ABSTRACT
Low soil nitrogen (N) is one of the most important constraints to maize production in subSaharan Africa (SSA) in general and in particular the Bimodal Humid Forest Zone (BHFZ) of
Cameroon. The development and adoption of maize varieties tolerant to low N soils could reduce
the need for nitrogen inputs and significantly contribute to sustainable maize production. The
objectives of this research were to: i) identify maize production constraints and farmers preferred
maize characteristics in the Bimodal Humid Forest Zone of Cameroon; ii) identify maize
genotypes tolerant to low N soils; iii) examine the combining abilities of maize inbreds and
classify them into heterotic groups and iv) determine the effect of genotype x environment
interaction on grain yield and yield stability of maize hybrids across low N and optimal
environments. A Participatory Rural Appraisal (PRA) consisting of focus group discussions
followed by formal surveys was conducted in six villages of the Central Region in the Bimodal
Humid Forest Zone of Cameroon. Thirty nine inbreds originating from IRAD, IITA and
CIMMYT were crossed to three heterotic testers (87036, Exp1 24 and 9071) in a line x tester
scheme to generate 117 F1 hybrids. The 117 F1 hybrids along with 4 checks were evaluated under
low N (20 kg ha-1
) and optimum N (100 kg ha-1 N) at two location viz., Mbalmayo and
Nkolbisson, during the minor season of 2012 and minor and major seasons of 2013. Genotype x
environment interaction and grain yield stability of 80 hybrids were assessed across 11
environments under low and optimum N using AMMI and GGE biplot analysis. The study
revealed that low soil fertility and high cost of fertilizers were among the most important
constraints to maize production in the study area. Farmers cited large grain size, soft grain
texture, large ear size, high prolificacy, early maturity, short plants, resistance to lodging,
resistance to diseases and reduced post-harvest losses as their preferred characteristics in maize
iii
varieties. Across environments, CLYN246 x 87036, CLWN201 x Exp1 24, J16-1 x Exp1 24,
1368 x 87036, ATP S6-20-Y-1 x Exp1 24 and Cam inb gp1 17 x 87036 were higher yielding
than 87036 x Exp1 24, the commercial hybrid used as check in the study. Among these hybrids,
CLWN201 x Exp1 24, J16-1 x Exp1 24 and 1368 x 87036 may be candidates for release. Inbreds
CLYN246, ATP S6-20-Y-1 and Cam inb gp1 17 could be used as testers to classify lines into
heterotic groups or recombined within groups to develop source populations for new inbred
development. For specific areas with low N stress, TL-11-A-1642-5 x Exp1 24, CLWN201 x
87036 and J16-1 x Exp1 24 may be candidates for release while TL-11-A-1642-5 x 87036, TZSTR-133 x 87036, CLWN201 x Exp1 24 and J16-1 x Exp1 24 could be proposed for release for
optimal N conditions. Both additive and non-additive gene action influenced grain yield under
low N with predominance of non-additive genetic effects while additive gene action was
predominant under optimum conditions. Hybrid development could therefore be employed to
exploit non additive gene action under low N. Based on SCA and yield performance of test
crosses under low and optimum N, lines were classified into three heterotic groups for each
environment; group A (anti-87036), group B (anti-Exp1 24) and group C (anti-9071). Lines from
each group will serve as germplasm for development of the second generation of inbreds.
Analysis of variance for grain yield revealed highly significant genotype x environment
interactions. The GGE biplot analysis divided the study area into three mega environments. One
mega-environment included enviroments related with the major season of the year while the two
others included environments related to the minor season. Hybrid 1368 x 87036 was identified as
the highest yielding hybrid in minor season while TL-11-A-1642-5 x 87036 was the best hybrid
for major season. Hybrid TL-11-A-1642-5 x 87036 was the outstanding hybrid, combining high
yield and stability and has the potential for commercialization across environments.
Edu, F (2021). General Analysis of Tolerance to Low Soil Nitrogen in Immediate Maturing Maize Inbred Lines. Afribary.com: Retrieved April 17, 2021, from https://afribary.com/works/general-analysis-of-tolerance-to-low-soil-nitrogen-in-immediate-maturing-maize-inbred-lines
Frontiers, Edu. "General Analysis of Tolerance to Low Soil Nitrogen in Immediate Maturing Maize Inbred Lines" Afribary.com. Afribary.com, 07 Apr. 2021, https://afribary.com/works/general-analysis-of-tolerance-to-low-soil-nitrogen-in-immediate-maturing-maize-inbred-lines . Accessed 17 Apr. 2021.
Frontiers, Edu. "General Analysis of Tolerance to Low Soil Nitrogen in Immediate Maturing Maize Inbred Lines". Afribary.com, Afribary.com, 07 Apr. 2021. Web. 17 Apr. 2021. < https://afribary.com/works/general-analysis-of-tolerance-to-low-soil-nitrogen-in-immediate-maturing-maize-inbred-lines >.
Frontiers, Edu. "General Analysis of Tolerance to Low Soil Nitrogen in Immediate Maturing Maize Inbred Lines" Afribary.com (2021). Accessed April 17, 2021. https://afribary.com/works/general-analysis-of-tolerance-to-low-soil-nitrogen-in-immediate-maturing-maize-inbred-lines