1. IntroductionEthylene plays an im

1. Introduction
Ethylene plays an important role in many plant processes
including seed germination, organ senescence, stress responses
and fruit ripening (Nath et al., 2006). Depending on the massive
increase in respiration or ethylene production during ripening,
fruit are classified as climacteric and non climacteric (Biale and
Young, 1981). At the onset of ripening, climacteric fruit exhibit
a peak in respiration followed by a burst in ethylene production.
In non-climacteric fruit, no such burst in ethylene production
and respiration is observed. Though a basal level of ethylene
production is present even in non-climacteric fruit, ripening in
these fruits is ethylene independent. Based on the nature and
amount of ethylene produced during plant growth and
development including fruit ripening, the concept of system-1
and system-2 ethylene was introduced (McMurchie et al.,
1972). System-1 ethylene is produced at low level and
contributes to the basal levels produced by the plant during
various stages of growth and development and is autoinhibitory
(Oetiker and Yang, 1995). System-2 ethylene
production is at a high level, and operates during ripening of
climacteric fruits and senescence of some flowers and is autostimulatory
(Oetiker and Yang, 1995). The transition from
system-1 to system-2 ethylene production is an important step
during fruit ripening and is developmentally regulated. It is now
established that genes responsible for ethylene biosynthesis and
signal transduction are stimulated during a climacteric burst of
ethylene production and may be tightly associated during the
transition from system-1 to system-2 (Nakatsuka et al., 1998).
The ethylene biosynthesis pathway is well characterised in
higher plants with ACC synthase and ACC oxidase playing key