The effects of temperature and the Rht3 dwarfing gene on growth, cell extension, and gibberellin content and responsiveness in the wheat leaf

The effects of temperature and the Rht3 dwarfing gene on growth, cell extension, and gibberellin content and responsiveness in the wheat leaf

The effects of low temperature and the Rht3 dwarfing gene on the dynamics of cell extension in leaf 2 of wheat were examined in relation to gibberellin (GA) content and GA-responsiveness of the extension zone. Leaf 2 of wild-type (rht3) wheat closely resembled that of the Rht3 dwarf mutant when seed...

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Bibliographic Details
Published in:Journal of experimental botany Vol. 48; no. 4; pp. 963 - 970
Main Authors: Tonkinson, C.L., Lyndon, R.F., Arnold, G.M., Lenton, J.R.
Format: Journal Article
Language:English
Published: Oxford Oxford University Press 01-04-1997
OXFORD UNIVERSITY PRESS
Subjects:
Agronomy. Soil science and plant productions
Alleles
Biological and medical sciences
Cell extension
Cell growth
Chemical agents
Dwarfing
Economic plant physiology
Epidermal cells
Fundamental and applied biological sciences. Psychology
Genotypes
gibberellin
Gibberellins
Growth and development
Growth regulators
Plant growth
Plant growth regulators
Plant physiology and development
Plants
Research Papers
Rht3 dwarfing gene
Seedlings
temperature
Vegetative apparatus, growth and morphogenesis. Senescence
wheat leaf
Monocotyledones
Growth
Gibberellin
Genotype
Plant leaf
Cereal crop
Dwarfism
Gramineae
Angiospermae
Abscisic acid
Plant growth substance
Spermatophyta
Phytohormone
Mutation
Biological accumulation
Cell
Elongation
Plant height
Triticum aestivum
Low temperature
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Summary:The effects of low temperature and the Rht3 dwarfing gene on the dynamics of cell extension in leaf 2 of wheat were examined in relation to gibberellin (GA) content and GA-responsiveness of the extension zone. Leaf 2 of wild-type (rht3) wheat closely resembled that of the Rht3 dwarf mutant when seedlings were grown at 10°C. The maximum relative elemental growth rate (REGR) within the extension zone in both genotypes was lower at 10°C than at 20°C, but the position with respect to the leaf base was unaffected by temperature. The size of the extension zone and epidermal cell lengths were similar in both genotypes at 10°C. Growth at 20°C, instead of 10°C, increased the length of the extension zone beyond the point of maximum REGR in the wild type, but not in the Rht3 mutant. Increasing temperature resulted in longer epidermal cells in the wild type. Treating wild-type plants at 10°C with gibberellic acid (GA3) also increased the length of the extension zone, but the Rht3 mutant was GA-non-responsive. However, the concentrations of endogenous GA1 and GA3 remained similar across the extension zone of wild-type plants grown at both temperatures, despite large differences in leaf growth rates. The period of accelerating REGR as cells enter the extension zone, and the maximum REGR attained, are apparently not affected by GA. It is proposed that GA functions as a stimulus for continued cell extension by preventing cell maturation in the region beyond maximum REGR and that low temperature increases the sensitivity threshold for GA action.
Bibliography:ark:/67375/HXZ-B5RXXXWN-N
istex:A0377233AFB14FC849A964EDFF1A0193EA4FE4D8
3To whom correspondence should be addressed. Fax: +44 1275 394281
ArticleID:48.4.963
ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0022-0957
1460-2431
DOI:10.1093/jxb/48.4.963