Vigna Radiata Seed Germination under Salinity

Salinity reduced mung bean (Vigna radiata Wilczek) radicle and root elongation, delayed and inhibited hypocotyl elongation and mobilization of reserves from the cotyledons to the embryo axis. Fresh and dry masses and water content of the embryo axes were reduced. Under salinity, a net leakage of K to the media increased with time and increasing NaCl concentrations. Sugars present in the cotyledons of seeds were of primary importance for growth of the embryo axis upto 18 h after sowing whereas breakdown of starch by amylase contributed later, the contribution being delayed and reduced with increasing NaCl concentration. Even when amylase activity in the cotyledons was progressively reduced with increasing NaCl concentration, the increasing contents of soluble sugars in the cotyledons indicated that sugars were not limiting for mung bean seedling growth under salinity.     

Pullulanase in mung bean cotyledons. Purification, some properties and developmental pattern during and following germination

Starch debranching enzyme was purified from mung bean ( Vigna radiata ) cotyledons to investigate its properties and developmental pattern during and following germination. A debranching enzyme was purified up to the step where only a doublet of polypeptides with molecular masses of 99 and 101 kDa, respectively, was detected by SDS-PAGE. The enzyme is thought to be a single chain monomer, as the molecular mass of the enzyme determined by gel filtration was 72 kDa. Monoclonal antibodies raised against the purified preparation recognized the doublet, indicating that the two polypeptides have immunological homology to each other. The enzyme preparation showed a high activity with pullulan as a substrate, low activity with soluble starch and amylopectin, and no activity with glycogen. These substrate specificities indicate that the debranching enzyme from mung bean cotyledons is of the pullulanase type. Immunoblotting profiles revealed that the enzyme is present in dry seeds and decreases gradually after imbibition, suggesting the possibility that the pullulanase plays a role in developing mung bean cotyledons.     

Rice α-glucosidase isozymes and isoforms showing different starch granules-binding and -degrading ability

Insoluble starch granules stored in plant seeds have generally been considered to be degraded effectively by the combination of amylolytic enzymes following initial attack by de novo synthesized α-amylase at germination. We have shown that rice (Oryza sativa L., var Nipponbare) α-glucosidase isozymes (ONG1, ONG2, and ONG3) are also capable of binding to and degrading starch granules directly, indicating the direct liberation of glucose from starch granules by α-glucosidase at germination. ONG1 and ONG2 are encoded in a distinct locus of the rice genome, while ONG2 and ONG3 are generated by alternative splicing. Interestingly, each of the α-glucosidase isozymes showed different action toward starch granules. In addition, two ONG2 isoforms were found to be produced by post-translational proteolysis. The proteolysis induced changes in binding to and degradation of starch granules.     

Preparation of clear noodles with mixtures of tapioca and high-amylose starches

Ways to simulate the making of clear noodles from mung bran starch were investigated by studying the molecular structures of mung bean and tapioca starches. Scanning electron micrographs showed that tapioca starch granules were smaller than those of mung bean starch. X-ray diffraction patterns of mung bean and tapioca starch were A- and C_A-patterns, respectively. Iodine affinity studies indicated that mung bean starch contained 37% of apparent amylose and tapioca starch contained 24%. Gel permeation chromatograms showed that mung bean amylopectin had longer peak chain-length of long-branch chains (DP 40) than that of tapioca starch (DP 35) but shorter peak chain-length of short-branch chains (DP 16) than that of tapioca starch (DP 21). P-31 n.m.r. spectroscopy showed that both starches contained phosphate monoesters, but only mung bean starch contained phospholipids. Physical properties, including pasting viscosity, gel strength, and thermal properties (gelatinization), were determined. The results of the molecular structure study and physical properties were used to develop acceptable products using mixtures of cross-linked tapioca and high-amylose maize starches. Tapioca starch was cross-linked by sodium trimetaphosphate (STMP) with various reaction times, pH values, and temperatures. The correlation between those parameters and the pasting viscosity were studied using a visco/amylograph. Starches, cross-linked with 0.1% STMP, pH 11.0, 3.5 h reaction time at 25, 35, and 45°C (reaction temperature), were used for making noodles. High-amylose maize starch (70% amylose) was mixed at varying ratios (9, 13, 17, 28, 37, and 44%) with the cross-linked tapioca starches. Analysis of the noodles included: tensile strength, water absorption, and soluble loss. Noodle sensory properties were evaluated using trained panelists. Noodles made from a mixture of cross-linked tapioca starch and 17% of a high-amylose starch were comparable to the clear noodles made from mung bean starch.     

Studies on α-Glucosidase in Rice

Two kinds of αglucosidase which were homogeneous in disc electrophoretic and ultra-centrifugal analysis were isolated from rice seeds by means of ammonium sulfate fractionation and CM-cellulose, Sephadex G–100 and DEAE-cellulose column chromatography and designated as α-glucosidase I and α-glucosidase II.

Both α-glucosidases hydrolyzed maltose and soluble starch to glucose and showed same optimal pH (4.0) on the both substrates. In addition, both enzymes acted on various α-linked gluco-oligosaccharides and soluble starch but little or not on α-linked hetero-glucosides and α-l,6-glucan (dextran).

Activity of the enzymes on maltose and soluble starch was inhibited by Tris and erythritol. α-Glucosidase II was more sensitive to the inhibitors than α-glucosidase I.

Km value for maltose was 1.1 mM for α-glucosidase I and 2.0 mM for α-glucosidase II.     

Studies on energy status and mitochondrial respiration during growth and senescence of mung bean cotyledons

Several characteristics of mitochondrial respiration and energy status have been studied during growth and senescence of mung bean ( Phaseolus radiatus L.) cotyledons. The results showed that mitochondrial oxygen consumption, respiratory control, ADP:O ratios, and energy charge changed in the cotyledons during germination and growth of the seedlings. The respiration rate of intact cotyledons approximately reflected the trend of the oxidative activities of the isolated mitochondria. An increase was observed in both whole cotyledon respiration and mitochondrial oxygen uptake at the onset of senescence of mung bean cotyledons (day 3 after germination), which thereafter declined gradually. The capacity and activity of the alternative pathway increased markedly in mitochondria isolated from senescent cotyledons. After the onset of senescence, the mung bean cotyledon mitochondria exhibited a decrease both in the respiratory control ratios and ADP:O ratios, and the cotyledons exhibited a gradual decline in energy charge. All these results showed an irreversible deterioration of energy conservation in mung bean cotyledons. The role(s) of the alternative pathway in senescent mung bean cotyledons is discussed.     

Changes in nitrogen content and protein profiles following <Emphasis Type="Italic">in vitro</Emphasis> selection of NaCl resistant mung bean and tomato

Mung bean and tomato were in vitro selected on media containing 0, 25, 50, 100 and 150 mM NaCl. Two types of media (hormone supplemented media, CB and hormone free media, MS) were used for mung bean using cotyledon explants whereas two types of explants (cotyledons and shoot apices) were used for tomato on MS media. Total-N, protein content, nitrite reductase (NiR) activity and protein protein profiles were checked in selected plants and compared to original non selected ones. NaCl at low concentrations slightly increased total-N in shoots and roots of in vitro selected mung bean and tomato whereas higher concentrations induced significant reductions. Similar increases in protein content were detected at lower concentrations with no significant effects thereover. On the contrary, NaCl gradually inhibited NiR activity. Similar responses of total-N, protein and NiR activity, but with greater magnitudes, were detected in original plants. In addition, NaCl significantly reduced dry weights of shoots and roots of either in vitro selected or, in particular, original intact plants. Moreover, electrophoresis (SDS-PAGE) of protein from shoots of either in vitro selected or intact plants showed that NaCl induced new protein bands while some others were concomitantly disappeared. The induction of one or more of the 86.4, 79, 77.6, 77 and 71.5 kDa bands following in vitro selection and/or the disappearance of the 86 kDa band from intact plants seemed necessary for mung bean resistance. Also, the presence of 86.2 kDa band and/or the loss of the 85.8 and 57.5 kDa bands might be included in tomato resistance. Of these induced bands in mung bean selected on CB media, only two bands were detected in plants selected on MS media. In tomato, two bands lost following selection from cotyledons but only one band lost following selection from shoot apices. These changes in protein pattern therefore might serve as adaptive regulators for resistance to NaCl.     

Rapid degradation and limited synthesis of phospholipids in the cotyledons of mung bean seedlings

Seedling growth of mung bean is accompanied by the rapid catabolism of the three major phospholipids in the cotyledons (phosphatidylcholine, phosphatidylethanolamine, and phosphatidylinositol). The decline starts 24 hours after the beginning of imbibition and by the 4th day of growth more than 50% of the phospholipids have been catabolized. Extracts of cotyledons of 24-hour-imbibed beans contain enzymes capable of degrading membrane-associated phospholipids in vitro. This degradation involves phospholipase D and phosphatase activity.     

Enzymes involved in starch synthesis in the developing mung bean seed

The levels of free sugars, starch and enzymes involved in starch metabolism—sucrose synthetase, UDP and ADP glucose pyrophosphorylase, phosphorylase and starch synthetase—were assayed during seed development of three cultivars of mung bean (Vigna radiata). Free sugars and starch increased with increasing seed weight. Changes in levels of sucrose synthetase, UDP- and ADP-glucose pyrophosphorylases, and phosphorylase were paralleled by changes in starch accumulation. After the maximum activity levels of these enzymes had been reached, maximum activities of soluble starch synthetase and starch granule-bound starch synthetase occurred. There were high activities of sucrose synthetase and phosphorylase at maximum rates of starch accumulation. Thus, starch could be synthesized via the ADP glucose pathway in mung bean seeds. However, phosphorylase may account for the starch accumulation in the early stages of mung bean seed development.     

Purification and Properties of α-Glucosidase and Glucoamylase from Lentinus edodes (Berk.) Sing.

An α-glucosidase and a glucoamylase have been isolated from fruit bodies of Lentinus edodes (Berk.) Sing., by a procedure including fractionation with ammonium sulfate, DEAE-cellulose column chromatography, and preparative gel electrofocusing. Both of them were homogeneous on gel electrofocusing and ultracentrifugation. The molecular weight of α-glucosidase and glucoamylase was 51,000 and 55,000, respectively. The α-glucosidase hydrolyzed maltose, maltotriose, phenyl α-maltoside, amylose, and soluble starch, but did not act on sucrose. The glucoamylase hydrolyzed maltose, maltotriose, phenyl α-maltoside, soluble starch, amylose, amylopectin, and glycogen, glucose being the sole product formed in the digests of these substrates. Both enzymes hydrolyzed phenyl a-maltoside into glucose and phenyl α-glucoside. The glucoamylase hydrolyzed soluble starch, amylose, amylopectin, and glycogen, converting them almost completely into glucose. It was found that β-glucose was liberated from amylose by the action of glucoamylase, while α-glucose was produced by the α-glucosidase.

Maltotriose was the main α-glucosyltransfer product formed from maltose by the α-glucosidase.     

A series of cinnamic acid derivatives and their inhibitory activity on intestinal α-glucosidase

Inhibition of α-glucosidase and α-amylase delays the digestion of starch and disaccharides to absorbable monosaccharides, resulting in a reduction of postprandial hyperglycemia. Finding effective mammalian α-glucosidase inhibitors from natural sources can be beneficial in the prevention and treatment of diabetes mellitus. We investigated the inhibitory activity of cinnamic acid derivatives against rat intestinal α-glucosidase and porcine pancreatic α-amylase in vitro. Among 11 cinnamic acid derivatives, caffeic acid, ferulic acid, and isoferulic acid were the most potent inhibitors against intestinal maltase with IC₅₀ values of 0.74?±?0.01, 0.79?±?0.04, and 0.76?±?0.03?mM, respectively, whereas ferulic acid (IC₅₀?=?0.45?±?0.01?mM) and isoferulic acid (IC₅₀?=?0.45?±?0.01?mM) were effective intestinal sucrase inhibitors. However, all cinnamic acid derivatives were found to be inactive in pancreatic α-amylase inhibition. Kinetic analysis revealed that intestinal maltase was inhibited by caffeic acid, ferulic acid, and isoferulic acid in a mixed-inhibition manner. In addition, ferulic acid and isoferulic acid inhibited intestinal sucrase in a mixed type manner, whereas caffeic acid was a non-competitive inhibitor. The combination of isoferulic acid and acarbose showed an additive inhibition on intestinal sucrase. This study could provide a new insight into naturally occurring intestinal α-glucosidase inhibitors that could be useful for treatment of diabetes and its complications.     

Modulation of Chlorophyll, Carotene and Xanthophyll Formation by Penicillin, Benzyladenine and Embryonic Axis in Mung Bean (Phaseolus aureus L.) Cotyledons

Penicillin stimulated the synthesis of pigments in the cotyledonsof intact embryos and excised cotyledons of mung bean (Phaseolusaureus L.) and enhanced benzyladenine-induced accumulation ofchloroplast pigments. The presence of the embryonic axis duringlight exposure proved to be beneficial for chlorophyll synthesisby the cotyledons whereas its presence in dark germination producedan adverse effect. The possible involvement of nucleic acidand protein synthesis in light-regulated chlorophyll formationis suggested. The stimulating effect on pigment synthesis providedby penicillin in this system seems to involve a maintenanceof nucleic acid and protein synthesis. Phaseolus aureus L., mung bean, pigment synthesis, cotyledons     

Phytotoxicity of selected herbicides to mung bean (Phaseolus aureus Roxb.)

Mung bean (Phaseolus aureus Roxb.) is grown after harvest of wheat during the fallow period. Herbicides such as metsulfuron, atrazine and isoxaflutole are recommended to control weeds in wheat–rice cropping system including weeds of fallow crop. The effects of three herbicides with different modes of action—atrazine, photosystem II inhibitor; metsulfuron, acetolactate synthase inhibitor; and isoxaflutole, 4-hydroxyphenylpyruvatedioxygenase inhibitor—on shoot height, chlorophyll concentrations and cellular damage in herbicide-treated mung bean were studied. While isoxaflutole inhibited shoot growth and chlorophyll concentration of mung bean, atrazine and metsulfuron did not cause reduction in the shoot growth of mung bean. Metsulfuron (226, 452, 1356 and 2260 μg/kg soil) and isoxaflutole (452, 1356 and 2260 μg/kg soil) in soil reduced the concentration of leaf chlorophyll of mung bean compared to the control. Atrazine in soil did not affect the total chlorophyll concentration of mung bean leaves. Electron micrographs showed that untreated mung bean had elongated chloroplasts, thylakoids organized as intact grana, distinct starch grains and a small number of plastoglubuli. Mesophyll cells of atrazine-treated mung bean leaves had swollen chloroplasts and thylakoids with disorganized grana. Leaves of metsulfuron-treated mung bean had swollen chloroplasts with a large number of starch grains. Starch grains were not observed in leaves of mung bean treated with either atrazine or isoxaflutole. Complete disruption of thylakoids was observed in isoxaflutole-treated mung bean leaves. Leaves of atrazine-treated mung bean showed detached microfibrils along with distorted and degenerated secondary walls. Metsulfuron-treated mung bean leaves showed aggregated microfibrils with completely dissolved secondary walls, while isoxaflutole-treated leaves had completely degenerated secondary walls with complete loss of microfibrils. We conclude that isoxaflutole at higher doses, influence mung bean at the morphological, physiological and cellular levels.     

The endoplasmic reticulum of mung-bean cotyledons: Quantitative morphology of cisternal and tubular ER during seedling growth

The ultrastructure of the endoplasmic reticulum (ER) in storage parenchyma cells in the cotyledons of mung beans (Vigna radiata L.) was examined during germination and seedling growth. Two different methods were used to visualize the ER: thin (0.08 m) sections of tissue fixed in formaldehyde and glutaraldehyde and post-fixed with osmium tetroxide, and thick (1 m) sections of tissue fixed in buffered aldehyde and post-fixed with zinc iodide-osmium tetroxide (ZIO). Changes in relative amounts of ER were quantified by morphometry (stereology).The ER occurs in two forms: a cisternal form with associated ribosomes which can be seen at all stages from imbibition to cotyledon senescence, and a tubular form which initially has associated ribosomes. Stereoscopic images of thick sections of cotyledons of 2-day-old seedlings show that the tubular ER consists of a three-dimensional array of interconnecting tubules which have numerous connections with the cisternal ER. The network of tubules and cisternae extends throughout the cytoplasm enveloping the protein bodies. Germination and seedling growth are accompanied by a reduction in the total volume occupied by the ER. This reduction is the result of a preferential loss of tubular ER and occurs largely before protein mobilization. Cisternal ER decreases during the first 48 h of imbibition and seedling growth, but storage cells subsequently show an increase in cisternal ER just prior to and during the period of protein mobilization. Cisternal ER remains conspicuous during the last phase of reserve mobilization when starch is broken down and the cells are starting autophagy.Abbreviations ER endoplasmic reticulum - ZIO zinc iodide-osmium tetroxide This is the second in a series of papers on the endoplasmic reticulum of mung bean cotyledons. The first paper is referenced herein as Gilkes and Chrispeels (1980)     

Purification and Properties of Three Forms of α-Glucosidase from Germinated Green Gram (Phaseolus vidissimus Ten.)

Three forms of α-glucosidase have been isolated from 5-day-old green gram (Phaseolus vidissimus Ten.) seedlings, by a procedure including fractionation with ammonium sulfate and polyethylene glycol 6000, DEAE-cellulose column chromatography, SP-Sephadex column chromatography, preparative gel electrofocusing and preparative disc gel electrophoresis. The α-glucosidases isolated were designated as α-glucosidase I, α-glucosidase II–1 and α-glucosidase II–2. They were homogeneous on polyacrylamide disc gel electrophoresis. Their molecular weights were 145,000, 105,000 and 65,000, respectively. The three enzymes hydrolyzed maltose, maltotriose, phenyl α-maltoside, amylose and soluble starch liberating glucose, but did not act on sucrose. Their enzymes hydrolyzed phenyl α-maltoside into glucose and phenyl α-glucoside. They hydrolyzed amylose liberating α-glucose. Maltotriose was the main α-glucosyltransfer product formed from maltose by the three α-glucosidases.     

Comparison of the developmental patterns of mitochondrial malate dehydrogenase between mung bean and cucumber cotyledons during and following germination

The development of mitochondrial NAD⁺-malate dehydrogenase (EC 1.1.1.37) in mung bean and cucumber cotyledons was followed. using the antibody raised against it, during and following germination. The developmental patterns were quite different between the two. In cucumber, the content of mitochondrial malate dehydrogenase continued to increase through 3–4 days after the beginning of imbibition. This was, at least in part, due to active synthesis of the enzyme protein, and the synthesis seemed to be regulated by the availability of the translatable mRNA for the enzyme. In mung bean, on the other hand, the enzyme was present in dry cotyledons at a rather high concentration, and remained at a constant level between day 1 and day 3 after the reduction of the content to one-half its initial level during the first day. De novo synthesis of the enzyme could not be detected in mung bean cotyledons by pulse-labeling experiment.     

The Stereochemistry of Maingayic Acid

Kinetic studies on the active site of pig serum α-glucosidase and buckwheat α-glucosidase catalyzing the hydrolyses of maltose and soluble starch were made. The kinetic features obtained by the experiments with the mixed substrates, the linearity of Lineweaver-Burk plots, and the dependence of the apparent Michaelis constants and the apparent maximal velocities on the fraction f of maltose in the mixed substrate solutions, that is, f=maltose/(maltose + soluble starch), were in good agreement with those expected for the single active site catalyzing the hydrolyses of both substrates. From the results it was concluded that these enzymes attacked maltose and soluble starch by the single active site mechanism.     

Impact of legume seed extracts on degradation and functional properties of gelatin from unicorn leatherjacket skin

Trypsin inhibitor was extracted from the seed flour of soybean (SB; Glycine max), mung bean (MB; Vigna radiata), cowpea bean (CP; Vigna unguiculata) and adzuki bean (AB; Vigna angularis) using 0.15 M NaCl, followed by heat precipitation at 70 °C. The extract from SB showed the highest specific trypsin inhibitory activity, followed by those from MB, CP and AB, respectively. Based on inhibitory activity staining, molecular weights (MWs) of trypsin inhibitor from SB, MB, CP and AB were 20.1, 14, 10 and 13 kDa, respectively. The SB extract powder (SBEP) containing trypsin inhibitor in the range of 10–100 TIU/g effectively prevented the degradation of γ-, β- and α-chains of collagenolytic proteins of leatherjacket skin subjected to incubation at 50 °C for 30 min. The impact of SBEP on the extraction yield, physical and functional properties of gelatin from leatherjacket skin was investigated. The gelatin extracted in the presence of SBEP contained α₁ and α₂ chains as the predominant components with some degradation peptides. FTIR spectra indicated the significant loss of molecular order of triple helix and higher degradation was found in gelatin extracted in the absence of SBEP. Gelatin extracted in the presence of SBEP had the higher gel strength (232.8–268.5 g) than that extracted in the absence of SBEP (90.4 g). Higher foam stability (FS) but lower emulsion stability index (ESI) was observed in the former. Therefore, the addition of SBEP effectively prevented the degradation of gelatin from the skin of unicorn leatherjacket, thereby yielding the gelatin with improved gel strength and foam stability.     

Promotive effect of chrysanthemic acids on adventitious root formation in some plants

Adventitious root formation in excised cucumber (Cucumis sativus L.) cotyledons was significantly promoted by (±)-cis-chrysanthemic acid at 0.006–1.8 mM. The effect of (±)-cis-chrysanthemic acid on indole-3-acetic acid (IAA)-induced rooting was additive. Rooting in excised cucumber cotyledons was significantly promoted by several isomers of chrysanthemic acid and sodium (±)-cis-chrysanthemate at 0.18 mM. Rooting in mung bean (Phaseolus radiatus L.) hypocotyls was also stimulated by the sodium salt at 0.06–0.6 mM. Rooting of kidney bean (Phaseolus vulgaris L.) hypocotyls was also clearly enhanced by sodium (±)-cis-chrysanthemate at 0.18–6 mM.     

The role of alpha-glucosidase in germinating barley grains

The importance of α-glucosidase in the endosperm starch metabolism of barley (Hordeum vulgare) seedlings is poorly understood. The enzyme converts maltose to glucose (Glc), but in vitro studies indicate that it can also attack starch granules. To discover its role in vivo, we took complementary chemical-genetic and reverse-genetic approaches. We identified iminosugar inhibitors of a recombinant form of an α-glucosidase previously discovered in barley endosperm (ALPHA-GLUCOSIDASE97 [HvAGL97]), and applied four of them to germinating grains. All four decreased the Glc-to-maltose ratio in the endosperm 10 d after imbibition, implying inhibition of maltase activity. Three of the four inhibitors also reduced starch degradation and seedling growth, but the fourth did not affect these parameters. Inhibition of starch degradation was apparently not due to inhibition of amylases. Inhibition of seedling growth was primarily a direct effect of the inhibitors on roots and coleoptiles rather than an indirect effect of the inhibition of endosperm metabolism. It may reflect inhibition of glycoprotein-processing glucosidases in these organs. In transgenic seedlings carrying an RNA interference silencing cassette for HvAgl97, α-glucosidase activity was reduced by up to 50%. There was a large decrease in the Glc-to-maltose ratio in these lines but no effect on starch degradation or seedling growth. Our results suggest that the α-glucosidase HvAGL97 is the major endosperm enzyme catalyzing the conversion of maltose to Glc but is not required for starch degradation. However, the effects of three glucosidase inhibitors on starch degradation in the endosperm indicate the existence of unidentified glucosidase(s) required for this process.