Utilizing the genetic diversity within rice cultivars

Plant breeding of rice emphasizes improvement in yield, disease resistance, and milling quality. Numerous other traits (e.g., bran carotenoids) that historically have not been selected for could provide added value in expanding niche markets, as well as be useful tools for understanding the genetic...

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Bibliographic Details
Published in:Planta 2012-03, Vol.235 (3), p.641-647
Main Authors: Belefant-Miller, Helen, Miller, Gordon H., Moldenhauer, Karen A. K.
Format: Article
Language:English
Subjects:
Agriculture
Agronomic traits
Biological and medical sciences
Biomedical and Life Sciences
Breeding - methods
Carotenoids
Carotenoids - metabolism
Crop science
Cultivars
Disease resistance
Ecology
Emerging Technologies
Forestry
Fundamental and applied biological sciences. Psychology
Genetic control
Genetic diversity
Genetic Variation - genetics
Heterozygosity
Life Sciences
Niches
Oryza - genetics
Oryza - metabolism
Oryza sativa
Phenotypic traits
Plant breeding
Plant Sciences
Plants
Rice
Seeds
Simple sequence repeats
Sprouting
Tillering
Tillers
Yellowing
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Summary:Plant breeding of rice emphasizes improvement in yield, disease resistance, and milling quality. Numerous other traits (e.g., bran carotenoids) that historically have not been selected for could provide added value in expanding niche markets, as well as be useful tools for understanding the genetic control of these traits. Residual heterozygosity is present in many rice cultivars; therefore, it is possible to select for different alíeles within an existing cultivar. By identifying and using cultivars with high levels of variability for a trait, we were able to develop separate lines from single cultivars that showed high and low levels of that trait. The rice cultivar RU9101001 and the warm-and cold-sprouting lines that were derived from it were used to demonstrate that residual heterozygosity was present within a cultivar and that the original heterozygosity was separated in the derived lines. Rice simple sequence repeat markers were heterozygous in the parent RU9101001 cultivar, but the cold-sprouting lines were homozygous for one set of alíeles and the warm-sprouting lines were homozygous for the other set. Through detailed phenotypic screening, we developed lines that exhibited low and high levels of the following traits in the specified cultivars: cold-sprouting from RU9101001 and Bonnet 73, postharvest yellowing from Tominishiki, early tillering from Hei Jaio and Tominishiki, and bran carotenoid levels from Spring. If variability exists in a cultivar, then utilization of residual heterozygosity may provide a quicker and more efficient means to develop lines with special characteristics using cultivars that are already agronomically valuable or to develop near isogenic lines for genetic and biochemical investigations.
ISSN:0032-0935
1432-2048
DOI:10.1007/s00425-011-1566-x