.6% (rp gene) with Alfalfa witches-broom (EF193371) and 99.1% (SecA gene) with Sesame phyllody phytoplasmas and that it belongs to the Ca. P. aurantifolia (16SrII) group. This result was well supported by the phylogenetic analysis showing GePP1 (16Sr RNA, SecY, rp and SecA genes) closely clustering with the Ca. P. aurantifolia 16SrII group isolates reported so far. The virtual RFLP pattern generated for the phytoplasma from gerbera was different (similarity coefficient 0.89) from the reference pattern of Ca. P. aurantifolia (16Sr II) subgroup after analysis with four enzymes (BfaI, Hha1, Sau3AI and RsaI). Based on the threshold similarity coefficient for a new subgroup (delineation should be set at 0.97), the GePP1 may be considered as new subgroup of Ca. P. aurantifolia (16SrII) group. This is the first report of Ca. P. aurantifolia belonging to 16Sr II group affecting gerbera in India. Keywords: Candidatus Phytoplasma aurantifolia; phyllody; gerbera; PCR; phylogenetic analysis.
