Expression of α-amylase and other gibberellin-regulated genes in aleurone tissue of developing wheat grains

Aleurone tissue from freshly harvested immature wheat grains (Triticum aestivum L. cv. Sappo) which is normally unresponsive to gibberellic acid can be made responsive by subjecting the tissue to a pre-incubation treatment in a simple buffered medium prior to the addition of the growth substance. The effectiveness of this treatment is dependent on grain age, with grains less than 15–20 days post anthesis failing to become converted to a responsive state whilst tissue from grains older than this become increasingly susceptible. Tissue from grains of a certain age (approx. 25–28 days post anthesis) produce small amounts of -amylase following this treatment even in the absence of exogenously applied growth substance. Using different ³²-labelled complementary-DNA probes for -amylase in wheat it was demonstrated that the failure of freshly harvested tissue to produce -amylase was correlated with the absence of the appropriate mRNA species. Inability to accumulate -amylase mRNA in response to gibberellic acid was removed by the pre-iccubation treatment and also by enforced drying. The gibberellin-regulated expression of other unidentified genes also responds to pre-incubation or drying. Induction of gibberellin-responsiveness in immature aleurone cells did not extend to the secretion of acid phosphatase, protease and ribonuclease.Abbreviations cDNA complementary DNA - dpa days post anthesis - GA gibberellin - GA₃ gibberellic acid     

The mode of secretion of α-amylase in barley aleurone layers

The involvement of the endomenbrane system of barley (Hordeum vulgare L.) aleurone cells in the secretion of gibberellin-induced hydrolases has been investigated at the biochemical level. Our results show that at least 40–60% of the -amylase activity in homogenates of aleurone layers occurs in a membrane-bound, latent form. The latent -amylase can be assayed quantitatively following disruption of membranes by treatment with Triton X-100, ethanol, sonication, or osmotic shock and shear. The association of -amylase with the membrane is not an artifact arising from homogenization of the tissue, and acid protease is also enriched in the same subcellular fraction as the -amylase. The membrane fraction with which the -amylase is associated has many properties of the endoplasmic reticulum (ER). When membranebound -amylase is prepared in buffers containing 3 mM MgCl₂ two fractions from a sucrose step gradient contain most of the -amylase activity. These fractions are enriched in the ER marker enzyme, NADH-dependent cytochrome-c reductase, and show densities characteristic of smooth and rough ER during subsequent purification on continuous gradients. In step gradients prepared with ethylenediaminete-traacetic-acid-treated membranes, -amylase activity is contained primarily in one fraction having the density of smooth ER. Electron microscopy of the purified fractions is consistent with -amylase being associated with smooth and rough ER. However, it has not been ruled out that the enzyme is also associated with plasma membrane, Golgi membranes, or tonoplast. Examination of the isoenzyme patterns of secreted, of total-homogenate and of membrane-associated -amylases, as well as the results from pulsechase experiments using L-[³H]leucine for labeling of -amylase, are all consistent with the hypothesis that membrane-associated -amylase is an intermediate in the secretory process.Abbreviations CNTPE N-carbobenzoxy-L-tyrosine p-nitrophenylester - Cyt oxidase Cytochrome oxidase - ER endoplasmic reticulum - EDTA ethylenediaminetetraacetic acid - GA₃ gibberellic acid - IDPase inosine diphosphatase - K⁺-ATPase pH 6.5 K⁺-stimulated adenosine triphosphatase - MES 2-(N-morpholino)ethanesulfonic acid - MOPS 3-(N-morpholino)propanesulfonic acid - NADH: Cyt c reductase cyanide-insensitive NADH-linked cytochrome-c reductase - RER rough endoplasmic reticulum - Tris tris-(hydroxymethyl)-aminomethane     

Calcium regulation of the secretion of α-amylase isoenzymes and other proteins from barley aleurone layers

The effect of calcium on the secretion of α-amylase (EC 3.2.1.1) and other hydrolases from aleurone layers of barley (Hordeum vulgare L. cv. Himalaya) was studied. Withdrawal of Ca²⁺ from the incubation medium of aleurone layers preincubated in 5 μM gibberellic acid (GA₃) and 5 mM CaCl₂ results in a 70–80% reduction in the secretion of α-amylase activity to the incubation medium. Agar-gel electrophoresis shows that the reduction in α-amylase activity following Ca²⁺ withdrawal is correlated with the disappearance of group B isoenzymes from the incubation medium. The secretion of isoenzymes of group A is unaffected by Ca²⁺. The addition of Ca²⁺ stimulates the secretion of group-B isoenzymes but has no measurable effect on either the α-amylase activity or the isoenzyme pattern of aleurone-layer extracts. Pulse-labelling experiments with [³⁵S]methionine show that Ca²⁺ withdrawal results in a reduction in the secretion of labelled polypeptides into the incubation medium. Immunochemical studies also show that, in the absence of Ca²⁺, α-amylase isoenzymes of group B are not secreted into the incubation medium. In addition to its effect on α-amylase, Ca²⁺ influences the secretion of other proteins including several acid hydrolases. The secretion of these other proteins shows the same dependence on Ca²⁺ concentration as does that of α-amylase. Other cations can promote the secretion of α-amylase to less and varying extents. Strontium is 85% as effective as Ca²⁺ while Ba²⁺ is only 10% as effective. We conclude that Ca²⁺ regulates the secretion of enzymes and other proteins from the aleurone layer of barley.     

The effect of abscisic acid on the differential expression of α-amylase isozymes in barley aleurone layers

Summary The treatment of barley aleurone layers with gibberellic acid (GA₃) results in the synthesis of two groups of -amylase isozymes. Addition of abscisic acid (ABA) at the same time as GA₃ inhibited the synthesis of both groups of isozymes. However, midcourse ABA addition (12 h or later after GA₃) had a more inhibitory effect on the high pI -amylase group than on the low pI -amylase group. This midcourse inhibition was detectable within 2 h of ABA addition. Northern analysis results using cDNA probes for the high pI and low pI -amylase groups paralleled the protein synthesis results for both isozyme groups. High pI -amylase mRNA levels began to decrease within 2 h of midcourse ABA treatment and were less than 10% of the original level by 4 h. The levels of low pI -amylase mRNA were decreased less by midcourse ABA addition than were high pI mRNA levels. Cordycepin and cycloheximide blocked the effects of midcourse ABA addition on -amylase mRNA. These observations indicate that ABA inhibits -amylase expression at the pretranslational level and that protein and RNA synthesis are required for midcourse ABA action to occur. Our results also show that -amylase mRNA, which has been thought to be very stable, is degraded after midcourse ABA treatment.     

Differential expression of α-amylase genes in germinating rice and barley seeds

Steady-state levels of mRNA from individual -amylase genes were measured in the embryo and aleurone tissues of rice (Oryza sativa) and two varieties of barley (Hordeum vulgare L. cv. Himalaya and cv. Klages) during germination. Each member of the -amylase multigene families of rice and barley was differentially expressed in each tissue. In rice, -amylase genes displayed tissue-specific expression in which genes RAmy3B, RAmy3C, and RAmy3E were preferentially expressed in the aleurone layer, genes RAmy1A, RAmy1B and RAmy3D were expressed in both the embryo and aleurone, and genes RAmy3A and RAmy2A were not expressed in either tissue. Whenver two or more genes were expressed in any tissue, the rate of mRNA accumulation from each gene was unique. In contrast to rice, barley -amylase gene expression was not tissue-specific. Messenger RNAs encoding low- and high-pI -amylase isozymes were detectable in both the embryo and aleurone and accumulated at different rates in each tissue. In particular, peak levels of mRNA encoding high-pI -amylases always preceded those encoding low-pI -amylases. Two distinct differences in -amylase gene expression were observed between the two barley varieties. levels of high-pI -amylase mRNA peaked two days earlier in Klages embryos than in Himalaya embryos. Throughout six days of germination, Klages produced three times as much high-pI -amylase mRNA and nearly four times as much low-pI -amylase mRNA than the slower-germinating Himalaya variety.     

Polymorphism and chromosomal location of endogenous α-amylase inhibitor genes in common wheat

Summary Polymorphism of an endogenous -amylase inhibitor in wheat was studied using iso-electric focusing followed by monoclonal antibody — based immunoblotting. Ten isoforms of the inhibitor detected in common wheat and its wild counterparts were assigned to five homoeologous loci. Three -amylase inhibitor loci (Isa-1) were identified in common wheat and located on the long arms of chromosomes 2A, 2B and 2D. In a sample of 27 bread wheats, eight durum wheats, and 12 diploid wheat relatives, amphiploids and triticales, a high resolution isoelectric-focusing separation demonstrated two active and one null allele at the Isa-A1, two alleles at the Isa-B1, one allele at the Isa-D1, four alleles at the Isa-S1, and one allele at the Isa-G1 locus. The most frequent electrophoretic pattern of common wheat cultivars consisted of two isoforms, encoded respectively by the Isa-B1b, Isa-D1 a alleles and the Isa-Alnull allele. All the durum wheats had only one inhibitor form controlled by allele Isa-B1b, which was accompanied by the null allele at the Isa-A1 locus.Contribution No. 210 of the Food Science Department, University of Manitoba     

The role of the endoplasmic reticulum in the synthesis and transport of α-amylase in barley aleurone layers

The subcellular site of -amylase (EC 1.6.2.1) synthesis and transport was studied in barley aleurone layers incubated in the presence or absence of gibberellic acid (GA₃). Using [³⁵S]methionine as a marker, the site of amino-acid incorporation into organelles isolated from aleurone layers incubated with and without GA₃ was determined following purification by isopycnic sucrose-density-gradient centrifugation. Incorporation of radioactivity into trichloroacetic-acid-insoluble proteins was greatest in those fractions exhibiting activity of an endoplasmic reticulum (ER) marker enzyme. Further fractionation of densitygradient fractions by sodium-dodecyl-sulfate polyacrylamide-gel electrophoresis showed that a major portion of the radioactivity in the ER fractions was present in a protein co-migrating with marker -amylase. This protein was identified as authentic -amylase by immunoadsorbent chromatography and affinity chromatography. The newly synthesized -amylase associated with the ER was shown to be sequenstered within the lumen of the ER by experiments which showed that the enzyme was resistant to proteolytic degradation. The labelled -amylase sequestered in the ER can be chased from this organelle when tissue is incubated in unlabelled methionine following a 1-h pulse of labelled methionine. The isoenzymic forms of -amylase found in tissue homogenates and incubation media of aleurone layers incubated with and without GA₃ were characterized after chromatography on diethylaminoethyl cellulose. In homogenates of GA₃-treated aleurone layers, five peaks of -amylase activity were detected, while in homogenates of aleurone layers incubated with-out GA₃ only three peaks of activity were found. In incubation media, four isoenzymes were found after GA₃ treatment and two were found after incubation without GA₃. We conclude that at least five -amylase isoenzymes are synthesized by the ER of barley aleurone layers and that this membrane system is involved in the sequestration and transport of four of these isoenzymes.Abbreviations CHA cyclohepataamylose - DEAE-cellulose diethylaminoethyl-cellulose - ER endoplasmic reticulum - GA₃ gibberellic acid - SDS-PAGE sodium-dodecyl-sulfate polyacrylamide-gel electrophoresis     

Composition of α-amylase secreted by aleurone layers of grains of himalaya barley

α-Amylases secreted by the aleurone layer of whole barley grains were relatively rich in histidine and relatively poor in glutamate/glutamine and serine when compared to other eukaryotic proteins. The secreted α-amylases had an estimated 0.5 residues each of glucose, mannose and N-acetylglucosamine per molecule of protein (MW 41 400 daltons), and gave positive staining reactions for carbohydrate on sodium dodecylsulfate polyacrylamide gels. Because the average α-amylase molecule had less than one sugar residue per enzyme molecule, it was concluded that secreted α-amylases were heterogeneous with respect to glycosylation. A second protein co-purified with α-amylase, but the amino acid composition of this protein was different from that of barley or wheat α-amylase. This protein was composed of two 21 500 dalton polypeptides. No significant amounts of L-leucine (¹⁴C-U) were incorporated into this second protein in isolated aleurone tissue during incubation with gibberellic acid, perhaps because much of it was already present in the starchy endosperm at the time of hormone addition.     

A cell-free system for the study of α-amylase synthesis in barley aleurone layers

1. A cell-free system capable of alpha-amylase synthesis has been obtained from the aleurone layers of germinating barley. 2. This system requires potassium chloride, sucrose and an amino acid mixture in order to function. The crude preparation does not require calcium chloride. Chloramphenicol inhibits alpha-amylase synthesis as indicated both by increase in measurable enzyme activity and incorporation of l-[U-(14)C]glutamic acid.     

Cytochemical localization and antigenicity of α-amylase in barley aleurone tissue

Summary Gibberellic-acid(GA₃)-induced -amylase has been localised in barley aleurone layers using cytochemical methods and light microscopy. Evidence obtained from the use of a starch substrate film method as well as immunofluorescence indicated that the first amylase to appear in the cell was associated with aleurone grains, apparently with the outer membrane, and also with the peripheral cytoplasm. In GA₃-treated tissue, the amylase distribution was much more diffuse, although patchy, throughout the cytoplasm and it tended to accumulate in the endosperm side of the cell. The possibility that the aleurone grain membrane is the site of gibberellin-induced enzyme synthesis and that it proliferates to become rough endoplasmic reticulum is considered. Immunological information was obtained which supports earlier indications that induced -amylase consists of two different proteins, each with molecular heterogeneity.     

SNP and haplotype identification of the wheat monomeric α-amylase inhibitor genes

Seventy-three gene sequences encoding monomeric α-amylase inhibitors were characterized from cultivated wheat “Chinese Spring”, group 6 nullisomic-tetrasomic lines of “Chinese Spring” and diploid putative progenitors of common wheat. The monomeric α-amylase inhibitors from the different sources shared very high homology (99.54%). The different α-amylase inhibitors, which were determined by the 24 single nucleotide polymorphisms (SNPs) of their gene sequences, were investigated. A total of 15 haplotypes were defined by sequence alignment, among which 9 haplotypes were found with only one single sequence sample. Haplotype H02 was found to be the main haplotype occurring in 83 WMAI sequence samples, followed by haplotype H11. The median-joining network for the 15 haplotypes of monomeric α-amylase inhibitor gene sequences from hexaploid wheats was star like, and at least two subclusters emerged. Furthermore evidence of homologous recombination was found between the haplotypes. The relationship between nucleotide substitutions and the amino acid changes in WMAI of hexaploid wheats was summarized. It was clear that only five polymorphic sites in the nucleotide sequence of WMAI resulted in amino acid variations, and that should be the reason for different structure and function of inhibitors. However, little evidence could be found that there were WMAI genes in the A genome of hexaploid wheat, whereas it could conclude from our results that the A genome diploid wheat had WMAI genes. The overall information on the monomeric α-amylase inhibitors from wheat and Aegilops strongly support the view that these inhibitors have evolved from a common ancestral gene through duplication and mutation. Ji-Rui Wang and Yu-Ming Wei are contributed equally to this paper.     

On the secretion of α-amylase by barley aleurone layers after incubation in gibberellic acid

Summary Gel filtration and centrifugation studies were used to study the distribution of -amylase activity in homogenates of barley (Hordeum vulgare L.) aleurone layers. The results obtained were consistent with the hypothesis that -amylase is secreted via membrane-bound vesicles. The -amylase activity in an homogenate of barley aleurone layers was derived not only from the enzyme retained in the aleurone cells but also from enzyme previously secreted from the cells but apparently retained by the cell walls. The amount of -amylase retained by the cell wall was influenced by factors such as the buffer in which the layers were incubated or the presence of Actinomycin D in the incubation medium.Abbreviations GA₃ gibberellic acid - RER rough endoplasmic reticulum - Act. D Actinomycin D     

Expression and secretion of wheat α-amylase in Kluyveromyces lactis

The plasmid pCR1 has been constructed to express a wheat -amylase enzyme in Kluyveromyces lactis strains. The contruct is based on the vector pCXJ-kan1, which has been derived from pDK1, a native plasmid of K. lactis var. drosophilarum containing the essential regions for plasmid replication and stability. Contruct pCR1 produces an -amylase by DNA isolated from a wheat cDNA clone and is controlled by a Saccharomyces cerevisia PGK promoter. Correspondence to: C. Russell     

The effects of gibberellic acid and abscisic acid on α-amylase mRNA levels in barley aleurone layers studies using an α-amylase cDNA clone

Summary Two cDNA clones were characterized which correspond to different RNA species whose level is increased by gibberellic acid (GA₃) in barley (Hordeum vulgare L.) aleurone layers. On the criteria of amino terminal sequencing, amino acid composition and DNA sequencing it is likely that one of these clones (pHV19) corresponds to the mRNA for -amylase (1,4--D-glucan glucanohydrolase, EC 3.2.1.1.), in particular for the B family of -amylase isozymes (Jacobsen JV, Higgins TJV: Plant Physiol 70:1647–1653, 1982). Sequence analysis of PHV19 revealed a probable 23 amino acid signal peptide. Southern hybridization of this clone to barley DNA digested with restriction endonucleases indicated approximately eight gene-equivalents per haploid genome.The identity of the other clone (pHV14) is unknown, but from hybridization studies and sequence analysis it is apparently unrelated to the -amylase clone.Both clones hybridize to RNAs that are similar in size (1500b), but which accumulate to different extents following GA₃ treatment: -amylase mRNA increases approximately 50-fold in abundance over control levels, whereas the RNA hybridizing to pHV14 increases approximately 10-fold. In the presence of abscisic acid (ABA) the response to GA₃ is largely, but not entirely, abolished. These results suggest that GA₃ and ABA regulate synthesis of -amylase in barley aleurone layers primarily through the accumulation of -amylase mRNA.Abbreviations ABA abscisic acid - CHA cyclohepta-amylose - CMC carboxymethyl cellulose - GA₃ gibberellic acid     

The role of endogenous gibberellins in the formation of α-amylase by aleurone layers of germinating barley caryopses

Using sensitive and selective immunological assays we have shown that in germinating caryopses of Hordeum vulgare L. cv. Himalaya, the level of gibberellin A₄ (GA₄) rises approximately 18-to 20-fold shortly (2–4 h) before -amylase activity increases. Gibberellin A₄ is the predominant immunoreactive gibberelin during these developmental stages and reaches a peak amount of approximately 9 pmol per caryopsis about 48 h after imbibition. Isolated aleurone layers produce GA₄ in the presence of an exogenous gibberellin, such as GA₁, which is not a biosynthetic precursor for GA₄. Experiments with inhibitors of gibberellin biosynthesis indicate that gibberellin synthesis is required in this tissue for the induction of -amylase. The inductive effect of exogenously applied GA₁ is indirect and appears to be mediated by GA₄. Embryos form predominantly GA₁; however, very little of this material is released by isolated embryos into the incubation medium. The results presented make it unlikely that the role of the embryo in the process of -amylase induction in aleurone layers is to provide gibberellins or gibberellin precursors.Abbreviations ABA abscisic acid - GA gibberellin - GA₃ gibberellic acid - RIA radioimmunoassay - TLC thin-layer chromatography