Compatible Solute Engineering in Plants for Abiotic Stress Tolerance - Role of Glycine Betaine
Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are the most destructive. Different strategies have been proposed for management of these stresses. Being a complex trait, conventional breeding approaches have resulted in less success. Biotec...
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| Published in | Current genomics Vol. 14; no. 3; pp. 157 - 165 |
|---|---|
| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
United Arab Emirates
Bentham Science Publishers Ltd
01.05.2013
Bentham Science Publishers |
| Subjects | |
| Online Access | Get full text |
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| Abstract | Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are
the most destructive. Different strategies have been proposed for management of these stresses. Being a complex trait,
conventional breeding approaches have resulted in less success. Biotechnology has emerged as an additional and novel
tool for deciphering the mechanism behind these stresses. The role of compatible solutes in abiotic stress tolerance has
been studied extensively. Osmotic adjustment, at the physiological level, is an adaptive mechanism involved in drought or
salinity tolerance, which permits the maintenance of turgor under conditions of water deficit, as it can counteract the effects
of a rapid decline in leaf water potential. Increasing evidence from a series of in vivo and in vitro studies of the
physiology, biochemistry, genetics, and molecular biology of plants suggest strongly that Glycine Betaine (GB) performs
an important function in plants subjected to environmental stresses. It plays an adaptive role in mediating osmotic adjustment
and protecting the sub-cellular structures in stressed plants, protection of the transcriptional and translational machineries
and intervention as a molecular chaperone in the refolding of enzymes. Many important crops like rice do not
accumulate glycinebetaine under stress conditions. Both the exogenous application of GB and the genetically engineered
biosynthesis of GB in such crops is a promising strategy to increase stress tolerance. In this review we will discuss the
importance of GB for abiotic stress tolerance in plants. Further, strategies like exogenic application and transgenic development
of plants accumulating GB will be also be discussed. Work done on exogenic application and genetically engineered
biosynthesis of GB will be listed and its advantages and limitations will be described. |
|---|---|
| AbstractList | Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are
the most destructive. Different strategies have been proposed for management of these stresses. Being a complex trait,
conventional breeding approaches have resulted in less success. Biotechnology has emerged as an additional and novel
tool for deciphering the mechanism behind these stresses. The role of compatible solutes in abiotic stress tolerance has
been studied extensively. Osmotic adjustment, at the physiological level, is an adaptive mechanism involved in drought or
salinity tolerance, which permits the maintenance of turgor under conditions of water deficit, as it can counteract the effects
of a rapid decline in leaf water potential. Increasing evidence from a series of in vivo and in vitro studies of the
physiology, biochemistry, genetics, and molecular biology of plants suggest strongly that Glycine Betaine (GB) performs
an important function in plants subjected to environmental stresses. It plays an adaptive role in mediating osmotic adjustment
and protecting the sub-cellular structures in stressed plants, protection of the transcriptional and translational machineries
and intervention as a molecular chaperone in the refolding of enzymes. Many important crops like rice do not
accumulate glycinebetaine under stress conditions. Both the exogenous application of GB and the genetically engineered
biosynthesis of GB in such crops is a promising strategy to increase stress tolerance. In this review we will discuss the
importance of GB for abiotic stress tolerance in plants. Further, strategies like exogenic application and transgenic development
of plants accumulating GB will be also be discussed. Work done on exogenic application and genetically engineered
biosynthesis of GB will be listed and its advantages and limitations will be described. Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are the most destructive. Different strategies have been proposed for management of these stresses. Being a complex trait, conventional breeding approaches have resulted in less success. Biotechnology has emerged as an additional and novel tool for deciphering the mechanism behind these stresses. The role of compatible solutes in abiotic stress tolerance has been studied extensively. Osmotic adjustment, at the physiological level, is an adaptive mechanism involved in drought or salinity tolerance, which permits the maintenance of turgor under conditions of water deficit, as it can counteract the effects of a rapid decline in leaf water potential. Increasing evidence from a series of in vivo and in vitro studies of the physiology, biochemistry, genetics, and molecular biology of plants suggest strongly that Glycine Betaine (GB) performs an important function in plants subjected to environmental stresses. It plays an adaptive role in mediating osmotic adjustment and protecting the sub-cellular structures in stressed plants, protection of the transcriptional and translational machineries and intervention as a molecular chaperone in the refolding of enzymes. Many important crops like rice do not accumulate glycinebetaine under stress conditions. Both the exogenous application of GB and the genetically engineered biosynthesis of GB in such crops is a promising strategy to increase stress tolerance. In this review we will discuss the importance of GB for abiotic stress tolerance in plants. Further, strategies like exogenic application and transgenic development of plants accumulating GB will be also be discussed. Work done on exogenic application and genetically engineered biosynthesis of GB will be listed and its advantages and limitations will be described. Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are the most destructive. Different strategies have been proposed for management of these stresses. Being a complex trait, conventional breeding approaches have resulted in less success. Biotechnology has emerged as an additional and novel tool for deciphering the mechanism behind these stresses. The role of compatible solutes in abiotic stress tolerance has been studied extensively. Osmotic adjustment, at the physiological level, is an adaptive mechanism involved in drought or salinity tolerance, which permits the maintenance of turgor under conditions of water deficit, as it can counteract the effects of a rapid decline in leaf water potential. Increasing evidence from a series of in vivo and in vitro studies of the physiology, biochemistry, genetics, and molecular biology of plants suggest strongly that Glycine Betaine (GB) performs an important function in plants subjected to environmental stresses. It plays an adaptive role in mediating osmotic adjustment and protecting the sub-cellular structures in stressed plants, protection of the transcriptional and translational machineries and intervention as a molecular chaperone in the refolding of enzymes. Many important crops like rice do not accumulate glycinebetaine under stress conditions. Both the exogenous application of GB and the genetically engineered biosynthesis of GB in such crops is a promising strategy to increase stress tolerance. In this review we will discuss the importance of GB for abiotic stress tolerance in plants. Further, strategies like exogenic application and transgenic development of plants accumulating GB will be also be discussed. Work done on exogenic application and genetically engineered biosynthesis of GB will be listed and its advantages and limitations will be described. Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are the most destructive. Different strategies have been proposed for management of these stresses. Being a complex trait, conventional breeding approaches have resulted in less success. Biotechnology has emerged as an additional and novel tool for deciphering the mechanism behind these stresses. The role of compatible solutes in abiotic stress tolerance has been studied extensively. Osmotic adjustment, at the physiological level, is an adaptive mechanism involved in drought or salinity tolerance, which permits the maintenance of turgor under conditions of water deficit, as it can counteract the effects of a rapid decline in leaf water potential. Increasing evidence from a series of in vivo and in vitro studies of the physiology, biochemistry, genetics, and molecular biology of plants suggest strongly that Glycine Betaine (GB) performs an important function in plants subjected to environmental stresses. It plays an adaptive role in mediating osmotic adjustment and protecting the sub-cellular structures in stressed plants, protection of the transcriptional and translational machineries and intervention as a molecular chaperone in the refolding of enzymes. Many important crops like rice do not accumulate glycinebetaine under stress conditions. Both the exogenous application of GB and the genetically engineered biosynthesis of GB in such crops is a promising strategy to increase stress tolerance. In this review we will discuss the importance of GB for abiotic stress tolerance in plants. Further, strategies like exogenic application and transgenic development of plants accumulating GB will be also be discussed. Work done on exogenic application and genetically engineered biosynthesis of GB will be listed and its advantages and limitations will be described.Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are the most destructive. Different strategies have been proposed for management of these stresses. Being a complex trait, conventional breeding approaches have resulted in less success. Biotechnology has emerged as an additional and novel tool for deciphering the mechanism behind these stresses. The role of compatible solutes in abiotic stress tolerance has been studied extensively. Osmotic adjustment, at the physiological level, is an adaptive mechanism involved in drought or salinity tolerance, which permits the maintenance of turgor under conditions of water deficit, as it can counteract the effects of a rapid decline in leaf water potential. Increasing evidence from a series of in vivo and in vitro studies of the physiology, biochemistry, genetics, and molecular biology of plants suggest strongly that Glycine Betaine (GB) performs an important function in plants subjected to environmental stresses. It plays an adaptive role in mediating osmotic adjustment and protecting the sub-cellular structures in stressed plants, protection of the transcriptional and translational machineries and intervention as a molecular chaperone in the refolding of enzymes. Many important crops like rice do not accumulate glycinebetaine under stress conditions. Both the exogenous application of GB and the genetically engineered biosynthesis of GB in such crops is a promising strategy to increase stress tolerance. In this review we will discuss the importance of GB for abiotic stress tolerance in plants. Further, strategies like exogenic application and transgenic development of plants accumulating GB will be also be discussed. Work done on exogenic application and genetically engineered biosynthesis of GB will be listed and its advantages and limitations will be described. |
| Author | Javed Iqbal Mir Naorem Brajendra Singh Athokpam Haribhushan Shabir Hussain Wani |
| AuthorAffiliation | 3 Biotechnology Laboratory, Central Institute of Temperate Horticulture, Rangreth, Srinagar, Jammu and Kashmir 190007, India 1 Farm Science Centre-(KVK) Hengbung, Senapati, Manipur, India 795129 2 Department of Plant Breeding and Genetics, COA, Central Agricultural University, Imphal, Manipur, India 795004 |
| AuthorAffiliation_xml | – name: 1 Farm Science Centre-(KVK) Hengbung, Senapati, Manipur, India 795129 – name: 2 Department of Plant Breeding and Genetics, COA, Central Agricultural University, Imphal, Manipur, India 795004 – name: 3 Biotechnology Laboratory, Central Institute of Temperate Horticulture, Rangreth, Srinagar, Jammu and Kashmir 190007, India |
| Author_xml | – sequence: 1 givenname: Shabir surname: Hussain Wani fullname: Hussain Wani, Shabir – sequence: 2 givenname: Naorem surname: Brajendra Singh fullname: Brajendra Singh, Naorem – sequence: 3 givenname: Athokpam surname: Haribhushan fullname: Haribhushan, Athokpam – sequence: 4 givenname: Javed surname: Iqbal Mir fullname: Iqbal Mir, Javed |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/24179438$$D View this record in MEDLINE/PubMed |
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| Keywords | Osmoprotectants Compatible solute Abiotic stress Choline Genetic engineering Glyicine betaine Salinity |
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| Snippet | Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are
the most destructive. Different strategies have... Abiotic stresses collectively are responsible for crop losses worldwide. Among these, drought and salinity are the most destructive. Different strategies have... |
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| SubjectTerms | Oryza sativa |
| Title | Compatible Solute Engineering in Plants for Abiotic Stress Tolerance - Role of Glycine Betaine |
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