Abstract
Seed priming is a controlled hydration process, followed by dehydration, that allows
pregerminative metabolic activity to proceed without germination. The objective of this
research was to investigate the effects of priming on intrinsic characteristics of seed
germination including temperature, water, and development, in order to understand how
priming affects the germination of broccoli (Brassica oleracea var. italica Plenck) seeds.
Priming of broccoli seeds consistently improved germination and emergence rate in the
laboratory and field and was related to the accumulation of a specific level of
hydropriming units expressed in MPa*h. Priming reduced the sensitivity of seed
germination to temperature and increased the temperature range of germination but did
not lower the minimum temperature for germination. Primed seeds leaked less electrolytes
at supraoptimal temperatures (≥35°C) compared to nonprimed seeds. In the field, primed
seeds produced a greater plant stand and yield under stressful emergence conditions.
Under optimal conditions in the field for stand establishment, the advancement in
emergence of primed seeds did not carry over to earlier, greater yields. Matric priming,
using calcium silicate as the carrier in the ratio 1.0:0.8:1.8 (seed:carrier:water; by weight)
for 7 d at 20°C, was superior to osmotic priming using polyethylene glycol (pEG 8000) at
-1.2 :MPa in nearly all variables examined. This may be attributed to reduced respiration
during priming of seeds in PEG or nutrient uptake by seeds in calcium silicate.
The testa was observed to be a barrier to broccoli seed germination. Priming-induced
changes to the physical characteristics of broccoli seeds included increased volume (32%)
and an irreversibly expanded, and weakened testa with some minute cracking near the area
where the radicle emerges. Primed seeds germinated faster, in part by maintaining a lower
hydrotime constant, and thus exhibited a greater progression towards germination per unit
water potential at a constant temperature compared with nonprimed seeds. It was
hypothesized that, since the testa threshold was reduced after priming by expansion and
formation of free spaces, the reversibly expanded embryo of primed seeds does not
become immediately appressed to the testa upon rehydration. Thus the yield threshold
component controlling the rate of germination of primed seeds is lower by the amount of
the testa threshold. The priming effect is more than just reducing the yield threshold as
indicated by a significant invigoration of seeds with split testae. Despite the increased
volume as a result of the formation of free spaces, primed broccoli seeds did not imbibe
more water or have a greater turgor at full hydration. Priming did not lower the minimum
water potential allowing germination, and primed seeds did not plateau in water uptake
but, instead, moved immediately from imbibition to expansive growth. Priming improved
the germination rate of broccoli seeds at all stages of maturity with the most significant
effects at stages before attainment of maximum dry weight. Dry storage of broccoli seeds
at harvest able maturity (≥ 56 days after pollination) did not improve germination,
indicating a lack of post harvest dormancy.
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