Regulation of the synthesis of barley aleurone alpha-amylase by gibberellic Acid and calcium ions

The effects of gibberellic acid (GA₃) and calcium ions on the production of α-amylase and acid phosphatase by isolated aleurone layers of barley (Hordeum vulgare L. cv Himalaya) were studied. Aleurone layers not previously exposed to GA₃ or Ca²⁺ show qualitative and quantitative changes in hydrolase production following incubation in either GA₃ or Ca²⁺ or both. Incubation in H₂O or Ca²⁺ results in the production of low levels of α-amylase or acid phosphatase. The addition of GA₃ to the incubation medium causes a 10- to 20-fold increase in the amounts of these enzymes released from the tissue, and addition of Ca²⁺ at 10 millimolar causes a further 8- to 9-fold increase in α-amylase release and a 75% increase in phosphatase release. Production of α-amylase isoenzymes is also modified by the levels of GA₃ and Ca²⁺ in the incubation medium. α-Amylase 2 is produced under all conditions of incubation, while α-amylase 1 appears only when layers are incubated in GA₃ or GA₃ plus Ca²⁺. The synthesis of α-amylases 3 and 4 requires the presence of both GA₃ and Ca²⁺ in the incubation medium. Laurell rocket immuno-electrophoresis shows that two distinct groups of α-amylase antigens are present in incubation media of aleurone layers incubated with both GA₃ and Ca²⁺, while only one group of antigens is found in media of layers incubated in GA₃ alone. Strontium ions can be substituted for Ca²⁺ in increasing hydrolase production, although higher concentrations of Sr²⁺ are required for maximal response. We conclude that GA₃ is required for the production of α-amylase 1 and that both GA₃ and either Ca²⁺ or Sr²⁺ are required for the production of isoenzymes 3 and 4 of barley aleurone α-amylase.     

Control of alpha-amylase mRNA accumulation by gibberellic Acid and calcium in barley aleurone layers

Pulse-labeling of barley (Hordeum vulgare L. cv Himalaya) aleurone layers incubated for 13 hours in 2.5 micromolar gibberellic acid (GA₃) with or without 5 millimolar CaCl₂ shows that α-amylase isozymes 3 and 4 are not synthesized in vivo in the absence of Ca²⁺. A cDNA clone for α-amylase was isolated and used to measure α-amylase mRNA levels in aleurone layers incubated in the presence and absence of Ca²⁺. No difference was observed in α-amylase mRNA levels between layers incubated for 12 hours in 2.5 micromolar GA₃ with 5 millimolar CaCl₂ and layers incubated in GA₃ alone. RNA isolated from layers incubated for 12 hours in GA₃ with and without Ca²⁺ was translated in vitro and was found to produce the same complement of translation products regardless of the presence of Ca²⁺ in the incubation medium. Immunoprecipitation of translation products showed that the RNA for α-amylase synthesized in Ca²⁺-deprived aleurone layers was translatable. Ca²⁺ is required for the synthesis of α-amylase isozymes 3 and 4 at a step after mRNA accumulation and processing.     

Embryoless Wheat Grain: A Natural System for the Study of Gibberellin-induced Enzyme Formation

Yorkstar wheat, grown in New York State, has a high percentage (10-11) of grains without embryos. The embryoless grains have viable aleurone layers and show no sign of injury. These grains are able to support α-amylase synthesis only in the presence of gibberellin A₃ (GA₃). In the absence of GA₃ some protein synthesis occurs in embryoless grains during the early hours of soaking, indicating that such activity occurs prior to and independent of GA₃ induction of α-amylase. The level of β-amylase on a dry weight basis is the same in embryoless and normal grains and decreases with time of soaking. In the presence of GA₃, β-amylase decreases at a slower rate. Isoenzymes of α-amylase from GA₃-treated embryoless and normal grains show quantitative as well as qualitative differences. Cycloheximide (60 μg/ml) completely inhibits the synthesis of α-amylase by embryoless grains. Of the RNA synthesis inhibitors, actinomycin D (60 μg/ml) was ineffective while 6-methylpurine (60 μg/ml) gave 65% inhibition without decreasing the number of isoenzymes.     

Screening for barley mutants with altered hormone sensitivity in their aleurone layers

A method, based on the diffusion assay of α-amylase on agar plates, was developed to screen for barley (Himalaya) mutants with altered sensitivity to gibberellic acid (GA₃) or abscisic acid (ABA) in their aleurone layers. The seeds produced by sodium azide-mutagenized barley were screened for their ability to synthesize and secrete α-amylase when treated with different combinations of hormones. Various GA₃-insensitive or supersensitive, ABA-insensitive, temperature-dependent GA₃-insensitive, and constitutive mutants have been identified. Several stable mutants with altered GA₃ sensitivity were recovered. Two of the homozygous GA₃-insensitive mutants have been preliminarily characterized. The GA₃-enhanced production of α-amylase and release of phosphatase are hampered in these mutants. However, they have normal stem height, and the uptake of GA₃ by their aleurone layers appears to be the same as that of wild-type barley. They are most likely regulatory mutants affecting both α-amylase synthesis and phosphatase release.     

Ca-stimulated secretion of alpha-amylase during development in barley aleurone protoplasts

The effects of gibberellic acid (GA₃) and Ca²⁺ on the synthesis and secretion of α-amylase from protoplasts of barley (Hordeum vulgare L. cv Himalaya) aleurone were studied. Protoplasts undergo dramatic morphological changes whether or not the incubation medium contains GA₃, CaCl₂, or both. Incubation of protoplasts in medium containing both GA₃ and Ca²⁺, however, causes an increase in the α-amylase activity of both incubation medium and tissue extract relative to controls incubated in GA₃ or Ca²⁺ alone. Isoelectric focusing shows that adding Ca²⁺ to incubation media containing GA₃ increases the levels of α-amylase isozymes having high isoelectric points (pI). In the presence of GA₃ alone, only isozymes with low pIs accumulate. The increase in α-amylase activity in the incubation medium begins after 36 hours of incubation, and secretion is complete after about 72 hours. Protoplasts require continuous exposure to Ca²⁺ to maintain elevated levels of α-amylase release. Immunoelectrophoresis shows that Ca²⁺ stimulates the release of low-pI α-amylase isozymes by 3-fold and high-pI isozymes by 30-fold over controls incubated in GA₃ alone. Immunochemical data also show that the half-maximum concentration for this response is between 5 and 10 millimolar CaCl₂. The response is not specific for Ca²⁺ since Sr²⁺ can substitute, although less effectively than Ca²⁺. Pulse-labeling experiments show that α-amylase isozymes produced by aleurone protoplasts in response to GA₃ and Ca²⁺ are newly synthesized. The effects of Ca²⁺ on the process of enzyme synthesis and secretion is not mediated via an effect of this ion on α-amylase stability or on protoplast viability. We conclude that Ca²⁺ directly affects the process of enzyme synthesis and transport. Experiments with protoplasts also argue against the direct involvement of the cell wall in Ca²⁺-stimulated enzyme release.     

Effect of Ethylene on the Release of alpha-Amylase through Cell Walls of Barley Aleurone Layers

A large portion of the gibberellic acid (GA₃)-induced α-amylase in isolated aleurone layers is transported into the incubation medium. In the presence of GA₃ and ethylene, an even larger portion of the enzyme is found in the medium. Employing an acid washing technique developed by Varner and Mense (Plant Physiol 1972 49:187-189), it was observed that ethylene significantly reduces the amount of α-amylase trapped by the thick cell walls of aleurone layers. However, the amount of enzyme remaining in the cell (within the boundary of plasma membrane) is not affected by ethylene. Ethylene has no observable effect on membrane formation as measured by the incorporation of [³²P]orthophosphate into phospholipids. Because of these observations it is suggested that ethylene enhances the release of α-amylase, i.e. transport of α-amylase across cell walls, but not the secretion of α-amylase, i.e. transport of α-amylase past the barrier of plasma membrane. The possible mechanism of this ethylene effect is discussed.     

Dormancy of the barley grain is correlated with gibberellic Acid responsiveness of the isolated aleurone layer

The relationship between barley grain dormancy and gibberellic acid (GA₃) responsiveness of aleurone layers has been investigated. Barley (Hordeum distichum L. cvs Triumph and Kristina) grains were matured under defined conditions in a phytotron. Grains of Triumph plants grown under long-day/warm conditions had lower dormancy levels than grains of plants grown under short-day/cool conditions. Aleurone layers isolated from grains of long-day Triumph plants secreted more α-amylase and had a higher responsiveness to GA₃ as measured by α-amylase secretion. Storage of the grains increased both the percentage of germination and the responsiveness of the aleurone to GA₃. Use of different sterilization methods to break dormancy confirmed the correlation between germination percentage and aleurone layer GA₃ responsiveness. The response of embryoless Triumph grains to GA₃ was lower than that of the isolated aleurone layers, suggesting a role of the starchy endosperm in regulating the GA₃ response of the aleurone layer. Grains of the cultivar Kristina harvested from short day- and long day-grown plants lacked dormancy, and their isolated aleurone layers had a similar responsiveness to GA₃ as measured by α-amylase secretion. The data indicate that the physiological state of the aleurone layers contributes to the percentage germination of the grains.     

Polyamine metabolism and its relation to response of the aleurone layers of barley seeds to gibberellic Acid

Polyamine metabolism and its relation to the induction of α-amylase formation in the aleurone layers of barley seeds (Hordeum vulgare cv Himalaya) in response to gibberellic acid (GA₃) has been investigated. A high-performance liquid chromatographic system has been employed for qualitative and quantitative analyses of putrescine (Put), cadaverine (Cad), spermidine (Spd), spermine (Spm), and agmatine (Agm).

Active polyamine metabolism occurs in the aleurone cells of deembryonate barley half seeds during imbibition. The aleurone layers isolated from fully imbibed half seeds contain about 880 nanomoles of Put, 920 nanomoles of Spd, and 610 nanomoles of Spm as free form per gram tissue dry weight while the levels of Cad and Agm are relatively low. The polyamine levels do not change significantly in the aleurone layers in response to added GA₃ (1.5 micromolar) during the 8-hour lag period of the growth substance-induced formation of α-amylase. Also, the polyamine levels are not altered by the presence of abscisic acid (3 micromolar) which inhibits the enzyme induction by GA₃. Kinetic studies show that both applied [U-¹⁴C]ornithine and [U-¹⁴C]arginine are primarily incorporated into Put during 2 hours of incubation, but the incorporation is not significantly affected by added GA₃. Additionally, added GA₃ does not affect the uptake and turnover of [1,4-¹⁴C]Put, nor does it affect the conversion of Put → Spd or Spd → Spm. Treatment of the aleurone layers with GA₃ for 2 hours results in no significant changes in the total activities or the specific activities of ornithine decarboxylase and arginine decarboxylase.

Experiments with polyamine synthesis inhibitors demonstrate that the level of Spd in the aleurone layers could be substantially reduced by the presence of methylglyoxal-bis(guanylhydrazone) (MGBG) during imbibition. MGBG treatment does not affect in vivo incorporation of [8-¹⁴C] adenosine into ATP. The lower the level of Spd the less α-amylase formation is induced by added GA₃. The reduction of GA₃-induced α-amylase formation by MGBG treatment can be either completely or partially overcome by added Spd, depending upon the concentration of MGBG used in the imbibition medium. The results indicate that the early action of GA₃, with respect to induction of α-amylase formation in barley aleurone layers, appears to be not on polyamine metabolism. However, polyamines, particularly Spd, may be involved in regulation of the growth substance-dependent enzyme induction.

     

Endogenous Gibberellins from Sporophytes of Two Tree Ferns, Cibotium glaucum and Dicksonia antarctica

Gibberellin A₁ (GA₁), 3-epi-GA₁, GA₄, GA₉, 11α-hydroxyGA₁₂, 12α-hydroxyGA₁₂, GA₁₅, GA₁₇, GA₁₉, GA₂₀, GA₂₅, GA₃₇, GA₄₀, GA₅₈, GA₆₉, GA₇₀, and GA₇₁ have been identified from Kovats retention indices and full scan mass spectra by capillary GC-MS analyses of purified extracts from sporophytes of the tree fern, Cibotium glaucum. Abscisic acid, dihydrophaseic acid, an epimer of 4′-dihydrophaseic acid, and the epimeric ent-6α, 7α, 16α, 17-(OH)₄ and ent-6α, 7α, 16β, 17-(OH)₄ derivatives of ent16, 17-dihydrokaurenoic acid, in addition to the epimeric 16α, 17- and 16β, 17-dihydroxy-16, 17-dihydro derivatives of GA₁₂, were also identified in extracts of C. glaucum. An oxodihydrophaseic acid and a hydroxydihydrophaseic acid were also detected. In extracts of sporophytes of Dicksonia antarctica, GA₄, GA₉, 12α- and 12β-hydroxyGA₁₂, GA₁₅, GA₂₅, and GA₃₇ were identified by the same criteria, as well as abscisic acid, phaseic acid, 8′-hydroxymethylabscisic acid and dihydrophaseic acid. This is the first time that GA₄₀ has been identified in a higher plant; it is also the first report of the natural occurrence of the two gibberellins, 11α- and 12β-hydroxyGA₁₂. The total gibberellin (GA) content in C. glaucum (tall) was at least one order of magnitude greater than that of D. antarctica (dwarf) based on total ion current response in GC-MS and bioassay data. Abscisic acid was a major component of D. antarctica and the oxodihydrophaseic acid was a major component of C. glaucum.     

The Effect of Ultracentrifugation on Fine Structure and α-Amylase Production in Barley Aleurone Cells

Ultracentrifugation of barley aleurone cells results in the stratification of organelles thus allowing for a quantitation of those organelles. Gibberellic acid (GA₃)-stimulated α-amylase production in stratified cells is reduced by centrifugation at gravitational forces greater than 40,000g. Forces below 30,000g do not affect GA₃-stimulated α-amylase production although stratification of organelles occurs at these forces. The ability of centrifuged cells to respond maximally to GA₃ by producing α-amylase is related to the degree of redistribution of organelles within these cells. Thus, recovery of cells from centrifugation at forces below 30,000g is rapid, while recovery from forces above 40,000g is slow.     

Characterization of the alpha-Amylases Synthesized by Aleurone Layers of Himalaya Barley in Response to Gibberellic Acid

The gibberellic acid (GA₃)-induced α-amylases from the aleurone layers of Himalaya barley (Hordeum vulgare L. cv Himalaya) have been purified by cycloheptaamylose-Sepharose affinity chromatography and fractionated by DEAE-cellulose chromatography. Four fractions (α-amylases 1-4) were obtained which fell into two groups (A and B) on the basis of a number of characteristics. Major differences in serological characteristics and in proteolytic fingerprints were found between group A (α-amylases 1 and 2) and group B (α-amylases 3 and 4). Also, the lag time for appearance of group B enzyme activity was longer than for group A, and the appearance of group B required higher GA₃ levels than group A. The components of each group behaved similarly, although differences in proteolytic fingerprints were detected.

These results together with those from other studies indicate that GA₃ differentially controls the expression of two α-amylase genes or groups of genes giving rise to two groups of α-amylases with many different properties.

     

Alpha-amylase synthesis in wheat kernels as influenced by the seed coat

The effect of seed coat removal on the synthesis of α-amylase isoenzymes in wheat was investigated. The immature wheat endosperm-aleurone (seed coat and embryo detached) produced considerably less α-amylase activity than immature whole or de-embryonated wheat kernels, when incubated under identical conditions of 18.5 C and 99% humidity, in the presence or absence of gibberellic acid (GA₃). The incubated endosperm-aleurone also exhibited unique α-amylase isoenzyme composition when compared to the isoenzyme compositions of incubated whole and de-embryonated immature and mature wheat kernels both in the presence or absence of GA₃. Subsequent studies indicated that the seed coat may contain factor(s) required for normal α-amylase isoenzyme synthesis.     

No Effect of 5-Fluorouracil on the Properties of Purified alpha-Amylase from Barley Half-seeds

α-Amylase has been purified from de-embryonated seeds of barley (Hordeum vulgare L. cv. Betzes) which have been incubated on 10⁻⁶ m gibberellic acid (GA₃) following 3 days of imbibition in buffer. Incubation of the half-seeds in up to 10⁻² m 5-fluorouracil (5-FU) during the entire incubation period, including imbibition, had no effect on any of the following characteristics of purified α-amylase: thermal stability in the absence of calcium, molecular weight of the enzyme, isozyme composition, specific activity, or the amount of α-amylase synthesized by the aleurone tissue. The synthesis of rRNA and tRNA was strongly inhibited by 5-FU, indicating that the analog had entered the aleurone cells. These results are not in agreement with those of Carlson (Nature New Biology 237: 39-41 [1972]) who found that treatment of barley aleurone with 10⁻⁴ m 5-FU prior to the addition of GA₃ resulted in decreased thermal stability of GA₃-induced α-amylase and who interpreted this as evidence that the mRNA for α-amylase was synthesized during the imbibition of the aleurone tissue and independently of gibberellin action. Results of the present experiments indicate that the thermal stability of highly purified α-amylase is not altered by treatment of barley half-seeds with 5-FU, and that 5-FU cannot be used as a probe to examine the timing of α-amylase mRNA synthesis.     

Biosynthetic Origin of Gibberellins A(3) and A(7) in Cell-Free Preparations from Seeds of Marah macrocarpus and Malus domestica

Cell-free preparations from seeds of Marah macrocarpus L. and Malus domestica L. catalyzed the conversion of gibberellin A₉ (GA₉) and 2,3-dehydroGA₉ to GA₇; GA₉ was also metabolized to GA₄ in a branch pathway. The preparation from Marah seeds also metabolized GA₅ to GA₃ in high yield; GA₆ was a minor product and was not metabolized to GA₃. Using substrates stereospecifically labeled with deuterium, it was shown that the metabolism of GA₅ to GA₃ and of 2,3-dehydroGA₉ to GA₇ occurs with the loss of the 1β-hydrogen. In cultures of Gibberella fujikuroi, mutant B1-41a, [1β,2β-²H₂]GA₄, was metabolized to [1,2-²H₂]GA₃ with the loss of the 1α- and 2α-hydrogens. These results provide further evidence that the biosynthetic origin of GA₃ and GA₇ in higher plants is different from that in the fungus Gibberella fujikuroi.     

Identification of Ten Gibberellins from Sporophytes of the Tree fern, Cyathea australis

Ten gibberellins (GAs) have been identified by Kovats retention indices and full mass spectra from GC-MS analysis of purified extracts of sporophytes of the tree-fern, Cyathea australis. These include the known GA₁, GA₄, GA₉, GA₁₅, GA₂₄, GA₃₅, and GA₅₈ and three new GAs, 12β-hydroxyGA₉ (GA₆₉), 12α-hydroxyGA₉ (GA₇₀) and 12β-hydroxyGA₄ (GA₇₁). The structure of GA₇₁ was established by the preparation and characterization of its methyl ester (as a metabolite of GA₄ methyl ester in a culture of prothallia of Lygodium japonicum).     

Hormonal regulation of the development of protease and carboxypeptidase activities in barley aleurone layers

Carboxypeptidase and protease activities of hormone-treated barley (Hordeum vulgare cv Himalaya) aleurone layers were investigated using the substrates N-carbobenzoxy-Ala-Phe and hemoglobin. A differential effect of gibberellic acid (GA₃) on these activities was observed. The carboxypeptidase activity develops in the aleurone layers during imbibition without the addition of hormone, while the release of this enzyme to the incubation medium is enhanced by GA₃. In contrast, GA₃ is required for both the production of protease activity in the aleurone layer and its secretion. The time course for development of protease activity in response to GA₃ is similar to that observed for α-amylase. Treating aleurone layers with both GA₃ and abscisic acid prevents all the GA₃ effects described above. Carboxypeptidase activity is maximal between pH 5 and 6, and is inhibited by diisopropylfluorophosphate and p-hydroxymercuribenzoate. We have observed three protease activities against hemoglobin which differ in charge but are all 37 kilodaltons in size on sodium dodecyl sulfate polyacrylamide gels. The activity of the proteases can be inhibited by sulfhydryl protease inhibitors, such as bromate and leupeptin, yet is enhanced by 2-fold with 2-mercaptoethanol. In addition, these enzymes appear to be active against the wheat and barley storage proteins, gliadin and hordein, respectively. On the basis of these characteristics and the time course of GA₃ response, it is concluded that the proteases represent the GA₃-induced, de novo synthesized proteases that are mainly responsible for the degradation of endosperm storage proteins.     

Low Temperature-Induced GA(3) Sensitivity of Wheat : I. Characterization of the Low Temperature Effect on Isolated Aleurone OF KITE

Gibberellic acid (GA₃) sensitivity (measured as α-amylase production) of the isolated aleurone tissue/deembryonated seed of two wheat (Triticum aestivum L. var Kite and var Aroona) varieties each containing either one of the dwarfing genes, Rht1 and Rht2, was increased significantly as a result of low temperature treatment. The magnitude of the low temperature-induced increase occurred without any change in the lag time of α-amylase production. This low temperature induction of GA₃ sensitivity was found to be operative in aleurone tissue of only those varieties having at least one of the three Rht alleles. It is likely, therefore, that the low temperature treatment effect which `cures' or circumvents the genetic lesions manifest in the Rht1 and Rht2 genotypes is the same as that effective in the Rht3-containing genotype and probably involves an increase in hormone (GA₃) receptor sites. Furthermore, this increase appears to be a quantitative temporal one.