Abstract
This study investigated the influence of both shaking duration and number of trees per bale on postharvest needle characteristics such as percentage needle loss, needle retention duration and explored the physiological roles of endogenous ethylene and volatile terpene compounds (VTCs). To accomplish these objectives, 25 six-year-old trees were detached and exposed to a range of shaking durations (0 to 60 sec.), and 30 six-year-old detached trees were exposed to baling treatments from 0 to 5 trees. Response variables measured were percent needle loss, needle retention duration, average water use, ethylene and volatile terpene compound evolution. Trees shaken for 60 seconds lost 16% less needle compared to control, which was consistent with the decrease in percent needle loss with increasing shaking duration. Baled trees lost 13% more needles compared to control, but percent needle loss was observed to decrease with increasing number of trees in a bale. These trends corresponded with increasing ethylene and VTC evolutions, where the longer the shaking duration or larger number of trees in a bale, the higher the ethylene and VTC evolutions. One can therefore draw inference that mechanical perturbation as a result of shaking and baling induce biosynthesis and regulation of ethylene and VTC in balsam fir trees in an effort to regulate postharvest needle abscission.
Highlights
This study investigated the influence of both shaking duration and number of trees per bale on postharvest needle characteristics such as percentage needle loss, needle retention duration and explored the physiological roles of endogenous ethylene and volatile terpene compounds (VTCs)
1) Percent needle loss (PNL)—ANOVA test performed showed that duration of tree shaking and number of trees in a bale had a significant effect on Percentage Needle Loss (PNL) (Table 1)
Ethylene and VTC evolution were consistent with the trends in PNL
Summary
Shaking of trees is done in an attempt to meet international-market quarantine standards since the practice is known to reduce or remove dust, pollen, debris and molds off the trees, and remove any dead needles, broken branches and hidden insects [1]. Postharvest shaking and baling of trees have been suggested to cause mechanical stress, contributing to a significant negative effect on postharvest qualities of trees [2]. Mechanical stresses caused through shaking and baling of trees can cause physiological perturbations, which may cause postharvest needle abscission. Such a mechanically-induced postharvest stress has been reported in several species [3] [4] [5]. Mechanical perturbations as a result of wind, rain, handling and predations are among the many environmental stimuli to which plants respond [4] [6]
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