Abstract
Capsicum annuum, a valuable spice and vegetable crop belonging to the Solanaceae family, is extensively grown across the Indian subcontinent. Chilli production is restricted by a begomoviral infection named as chilli leaf curl disease (ChiLCD) mainly in tropical and subtropical regions which leads to considerable economic losses, thus affecting chilli cultivation. Here, we studied the genetic diversity with structural evaluation of chilli leaf curl disease and satellite molecules infecting Chilli in India. We retrieved 121 reference sequences of ChiLCD including DNA-A, DNA-B, beta-satellite and alpha-satellites from GenBank reported from India. The population diversity and genetic variation were estimated through various parameters which decipher the four major groups of phylogenetic divergence for DNA-A and five groups of beta-satellite showing percentage similarity with isolates within and across India. Further, transitional and transversional bias for ORFs were observed highest in C4 and REn genes, respectively, and for DNA-A and DNA-B, these values were 1.07 and 1.22, respectively. The recombination breakpoints for DNA-A were estimated 49 majorly in V1, C1,C2 and C4 genome region and highest 22 breakpoints were determined for Rep (AC1) of ORFs, similarly 9 events for beta-satellite were found less around βC1ORF. Moreover, the evolution and genetic variability were also contributed through parameters such as nucleotide substitution which were found within the range of RNA viruses for DNA-A, DNA-B, for all 6 ORFs (relaxed clock) and beta-satellite. Additionally, total numbers of mutations (η) for DNA-A, DNA-B, alpha-satellites and beta-satellites were 2505, 419, 807 and 1288 detected, respectively, while it was found 987 highest for Rep gene among all ORFs. Further, neutrality tests determine the dominant nature of population expansion and purifying selection for all the genes of begomovirus associated with ChiLCD and satellite molecules supporting conserved nature of gene. The combined Tajima’s D and Fu and Li’S D* negative values in tests indicated that population are under purified selection and an excess of low-frequency polymorphism. Our analysis indicates the potential contribution of genetic mutations and recombination of ChiLCD which leads to rapid adaptation and evolution of begomovirus and its satellite molecules accelerating its host range and diversity within and across the Indian subcontinent.
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RKG is thankful to Uttar Pradesh Higher Education Department (UPHED, File No. 1/2022/01/04-2022-4(28)/21 dated 04/01/2022) for providing the financial support during this study.
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VP, AS and MM have performed the analysis and RKG framed the manuscript and critical editing along with the help of MM.
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13205_2022_3139_MOESM1_ESM.jpg
Supplementary Figure 1.Geographical (State and district wise) distribution of DNA-A, DNA-B, Alpha and betasatellite associated with ChiLCD on Capsicum annuum across India. All the states are shown with different colour and distinct geometrical shape with various colours indicates the diverse begomovirus components in particular district/city. (JPG 268 KB)
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Pandey, V., Srivastava, A., Mishra, M. et al. Chilli leaf curl disease populations in India are highly recombinant, and rapidly segregated. 3 Biotech 12, 83 (2022). https://doi.org/10.1007/s13205-022-03139-w
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DOI: https://doi.org/10.1007/s13205-022-03139-w