ABSTRACT
Effect of different water conditions on the physiological indexes (e.g.seed water content, vigor, antioxidase activities)of Panax notoginseng seeds were studied under process of after-ripening and germination.The results showed show that compared with 2.5% treatment, under the treatment of 5%, P.notoginseng seeds possessed stable seed water content, the seed vigor was exceed by 51%,variation of antioxidant enzyme (SOD, POD, CAT) activity and malondialdehyde (MDA) content were small, crude fat and total sugar content decreased significantly.With the increase of PEG 6000 concentration, the germination characteristic indexes obviously decreased, antioxidase activities increased firstly and decreased afterwards, content of MDA, soluble protein and total sugar increased obviously.There were significant positive correlation between germination characteristic indexes and osmotic substance content(r>0.900, P<0.01), and significant negative correlation with MDA (r>0.900, P<0.01).In conclusion, because the characteristic of dehydration intolerance of P.notoginseng seeds, 5% water content of sand burying stratification treatment was the best for after-ripening, 15% concentration of PEG 6000 treatment was the highest tolerance limit of germination process.
ABSTRACT
Miconia chartacea es un árbol con amplia distribución altitudinal y latitudinal en Brasil, que se encuentra desde formaciones vegetales estacionales xerofíticas como Caatinga y Cerrado hasta bosques pluviales como Mata Atlántica, en pastizales con árboles aislados hasta interior de bosques maduros. Fue descrita la respuesta germinativa de las semillas de M. chartacea a la luz, temperatura, hormonas vegetales y posmaduración a baja temperatura. Los frutos se recolectaron en la reserva de Cerrado "Prof. Karl Arens", en el municipio Corumbataí (San Paulo, Brasil), la cual presenta una estación seca y fría desde abril hasta septiembre y una estación húmeda y caliente de octubre a marzo. Las semillas se dispersaron durante la estación seca, son fotoblásticas positivas bajo temperaturas constantes y variables, la germinación disminuye bajo irradiaciones de luz blanca inferiores a 17 umol/m2s, la razón rojo/rojo lejano (R/RL) no afectó el porcentaje de germinación, pero la velocidad de germinación aumentó a partir de razones R/ RL > 0.4. Las semillas germinaron en el intervalo térmico de 15 a 35 °C, la temperatura optima esta entre 20 y 25 °C, la alternancia de temperatura no estimuló la germinación respecto a las temperaturas constantes. Las semillas presentaron latencia fisiológica no profunda, la cual fue rota mediante posmaduración durante 93 días a 7 °C y el etileno estimuló la germinación. La gama de temperaturas en la cual germinan las semillas fue menor en las semillas maduradas bajo las condiciones más calientes de la transición de la estación lluviosa a seca que las semillas maduradas en la estación seca. El requerimiento de un periodo frío para romper latencia disminuye la probabilidad de que las semillas germinen durante el invierno, quedando listas para germinar en el verano. Así, la detección de cambios estacionales de temperatura del suelo y el aumento de sensibilidad a la temperatura después de un periodo de frío son responsables por el control temporal de la germinación de M. chartacea, mientras que la respuestas a luz permite que solo germinen las semillas que están en la superficie del suelo, y favorece la germinación en claros de bosque pequeños a grandes.
Miconia chartacea is a widely distributed tree along both altitudinal and latitudinal gradients in Brazil, and it can be found in seasonal xerophytic vegetation, e.g. Caatinga and Cerrado, and tropical rainforest (e.g. Mata Atlantica), from grassland with scattered trees to mature forest. We studied the germination response of M. chartacea seeds to light, temperature, plant hormones and after-ripening at low temperature. Seeds were collected from a Cerrado reserve located in Corumbataí, Sao Paulo State, which characterizes to have a cool dry season from April to September, and a warm wet season from October to March. M. chartacea seeds are dispersed in the dry season and exhibited a photoblastic behavior both at constant and alternating temperatures. The germination was decreased at irradiances below 17 umol / m2s, whereas R: FR ratios below 0.4 reduced the germination rate, but not the germination capacity. The germination-permissive temperatures range from 15 to 35 °C, with an optimum interval from 20 to 25 °C. Germination is not improved by alternating temperature regimes as compared to isothermal treatments. The seeds have a non-deep physiological dormancy, which can be partially overcame either by dry after-ripening at 7 °C for 93 days, or by the 2-chloroethylphosphonic acid treatment. The thermal window within which the seeds germinate was narrower for seeds matured in the rainy to dry season transition period, under warmer conditions, than in the dry season. Cold requirement for dormancy break in seeds of M. chartacea can prevent the germination in the winter, allowing the seeds to germinate in the summer under more favorable conditions. The results suggest that seed response to temperature accounts for temporal distribution of germination, of M. chartacea, while light predominantly influences the spatial distribution of seedlings, precluding the germination of buried seeds and affecting the germination response to gap size.
ABSTRACT
Objective: The studies were carried out on the endogenous phytohormone changes of Panax notoginseng seeds during the after-ripening process in order to understand the machanism of endogenous phytohormones (GA, IAA, ZR, and ABA) in the process of embryo development and dormancy release. Methods: Dynamic changes of endogenous phytohormones of P. notoginseng seeds were measured by ELISA method through the entire after-ripening process. Results: The contents of endogenous GA, IAA, and ZR increased with the embryo development, while the ABA content decreased contrarily. Conclusion: The change of phytohormone balance is one of determining factors for relieving dormancy and promoting germination of P. notoginseng seeds.