Changes in Levels of alpha-Amylase Components in Barley Tissues during Germination and Early Seedling Growth

Kernels of Klages barley (Hordeum vulgare L.) were germinated for 1 to 4 days on moist sand at 18°C. Representative kernels from each time period were dissected to give the following fractions: scutellum, subscutellar endosperm, aleurone-scutellum interface, remaining aleurone, subaleurone endosperm, and core endosperm. These tissues were analyzed for α-amylase components by isoelectric focusing and rocket-line immunoelectrophoresis. Although aleurone and scutellar tissues appeared to synthesize the same α-amylase components, enzyme was detected first in the scutellum. A larger proportion of scutellar α-amylase was excreted into the endosperm compared to aleurone synthesized α-amylase. Aleurone cells appeared to synthesize appreciably more α-amylase than did scutellar tissue.     

Occurrence of alpha-amylase in the axis of germinating peas

α-Amylase was found in the axis portion of ungerminated pea seeds (Pisum sativum var. Alaska). The occurrence of this enzyme was demonstrated with crude homogenates (also containing β-amylase) using three different methods: the hydrolysis of β-limit dextrin, the change in absorption spectra for the iodine-starch complex, and the increase in reducing materials relative to the decrease in starch. The first method was used to quantitate the changes in α-amylase activity during germination. The increase in total amylase activity (primarily β-amylase) paralleled germination; the accumulation of α-amylase activity was not initiated for an additional day. The increased α-amylase activity was related to epicotyl growth. Approximately half of this activity was found in the etiolated stem, the distribution being higher in growing than in nongrowing portions.     

Characteristics of alpha-Amylase during Germination of Two High-Sugar Sweet Corn Cultivars of Zea mays L

The role of the scutellum and the aleurone in α-amylase production in the high-sugar sweet corn cultivars Illini X-tra Sweet (shrunken-2, sh2) and Illinois 677a (sugary, sugary enhancer; su se) was compared to that in the starchy (Su) hybrid Funks G4646 with the use of α-amylase enzyme assays, isoelectric focusing, electron microscopy, and laser scanning confocal microscopy. The scutellum of Illinois 677a had low levels of α-amylase activity compared to that of Funks G4646 through 10 days after imbibition, and the aleurone of Illini X-tra Sweet had negligible activity. On the isoelectric focusing gels, the Illinois 677a scutellum had fewer α-amylase isozymes at 7 days compared to the Funks G4646 scutellum. The Illini X-tra Sweet aleurone had no α-amylase isozymes. Funks G4646 scutellar epithelial and aleurone cells contained abundant rough endoplasmic reticulum, polysomes, and dictyosomes at 5 and 7 days, respectively. The scutellar epithelial cells of Illinois 677a contained fewer of these structures by 5 days, and the Illini X-tra Sweet aleurone contained mostly lipid bodies through 7 days. Few cytoplasmic membranes and little RNA were detected with laser scanning confocal microscopy in the Illini X-tra Sweet aleurone compared to Funks G4646 at 7 days. These data suggest that the scutellum of Illinois 677a and the aleurone of Illini X-tra Sweet have impaired abilities to produce α-amylase.     

beta-Amylases in Cereals : A Study of the Maize beta-Amylase System

β-Amylase of maize (Zea mays L.) caryopses was studied during development and germination by means of enzymic, electrophoretic, and immunochemical techniques. β-Amylase activity increased during caryopsis development to a maximum value at the beginning of the water content plateau (at this stage the enzyme was located primarily within the pericarp) and then decreased. Almost no β-amylase (activity or antigen) was found in either free or bound forms in the mature maize caryopsis. The activity increased again during seedling growth and reached much higher values. Both the aleurone layer (to a major extent) and the scutellum produced and secreted β-amylase during germination, the secretion being stimulated by Ca²⁺. No posttranslational modification of the enzyme was detected during germination. The molecular specific activity of the enzyme remained unchanged during the observed periods, indicating that the regulation of the activity is based essentially on protein turnover. The enzyme from developing and germinating caryopses was found to be identical in terms of antigenicity, isoelectric point, and molecular mass to the β-amylases extracted from the roots and the leaves of the maize seedling. The maize β-amylase resembles in all respects the ubiquitous β-amylase described for rye and wheat, whereas the major β-amylase of those cereals appears to be lacking in the maize caryopsis.     

Enzymic Mechanism of Starch Breakdown in Germinating Rice Seeds: 9. DE NOVO SYNTHESIS OF beta-AMYLASE

Germinating rice seeds were fed with [³⁵S]methionine and the incorporation of ³⁵S into β-amylase demonstrated by quantitative immunoprecipitation using rabbit anti-β-amylase immunoglobulin G fraction. Separation of the antigen-antibody complex by Na-dodecylsulfate gel electrophoresis and subsequent radioautography clearly showed the radioactive labeling of the β-amylase molecule. The specific radioactivity of β-amylase derived from scutellum by immunoprecipitation was significantly greater than that of the endosperm. The results strongly indicate that at the onset of germination of rice seeds β-amylase is synthesized de novo in the scutellum and that in later stages there occurs activation of an inactive, latent form of the enzyme associated with starch granules in the endosperm. In later stages of germination this activated form of the enzyme becomes dominant.     

Water stress enhances expression of an alpha-amylase gene in barley leaves

The amylases of the second leaves of barley seedlings (Hordeum vulgare L. cv Betzes) were resolved into eight isozymes by isoelectric focusing, seven of which were β-amylase and the other, α-amylase. The α-amylase had the same isoelectric point as one of the gibberellin-induced α-amylase isozymes in the aleurone layer. This and other enzyme characteristics indicated that the leaf isozyme corresponded to the type A aleurone α-amylase (low pI group). Crossing experiments indicated that leaf and type A aleurone isozymes resulted from expression of the same genes.

In unwatered seedlings, leaf α-amylase increased as leaf water potential decreased and ABA increased. Water stress had no effect on β-amylase. α-Amylase occurred uniformly along the length of the leaf but β-amylase was concentrated in the basal half of the leaf. Cell fractionation studies indicated that none of the leaf α-amylase occurred inside chloroplasts.

Leaf radiolabeling experiments followed by extraction of α-amylase by affinity chromatography and immunoprecipitation showed that increase of α-amylase activity involved synthesis of the enzyme. However, water stress caused no major change in total protein synthesis. Hybridization of a radiolabeled α-amylase-related cDNA clone to size fractionated RNA showed that water-stressed leaves contained much more α-amylase mRNA than unstressed plants. The results of these and other studies indicate that regulation of gene expression may be a component in water-stress induced metabolic changes.

     

Secretion of alpha-amylase by the aleurone layer and the scutellum of germinating barley grain

α-Amylase activities in extracts of different parts of barley grain (Hordeum vulgare L. cv Himalaya) were low after 1 day of germination at 20°C, but they began to increase afterwards. In the scutellum and the aleurone layer, the increases were small, but in the starchy endosperm a great increase took place between days 1 and 6.

When the aleurone layers were separated from germinating whole grains and incubated in 10 millimolar CaCl₂, the α-amylase activity in the medium increased linearly for about 30 to 60 minutes, indicating secretion. The activity inside the aleurone layer decreased only slightly during the incubation, indicating that secretion of α-amylase was accompanied by synthesis. The rates of secretion in vitro by the aleurone layers separated at different stages of germination corresponded rather well to the rate of accumulation of α-amylase activity in the starchy endosperm in a whole grain.

Scutella separated after 1 day of germination released small amounts of α-amylase activity into 10 millimolar CaCl₂. This release was linear for at least 1 hour and did not occur at 0°C; it is therefore likely to be due to secretion. At later stages of germination, the secretion by the scutella was slower than at day 1 and the total secretion accounted for only 5 to 10% of the increase of α-amylase activity in the starchy endosperm in a whole grain.

Since the times from the separation of the parts of the grain to the beginning of the secretion assay (10-40 minutes) as well as the duration of the assay itself (20-60 minutes) were short, the rates of secretion by the separated grain parts are likely to represent those in an intact grain. The results indicate therefore that at least in the conditions used the bulk of the total α-amylase in the starchy endosperm is secreted by the aleurone layer, the contribution by the scutellum being only 5 to 10% of the total activity.

     

Enzymic mechanism of starch breakdown in germinating rice seeds : 12. Biosynthesis of alpha-amylase in relation to protein glycosylation

The biosynthetic mechanism of α-amylase synthesis in germinating rice (Oryza sativa L. cv. Kimmazé) seeds has been studied both in vitro and in vivo. Special attention has been focused on the glycosylation of the enzyme molecule. Tunicamycin was found to inhibit glycosylation of α-amylase by 98% without significant inhibition of enzyme secretion. The inhibitory effect exerted by the antibiotic on glycosylation did not significantly alter enzyme activity.

In an in vitro system using poly-(A) RNA isolated from rice scutellum and the reticulocyte lysate translation system, a precursor form of α-amylase (precursor I) is formed. Inhibition of glycosylation by Tunicamycin allowed detection of a nonglycosylated precursor (II) of α-amylase. The molecular weight of the nonglycosylated precursor II produced in the presence of Tunicamycin was 2,900 daltons less than that of the mature form of α-amylase (44,000) produced in the absence of Tunicamycin, and 1,800 daltons less than the in vitro synthesized molecule.

The inhibition of glycosylation by Tunicamycin as well as in vitro translation helped clarify the heterogeneity of α-amylase isozymes. Isoelectrofocusing (pH 4-6) of the products, zymograms, and fluorography were employed on the separated isozyme components. The mature and Tunicamycin-treated nonglycosylated forms of α-amylase were found to consist of three isozymes. The in vitro translated precursor forms of α-amylase consisted of four multiple components. These results indicate that heterogeneity of α-amylase isozymes is not due to glycosylation of the enzyme protein but likely to differences in the primary structure of the protein moiety, which altogether support that rice α-amylase isozymes are encoded by multiple genes.

     

Purification and Characterization of Pea Epicotyl beta-Amylase

The most abundant β-amylase (EC 3.2.1.2) in pea (Pisum sativum L.) was purified greater than 880-fold from epicotyls of etiolated germinating seedlings by anion exchange and gel filtration chromatography, glycogen precipitation, and preparative electrophoresis. The electrophoretic mobility and relative abundance of this β-amylase are the same as that of an exoamylase previously reported to be primarily vacuolar. The enzyme was determined to be a β-amylase by end product analysis and by its inability to hydrolyze β-limit dextrin and to release dye from starch azure. Pea β-amylase is an approximate 55 to 57 kilodalton monomer with a pl of 4.35, a pH optimum of 6.0 (soluble starch substrate), an Arrhenius energy of activation of 6.28 kilocalories per mole, and a K_m of 1.67 milligrams per milliliter (soluble starch). The enzyme is strongly inhibited by heavy metals, p-chloromer-curiphenylsulfonic acid and N-ethylmaleimide, but much less strongly by iodoacetamide and iodoacetic acid, indicating cysteinyl sulfhydryls are not directly involved in catalysis. Pea β-amylase is competitively inhibited by its end product, maltose, with a K_i of 11.5 millimolar. The enzyme is partially inhibited by Schardinger maltodextrins, with α-cyclohexaamylose being a stronger inhibitor than β-cycloheptaamylose. Moderately branched glucans (e.g. amylopectin) were better substrates for pea β-amylase than less branched or non-branched (amyloses) or highly branched (glycogens) glucans. The enzyme failed to hydrolyze native starch grains from pea and glucans smaller than maltotetraose. The mechanism of pea β-amylase is the multichain type. Possible roles of pea β-amylase in cellular glucan metabolism are discussed.     

Beta-Amylases from Alfalfa (Medicago sativa L.) Roots

Amylase was found in high activity (193 international units per milligram protein) in the tap root of alfalfa (Medicago sativa L. cv. Sonora). The activity was separated by gel filtration chromatography into two fractions with molecular weights of 65,700 (heavy amylase) and 41,700 (light amylase). Activity staining of electrophoretic gels indicated the presence of one isozyme in the heavy amylase fraction and two in the light amylase fraction. Three amylase isozymes with electrophoretic mobilities identical to those in the heavy and the light amylase fractions were the only amylases identified in crude root preparations. Both heavy and light amylases hydrolyzed amylopectin, soluble starch, and amylose but did not hydrolyze pullulan or β-limit dextrin. The ratio of viscosity change to reducing power production during starch hydrolysis was identical for both alfalfa amylase fractions and sweet potato β-amylase, while that of bacterial α-amylase was considerably higher. The identification of maltose and β-limit dextrin as hydrolytic end-products confirmed that these alfalfa root amylases are all β-amylases.     

Enzyme-Synthesized Highly Branched Maltodextrins Have Slow Glucose Generation at the Mucosal α-Glucosidase Level and Are Slowly Digestible In Vivo

For digestion of starch in humans, α-amylase first hydrolyzes starch molecules to produce α-limit dextrins, followed by complete hydrolysis to glucose by the mucosal α-glucosidases in the small intestine. It is known that α-1,6 linkages in starch are hydrolyzed at a lower rate than are α-1,4 linkages. Here, to create designed slowly digestible carbohydrates, the structure of waxy corn starch (WCS) was modified using a known branching enzyme alone (BE) and an in combination with β-amylase (BA) to increase further the α-1,6 branching ratio. The digestibility of the enzymatically synthesized products was investigated using α-amylase and four recombinant mammalian mucosal α-glucosidases. Enzyme-modified products (BE-WCS and BEBA-WCS) had increased percentage of α-1,6 linkages (WCS: 5.3%, BE-WCS: 7.1%, and BEBA-WCS: 12.9%), decreased weight-average molecular weight (WCS: 1.73×10⁸ Da, BE-WCS: 2.76×10⁵ Da, and BEBA-WCS 1.62×10⁵ Da), and changes in linear chain distributions (WCS: 21.6, BE-WCS: 16.9, BEBA-WCS: 12.2 DP_w). Hydrolysis by human pancreatic α-amylase resulted in an increase in the amount of branched α-limit dextrin from 26.8% (WCS) to 56.8% (BEBA-WCS). The α-amylolyzed samples were hydrolyzed by the individual α-glucosidases (100 U) and glucogenesis decreased with all as the branching ratio increased. This is the first report showing that hydrolysis rate of the mammalian mucosal α-glucosidases is limited by the amount of branched α-limit dextrin. When enzyme-treated materials were gavaged to rats, the level of postprandial blood glucose at 60 min from BEBA-WCS was significantly higher than for WCS or BE-WCS. Thus, highly branched glucan structures modified by BE and BA had a comparably slow digesting property both in vitro and in vivo. Such highly branched α-glucans show promise as a food ingredient to control postprandial glucose levels and to attain extended glucose release.     

Messenger RNAs from the Scutellum and Aleurone of Germinating Barley Encode (1-->3,1-->4)-beta-d-Glucanase, alpha-Amylase and Carboxypeptidase

Polyclonal antibodies raised against barley (1→3,1→4)-β-d-glucanase, α-amylase and carboxypeptidase were used to detect precursor polypeptides of these hydrolytic enzymes among the in vitro translation products of mRNA isolated from the scutellum and aleurone of germinating barley. In the scutellum, mRNA encoding carboxypeptidase appeared to be relatively more abundant than that encoding α-amylase or (1→3,1→4)-β-d-glucanase, while in the aleurone α-amylase and (1→3,1→4)-β-d-glucanase mRNAs predominated. The apparent molecular weights of the precursors for (1→3,1→4)-β-d-glucanase, α-amylase, and carboxypeptidase were 33,000, 44,000, and 35,000, respectively. In each case these are slightly higher (1,500-5,000) than molecular weights of the mature enzymes. Molecular weights of precursors immunoprecipitated from aleurone and scutellum mRNA translation products were identical for each enzyme.     

Amylases in Pea Tissues with Reduced Chloroplast Density and/or Function

Pea (Pisum sativum L.) tissues with reduced chloroplast density (e.g. petals and stems) or function (i.e. senescent leaves and leaves darkened for prolonged periods) were surveyed to determine whether tissues with genetically or environmentally reduced chloroplast density and/or function also have significantly different amylolytic enzyme activities and/or isoform patterns than leaf tissues with totally competent chloroplasts. Native PAGE followed by electrophoretically blotting through a starch or β-limit dextrin containing gel and KI/I₂ staining revealed that the primary amylases in leaves, stems, petals, and roots were the primarily vacuolar β-amylase (EC 3.2.1.2) and the primarily apoplastic α-amylase (EC 3.2.1.1). Among tissues of light grown pea plants, petals contained the highest levels of total amylolytic (primarily β-amylase) activity and considerably higher ratios of β- to α-amylase. In aerial tissues there was an inverse relationship between chlorophyll and starch concentration, and β-amylase activity. In sections of petals and stems there was a pronounced inverse relationship between chlorophyll concentration and the activity of α-amylase. Senescing leaves of pea, as determined by age, and protein and chlorophyll content, contained 3.8-fold (fresh weight basis) and 32-fold (protein basis) higher α-amylase activity than fully mature leaves. Leaves maintained in darkness for 12 days displayed a 14-fold (fresh weight basis) increase in α-amylase activity over those grown under continuous light. In senescence and prolonged darkness studies, the α-amylase that was greatly increased in activity was the primarily apoplastic α-amylase. These studies indicate that there is a pronounced inverse relationship between chloroplast function and levels of apoplastic α-amylase activity and in some cases an inverse relationship between chloroplast density and/or function and vacuolar β-amylase activity.     

Purification and characteristics of an endogenous alpha-amylase inhibitor from barley kernels

An inhibitor of malted barley (Hordeum vulgare cv Conquest) α-amylase II was purified 125-fold from a crude extract of barley kernels by (NH₄)₂SO₄ fractionation, ion exchange chromatography on DEAE-Sephacel, and gel filtration on Bio-Gel P 60. The inhibitor was a protein with an approximate molecular weight of 20,000 daltons and an isoelectric point of 7.3. The protein was homogeneous, as assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Amino acid analysis indicated the presence of about 9 half-cystine residues per mole. The neutral isoelectric point of the inhibitor suggested that some of the apparently acidic residues (glutamic and aspartic) existed in the amide form. The first twenty N-terminal amino acids were sequenced. Some homology appeared to exist between the α-amylase II inhibitor and trypsin inhibitor from barley. Complex formation between α-amylase II and the inhibitor was detected by the appearance of a new molecular weight species after gel filtration on Bio-Gel P 100. Enzyme and inhibitor had to be preincubated for 5 min, prior to assaying for enzyme activity before maximum inhibition was attained. Inhibition increased at higher pH values. At pH 5.5, an approximately 1100 molar excess of inhibitor over α-amylase II produced 40% inhibition, whereas, at pH 8.0, a 1:1 molar ratio of inhibitor to enzyme produced the same degree of inhibition.     

Amylases from aleurone layers and starchy endosperm of barley seeds

Amylases from incubated aleurone layers or from starchy endosperm of barley seeds (Hordeum vulgare L. cv. Himalaya) were investigated using acrylamide gel electrophoresis and analytical gel filtration with Sephadex G-200. Electrophoresis of amylase from aleurone layers yields seven visually distinct isozymes with an estimated molecular weight of 43,000. Because each isozyme hydrolyzes β-limit dextrin azure and incorporates calcium-45, they are α-amylases. On Sephadex G-200, amylase from the aleurone layers is separated into seven fractions ranging in estimated molecular weights from 45,000 to 3,000. Little or no activity is observed when six fractions are subjected to electrophoresis. Electrophoresis of only the fraction with the estimated molecular weight of 45,000 gave the seven isozymes. The amylases are heat labile and cannot be stabilized by the presence of substrate or by the protease inhibitor, phenylmethylsulfonylfluoride. Electrophoresis of amylase from the starchy endosperm yields nine β-amylases. Four of these β-amylases are isozymes with an estimated molecular weight of 43,000. The other five forms of β-amylase represent molecular aggregates of the four basic β-amylase monomers. A dimer, a tetramer, and an octamer of β-amylase can be identified with estimated molecular weights of about 86,000, 180,000 and 400,000, respectively. These estimated molecular weights were confirmed on Sephadex G-200. There are five additional fractions of β-amylase with estimated molecular weights ranging from 30,000 to 4,000. These fractions are not observed electrophoretically.     

Purification and properties of starch hydrolyzing enzymes in mature roots of sugar beets

Mature roots of sugar beets, which accumulate large amounts of sucrose but not starch, nevertheless contained acid and neutral amylases, judging from their pH optima, as well as pullulanase. Acid and neutral amylases were partially purified by procedures including fractionation with ammonium sulfate, ion exchange column chromatography, and gel filtration. Acid amylase was classified as an exoamylase, since it produced only glucose from soluble starch, amylopectin. β-limit dextrin, and rabbit liver glycogen. Neutral amylase was classified as an endoamylase, since it liberated maltose as the main product plus a small amount of glucose and oligosaccharides, and was capable of hydrolyzing β-limit dextrin. Pullulanase was purified to apparent homogeneity by procedures including fractionation with ammonium sulfate, Diethylaminoethyl-cellulose column chromatography and affinity chromatography. Pullulanase was capable of hydrolyzing soluble starch, amylopectin, β-limit-dextrin, and pullulan. Debranching of amylopectin was further evident by an increase in extinction coefficient, and by a shift of λ_max from 530 to 560 nm when the debranched amylopectin formed a complex with I₂-KI.     

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.     

alpha-Amylase Isozymes in Gibberellic Acid-treated Barley Half-seeds

The presence of multiple forms of α-amylase in gibberellic acid-treated embryoless barley half-seeds was demonstrated by separation on diethylaminoethyl-Sephadex and isoelectric focusing polyacrylamide gel disc electrophoresis. Two major α-amylase fractions (A and B), each consisting of two to three isozyme components, were purified. α-Amylase fractions A and B were distinguishable in their reaction patterns. The optimal pH of fraction A α-amylase was found to reside in the acidic side (pH 5.0), as was determined by analyzing the reducing sugars formed as well as the paper chromatographic detection of reaction products. At neutral pH, 6.9, fraction A exhibited weak amylolytic activity in forming maltose. The α-amylase activity in fraction A was markedly stimulated by heat treatment (70 C/15 minutes). Fraction B, constituting a major part of amylases in the endosperm extract, was also found to be composed of α-amylase, as evidenced by the loss of enzyme activity upon allowing fractions A and B to stand at pH 3.3 for a prolonged period. The possible physiological function of the two different types of α-amylase in the carbohydrate breakdown of barley seeds is discussed.     

Isolation and Partial Characterization of a Factor from Barley Aleurone that Modifies alpha-Amylase in Vitro

Posttranslational modifications that give rise to multiple forms of α-amylase (EC 3.2.1.1) in barley (Hordeum vulgare L. cv Himalaya) were studied. When analyzed by denaturing polyacrylamide gel electrophoresis, barley α-amylase has a molecular mass of 43 to 44 kilodaltons, but isoelectric focusing resolves the enzyme into a large number of isoforms. To precisely identify these isoforms, we propose a system of classification based on their isoelectric points (pl). α-Amylases with pls of approximately 5, previously referred to as low pl or Amy1 isoforms, have been designated HAMY1, and α-amylases with pls of approximately 6, referred to as high pl or Amy2, are designated HAMY2. Individual isoforms of HAMY1 and HAMY2 are identified by their pls. For example, the most acidic α-amylase synthesized and secreted by barley aleurone layers is designated HAMY1(4.56). Some of the diversity in the pls of barley α-amylases arises from posttranslational modifications of the enzyme. We report the isolation of a factor from barley aleurone layers and incubation media that can modify HAMY1 isoforms in vitro. This factor has a molecular mass between 30 and 50 kilodaltons, and it can catalyze the conversion of HAMY1(4.90) and HAMY1(4.64) to isoforms 4.72 and 4.56, respectively. The in vitro conversion of HAMY1 isoforms by the factor is favored by pH values of approximately 5 and is inhibited at approximately pH 7. The level of this factor in aleurone layers and incubation media is not affected by treatment of the tissue with gibberellic acid. The amylase-modifying activity from barley will also modify α-amylases isolated from human saliva and porcine pancreas. An activity that can modify HAMY1 isoforms in vitro has also been isolated from Onozuka R10 cellulase. Because the activity isolated from barley lowers the pl of α-amylase from barley, human saliva, and porcine pancreas, we speculate that it is a deamidase.     

Selection for low dormancy in annual ryegrass (Lolium rigidum) seeds results in high constitutive expression of a glucose-responsive α-amylase isoform

Background and Aims

α-Amylase in grass caryopses (seeds) is usually expressed upon commencement of germination and is rarely seen in dry, mature seeds. A heat-stable α-amylase activity was unexpectedly selected for expression in dry annual ryegrass (Lolium rigidum) seeds during targeted selection for low primary dormancy. The aim of this study was to characterize this constitutive activity biochemically and determine if its presence conferred insensitivity to the germination inhibitors abscisic acid and benzoxazolinone.

Methods

α-Amylase activity in developing, mature and germinating seeds from the selected (low-dormancy) and a field-collected (dormant) population was characterized by native activity PAGE. The response of seed germination and α-amylase activity to abscisic acid and benzoxazolinone was assessed. Using an alginate affinity matrix, α-amylase was purified from dry and germinating seeds for analysis of its enzymatic properties.

Key Results

The constitutive α-amylase activity appeared late during seed development and was mainly localized in the aleurone; in germinating seeds, this activity was responsive to both glucose and gibberellin. It migrated differently on native PAGE compared with the major activities in germinating seeds of the dormant population, but the enzymatic properties of α-amylase purified from the low-dormancy and dormant seeds were largely indistinguishable. Seed imbibition on benzoxazolinone had little effect on the low-dormancy seeds but greatly inhibited germination and α-amylase activity in the dormant population.

Conclusions

The constitutive α-amylase activity in annual ryegrass seeds selected for low dormancy is electrophoretically different from that in germinating seeds and its presence confers insensitivity to benzoxazolinone. The concurrent selection of low dormancy and constitutive α-amylase activity may help to enhance seedling establishment under competitive conditions.