Genotypic adaptation of rice to lowland hydrology in West Africa

In West Africa, the lowlands comprise a wide range of hydrological environments—from permanently flooded to permanently non-flooded conditions. Rice breeding programs must develop genotypes that are expected to perform well either across all hydrological environments or for a specific target populat...

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Bibliographic Details
Published in:Field crops research 2010-11, Vol.119 (2), p.290-298
Main Authors: Saito, K., Azoma, K., Sokei, Y.
Format: Article
Language:English
Subjects:
aerobic conditions
Aerobic rice
dry matter accumulation
duration
environmental factors
field experimentation
flooded conditions
genetic variation
genotype
Genotype × environment interaction
genotype-environment interaction
germplasm screening
grain yield
harvest index
high-yielding varieties
Inland valley
Interspecific hybrid
irrigated farming
New Rice for Africa
Oryza
Oryza glaberrima
Oryza sativa
plant adaptation
plant available water
rainfed farming
rice
vigor
yield components
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Summary:In West Africa, the lowlands comprise a wide range of hydrological environments—from permanently flooded to permanently non-flooded conditions. Rice breeding programs must develop genotypes that are expected to perform well either across all hydrological environments or for a specific target population of environments. We evaluated 14 rice ( Oryza spp.) genotypes in seven experiments during 2 years (2007 and 2008) in Benin to investigate genotype × environment (G × E) interaction for grain yield, and to identify high-yielding genotypes and plant characteristics associated with high yield. The genotypes consisted of O. sativa indica genotypes, including ‘aerobic rice genotypes’ and interspecific genotypes, developed from crossing O. sativa and O. glaberrima for upland (‘NERICA’ genotypes) and lowland conditions (‘NERICA-L’). The mean grain yield ranged from 231 to 588 g m −2 across experiments, with the higher grain yields from flooded lowland conditions. The G × E interaction accounted for 22% of the total sum of squares, with environment and genotype responsible for 71 and 8%, respectively. Three environment groups were identified from a pattern analysis on grain yield. Grouping was related to water availability, distinguishing (i) an aerobic environment, with rice grown under aerobic conditions with supplemental irrigation, (ii) a hydromorphic environment, with rice grown under rainfed conditions with drought spells at the vegetative stage, and (iii) a permanently flooded environment. An interspecific genotype WAB1159-4-10-15-1-3 produced high yields in both flooded and hydromorphic environments, while two interspecific genotypes, NERICA-L-6 and NERICA-L-54 performed well only in a flooded environment. An aerobic rice genotype B 6144F-MR-6-0-0 outyielded these three interspecific genotypes in the aerobic environment. High grain yields in the flooded and hydromorphic environments resulted from biomass accumulation rather than harvest index, whereas the higher yield in the aerobic environment was the result of harvest index rather than biomass accumulation. Genotypes with high growth vigor at 42 and 63 days after sowing tended to have higher yields in the flooded and aerobic environments. Grain yield in the hydromorphic environment was positively correlated with growth duration. We conclude that while interspecific breeding appears to offer an effective approach to improving lowland rice productivity, a systematic effort is needed to screen a wide range of
ISSN:0378-4290
1872-6852
DOI:10.1016/j.fcr.2010.07.020