Abstract
The success of a hybrid breeding program is dependent on available heterotic patterns for exploitation of grain-yield heterosis. The efficiency of the assignment of germplasm lines into heterotic groups is a prerequisite for obtaining useful heterotic patterns among germplasm lines. A total of 256 maize hybrids, comprising 244 top crosses, six diallel cross hybrids, and six checks, were grown under Striga infestation, drought, and optimal conditions, from 2015 to 2017. The study determined the combining abilities of the parental inbreds, classified the inbreds into heterotic groups, and compared the efficiencies of the following four grouping methods for classifying the inbreds: specific combining ability (SCA) effect of grain yield; general combining ability (GCA) effects of multiple traits (HGCAMT); SCA and GCA (HSGCA) for yield; and single nucleotide polymorphism-based genetic distance (SNP-based genetic distance (GD)). Significant GCA and/or SCA mean squares were revealed for most measured traits in all test environments. Sums of squares (SS) due to GCA were higher than SCA SS for measured traits in all test environments. The HSGCA, SCA, and SNP-based GD methods identified four heterotic groups, whereas the HGCAMT identified three groups, in all environments. The additive gene effect was preponderant in the inheritance of most measured traits. The efficiencies of the grouping methods varied with the test environments. The HSGCA and SCA methods were the most efficient for grouping in all test conditions. For practical breeding purposes, the HGCAMT and HSGCA methods were recommended under Striga infestation and drought, respectively. The heterotic patterns, which were revealed in this study, were effective for planning hybridization schemes for developing high-yielding, Striga-tolerant/resistant, and drought-tolerant maize hybrids for stressful environments.
Highlights
The HGCAMT and HSGCA methods were recommended under Striga infestation and drought, respectively
The development of hybrid maize for the exploitation of grain yield heterosis has contributed to making maize (Zea mays L.) a crop of economic importance in sub-Saharan Africa (SSA), satisfying the growing requirement for a nutritional crop for the people in the subregion
In individual and combined environments, significant (p < 0.05/0.01) GCALine × E, and specific combining ability (SCA)×E mean squares were observed for all traits except
Summary
The development of hybrid maize for the exploitation of grain yield heterosis has contributed to making maize (Zea mays L.) a crop of economic importance in sub-Saharan Africa (SSA), satisfying the growing requirement for a nutritional crop for the people in the subregion. Several biotic and abiotic stress factors including drought and infestation by Striga hermonthica, a parasitic weed, have constrained maize cultivation in SSA. Concerted research efforts are continually required to identify parental resources for the development of hybrids adapted to areas experiencing the stresses. According to Adebayo and Menkir [2], drought causes as high as 15 and 17% reductions in annual grain yield, respectively, in West and Central Africa and the tropics. Drought occurrence when the maize plant is most responsive has caused up to 90% reduction in grain yield [3]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
