AI Article Synopsis
- Tomato yellow leaf curl virus (TYLCV) causes widespread epidemics in tomatoes, prompting research into identifying resistance in wild tomato species.
- Previous studies suffered from inconsistent reporting of accession numbers, leading to duplicated screenings, which the current study aims to address by summarizing past efforts and screening 708 accessions from 13 wild species.
- The researchers found 138 symptomless accessions, investigated allelic variations of resistance genes, and provided a detailed overview of TYLCV resistance in wild tomato germplasm.
Article Abstract
Tomato yellow leaf curl virus (TYLCV) is a virus species causing epidemics in tomato () worldwide. Many efforts have been focused on identification of resistance sources by screening wild tomato species. In many cases, the accession numbers were either not provided in publications or not provided in a consistent manner, which led to redundant screenings. In the current study, we summarized efforts on the screenings of wild tomato species for TYLCV resistance from various publications. In addition, we screened 708 accessions from 13 wild tomato species using different inoculation assays (i.e., whitefly natural infection and Agrobacterium-mediated inoculation) from which 138 accessions exhibited no tomato yellow leaf curl disease (TYLCD) symptoms. These symptomless accessions include 14 accessions from , 43 from , 1 from , 28 from , 5 from , 4 from , 2 from , 1 from , 39 from , and 1 from . Most of the screened accessions remained symptomless. Many symptomless accessions were also identified in , , and . A large number of accessions were screened. However, almost all of the tested accessions showed TYLCD symptoms. Further, we studied allelic variation of the / gene in few accessions by applying virus-induced gene silencing and allele mining, leading to identification of a number of allele-specific polymorphisms. Taken together, we present a comprehensive overview on TYLCV resistance and susceptibility in wild tomato germplasm, and demonstrate how to study allelic variants of the cloned -genes in TYLCV-resistant accessions.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6110163 | PMC |
| http://dx.doi.org/10.3389/fpls.2018.01198 | DOI Listing |
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