Development of high-amylose maize (Zea mays L.) genotypes adapted to Indian conditions through molecular breeding
Arushi Arora A B , Deepak Bhamare A B C , Abhijit Kumar Das A * , Shubhank Dixit A , Sreya Venadan A B C , Yathish K. R. C , Ramesh Kumar A , Dharam Paul A , J. C. Sekhar C , Sunil Neelam C , Sudip Nandi A , M. C. Kamboj D and Sujay Rakshit A E *A
B
C
D
E
Abstract
Amylose is a type of resistant starch with numerous health benefits and industrial applications. Starch from maize (Zea mays L.) usually has an amylose content of ~25%.
The aim was to develop high-amylose maize genotypes suitable for human consumption and adapted to Indian conditions.
Marker-assisted backcross breeding was used to transfer the mutant ae1 allele from a high-amylose donor from the USA into the three parents (HKI 1344, HKI 1378, HKI 1348-6-2) of two high-yielding white maize hybrids (HM5 and HM12) grown in India.
In converted lines, amylose content was 40.40–58.10% of total kernel starch, compared with 22.25–26.39% in parents. The percentage increase in amylose content was 63.70–153.03%. There was a significant amount of background recovery in each backcross generation: 66.80–79% in BC1F1, 72.85–88.60% in BC2F1, and 84.45–93.70% in BC2F2. Overall, the total kernel starch content was reduced (by ~22%) in the ae1-introgressed families.
The converted lines developed in the study are enriched with kernel amylose while showing significant background recovery.
The high-amylose lines developed may be highly beneficial for diabetic patients and in the bioplastics industry, and should be suitable for growing under Indian conditions.
Keywords: ae1, amylose, diabetes, maize, marker-assisted backcross breeding, SBEs, SSR, starch.
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