Variability within cotton cultivars for yield, fibre quality and physiological traits

Selection within elite cotton cultivars is ineffective; it is believed that they are genetically homogeneous. Research in other crops, however, has verified significant intra-cultivar variation based either on phenotypic differentiation or molecular analysis techniques. The present study primarily i...

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Bibliographic Details
Published in:The Journal of agricultural science 2008-08, Vol.146 (4), p.483-490
Main Authors: TOKATLIDIS, I. S., TSIKRIKONI, C., TSIALTAS, J. T., LITHOURGIDIS, A. S., BEBELI, P. J.
Format: Article
Language:English
Subjects:
Agricultural production
Agronomy. Soil science and plant productions
artificial selection
ash content
Biological and medical sciences
carbon
Carbon isotopes
Cotton
crop yield
Cultivars
fiber quality
Fundamental and applied biological sciences. Psychology
Genetic diversity
genetic variation
Genetics
Genetics and breeding of economic plants
genotype
Gossypium hirsutum
honeycomb selection
Offspring
phenotype
Physiology
plant density
plant genetic resources
plant physiology
potassium
seed cotton
selfing
stable isotopes
Variables
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Summary:Selection within elite cotton cultivars is ineffective; it is believed that they are genetically homogeneous. Research in other crops, however, has verified significant intra-cultivar variation based either on phenotypic differentiation or molecular analysis techniques. The present study primarily investigated possible intra-cultivar variation for seedcotton yield. Honeycomb selection within three elite cotton cultivars, on the basis of single-plant seedcotton yield and under the ultra-low density of 1·2 plants/m2, was performed. From each cultivar, six selfed (hand-pollinated) plants were selected and seed of each selected plant constituted a separate line. The 18 first generation lines were evaluated in three locations at a density of 1·2 plants/m2. Within each line, the 10 selfed plants which yielded the highest were selected. Mixed seed from these selected plants constituted the respective second generation line. Offspring performance of the 18 second generation lines was also tested in three locations at a density of 1·2 plants/m2. The results were indicative of intra-cultivar variation, since significant differentiation between lines of each cultivar was found for seedcotton yield per plant, averaged across two years and three locations. Additionally, significant intra-cultivar variation was found for fibre quality properties (length and micronaire, but not strength and uniformity) averaged across two years in a single location, as well as for physiological traits (leaf carbon isotope discrimination, ash content and K concentration) averaged across two years and three locations. In comparison with the original cultivars the second generation lines had higher seedcotton yields supporting the existence of exploitable genetic variation. The conclusion was that honeycomb selection in the absence of competition could be an effective technique in breeders' seed treatment in order to avoid gradual degeneration and beneficially exploit any latent or newly developed genetic variation.
ISSN:0021-8596
1469-5146
DOI:10.1017/S0021859608007867