ABA insensitivity and low ABA levels during seed development of non-dormant wheat mutants

Three wheat (Triticum aestivum L.) mutants that lacked dormancyat maturity were isolated from an ethylmethane sulphonate-treatedpopulation of a dormant red-grained line, Kitakei-1354 (Kitakei).The three mutants (EH47-1, EH47-2-5 and EH47-2-6) were selectedin segregating generations derived from one M₂ plant. They differin morphological and physiological characteristics, showingthat these mutants contained several mutations besides non-dormancy.Despite these differences, embryos of all the mutants rapidlylost sensitivity to abscisic acid (ABA) during the later halfof seed maturation while Kitakei embryos maintained the sensitivityeven after maturity. These results suggest that embryo sensitivityto ABA plays a key role in seed dormancy. The profile of ABAcontent of EH47-1 embryos during seed development was similarto that of Kitakei, except for a significantly lower level at30 d after pollination (DAP). This reduced level of ABA at DAP30is discussed in relation to the development of seed dormancyand ABA sensitivity of the embryos. Segregation ratios for non-dormancyin progeny of EH47-1Kitakei crosses suggest that the non-dormancyof EH47-1 is a single dominant mutation. Key words: Abscisic acid, wheat, seed dormancy, inheritance, mutant     

Breakage of Pseudotsuga menziesii seed dormancy by cold treatment as related to changes in seed ABA sensitivity and ABA levels

The main aims of the present work were to investigate whether a chilling treatment which breaks dormancy of Douglas fir ( Pseudotsuga menziesii (Mirb.) Franco) seeds induces changes in the sensitivity of seeds to exogenous ABA or in ABA levels in the embryo and the megagametophyte, and whether these changes are related to the breaking of dormancy. Dormant seeds germinated very slowly within a narrow range of temperatures (20–30°C), the thermal optimum being approximately 25°C. The seeds were also very sensitive to oxygen deprivation. Treatment of dormant seeds at 5°C improved further germination, and resulted in a widening of the temperature range within which germination occurred and in better germination in low oxygen concentrations. In dry dormant seeds the embryo contained about one-third of the ABA in the megagametophyte. ABA content of both organs increased during the first 4 weeks of chilling. It then decreased sharply in the megagametophyte to the level in the embryo after 7–15 weeks of chilling. At 15°C, a temperature at which dormancy was expressed, the ABA level increased in the embryo and the megagametophyte of dormant unchilled seeds whereas it decreased in the organs of chilled seeds. The longer the chilling treatment, the faster the decrease in ABA after the transfer of seeds from 5°C to higher temperatures, and the decrease was faster at 25 than at 15°C. These results suggest that the breaking of dormancy by cold was associated with a lower capacity of ABA biosynthesis and/or a higher ABA catabolism in the seeds subsequently placed at 15 or 25°C. Moreover, the chilling treatment resulted in a progressive decrease in the sensitivity of seeds to exogenous ABA. However, seeds remained more sensitive to ABA at 15 than at 25°C. The possible involvement of ABA synthesis and of responsiveness of seeds to ABA in the breaking of dormancy by cold treatment is discussed.     

ABA调控种子发育的研究进展

种子发育是一个复杂的生物学过程，受各种遗传和外界因素的调节，显著影响农作物特别是禾谷类作物的种子活力和产量与质量。脱落酸(ABA)是调控种子发育和萌发最重要的植物激素之一，其活性水平、信号转导及其LAFL网络在种子发育包括胚胎发生和成熟过程的调控中起关键作用。该文主要综述了近年来ABA调控种子发育的研究取得的重要进展，包括ABA代谢和信号转导对种子发育的调控，ABA与种子成熟转录因子(AFL-B3、FUS3、ABI3、LEC2等)的作用，以及ABA在种子发育中的作用机制，并提出了需要进一步研究的科学问题，为深入理解种子发育的分子机制提供参考，从而提高种子的活力、产量和质量。     

Dormancy, ABA content and sensitivity of a barley mutant to ABA application during seed development and after ripening.

Assessment of dormancy inception, maintenance and release was studied for artificially dried immature seeds harvested throughout seed development in the barley cv. Triumph and its mutant line TL43. Each was grown in Spain and Scotland under low and high dormancy inducing conditions, respectively. Both TL43 and Triumph followed a similar pattern of release from dormancy across the seasons, although seeds of TL43 were able to germinate at an earlier seed development stage. Abscisic acid (ABA) content was also studied in immature grains throughout the seed development period. Total amount of ABA in seeds of Triumph and TL43 was higher in plants grown in Scotland than in Spain. However, no clear genotypic differences in ABA pattern in the course of grain development could be detected whilst significant genotypic differences were observed for germination percentage (GP). Endogenous ABA content alone throughout grain development did not explain genetic differences in GP within environments. Environmental and genetic differences in dormancy were also observed on mature seeds throughout the after-ripening period. The initial germination (GP(0)) played a key role in the sensitivity to ABA of post-harvest mature seeds. For the same after-ripening stage, TL43 was more insensitive to exogenous ABA than Triumph. However, ABA responses in seeds of the two genotypes with similar GP(0) at different after-ripening stages were comparable. Therefore, differences in exogenous ABA sensitivity of post-harvest mature grain of these two genotypes seemed to be determined by, or coincident with, the initial germination percentage.     

Influence of an abscisic acid (ABA) seed coating on seed germination rate and timing of Bluebunch Wheatgrass

Semi‐arid rangeland degradation is a reoccurring issue throughout the world. In the Great Basin of North America, seeds sown in the fall to restore degraded sagebrush (Artemisia spp.) steppe plant communities may experience high mortality in winter due to exposure of seedlings to freezing temperatures and other stressors. Delaying germination until early spring when conditions are more suitable for growth may increase survival. We evaluated the use of BioNik? (Valent BioSciences LLC) abscisic acid (ABA) to delay germination of bluebunch wheatgrass (Pseudoroegneria spicata). Seed was either left untreated or coated at five separate rates of ABA ranging from 0.25 to 6.0 g 100 g^?1 of seed. Seeds were incubated at five separate constant temperatures from 5 to 25°C. From the resultant germination data, we developed quadratic thermal accumulation models for each treatment and applied them to 4 years of historic soil moisture and temperature data across six sagebrush steppe sites to predict germination timing. Total germination percentage remained similar across all temperatures except at 25°C, where high ABA rates had slightly lower values. All ABA doses delayed germination, with the greatest delays at 5–10°C. For example, the time required for 50% of the seeds to germinate at 5°C was increased by 16–46 d, depending on the amount of ABA applied. Seed germination models predicted that the majority of untreated seed would germinate 5–11 weeks after a 15 October simulated planting date. In contrast, seeds treated with ABA were predicted to delay germination to late winter or early spring. These results indicate that ABA coatings may delay germination of fall planted seed until conditions are more suitable for plant survival and growth.     

脱落酸和赤霉素调控种子休眠与萌发研究进展

种子的休眠与萌发是高等植物生长发育进程中非常重要的环节,是维系物种繁衍的重要过程。而激素在这一过程中扮演着非常重要的角色。而在这个过程中脱落酸(abscisic acid,ABA)和赤霉素(gibberellin GA)发挥着尤其重要的作用。本文综述了当前对复杂分子网络的理解,这些分子网络涉及脱落酸和赤霉素在调节种子休眠和萌发中的关键作用,其中含AP2结构域的转录因子起着关键作用。     

AtNEK6 interacts with ARIA and is involved in ABA response during seed germination

ARIA is an ARM repeat protein that is a positive regulator of ABA response. To identify ARIA-interacting proteins, we conducted yeast two-hybrid screening. One of the positive clones obtained from the screen encoded a protein kinase, AtNEK6, which belongs to the NIMA (Never In Mitosis, gene A)-related kinase family. We analyzed AtNEK6 over-expression (OX) and knockout (KO) lines to investigate its in vivo function. The AtNEK6 OX lines grew slowly, whereas the KO line germinated and grew faster than wild type plants. AtNEK6 also affected ABA and stress responses. During seed germination, AtNEK6 OX lines were hypersensitive to ABA and high osmolarity, whereas its KO line was partially insensitive to ABA and high osmolarity. Previously, AtNEK6 was shown to be involved in epidermal cell morphogenesis. Our results indicate that AtNEK6 is also involved in plant growth regulation and responses to ABA and high osmolarity during the seed germination stage.     

AtPER1 enhances primary seed dormancy and reduces seed germination by suppressing the ABA catabolism and GA biosynthesis in Arabidopsis seeds

Seed is vital to the conservation of germplasm and plant biodiversity. Seed dormancy is an adaptive trait in numerous seed‐plant species, enabling plants to survive under stressful conditions. Seed dormancy is mainly controlled by abscisic acid (ABA) and gibberellin (GA) and can be classified as primary and secondary seed dormancy. The primary seed dormancy is induced by maternal ABA. Here we found that AtPER1, a seed‐specific peroxiredoxin, is involved in enhancing primary seed dormancy. Two loss‐of‐function atper1 mutants, atper1‐1 and atper1‐2, displayed suppressed primary seed dormancy accompanied with reduced ABA and increased GA contents in seeds. Furthermore, atper1 mutant seeds were insensitive to abiotic stresses during seed germination. The expression of several ABA catabolism genes (CYP707A1, CYP707A2, and CYP707A3) and GA biosynthesis genes (GA20ox1, GA20ox3, and KAO3) in atper1 mutant seeds was increased compared to wild‐type seeds. The suppressed primary seed dormancy of atper1‐1 was completely reduced by deletion of CYP707A genes. Furthermore, loss‐of‐function of AtPER1 cannot enhance the seed germination ratio of aba2‐1 or ga1‐t, suggesting that AtPER1‐enhanced primary seed dormancy is dependent on ABA and GA. Additionally, the level of reactive oxygen species (ROS) in atper1 mutant seeds was significantly higher than that in wild‐type seeds. Taken together, our results demonstrate that AtPER1 eliminates ROS to suppress ABA catabolism and GA biosynthesis, and thus improves the primary seed dormancy and make the seeds less sensitive to adverse environmental conditions.     

The endosperm seed protein Solin: biochemical characterization,induction by ABA and species-specific subunits

Summary Comparison of endosperm storage protein sub units from single seeds of 19 Solanum species was done by isoelectric focusing. Species-specific profiles of the subunits were evident and species relationships within a taxonomic series could be delineated. The identification of both intraspecific and interspecific hybrid seed may be possible from Solin IEF subunit profiles. The glutelin nature of the protein was unusual for a dicotyledon genus. We named this major endosperm protein complex Solin. Solin was found in developing seeds with embryos at the heart stage, 16 to 18 days after pollination. Seeds excised at the globular stage responded to the addition of ABA and synthesized Solin. This is the first report of the induction of seed protein in endosperm cells of Solanum.Scientific journal series article No. 14703 of the Minnesota Experiment Station     

De novo ABA synthesis and expression of seed dormancy in a gymnosperm: Pseudotsuga menziesii

Seeds of dormant Douglas-fir seeds germinated poorly when they were cultivated at 20–23 °C while isolated embryos germinated fully within two weeks. Seed dormancy was therefore imposed on the embryo by its surrounding structures. This physiological behaviour was well correlated with changes in ABA level during culture. Indeed, the ABA level decreased in isolated embryos while it increased in both embryo and megagametophyte during culture of whole seeds. The origin of this increase was analysed and the different ways by which seed coats could interfere with ABA accumulation are discussed.     

MtABCG20 is an ABA exporter influencing root morphology and seed germination of Medicago truncatula

Abscisic acid (ABA) integrates internal and external signals to coordinate plant development, growth and architecture. It plays a central role in stomatal closure, and prevents germination of freshly produced seeds and germination of non‐dormant seeds under unfavorable circumstances. Here, we describe a Medicago truncatula ATP‐binding cassette (ABC) transporter, MtABCG20, as an ABA exporter present in roots and germinating seeds. In seeds, MtABCG20 was found in the hypocotyl–radicle transition zone of the embryonic axis. Seeds of mtabcg20 plants were more sensitive to ABA upon germination, due to the fact that ABA translocation within mtabcg20 embryos was impaired. Additionally, the mtabcg20 produced fewer lateral roots and formed more nodules compared with wild‐type plants in conditions mimicking drought stress. Heterologous expression in Arabidopsis thaliana provided evidence that MtABCG20 is a plasma membrane protein that is likely to form homodimers. Moreover, export of ABA from Nicotiana tabacum BY2 cells expressing MtABCG20 was faster than in the BY2 without MtABCG20. Our results have implications both in legume crop research and determination of the fundamental molecular processes involved in drought response and germination.     

Relationship of chlorophyll, seed moisture and ABA levels in the maturing Brassica napus seed and effect of a mild freezing stress

Chlorophyll (Chl) retention by mature seed of canola as the result of an early frost or other environmental factors (the "green seed problem") causes serious economic losses. The relationship of seed degreening to rate of moisture loss by seed and silique and the role of ABA in this process were investigated as a function of developmental age. During the normal predesiccation stage (28–45 days after pollination), seed of Brassica napus (cv. Westar) loses Chl rapidly but seed moisture slowly. After a mild freezing stress, there is a rapid loss of moisture from silique walls, followed by accelerated loss of seed moisture. Chl degradation ceases at 35–45% seed moisture. ABA levels in silique walls of frozen plants (determined by enzyme‐linked immunosorbant assay) increased after freezing, apparently in response to moisture loss. In contrast, ABA levels in the seed increased dramatically 1 day after freezing, then decreased to control levels. The influence of the rate of seed moisture loss on Chl degradation was investigated by fast and slow drying of isolated seed under controlled humidity conditions. Seed dried rapidly at 22% RH retained most of its Chl, whereas seed dried slowly at 86% RH lost Chl as fast or faster than seed on control (unfrozen) plants. In all treatments, Chl loss stopped at about 40% seed moisture.     

A proteomic analysis of rice seed germination as affected by high temperature and ABA treatment

Seed germination is a critical phase in the plant life cycle, but the specific events associated with seed germination are still not fully understood. In this study, we used two‐dimensional gel electrophoresis followed by mass spectrometry to investigate the changes in the proteome during imbibition of Oryza sativa seeds at optimal temperature with or without abscisic acid (ABA) and high temperature (germination thermoinhibition) to further identify and quantify key proteins required for seed germination. A total of 121 protein spots showed a significant change in abundance (1.5‐fold increase/decrease) during germination under all conditions. Among these proteins, we found seven proteins specifically associated with seed germination including glycosyl hydrolases family 38 protein, granule‐bound starch synthase 1, Os03g0842900 (putative steroleosin‐B), N‐carbamoylputrescine amidase, spermidine synthase 1, tubulin α‐1 chain and glutelin type‐A; and a total of 20 imbibition response proteins involved in energy metabolism, cell growth, cell defense and storage proteins. High temperature inhibited seed germination by decreasing the abundance of proteins involved in methionine metabolism, amino acid biosynthesis, energy metabolism, reserve degradation, protein folding and stress responses. ABA treatment inhibited germination and decreased the abundance of proteins associated with methionine metabolism, energy production and cell division. Our results show that changes in many biological processes including energy metabolism, protein synthesis and cell defense and rescue occurred as a result of all treatments, while enzymes involved in methionine metabolism and weakening of cell wall specifically accumulated when the seeds germinated at the optimal temperature.