The Role of Pea Chloroplast [alpha]-Glucosidase in Transitory Starch Degradation.

Pea chloroplastic [alpha]-glucosidase (EC 3.2.1.20) involved in transitory starch degradation was purified to apparent homogeneity by ion exchange, reactive dye, hydroxylapatite, hydrophobic interaction, and gel filtration column chromatography. The native molecular mass and the subunit molecular mass were about 49.1 and 24.4 kD, respectively, suggesting that the enzyme is a homodimer. The enzyme had a Km of 7.18 mM for maltose. The enzyme's maximal activity at pH 7.0 and stability at pH 6.5 are compatible with the diurnal oscillations of the chloroplastic stromal pH and transitory starch accumulation. This pH modulation of the [alpha]-glucosidase's activity and stability is the only mechanism known to regulate starch degradative enzymes in leaves. Although the enzyme was specific for the [alpha]-D-glucose in the nonreducing end as the glycon, the aglycon moieties could be composed of a variety of groups. However, the hydrolysis rate was greatly influenced by the aglycon residues. Also, the enzyme could hydrolyze glucans in which carbon 1 of the glycon was linked to different carbon positions of the penultimate glucose residue. The ability of the [alpha]-glucosidase to hydrolyze [alpha]-1,2- and [alpha]-1,3-glucosidic bonds may be vital if these bonds exist in starch granules because they would be barriers to other starch degradative enzymes. This purified pea chloroplastic [alpha]-glucosidase was demonstrated to initiate attacks on native transitory chloroplastic starch granules.

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 beta-limit dextrin containing gel and KI/I(2) staining revealed that the primary amylases in leaves, stems, petals, and roots were the primarily vacuolar beta-amylase (EC 3.2.1.2) and the primarily apoplastic alpha-amylase (EC 3.2.1.1). Among tissues of light grown pea plants, petals contained the highest levels of total amylolytic (primarily beta-amylase) activity and considerably higher ratios of beta- to alpha-amylase. In aerial tissues there was an inverse relationship between chlorophyll and starch concentration, and beta-amylase activity. In sections of petals and stems there was a pronounced inverse relationship between chlorophyll concentration and the activity of alpha-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 alpha-amylase activity than fully mature leaves. Leaves maintained in darkness for 12 days displayed a 14-fold (fresh weight basis) increase in alpha-amylase activity over those grown under continuous light. In senescence and prolonged darkness studies, the alpha-amylase that was greatly increased in activity was the primarily apoplastic alpha-amylase. These studies indicate that there is a pronounced inverse relationship between chloroplast function and levels of apoplastic alpha-amylase activity and in some cases an inverse relationship between chloroplast density and/or function and vacuolar beta-amylase activity.

Partial Characterization and Subcellular Localization of Three alpha-Glucosidase Isoforms in Pea (Pisum sativum L.) Seedlings.

Three isoforms of alpha-glucosidase (EC 3.2.1.20) have been extracted from pea (Pisum sativum L.) seedlings and separated by DEAE-cellulose and CM-Sepharose chromatography. Two alpha-glucosidase isoforms (alphaG1 and alphaG2) were most active under acid conditions, and appeared to be apoplastic. A neutral form (alphaG3) was most active near pH 7, and was identified as a chloroplastic enzyme. Together, the activity of alphaG1 and alphaG2 in apoplastic preparations accounted for 21% of the total acid alpha-glucosidase activity recovered from pea stems. The vast majority (86%) of the apoplastic acid alpha-glucosidase activity was due to alphaG1. The apparent K(m) values for maltose of alphaG1 and alphaG2 were 0.3 and 1.3 millimolar, respectively. The apparent K(m) for maltose of alphaG3 was 33 millimolar. The respective native molecular weights of alphaG1, alphaG2, and alphaG3 were 125,000, 150,000, and 110,000.

Chloroplastic regulation of apoplastic alpha-amylase activity in pea seedlings.

Photobleaching of pea (Pisum sativum L.) seedling leaves by treatment with norflurazon (San 9789) and 7 days of continuous white light caused a 76- to 85-fold increase in the activity of the primary alpha-amylase, a largely apoplastic enzyme, over normally greening seedlings. Levels of chlorophyll were near zero and levels of plastid marker enzyme activities were very low in norflurazon-treated seedlings, indicating severe photooxidative damage to plastids. As levels of norflurazon or fluence rates were lowered, decreasing photobleaching of tissues, alpha-amylase activity decreased. Levels of leaf beta-amylase and starch debranching enzyme changed very little in norflurazon-treated seedlings. Infiltration extraction of leaves of norflurazon-treated and normally greening seedlings indicated that at least 57 and 62%, respectively, of alpha-amylase activity was in the apoplast. alpha-Amylase activity recovered from the apoplast of photobleached leaves of norflurazon-treated seedlings was 18-fold higher than that for green leaves. Inhibitors of photosynthesis (DCMU and atrazine) and an inhibitor of chlorophyll accumulation that does not cause photooxidation of plastid components (tentoxin) had little effect on levels of alpha-amylase activity, indicating norflurazon-caused loss of chlorophyll and lack of photosynthesis did not cause the large induction in alpha-amylase activity. An inhibitor of both abscisic acid and gibberellin synthesis (paclobutrazol [PP333]) and an analog of norflurazon which inhibits photosynthesis but not carotenoid synthesis (San 9785) caused only moderate (about five-fold) increases in alpha-amylase activity. Lincomycin and chloramphenicol increased alpha-amylase activity in light grown seedings to the same magnitude as norflurazon, indicating that the effect of norflurazon is probably through the destruction of plastid ribosomes. It is proposed that chloroplasts produce a negative signal for the regulation of the apoplastic alpha-amylase in pea.

Characterization of alpha-Amylase from Shoots and Cotyledons of Pea (Pisum sativum L.) Seedlings.

The most abundant alpha-amylase (EC 3.2.1.1) in shoots and cotyledons from pea (Pisum sativum L.) seedlings was purified 6700-and 850-fold, respectively, utilizing affinity (amylose and cycloheptaamylose) and gel filtration chromatography and ultrafiltration. This alpha-amylase contributed at least 79 and 15% of the total amylolytic activity in seedling cotyledons and shoots, respectively. The enzyme was identified as an alpha-amylase by polarimetry, substrate specificity, and end product analyses. The purified alpha-amylases from shoots and cotyledons appear identical. Both are 43.5 kilodalton monomers with pls of 4.5, broad pH activity optima from 5.5 to 6.5, and nearly identical substrate specificities. They produce identical one-dimensional peptide fingerprints following partial proteolysis in the presence of SDS. Calcium is required for activity and thermal stability of this amylase. The enzyme cannot attack maltodextrins with degrees of polymerization below that of maltotetraose, and hydrolysis of intact starch granules was detected only after prolonged incubation. It best utilizes soluble starch as substrate. Glucose and maltose are the major end products of the enzyme with amylose as substrate. This alpha-amylase appears to be secreted, in that it is at least partially localized in the apoplast of shoots. The native enzyme exhibits a high degree of resistance to degradation by proteinase K, trypsin/chymostrypsin, thermolysin, and Staphylococcus aureus V8 protease. It does not appear to be a high-mannose-type glycoprotein. Common cell wall constituents (e.g. beta-glucan) are not substrates of the enzyme. A very low amount of this alpha-amylase appears to be associated with chloroplasts; however, it is unclear whether this activity is contamination or alpha-amylase which is integrally associated with the chloroplast.

Purification and Characterization of Pea Epicotyl beta-Amylase.

The most abundant beta-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 beta-amylase are the same as that of an exoamylase previously reported to be primarily vacuolar. The enzyme was determined to be a beta-amylase by end product analysis and by its inability to hydrolyze beta-limit dextrin and to release dye from starch azure. Pea beta-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 beta-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 alpha-cyclohexaamylose being a stronger inhibitor than beta-cycloheptaamylose. Moderately branched glucans (e.g. amylopectin) were better substrates for pea beta-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 beta-amylase is the multichain type. Possible roles of pea beta-amylase in cellular glucan metabolism are discussed.

Characterization of Pea Chloroplast D-Enzyme (4-alpha-d-Glucanotransferase).

Pea (Pisum sativum L.) chloroplast D-enzyme (4-alpha-d-glucanotransferase, EC 2.4. 1.25) was purified greater than 750-fold and partially characterized. It is a dimer with a subunit M(r) of ca. 50,000. Optimal activity is between pH 7.5 and 8.0 with maltotriose as substrate and the enzyme's K(m) for maltotriose is 3.3 millimolar. Chloroplast D-enzyme converts maltotriose to maltopentaose and glucose via the exchange of alpha-1,4-glycosidic linkages. Maltotriose acts either as a donor or acceptor of a maltosyl group. The enzyme has highest activity with maltotriose as substrate. As initial substrate degree of polymerization is increased to maltoheptaose, D-enzyme activity drops to zero at 10 millimolar substrate concentrations and by 70% at 1 millimolar concentrations. The enzyme cannot use maltose as a substrate. Glucose was found to be a suitable acceptor substrate for this D-enzyme. Addition of glucose to incubation mixtures, or production of glucose by D-enzyme, prevents the synthesis of maltodextrins larger than maltopentaose. Removal of glucose produced by D-enzyme activity with maltotriose as substrate resulted in the synthesis of maltopentaose and maltodextrins with sufficient degrees of polymerization to be suitable substrates for pea chloroplast starch phosphorylase. The possible role of D-enzyme in pea chloroplast starch metabolism is discussed.

Localization of alpha-Amylase in the Apoplast of Pea (Pisum sativum L.) Stems.

Most of the activity of an alpha-amylase present in crude pea (Pisum sativum L. cv Laxton's Progress No. 9) leaf preparations cannot be found in isolated pea leaf protoplasts. The same extrachloroplastic alpha-amylase is present in pea stems, representing approximately 6% of total stem amylolytic activity and virtually all of the alpha-amylase activity. By a simple infiltration-extraction procedure, the majority (87%) of this alpha-amylase activity was recovered from the pea stem apoplast without significantly disrupting the symplastic component of the tissue. Only 3% of the beta-amylase activity and less than 2% of other cellular marker enzymes were removed during infiltration-extraction.

A special group of ultradian oscillations.

Based on results from our studies, including those on leaf movements, circummutations of shoots, levels of enzyme activity, and metabolites, and from an extensive review of the literature, we have identified a special group of ultradian oscillations. Collectively, these oscillations have periods that range from approximately 30 to 240 min. Their patterns seldom exhibit strict periodicity or constant waveform. They have been observed in various animals, human beings, plants, and microorganisms. These oscillations appear to be a ubiquitous phenomenon, present at various levels of organization, e.g., biochemical to behavioral, and provide a unifying paradigm for exploring biological dynamics.

Chloroplast and extrachloroplastic starch-degrading enzymes in Pisum sativum L.

Starch-degrading enzymes in isolated pea (Pisum sativum L. cv. Laxton's Progress No. 9) chloroplasts were investigated and compared with those in crude pea leaf and stipule preparations. End-product analysis of amylopectin degradation by chloroplast and crude extracts indicates that maltose is the major product of both. Two multiforms of ß-amylase (EC 3.2.1.2) were detected in pea chloroplasts using an electrophoretic transfer technique. A starch-debranching enzyme (EC 3.2.1.10) was detected in chloroplasts by electrophoretic transfer and the degradation of pullulan. A different multiform of debranching enzyme was found in crude preparations. α-Amylases (EC 3.2.1.1) were detected by electrophoretic transfer through gels containing starch and starch azure, and by change in viscosity of a starch solution, but were only found in crude preparations indicating an extrachloroplastic location. Incubation of maltotriose with chloroplast extracts gave high levels of glucose production and formation of oligosaccharides with degrees of polymerization larger than that of maltotriose indicating transglycosylase (EC 2.4.1.25) activity. Neither α-glucosidase (EC 3.2.1.20) nor maltose-phosphorylase (EC 2.4.1.1) activity were found in either chloroplast or crude preparations, whereas starch-phosphorylase (EC 2.4.1.1) activity was in both. The possible role of these enzymes in starch degradation by pea chloroplasts is discussed.

Electrophoretic transfer as a technique for the detection and identification of plant amylolytic enzymes in polyacrylamide gels.

An electrophoretic transfer technique was developed for the specific identification of isozymes of starch debranching enzyme, alpha-amylase, and beta-amylase. Amylolytic enzymes are separated by native polyacrylamide slab gel electrophoresis and proteins in gels are electrophoretically transferred through starch-containing polyacrylamide gels. Each amylolytic enzyme degrades starch in the transfer gel to its characteristic limit dextrin as it moves through the gel. Various limit dextrins in the starch gel are identified by their characteristic color development in KI/I solution. Isozymes of starch debranching enzyme, alpha-amylase, and beta-amylase can be easily identified in the same gel.

Differential light induction of nitrate reductases in greening and photobleached soybean seedlings.

Soybean (Glycine max [L.] Merr.) seeds were imbibed and germinated with or without NO(3) (-), tungstate, and norflurazon (San 9789). Norflurazon is a herbicide which causes photobleaching of chlorophyll by inhibiting carotenoid synthesis and which impairs normal chloroplast development. After 3 days in the dark, seedlings were placed in white light to induce extractable nitrate reductase activity. The induction of maximal nitrate reductase activity in greening cotyledons did not require NO(3) (-) and was not inhibited by tungstate. Induction of nitrate reductase activity in norflurazon-treated cotyledons had an absolute requirement for NO(3) (-) and was completely inhibited by tungstate. Nitrate was not detected in seeds or seedlings which had not been treated with NO(3) (-). The optimum pH for cotyledon nitrate reductase activity from norflurazon-treated seedlings was at pH 7.5, and near that for root nitrate reductase activity, whereas the optimum pH for nitrate reductase activity from greening cotyledons was pH 6.5. Induction of root nitrate reductase activity was also inhibited by tungstate and was dependent on the presence of NO(3) (-), further indicating that the isoform of nitrate reductase induced in norflurazon-treated cotyledons is the same or similar to that found in roots. Nitrate reductases with and without a NO(3) (-) requirement for light induction appear to be present in developing leaves. In vivo kinetics (light induction and dark decay rates) and in vitro kinetics (Arrhenius energies of activation and NADH:NADPH specificities) of nitrate reductases with and without a NO(3) (-) requirement for induction were quite different. K(m) values for NO(3) (-) were identical for both nitrate reductases.

Differential leakage of intracellular substances from imbibing soybean seeds.

Leakage of electrolytes, substances absorbing UV light, and enzymic activities from imbibing soybean (Glycine max [L.] Merr.) seeds were compared to determine the extent that passive diffusion and cellular rupture contribute to each. Imbibing seeds with testae removed had average Arrhenius energies of activation (5 to 25 degrees C) of 3.0 and 15.8 kilocalories per mole, respectively, for the leakage of electrolytes and embryo malate dehydrogenase activity. Leakage of embryo enzymes from imbibing seeds was dependent on loss of testa integrity and subsequent loss of cellular membrane integrity or inability to seal preexisting membrane discontinuities. These data suggest that electrolyte leakage from imbibing seeds is primarily by passive diffusion, whereas the diffusion of intracellular macromolecules is primarily dependent on physiological phenomena affecting membrane integrity. Kinetic data and examination of the composition of seed leachates indicated that the leakage of substances absorbing UV light during imbibition is due to both passive diffusion of low molecular weight solutes and macromolecules released from ruptured cells.

Specific Determination of alpha-Amylase Activity in Crude Plant Extracts Containing beta-Amylase.

The specific measurement of alpha-amylase activity in crude plant extracts is difficult because of the presence of beta-amylases which directly interfere with most assay methods. Methods compared in this study include heat treatment at 70 degrees C for 20 min, HgCl(2) treatment, and the use of the alpha-amylase specific substrate starch azure. In comparing alfalfa (Medicago sativa L.), soybeans (Glycine max [L.] Merr.), and malted barley (Hordeum vulgare L.), the starch azure assay was the only satisfactory method for all tissues. While beta-amylase can liberate no color alone, over 10 International units per milliliter beta-amylase activity has a stimulatory effect on the rate of color release. This stimulation becomes constant (about 4-fold) at beta-amylase activities over 1,000 International units per milliliter. Two starch azure procedures were developed to eliminate beta-amylase interference: (a) the dilution procedure, the serial dilution of samples until beta-amylase levels are below levels that interfere; (b) the beta-amylase saturation procedure, addition of exogenous beta-amylase to increase endogenous beta-amylase activity to saturating levels. Both procedures yield linear calibrations up to 0.3 International units per milliliter. These two procedures produced statistically identical results with most tissues, but not for all tissues. Differences between the two methods with some plant tissues was attributed to inaccuracy with the dilution procedure in tissues high in beta-amylase activity or inhibitory effects of the commercial beta-amylase. The beta-amylase saturation procedure was found to be preferable with most species. The heat treatment was satisfactory only for malted barley, as alpha-amylases in alfalfa and soybeans are heat labile. Whereas HgCl(2) proved to be a potent inhibitor of beta-amylase activity at concentrations of 10 to 100 micromolar, these concentrations also partially inhibited alpha-amylase in barley malt. The reported alpha-amylase activities in crude enzyme extracts from a number of plant species are apparently the first specific measurements reported for any plant tissues other than germinating cereals.

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 beta-limit dextrin. The ratio of viscosity change to reducing power production during starch hydrolysis was identical for both alfalfa amylase fractions and sweet potato beta-amylase, while that of bacterial alpha-amylase was considerably higher. The identification of maltose and beta-limit dextrin as hydrolytic end-products confirmed that these alfalfa root amylases are all beta-amylases.The pH optimum for both beta-amylase fractions was 6.0. Both light and heavy beta-amylases showed normal Michaelis-Menten kinetics, with soluble starch as substrate, and had respectively K(m) values of 5.9 and 6.8 milligrams starch per milliliter and V(max) of 640 and 130 international units per milligram protein. Arrhenius plots indicated that the energy of activation for the heavy beta-amylase remained relatively unchanged (12.7 to 13.0 kilocalories per mole) from 0 to 30 degrees C, whereas the energy of activation for the light amylase increased from 12.0 to about 28.0 kilocalories per mole at 8.7 degrees C as temperature was lowered. The light amylase was shown to be inhibited by maltose.

Ultrastructural localization of urate oxidase in nodules of Sesbania exaltata, Glycine max, and Medicago sativa.

The localization of urate oxidase (=uricase, E.C. 1.7.3.3) was determined cytochemically in nodules of Sesbania exaltata (Raf.) Cory, soybean (Glycine max [L.] Merr.) and alfalfa (Medicago sativa [L.] ), using the precipitation of peroxide (produced during the oxidation of urate) by cerium chloride. Cerium perhydroxide reaction product was noted only in the microbodies, a localization consistent with biochemical fractionation studies on urate oxidase. Urate oxidase was present not only in the uninfected cells of the cortical tissue, but also in both infected and interstitial cells in the central tissue, suggesting that at least this enzyme of ureide metabolism is not confined to interstitial cells. Urate oxidase cytochemistry of nodules from alfalfa (Medicago sativa L.), an amide producer, also resulted in microbody staining but the microbodies were infrequently noted in cell profiles.

Role of the testa in preventing cellular rupture during imbibition of legume seeds.

Studies with the seeds of soybean, navy bean, pea, and peanut were made to determine the extent of leakage of intracellular enzymes during imbition. Embryos with intact testae from all four species were found to leak detectable activities of either intracellular enzymes of the cytosol (glucose-6-phosphate dehydrogenase) or enzymes found in both the cytosol and organelles (malate dehydrogenase, glutamate dehydrogenase, glutamate oxaloacetate transaminase, and NADP-isocitrate dehydrogenase) after 6 hours imbition at 25 C. Pea and peanut embryos with testae leaked considerably lower levels of activity for these enzymes than did those of soybean and bean. Leakage of mitochondrial marker enzymes (fumarase, cytochrome c oxidase, and adenylate kinase) was not detected from embryos with testae, suggesting that a differential diffusion of intracellular components out of cells occurred. Soybean and bean embryos without testae leaked high, and proportionally (per cent dry seed basis) similar, levels of all cytosol, cytosol-organelle, and mitochondrial marker enzymes and protein during imbibition, indicating that cell membranes were not differential to leakage and that they had ruptured. Pea and peanut embryos without testae leaked detectable activities of all cytosol and cytosol-organelle enzymes, although fumarase was the only detectable mitochondrial marker enzyme leaked, suggesting that some degree of differential leakage may have occurred in these species. The outermost layers of embryo cells of seeds without testae of all four species absorbed and sequestered the nonpermeating pigment Evan's blue after 5 to 15 minutes imbibition, indicating that membranes had ruptured. This occurred to a much lesser extent in seeds with intact testae. Both soybean and bean embryos without testae were observed to disintegrate during imbibition, whereas those of pea and peanut did not. These data indicate that seeds of certain legumes are susceptible to cellular rupture during imbibition when seed coats are damaged or missing.

Selection and characterization of ethionine-resistant alfalfa (Medicago sativa L.) cell lines.

Diploid alfalfa (HG2), capable of plant regeneration from tissue culture, was used to select variant cell lines resistant to growth inhibition due to ethionine (an analog of methionine). Approximately 10(7) suspension-cultured cells were mutagenized with methane sulfonic acid ethylester and then plated in solid media containing ethionine. Callus colonies formed on media with 0.02 mM ethionine. Of the 124 cell lines recovered, 91 regenerated plants. After six months growth on media without ethionine, 15 of 110 cell lines of callus grew significantly better than HG2 on 1 mM ethionine. Several ethionine-resistant callus cultures were also resistant to growth inhibition due to the addition of lysine + threonine to the media. High concentrations, relative to unselected HG2 callus, of methionine, cysteine, cystathionine, and glutathione were found in some, but not all, ethionine-resistant callus cultures. Cell line R32, which had a ca. tenfold increase in soluble methionine, had a 43% increase in total free amino acids and a 40% increase in amino acids in protein as compared to unselected HG2 callus. Relative amounts of each amino acid in protein were the same in both.