Role of ABA in Maturation of Rapeseed Embryos

Development of Brassica napus L. cv Tower embryos of different ages cultured in vitro with and without abscisic acid (ABA) was compared with normal development in situ to investigate the role of ABA in embryo maturation. Endogenous ABA levels were measured by radioimmunoassay, and sensitivity to ABA was assayed in terms of its ability to suppress precocious germination and stimulate accumulation of storage protein and storage protein mRNA. During development in situ, the levels of endogenous ABA and 12S storage protein mRNA both reach their peaks just before the embryos begin to desiccate. The ABA levels during this phase of development also correlate with the time required in culture before germination is evident. Following these peaks, increasing concentrations of exogenous ABA are required to both suppress germination and continue storage protein accumulation in vitro. Thus, both endogenous ABA and ABA sensitivity decline during maturation. The concentrations of exogenous ABA required to suppress germination at these later stages result in abnormally high levels of endogenous ABA and appear to be toxic. These results are consistent with the hypothesis that in maturing rapeseeds, low water content rather than ABA prevents germination during the later stages of development.     

Effects of jasmonic Acid on embryo-specific processes in brassica and linum oilseeds

A number of effects on embryogenesis of the putative phytohormone jasmonic acid (JA), and its methyl ester (MeJA), were investigated in two oilseed plants, repeseed (Brassica napus) and flax (Linum usitatissimum). Results from treatments with JA and MeJA were compared with those of a known effector of several aspects of embryogenesis, abscisic acid (ABA). Jasmonic acid was identified by gas chromatography-mass spectrometry as a naturally occurring substance in both plant species during embryo development. Both JA and MeJA can prevent precocious germination of B. napus microspore embryos and of cultured zygotic embryos of both species at an exogenous concentration of >1 micromolar. This dose-response was comparable with results obtained with ABA. Inhibitory effects were also observed on seed germination with all three growth regulators in rapeseed and flax. A number of molecular aspects of embryogenesis were also investigated. Expression of the B. napus storage protein genes (napin and cruciferin) was induced in both microspore embryos and zygotic embryos by the addition of 10 micromolar JA. The level of napin and cruciferin mRNA detected was similar to that observed when 10 micromolar ABA was applied to these embryos. For MeJA only slight increases in napin or cruciferin mRNA were observed at concentrations of 30 micromolar. Several oilbody-associated proteins were found to accumulate when the embryos were incubated with either JA or ABA in both species. The MeJA had little effect on oilbody protein synthesis. The implications of JA acting as a natural regulator of gene expression in zygotic embryogenesis are discussed.     

An Analysis of Seed Development in Pisum sativum: VIII. DOES ABSCISIC ACID PREVENT PRECOCIOUS GERMINATION AND CONTROL STORAGE PROTEIN SYNTHESIS?

The influence of abscisic acid (ABA) on the precocious germinationand storage protein production of pea seeds has been examinedusing embryo and pod culture. The precocious germination ofembryos in culture could not be inhibited fully by ABA on apermissive medium (2% sucrose) even at 0.1 mol m^–3. However,increasing the sucrose concentration to 5% caused near completeinhibition when ABA was added to the medium. Embryos of differentweights cultured on a high osmoticum (mannitol-containing medium),equivalent to 10% sucrose, did not show any consistent differencein ABA content. When fluridone was added to a non-permissiveculture medium, no decrease in ABA content of the embryos couldbe observed and no precocious germination was induced. In contrast,fluridone was able to prevent the accumulation of ABA in seedspresent in pods cultured in its presence from an early stageof development. These seeds, however, grew normally and reachedmaturity, did not germinate precociously in vivo, were desiccationtolerant and still produced storage protein message whetheror not ABA was included in the culture medium. It does not appear,therefore, that ABA regulates normal development or storageprotein synthesis in pea embryos. Key words: Abscisic acid, peas, Pisum sativum, seed development     

Accumulation of Group 3 Late Embryogenesis Abundant Proteins in Zea mays Embryos : Roles of Abscisic Acid and the Viviparous-1 Gene Product

Several different types of proteins that are modulated by abscisic acid (ABA) accumulate in developing embryos of maize (Zea mays L.). Some of these proteins are specific to the developing seed, such as the storage globulin, GLB1, whereas others are involved in general responses to water deficit. Here we describe a maize protein family of this second type, a Group 3 late embryogenesis abundant (MLG3). Like other proteins of this class, MLG3 polypeptides are ABA-responsive. They are found in maturing seeds and in dehydrating plant tissues. Antigenically related proteins are found in other cereals. To distinguish the regulation of developmentally programmed ABA responses from those that are environmentally induced, we compared the ontological pattern and accumulation requirements of MLG3 polypeptides with those we previously described for GLB1. GLB1 accumulation begins early in the maturation phase and specifically requires high levels of ABA and the participation of the Viviparous-1 (Vp1) gene product. Vp1 is required for other ABA-modulated events in maize seed development as well. In experiments using vp1 mutants and mutants deficient in ABA synthesis (vp5 mutation), we show that MLG3 accumulation also is dependent upon ABA, but it shows striking differences from GLB1. MLG3 accumulates much later in embryogenesis, coincident with the onset of dehydration. In contrast to GLB1, MLG3 proteins can be induced by de novo ABA synthesis in response to culturing in high osmoticum. Unlike GLB1, MLG3 has no specific requirement for the Vp1 gene product.     

Characterization of embryo globulins encoded by the maizeGlb genes

Two of the most abundant proteins in maize embryos are saline-soluble, water-insoluble globulins. One is aM _r 63,000 protein encoded by theGlbl gene and the other is aM _r 45,000 component encoded by theGlb2 gene. Both proteins accumulate to high levels during embryo development and are rapidly degraded during the early stages of seed germination. Amino acid composition analysis indicates that these proteins may serve as storage reserves to provide sources of nitrogen and carbon to the germinating embryo. Amino-terminal sequence analysis of the finalGlb1 gene product, GLB1, and its immediate precursor, GLB1′, indicates that the latter is proteolytically cleaved near the amino terminus to form GLB1. In addition to these biochemical studies, we describe the identification of a novel maize variant which lacks the protein product of theGlb2 gene. This contribution from the University of Illinois Agricultural Experiment Station was supported by grants from The Standard Oil Corporation, a wholly owned subsidiary of BP America, Inc., and the U.S. Department of Agriculture (No. 88-37262-3427).     

Three Classes of Abscisic Acid (ABA)-Insensitive Mutations of Arabidopsis Define Genes that Control Overlapping Subsets of ABA Responses

Wild type and three abscisic acid (ABA)-insensitive mutants of Arabidopsis (ABI1, ABI2, and ABI3) were compared for their ability to respond to ABA for a variety of ABA-inducible responses throughout the life cycle of the plants. The responses tested included effects on seedling growth, proline accumulation in seedlings, ABA-regulated protein synthesis in plantlets, and seed storage protein and lipid synthesis and accumulation. The abi1 and abi2 mutants showed reduced sensitivity to ABA for inhibition of seedling growth, induction of proline accumulation, and alterations in protein synthesis patterns during vegetative growth, but had wild type levels of storage reserves. In contrast, the abi3 mutant had wild type sensitivity for induction of proline accumulation and was only slightly less responsive to ABA with respect to effects on seedling growth and changes in patterns of protein synthesis. The major effects of this mutation were on seed development. Seeds of the abi3 mutant had two-thirds of the wild type level of storage protein and one-third the wild type level of eicosenoic acid, the major fatty acid component of storage lipids in wild type seeds. These results show that none of the abi mutants is insensitive for all ABA-inducible responses and that the abi3 effects are not seed-specific. Comparison of the degree of ABA sensitivity of monogenic mutant lines with that of digenic mutant lines carrying pairwise combinations of the abi mutations suggests that ABA responses in mature seeds are controlled by at least two parallel pathways.     

Modulation by abscisic acid of storage protein accumulation in Vicia Faba L. cotyledons cultured in vitro

The effects of abscisic acid (ABA), high osmotica, fluridone (an inhibitor of carotenoid biosynthesis), gibberellic acid (GA₃) and an inhibitor of gibberellin biosynthesis, paclobutrazol (1-(4-chlorophenyl)-4,4-dimethyl-2-(1-24-triazol-1-yl)pentan-3-ol) on storage protein accumulation were studied in developing Vicia faba L. cotyledons cultured for 2 or 3 days in vitro. Extracts of these cotyledons were separated by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) under reducing conditions. ABA stimulated the accumulation of vicilin and legumin polypeptides. GA₃ did not noticeably stimulate the accumulation of any polypeptide. There was stimulation of vicilin and legumin polypeptide accumulation by high osmoticum (18% sucrose), which was further enhacedd by ABA and inhibited by fluridone. The fluridone inhibition was reversed by ABA addition.The data provides evidence that ABA modulates the synthesis of V. faba storage proteins.     

Gibberellins and seed development in maize. II. Gibberellin synthesis inhibition enhances abscisic acid signaling in cultured embryos

Abscisic acid (ABA) is required for seed maturation in maize (Zea mays L.) and other plants. Gibberellins (GAs) are also present in developing maize embryos, and mutual antagonism of GAs and ABA appears to govern the choice between precocious germination or quiescence and maturation. Exogenous ABA can also induce quiescence and maturation in immature maize embryos in culture. To examine the role of GAs versus ABA in regulating maize embryo maturation, the effects of modulating GA levels were compared with those of ABA in embryos cultured at successive stages of development. The effects of GA synthesis inhibition or exogenous GA application differed markedly in embryos at different stages of development, indicating changes in both endogenous GA levels and in the capacity for GA synthesis as embryogenesis and maturation progress. In immature embryos, the inhibition of GA synthesis mimicked the effects of exogenous ABA, as shown by the suppression of germination, the acquisition of anthocyanin pigments, and the accumulation of a variety of maturation-phase mRNAs. We suggest that GA antagonizes ABA signaling in developing maize embryos, and that the changing hormone balance provides temporal control over the maturation phase.     

花生胚离体发育及渗调物质的影响

在无外源激素培养基上花生胚能继续发育．渗调物质如甘露醇可抑制胚早萌,维持胚性发育,促进贮藏蛋白质合成和累积．渗调物质对胚离体发育的调控与其提高胚内源ＡＢＡ含量有关．     

mRNAs for two ribosomal proteins are preferentially translated in the chloroplast of Chlamydomonas reinhardtii under conditions of reduced protein synthesis

Previous studies have identified a set of highly phosphorylated proteins of 23–25 kDa accumulated during normal embryogenesis of Zea mays L. and which disappear in early germination. They can be induced precociously in embryos by abscisic acid (ABA) treatment. Here the synthesis and accumulation of this group of proteins and their corresponding mRNAs were examined in ABA-deficient viviparous embryos at different developmental stages whether treated or not with ABA, and in water-stressed leaves of both wild-type and viviparous mutants.During embryogenesis and precocious germination of viviparous embryos the pattern of expression of the 23–25 kDa proteins and mRNAs closely resembles that found in non-mutant embryo development. They are also induced in young viviparous embryos by ABA treatment. In contrast, leaves of ABA-deficient mutants fail to accumulate mRNA in water stress, yet do respond to applied ABA. In water-stressed leaves of wild type plants the mRNAs are induced and translated into 4 proteins with a molecular weight and isoelectric point identical to those found in embryos.These results indicate that the 23–25 kDa protein set is a new member of the recently described class or proteins involved in generalized plant ABA responses.The different pattern of expression for the ABA-regulated 23–25 kDa proteins and mRNAs found in embryo and in vegetative tissues of viviparous mutants is discussed.     

Abscisic acid inhibits germination of mature Arabidopsis seeds by limiting the availability of energy and nutrients

The addition of abscisic acid (ABA) to mature non-dormant seeds inhibits their germination. This effect of ABA might be related to its natural function as an endogenous inhibitor of precocious germination during seed formation. In this work, we studied how ABA affects the germination of mature seeds and the growth of nascent seedlings of Arabidopsisthaliana (L.) Heynh. Our findings were as follows: (i) inhibition by ABA was gradual, dose-dependent, and did not disappear after germination; (ii) inhibition of germination was relieved by the addition of metabolizable sugars or amino acids to the plating media; (iii) the effect of sugars and amino acids was cooperative, indicating that these two groups of metabolites relieve different deficiencies; (iv) ABA caused appreciable alterations in energy and nitrogen metabolism; and (v) ABA prevented the degradation of the seed storage proteins. In summary, ABA appears to inhibit seed germination by restricting the availability of energy and metabolites. This mechanism seems consistent with other known effects of ABA. Received: 3 February 1997 / Accepted: 10 March 1997     

Rapeseed embryo development in culture on high osmoticum is similar to that in seeds

The development of Brassica napus L. cv Tower embryos of different ages cultured in vitro with and without high osmoticum (0.48 and 0.69 molar sorbitol) was compared with normal development in situ to investigate the role of a drying environment in embryo maturation. Sensitivity to osmoticum was assayed in terms of its ability to mimic normal development, i.e. to both suppress germination and maintain 12 S storage protein (cruciferin) synthesis at levels comparable to those seen in the developing seed. The osmotic conditions used block germination of predesiccation stage embryos but were not sufficient to prevent desiccation stage embryos from taking up water and germinating. At all stages tested, the osmotically treated embryos had approximately normal levels of cruciferin mRNA. Measurements of endogenous abscisic acid (ABA) levels by radioimmunoassay indicated that the osmotic effects on germination and gene expression were not mediated by elevated embryonic ABA. Comparison of the kinetics of osmotic and ABA effects on gene expression showed that the osmotic effect is more rapid. These results are consistent with the hypothesis that ABA acts by inhibiting water uptake, which mechanically prevents germination and affects gene expression in some unknown manner.     

Globulin-1 gene expression in regenerable<Emphasis Type="Italic"> Zea mays</Emphasis> (maize) callus

Since maize callus cultures regenerate plants via somatic embryogenesis, one might expect to find similar proteins in both zygotic embryos and tissue cultures. The 63-kD globulin protein designated GLB1, the expression of which is regulated by abscisic acid (ABA), is one such protein. When maize Type I regenerable callus was exposed for 24 h to 0.1 m M ABA or a water stress induced by 0.53 M mannitol, GLB1 was produced as determined by Western analysis. This protein was not detected in ABA or mannitol-treated regenerable cultured tissue of a null genotype or in tissues not exposed to ABA or water stress. Exposure to ABA in the culture medium increased the callus ABA levels greatly but a mannitol-induced water stress had only a small effect on ABA levels. Regenerable callus exposed to 0.1 m M ABA also produced mRNA that hybridized on a Northern blot with a globulin- 1 gene ( Glb1) probe. When both Type I and Type II regenerable cultured tissues were exposed to regeneration medium without ABA or mannitol, several GLB1 antibody immunoreactive proteins were produced. These proteins were not detected in regenerated plants nor in non-regenerable callus treated with ABA. These results suggest that: (1) at least for expression of Glb1, somatic embryogenesis is similar to zygotic embryogenesis, (2) there may be a regulatory role for auxin in the processing of Glb1-encoded polypeptides since fewer are seen when dicamba is present in the medium, (3) ABA has a role in somatic embryogenesis, and (4) regenerability of a maize callus culture may be assessed by treating the cultured tissue with 0.1 m M ABA to determine if GLB1 proteins are induced.     

Precociously germinating somatic embryos of Vitis vinifera have lower ABA and IAA levels than their germinating zygotic counterparts

Somatic embryos of Vitis vinifera (cv. Grenache noir) develop normally up to the torpedo stage, but they germinate precociously and form viable plantlets with very low frequency. Because a peak in abscisic acid (ABA) in mid‐embryogenesis could be one factor preventing precocious germination during normal seed development, we followed the development of ABA content concurrent with that of the somatic embryos. Additionally, we measured changes in indoleacetic acid (IAA) levels. We also compared the levels of both hormones during precocious germination of somatic embryos and during normal germination of their zygotic counterparts. Somatic embryos were able to accumulate ABA and IAA throughout their development but no peak in ABA concentration was detected during embryogenesis. This suggests that the switch from mid‐ to late‐embryogenesis is not triggered. Furthermore, during precocious germination, i.e. from the torpedo stage onwards, the concentrations of ABA and IAA in somatic embryos were much lower than during normal germination of zygotic embryos. Thus, it is likely that when precocious germination occurs, grape somatic embryos do not accumulate ABA and/or IAA in sufficient concentrations to support normal plantlet development. Therefore, for grape somatic embryos we propose that prevention of precocious germination, i.e. triggering late‐embryogenesis, is attainable by an ABA treatment followed by slow desiccation, as already shown for conifer somatic embryos. Our results also suggest that the role of ABA and IAA for improving normal germination after imposed quiescence should be investigated.     

Development and storage-protein synthesis in Brassica napus L. embryos in vivo and in vitro

Immature embryos of Brassica napus were cultured in vitro with and without various concentrations of germination inhibitors, and the progress of embryogeny was monitored by comparing accumulation of storage proteins in culture with the normal accumulation in seeds. The two major B. napus storage proteins (12S and 1.7S) were purified from seed extracts and analyzed by rocket immunoelectrophoresis (12S protein) or by sodium lauryl sulfate polyacrylamide gel electrophoresis (1.7S protein). During embryo development within seeds both the 12S and 1.7S proteins were first detected when the cotyledons were well developed (embryo dry weight, 0.4 mg), and each storage protein accumulated at an average rate of 26 g d^-1 during maximum deposition. Accumulation of the 1.7S protein stopped when the water content of the embryo began to decline (embryo DW, 2.7 mg), but accumulation of the 12S protein continued until seed maturity (embryo DW, 3.6 mg). At the end of embryo development the 12S and the 1.7S proteins comprised approx. 60 and 20% of the total salt-soluble protein, respectively. When embryos were removed from seeds at day 27, just as storage protein was starting to accumulate, and placed in culture on a basal medium, they precociously germinated within 3d, and incorporation of amino acids into the 12S storage protein dropped from 3% of total incorporation to less than 1%. If 10^-6 M abscisic acid (ABA) was included in the medium, amino-acid incorporation into the 12S protein increased from 3% of total incorporation when embryos were placed into culture to 18%, 5d later, and the accumulation rate (27.1±2.6 g embryo^-1 d^-1) matched the maximum rate observed in the seed. High osmotica, such as 0.29 M sucrose or mannitol, added to the basal medium, also inhibited precocious germination, but there was a lag period before 12S-protein synthesis rates equaled the rates on ABA media. These results indicate that some factor in the seed environment is necessary for storage-protein synthesis to proceed, and that ABA is a possible candidate.Abbreviations ABA abscisic acid - PAGE polyacrylamide gel electrophoresis - PMSF phenylmethylsulfonylfluoride - SDS sodium lauryl sulfate     

Developmental Biochemistry of Cottonseed Embryogenesis and Germination: VIII. Free Amino Acid Pool Composition during Cotyledon Development

The composition of the free amino acid pool in embryonic cotton (Gossypium hirsutum) cotyledons is quite distinct from that of endosperm, and that of germinated, greened cotyledons is quite distinct from that of leaves. During germination (including the precocious germination of immature seeds), the pool expands considerably showing a pronounced accumulation of asparagine. The high level of asparagine found in seedling roots and in the cotyledon vascular exudate indicates that this is the major transported amino acid in germination. There is no pool expansion in the presence of abscisic acid. In the presence of actinomycin D, the pool expands, but an enormous accumulation of glutamine takes place. The composition of the pool at any stage is not related to the composition of the isoacceptor transfer RNA pool, nor to the composition of the storage protein. Anaerobiosis leads to an accumulation of aspartate, alanine, and glycine at the expense of asparagine; however, desiccation does not result in an accumulation of proline. Conspicuously high levels of arginine are maintained through embryogenesis and germination. The levels of individual amino acids are presented as nanomol per cotyledon pair and as per cent of total pool.