Abstract
The germination response of Hylocereus setaceus seeds to isothermic incubation at different water potentials was analysed by using the thermal time and hydrotime models, aiming to describe some germination parameters of the population and to test the validity of the models to describe the response of the seeds to temperature and water potential. Hylocereus setaceus seeds germinated relatively well in a wide range of temperatures and the germination was rate limited from 11 to 20 degrees C interval and beyond 30 degrees C until 40 degrees C, in which the germination rate respectively shifts positively and negatively with temperature. The minimum or base temperature (T(b)) for the germination of H. setaceus was 7 degrees C, and the ceiling temperature varied nearly from 43.5 to 59 degrees C depending on the percent fraction, with median set on 49.8 degrees C. The number of degrees day necessary for 50% of the seeds to germinate in the infra-optimum temperature range was 39.3 degrees C day, whereas at the supra-optimum interval the value of theta = 77 was assumed to be constant throughout. Germination was sensitive to decreasing values of psi in the medium, and both the germinability and the germination rate shift negatively with the reduction of psi, but the rate of reduction changed with temperature. The values of base water potential (psi(b)) shift to zero with increasing temperatures and such variation reflects in the relatively greater effect of low psi on germination in supra optimum range of T. In general, the model described better the germination time courses at lower than at higher water potentials. The analysis also suggest that Tb may not be independent of psi and that psi(b(g)) may change as a function of temperature at the infra-otimum temperature range.
Highlights
Successful establishment of plant species in a natural environment can be related to timing for germination resulting from seed response to environmental factors such as water availability, light and temperature
The application of the model is based on the observation that there is a temperature range over which the germination rate for a given fraction g% increases linearly with the temperature according to the equation: 1/tg = (T – temperatura mínima ou base (Tb))/θg, where tg is the time to germination of the fraction g%, T is the actual temperature and θg is the “thermal time”, which is followed by the notation g to indicate that it varies from seed to seed
In order to find the cardinal temperatures of the seed batch, Hylocereus setaceus seeds were germinated in distilled water under white light at different constant temperatures
Summary
Successful establishment of plant species in a natural environment can be related to timing for germination resulting from seed response to environmental factors such as water availability, light and temperature. Only the germination rate (the reciprocal of the time taken for the germination) is affected by temperature and such germination rate dependency on temperature may be one of the most important factors controlling the emergence timing in the field, influencing the probability of seedling establishment (Washitani, 1985). The application of the model is based on the observation that there is a temperature range over which the germination rate for a given fraction g% increases linearly with the temperature according to the equation: 1/tg = (T – Tb)/θg, where tg is the time to germination of the fraction g%, T is the actual temperature and θg is the “thermal time”, which is followed by the notation g to indicate that it varies from seed to seed. The thermal time represents the progress toward germination and it can give a good estimate of the time to emergence for specific crops
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