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

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126 T.D. Sharkey and S.M. Schrader Pastenes, C. and Horton, P. (1996a). Effect of high temperature on photosynthesis in beans 1. Oxygen evolution and chlorophyll fluorescence. Plant Physiol. 112,1245-1251. Pastenes, C. and Horton, P. (1996b). Effect of high temperature on photosynthesis in beans 2. CO2 assimilation and metabolite contents. Plant Physiol. 112,1253-1260. Pearcy, R. W. (1978). Effect of growth temperature on fatty acid composition of leaf lipids in Atriplex lentiformis (Torr.) Wats. Plant Physiol. 61,484-486. Pearcy, R. W., Krall, J. P. and Sassenrath-Cole, G. F. (1996). Photosynthesis in fluctuating light environments. Photosynthesis and the Environment. Baker, N. R. (Ed.) Kluwer Academic Press Pp. 321-346. Pechan, P. M., and Smykal, P.(2001). Androgenesis, Affecting the fate of the male gametophyte. Physiol. Plant. 111,1-8. Peet, M. M., Sato, S. and Gardner, R. G. (1998). Comparing heat stress effects on male-fertile and male-sterile tomatoes. Plant Cell Environ. 21,225-231. Porch, T. G. and Jahn, M. (2001). Effects of high-temperature stress on microsporogenesis in heatsensitive and heat-tolerant genotypes of Phaseolus vulgaris. Plant Cell Environ. 24,723-731. Prandl, R., Hinderhofer, K., Eggers-Schumacher, G. and Schoffl, F. (1998). HSF3, a new heat shock factor from Arabidopsis thaliana, derepresses the heat shock response and confers thermotolerance when overexpressed in transgenic plants. Mol. Gen. Gen. 258,269-278. Prasad, P. V. V., Boote, K. J., Allen, L. H. and Thomas, J. M. G. (2002). Effects of elevated temperature and carbon dioxide on seed-set and yield of kidney bean (Phaseolus vulgaris L.). Global Change Biol. 8,710-721. Pratt, W. B., Krishna, P. and Olsen, L. J. (2001). Hsp90-binding immunophilins in plants, the protein movers. Trends Plant Sci. 6,54-58. Pueyo, J. J., Alfonso, M., Andres, C. and Picorel, R. (2002). Increased tolerance to thermal inactivation of oxygen evolution in spinach Photosystem II membranes by substitution of the extrinsic 33-kDa protein by its homologue from a thermophilic cyanobacterium. Biochim. Biophys. Acta 1554,29-35. Pursiheimo, S., Martinsuo, P., Rintamaki, E. and Aro, E. M. (2003). Photosystem II protein phosphorylation follows four distinctly different regulatory patterns induced by environmental cues. Plant Cell Environ. 26,1995-2003. Queitsch, C., Hong, S. W., Vierling, E. and Lindquist, S. (2000). Heat shock protein 101 plays a crucial role in thermotolerance in Arabidopsis. The Plant Cell 12,479-492. Queitsch, C., Sangster, T. A. and Lindquist, S. (2002). Hsp90 as a capacitor for genetic variation. Nature 417,618-624. Quinn, P. J., Joo, F., and Vigh, L. (1989). The role of unsaturated lipids in membrane-structure and stability. Prog. Biophys. Mol. Biol. 53,71-103. Radin, J. W., Lu, Z., Percy, R. G. and Zeiger, E. (1994). Genetic variability for stomatal conductance in Pima cotton and its relation to improvements of heat adaptation. Proc. Nat. Acad. Sci. 91,7217-7221. Raison, J. K., Roberts, J. K. M. and Berry, J. A. (1982). Correlations between the thermal stability of chloroplasts (thylakoid) membranes and the composition and fluidity of their polar lipids upon acclimation of the higher plant Nerium oleander to growth temperature. Biochim. Biophys. Acta 688,218-228. Reddy, K. R., Hodges, H. F. and McKinion, J. M. (1995). Carbon dioxide and temperature effects on pima cotton growth. Agric. Ecosys. Environ. 54,17-29. Rintamäki, E., Kettunen, R. and Aro, E. M. (1996). Differential D1 dephosphorylation in functional and photodamaged photosystem II centers. Dephosphorylation is a prerequisite for degradation of damaged D1. J. Biol. Chem. 271,14870-14875. Rokka, A., Aro, E. M., Herrmann, R. G., Andersson, B. and Vener, A. V. (2000). Dephosphorylation of photosystem II reaction center proteins in plant photosynthetic membranes as an immediate response to abrupt elevation of temperature. Plant Physiol. 123,1525-1535. Rokka, A., Zhang, L. and Aro, E. M. (2001). Rubisco activase, an enzyme with a temperaturedependent dual function? Plant J. 25,463-471.
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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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41 CHAPTER 3 SALT STRESS ZORA DAJIC
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Salt Stress 43 activities (mainly i
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Salt Stress 45 In summary, mechanis
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Salt Stress 47 tolerance research i
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Salt Stress 49 need to rely on sodi
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Salt Stress 51 (Echeverria, 2000).
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Salt Stress 53 Therefore, the capac
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Salt Stress 55 Reduced plant growth
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Salt Stress 57 Table 3. Salt tolera
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Salt Stress 59 6.2. Nitrogen Fixati
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Salt Stress 61 A significant number
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Salt Stress 63 macromolecules, irre
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Salt Stress 65 8.2. Ion Homeostasis
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Salt Stress 67 1997), is speculated
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Salt Stress 69 together with the At
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Salt Stress 71 important role in si
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Salt Stress 73 Figure 5. Determinan
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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 98 and 99: Salt Stress 87 Dajic, Z., Stevanovi
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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).
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Page 140 and 141: 131 CHAPTER 5 FREEZING STRESS: SYST
Page 142 and 143: Freezing Stress 133 Whereas, in the
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Page 146 and 147: Freezing Stress 137 with physiologi
Page 148 and 149: Freezing Stress 139 (1997). However
Page 150 and 151: Freezing Stress 141 (Barnett et al.
Page 152 and 153: Freezing Stress 143 (dehydrin) prot
Page 154 and 155: Freezing Stress 145 in cytosolic Ca
Page 156 and 157: Freezing Stress 147 Phospholiphase
Page 158 and 159: Freezing Stress 149 Accumulation of
Page 160 and 161: Freezing Stress 151 Ideker, T., Gal
Page 162 and 163: Freezing Stress 153 ellin acid on f
Page 164 and 165: Freezing Stress 155 Yoshida, S. and
Page 166 and 167: 158 A.R. Reddy and A.S. Raghavendra
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178 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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