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Functional Genomics <strong>of</strong> <strong>Stress</strong> Tolerance 331 barley. Plant Mol. Biol., 48, 551-573. Pan, X., Liu, H., Clarke, J., Jones, J., Bevan, M. <strong>and</strong> Stein, L. (2003). ATIDB: Arabidopsis thaliana insertion database. Nucleic Acids Res., 31, 1245-1251. P<strong>and</strong>ey, A. <strong>and</strong> Mann, M. (2000). Proteomics to study genes <strong>and</strong> genomes. Nature, 405, 837-846. Parinov, S., Sevugan, M., Ye, D., Yang, W.C., Kumaran, M. <strong>and</strong> Sundaresan, V. (1999). Analysis <strong>of</strong> flanking sequences from dissociation insertion lines: a database for reverse genetics in Arabidopsis. Plant Cell, 11, 2263-2270. Parinov, S. <strong>and</strong> Sundaresan, V. (2000). Functional genomics in Arabidopsis: large-scale insertional mutagenesis complements the genome sequencing project. Curr. Opin. Biotechnol., 11, 157- 161. Park, O.K. (2004). Proteomic studies in plants. J. Biochem. Mol. Biol., 37, 133-138. Pastori, G.M., Kiddle, G., Antoniw, J., Bernard, S., Veljovic-Jovanovic, S., Verrier, P.J., et al. (2003). Leaf vitamin C contents modulate plant defense transcripts <strong>and</strong> regulate genes that control development through hormone signaling. Plant Cell, 15, 939-951. Perez-Amador, M.A., Leon, J., Green, P.J. <strong>and</strong> Carbonell, J. (2002). Induction <strong>of</strong> the arginine decarboxylase ADC2 gene provides evidence for the involvement <strong>of</strong> polyamines in the wound response in Arabidopsis. Plant Physiol., 130, 1454-1463. Pih, K.T., Jang, H.J., Kang, S.G., Piao, H.L. <strong>and</strong> Hwang, I. (1997). Isolation <strong>of</strong> molecular markers for salt stress responses in Arabidopsis thaliana. Mol. Cells, 7, 567-571. Ramach<strong>and</strong>ran, S. <strong>and</strong> Sundaresan, V. (2001). Transposons as Tools for Functional Genomics. Plant <strong>Physiology</strong> <strong>and</strong> Biochemistry, 39, 243-252. Reymond, P., Weber, H., Damond, M. <strong>and</strong> Farmer, E.E. (2000). Differential gene expression in response to mechanical wounding <strong>and</strong> insect feeding in Arabidopsis. Plant Cell, 12, 707-720. Rhee, S.Y. (2000). Bioinformatic resources, challenges, <strong>and</strong> opportunities using Arabidopsis as a model organism in a post-genomic era. Plant Physiol., 124, 1460-1464. Rhee, S.Y., Beavis, W., Berardini, T.Z., Chen, G., Dixon, D., Doyle, A., et al. (2003). The Arabidopsis Information Resource (TAIR): a model organism database providing a centralized, curated gateway to Arabidopsis biology, research materials <strong>and</strong> community. Nucleic Acids Res., 31, 224-228. Riccardi, F., Gazeau, P., de Vienne, D. <strong>and</strong> Zivy, M. (1998). Protein changes in response to progressive water deficit in maize. Quantitative variation <strong>and</strong> polypeptide identification. Plant Physiol. 117, 1253-1263. Rossel, J.B., Wilson, I.W. <strong>and</strong> Pogson, B.J. (2002). Global changes in gene expression in response to high light in Arabidopsis. Plant Physiol., 130, 1109-1120. Rossi, M., Araujo, P.G., Paulet, F., Garsmeur, O., Dias, V.M., Chen, H., et al. (2003). Genomic distribution <strong>and</strong> characterization <strong>of</strong> EST-derived resistance gene analogs (RGAs) in sugarcane. Mol. Genet. Genomics, 269, 406-419. Rus, A., Yokoi, S., Sharkhuu, A., Reddy, M., Lee, B.H., Matsumoto, T.K., et al. (2001). AtHKT1 is a salt tolerance determinant that controls Na(+) entry into plant roots. Proc. Natl. Acad. Sci. U S A, 98, 14150-14155. Saha, S., Sparks, A.B., Rago, C., Akmaev, V., Wang, C.J., Vogelstein, B., et al. (2002). Using the transcriptome to annotate the genome. Nat. Biotechnol., 19, 508-512. Sahi, C., Agarwal, M., Reddy, M.K., Sopory, S.K. <strong>and</strong> Grover, A. (2003). Isolation <strong>and</strong> expression analysis <strong>of</strong> salt stress-associated ESTs from contrasting rice cultivars using a PCR-based subtraction method. Theor. Appl. Genet., 106, 620-628. Salekdeh, G.H., Siopongco, J., Wade, L.J., Ghareyazie, B. <strong>and</strong> Bennett, J. (2002). Proteomic analysis <strong>of</strong> rice leaves during drought stress <strong>and</strong> recovery. Proteomics, 2, 1131-1145. Samson, D., Legeai, F., Karsenty, E., Reboux, S., Veyrieras, J.B., Just, J., et al. (2003). GenoPlante- Info (GPI): a collection <strong>of</strong> databases <strong>and</strong> bioinformatics resources for plant genomics. Nucleic Acids Res., 31, 179-182. Sanchez, P., de Torres Zabala, M. <strong>and</strong> Grant, M. (2000). AtBI-1, a plant homologue <strong>of</strong> Bax inhibitor- 1, suppresses Bax-induced cell death in yeast <strong>and</strong> is rapidly upregulated during wounding <strong>and</strong> pathogen challenge. Plant J., 21, 393-399.
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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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18 A. Yokota, K. Takahara and K. Ak
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20 A. Yokota, K. Takahara and K. Ak
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22 A. Yokota, K. Takahara and K. Ak
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24 A. Yokota, K. Takahara and K. Ak
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26 A. Yokota, K. Takahara and K. Ak
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28 A. Yokota, K. Takahara and K. Ak
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30 A. Yokota, K. Takahara and K. Ak
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32 A. Yokota, K. Takahara and K. Ak
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34 A. Yokota, K. Takahara and K. Ak
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36 A. Yokota, K. Takahara and K. Ak
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38 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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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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104 T.D. Sharkey and S.M. Schrader
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106 T.D. Sharkey and S.M. Schrader
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108 T.D. Sharkey and S.M. Schrader
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110 T.D. Sharkey and S.M. Schrader
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112 T.D. Sharkey and S.M. Schrader
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114 T.D. Sharkey and S.M. Schrader
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116 T.D. Sharkey and S.M. Schrader
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118 T.D. Sharkey and S.M. Schrader
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120 T.D. Sharkey and S.M. Schrader
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122 T.D. Sharkey and S.M. Schrader
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124 T.D. Sharkey and S.M. Schrader
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126 T.D. Sharkey and S.M. Schrader
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128 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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160 A.R. Reddy and A.S. Raghavendra
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162 A.R. Reddy and A.S. Raghavendra
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164 A.R. Reddy and A.S. Raghavendra
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166 A.R. Reddy and A.S. Raghavendra
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168 A.R. Reddy and A.S. Raghavendra
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170 A.R. Reddy and A.S. Raghavendra
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172 A.R. Reddy and A.S. Raghavendra
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174 A.R. Reddy and A.S. Raghavendra
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176 A.R. Reddy and A.S. Raghavendra
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178 A.R. Reddy and A.S. Raghavendra
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180 A.R. Reddy and A.S. Raghavendra
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182 A.R. Reddy and A.S. Raghavendra
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184 A.R. Reddy and A.S. Raghavendra
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186 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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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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Metabolic Engineering for Stress To
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- Page 342 and 343: 336 Index Auxins, 146 Avena sativa
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- Page 346 and 347: 340 Index Magnesium, 195 Mairiena s
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