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Temperature-perception, molecules and mechanisms
Rafael Catala, Julio Salinas
Language English Country Czech Republic
Document type Review
NLK
Free Medical Journals
from 2003 to 2013
Freely Accessible Science Journals
from 2003 to 2013
ROAD: Directory of Open Access Scholarly Resources
from 2002
- MeSH
- Adaptor Proteins, Signal Transducing genetics immunology MeSH
- Acclimatization physiology genetics immunology MeSH
- Arabidopsis cytology genetics immunology MeSH
- Adaptation, Biological physiology genetics immunology MeSH
- Biotechnology methods trends MeSH
- Cytosol chemistry metabolism MeSH
- Financing, Organized MeSH
- Adaptation, Physiological physiology genetics immunology MeSH
- Metabolomics methods MeSH
- Molecular Biology methods MeSH
- Cold Temperature adverse effects MeSH
- Cell Membrane Permeability physiology genetics immunology MeSH
- Proteomics methods MeSH
- Gene Expression Regulation genetics immunology MeSH
- Plants MeSH
- Publication type
- Review MeSH
The strategies used by living organisms to survive under low and freezing temperatures reveal the extraordinary adaptability of life on Earth. Understanding the molecular mechanisms underlying cold adaptation and freezing survival will provide new insights into the existing relationships between living organisms and their environment, and the possibility of developing multiple biotechnological applications. In the case of plants, the use of classical genetic and new "omics" approaches is allowing to the identification of new elements involved in regulating the cold acclimation response. The challenge ahead is to determine temperature-perception molecules and mechanisms, to uncover new internodes of multiple responses, and to integrate the regulation not only at the transcriptome but also at proteome and metabolome levels. Attaining these goals will significantly contribute global understanding the adaptive strategies plants have evolved to cope with hostile environmental conditions, and to the development biotechnological strategies to improve crop tolerance to freezing and other important abiotic stresses.
References provided by Crossref.org
Lit.: 74
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- $a The strategies used by living organisms to survive under low and freezing temperatures reveal the extraordinary adaptability of life on Earth. Understanding the molecular mechanisms underlying cold adaptation and freezing survival will provide new insights into the existing relationships between living organisms and their environment, and the possibility of developing multiple biotechnological applications. In the case of plants, the use of classical genetic and new "omics" approaches is allowing to the identification of new elements involved in regulating the cold acclimation response. The challenge ahead is to determine temperature-perception molecules and mechanisms, to uncover new internodes of multiple responses, and to integrate the regulation not only at the transcriptome but also at proteome and metabolome levels. Attaining these goals will significantly contribute global understanding the adaptive strategies plants have evolved to cope with hostile environmental conditions, and to the development biotechnological strategies to improve crop tolerance to freezing and other important abiotic stresses.
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