Salt Tolerance in the Triticeae: The Contribution of the D Genome to Cation Selectivity in Hexaploid Wheat

Salt Tolerance in the Triticeae: The Contribution of the D Genome to Cation Selectivity in Hexaploid Wheat

Inorganic cation concentrations were measured in shoots of hexaploid bread wheat (Triticum aestivum L.) and its presumed ancestors grown at 100 mol m−3 external NaCl. Aegilops squarrosa and T. aestivum had high K/Na ratios while T. dicoccoides and Ae. speltoides had low K/Na ratios. T. monococcum al...

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Bibliographic Details
Published in:Journal of experimental botany Vol. 38; no. 2; pp. 254 - 269
Main Authors: SHAH, S. H., GORHAM, J., FORSTER, B. P., WYN JONES, R. G.
Format: Journal Article
Language:English
Published: Oxford Oxford University Press 01-02-1987
CLARENDON PRESS
Subjects:
Adaptation to environment and cultivation conditions
Aegiops squarrosa
Agronomy. Soil science and plant productions
Biological and medical sciences
D genome
Diploidy
Fundamental and applied biological sciences. Psychology
Genetics and breeding of economic plants
Genomes
Hexaploidy
Osmosis
Plant roots
Plants
Salt stress
Salt tolerance
Seedlings
synthetic hexaploids
Tetraploidy
Varietal selection. Specialized plant breeding, plant breeding aims
Wheat
Monocotyledones
Hexaploidy
Nutrition
Interspecific comparison
Inheritance
Artificial selection
Tolerance
Genotype
Selectivity
Cereal crop
Salinity
Genetic transfer
Tetraploidy
Inorganic cation
Gramineae
Angiospermae
Genetic improvement
Spermatophyta
Chemical composition
Synthetic variety
Species
Comparative study
Wild parent
Triticum aestivum
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Summary:Inorganic cation concentrations were measured in shoots of hexaploid bread wheat (Triticum aestivum L.) and its presumed ancestors grown at 100 mol m−3 external NaCl. Aegilops squarrosa and T. aestivum had high K/Na ratios while T. dicoccoides and Ae. speltoides had low K/Na ratios. T. monococcum although having a high K/Na ratio, had the highest total salt load of the five species tested. The effect of the D genome (from Ae. squarrosa) was further investigated in seedlings of synthetic hexaploid wheats, and was again found to improve cation selectivity. Different responses were obtained from root and shoot tissue in this experiment. One synthetic hexaploid and its constituent parents were grown to maturity at 100 mol m-3 NaCl and the yields recorded. Despite complications due to increased tillering in the stressed hexaploid, it was possible to show that the addition of the D genome enhanced yield characteristics in the hexaploid wheat. An experiment with synthetic hexaploids derived from the tetraploid wheat variety “Langdon” and several Ae. squarrosa accessions revealed differences in vegetative growth rates between the different synthetic hexaploids in the presence or absence of 150 or 200 mol m−3 external NaCl. The possibility of transferring salt tolerance genes from Ae. squarrosa to hexaploid wheat using synthetic hexaploids as bridging species is discussed.
Bibliography:3To whom correspondence should be addressed
ark:/67375/HXZ-PGD3Q308-R
istex:F066CF81D3B83B629A7D13FDD6A004CB4677D233
ArticleID:38.2.254
ISSN:0022-0957
1460-2431
DOI:10.1093/jxb/38.2.254