Enzymic mechanism of starch breakdown in germinating rice seeds I. An analytical study

Time-sequence analyses of carbohydrate breakdown in germinating rice seeds shows that a rapid breakdown of starch reserve in endosperm starts after about 4 days of germination. Although the major soluble carbohydrate in the dry seed is sucrose, a marked increase in the production of glucose and maltooligosaccharides accompanies the breakdown of starch. Maltotriose was found to constitute the greatest portion of the oligosaccharides throughout the germination stage. α-Amylase activities were found to parallel the pattern of starch breakdown. Assays for phosphorylase activity showed that this enzyme may account for much smaller amounts of starch breakdown per grain, as compared to the amounts hydrolyzed by α-amylase. There was a transient decline in the content of sucrose in the initial 4 days of seed germination, followed by the gradual increase in later germination stages. During the entire germination stage, sucrose synthetase activity was not detected in the endosperm, although appreciable enzyme activity was present in the growing shoot tissues as well as in the frozen rice seeds harvested at the mid-milky stage. We propose the predominant formation of glucose from starch reserves in the endosperm by the action of α-amylase and accompanying hydrolytic enzyme(s) and that this sugar is eventually mobilized to the growing tissues, shoots or roots.     

Enzymic Mechanism of Starch Breakdown in Germinating Rice Seeds II. Scutellum as the Site of Sucrose Synthesis

In a close parallel to the developmental pattern of α-amylase activity, a rapid increase of maltase activity occurred in the endosperm tissue of germinating rice seeds after about 4 days of the seed imbibition. The overall pattern of the 2 hydrolytic enzyme activities strongly suggest that amylolytic breakdown is the major metabolic route of starch utilization in the germinating rice seeds. Results of the chemical analyses of sugar constituents as well as the measurements of sucrose synthetase activity show that the scutellum is the site of sucrose synthesis in the germinating rice seeds. It is thus supported that glucose derived from the reserve starch in endosperm is transported to scutellum, where it is converted to sucrose. Sucrose is further mobilized to the growing tissues, shoots and roots.     

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

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

Immunohistochemical localization of β-amylase in resting barley seeds

The cellular localization of β-amylase (EC 3.2.1.2) in resting barley seeds was investigated by immunohistochemistry. The monospecificity of the antibodies used was shown by immunoelectrophoresis and western blotting. An adaptation of the immunofluorescence technique allowed the localization of β-amylase. free of autofluorescence, in the different parts of the seed. In endosperm, there was β-amylase protein in aleurone layers, only in the starchy endosperm, where the distribution of the enzyme was not uniform. The β-amylase of starchy endosperm. which can be in a free or a hound form, was mainly localized around starch granules of different sizes. In the embryo. β-amylase was present only in the part of the scutellum in front of the first leaf. By immunoquantitation after separation of the seed parts, its was shown that the ratio between the amounts of enzyme in embryo and endosperm was less than 1/3000.     

Sugar and starch changes in pea cotyledons during germination

Changes in starch and sugar contents in the cotyledons during germination have been compared in a smooth (cv. Alaska) and a wrinkled (cv. Progress) cultivar of the garden pea ( Pisum sativum L.). In both cultivars there was an initial accumulation of sucrose due to the hydrolysis of sucrosyl oligosaccharides, but galactose did not accumulate in the cotyledons. Starch mobilization in the Progress pea was linear with time and started before the rise in α-amylase (EC 3.2.1.1) activity in the cotyledons; sucrose was synthesized in the cotyledons, and their excision from the axis resulted in an additional accumulation of this sugar. In the Alaska pea, the onset of starch hydrolysis coincided with the rise in α-amylase activity; no accumulation of sucrose was found in excised cotyledons, whilst the sucrose content decreased continuously in attached cotyledons.
The same sugars were found in the cotyledons of both cultivars, suggesting a common pathway for starch breakdown. Maltose, maltotriose and linear malto-dextrins were not present and only trace amounts of glucose were detected, suggesting a degradation of starch by phosphorylase after an initial attack by α-amylase. α-Amylase activity in the cotyledons was higher in the presence of the axis, but was influenced by the water content of the cotyledons. Transient changes in α-amylase activity correlated well with changes in the rate of starch hydrolysis, but after 2–3 days starch mobilization was reduced in excised cotyledons probably due to the resynthesis of starch.     

Starch Degradation and Distribution of the Starch-Degrading Enzymes in Vicia faba Leaves (Diurnal Oscillation of Amylolytic Activity and Starch Content in Chloroplasts)

Subcellular localization of the starch-degrading enzymes in Vicia faba leaves was achieved by an electrophoretic transfer method through a starch-containing gel (SCG) and enzyme activity measurements. Total amylolytic and phosphorolytic activities were found predominantly in the extrachloroplastic fraction, whereas the debranching enzymes showed homogenous distribution between stromal and extrachloroplastic fractions. Staining of end products in the SCG revealed two isoforms of [alpha]-amylase (EC 3.2.1.1) and very low [beta]-amylase activity (EC 3.2.1.2) in the chloroplast preparation, whereas [alpha]- and [beta]-amylase exhibited higher activities in the crude extract. However, it is unclear whether the low [alpha]- and [beta]-amylase activities associated with the chloroplast are contamination or activities that are integrally associated with the chloroplast. Study of the diurnal fluctuation of the starch content and of the amylase activities under a 9-h/15-h photoperiod showed a 2-fold increase of the total amylolytic activity in the chloroplasts concurrent with the starch degradation in the dark. No fluctuation was detectable for the extrachloroplastic enzymes. The possible roles and function of the chloroplastic and extrachloroplastic hydrolytic enzymes are discussed.     

Measurement of Metabolites Associated with Nonaqueously Isolated Starch Granules from Immature Zea mays L. Endosperm

Starch granules with associated metabolites were isolated from immature Zea mays L. endosperm by a nonaqueous procedure using glycerol and 3-chloro-1,2-propanediol. The soluble extract of the granule preparation contained varying amounts of neutral sugars, inorganic phosphate, hexose and triose phosphates, organic acids, adenosine and uridine nucleotides, sugar nucleotides, and amino acids. Based on the metabolites present and on information about translocators in chloroplast membranes, which function in transferring metabolites from the chloroplast stroma into the cytoplasm, it is suggested that sucrose is degraded in the cytoplasm, via glycolysis, to triose phosphates which cross the amyloplast membrane by means of a phosphate translocator. It is further postulated that hexose phosphates and sugars are produced from the triose phosphates in the amyloplast stroma by gluconeogenesis with starch being formed from glucose 1-phosphate via pyrophosphorylase and starch synthase enzymes. The glucose 1-phosphate to inorganic phosphate ratio in the granule preparation was such that starch synthesis by phosphorylase is highly unlikely in maize endosperm.     

Nucleoside Diphosphate Sugar-Starch Glucosyl Transferase Activity of wx Starch Granules

Starch granule preparations from the endosperm tissue of all waxy maize (Zea mays L.) mutants tested have low and approximately equal capability to incorporate glucose from adenosine diphosphate glucose into starch. As the substrate concentration is reduced, however, the activity of waxy preparations relative to nonmutant increases until, at the lowest substrate concentration utilized (0.1 μM), the activity of the waxy preparations is nearly equal to that of the nonmutant preparation. The apparent K_m (adenosine diphosphate glucose) for starch granule preparations from wx-C/wx-C/wx-C endosperms was 7.1 × 10⁻⁵ M, which is compared to 3 × 10⁻³ M for preparations from nonwaxy endosperms. Starch granule preparations from three other waxy mutants of independent mutational origin have levels of enzymic activity approximately equal to wx-C at a given substrate concentration giving rise to similar apparent K_m estimates. We conclude that there is in maize endosperm starch granules a second starch granule-bound glycosyl transferase, whose presence is revealed when mutation eliminates activity of the more active glucosyl transferase catalyzing the same reaction.     

Production of α-Amylase by the Ruminal Anaerobic Fungus Neocallimastix frontalis

α-Amylase production was examined in the ruminal anaerobic fungus Neocallimastix frontalis. The enzyme was released mainly into the culture fluid and had temperature and pH optima of 55°C and 5.5, respectively, and the apparent K_m for starch was 0.8 mg ml⁻¹. The products of α-amylase action were mainly maltotriose, maltotetraose, and longer-chain oligosaccharides. No activity of the enzyme was observed towards these compounds or pullulan, but activity on amylose was similar to starch. Evidence for the endo action of α-amylase was also obtained from experiments which showed that the reduction in iodine-staining capacity and release in reducing power by action on amylose was similar to that for commercial α-amylase. Activities of α-amylase up to 4.4 U ml⁻¹ (1 U represents 1 μmol of glucose equivalents released per min) were obtained for cultures grown on 2.5 mg of starch ml⁻¹ in shaken cultures. No growth occurred in unshaken cultures. With elevated concentrations of starch (>2.5 mg ml⁻¹), α-amylase production declined and glucose accumulated in the cultures. Addition of glucose to cultures grown on low levels of starch, in which little glucose accumulated, suppressed α-amylase production, and in bisubstrate growth studies, active production of the enzyme only occurred during growth on starch after glucose had been preferentially utilized. When cellulose, cellobiose, glucose, xylan, and xylose were tested as growth substrates for the production of α-amylase (initial concentration, 2.5 mg ml⁻¹), they were found to be less effective than starch, but maltose was almost as effective. The fungal α-amylase was found to be stable at 60°C in the presence of low concentrations of starch (≤5%), suggesting that it may be suitable for industrial application.     

The Hydrolysis of Endosperm Protein in Zea mays

Degradation of the major storage proteins in maize endosperm, zein and glutelin, begins during the 2nd day of germination. The protein most abundant in the mature endosperm is degraded most rapidly. The patterns of protein loss are essentially similar in germinating seeds and excised endosperms. Cycloheximide, added at the beginning of the incubation period, prevents the development of α-amylase and protease activities and the disappearance of starch and protein reserves. Late additions (70 hours) of cycloheximide still inhibit the increase in hydrolase activity but have no effect on the hydrolysis of storage reserves. The results indicate that the hydrolytic enzymes are synthesized de novo in the maize endosperm.     

The function of the Waxy locus in starch synthesis in maize endosperm

The soluble adenosine diphosphate glucose-starch glucosyltransferase of maize (Zea mays L.) endosperm uses adenosine diphosphate glucose as a sole substrate, but the starch granule-bound nucleoside diphosphate glucose-starch glucosyltransferase utilizes both adenosine diphosphate glucose and uridine diphosphate glucose. The soluble glucosyltransferase can be bound to added amylose or to maize starch granules that contain amylose. However, binding of the soluble enzyme to the starch granules does not change its substrate specificity to that of the natural starch granule-bound glucosyltransferase. Furthermore, the soluble glucosyltransferase bound to starch granules can be removed by repeated washing without a change in specificity. The bound glucosyltransferase can be released by mechanical disruption of starch granules, and the released enzyme behaves in a manner similar to that of the bound enzyme in several respects. These observations suggest that the soluble and bound glucosyltransferases are different enzymes. The starch granule-bound glucosyltransferase activity is linearly proportional to the number of Wx alleles present in the endosperm. This is compatible with the hypothesis that the Wx allele is a structural gene coding for the bound glucosyltransferase, which is important for the normal synthesis of amylose.Journal Paper No. 4818 of the Purdue University Agricultural Experiment Station.     

Production and Characteristics of Raw-Potato-Starch-Digesting α-Amylase from Bacillus subtilis 65

A newly isolated bacterium, identified as Bacillus subtilis 65, was found to produce raw-starch-digesting α-amylase. The electrophoretically homogeneous preparation of enzyme (molecular weight, 68,000) digested and solubilized raw corn starch to glucose and maltose with small amounts of maltooligosaccharides ranging from maltotriose to maltoheptaose. This enzyme was different from other amylases and could digest raw potato starch almost as fast as it could corn starch, but it showed no adsorbability onto any kind of raw starch at any pH. The mixed preparation with Endomycopsis glucoamylase synergistically digested raw potato starch to glucose at 30°C. The raw-potato-starch-digesting α-amylase showed strong digestibility to small substrates, which hydrolyzed maltotriose to maltose and glucose, and hydrolyzed p-nitrophenyl maltoside to p-nitrophenol and maltose, which is different from the capability of bacterial liquefying α-amylase.     

Starch-synthesizing Enzymes in the Endosperm and Pollen of Maize

Two mutations, amylose-extender and waxy, which affect the proportion of amylose and amylopectin of starch synthesized in the endosperm of maize (Zea mays L.) seeds, are also expressed in the pollen. However, most mutations that affect starch synthesis in the maize endosperm are not expressed in the pollen. In an attempt to understand the nonconcordance between the endosperm and pollen, extracts of mature pollen grains were assayed for a number of the enzymes possibly implicated in starch synthesis in the endosperm. Sucrose synthetase (sucrose-UDP glucosyl transferase, EC 2.4.1.13) activity was not detectable in either mature or immature pollen grains of nonmutant maize, but both bound and soluble invertase (EC 3.2.1.26) exhibited much greater specific activity (per milligram protein) in pollen extracts than in 22-day-old endosperm extracts. Phosphorylase (EC 2.4.1.1) activity was also higher in pollen than in endosperm extracts. ADP-Glucose pyrophosphorylase (EC 2.7.7.27) activity was much lower in pollen than endosperm extracts, but mutations that drastically reduced ADP-glucose pyrophosphorylase activity in the endosperm (brittle-2 and shrunken-2) did not markedly affect enzymic activity in the pollen. Specific activities of other enzymes implicated in starch synthesis were similar in endosperm and pollen extracts.     

Biosynthesis of Starch in Proplastids of Germinating Ricinus communis Endosperm Tissue

Electron photomicrographs of endosperm tissue from germinating seed of Ricinus communis L. cv. Hale show proplastids which contain prominent starch grains. The content of starch in endosperm tissue increased from 500 micrograms per seed, in imbibed seed, to 1,100 micrograms per seed in 5-day-old seedlings. The maximum net rate of starch deposition was 1.1 nanomoles glucose incorporated per minute per seed. About 200 micrograms of starch remained in the endosperm 9 days after imbibition. Starch content followed the same developmental pattern as the content of sucrose, free reducing sugars, and other metabolic processes found in this tissue. Two key enzymes of starch synthesis, adenosine diphosphoglucose (ADPG) pyrophosphorylase and ADPG-starch glucosyl transferase (starch synthetase) exhibited maximum activities at 4 and 5 days after germination, respectively. The maximum activity of ADPG pyrophosphorylase was 8.17 nanomoles ADPG formed per minute per seed, whereas starch synthetase exhibited an activity of 125 nanomoles glucose incorporated per minute per seed. These levels of enzyme activity are sufficient to account for the starch synthesis observed. Other enzymes which may be involved in starch synthesis include 3-phosphoglycerate kinase which showed an activity of 8.76 units per seed, triose-P isomerase (2.56 units per seed), fructose-1,6-bisphosphate aldolase (0.99 units per seed), fructose-1,6-bisphosphatase (0.23 units per seed), phosphoglucose isomerase (12.6 units per seed), and phosphoglucomutase (9.72 units per seed). The activities of these enzymes were similar to previously reported values.

Starch synthetase was found in association with the fraction containing proplastids isolated from endosperm tissue. Of the total starch synthetase activity in the endosperm, 38% was particulate. Forty-four% of the total particulate activity of starch synthetase placed on sucrose gradients was associated with the band containing proplastids. The proplastids contained 98% of the ribulose 1,5-bisphosphate carboxylase carboxylase activity placed on the gradient.

     

Starch synthetase: Comparison of UDPG and ADPG as glucosyl donors in immature barley endosperm

Summary The activity of starch synthetase in developing barley endosperm was measured in amyloplasts and in the soluble endosperm fraction by incorporation of radioactively labelled glucose into starch. Both uridine diphosphate glucose (UDPG) and adenosine diphophate glucose (ADPG) were used as glucosyl donors. Enzyme activity was initially located in the soluble fraction, but increasing activity could be detected in the amyloplast fraction during endosperm maturation.     

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.     

Study of the formation and properties of the amylolytic system ofCandida japonica

In the logarithmic phase of growth,Candida japonica produced into media containing soluble starch, maltose or glucose, an amylase hydrolysing starch to glucose, oligosaccharides of the maltose series and dextrins which coloured red with iodine. The presence of calcium carbonate in the medium promoted growth of the culture, but markedly lowered the amylolytic activity of the culture fluid. Paper electrophoretic separation, ionex chromatography on DEAE cellulose and study of substrate specificity and the relationship of activity to the temperature and pH of the medium showed only one enzyme in the crude enzyme preparation. This was a dextrinogenic amylase of the α-amylase type, with greater capacity for breaking down lower homologues of substances of the amylose series, including maltose, than other known α-amylases. The optimum temperature was 55°C, with 20 minutes’ incubation, and the optimal pH was between 5 and 6. The reaction rate of hydrolytic reactions rose with the length of the chain of the substrate. Isomaltotetraose was hydrolysed about 20 times more slowly than maltotetraose. No formation of isomaltose or panose transglucosidation products was found.     

Distribution of enzyme activities within the developing maize (Zea mays) kernel in relation to starch, oil and protein accumulation

The association of enzyme activities in developing kernels with specific storage product accumulation at maturity was analyzed in different parts of Zea mays inbred OH43 kernels. Maize kernels were harvested at 20 and 55 days post-pollination and dissected into basal region, pericarp, embryo, lower endosperm, middle endosperm and upper endosperm. Mature (55 days pos(-pollination) kernel parts were analyzed for starch, total protein, zein and oil content. Immature (20 days post-pollination) kernel parts were assayed for activities of 15 enzymes of sugar and amino acid metabolism. Statistical analyses of the data suggested that glucokinase (EC 2.7.1.2) fructokinase (EC 2.7.1.4) and phosphofructokinase (EC 2.7.1.1 11) activities were primarily associated with oil accumulation, whereas ADP'-glueose pyrophosphorylasc (EC 2.7.7.27) and sucrose synthase (EC 2.4.1.13) activities were associated with starch accumulation. The results suggest that oil biosynthesis utilizes inveitase-mediated sucrose degradation in a pathway not requiring pyrophosphatc. whereas starch biosynthesis utilizes a sucrose synthase-mediated pathway of sucrose degradation in a pathway requiring pyrophosphatc. Additional groups of enzyme activities were associated with each oilier but not with any specific storage product and appeared to be associated with general metabolic activity.     

Dry weight accumulation and starch-synthesis enzymes in grain of cultured ears of three winter wheat varieties

Detached ears of three winter wheat ( Triticum aestivum L.) varieties were cultured in solution for 12 days with sucrose levels varying from 36.5 to 292 m M. The dry weight and starch content of grains increased asymptotically with the sucrose level in the solution. At 4 days of culture, glucose phosphate isomerase (EC 5.3.1.9) activity grain⁻¹ was lower with 36.5 m M than with higher sucrose levels in the medium; at 8 days, adenosinc diphosphoglucose pyrophosphorylase (EC 2.7.7.27) and (soluble plus bound) starch synthase (EC 2.4.1.21) activities grain⁻¹ were higher with 146 and 292 m M sucrose than with 36.5 and 73 m M sucrose. The multiple regression of starch content over these enzyme activities showed that starch synthase was relatively more important as an independent variable. The dry weight and starch content of grains were higher in the variety Maris Huntsman than in Splendeur and Hobbit. The water content of grains was lower in Splendeur than in the other two varieties. At 4 days the glucose phosphate isomerase, adenosine diphosphoglucose pyrophosphorylase and starch synthase activities grain⁻¹ were smaller in Splendeur than in Hobbit and Maris Huntsman and al 8 days they were higher in Maris Huntsman than in Hobbit and Splendeur. The varietal differences in starch content of grains were related to the activities of glucose phosphate isomerase and especially of starch synthase.