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(Wang and Woodson, 1991); and pBANUU10 from banana (Medina-Suarez et al., 1997).
While pTOM13 is upregulated in leaves, flowers, and fruits, SR120 is flower-specific (Barry
et al., 1996). On the identification of additional ACC-synthase and ACC-oxidase genes,
transcriptional upregulation has been reported during flower and leaf senescence and fruit
ripening in many species (Abeles et al., 1992). While the ethylene biosynthetic pathway is
well established, components involved in ethylene perception and signal transduction have
only recently been identified. Initial studies on the expression of genes encoding the ethy-
lene receptor report that specific receptor genes are upregulated during fruit ripening and
senescence, while others appear to be constitutively expressed in multiple tissues (Tieman
and Klee, 1999).
During the last 10 years, enormous progress has been made both in the understanding
of the mode of action of ethylene at the molecular level as well as in the translation of this
knowledge into strategies to counteract the detrimental effects of ethylene on ornamental
products. Currently, 1-MCP is entering the market worldwide to treat a variety of orna-
mental products and, genetically engineered ornamentals, with either a decreased ethylene
production or perception, and subsequent superior postharvest performance have been pro-
duced. Given the changing public and political opinions with regard to genetically modified
organisms, it is expected that the latter products will also soon enter the flower market.
4.7 Role of plant growth regulators in flower senescence
4.7.1 Cytokinins
Flower senescence process, like whole plant senescence, is an active one that is executed
via a defined genetic program. Once a flower has been pollinated or is no longer receptive to
pollination, the programmed senescence of petals allows for the removal of a metabolically
costly tissue whose sole role in sexual reproduction is to attract a pollinator. In many flowers,
pollination-induced petal senescence results in the degradation of macromolecules from a
structure that is no longer needed and allows for the remobilization of nutrients to developing
tissues like the ovary (Stead, 1992).
Senescence is accompanied by changes in endogenous ethylene, abscisic acid (ABA),
and cytokinins, and these changes are believed to mediate signaling events that control
the process. In ethylene-insensitive plants like daylily, ABA is thought to be the primary
hormonal regulator of flower senescence, and exogenous application of ABA accelerates vi-
sual senescence symptoms and regulates transcription of senescence-related genes (Panavas
et al., 1998). In ethylene-sensitive flowers like carnation ( D.caryophyllus ), ABA accelerates
flower senescence by increasing the endogenous production of ethylene (Ronen and Mayak,
1981). In contrast to the actions of ethylene and ABA, cytokinins delay senescence in vege-
tative and floral tissues (Van Staden et al., 1988). An inverse relationship between cytokinin
content and senescence occurs in some flowers (Van Staden et al., 1988). Cytokinin con-
tent in roses (Mayak et al., 1972), carnation (Van Staden and Dimalla, 1980), and Cosmos
sulfurous (Saha et al., 1985) is greatest in young flowers and decreases during corolla open-
ing and development. Rose varieties with longer vase lives have been reported to contain
more cytokinins than those with shorter vase lives (Mayak and Halevy, 1970). Results from
exogenous application of cytokinins in vase solutions have been variable (Baker, 1983).
Cytokinin application delayed senescence in carnations (Upfold and Van Staden, 1990),
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