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Y. Castonguay, P. Nadeau, S. Laberge, L. Vézina (1997)
Changes in Gene Expression in Six Alfalfa Cultivars Acclimated under Winter Hardening ConditionsCrop Science, 37
S. Mohapatra, L. Wolfraim, R. Poole, R. Dhindsa (1989)
Molecular cloning and relationship to freezing tolerance of cold-acclimation-specific genes of alfalfa.Plant physiology, 89 1
L. Cattivelli, D. Bartels (1989)
Cold-induced mRNAs accumulate with different kinetics in barley coleoptilesPlanta, 178
K. Bradford, P. Chandler (1992)
Expression of "Dehydrin-Like" Proteins in Embryos and Seedlings of Zizania palustris and Oryza sativa during Dehydration.Plant physiology, 99 2
M. Grossi, E. Giorni, F. Rizza, A. Stanca, L. Cattivelli (1998)
Wild and cultivated barleys show differences in the expression pattern of a cold-regulated gene family under different light and temperature conditionsPlant Molecular Biology, 38
R. Pearce, M. Dunn, J. Rixon, P. Harrison, M. Hughes (1996)
Expression of cold‐inducible genes and frost hardiness in the crown meristem of young barley (Hordeum vulgare L. cv. Igri) plants grown in different environmentsPlant Cell and Environment, 19
C. Crosatti, F. Rizza, L. Cattivelli (1994)
Accumulation and characterization of the 75 kDa protein induced by low temperature in barleyPlant Science, 97
M. Hughes, M. Dunn (1996)
The molecular biology of plant acclimation to low temperatureJournal of Experimental Botany, 47
M. Houde, R. Dhindsa, F. Sarhan (1992)
A molecular marker to select for freezing tolerance in GramineaeMolecular and General Genetics MGG, 234
J. Sambrook, E. Fritsch, T. Maniatis (2001)
Molecular Cloning: A Laboratory Manual
L. Hömmö (1994)
Hardening of some winter wheat (Triticum aestivum L.), rye (Secale cereale L.), Triticale (x Triticosecale Wittmack) and winter barley (Hordeum vulgare L.) cultivars during autumn and the final winter survival in FinlandPlant Breeding, 112
D. Gallie (1996)
Translational control of cellular and viral mRNAsPlant Molecular Biology, 32
C. Charest, C. Phan (1990)
Cold acclimation of wheat (Triticum aestivum): Properties of enzymes involved in proline metabolismPhysiologia Plantarum, 80
M. Grossi, M. Gullì, A. Stanca, L. Cattivelli (1995)
Characterization of two barley genes that respond rapidly to dehydration stressPlant Science, 105
Jonathan Phillips, M. Dunn, Monica Hughes (1997)
mRNA stability and localisation of the low-temperature-responsive barley gene family blt14Plant Molecular Biology, 33
C. Olien, J. Clark (1993)
Changes in Soluble Carbohydrate Composition of Barley, Wheat, and Rye during WinterAgronomy Journal, 85
C. Crosatti, E. Nevo, A. Stanca, L. Cattivelli (1996)
Genetic analysis of the accumulation of COR14 proteins in wild (Hordeum spontaneum) and cultivated (Hordeum vulgare) barleyTheoretical and Applied Genetics, 93
J. Levitt (1980)
Responses of Plants to Environmental Stress, 2nd Edition, Volume 1: Chilling, Freezing, and High Temperature Stresses.
(1994)
Hardening of some winter wheat
L. Cattivelli, D. Bartels (1990)
Molecular cloning and characterization of cold-regulated genes in barley.Plant physiology, 93 4
S. Lee, THH. Chen (1993)
Molecular Cloning of Abscisic Acid-Responsive mRNAs Expressed during the Induction of Freezing Tolerance in Bromegrass (Bromus inermis Leyss) Suspension Culture, 101
D. Fowler, L. Chauvin, A. Limin, F. Sarhan (1996)
The regulatory role of vernalization in the expression of low-temperature-induced genes in wheat and ryeTheoretical and Applied Genetics, 93
F. Rizza, C. Crosatti, A. Stanca, L. Cattivelli (2004)
Studies for assessing the influence of hardening on cold tolerance of barley genotypesEuphytica, 75
(1980)
Response of Plants to Environmental Stresses. Vol. 1. Chilling, Freezing, and High Temperature Stresses
M. Dunn, M. Hughes, R. Pearce, P. Jack (1990)
Molecular Characterization of a Barley Gene Induced by Cold TreatmentJournal of Experimental Botany, 41
Boguslaw Szewczyk, Lloyd Kozloff (1985)
A method for the efficient blotting of strongly basic proteins from sodium dodecyl sulfate-polyacrylamide gels to nitrocellulose.Analytical biochemistry, 150 2
(1997)
mRNA stability and localisation of the low - temperature responsive gene family blt 14
L. Cattivelli, G. Delogu, V. Terzi, A. Stanca, G. Slafer (1994)
Progress in Barley BreedingGenetic Improvement of Field Crops
S. Kolar, P. Hayes, T. Chen, R. Linderman (1991)
Genotypic Variation for Cold Tolerance in Winter and Facultative BarleyCrop Science, 31
J. Levitt (1980)
Chilling, Freezing, and High Temperature Stresses
(1996)
netic analysis of the accumulation of COR 14 proteins in wild ( Hordeum spontaneum ) and cultivated ( Hordeum vulgare ) bar
C. Crosatti, C. Soncini, A. Stanca, L. Cattivelli (2004)
The accumulation of a cold-regulated chloroplastic protein is light-dependentPlanta, 196
Winterhardiness is a basic trait for successful winter survival barley (Hordeum vulgare L.) crop. Freezing tolerance, a fundamental component of winterhardiness, is based on an inducible process known as hardening or cold acclimation that occurs when plants are exposed to low non-freezing temperatures. In the recent years, many temperature-dependent genes specifically expressed during hardening have been isolated. Current data on relationship between gene expression and cold tolerance are mostly based on plants grown and hardened under environmentally controlled conditions and, usually, over a short period of time. In order to verify whether variations in the molecular response to cold are likely to be of significant adaptive value under natural environments, we have followed the accumulation of several COR genes ( pt59, pao86 and paf93) and proteins (COR14a and COR14b) during the 1996/97 and 97/98 winter seasons in barley cultivars with contrasting winterhardiness capacity grown under field conditions. In the 1996/97 experiment, a winter cultivar Onice and a spring cultivar Gitane were tested for the accumulation of the cold-regulated genes and proteins. The ability of the plants to promote a strong molecular response to cold was found to be associated with the winterhardiness capacity of the two cultivars. This result was further tested in the winter season 1997/98 using 10 barley varieties. All winter cultivars showed high accumulation of the cold-regulated proteins COR14a and COR14b, while some variations for this character were detected in the spring cultivars suggesting that the selection for winter survival has been effective to fix the high COR14 accumulation capacity. We conclude that a high level of COR14 may be a component the winter survival capacity of barley.
Euphytica – Springer Journals
Published: Oct 14, 2004
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