Postharvest Biology and Technology of Fruits, Vegetables, and Flowers

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BIOCHEMISTRY OF FLOWER SENESCENCE 83 Smart, C.M. 1994. Gene expression during leaf senescence. New Phytol., 126: 419–448. Smart, C.M., Hosken, S.E., Thomas, H., Greaves, J.A., Blair, B.G., and Schuch, W. 1995. The timing of maize leaf senescence and characterization of senescence-related cDNAs. Plant Physiol., 93: 673–682. Son, K.C., Gu, E.G., Byoun, H.J., and Lim, J.H. 1994. Effects of sucrose, BA, or aluminum sulfate in the preservative solutions on photosynthesis, respiration, and transpiration of cut rose leaf. J. Kor. Soc. Hort. Sci., 35: 480–486. Sriskandarajah, S., Frello, S., Jorgensen, K., and Serek, M. 2004. Agrobacterium tumefaciens-mediated transformation of Campanula carpatica: factors affecting transformation and regeneration of transgenic shoots. Plant Cell Rep., 23: 59–63. Sriskandarajah, S., Frello, S., and Serek, M. 2001. Induction of adventitious shoots in vitro in Campanula carpatica. Plant Cell Tissue Organ, 67: 295–298. Stead, A.D. 1992. Pollination-induced flower senescence: a review. Plant Growth Regul., 11: 13–20. Stepanova, A.N. and Alonso, J.M. 2005. Ethylene signalling and response pathway: a unique signalling cascade with a multitude of inputs and outputs. Physiol. Plantarum, 123: 195–206. Stephenson, P. and Rubinstein, B. 1998. Characterization of proteolytic activity during senescence in daylily. Plant Physiol., 104: 463–473. Sugawara, H., Shibuya, K., Yoshioka, T., Hashiba, T., and Satoh, S. 2002. Is a cysteine proteinase inhibitor involved in the regulation of petal wilting in senescing carnation (Dianthus caryophyllus L.) flowers? J. Exp. Bot., 53: 407–413. Sun, J., Niu, Q.-W., Tarkowski, P., Zheng, B., Tarkowska, D., Sandberg, G., Chua, N.-H., and Zuo, J. 2003. The Arabidopsis AtIPT8/PGA22 gene encodes an isopentenyl transferase that is involved in de novo cytokinin biosynthesis. Plant Physiol., 131: 167–176. Taverner, E., Letham, D.S., Wang, J., Cornish, E., and Willcocks, D.A. 1999. Influence of ethylene on cytokinin metabolism in relation to Petunia corolla senescence. Phytochemistry, 51: 341–347. ten Have, A. and Woltering, E.J. 1997. Ethylene biosynthetic genes are differentially expressed during carnation (Dianthus caryophyllus L.) flower senescence. Plant Mol. Biol., 34: 89–97. Thomas, H., Ougham, H.J., Wagstaff, C., and Stead, A.D. 2003. Defining senescence and death. J. Exp. Bot., 54: 1127–1132. Thomas, H. and Stoddart, J.L. 1980. Leaf senescence. Ann. Rev. Plant Physiol., 31: 83–111. Thompson, J.E. 1988. The molecular basis for membrane deterioration. In: Senescence and Aging in Plants (eds, L.D. Nooden and A.C. Leopold), Academic Press, San Diego, pp. 51–83. Tieman, D.M. and Klee, H.J. 1999. Differential expression of two novel members of the tomato ethylene-receptor family. Plant Physiol., 120: 165–172. Tournaire, C., Kushnir, S., Bauw, G, Inze, D., de la Serve, B.T., and Renaudin, J.P. 1996. A thiol protease and an anionic peroxidase are induced by lowering cytokinins during callus growth in Petunia. Plant Physiol., 111: 159–168. Upfold, S.J. and Van Staden, J. 1990. Cytokinins in cut carnation flowers: VII. The effect of zeatin and dihydrozeatin derivatives on flower longevity. Plant Growth Regul., 9: 77–81. Valpuesta, V., Lange, N.E., Guerrero, C., and Reid, M.S. 1995. Up-regulation of a cysteine protease accompanies the ethylene-insensitive senescence of daylily (Hemerocallis) flowers. Plant Mol. Biol., 28: 575–582. Van Der Meulen-Muisers, J.J.M., Van Oeveren, J.C., Jansen, J., and Van Tuyl, J.M. 1999. Genetic analysis of postharvest flower longevity in Asiatic hybrid lilies. Euphytica, 107: 149–157. van Doorn, W.G. 2001. Categories of petal senescence and abscission: a reevaluation. Ann. Bot., 87: 447–456. van Doorn, W.G. 2004. Is petal senescence due to sugar starvation? Plant Physiol., 134: 35–42. van Doorn, W.G., Balk, P.A., van Houwelingen, A.M., Hoeberichts, F.A., Hall, R.D., Vorst, O., van der Schoot, C., and van Wordragen, M.F. 2003. Gene expression during anthesis and senescence in Iris flowers. Plant Mol. Biol., 53: 845–863. van Doorn, W.G., Hibma, J., and de Wit, J. 1992. Effect of exogenous hormones on leaf yellowing in cut flowering branches of Alstroemeria pelegrina L. Plant Growth Regul., 11: 59–62. van Doorn, W.G., Pak, C., and Buddendorf, C.J.J. 1993. Effects of surfactants on the vascular occlusion induced by exposure to air in cut flowering stems of Astilbe, Bouvardia, and rose. J. Plant Physiol., 141: 251–253. van Doorn, W.G., Sinz, A., and Tomassen, M.M. 2004. Daffodil flowers delay senescence in cut Iris flowers. Phytochemistry, 65: 571–577. van Doorn, W.G. and Stead, A.D. 1997. Abscission of flowers and floral parts. J. Exp. Bot., 48: 821–837. van Doorn, W.G. and Vojinovic, A. 1996. Petal abscission in rose flowers: effects of water potential, light intensity and light quality. Ann. Bot., 78: 619–623.
84 POSTHARVEST BIOLOGY & TECHNOLOGY OF FRUITS, VEGETABLES, & FLOWERS van Doorn, W.G. and Woltering, E.J. 2004. Senescence and programmed cell death: substance or semantics? J. Exp. Bot., 55: 2147–2153. van Meeteren, U. 1979. Water relations and keeping-quality of cut Gerbera flowers: III. Water content, permeability and dry weight of aging petals. Sci. Hort., 10: 261–269. van Meeteren, U., van Gelder, H., and van Ieperen, W. 2000. Reconsideration of the use of deionized water as vase water in postharvest experiments on cut flowers. Postharvest Biol. Technol., 18: 169–181. Van Staden, J., Cook, E.L., and Nooden, L.D. 1988. Cytokinins and senescence. In: Senescence and Aging in Plants (ed., L.D. Nooden), Academic Press, San Diego, pp. 281–328. Van Staden, J. and Dimalla, G.G. 1980. The effect of silver thiosulfate preservative on the physiology of cut carnations: II. Influence of endogenous cytokinins. Z Pflanzenphysiol., 99: 19–26. Verlinden, S., Boatright, J., and Woodson, W.R. 2002. Changes in ethylene responsiveness of senescence-related genes during carnation flower development. Physiol. Plantarum, 116: 503–511. Verlinden, S. and Garcia, J.J.V. 2004. Sucrose loading decreases ethylene responsiveness in carnation (Dianthus caryophyllus cv. White Sim) petals. Postharvest Biol. Technol., 31: 305–312. Verlinden, S. and Woodson, W.R. 1998. The physiological and molecular responses of carnation flowers to high temperature. Postharvest Biol. Technol., 14: 185–192. Wagstaff, C., Leverentz, M.K., Griffiths, G., Thomas, B., Chanasut, U., Stead, A.D., and Rogers, H.J. 2002. Cysteine protease gene expression and proteolytic activity during senescence of Alstroemeria petals. J. Exp. Bot., 53: 233–240. Wagstaff, C., Malcolm, P., Rafiq, A., Leverentz, M., Griffiths, G., Thomas, B., Stead, A., and Rogers, H. 2003. Programmed cell death (PCD) processes begin extremely early in Alstroemeria petal senescence. New Phytologist, 160: 49–59. Wang, H. and Woodson, W.R. 1991. A flower senescence-related mRNA from carnation shares sequence similarity with fruit ripening-related mRNAs involved in ethylene biosynthesis. Plant Physiol., 96: 1000–1001. Weaver, L.M., Froehlich, J.F., and Amasino, R.M. 1999. Chloroplast-targeted ERD1 protein declines but its mRNA increases during senescence in Arabidopsis. Plant Physiol., 119: 1209–1216. Weaver, L.M., Gan, S., Quirino, B., and Amasino, R.M. 1998. A comparison of the expression patterns of several senescence-associated genes in response to stress and hormone treatment. Plant Mol. Biol., 37: 455–469. Weaver, L.M., Himelblau, E., and Amasino, R.M. 1997. Leaf senescence: gene expression and regulation. In: Genetic Engineering: Principles and Methods (ed., J.K. Setlow), Vol. 19, Plenum Press, New York, pp. 215– 234. Wilkinson, J.Q., Lanahan, M.B., Clark, D.G., Bleecker, A.B., Chang, C., Meyerowitz, E.M., and Klee, H.J. 1997. A dominant mutant receptor from Arabidopsis confers ethylene insensitivity in heterologous plants. Nat. Biotechnol., 15: 444–447. Wisniewski, K. and Zagdanska, B. 2001. Genotype-dependent proteolytic response of spring heat to water deficiency. J. Exp. Bot., 52: 1455–1463. Woltering, E.J. 1987. Effects of ethylene on ornamental pot plants: a classification. Sci. Hort., 31: 283–294. Woltering, E.J. and Harkema, H. 1994. Use of AOA to prevent emasculation induced quality loss in cut flowers. Proceedings of NIOC, pp. 139–145. Woltering, E.J., Somhorst, D., and de Beer, C.A. 1993. Roles of ethylene production and sensitivity in senescence of carnation flowers (Dianthus caryophyllus) cultivars White Sim, Chinera and Epomeo. J. Plant Physiol., 141: 329–335. Woltering, E.J. and van Doorn, W.G. 1988. Role of ethylene in senescence of petals: morphological and taxonomical relationships. J. Exp. Bot., 39: 1605–1616. Woltering, E.J., van Schaik, A.C.R., and Jongen, W.M.F. 1994. Physiology and biochemistry of controlled atmosphere storage: the role of ethylene. Proceedings of Cost94, the Post Harvest Treatment of Fruit and Vegetables—Controlled Atmosphere Storage of Fruit and Vegetables, pp. 35–42. Woodson, W.R. 1987. Changes in protein and mRNA populations during carnation petal senescence. Physiol. Plant, 71: 495–502. Woodson, W.R. 1994. Molecular biology of flower senescence in carnation. In: Molecular and Cellular Aspects of Plant Reproduction (eds, R.J. Scott and A.D. Stead), Cambridge University Press, Cambridge, UK, pp. 225–267. Woodson, W.R., Brandt, A.S., Itzhaki, H., Maxon, J.M., Park, K.Y., and Wang, H. 1993. Regulation and function of flower senescence-related genes. Acta Hort., 336: 41–46. Woodson, W.R. and Lawton, K.A. 1988. Ethylene-induced gene expression in carnation petals: relationship to autocatalytic ethylene production and senescence. Plant Physiol., 87: 498–503.
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Postharvest Biology and Technology
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Edition first published 2008 c○ 2
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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 BIOLOGY AND TECHNOLOGY
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COMMON FRUITS, VEGETABLES, FLOWERS,
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Chapter 3 Biochemistry of Fruits Go
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BIOCHEMISTRY OF FRUITS 21 et al., 2
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BIOCHEMISTRY OF FRUITS 23 3.2.2 Lip
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BIOCHEMISTRY OF FRUITS 25 exposure
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BIOCHEMISTRY OF FRUITS 27 isoform o
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BIOCHEMISTRY OF FRUITS 29 Maltose
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BIOCHEMISTRY OF FRUITS 31 content i
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ETHYLENE PERCEPTION AND GENE EXPRES
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Chapter 7 Enhancing Postharvest She
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ENHANCING POSTHARVEST SHELF LIFE AN
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THE BREAKDOWN OF CELL WALL COMPONEN
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Table 8.3 Transgenic genetics to de
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Chapter 9 Structural Deterioration
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PHOSPHOLIPASE D, MEMBRANE DETERIORA
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Fig. 9.3 Fracture face of a fully o
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PHOSPHOLIPASE D INHIBITION TECHNOLO
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HEAT TREATMENT FOR ENHANCING POSTHA
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THE ROLE OF POLYPHENOLS 261 mainly
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THE ROLE OF POLYPHENOLS 263 Table 1
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THE ROLE OF POLYPHENOLS 265 Pentose
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THE ROLE OF POLYPHENOLS 267 Phenyla
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THE ROLE OF POLYPHENOLS 269 3' OH H
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THE ROLE OF POLYPHENOLS 271 OH OH O
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THE ROLE OF POLYPHENOLS 273 compoun
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THE ROLE OF POLYPHENOLS 275 washing
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THE ROLE OF POLYPHENOLS 277 (Fujita
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THE ROLE OF POLYPHENOLS 279 Boyer,
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THE ROLE OF POLYPHENOLS 281 Peschel
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ISOPRENOID BIOSYNTHESIS IN FRUITS A
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Chapter 14 Postharvest Treatments A
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POSTHARVEST TREATMENTS AFFECTING SE
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Chapter 15 Polyamines and Regulatio
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POLYAMINES AND REGULATION OF RIPENI
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Chapter 16 Postharvest Enhancement
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POSTHARVEST ENHANCEMENT OF PHENOLIC
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RHIZOSPHERE MICROORGANISMS 361 the
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RHIZOSPHERE MICROORGANISMS 363 Rese
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RHIZOSPHERE MICROORGANISMS 365 Tabl
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RHIZOSPHERE MICROORGANISMS 367 Toma
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RHIZOSPHERE MICROORGANISMS 369 Such
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RHIZOSPHERE MICROORGANISMS 371 Gian
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Chapter 18 Biotechnological Approac
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BIOTECHNOLOGICAL APPROACHES 375 tec
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BIOTECHNOLOGICAL APPROACHES 377 pro
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BIOTECHNOLOGICAL APPROACHES 381 Fla
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BIOTECHNOLOGICAL APPROACHES 383 adm
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BIOTECHNOLOGICAL APPROACHES 387 Bar
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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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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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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,
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