Amylases in developing barley seeds

The amylases of developing barley seeds (Hordeum vulgare L. cv. Himalaya) were investigated by colorimetric and electrophoretic methods. Maxima of amylolytic activity appeared in the aleurone layers and starchy endosperm at 5 and 20 days after anthesis. Amylase from 5-day-old aleurone layers could be separated into four rapidly moving bands with α-amylase activity. By 20 days the four bands had been replaced by seven bands of medium mobility. These seven bands of amylase were electrophoretically identical to those observed when mature aleurone layers are treated with gibberellic acid. Immature aleurone layers failed to respond to exogenous gibberellic acid. In the starchy endosperm the seven bands of medium mobility were also present. Calcium-dependent alterations in the electrophoretic mobility and activity of particular bands occurred during the maturation of the starchy endosperm. Treatment of the immature starchy endosperm with papain yielded four forms of β-amylase.     

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.     

Response of barley aleurone layers to abscisic Acid

Cordycepin, an inhibitor of RNA synthesis in barley (Hordeum vulgare L.) aleurone cells, does not inhibit the gibberellic acid-enhanced α-amylase (EC 3.2.1.1.) synthesis in barley aleurone layers if it is added 12 hours or more after the addition of the hormone. However, the accumulation of α-amylase activity after 12 hours of gibberellic acid can be decreased by abscisic acid. The accumulation of α-amylase activity is sustained or quickly restored when cordycepin is added simultaneously or some time after abscisic acid, indicating that the response of aleurone layers to abscisic acid depends on the continuous synthesis of a short lived RNA. By analysis of the newly synthesized proteins by gel electrophoresis with sodium dodecylsulfate, we observed that the synthesis of α-amylase is decreased in the presence of abscisic acid while the synthesis of most of the other proteins remains unchanged. From the rate of resumption of α-amylase production in the presence of cordycepin and abscisic acid, it appears that abscisic acid does not have a measurable effect on the stability of α-amylase mRNA.     

Hormonal control of polyribosome formation in barley aleurone layers

The addition of abscisic acid to barley (Hordeum vulgare L. cv. Himalaya) aleurone layers at the same time as gibberellic acid completely prevents the gibberellin-induced increases in the percentage of polysomes, the formation of polyribosomes, and the synthesis of α-amylase, even when the molar concentration of gibberellic acid is four times greater than the concentration of abscisic acid. The addition of abscisic acid to aleurone cells producing α-amylase (midcourse addition) inhibits the further synthesis of α-amylase and decreases the percentage of polysomes but does not change the number of ribosomes per cell.     

Substrate induction of nitrate reductase in barley aleurone layers

Nitrate induces the formation of nitrate reductase activity in barley (Hordeum vulgare L. cv. Himalaya) aleurone layers. Previous work has demonstrated de novo synthesis of α-amylase by gibberellic acid in the same tissue. The increase in nitrate reductase activity is inhibited by cycloheximide and 6-methylpurine, but not by actinomycin D. Nitrate does not induce α-amylase synthesis, and it has no effect on the gibberellic acid-induced synthesis of α-amylase. Also, there is little or no direct effect of gibberellic acid (during the first 6 hr of induction) or of abscisic acid on the nitrate-induced formation of nitrate reductase. Gibberellic acid does interfere with nitrate reductase activity during long-term experiments (greater than 6 hr). However, the time course of this inhibition suggests that the inhibition may be a secondary one. Barley aleurone layers therefore provide a convenient tissue for the study of both substrate- and hormone-induced enzyme formation.     

Gibberellic Acid-enhanced Release of beta-1,3-Glucanase from Barley Aleurone Cells

A β-1, 3-glucanase of barley (Hordeum vulgare) aleurone cells accumulates when half-seeds are imbibed on water, and accumulation continues when the aleurone layers are incubated in buffer solution. The release of the enzyme is a gibberellic acid-dependent process, however. Although gibberellic acid stimulates glucanase release, it does not markedly affect the total amount of glucanase obtained from these cells when compared with water controls. β-1, 3-Glucanase release from aleurone cells is a function of gibberellic acid concentration and commences after a 4-hour lag period. Processes occurring during this lag period are also dependent upon gibberellic acid concentration. Removal of gibberellic acid from the incubation medium at the end of the lag period, however, does not affect subsequent release of glucanase. The release of glucanase from aleurone cells is an active process with a Q₁₀ greater than 3. Inhibitors of respiration and protein and RNA synthesis effectively inhibit the formation and release of glucanase. It is concluded that gibberellic acid functions primarily to enhance glucanase release rather than its formation.     

Characteristics of the process of enzyme release from secretory plant cells

Secretion—the outward movement of molecules across the plasmalemma—of α-amylase by barley (Hordeum vulgare L. cv. Himalaya) aleurone layers is an energy-dependent process that is not directly dependent upon protein synthesis or RNA synthesis and does not appear to be under the direct control of gibberellic acid or abscisic acid. Release—the movement of the secreted α-amylase molecules through the walls into the surrounding medium—is apparently diffusion limited and is markedly dependent upon the presence of ions.     

A Correlation between a Ribonucleic Acid Fraction Selectively Labeled in the Presence of Gibberellic Acid and Amylase Synthesis in Barley Aleurone Layers

The effects of gibberellic acid on the incorporation of radio-active uridine and adenosine into RNA of barley aleurone layers were investigated using a double labeling method combined with acrylamide gel electrophoresis. After 16 hours of incubation, gibberellic acid stimulated the incorporation of label into all species of RNA, but the effects were very small (0-10%) for ribosomal and transfer RNA and comparatively large (up to 300%) for RNA sedimenting between 5S and 14S. This result was obtained for both isolated aleurone layers and for layers still attached to the endosperm. A similar but less marked pattern occurred in layers incubated for 8 hours, but the effect was not observed after 4 hours. The gibberellic acid-enhanced RNA labeling was not due to micro-organisms. The following evidence was obtained for an association between the gibberellic acid-enhanced RNA synthesis and α-amylase synthesis: (a) synthesis of α-amylase took place in parallel with incorporation of label into gibberellic acid-RNA; (b) actinomycin D inhibited amylase synthesis and gibberellic acid-RNA by similar percentages; (c) 5-fluorouracil halved incorporation of label into ribosomal RNA but had no effect on amylase synthesis and gibberellic acid-RNA; and (d) abscisic acid had little effect on synthesis of RNA in the absence of gibberellic acid, but when it was included with gibberellic acid the synthesis of both enzyme and gibberellic acid-RNA was eliminated. We conclude that large changes in the synthesis of the major RNA species are not necessary for α-amylase synthesis to occur but that α-amylase synthesis does not occur without the production of gibberrellic acid-RNA. Gibberellic acid-RNA is probably less than 1% of the total tissue RNA, is polydisperse on acrylamide gels, and could be messenger species for α-amylase and other hydrolytic enzymes whose synthesis is under gibberellic acid control.     

Heat Shock Inhibits alpha-Amylase Synthesis in Barley Aleurone without Inhibiting the Activity of Endoplasmic Reticulum Marker Enzymes

The effects of heat shock on the synthesis of α-amylase and on the membranes of the endoplasmic reticulum (ER) of barley (Hordeum vulgare) aleurone were studied. Heat shock, imposed by raising the temperature of incubation from 25°C to 40°C for 3 hours, inhibits the accumulation of α-amylase and other proteins in the incubation medium of barley aleurone layers treated with gibberellic acid and Ca²⁺. When ER is isolated from heat-shocked aleurone layers, less newly synthesized α-amylase is found associated with this membrane system. ER membranes, as indicated by the activities of NADH cytochrome c reductase and ATP-dependent Ca²⁺ transport, are not destroyed by heat stress, however. Although heat shock did not reduce the activity of ER membrane marker enzymes, it altered the buoyant density of these membranes. Whereas ER from control tissue showed a peak of marker enzyme activity at 27% to 28% sucrose (1.113-1.120 grams per cubic centimeter), ER from heat-shocked tissue peaked at 30% to 32% sucrose (1.127-1.137 grams per cubic centimeter). The synthesis of a group of proteins designated as heat-shock proteins (HSPs) was stimulated by heat shock. These HSPs were localized to different compartments of the aleurone cell. Several proteins ranging from 15 to 30 kilodaltons were found in the ER and the mitochondrial/plasma membrane fractions of heat-shocked cells, but none of the HSPs accumulated in the incubation medium of heat-shocked aleurone layers.     

Development of (1-->3,1-->4)-beta-d-Glucan Endohydrolase Isoenzymes in Isolated Scutella and Aleurone Layers of Barley (Hordeum vulgare)

An immunological assay has been used to investigate the synthesis of (1→3,1→4)-β-glucanase (EC 3.2.1.73) isoenzymes from isolated barley aleurone layers and scutella. Enzyme release from both tissues is enhanced by 1 micromolar gibberellic acid and 10 millimolar Ca²⁺, although increases induced by gibberellic acid are observed only in the presence of Ca²⁺. Isoenzyme I is synthesized predominantly in the scutellum, while isoenzyme II is synthesized exclusively in the aleurone. A third, putative isoenzyme III has been detected in significant proportions in scutellar secretions and may also be secreted from aleurone layers. Both gibberellic acid and Ca²⁺ appear to preferentially enhance isoenzyme II secretion from the aleurone and isoenzyme III secretion from scutella. The patterns of isoenzyme secretion are suggestive of tissue-specific differences in expression of the genes which code for (1→3,1→4)-β-glucanase isoenzymes. Qualitatively similar results were obtained with barley cultivars harvested in Australia and North America.     

Control of lactate dehydrogenase, lactate glycolysis, and alpha-amylase by o(2) deficit in barley aleurone layers

After 4 days in an atmosphere of N₂, aleurone layers of barley (Hordeum vulgare L. cv Himalaya) remained viable as judged by their ability to produce near normal amounts of α-amylases when incubated with gibberellic acid (GA₃) in air. However, layers did not produce α-amylase when GA₃ was supplied under N₂, apparently because α-amylase mRNA failed to accumulate.     

Alpha-amylase secretion by single barley aleurone layers

The secretion of α-amylase from single isolated (Hordeum vulgare L. cv Himalaya) aleurone layers was studied in an automated flow-through apparatus. The apparatus, consisting of a modified sample analyzer linked to a chart recorder, automatically samples the flow-through medium at 1 minute intervals and assays for the presence of α-amylase. The release of α-amylase from aleurone layers begins after 5 to 6 hours of exposure to gibberellic acid and reaches a maximum rate after 10 to 12 hours. The release of α-amylase shows a marked dependence on Ca²⁺, and in the absence of Ca²⁺ it is only 20% of that in the presence of 10 millimolar Ca²⁺. Withdrawal of Ca²⁺ from the flow-through medium results in the immediate cessation of enzyme release and addition of Ca²⁺ causes immediate resumption of the release process. The effect of Ca²⁺ is concentration-dependent, being half-maximal at 1 millimolar Ca²⁺ and saturated at 10 millimolar Ca²⁺. Ruthenium red, which blocks Ca²⁺ but not Mg²⁺ efflux from barley aleurone layers, renders α-amylase release insensitive to Ca²⁺ withdrawal. Inhibitors of respiratory metabolism cause a burst of α-amylase release which lasts for 0.5 to 5 hours. Following this phase of enhanced α-amylase release, the rate of release declines to zero. Pretreatment of aleurone layers with HCl prior to incubation in HCN also causes a burst of α-amylase release, indicating that the inhibitor is affecting the secretion of α-amylase and not its movement through the cell wall. The rapid inhibition of α-amylase release upon incubation of aleurone layers at low temperature (5°C) or in 0.5 molar mannitol also indicates that enzyme release is dependent on a metabolically linked process and is not diffusion-limited. This conclusion is supported by cytochemical observations which show that, although the cell wall matrix of aleurone layers undergoes extensive digestion after gibberellin treatment, the innermost part of the cell wall is not degraded and could influence enzyme release.     

Regulation of the accumulation of mRNA for alpha-amylase in barley aleurone

The effect of gibberellic acid and Ca²⁺ on the accumulation of α-amylase mRNAs in aleurone layers of barley (Hordeum vulgare L. cv Himalaya) was studied using cDNA clones containing sequences of mRNAs for the high and low isoelectric point (pI) α-amylases. There is no significant hybridization between the two α-amylase cDNA clones under the hybridization and washing conditions employed. These clones were therefore used to monitor levels of mRNAs for high and low pI α-amylases. It is shown that although the synthesis of the high pI α-amylase proteins depends on the presence of Ca²⁺ in the incubation medium, the accumulation of mRNA for this group occurs to the same degree in the presence or the absence of Ca²⁺. The accumulation of low pI α-amylase mRNA is also not affected by the presence or absence of Ca²⁺ in the incubation medium. These results establish gibberellic acid, not Ca²⁺, as the principal regulator of α-amylase mRNA accumulation in barley aleurone, while Ca²⁺ controls high pI α-amylase synthesis at a later step in the biosynthetic pathway.     

Multiple Forms of Amylase Induced by Gibberellic Acid in Isolated Barley Aleurone Layers

The addition of gibberellic acid to isolated aleurone layers of barley (Hordeum vulgare L.) causes the production and secretion of four α-amylases. Two of these are stable at pH 3.7 and are not inactivated by ethylenediaminetetraacetate. The other two represent the classical barley α-amylases; i.e., they are inactivated at pH 3.7 and by reagents which from complexes with divalent metal ions. All four forms are synthesized de novo in response to the addition of gibberellic acid.     

Inhibition of Gibberellic Acid-induced alpha-Amylase Formation by Polyethylene Glycol and Mannitol

Both polyethylene glycol (PEG) and mannitol inhibit gibberellic acid-induced α-amylase production in barley aleurone layers. The effect of the osmotic solution is on enzyme synthesis rather than α-amylase secretion. The inhibition of α-amylase synthesis does not appear to be mediated via an indirect effect on respiration or protein synthesis. Rather it seems that the osmotic solutions reduce the extent of proteolysis of the stored aleurone grain protein thus making available less substrate for new protein synthesis.     

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.     

alpha-Amylase Isoforms are Posttranslationally Modified in the Endomembrane System of the Barley Aleurone Layer

The subcellular site of the posttranslational modification of α-amylase was investigated in aleurone layers of barley (Hordeum vulgare L. cv Himalaya). Aleurone layers of Himalaya barley synthesize and secrete two groups of α-amylase isoforms, referred to as low-isoelectric point (low-pl) or HAMY1 and high-pl or HAMY2, when incubated in gibberellic acid and CaCl₂. Whereas homogenates of aleurone layers contain four isoforms of HAMY1 with pls 4.90, 4.72, 4.64, and 4.56, incubation media contain predominantly isoforms 4.72 and 4.56. Microsomal membranes isolated from aleurone layers contain all four isoforms of HAMY1. Microsomal membranes can be resolved into two peaks by isopycnic density gradient centrifugation: a peak of heavy membranes with endoplasmic reticulum and Golgi apparatus (GApp) marker enzyme activities and a peak of light membranes with characteristics of the GApp. The heavy membranes contain proportionally more HAMY1 pl 4.90 and 4.64 isoforms, whereas light membranes contain a higher proportion of pl 4.72 and 4.56 isoforms. Experiments with the ionophore monensin show that membranes of the GApp as well as the endoplasmic reticulum are involved in the posttranslational modification of HAMY1 isoforms. Monensin inhibits the secretion of α-amylase and causes the enzyme to accumulate within the cell. Precursor forms of HAMY1 accumulate in light membranes isolated from monensin-treated aleurone layers indicating that the GApp is involved in the conversion of the precursor to the secreted forms of the enzyme.     

Hypochlorite Disinfection Influences the GA(3)-Induced Synthesis of alpha-Amylase Isozymes by Isolated Barley Aleurone Layers

Aleurone layers isolated from half-seeds of Himalaya barley (Hordeum vulgare cv Himalaya) disinfected in hypochlorite solutions containing 1.0% available chlorine synthesized significantly less α-amylase in response to gibberellic acid than layers derived from half-seeds disinfected in 0.1% hypochlorite. This effect of hypochlorite involved neither a differential decrease in the synthesis of group A or B α-amylase isozymes nor a general decrease in α-amylase synthesis attributable to fewer viable aleurone cells in layers from half-seeds disinfected with 1% hypochlorite. Our results emphasize the need to evaluate the potential effects of routine disinfection procedures used in physiological and biochemical studies.     

Evidence for osmotic regulation of hydrolytic enzyme production in germinating barley seeds

α-Amylase levels in intact seeds of barley (Hordeum vulgare L. cv. Himalaya) reach a maximum at 3 to 4 days of germination while gibberellin levels continue to increase beyond 6 days of germination. In contrast to its effect on half seeds, gibberellic acid does not increase the total amount of α-amylase produced in germinating seeds. The inability of gibberellic acid to stimulate α-amylase production is not related to its availability; rather, evidence suggests that a factor(s) in whole seeds prevents further enhancement of α-amylase formation and accumulation. Hydrolysis products accumulate in the subaleurone space of the endosperm of germinating seeds up to concentrations of 570 milliosmolar. Chromatography of these hydrolysis products indicate the presence of maltose and glucose. Calculations based on reducing sugar determinations show that glucose accounts for as much as 57% of the solutes present in the endosperm fluid. Both maltose and glucose in the range of 0.2 to 0.4 M effectively inhibit the production of α-amylase by isolated barley aleurone layers. This inhibition is quantitatively similar to that brought about by solutions of polyethylene glycol and mannitol. On the basis of these data we propose that hydrolysis products which accumulate in the starchy endosperm of germinating seeds function to regulate the production of hydrolytic enzymes by the aleurone layer.