Physiology and Molecular Biology of Stress ... - KHAM PHA MOI

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Salt Stress 87 Dajic, Z., Stevanovic, B. and Ajder, S. (1998). The role of ions in osmotic adjustment of several euhalophytes grown in natural habitat. Ekologija (Belgrade), 33, 169-174. Dalton, F.N., Maggio, A. and Piccinni, G. (1997). Effect of root temperature on plant response functions for tomato: comparison of static and dynamic salinity stress indices. Plant Soil 192, 307-319. Dalton, F.N., Maggio, A. and Piccinni, G. (2000). Simulation of shoot chloride accumulation: separation of physical and biochemical processes governing plant salt tolerance. Plant Soil 219, 1- 11. Deal, K, R., Goyal, S. and Dvorak, J. (1999). Arm location of Lophopyrum elongatum genes affecting K + /Na + selectivity under salt stress. Euphytica 108, 193-198. Dionisiosese, M.L. and Tobita, S. (1998). Antioxidant responses of rice seedlings to salinity stress. Plant Sci. 135, 1-9. Dracup, M.N.H. and Greenway, H. (1985). A procedure for isolating vacuoles from leaves of the halophyte Suaeda maritima. Plant Cell Environ. 8, 149-154. Dschida, D.J., Platt-Aloia, K.A. and Thomson, W.W. (1992). Epidermal peels of Avicennia germinans (L.) Stearn: a useful system to study the function of salt glands. Ann. Bot. 70, 501-509. Dziadczyk, P., Bolibok, H., Tyrka, M. and Hortynski, J.A. (2003). In vitro selection of strawberry (Fragaria ananassa Duch.) clones tolerant to salt stress. Euphytica. 132, 49-55. Echeverria, E. (2000). Vesicle-mediated solute transport between the vacuole and the plasma membrane. Plant Physiol. 123, 1217-1226. El-Haddad, S.H. and Noaman, M.M. (2001). Leaching requirement and salinity threshold for the yield and agronomic characteristics of halophytes under salt stress. J. Arid Environ. 49, 865- 874. El-Hamdaoui, A., Redondo-Nieto, M., Rivilla, R., Bonilla, I. and Bolanos, L. (2003). Effects of boron and calcium nutrition on the establishment of the Rhizobium leguminosarum- pea (Pisum sativum) symbiosis and nodule development under salt stress. Plant Cell Environ, 26, 1003- 1011. Ellis, R.P., Forster, B.P., Gordon, D.C., Handley, L.L., Keith, R.P., Lawrence, P., et al. (2002). Phenotype/genotype associations for yield and salt tolerance in a barley mapping population segregating for two dwarfing genes. J. Exp. Bot. 53, 1163-1176. Essa, T.A. (2002). Effect of salinity stress on growth and nutrient composition of three soybean (Glycine max L. Merill) cultivars. J. Agron. Crop Sci, 188, 86-93. Fitter, A.H. and Hay, R.K.M. (1989). Environmental Physiology of Plants. London, San Diego, New York, Boston, Sydney, Tokyo, Toronto: Academic Press. Flowers, T.J. (2004). Improving crop salt tolerance. J. Exp. Bot. 55, 307-319. Flowers, T.J. and Dalmond, D. (1992). Protein synthesis in halophytes: the influence of potassium, sodium and magnesium in vitro. Plant Soil 146, 153-161. Flowers, T.J. and Hajibagheri, M.A. (2001). Salinity tolerance in Hordeum vulgare: ion concentrations in root cells of cultivars differing in salt tolerance. Plant Soil 231, 1-9. Flowers, T.J., Hajibagheri, M.A. and Yeo, A.R. (1991). Ion accumulation in the cell walls of rice plants growing under saline conditions: evidence for the Oertli hypothesis. Plant Cell Environ 14, 319-325. Flowers, T.J., Koyama, M.L., Flowers, S.A., Chinta Sudhakar, Singh, K.P. and Yeo, A.R. (2000). QTL: their place in engineering tolerance of rice to salinity. J.Exp. Bot, 51, (MP Special Issue), 99-106. Flowers, T.J., Troke, P.F. and Yeo, A.R. (1977). The mechanism of salt tolerance in halophytes. Annu. Rev. Plant Physiol, 28, 89-121. Flowers, T.J. and Yeo, A.R. (1988). Ion relations of salt tolerance. In D.A. Baker and J.L. Hall (Eds.), Solute Transport in Plant Cells and Tissues, Harlow: Longman Scientific and Technical. (pp. 392-416). Flowers, T.J. and Yeo, A.R. (1992). Solute Transport in Plants. Glasgow, Scotland: Blackie. 176 pp. Flowers, T.J. and Yeo, A.R. (1995). Breeding for salinity resistance in crop plants: where next? Aust. J. Plant Physiol 22, 875-884.
88 Z . Dajic Foolad, M.R. and Jones, R.A. (1993). Mapping salt-tolerance genes in tomato (Lycopersicon esculentum) using trait-based marker analysis. Theor. Appl. Genet. 87, 184-192. Foolad, M.R., Zhang, L.P. and Lin, G.Y. (2001). Identification and validation of QTLs for salt tolerance during vegetative growth in tomato by selective genotyping. Genome. 44, 444-454. Forment, J., Naranjo, M.A., Roldan, M., Serrano, R., and Vicente, O. (2002). Expression of Arabidopsis Sr-like splicing proteins confers salt tolerance in yeast and transgenic plants. Plant J. 30, 511- 519. Fortmeier, R. and Schubert, S. (1995). Salt tolerance of maize (Zea mays L.): the role of sodium exclusion. Plant Cell Environ. 18, 1041-1047. Fougere, F., Le-Rudilier, D. and Streeter, J.G. (1991). Effects of salt stress on amino acid, organic acid and carbohydrate composition of roots, bacteroids and cytosol of alfalfa (Medicago sativa L.). Plant Physiol. 96, 1228-1236. Francois, L.E. and Maas, E.V. (1994). Crop response and management of salt-affected soils. In M. Pessarakli (Eds.), Handbook of Plant and Crop Stress (pp. 169-201). New York: Marcel Dekker. Freitas, H. and Breckle, S.W. (1992). Importance of bladder hairs for the salt tolerance of field grown Atriplex species from a Portuguese salt marsh. Flora 187, 283-297. Fukuda, A., Nakamura, A. and Tanaka, Y. (1999). Molecular cloning and expression of the Na + /H + exchanger gene in Oryza sativa. Biochim. Biophys. Acta 1446, 149-155. Garay-Arroyo, A., Colmenero-Flores, J.M., Garciarrubio, A. and Covarrubias, A.A. (2000). Highly hydrophilic proteins in prokaryotes and eukaryotes are common during conditions of water deficit. J. Biol. Chem. 275, 5668-5674. Garcia, A., Rizzo, C.A., Ud-Din, J., Bartos, S.L., Senadhira, D., Flowers, T.J., et al. (1997). Sodium and potassium transport to the xylem are inherited independently in ice, and the mechanism of sodium: potassium selectivity differs between rice and wheat. Plant Cell Environ. 20, 1167- 1174. Garcia, A., Senadhira, D., Flowers, T.J. and Yeo. A.R. (1995). The effects of selection for sodium transport and of selection for agronomic characteristics upon salt resistance in rice (Oryza sativa L.). Theor. Appl. Genet. 90, 1106-1111. Garcia, A.B., Engler, J.D., Claes, B., Villarroel, R., Vanmontagu, M., Gerats, T., et al. (1998). The expression of salt-responsive gene salT from rice is regulated by hormonal and developmental cues. Planta 207, 172-180. Garciadeblas, B., Senn, M.E., Banuelos, M.A. and Rodriguez-Navarro, A. (2003). Sodium transport and HKT transporters: the rice model. Plant J. 36, 788-801. Garg, A.K., Kim, J.K., Owens, T.G., Ranwala, A.P., Do Choi, Y., Kochian, L.V., et al. (2002). Trehalose accumulation in rice plants confers high tolerance levels to different abiotic stresses. Proc. Nat. Acad. Sci. USA, 99, 15898-15903. Gaxiola, R., Li, J., Undurraga, S., Dang, L.M., Allen, S.L. and Fink, G.R. (2001). Drought- and salttolerant plants result from overexpression of the AVP1 H + -pump. Proc. Nat. Acad. Sci. USA, 98, 11444-11449. Ghosh, S., Bagchi, S. and Majumder, A.L. (2001). Chloroplast fructose 1,6 bisphosphatase from Oryza differs in salt tolerance property from the Porteresia enzyme and is protected by osmolytes. Plant Sci. 160, 1171-1181. Gimmler, H. (2000). Primary sodium plasma membrane ATPases in salt tolerant algae: facts and fictions. J. Exp. Bot. 51, 1171-1178. Ginzberg, I., Stein, H., Kapulnik, Y., Szabados, L., Strizhov, N., Schell, J., et al. (1999). Isolation and characterization of two different cDNAs of delta (1) pyrroline-5- carboxylate synthase in alfalfa, transcriptionally induced upon salt stress. Plant Mol. Biol. 38, 755-764. Glenn, E.P., Brown, J.J. and Blumwald, E. (1999). Salt tolerance and crop potential of halophytes. Crit. Rev.Plant Sci. 18, 227-255. Glenn, E.P. and O’Leary, J.W. (1985). Productivity and irrigation requirements of halophytes grown with seawater in the Sonora Desert. J. Arid Environ. 9, 81-91. Gorham, J. (1990). Salt tolerance in Triticeae: K/Na discrimination in synthetic hexaploid wheats. J. Exp. Bot. 41, 623-627.
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PHYSIOLOGY AND MOLECULAR BIOLOGY OF
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A C.I.P. Catalogue record for this
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About the Editors K.V. Madhava Rao
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LIST OF CONTRIBUTORS K. AKASHI Grad
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List of Contributors xiii NAVINDER
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PREFACE Increasing agricultural pro
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2 K.V. Madhava Rao Abiotic stresses
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4 K.V. Madhava Rao SOME O THE PROMI
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6 K.V. Madhava Rao 2. WATER STRESS
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8 K.V. Madhava Rao 5. FREEZING STRE
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10 K.V. Madhava Rao of these pathwa
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12 K.V. Madhava Rao Bray, E.A. (199
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14 K.V. Madhava Rao Rao, K.V. Madha
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16 A. Yokota, K. Takahara and K. Ak
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Page 52 and 53: 41 CHAPTER 3 SALT STRESS ZORA DAJIC
Page 54 and 55: Salt Stress 43 activities (mainly i
Page 56 and 57: Salt Stress 45 In summary, mechanis
Page 58 and 59: Salt Stress 47 tolerance research i
Page 60 and 61: Salt Stress 49 need to rely on sodi
Page 62 and 63: Salt Stress 51 (Echeverria, 2000).
Page 64 and 65: Salt Stress 53 Therefore, the capac
Page 66 and 67: Salt Stress 55 Reduced plant growth
Page 68 and 69: Salt Stress 57 Table 3. Salt tolera
Page 70 and 71: Salt Stress 59 6.2. Nitrogen Fixati
Page 72 and 73: Salt Stress 61 A significant number
Page 74 and 75: Salt Stress 63 macromolecules, irre
Page 76 and 77: Salt Stress 65 8.2. Ion Homeostasis
Page 78 and 79: Salt Stress 67 1997), is speculated
Page 80 and 81: Salt Stress 69 together with the At
Page 82 and 83: Salt Stress 71 important role in si
Page 84 and 85: Salt Stress 73 Figure 5. Determinan
Page 86 and 87: Salt Stress 75 9.1.Transgenic Plant
Page 88 and 89: Salt Stress 77 tolerance from halop
Page 90 and 91: Salt Stress 79 sponse and yield (Su
Page 92 and 93: Salt Stress 81 Table 5. Possible ut
Page 94 and 95: Salt Stress 83 monitored with fluor
Page 96 and 97: Salt Stress 85 Func. Plant Biol. 29
Page 100 and 101: Salt Stress 89 Gouia, H., Ghorbal,
Page 102 and 103: Salt Stress 91 Larcher, W. (1995).
Page 104 and 105: Salt Stress 93 Munns, R. and James,
Page 106 and 107: Salt Stress 95 Rausell, A., Kanhono
Page 108 and 109: Salt Stress 97 durum wheat crops gr
Page 110 and 111: Salt Stress 99 Yoshida, K. (2002).
Page 112 and 113: 102 T.D. Sharkey and S.M. Schrader
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Page 142 and 143: Freezing Stress 133 Whereas, in the
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Freezing Stress 139 (1997). However
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Freezing Stress 141 (Barnett et al.
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Freezing Stress 143 (dehydrin) prot
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Freezing Stress 145 in cytosolic Ca
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Freezing Stress 147 Phospholiphase
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Freezing Stress 149 Accumulation of
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Freezing Stress 151 Ideker, T., Gal
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Freezing Stress 153 ellin acid on f
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Freezing Stress 155 Yoshida, S. and
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158 A.R. Reddy and A.S. Raghavendra
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188 K. Janardhan Reddy constitution
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190 K. Janardhan Reddy World nitrog
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192 K. Janardhan Reddy nitrogen def
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194 K. Janardhan Reddy endoplasmic
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196 K. Janardhan Reddy drought cond
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198 K. Janardhan Reddy Manganese-de
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200 K. Janardhan Reddy zinc deficie
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202 K. Janardhan Reddy Table 12 . E
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204 K. Janardhan Reddy Table 14. Ef
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206 K. Janardhan Reddy Table 15. Th
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208 K. Janardhan Reddy Table 17. Co
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210 K. Janardhan Reddy 18. MOLECULA
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212 K. Janardhan Reddy Bush, D.S.,
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214 K. Janardhan Reddy and Cobbett,
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216 K. Janardhan Reddy 143, 109-111
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219 CHAPTER 8 HEAVY METAL STRESS KS
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Heavy Metal Stress 221 porter) and
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Heavy Metal Stress 223 Figure 1. Su
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Heavy Metal Stress 225 is enzymatic
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Heavy Metal Stress 227 BjPCS1 was e
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Heavy Metal Stress 229 following: (
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Heavy Metal Stress 231 a precursor
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Heavy Metal Stress 233 notype. Incr
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Table 1. Proposed specificity and l
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Heavy Metal Stress 237 4.2. Chapero
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Heavy Metal Stress 239 of prokaryot
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Heavy Metal Stress 241 5. HYPERACCU
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Table 2. Genes introduced into plan
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Heavy Metal Stress 245 7. CONCLUSIO
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Heavy Metal Stress 247 controlled b
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Heavy Metal Stress 249 Kägi, J.H.R
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Heavy Metal Stress 251 Murphy, A.,
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Heavy Metal Stress 253 through xyle
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255 CHAPTER 9 METABOLIC ENGINEERING
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Metabolic Engineering for Stress To
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302 A.K. Tyagi, S. Vij and N. Saini
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Table 3. Continued... Source Resour
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336 Index Auxins, 146 Avena sativa
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338 Expressed sequence tags (ESTs),
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340 Index Magnesium, 195 Mairiena s
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342 Index Processes less sensitive
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344 Index Sunflecks, 104 Sunflower,
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