Fluctuating temperatures have different effects on embryonic sensitivity to ABA in Sorghum varieties with contrasting pre-harvest sprouting susceptibility

The effect of fluctuating temperatures on the germination ofimmature caryopses of two Sorghum varieties presenting contrastingsusceptibility to pre-harvest sprouting was investigated. Fluctuatingtemperatures were able to stimulate germination of immaturecaryopses of both varieties from early stages of development(i.e. 15 d after pollination). Isolated embryos from both varietiesgerminated well in water irrespective of the thermal regimeof incubation. However, the ability of ABA to block germinationin Redland B2 (sproutingsusceptible) isolated embryos was significantlyreduced when embryos were incubated under fluctuating temperaturesfrom 23 DAP onwards. No such effect was found in IS 9530 (sprouting-resistant)embryos. No differences in the pattern with which embryonicABA content decreased during whole grain incubation were foundin 25 and 35 DAP grains from both varieties incubated underconstant or fluctuating temperatures. Therefore, these resultsindicate that alternating temperatures can promote germinationthrough different mechanisms. One of them is the decrease inembryo sensitivity to ABA inhibition which appears to be actingin Redland B2 caryopses from 23 DAP onwards; the other one seemsto be independent of ABA level and sensitivity and is activeat very early stages of development in one variety (RedlandB2) and throughout seed development in the other (IS 9530). Key words: Germination, dormancy, fluctuating temperatures, abscisic acid, seed development, Sorghum bicolor     

Changes in the light sensitivity of buried Polygonum aviculare seeds in relation to cold-induced dormancy loss: development of a predictive model

The effect of cold (stratification) temperature on changes in the sensitivity of Polygonum aviculare seeds to light was investigated. Seeds buried in pots were stored under stratification temperatures (1.6, 7 and 12 degrees C) for 137 d. Seeds exhumed at regular intervals during storage were exposed to different light treatments. Germination responses obtained for seeds exposed to different light treatments and stratification temperatures were used to develop a model to predict the sensitivity of buried seeds to light. Seed sensitivity to light increased as dormancy loss progressed, showing the successive acquisition of low-fluence responses (LFR), very low-fluence responses (VLFR), and the loss of the light requirement for germination for a fraction of the seed population. These changes were inversely correlated to stratification temperature, allowing the use of a thermal time index to relate observed changes in seed light sensitivity to stratification temperature. The rate of increase in sensitivity of P. aviculare seeds to light during stratification is inversely correlated to soil temperature, and these changes in light sensitivity could be predicted in relation to temperature using thermal-time models.     

Hormonal Regulation of Dormancy in Developing Sorghum Seeds

The role of abscisic acid (ABA) and gibberellic acid (GA) in determining the dormancy level of developing sorghum (Sorghum bicolor [L.] Moench.) seeds from varieties presenting contrasting preharvest sprouting behavior (Redland B2, susceptible; IS 9530, resistant) was investigated. Panicles from both varieties were sprayed soon after pollination with fluridone or paclobutrazol to inhibit ABA and GA synthesis, respectively. Fluridone application to the panicles increased germinability of Redland B2 immature caryopses, whereas early treatment with paclobutrazol completely inhibited germination of this variety during most of the developmental period. Incubating caryopses in the presence of 100 [mu]M GA4+7 overcame the inhibitory effect of paclobutrazol, but also stimulated germination of seeds from other treatments. IS 9530 caryopses presented germination indices close to zero until physiological maturity (44 d after pollination) in control and paclobutrazol-treated particles. However, fluridone-treated caryopses were released from dormancy earlier than control and paclobutrazol-treated caryopses. Incubation in the presence of GA4+7 stimulated germination of caryopses from all treatments. Our results support the proposition that a low dormancy level (which is related to a high preharvest sprouting susceptibility) is determined not only by a low embryonic sensitivity to ABA, but also by a high GA content or sensitivity.     

Effects of Neotyphodium fungi on Lolium multiflorum seed germination in relation to water availability

BACKGROUND AND AIMS: Temperate endophyte-infected (Neotyphodium sp.) grasses have been shown to exhibit an ecological advantage over endophyte-uninfected grasses under abiotic stressful conditions. It is predicted that endophyte-infected plant populations will display higher rates of germination and proportion of germinated seeds under limiting water conditions. METHODS: The hydrotime regression model was used to describe the effect of Neotyphodium endophyte on seed germination of Lolium multiflorum at different water potentials. Additionally, seed mortality after water stress exposure was estimated in endophyte-infected and -uninfected seeds. KEY RESULTS: Endophyte infection inhibited seed germination at all water potentials. The hydrotime model described satisfactorily the germination responses, and revealed that endophyte-free seeds exhibited higher rates of and final percentage germination, probably due to a lower base water potential compared with endophyte-infected seeds. However, Neotyphodium endophyte conferred a higher rate of survival in those seeds that remained ungerminated when exposed to highly water stress conditions. CONCLUSIONS: Changes produced by Neotyphodium endophyte in L. multiflorum seeds might affect fitness in particular ecological scenarios. For example, the presence of the endophyte may curtail seed germination when water is limiting, reducing the risk of seedling death. Conversely, endophyte-free seeds would display an enhanced germination, ensuring a more rapid seedling establishment if later water conditions do not restrict plant growth.     

Quantifying the sensitivity of barley seed germination to oxygen, abscisic acid, and gibberellin using a population-based threshold model

Barley (Hordeum vulgare L.) seeds (grains) exhibit dormancyat maturity that is largely due to the presence of the glumellae(hulls) that reduce the availability of oxygen (O₂) to the embryo.In addition, abscisic acid (ABA) and gibberellins (GAS) interactwith O₂ to regulate barley seed dormancy. A population-basedthreshold model was applied to quantify the sensitivities ofseeds and excised embryos to O₂, ABA, and GA, and to their interactiveeffects. The median O₂ requirement for germination of dormantintact barley seeds was 400-fold greater than for excised embryos,indicating that the tissues enclosing the embryo markedly limitO₂ penetration. However, embryo O₂ thresholds decreased by anotherorder of magnitude following after-ripening. Thus, increasesin both permeability of the hull to O₂ and embryo sensitivityto O₂ contribute to the improvement in germination capacityduring after-ripening. Both ABA and GA had relatively smalleffects on the sensitivity of germination to O₂, but ABA andGA thresholds varied over several orders of magnitude in responseto O₂ availability, with sensitivity to ABA increasing and sensitivityto GA decreasing with hypoxia. Simple additive models of O₂–ABAand O₂–GA interactions required consideration of theseO₂ effects on hormone sensitivity to account for actual germinationpatterns. These quantitative and interactive relationships amongO₂, ABA, and GA sensitivities provide insight into how dormancyand germination are regulated by a combination of physical (O₂diffusion through the hull) and physiological (ABA and GA sensitivities)factors. Key words: Abscisic acid, barley, germination, gibberellin, Hordeum vulgare L., model, oxygen, sensitivity Received 2 August 2007; Revised 14 November 2007 Accepted 19 November 2007