Purification of a non-chloroplastic α-glucan phosphorylase from spinach leaves

The non-chloroplastic -glucan phosphorylase (EC 2.4.1.1) from spinach leaves has been purified to homogeneity as revealed by dodecylsulfate gel electrophoresis. Both purification and separation from the chloroplastic phosphorylase were achieved by chromatography on Sepharose-bound dextrin. The chloroplastic phosphorylase did not bind to Sepharose-dextrin and was removed from the column by washing with buffer, as verified by polyacrylamide gel electrophoresis of the buffer eluate and by chromatography of a preparation from isolated intact chloroplasts. The non-chloroplastic phosphorylase did bind to a high extent to Sepharose-dextrin and could be eluted by a dextrin gradient. Based on dodecylsulfate gel electrophoresis and pyridoxal phosphate determination, a molecular weight of about 90,000 was found for the monomer. Molecular-weight determination by porosity density gradient electrophoresis and gel filtration on Sephadex G-200 suggested that the native enzyme is a dimer, as are other phosphorylases.Abbreviations DEAE diethylaminoethyl - EDTA ethylenediamine tetraacetic acid - G1P glucose 1-phosphate - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulphonic acid - PMSF phenylmethyl sulphonyl fluoride - SDS sodium dodecylsulfate - Tris Tris (hydroxymethyl)aminomethane Dedicated to Professor Dr. A. Pirson on the occasion of his 70th birthday     

Multiple forms of α-glucan phosphorylase in banana fruits: Properties and kinetics

Multiple forms of α-glucan phosphorylase isolated from mature banana fruit pulp differ from each other in several respects—pH optimun, temperature optimum, energy of activation, primer specificity, kinetics, and sensitivity towards metal ions, nucleotides, sugar mucleotides, amino acids, glycolytic intermediates, sulfhydryl binding agents, sulfhydryl reagents and phenolics.     

Characterization of multiple forms of α-glucan phosphorylase from Musa paradisiaca fruits

Three forms of α-glucan phosphorylase from mature banana fruit pulp separated by ammonium sulfate fractionation and DEAE-cellulose chromatography were anodic at pH 8·6 on starch gel electrophoresis. The three forms differed in sensitivity to the phenolics extracted from immature and mature banana fruit pulp. Only two forms of the enzyme were detected in immature banana fruit pulp.     

Non-chloroplast α-1,4-glucan phosphorylase from pea leaves: characterization and in situ localization by indirect immunofluorescence

Leaf extracts of Pisum sativum L. contain three forms of α-1,4-glucan phosphorylase (EC 2.4.1.1) activity. One of these (form I) is located outside the chloroplast; the other two reside inside this organelle (Steup, M. and Latzko, E. (1979) Planta 145, 69–75). The extra-chloroplastic enzyme form, which represents the major proportion of the total extractable phosphorylase activity, was purified and characterized. Its in situ location was determined by indirect immunofluorescence performed with cryostat sections of formaldehyde-fixed leaf. By this technique the enzyme was localized in the cytoplasm of mesophyll and guard cells, whereas the other epidermal cells lacked the enzyme. In its kinetic properties, especially glucan specificity, the enzyme was very similar to the cytosolic phosphorylase from spinach leaves; it has a low affinity towards low-molecular-weight glucans but a very high affinity towards branched polysaccharides such as strach and glycogen. The immunological properties of the enzyme and its peptide pattern were determined and compared with those of other plant phosphorylase. The pea phosphorylase form I was immunologically different from the two chloroplastic phosphorylase forms, and it reacted more strongly with antibodies raised against the spinach cytosolic phosphorylase than with those directed against the spinach chloroplastic counterpart. Peptide patterns obtained after cleavage with N-chlorosuccinimide were very similar for the cytosolic spinach and pea leaf phosphorylase forms, suggesting a high degree of homology between both proteins.     

Improved histochemical method for the demonstration of the activity of α-glucan phosphorylase

Summary The activity and localization of -glucan phosphorylase in experimental canine glycogen-depleted heart tissue has been investigated with biochemical and histochemical methods using dextran as enzyme acceptor. Only linear, essentially unbranched, dextrans exhibit acceptor properties; highly branched dextrans are not suitable acceptors for the enzyme. Results of Michaelis-Menten constant measurements for the linear essentially unbranched dextran fractions used, indicate that the affinity of the enzyme for the non-reducing end group of the dextran molecule increases with increasing molecular weight of the acceptor.In the glycogen-depleted tissue of anoxic and ischaemic cardiac musculature there is a gradual inactivation of the enzyme during the ischaemic period. Shortly before total inactivation the affinity of the enzyme, especially for the lower molecular dextran fractions, is greatly reduced. Therefore, for the histochemical demonstration of phosphorylase activity in infarcted areas of the heart it is essential to use as acceptor an unbranched dextran fraction with a high average molecular weight.This investigation was partially supported by a grant from the Netherlands Organization for the Advancement of Pure Research (Z.W.O.).     

Properties of β-glucan synthetase from Saccharomyces cerevisiae

Properties of -glucan synthetase from S. cerevisiae were studied. The enzyme exhibited optimal activity at pH 6.7 and 24 C. Km for UDP-glucose was 0.12mm. Addition of Mg⁺⁺ or Mn⁺⁺ stimulated its activity by 60% and 21% respectively. High concentrations of EDTA and hydroxyquinoline were inhibitory. Glucan synthetase was fully active in cell-free extracts. Small concentrations of trypsin or subtilopeptidase A from Bacillus subtilis, caused only a slight increase in glucosyl transferase activity, but larger concentrations destroyed -glucan synthetase. Acid proteases were neither stimulatory nordestructive. Thus it seemsunlikelythat -glucan synthetase exists in a zymogen form. Glucan synthetase was unstable. It was inactivated more rapidly at 28 C than at 0 C. The presence of substrate, -glucan or the protease inhibitors PMSF, Antipain or Pepstatin A did not protect -glucan synthetase from inactivation. Glucan synthetase was not stimulated by addition of cellobiose or -glucans. The synthesis of -glucans was competitively inhibited by UDP (K_i=0.45mm). Glucono--lactone, a known inhibitor of -glucosidases was a strong non-competitive inhibitor of -glucan synthetase.This work was supported by grants PNCB 00071 and 847 of the Consejo Nacional de Ciencia y Tecnología, México.     

Improved histochemical method for the demonstration of the activity of α-glucan phosphorylase

Summary A modified method for the histochemical demonstration of the activity of -glucan phosphorylase is described. In the histochemical system the enzyme catalyses the synthesis of glycogen by transglucosylation from -d-glucosylphosphate. The incubation medium contains dextran as glucosyl acceptor. Therefore, in contrast with the unmodified method, the new technique is able to demonstrate the activity of phosphorylase in ischaemic glycogen-depleted tissues.     

Recombinant production and biochemical characterization of a hyperthermostable α-glucan/maltodextrin phosphorylase from Pyrococcusfuriosus

Alpha-glucan phosphorylase catalyzes the reversible cleavage of α-1-4-linked glucose polymers into α-D-glucose-1-phosphate. We report the recombinant production of an α-glucan/maltodextrin phosphorylase (PF1535) from a hyperthermophilic archaeon, Pyrococcus furiosus, and the first detailed biochemical characterization of this enzyme from any archaeal source using a mass-spectrometry-based assay. The apparent 98 kDa recombinant enzyme was active over a broad range of temperatures and pH, with optimal activity at 80 °C and pH 6.5–7. This archaeal protein retained its complete activity after 24 h at 80 °C in Tris-HCl buffer. Unlike other previously reported phosphorylases, the Ni-affinity column purified enzyme showed broad substrate specificity in both the synthesis and degradation of maltooligosaccharides. In the synthetic direction of the enzymatic reaction, the lowest oligosaccharide required for the chain elongation was maltose. In the degradative direction, the archaeal enzyme can produce glucose-1-phosphate from maltotriose or longer maltooligosaccharides including both glycogen and starch. The specific activity of the enzyme at 80 °C in the presence of 10 mM maltoheptaose and at 10 mg ml^–1 glycogen concentration was 52 U mg^–1 and 31 U mg^–1, respectively. The apparent Michaelis constant and maximum velocity for inorganic phosphate were 31 ± 2 mM and 0.60 ± 0.02 mM min^–1 µg^–1, respectively. An initial velocity study of the enzymatic reaction indicated a sequential bi-bi catalytic mechanism. Unlike the more widely studied mammalian glycogen phosphorylase, the Pyrococcus enzyme is active in the absence of added AMP.     

Thermophilic α-glucan phosphorylase from Clostridium thermocellum: Cloning,characterization and enhanced thermostability

ORF Cthe0357 from the thermophilic bacterium Clostridium thermocellum ATCC 27405 that encodes a putative α-glucan phosphorylase (αGP) was cloned and expressed in Escherichia coli. The protein with a C-terminal His-tag was purified by Ni²⁺ affinity chromatography; the tag-free protein obtained from a cellulose-binding module–intein–αGP fusion protein was purified through affinity adsorption on amorphous cellulose followed by intein self-cleavage. Both purified enzymes had molecular weights of ca. 81,000 and similar specific activities. The optimal conditions were pH 6.0–6.5 and 60 °C for the synthesis direction and pH 7.0–7.5 and 80 °C for the degradation direction. This enzyme had broad substrate specificities for different chain length dextrins and soluble starch. The thermal inactivation of this enzyme strongly depended on temperature, protein concentration, and certain addictives that were shown previously to benefit the protein thermostability. The half lifetime of 0.05 mg αGP/mL at 50 °C was extended by 45-fold to 90 h through a combined addition of 0.1 mM Mg²⁺, 5 mM DTT, 1% NaCl, 0.1% Triton X-100, and 1 mg/mL BSA. The enzyme with prolonged stability would work as a building block for cell-free synthetic enzymatic pathway biotransformations, which can implement complicated biocatalysis through assembly of a number of enzymes and coenzymes.     

Rice endosperm-specific plastidial α-glucan phosphorylase is important for synthesis of short-chain malto-oligosaccharides

Previous genetic studies have indicated that the type L α-glucan phosphorylase (Pho1) has an essential role during the initiation process of starch biosynthesis during rice seed development. To gain insight into its role in starch metabolism, we characterized the enzymatic properties of the Pho1 recombinant form. Pho1 has significantly higher catalytic efficiency toward both linear and branched α-glucans in the synthesis direction than in the degradation direction with equilibrium constants for the various substrates ranging from 13 to 45. Pho1 activity is strongly inhibited by its own reaction product (Pi) in the synthesis reaction (K_i = 0.69 mM) when amylopectin is the primer substrate, but this inhibition is less pronounced (K_i = 14.2 mM) when short α-glucan chains are used as primers. Interestingly, even in the presence of Pi alone, Pho1 not only degrades maltohexaose but also extends them to synthesize longer MOSs. Production of a broad spectrum of MOSs (G4-G19) was stimulated by both Pi and Glc1P in an additive fashion. Thus, even under physiological conditions of high Pi/Glc1P, Pho1 extends the chain length of short MOSs which can then be used as subsequent primer by starch synthase activities. As ADP-glucose strongly inhibits Pho1activity, Pho1 likely operates only during the initial stage and not during maturation phase of starch synthesis.     

Properties and synthesis de novo of auxin-induced α-amylase in pea cotyledons

Analysis of starch-degrading enzymes in a crude extract of detached cotyledons of Pisum sativum L. by polyacrylamide gel electrophoresis (PAGE) demonstrated the presence of one band of -amylase (EC 3.2.1.1) activity. The activity of only this amylase was promoted in cotyledons incubated with 2,4-dichlorophenoxyacetic acid (2,4-D). The auxin-induced -amylase from pea cotyledons was purified to homogeneity, as judged by the criterion of a single band after PAGE. The relative molecular mass (M_r), estimated by gel filtration, was approx. 42 000 and the enzyme contained no carbohydrate moiety. Sodium dodecylsulfate-PAGE yielded a single band that corresponded to an M_r of 41 000. The isoelectric point was 5.85 and the aminoacid composition was similar to that of -amylase from other plants. When [³H]leucine was fed to detached dry cotyledons prior to incubation, the radioactivity in -amylase from cotyledons incubated in the presence of 2,4-D was found to be approx. 10-fold higher than that from cotyledons incubated in distilled water. When -amylase from cotyledons incubated with ²H₂O that contained 2,4-D and the tritiated amylase were centrifuged together in a CsCl density gradient, the peak of enzymatic activity of deuterated -amylase was shifted to a denser fraction than the peak of radioactivity of the tritiated enzyme. These results show that auxin-induced -amylase in pea cotyledons is synthesized de novo.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - M_r relative molecular mass - PAGE polyacrylamide gel electrophoresis - PAS periodic acid-Schiff - pI isoelectric point - SDS sodium dodecyl sulfate We are very grateful to Mr. Kazuo Itoh and Mrs. Matsumi Doe for carrying out the analysis of amino-acid composition.     

Isolation of α-glucan and lipopolysaccharide fractions from Acetobacter xylinum

A cellular phenol-water extract of Acetobacter xylinum NRC 17007 was fractionated on Sepharose 4 B. The fraction eluting with the void volume consisted to about 95% of glycogen-like material. The lipopolysaccharide fraction was of lower molecular weight and had the following composition (%, w/w): Mannose, 42; glucose, 7; galactose, 3.8; heptose, 2; 2-keto-3-deoxy-octonate, 1.2; glucosamine, 3.3; phosphate, 4.5; total fatty acids, 3.9. Among the fatty acids, 3-hydroxy-tetradecanoic acid was present, and 2-hydroxy-hexadecanoic acid predominated.     

Certain Properties of α-Glucosidase from Mucor racemosus

The substrate and inhibitor specificities, and α-glucosyltransfer products of the purified α-glucosidase from the mycelia of Mucor racemosus were investigated. The enzyme hydrolyzed maltose, maltotriose, phenyl α-maltoside, isomaltose, soluble starch, and amylose liberating glucose, but did not act on sucrose. The enzyme hydrolyzed phenyl a-maltoside into glucose and phenyl α-glucoside. Maltotriose was the main a-glucosyltransfer product formed from maltose, and isomaltose was that from soluble starch. Tris and turanose inhibited the enzyme activity, but PCMB and EDTA did not. The enzyme hydrolyzed amylose liberating a-glucose. The enzyme was a glycoprotein containing 4.1% of neutral sugar. The neutral sugar was identified as mannose in the acid hydrolyzate of the enzyme.     

Properties of Crystalline α-Glucosidase from Mucor javanicus

Substrate and inhibitor specificities, and transglucosylation action of crystalline α-glucosidase from the mycelia of Mucor javanicus have been investigated. The enzyme hydrolyzed maltose, methyl-α-maltoside, and soluble starch liberating glucose, but little or not phenyl-α-glucoside, methyl-α-glucoside, sucrose, isomaltose, panose and dextran. The enzyme hydrolyzed phenyl-α-maltoside to glucose and phenyl-α-glucoside. The enzyme acted also as a glucosyltransferase when it was incubated with glucosyl donor such as maltose. Maltotriose was the principal transglucosylation product formed from maltose. The enzyme also catalyzed transglucosylation from maltose to riboflavin, pyridoxine, esculin and rutin. Tris and turanose inhibited the enzyme activity, but PCMB and EDTA did not. It is suggested that the enzyme activity is closely related to the histidine residue in the active center, from the inhibition experiments using diazonium-1-H-tetrazole and rose bengal.     

α-1,4-glucan phosphorylase forms from leaves of spinach (Spinacia oleracea L.)

Peptide patterns and immunological properties of the cytoplasmic and chloroplastic -1,4-glucan phosphorylase (EC 2.4.1.1) from spinach leaves have been studied and were compared with those of phosphorylases from other sources. The two spinach leaf phosphorylases were immunologically different; a limited cross-reactivity was observed only at high antigen or antibody concentrations. Peptide mapping of the two enzymes resulted in complex patterns composed of more than 20 fragments; but no peptide was electrophoretically identical in both proteins. Approximately 13 to 15 of the fragments exhibited antigeneity but no cross-reactivity of any peptide was observed. Therefore, the two compartment-specific phosphorylase forms from spinach leaves represent isoenzymes possessing different primary structures. Peptide patterns of potato tuber and rabbit muscle phosphorylase were different from those of the two spinach leaf enzymes. Although the potato tuber phosphorylase resides in the plastidic compartment and is kinetically closely related to the chloroplastic spinach enzyme, it reacted more strongly with the anti-cytoplasmic-phosphorylase immunoglobulin G. Similar results were obtained with rabbit muscle phosphorylase. These observations support the assumption that the chloroplast-specific phosphorylase isoenzyme has a higher structural diversity than does the cytoplasmic counterpart.Abbreviations EDTA ethylenediaminetetraacetic acid - Hepes 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid - PEG polyethylene glycol (approx. MW 8000) I=Schächtele and Steup 1986     

Purification and Properties of α-Glucosidase from Bacillus cereus

α-Glucosidase has been isolated from Bacillus cereus in ultracentrifugally and electrophoretically homogeneous form, and its properties have been investigated. The enzyme has a sedimentation constant of 1.4 S and a molecular weight of 12,000. The highly purified enzyme splits α-d-(1→4)-glucosidic linkages in maltose, maltotriose, and phenyl α-maltoside, but shows little or no activity toward polysaccharides, such as amylose, amylopectin, glycogen and soluble starch. The enzyme has α-glucosyltransferase activity, the main transfer product from maltose being maltotriose. The enzyme can also catalyze the transfer of α-glucosyl residue from maltose to riboflavin. On the basis of inhibition studies with diazonium-1-H-tetrazole, rose bengal and p-chloromercuribenzoate, it is assumed that the enzyme contains both histidine and cysteine residues in the active center.     

Certain Properties of Crystalline α-Glucosidase from Mucor javanicus

The crystalline α-glucosidase from Mucor javanicus has a sedimentation constant () of 6.1 S, a diffusion constant (D_{20, w}) of 4.8 × 10^?7 cm² · sec^?1, and an average molecular weight, as determined by two different methods, of 124,600. The α-glucosidase is a glycoprotein containing the following constituents; tryptophan₂₃, lysine₈₁, histidine₃₉, arginine₃₄, aspartic acid₁₀₂, threonine₆₉, serine₄₆, glutamic acid₇₈, proline₅₅, glycine₇₈, alanine₅₅, half cystine₈, valine₅₃, methionine₁₇, isoleucine₅₈, leucine₈₁, tyrosine₅₁, phenylalanine₄₁, glucosamine₁₂, and mannose₃₈.

The low content of half cystine, the high contents of aspartic acid, lysine, and histidine, and the presence of mannose as the sole constituent of neutral sugar are the characteristics of this enzyme.     

Properties of α-l-iduronidase in cultured skin fibroblasts from α-l-iduronidase-deficient patients

Summary On DEAE cellulose column chromatography, -l-iduronidase in cultured skin fibroblasts was resolved into two distinct components, forms A and B. They had similar K_m values for 4-methylumbelliferyl--l-iduronide, but differed in pH optima and thermal stability. Form B was more heat-stable than form A.Residual -l-iduronidase activity in Hurler fibroblasts was heat-stable, while that in Scheie fibroblasts was heat-labile, and moreover, that in Hurler-Scheie compound fibroblasts lay intermediate between Hurler and Scheie syndromes. These findings demonstrated that Hurler syndrome, Scheie syndrome and Hurler-Scheie compound were enzymatically distinguishable.