PROGRAMMED CELL DEATH DURING PLANT SENESCENCE 123 Swidzinski, J.A., Sweetlove, L.J., <strong>and</strong> Leaver, C.J. 2002. A custom microarray analysis <strong>of</strong> gene expression during programmed cell death in Arabidopsis thaliana. Plant J., 30: 431–446. Swidzinski, J.A., Leaver, C.J., <strong>and</strong> Sweetlove, L.J. 2004. A proteomic analysis <strong>of</strong> plant programmed cell death. Phytochemistry, 65: 1829–1838. ten Have, A. <strong>and</strong> Woltering, E.J. 1997. Ethylene biosynthetic genes are differentially expressed during carnation (Dianthus caryophyllus L.) flower senescence. Plant Mol. Biol., 34: 89–97. Thoenen, M. <strong>and</strong> Feller, U. 1998. Degradation <strong>of</strong> glutamine synthetase in intact chloroplasts isolated from pea (Pisum sativum) leaves. Aust. J. Plant Physiol., 25: 279–286. Thomas, H. <strong>and</strong> Howarth, C.J. 2000. Five ways to stay green. J. Exp. Bot., 51: 329–337. Thomas, H., Ougham, H.J., Wagstaff, C., <strong>and</strong> Stead, A.D. 2003. Defining senescence <strong>and</strong> death. J. Exp. Bot., 54: 1127–1132. Thomas, S. <strong>and</strong> Franklin-Tong, V.E. 2004. Self-incompatibility triggers programmed cell death in Papaver pollen. Nature, 429: 305–309. Toyooka, K., Okamoto, T., <strong>and</strong> Minamikawa, T. 2001. Cotyledon cells <strong>of</strong> Vigna mungo seedlings use at least two distinct autophagic machineries for degradation <strong>of</strong> starch granules <strong>and</strong> cellular components. J. Cell Biol., 154: 973–982. Uren, A.G., O’Rourke, K., Aravind, L., Pisabarro, M.T., Seshagiri, S., Koonin, E.V., <strong>and</strong> Dixit, V.M. 2000. Identification <strong>of</strong> paracaspases <strong>and</strong> metacaspases: two ancient families <strong>of</strong> caspase-like proteins, one <strong>of</strong> which plays a key role in MALT lymphoma. Mol. Cell, 6: 961–967. Valpuesta, V., Lange, N.E., Guerrero, C., <strong>and</strong> Reid, M.S. 1995. Up-regulation <strong>of</strong> a cysteine protease accompanies the ethylene-insensitive senescence <strong>of</strong> daylily (Hemeroca/lis) flowers. Plant Mol. Biol., 28: 575–582. van Doorn, W.G. <strong>and</strong> Woltering, E.J. 2004. Senescence <strong>and</strong> programmed cell death: substance or semantics? J. Exp. Bot., 55: 2147–2153. van Doorn, W.G. <strong>and</strong> Woltering, E.J. 2005. Many ways to exit? Cell death categories in plants. Trends Plant Sci., 10: 117–122. van Doorn, W.G., Balk, P.A., van Houwelingen, A.M., Hoeberichts, F.A., Hall, R.D., <strong>and</strong> Vorst, O. 2003. Gene expression during anthesis <strong>and</strong> senescence in Iris flowers. Plant Mol. Biol., 53: 845–863. van Engelen, F.A., Sterk, P., Booij, H., Cordewener, J.H.G., Rook, W., van Kammen, A., <strong>and</strong> de Vries, S.C. 1991. Heterogeneity <strong>and</strong> cell type-specific localization <strong>of</strong> a cell wall glycoprotein from carrot suspension cells. Plant Physiol., 96: 705–712. Verberne, M.C., Verpoorte, R., Bol, J.F., Mercado-Blanco, J., <strong>and</strong> Linthorst, H.J.B. 2000. Overproduction <strong>of</strong> salicylic acid in plants by bacterial transgenes enhances pathogen resistance. Nature Biotechnol., 18: 779– 783. Wagstaff, C., Chanasut, U., Harren, F.J.M., Laarhoven, L.J., Thomas, B., <strong>and</strong> Rogers, H.J. (2005). Ethylene <strong>and</strong> flower longevity in Alstroemeria: relationship between petal senescence, abscission <strong>and</strong> ethylene biosynthesis. J. Exp. Bot., 56: 1007–1016. Wagstaff, C., Leverentz, M.K., Griffiths, G., Thomas, B., Chanasut, U., Stead, A.D., <strong>and</strong> Rogers, H.J. 2002. Cysteine protease gene expression <strong>and</strong> proteolytic activity during senescence <strong>of</strong> Aistroemeria petals. J. Exp. Bot., 53: 233–240. Wagstaff, C., Malcolm, P., Rafiq, A., Leverentz, M., Griffiths, G., <strong>and</strong> Thomas, B. 2003. Programmed cell death (PCD) processes begin extremely early in Alstroemeria petal senescence. New Phytologist, 160: 49–59. Wang, M., Hoekstra, S., Van Bergen, S., Lamers, G.E.M., Oppedijk, B.J., <strong>and</strong> Van Der Heijden, M.W. 1999. Apoptosis in developing anthers <strong>and</strong> the role <strong>of</strong> ABA in this process during <strong>and</strong>rogenesis in Hordeum vulgare L. Plant Mol. Biol., 39: 489–501. Ward, E., Uknes, S.J., Williams, S.C., Dincher, S.S., Wiederhold, D.L., Alex<strong>and</strong>er, D.C., Ahl-Goy, P., Metraux J.P., <strong>and</strong> Ryals, J.A. 1991. Coordinate gene activity in response to agents that induce systemic acquired resistance. Plant Cell, 3: 1085–1094. Watanabe, N. <strong>and</strong> Lam, E. 2005. Two Arabidopsis metacaspases AtMCP1b <strong>and</strong> AtMCP2b are arginine/lysinespecific cysteine proteases <strong>and</strong> activate apoptosis-like cell death in yeast. J. Biol. Chem., 280: 14691–14699. Weymann, K., Hunt, M., Uknes, S., Neuenschw<strong>and</strong>er, U., Lawton, K., Steiner, H.Y., <strong>and</strong> Ryals, J. 1995. Suppression <strong>and</strong> restoration <strong>of</strong> lesion formation in Arabidopsis lsd mutants. Plant Cell, 7: 2013–2022. White, R.F. 1979. Acetylsalicylic acid (aspirin) induces resistance to tobacco mosaic virus in tobacco. Virology, 99: 410–412. Wilczynski, G., Kulma, A., <strong>and</strong> Szopa, J. 1998. The expression <strong>of</strong> 14–3-3 is<strong>of</strong>orms in potato is developmentally regulated. J. Plant Physiol., 153: 118–126. Wilkinson, K. 1999. Ubiquitin-dependent signaling: the role <strong>of</strong> ubiquitination in the response <strong>of</strong> cell to their environment. Recent Adv. Nutr. Sci., 129: 1933–1936.
124 POSTHARVEST BIOLOGY & TECHNOLOGY OF FRUITS, VEGETABLES, & FLOWERS Willekens, H., Chamnongpol, S., Davey, M., Schraudner, M., Langebartels, C., Van Montagu, M., Inze, D., <strong>and</strong> Van Camp, W. 1997. Catalase is a sink for H 2 O 2 <strong>and</strong> is indispensable for stress defence in C 3 plants. EMBO J., 16: 4806–4816. Willmer, C. <strong>and</strong> Fricker, M. 1996. Stomata: Topics in Plant Functional <strong>Biology</strong>, 2nd edn, Chapman & Hall, London. Wilson, R.N., Heckman, J.W., <strong>and</strong> Somerville, C.R. 1992. Gibberellin is required for flowering in Arabidopsis thaliana under short days. Plant Physiol., 100: 403–408. Wingler, A., von Schaewen, A., Leegood, R.C., Lea, P.J., <strong>and</strong> Quick, W.P. 1998. Regulation <strong>of</strong> leaf senescence by cytokinin, sugars <strong>and</strong> light. Plant Physiol., 116: 329–335. Woltering, E.J. <strong>and</strong> van Doorn, W.G. 1988. Role <strong>of</strong> ethylene <strong>and</strong> senescence <strong>of</strong> petals: morphological <strong>and</strong> taxonomical relationships. J. Exp. Bot., 39: 1605–1616. Woo, H.R., Chung, K.M., Park, J.H., Oh, S.A., Ahn, T., Hong, S.H., Jang, S.K., <strong>and</strong> Nam, H.G. 2001. ORE9, an F-box protein that regulates leaf senescence in Arabidopsis. Plant Cell, 13: 1779–1790. Woodson, W.R. <strong>and</strong> Lawton, K.A. 1988. Ethylene-induced gene expression in carnation petals. Relationship to autocatalytic ethylene production <strong>and</strong> senescence. Plant Physiol., 87: 498–503. Wu, H.M. <strong>and</strong> Cheung, A.Y. 2000. Programmed cell death in plant reproduction. Plant Mol. Biol., 44: 267–281. Xiao, S., Brown, S., Patrick, E., Brearley, C., <strong>and</strong> Turner, J.G. 2003. Enhanced transcription <strong>of</strong> the Arabidopsis disease resistance genes RPW8.1 <strong>and</strong> RPW8.2 via a salicylic acid-dependent amplification circuit is required for hypersensitive cell death. Plant Cell, 15: 33–45. Xu, Y. <strong>and</strong> Hanson, M.R. 2000. Programmed cell death during pollination-induced petal senescence in petunia. Plant Physiol., 122: 1323–1333. Yamada, T., Ichimura, K., <strong>and</strong> van Doorn, W.G. 2006. DNA degradation <strong>and</strong> nuclear degeneration during programmed cell death in petals <strong>of</strong> Antirrhinum, Argyranthemum, <strong>and</strong> Petunia. J. Exp. Bot., 57: 3543–3552. Yang, S.H., Berbeiich, T., Sano, H., <strong>and</strong> Kusaano, T. 2001. Specific association <strong>of</strong> transcripts <strong>of</strong> tbzF <strong>and</strong> tbzJ 7, tobacco genes encoding basic region leucine zipper-type transcriptional activators, with guard cells <strong>of</strong> senescing leaves <strong>and</strong>/or flowers. Plant Physiol., 127: 23–32. Yen, C.H. <strong>and</strong> Yang, C.H. 1998. Evidence for programmed cell death during leaf senescence in plants. Plant Cell Physiol., 39: 922–927. Yoshida, S., Ito, M., Callis, J., Nishida, I., <strong>and</strong> Watanabe, A. 2002a. A delayed senescence mutant is defective in arginyl-tRNA: protein arginyl transferase, a component <strong>of</strong> the N-end rule pathway in Arabidopsis. Plant J., 32: 129–137. Yoshida, S., Ito, M., Nishida, I., <strong>and</strong> Watanabe, A. 2002b. Identification <strong>of</strong> a novel gene HYSI/CPR5 that has a repressive role in the induction <strong>of</strong> leaf senescence <strong>and</strong> pathogen-defence responses in Arabidopsis thaliana. Plant J., 29: 427–437. Yuan, J. <strong>and</strong> Horvitz, H.R. 1990. The Caenorhabditis elegans genes ced-3 <strong>and</strong> ced-4 act cell autonomously to cause programmed cell death. Dev. Biol., 138: 33–41. Yuan, X.M., Li, W., Dalen, H., Lotem, J., Kama, R., Sachs, L., <strong>and</strong> Brunk, U. T. 2002. Lysosomal destabilization in p53-induced apoptosis. Proc. Natl. Acad. Sci. U.S.A., 99: 6286–6291. Zavaleta-Mancera, H.A., Thomas, B.J., Thomas, H., <strong>and</strong> Scott, I.M. 1999. Regreening <strong>of</strong> senescent Nicotiana leaves. II. Redifferentiation <strong>of</strong> plastids. J. Exp. Bot., 50:1683–1689. Zentgraf, U. <strong>and</strong> Kolb, D. 2002. Analysis <strong>of</strong> differential gene expression during leaf senescence using Arabidopsis high density genome arrays. In: 13th Congress <strong>of</strong> the Federation <strong>of</strong> European Society <strong>of</strong> Plant Physiologists. Zhao, Y., Jiang, Z.-F., Sun, Y.-L., <strong>and</strong> Zhai, Z.H. 1999. Apoptosis <strong>of</strong> mouse liver nuclei induced in the cytosol <strong>of</strong> carrot cells. FEBS Lett., 448: 197–200. Zhu, T., Budworth, P., Han, B., Brown, D., Chang, H.S., Zou, G., <strong>and</strong> Wang, X. 2001. Toward elucidating the global gene expression patterns <strong>of</strong> developing Arabidopsis: parallel analysis <strong>of</strong> 8300 genes by high-density oligonucleotide probe array. Plant Physiol. Biochem., 39: 221–242.
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vi CONTENTS 9 Structural Deteriorat
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Contributors Ishan Adyanthaya Depar
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x CONTRIBUTORS Gopinadhan Paliyath
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xii PREFACE difficult to find a boo
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Chapter 1 Postharvest Biology and T
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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,