Öz
Kaynakça
- Bray, E.A. and Bailey, J.(2000), "Responses to abiotic stress in Biochemistry and molecular biology of plants, The American society of plant physiologists.
- Sakai, A. and larcher, w. (2002), "Frost survival of plants", springer-verlag, Heidelberg.
- Steponkus, p.l. and Webb, M.S. (1993), "Memberane destabilization during Freeze induceddehydration, "Curr. Topics plant physiol. 10:37-47
- Palva, E.T. (1994), Gene expression under low 37-47 temprature stress in stress induced Gene expression in plants, "Basraed.pp: 103-130. Harwood Academic publishers. New York.
- Levitt, M. (1999), "Responses of plants to einviyoment al stress. Academic press. Vol 1.
- Lindow, S.E. (2006), "methods of preventing frost injury caused by epiphytic ice nucleation active bacteria, "plant Dis.327-330 67:397-330.
- Franks, f. (2005), "Biophysics and Biochemistry at low temperature". Cambridge university press, Cambridge.
- Thomashow, M.f. (2002), "plant cold acclimation: Freezing to lerance genes and regulatory mechanisms. plant physiol. 50:571-599.
- Ashworth, E.N.and Anderson, J.A. (2005), "Factors plant physiol. 79:1033-1037.
- Maki, G.A.and lindow, S.E. (2004), "survival, growth and epiphytic fitness mutants of pseudomonas syringae on Leaves. j. Appl. Environ. Microboil. 60: 3790-3798
- Lindow, S.E. and conell, J.H. (1994), "Reduction of frost injury to a lmond by control of ice nucleation active bacteria. J.Amer.SoC. Hortsci. 109:48-53.
- Burk, N.and Lindow, S.E. (1998), "Interaction of antifreeze proteins from cold hardened with ice nucleation active bacteria", Cryobiology. 29: 718-720
- Dure, L. (2003), "structural motifs in LEA proteins of higher plants, in response of plants to cellular dehydration during environmental stress", plant cell. 10:539-556.
- Wang, W.and Altman A, (2003), "plant responses to drought, salinity and extreme Tempratures: Thwards genetic engineering for stress tolerance. Planta.14:218-294
- Thomasow, M.F. (1998), "Role of cold responsive Genes and protein in plant freezing to lernance. Plant physiol: 117-200.
- Sakamoto, A. and murata, N. (2000), "Genetic engineering of glycinebetaine synthesis in plants: current status and implications for enhancement of stress to lerance", J,Exp. Bot. 51:81-88.
- Iba, k. (2002), "Acclimative response to temperature stress in higher plants: Approches of gene engineering for Temperature to Lerance", Ann.Rev.plant Bio.53:225-245.
- Sari T.and Heino, p. (2002), "Biological mechanisms of low temprature stress response: cold acclimation and development of freezing in plants. Plant MOL. Bio.41:187-223.
Öz
Abstract. One of the main environmental challenges in plants life is stress caused by abiotic environmental factors such as chilling and freezing which lead to cellular water deficit. Annually damage caused by spring frost leads to billions of dollars of economic losses. Cold stress with plants growth at low temperatures or cold climates has been studied. Plants have different adaptive mechanisms to cope with adverse effects of various abiotic stresses such as cold. chilling denotes physical and physiological changes which occur as a result of plants collision with cold. Cold stress is associated with a set of adaptive paths in plants such as activating various adaptive responses regulators and physiological and metabolic changes caused by stress. The studies have proven the relationship of biological materials such as osmolytes and compatible solutes, membrane lipids, heat shock proteins and antifreeze proteins, factors to remove active oxygen and their role in plants cold stress tolerance, controlling ice nucleating bacteria etc. In the present study, genetic engineering strategies are discussed to modify and achieve physiological and molecular adoption by changing the amount and composition of mentioned materials in living creatures and manipulating the number of ice nucleating active bacteria and creating mutants lacking ice nucleation and also future perspectives in the field of plants molecular modification for cold stress tolerance.
Anahtar Kelimeler
Plants chilling Freezing genetic engineering osmolytes Ice nucleation bacteria
Kaynakça
- Bray, E.A. and Bailey, J.(2000), "Responses to abiotic stress in Biochemistry and molecular biology of plants, The American society of plant physiologists.
- Sakai, A. and larcher, w. (2002), "Frost survival of plants", springer-verlag, Heidelberg.
- Steponkus, p.l. and Webb, M.S. (1993), "Memberane destabilization during Freeze induceddehydration, "Curr. Topics plant physiol. 10:37-47
- Palva, E.T. (1994), Gene expression under low 37-47 temprature stress in stress induced Gene expression in plants, "Basraed.pp: 103-130. Harwood Academic publishers. New York.
- Levitt, M. (1999), "Responses of plants to einviyoment al stress. Academic press. Vol 1.
- Lindow, S.E. (2006), "methods of preventing frost injury caused by epiphytic ice nucleation active bacteria, "plant Dis.327-330 67:397-330.
- Franks, f. (2005), "Biophysics and Biochemistry at low temperature". Cambridge university press, Cambridge.
- Thomashow, M.f. (2002), "plant cold acclimation: Freezing to lerance genes and regulatory mechanisms. plant physiol. 50:571-599.
- Ashworth, E.N.and Anderson, J.A. (2005), "Factors plant physiol. 79:1033-1037.
- Maki, G.A.and lindow, S.E. (2004), "survival, growth and epiphytic fitness mutants of pseudomonas syringae on Leaves. j. Appl. Environ. Microboil. 60: 3790-3798
- Lindow, S.E. and conell, J.H. (1994), "Reduction of frost injury to a lmond by control of ice nucleation active bacteria. J.Amer.SoC. Hortsci. 109:48-53.
- Burk, N.and Lindow, S.E. (1998), "Interaction of antifreeze proteins from cold hardened with ice nucleation active bacteria", Cryobiology. 29: 718-720
- Dure, L. (2003), "structural motifs in LEA proteins of higher plants, in response of plants to cellular dehydration during environmental stress", plant cell. 10:539-556.
- Wang, W.and Altman A, (2003), "plant responses to drought, salinity and extreme Tempratures: Thwards genetic engineering for stress tolerance. Planta.14:218-294
- Thomasow, M.F. (1998), "Role of cold responsive Genes and protein in plant freezing to lernance. Plant physiol: 117-200.
- Sakamoto, A. and murata, N. (2000), "Genetic engineering of glycinebetaine synthesis in plants: current status and implications for enhancement of stress to lerance", J,Exp. Bot. 51:81-88.
- Iba, k. (2002), "Acclimative response to temperature stress in higher plants: Approches of gene engineering for Temperature to Lerance", Ann.Rev.plant Bio.53:225-245.
- Sari T.and Heino, p. (2002), "Biological mechanisms of low temprature stress response: cold acclimation and development of freezing in plants. Plant MOL. Bio.41:187-223.
Ayrıntılar
| Bölüm | Derleme |
|---|---|
| Yazarlar | |
| Yayımlanma Tarihi | 13 Mayıs 2015 |
| Yayımlandığı Sayı | Yıl 2015 Cilt: 36 Sayı: 3 |