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

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12 K.V. Madhava Rao Bray, E.A. (1993). Molecular responses to water deficit. Plant Physiol. 103, 1035-1040. Bray, E.A. (1997). Plant responses to water deficit. Trends Plant Sc. 2, 48-54. Bray, E.A. (2002). Classification of genes differentially expressed during water-deficit stress in Arabidopsis thaliana: an analysis using microarray and differential expression data. Ann. Bot. 89, 803-811. Burke, J.J. and Usda-Ars, K.A.O. (1988). The heat-shock response in higher plants: a biochemical model. Plant Cell Environ. 11, 441-444. Camejo, D., Rodriguez, P., Morales, M.A., Dell’Amico, J.M., Torrecillas, A. and Alarcon, J.J. (2005). High temperature effects on photosynthetic activity of two tomato cultivars with different heat susceptibility. J. Plant Physiol. 162, 281-289. Carter, D.I. (1975). Problems of salinity in agrculture. In: Poljakoff-Mayber A and Gale J eds. Plants in Saline Environments. Springer-Verlag Berlin. pp. 25-35 Chakraborty, U. and Chakraborty, B. (eds) (2005). Stress Biology, Narosa Publishing House, New Delhi. Cheeseman, J.M. (1988). Mechanisms of salinity tolerance in plants. Plant Physiology. 87: 547- 550. Cherry, J.H., Robert, D.L. and Rychter, A. (eds) (2000). Plant tolerance to Abiotic Stresses in Agriculture: Role of Genetic Engineering. Kluwer Academic Publishers, The Netherlands. Christmann, A., Hoffmann, T., Teplova, I., Grill, E. and Müller, A. (2005) Generation of active pools of abscisic acid revealed by in vivo imaging of water stressed Arabidopsis. Plant Physiol. 137, 209-219. Clemens, S. (2001). Molecular mechanisms of plant metal tolerance and homeostasis. Planta. 212, 475-486. Cobbet, C. and Goldsbrough, P. (2002). Phytochelatins and metallothioneins: roles in heavy metal detoxification and homeostasis. Annu. Rev. Plant Biol. 53, 159-182. Cobett, C.S. (2000). Phytochelitins and their roles in heavy metal detoxification. Plant Physiol. 123, 825-832. Das, V.S.R. (2004). Photosynthesis: Regulation Under Varying Light Regimes. Science Publishers, Inc., UK. Dat, J., Van Denabeele, S., Varanova, E., Van Montagou, M., Inze, D. and Van Breusegem, F. (2000). Dual action of the active oxygen species during plant stress responses. CMLS Cellular Mol Life Sci 57, 779-795. Derra, S. (2004). How to make the most use of your microarray data. Drug Disc. Dev. 39-44. Di Toppi, L.S. and Pawlik-Skowronska, B. (eds) (2003). Abiotic Stresses in Plants. Kluwer Academic Publishers, The Netherlands. Flowers, T.J. and Yeo, A.R. (1986). Ion relations of plants under drought and salinity. Aust. J. Plant Physiol. 13, 75-91. Flowers, T.J. and Yeo, A.R. (1995). Breeding for salinity resistance in crop plants: where next? Aust. J. Plant Physiol. 22, 875-884. Fowdern, L., Mansfield, T. and Stoddart, J. (1993). Plant adaptation to environmental stress. Chapman and Hall, London. Foyer, C.H., Descourvieres, P. and Kunert, K.J. (1994). Protection against oxygen radicals: an important defense mechanism studied in transgenic plants. Plant Cell Environ. 17, 507-523. Foyer, C.H., Lelandais, M. and Kunert, K.J. (1994). Photooxidative stress in plants. Physiologia Plantarum. 92, 696-717. Foyer, C.H. and Noctor, G. (2000). Oxidant and antioxidant signaling in plants: a reevaluation of the concept of oxidative stress in a physiological context. Plant Cell Environ. 28, 1056-1071. Freeman, J.L., Garcia, D., Kim, D., Hopf, A. and Salt, D.E. (2005). Constitutively elevated salicylic acid signals glutathione-mediated nickel tolerance in Thalspi nickel hyperaccumulators. Plant Physiol. 137, 1082-1091. Griffiths, H. and Parry, M.A.J. (2002). Plant responses to water stress. Ann. Bot. 89, 801-802. Guy, C.L. (1990). Cold acclimation and freezing stress: role of protein metabolism. Annu.Rev. Plant Physiol. Plant Mol. Biol. 41, 187-223.
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Page 2 and 3: PHYSIOLOGY AND MOLECULAR BIOLOGY OF
Page 4 and 5: A C.I.P. Catalogue record for this
Page 6 and 7: About the Editors K.V. Madhava Rao
Page 8 and 9: LIST OF CONTRIBUTORS K. AKASHI Grad
Page 10 and 11: List of Contributors xiii NAVINDER
Page 12 and 13: PREFACE Increasing agricultural pro
Page 14 and 15: 2 K.V. Madhava Rao Abiotic stresses
Page 16 and 17: 4 K.V. Madhava Rao SOME O THE PROMI
Page 18 and 19: 6 K.V. Madhava Rao 2. WATER STRESS
Page 20 and 21: 8 K.V. Madhava Rao 5. FREEZING STRE
Page 22 and 23: 10 K.V. Madhava Rao of these pathwa
Page 26 and 27: 14 K.V. Madhava Rao Rao, K.V. Madha
Page 28 and 29: 16 A. Yokota, K. Takahara and K. Ak
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
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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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Salt Stress 75 9.1.Transgenic Plant
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Salt Stress 77 tolerance from halop
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Salt Stress 79 sponse and yield (Su
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Salt Stress 81 Table 5. Possible ut
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Salt Stress 83 monitored with fluor
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Salt Stress 85 Func. Plant Biol. 29
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Salt Stress 87 Dajic, Z., Stevanovi
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Salt Stress 89 Gouia, H., Ghorbal,
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Salt Stress 91 Larcher, W. (1995).
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Salt Stress 93 Munns, R. and James,
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Salt Stress 95 Rausell, A., Kanhono
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Salt Stress 97 durum wheat crops gr
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Salt Stress 99 Yoshida, K. (2002).
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102 T.D. Sharkey and S.M. Schrader
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131 CHAPTER 5 FREEZING STRESS: SYST
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Freezing Stress 133 Whereas, in the
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Freezing Stress 135 genes at the tr
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Freezing Stress 137 with physiologi
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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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