Author:
Darmanov Mukhtor M.,Makamov Abdusalom K.,Ayubov Mirzakamol S.,Khusenov Naim N.,Buriev Zabardast T.,Shermatov Shukhrat E.,Salakhutdinov Ilkhom B.,Ubaydullaeva Khurshida A.,Norbekov Jurabek K.,Kholmuradova Maftuna M.,Narmatov Sardor E.,Normamatov Ilyos S.,Abdurakhmonov Ibrokhim Y.
Abstract
Marker-assisted selection (MAS) helps to shorten breeding time as well as reduce breeding resources and efforts. In our MAS program, we have targeted one of previously reported LD-blocks with its simple sequence repeat (SSR) marker(s), putatively associated with, at least, four different fibre quality QTLs such as fibre length, strength, micronaire and uniformity. In order to transfer targeted QTLs from a donor genotype to a cultivar of choice, we selected G. hirsutum donor genotypes L-141 and LN-1, possessing a fibre quality trait-associated LD-block from the chromosome 7/16. We crossed the donor lines with local elite G. hirsutum cultivars ‘Andijan-35’ and ‘Mekhnat’ as recipients. As a result, two segregating populations on LD-block of interest containing fibre QTLs were developed through backcrossing (BC) of F1 hybrids with their relative recipients (used as recurrent parents) up to five generations. In each BC and segregating BC1-5F1 populations, a transfer of targeted LD-block/QTLs was monitored using a highly polymorphic SSR marker, BNL1604 genotype. The homozygous cultivar genotypes with superior fibre quality and agronomic traits, bearing a targeted LD-block of interest, were individually selected from self-pollinated BC5F1 (BC5F2–5) population plants using the early-season PCR screening analysis of BNL1604 marker locus and the end-of-season fibre quality parameters. Only improved hybrids with superior fibre quality compared to original recipient parent were used for the next cycle of breeding. We successfully developed two novel MAS-derived cotton cultivars (named as ‘Ravnaq-1’ and ‘Ravnaq-2’) of BC5F5 generations. Both novel MAS cultivars possessed stronger and longer fibre as well as improved fibre uniformity and micronaire compared to the original recurrent parents, ‘Andijan-35’ and ‘Mekhnat’. Our efforts demonstrated a precise transfer of the same LD-block with, at least, four superior fibre QTLs in the two independent MAS breeding experiments exploiting different parental genotypes. Results exemplify the feasibility of MAS in cotton breeding.
Reference52 articles.
1. Cotton research in Uzbekistan: Elite varieties and future of cotton breeding;Abdukarimov,2003
2. Molecular cloning of new DNA-markers for marker-assisted selection of cotton. Dissertation’ Thesis. Tashkent, Uzbekistan: Institute of Genetics and plant experimental biology, academy of Uzbek sciences;Abdurakhmonov,2002
3. Simple sequence repeat marker associated with a natural leaf defoliation trait in Tetraploid cotton;Abdurakhmonov;J. Hered.,2005
4. Utilization of natural diversity in Upland cotton (G. hirsutum) germplasm collection for pyramiding genes via marker-assisted selection program;Abdurakhmonov,2011
5. Molecular diversity and association mapping of fibre quality traits in exotic G. hirsutum L. germplasm;Abdurakhmonov;Genomics,2008
Cited by
6 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献