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Inhibition <strong>of</strong> proteasome activity by the TED4 protein in extracellular space: a novel mechanism for protection <strong>of</strong> living cells from injury caused by dying cells. Plant Cell Physiol., 42: 9–19. Eulgem, T., Rushton, P.J., Robatzek, S., <strong>and</strong> Somssich, I.E. 2000. The WRKY superfamily <strong>of</strong> transcription factors. Trends Plant Sci., 5: 199–206. Fang, S.C. <strong>and</strong> Fern<strong>and</strong>ez, D.E. 2002. Effect <strong>of</strong> regulated overexpression for the MADS domain facto AGLI5 on flower senescence <strong>and</strong> fruit maturation. Plant Physiol., 130: 78–89. Fath, A., Bethke, P.C., <strong>and</strong> Jones, R.L. 2001. Enzymes that scavenge reactive oxygen species are down-regulated prior to gibberellic acid-induced programmed cell death in barley aleurone. Plant Physiol., 126: 156–166. Fern<strong>and</strong>ez, D.E., Heck, G.R., Perry, S.E., Patterson, S.E., <strong>and</strong> Bleecker, A.R. 2000. The embryo MADS domain factor AGLI5 acts postembryonic ally: inhibition <strong>of</strong> perianth senescence <strong>and</strong> abscission via constitutive expression. Plant Cell, 12: 183–197. Ferri, K.F. <strong>and</strong> Kroemer, G. 2001. Organelle-specific initiation <strong>of</strong> cell death pathways. Nat. Cell Biol., 3: E255– E263. Fobel, M., Lynch, D.V., <strong>and</strong> Thompson, J.E. 1987. Membrane deterioration in senescing carnation flowers. Plant Physiol., 85: 204–211. Fukuchi-Mizutani, M., Ishiguro, K., Nakayama, T., Utsunomiya, Y., Tanaka, Y., Kusumi, T., <strong>and</strong> Ueda, T. 2000. Molecular <strong>and</strong> functional characterization <strong>of</strong> a rose lipoxygenase cDNA related to flower senescence. Plant Sci., 160: 129–137. Fukuda, H. 1996. Xylogenesis: initiation, progression, <strong>and</strong> cell death. Annu. Rev. Plant Physiol. Plant Mol. Biol., 47: 299–325. Gaffney, T., Friedrich, L., Vernooij, B., Negrotto, D., Nye, G., Uknes, S., Ward, E., Kessmann, H., <strong>and</strong> Ryals, J. 1993. Requirement <strong>of</strong> salicylic acid for the induction <strong>of</strong> systemic acquired resistance. Science, 261: 754–756. Gallie, D.R. <strong>and</strong> Young, T.E. 2004. The ethylene biosynthetic <strong>and</strong> perception machinery is differentially expressed during endosperm <strong>and</strong> embryo development in maize. Mol. Gen. Genom., 271: 267–281. Gan, S. <strong>and</strong> Amasino, R.M. 1995. Inhibition <strong>of</strong> leaf senescence by autoregulated production <strong>of</strong> cytokinin. Science, 270: 1986–1988. Gan, S. <strong>and</strong> Amasino, R.M. 1997. Making sense <strong>of</strong> senescence. Plant Physiol., 113: 313–319. Gazzarrini, S. <strong>and</strong> McCourt, P. 2001. Genetic interactions between ABA, ethylene <strong>and</strong> sugar signaling pathways. Curr. Opin. Plant Biol., 4: 387–391. Genschik, P., Durr, A., <strong>and</strong> Fleck, J. 1994. Differential expression <strong>of</strong> several E2-type ubiquitin carrier protein genes at different developmental stages in Arabidopsis thaliana <strong>and</strong> Nicotiana sylvestris. Mol. Gen. Genet., 244: 548–556. Gepstein, S., Sabehi, G., Carp, M.J., Hajouj, T., Nesher, M.F., Yariv, I., Dor, C., <strong>and</strong> Bassani, M. 2003. Large-scale identification <strong>of</strong> leaf senescence-associated genes. Plant J., 36: 629–642. Gibson, S.I. 2005. Control <strong>of</strong> plant development <strong>and</strong> gene expression by sugar signaling Curr. Opin. Plant Biol., 8: 93–102. Gietl, C. <strong>and</strong> Schmid, M. 2001. Ricinosomes: an organelle for developmentally regulated programme cell death in-senescing plant tissues. Naturwissenschaften, 88: 49–58. Gietl, C., Wimmer, B., Adamec, J., <strong>and</strong> Kalousek, F. 1997. 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118 POSTHARVEST BIOLOGY & TECHNOLOGY OF FRUITS, VEGETABLES, & FLOWERS A., <strong>and</strong> Briggs, S. 2002. A draft sequence <strong>of</strong> the rice genome (Oryza sativa L. ssp japonica). Science, 296: 92–100. Golldack, D., Popova, O.V., <strong>and</strong> Dietz, K.J. 2002. Mutation <strong>of</strong> the matrix metalloproteinase At2-MM inhibits growth <strong>and</strong> causes late flowering <strong>and</strong> early senescence in Arabidopsis. J. Biol. Chem., 277: 5541–5547. Graham, I.A., Leaver, C.J., <strong>and</strong> Smith, S.M. 1992. Induction <strong>of</strong> malate synthase gene-expression i senescent <strong>and</strong> detached organs <strong>of</strong> cucumber. Plant Cell, 4: 349–357. Granell, A. 1999. Dying according to programme: occurrence in plant developmental processes <strong>and</strong> in response to environmental cues. In: Environmental Stress <strong>and</strong> Gene Regulation (ed., K.B. 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Relationships among hormone changes, transmembrane Ca2p flux <strong>and</strong> lipid peroxidation during leaf senescence in spring maize. Acta Bot. Sinica, 41: 1221–1225. He, Y., Tang, W., Swain Johnnie, D., Green Anthony, L., Jack Thomas, P., <strong>and</strong> Gan, S. 2001. Networking senescence-regulating pathways by using Arabidopsis enhancer trap lines. Plant Physiol., 126: 707–716. Heck, S., Grau, T., Buchala, A., Metraux, J.P., <strong>and</strong> Nawrath, C. 2003. Genetic evidence that expression <strong>of</strong> NahG modifies defence pathways independent <strong>of</strong> salicylic acid biosynthesis in the Arabidopsis–Pseudomonas syringae pv. tomato interaction. Plant J., 36: 342–352. Hensel, L.L., Grbic, Y., Baumgarten, D.A., <strong>and</strong> Bleecker, A.B. 1993. Developmental <strong>and</strong> age-related processes that influence the longevity <strong>and</strong> senescence <strong>of</strong> photosynthetic tissues in Arabidopsis. 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Logjam at the Styx: programmed cell death in plants. Trends Plant Sci., 1: 114–119.
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vi CONTENTS 9 Structural Deteriorat
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Contributors Ishan Adyanthaya Depar
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BIOTECHNOLOGICAL APPROACHES 389 Kik
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BIOTECHNOLOGICAL APPROACHES 391 Tat
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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POSTHARVEST FACTORS AFFECTING POTAT
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BIOSENSOR-BASED TECHNOLOGIES 419 20
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BIOSENSOR-BASED TECHNOLOGIES 421 Ta
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BIOSENSOR-BASED TECHNOLOGIES 423 Ta
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BIOSENSOR-BASED TECHNOLOGIES 425 Li
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BIOSENSOR-BASED TECHNOLOGIES 427 So
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BIOSENSOR-BASED TECHNOLOGIES 429 Pr
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BIOSENSOR-BASED TECHNOLOGIES 431 e
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BIOSENSOR-BASED TECHNOLOGIES 433 el
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BIOSENSOR-BASED TECHNOLOGIES 435 st
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Cl O O O OH Cl O OH Cl Cl Cl 2,4-Di
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BIOSENSOR-BASED TECHNOLOGIES 439 O
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BIOSENSOR-BASED TECHNOLOGIES 441 Le
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Chapter 21 Changes in Nutritional Q
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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CHANGES IN NUTRITIONAL QUALITY OF F
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Index Abscisic acid (ABA), 65, 210,
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INDEX 469 Biosensor-based technolog
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INDEX 471 Cryptochlorogenic acid (4
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INDEX 473 French bean, 95 Fresh-cut
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INDEX 475 LePLDα3 (AY013253), 213-
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INDEX 477 Pectin methylesterase (PM
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INDEX 479 PSY1 expression, 289 PSY1
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INDEX 481 Sugars, biosynthesis of,