Development and evaluation of Fusarium wilt-resistant and high-yielding chickpea advanced breeding line, KCD 11

Article

Laxuman, C., Naik, Yogesh Dashrath, Desai, B. K., Kenganal, Mallikarjun, Patil, Bharat, Reddy, B. S., Patil, D. H., Chakurte, Sidramappa, Kuchanur, P. H., Kumar K, Shiva, Gaddi, Ashok Kumar, Yogesh, L. N., Nidagundi, Jayaprakash, Dodamani, B. M., Sunkad, Gururaj, Thudi, Mahendar and Varshney, Rajeev K.. 2024. "Development and evaluation of Fusarium wilt-resistant and high-yielding chickpea advanced breeding line, KCD 11." The Plant Genome. 17 (2). https://doi.org/10.1002/tpg2.20460
Article Title

Development and evaluation of Fusarium wilt-resistant and high-yielding chickpea advanced breeding line, KCD 11

ERA Journal ID211456
Article CategoryArticle
AuthorsLaxuman, C., Naik, Yogesh Dashrath, Desai, B. K., Kenganal, Mallikarjun, Patil, Bharat, Reddy, B. S., Patil, D. H., Chakurte, Sidramappa, Kuchanur, P. H., Kumar K, Shiva, Gaddi, Ashok Kumar, Yogesh, L. N., Nidagundi, Jayaprakash, Dodamani, B. M., Sunkad, Gururaj, Thudi, Mahendar and Varshney, Rajeev K.
Journal TitleThe Plant Genome
Journal Citation17 (2)
Article Numbere20460
Number of Pages11
Year2024
PublisherJohn Wiley & Sons
Place of PublicationUnited Kingdom
ISSN1940-3372
Digital Object Identifier (DOI)https://doi.org/10.1002/tpg2.20460
Web Address (URL)https://acsess.onlinelibrary.wiley.com/doi/10.1002/tpg2.20460
AbstractFusarium wilt (FW) is the most severe soil-borne disease of chickpea that causes yield losses up to 100%. To improve FW resistance in JG 11, a high-yielding variety that became susceptible to FW, we used WR 315 as the donor parent and followed the pedigree breeding method. Based on disease resistance and yield performance, four lines were evaluated in station trials during 2017–2018 and 2018–2019 at Kalaburagi, India. Further, two lines, namely, Kalaburagi chickpea desi 5 (KCD 5) and KCD 11, which possesses the resistance allele for a specific single-nucleotide polymorphism marker linked with FW resistance, were evaluated across six different locations (Bidar, Kalaburagi, Raichur, Siruguppa, Bhimarayanagudi and Hagari) over a span of 3 years (2020–2021, 2021–2022 and 2022–2023). KCD 11 exhibited notable performance, showcasing yield advantages of 8.67%, 11.26% and 23.88% over JG 11, and the regional checks Super Annigeri 1 (SA 1) and Annigeri 1, respectively, with enhanced FW resistance in wilt sick plot. Further, KCD 11 outperformed JG 11, SA 1 and Annigeri 1 in multi-location trials conducted across three seasons in the North Eastern Transition Zone, North Eastern Dry Zone, and North Dry Zones of Karnataka. KCD 11 was also tested in trials conducted by All India Coordinated Research Project on chickpea and was also nominated for state varietal trials for its release as a FW-resistant and high-yielding variety. The selected line is anticipated to cater the needs of chickpea growers with the dual advantage of yield increment and disease resistance.
Contains Sensitive ContentDoes not contain sensitive content
ANZSRC Field of Research 2020409901. Agricultural engineering
Byline AffiliationsUniversity of Agricultural Sciences Raichur, India
Dr. Rajendra Prasad Central Agricultural University, India
Agricultural Research Station, India
Collage of Agriculture, India
Main Agricultural Research Station, India
Centre for Crop Health (Operations)
International Crops Research Institute for the Semi-Arid Tropics (ICRISAT), India
Dr. Fort Valley State University, United States
Murdoch University
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