Involvement of ABA in induction of secondary dormancy in barley (Hordeum vulgare L.) seeds

At harvest, barley seeds are dormant because their germination is difficult above 20 degrees C. Incubation of primary dormant seeds at 30 degrees C, a temperature at which they do not germinate, results in a loss of their ability to germinate at 20 degrees C. This phenomenon which corresponds to an induction of a secondary dormancy is already observed after a pre-treatment at 30 degrees C as short as 4-6 h, and is optimal after 24-48 h. It is associated with maintenance of a high level of embryo ABA content during seed incubation at 30 degrees C, and after seed transfer at 20 degrees C, while ABA content decreases rapidly in embryos of primary dormant seeds placed directly at 20 degrees C. Induction of secondary dormancy also results in an increase in embryo responsiveness to ABA at 20 degrees C. Application of ABA during seed treatment at 30 degrees C has no significant additive effect on the further germination at 20 degrees C. In contrast, incubation of primary dormant seeds at 20 degrees C for 48 and 72 h in the presence of ABA inhibits further germination on water similarly to 24-48 h incubation at 30 degrees C. However fluridone, an inhibitor of ABA synthesis, applied during incubation of the grains at 30 degrees C has only a slight effect on ABA content and secondary dormancy. Expression of genes involved in ABA metabolism (HvABA8'OH-1, HvNCED1 and HvNCED2) was studied in relation to the expression of primary and secondary dormancies. The results presented suggest a specific role for HvNCED1 and HvNCED2 in regulation of ABA synthesis in secondary seed dormancy.     

Modulation of germination of embryos isolated from dormant and nondormant barley grains by manipulation of endogenous abscisic acid

Dormant and non-dormant barley (Hordeum distichum L.) grains with identical genetic backgrounds were obtained by maturing grains under different climate conditions. When isolated embryos from dormant grains were incubated in a well containing a fixed volume of water (300 l), the germination rate and percentage were dependent on the embryo number per well. A higher embryo number per well was correlated with a lower germination rate and percentage. However, this was not the case for the embryos isolated from nondormant grains. During germination, the endogenous cis-abscisic acid (ABA) in isolated embryos from both dormant and nondormant grains was analyzed. The inhibitory effect on germination of a higher number per well of isolated dormant embryos was due to diffusion of endogenous ABA out of the embryos and accumulation of ABA in the incubation medium. Moreover, there was de-novo synthesis of ABA in embryos isolated from dormant grains during incubation but not in embryos isolated from nondormant grains. The inhibitory effect of ABA on germination of embryos isolated from dormant grains could be mimicked by addition of ABA or the medium in which dormant embryos had been placed. Embryos isolated from nondormant grains were insensitive to addition of ABA and medium from dormant embryos. Our results demonstrate that diffusion of endogenous ABA, de-novo ABA synthesis and ABA sensitivity play a role in the control of germination. It is proposed that dormancy-breaking treatments act via changes to these processes.Abbreviations ABA cis-abscisic acid - E/W embryo(s) per well Prof. K.R. Libbenga (Institute of Molecular Plant Sciences, Leiden University) is thanked for fruitful discussions. B.V.D. was partly supported by E.E.C. BIOTECH program PL 920175.     

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.     

Involvement of phytohormones in germination of dormant and non-dormant oat (Avena sativa L.) seeds

Oat seeds are susceptible to high temperature dormancy. Dormant grainsdo not germinate at 30 °C unless afterripened, dry, for severalweeks. Isolated embryos of dormant grains do germinate, especially ifGA₃ is added to the germination medium. ABA inhibits germinationproportionally to the concentration applied and GA₃ can overcome theABA inhibitory effect. Measurements of endogenous ABA and several GAs revealedthat the initial levels of ABA in dormant and non-dormant grains were quitesimilar. But, endogenous ABA in non-dormant seeds almost disappeared within thefirst 16 h of imbibition, while the amount in dormant grains haddecreased by less than 24%. The level of GA₁₉ in non-dormant seedswas higher, and GA₁₉ appears to be converted to GA₂₀ within the first 16h. The GA₂₀ was converted to GA₁ at leastduring the first 48 h of the germination process. Bothphytohormones thus appear to be involved in the germination process ofnon-dormant seeds. ABA first declines, while GA₁ is producedduring the first 16 h of imbibition to allow proper germination.Indormant grains the level of ABA remained high enough to prevent germinationduring at least a week and precursor GAs were not converted to GA₁.     

Seed dormancy and ABA metabolism in Arabidopsis and barley: the role of ABA 8'-hydroxylase

We have investigated the relationship between seed dormancy and abscisic acid (ABA) metabolism in the monocot barley and the dicot Arabidopsis. Whether dormant (D) or non-dormant (ND), dry seed of Arabidopsis and embryos of dry barley grains all had similarly high levels of ABA. ABA levels decreased rapidly upon imbibition, although they fell further in ND than in D. Gene expression profiles were determined in Arabidopsis for key ABA biosynthetic [the 9-cis epoxycarotenoid dioxygenasegene family] and ABA catabolic [the ABA 8'-hydroxylase gene family (CYP707A)] genes. Of these, only the AtCYP707A2 gene was differentially expressed between D and ND seeds, being expressed to a much higher level in ND seeds. Similarly, a barley CYP707 homologue, (HvABA8'OH-1) was expressed to a much higher level in embryos from ND grains than from D grains. Consistent with this, in situ hybridization studies showed HvABA8'OH-1 mRNA expression was stronger in embryos from ND grains. Surprisingly, the signal was confined in the coleorhiza, suggesting that this tissue plays a key role in dormancy release. Constitutive expression of a CYP707A gene in transgenic Arabidopsis resulted in decreased ABA content in mature dry seeds and a much shorter after-ripening period to overcome dormancy. Conversely, mutating the CYP707A2 gene resulted in seeds that required longer after-ripening to break dormancy. Our results point to a pivotal role for the ABA 8'-hydroxylase gene in controlling dormancy and that the action of this enzyme may be confined to a particular organ as in the coleorhiza of cereals.     

Barley (Hordeum vulgare) seed dormancy as related to glumella characteristics

Dormancy of freshly harvested barley ( Hordeum vulgare L. cv. Sonja) caryopses results mainly from glumellae which fix oxygen by polyphenol oxidase (EC 1.14.18.1)-mediated oxidation of phenolic compounds present in high amounts. The breaking of dormancy during dry storage is not due to qualitative or quantitative modifications of the phenols or polyphenol oxidases. Glumellae of dormant caryopses start to take up oxygen at the beginning of inbibition, whereas those of non-dormant caryopses start to take up oxygen only after about 10 h. That delay should allow germination.     

Abscisic acid-regulated responses of dormant and non-dormant embryos of Helianthus annuus: Role of ABA-inducible proteins

Embryos of Helianthus annuus L. became dormant 3 weeks after anthesis and their dormancy was lifted during storage in dry conditions. The objectives of this study were to investigate changes in the pattern of soluble proteins associated with the release of embryo dormancy. Sunflower dehydrins and group 3 late embryogenesis-abundant (LEA) proteins were studied in developing embryos. Three dehydrins (17, 21 and 26 kDa) and two group 3 LEA polypeptides (17 and 23 kDa) appeared during dormancy induction. Their levels remained steady until maturity. After imbibition, these polypeptides disappeared within 24 h except for the 23-kDa protein whose levels remained stable for a further 4 d, whatever the culture condition. Analysis of radiolabelled proteins by two-dimensional gel electrophoresis revealed that among dormancy-associated proteins other than dehydrin and group 3 LEA, several low molecular mass (18, 19, 20 and 21 kDa) proteins were expressed in dormant embryos but not detected in non-dormant embryos. After a treatment with fluridone, which inhibits ABA synthesis, or with GA₃, which allows germination to occur, the 19-kDa protein could not be detected. In contrast, application of ABA to non-dormant embryos arrested germination and enhanced the synthesis of the 18- and 21-kDa proteins, but not that of the 19- and 20-kDa polypeptides. These results demonstrate that steady-state levels of specific proteins change during early imbibition of dormant and non-dormant sunflower embryos and indicate that these changes may be associated with differential gene expression responsible for the maintenance of dormancy.     

Poly(A) polymerase in Dormant Embryos of Triticum durum

Triticum durum‘Cappelli’ has a ‘relative’dormancy which can be broken by dry after-ripening at room temperature.The breakage of dormancy in the embryos of T. durum , is accompaniedby a decline in content and a different degree of synthesisof poly(A)⁺RNA. This work studies the activity of poly(A) polymerase(E.C. 2.7.7.19), the enzyme which permits polyadenylation. Anincrease in the activity of this enzyme in parallel with theenhanced rate of germination is revealed. Since poly(A) polymeraseactivity is the same in dormant and non-dormant dry embryos,it seems that the activity of the enzyme is not involved inthe breakage of dormancy. The use of cycloheximide and cordycepinshows the presence of enzymes with different origins: a storedenzyme and one bound to a long lived mRNA, present in dormantand non-dormant embryos, plus an enzyme bound to newly synthesizedmRNA which is mainly active in non-dormant embryos. Since dormancycould be the result of an interaction between hormones, thiswork analyses the effects of GA₃and ABA on poly(A) polymerase.GA₃enhanced poly(A) polymerase activity only in dormant embryoswhile ABA inhibited this activity only in non-dormant embryos.Cycloheximide applied to excised wheat embryos represses thestimulatory and inhibitory effects of GA₃and ABA, respectively.The hormone action on poly(A) polymerase activity is thus dependenton de novo protein synthesis. Results using cordycepin suggestthe presence of a stored mRNA for poly(A) polymerase, togetherwith hormonal regulation of enzyme activity at a translationallevel. Copyright 1999 Annals of Botany Company Triticum durum , wheat, dormancy breakage, poly(A) polymerase, GA₃, ABA, germination.     

Role of reactive oxygen species in the regulation of Arabidopsis seed dormancy

Freshly harvested seeds of Arabidopsis thaliana, Columbia (Col) accession were dormant when imbibed at 25°C in the dark. Their dormancy was alleviated by continuous light during imbibition or by 5 weeks of storage at 20°C (after-ripening). We investigated the possible role of reactive oxygen species (ROS) in the regulation of Col seed dormancy. After 24 h of imbibition at 25°C, non-dormant seeds produced more ROS than dormant seeds, and their catalase activity was lower. In situ ROS localization revealed that germination was associated with an accumulation of superoxide and hydrogen peroxide in the radicle. ROS production was temporally and spatially regulated: ROS were first localized within the cytoplasm upon imbibition of non-dormant seeds, then in the nucleus and finally in the cell wall, which suggests that ROS play different roles during germination. Imbibition of dormant and non-dormant seeds in the presence of ROS scavengers or donors, which inhibited or stimulated germination, respectively, confirmed the role of ROS in germination. Freshly harvested seeds of the mutants defective in catalase (cat2-1) and vitamin E (vte1-1) did not display dormancy; however, seeds of the NADPH oxidase mutants (rbohD) were deeply dormant. Expression of a set of genes related to dormancy upon imbibition in the cat2-1 and vet1-1 seeds revealed that their non-dormant phenotype was probably not related to ABA or gibberellin metabolism, but suggested that ROS could trigger germination through gibberellin signaling activation.     

Seed Dormancy in Acer pseudoplatanus L.: the Role of the Covering Structures

The present studies with Acer pseudoplatanus L. suggest thatthe covering structures play an important and multiple rolein the dormancy of the fruit. Whole fruits and seeds with thetesta intact required a period of chilling at 5 °C beforedormancy was broken whereas bare embryos germinated immediatelyat 20 °C without pretreatment. This suggested that dormancywas coat-imposed and that the testa was responsible for thiseffect. Germination of dormant seeds was inhibited by lightwhereas the non-dormant bare embryos showed little response.Studies on the manner in which the testa imposed dormancy onthe embryo indicated that restriction on oxygen uptake, wateruptake, mechanical restriction to embryo enlargement, and thepresence of germination inhibitors in the testa were not limitingfactors at this stage of dormancy. Results from leaching experimentssuggest that dormancy was the result of the restriction by thetesta of the outward diffusion of a germination inhibitor(s)present in the embryo. In seeds that had nearly completed theirstratification requirements, the covering structures seemedto act in a manner other than by preventing the leaching ofan inhibitor from the embryo. At this point the physical propertiesof the covering structures seem to determine any further delaysin germination by the mechanical restriction of embryo enlargementby the testa and by restriction of oxygen uptake by the pericarp.     

Induction of secondary dormancy in Amaranthus caudatus seeds

Nondormant A. caudatus seeds germinated in the darkat temperatures between 20 and 35° but not at 45 °C.Incubation at this temperature for at least 10 h inhibited seedgermination over the temperature range 20 to 35 °C,temperatures previously suitable for germination. Thus incubation at 45°C induced secondary dormancy. Mechanical or chemicalscarification or exposure to pure oxygen caused complete or almost completegermination of dormant seeds although more slowly in comparison to nondormantseeds. Secondary dormant scarified seeds required a lower concentration of ABAthan nondormant seeds to inhibit germination. The high temperature, whichinduced dormancy, 45 °C, caused the seed coat to be partiallyresponsible for secondary dormancy. Involvement of ABA (synthesis orsensitivity) in the induction and/or maintenance of this dormancy should beconsidered.     

Enhancement of ABA responsiveness in wheat embryos by high temperature*†

Abstract. Mature wheat (Triticum aestivum L.) grain often possesses high-temperature dormancy which restricts the grain from germinating at warm temperatures (25–30°C). Isolated embryos from such grain exhibited little high-temperature dormancy when germinated in water. Dormancy was restored by the application of abscisic acid (ABA) to the embryos. The ability of ABA to block germination in isolated embryos was enhanced significantly by elevating the germination temperature. ABA was 100 times more effective in reducing embryonic germination at 30°C than at 15°C. These temperature effects on embryonic response to ABA are a useful system for studying the mechanism of ABA action in seed dormancy.     

Physiological basis of pre-harvest sprouting resistance in Sorghum bicolor (L.) Moench. ABA levels and sensitivity in developing embryos of sprouting-resistant and -susceptible varieties

Pre–harvest sprouting is a major problem in Sorghum cropswhich leads to losses in seed viability and produces importantdecreases in grain weight. In this paper we aimed to have aninsight into the physiological basis of pre-harvest sproutingresistance in this crop by assessing germinability, ABA embryoniccontent and embryonic sensitivity to ABA during seed developmentin three varieties presenting contrasting sprouting behaviour:Redland B2 (very susceptible), SC 650 (moderately resistant)and IS 9530 (very resistant). Redland B2 caryopses were ableto germinate with high germination indices from early stagesof development, while caryopses from IS 9530 did not presentgermination indices different from 0 until near physiologicalmaturity. SC 650 (moderately resistant) grains presented anintermediate pattern of behaviour. In all three varieties isolatedembryos were able to germinate with maximum germination indicesfrom as early as 15 d after pollination (DAP). Differences ingrain dormancy level were not paralleled by a consistently differentendogenous ABA content throughout maturation. However, whenABA embryonic content was measured in incubated 35 DAP caryopses,ABA level in B2 embryos after 24 h of incubation was found tobe less than half that observed in IS 9530 embryo after thesame period of incubation. In addition, B2 embryos were foundto be 10–fold less sensitive to the inhibitory effectof ABA than embryos from the other two varieties. These resultsexplain to a considerable extent differences in germinabilitybetween sproutingresistant and –susceptible varietiesand are consistent with differences in sprouting behaviour. Key words: Sorghum bicolor, abscisic acid, pre-harvest sprouting, seed development, germination     

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     

Regulation of dormancy in barley by blue light and after-ripening: effects on abscisic acid and gibberellin metabolism

White light strongly promotes dormancy in freshly harvested cereal grains, whereas dark and after-ripening have the opposite effect. We have analyzed the interaction of light and after-ripening on abscisic acid (ABA) and gibberellin (GA) metabolism genes and dormancy in barley (Hordeum vulgare 'Betzes'). Analysis of gene expression in imbibed barley grains shows that different ABA metabolism genes are targeted by white light and after-ripening. Of the genes examined, white light promotes the expression of an ABA biosynthetic gene, HvNCED1, in embryos. Consistent with this result, enzyme-linked immunosorbent assays show that dormant grains imbibed under white light have higher embryo ABA content than grains imbibed in the dark. After-ripening has no effect on expression of ABA biosynthesis genes, but promotes expression of an ABA catabolism gene (HvABA8'OH1), a GA biosynthetic gene (HvGA3ox2), and a GA catabolic gene (HvGA2ox3) following imbibition. Blue light mimics the effects of white light on germination, ABA levels, and expression of GA and ABA metabolism genes. Red and far-red light have no effect on germination, ABA levels, or HvNCED1. RNA interference experiments in transgenic barley plants support a role of HvABA8'OH1 in dormancy release. Reduced HvABA8'OH1 expression in transgenic HvABA8'OH1 RNAi grains results in higher levels of ABA and increased dormancy compared to nontransgenic grains.     

Isolation of a VP1 homologue from wheat and analysis of its expression in embryos of dormant and non-dormant cultivars.

A VP (Viviparous) 1 homologous gene has been cloned from wheat (Triticum aestivumL.). Its expression level was examined in the mature embryos of dormant and non-dormant cultivars. The level of expression was positively correlated with the level of seed dormancy and embryo sensitivity to abscisic acid (ABA).     

A possible mechanism of high temperature dormancy regulation in seeds of Avena sativa L. (cv. Moyencourt)

Embryos of Avena sativa L. (cv. Moyencourt) show no high temperature dormancy. The dormancy is induced by the presence of endosperm-aleurone part of the seed. Germination of isolated embryos at 30°C can be prevented by ABA and the inhibition is reversed by GA. Inhibitors of GA synthesis also inhibit embryo germination. The embryos of dormant and non-dormant seeds vary greatly in their sensitivity to exogenous ABA. High temperature dormancy of the entire seeds can be relieved by low concentrations of ethanol. On the basis of these facts a hypothetic model is proposed showing how interaction between endogenous GA and ABA-like inhibitory substance, may regulate the high temperature dormancy of the seeds.