Detection of pullulanase in polyacrylamide gels using pullulan-reactive red agar plates

After electrophoresis, active pullulanase bands in acrylamide gels have been detected by overlaying and then incubating the gel on a replica gel containing 2.5% pullulan-reactive red conjugate and 2.1% agar. The enzyme activity is revealed as a clear band against a red background on the replica gel. The sensitivity of the replica plate is such that 0.0012 unit of Klebsiella aerogenes pullulanase can be detected easily. This procedure is effective in enzyme screening to distinguish pullulanase from other carbohydrases.     

Selective procedure for isolation of microorganisms producing pullulanase and isoamylase

Selective isolation of microorganisms producing pullulanase and isoamylase was accomplished using a two plate detection assay which distinguished both activities and excluded microorganisms producing other extracellular amylases. Over 115,000 colonies tested, 190 strains producing pullulanase and 57 strains producing isoamylase were isolated; extracellular activities of isolated strains were 0.2 to 4.2 and 0.5 to 2.1 nkat/ml of culture, respectively.This paper is dedicated to Prof. Dr. Raúl E. Trucco, in occasion of his 75th anniversary.     

The Starch-Debranching Enzymes Isoamylase and Pullulanase Are Both Involved in Amylopectin Biosynthesis in Rice Endosperm

The activities of the two types of starch debranching enzymes, isoamylase and pullulanase, were greatly reduced in endosperms of allelic sugary-1 mutants of rice (Oryza sativa), with the decrease more pronounced for isoamylase than for pullulanase. However, the decrease in isoamylase activity was not related to the magnitude of the sugary phenotype (the proportion of the phytoglycogen region of the endosperm), as observed with pullulanase. In the moderately mutated line EM-5, the pullulanase activity was markedly lower in the phytoglycogen region than in the starch region, and isoamylase activity was extremely low or completely lost in the whole endosperm tissue. These results suggest that both debranching enzymes are involved in amylopectin biosynthesis in rice endosperm. We presume that isoamylase plays a predominant role in amylopectin synthesis, but pullulanase is also essential or can compensate for the role of isoamylase in the construction of the amylopectin multiple-cluster structure. It is highly possible that isoamylase was modified in some sugary-1 mutants such as EM-273 and EM-5, since it was present in significant and trace amounts, respectively, in these mutants but was apparently inactive. The results show that the Sugary-1 gene encodes the isoamylase gene of the rice genome.     

Molecular cloning and biochemical characterization of a heat-stable type I pullulanase from Thermotoga neapolitana

The gene encoding a type I pullulanase from the hyperthermophilic anaerobic bacterium Thermotoga neapolitana (pulA) was cloned in Escherichia coli and sequenced. The pulA gene from T. neapolitana showed 91.5% pairwise amino acid identity with pulA from Thermotoga maritima and contained the four regions conserved in all amylolytic enzymes. pulA encodes a protein of 843 amino acids with a 19-residue signal peptide. The pulA gene was subcloned and overexpressed in E. coli under the control of the T7 promoter. The purified recombinant enzyme (rPulA) produced a 93-kDa protein with pullulanase activity. rPulA was optimally active at pH 5-7 and 80°C and had a half-life of 88 min at 80°C. rPulA hydrolyzed pullulan, producing maltotriose, and hydrolytic activities were also detected with amylopectin, starch, and glycogen, but not with amylose. This substrate specificity is typical of a type I pullulanase. Thin layer chromatography of the reaction products in the reaction with pullulan and aesculin showed that the enzyme had transglycosylation activity. Analysis of the transfer product using NMR and isoamylase treatment revealed it to be α-maltotriosyl-(1,6)-aesculin, suggesting that the enzyme transferred the maltotriosyl residue of pullulan to aesculin by forming α-1,6-glucosidic linkages. Our findings suggest that the pullulanase from T. neapolitana is the first thermostable type I pullulanase which has α-1,6-transferring activity.     

Analyses of isoamylase gene activity in wild-type barley indicate its involvement in starch synthesis

The notion of debranching enzyme activity as a participant in starch synthesis is gaining acceptance. Inconsistent reports from mutant analyses implicate either isoamylase or pullulanase as a determinant in amylopectin formation and whether wild-type plants utilize one or the other, or both, of these debranching enzymes in starch synthesis is unclear. Recent results on the su1 mutant in maize suggest that both forms of debranching enzymes might be involved in amylopectin formation. We wished to find out if isoamylase takes part in starch synthesis by comparing isoamylase gene activity under three conditions: (1) during starch accumulation in developing sink tissues; (2) during starch degradation in germinating seeds; (3) in ectopic expression after applying sucrose, a starch precursor. We isolated the gene for barley isoamylase, iso1, and analysed its expression and regulation in germinating seeds, developing endosperm and vegetative tissues, and compared the isoamylase gene expression in sink tissues from three different species. Our results indicate that isoamylase gene activity is involved in starch synthesis in wild-type plants and is modulated by sucrose.     

Cloning and nucleotide sequence of the isoamylase gene from Pseudomonas amyloderamosa SB-15

The gene (iam) coding for isoamylase (glycogen 6-glucanohydrolase) of Pseudomonas amyloderamosa SB-15 was cloned. Its nucleotide sequence contained an open reading frame of 2313 nucleotides (771 amino acids) encoding a precursor of secreted isoamylase. The precursor contained a signal peptide of 26 amino acid residues at its amino terminus and three regions homologous with those conserved in alpha-amylases (1,4-alpha-D-glucan 4-glucanohydrolase) of species ranging from prokaryotes to eukaryotes. These homologous regions were also found in another debranching enzyme, pullulanase (pullulan 6-glucanohydrolase) from Klebsiella aerogenes. Sequences of the isoamylase also showed significant homology with those between positions 300 and the carboxyl terminus of pullulanase. The regions required for the specificity of isoamylase were discussed on the basis of a comparison of its amino acid sequence with those of alpha-amylases, cyclomaltodextrin glucanotransferases, and pullulanase.     

Studies on carbohydrate-metabolising enzymes Part XXVII. A comparison of the action of yeast isoamylase and bacterial pullulanase on amylopectin

The action of purified yeast isoamylase on amylopectin, like that of bacterial pullulanase, results in the hydrolysis of the outermost inter-chain linkages with the liberation of linear maltosaccharides having an average degree of polymerisation of approximately 15 -glucose residues. This hydrolytic action distinguishes yeast isoamylase from yeast amylo-(1→6)-glucosidase, which acts by a combination of transferase and glucosidase activities. The products of enzyme action on amylopectin are discussed in relation to the probable molecular structure of the polysaccharide.     

Action of Pseudomonas isoamylase on various branched oligo- and poly-saccharides

Pseudomonas isoamylase (EC 3.2.1.68) hydrolyzes (1 → 6)-α-D-glucosidic linkages of amylopectin, glycogen, and various branched dextrins and oligosaccharides. The detailed structural requirements for the substrate are examined qualitatively and quantitatively in this paper, in comparison with the pullulanase of Klebsiella aerogenes. As with pullulanase. Ps. isoamylase is unable to cleave D-glucosyl stubs from branched saccharides. Ps. isoamylase differs from pullulanase in the following characteristics: (1) The favored substrates for Ps. isoamylase are higher-molecular-weight polysaccharides. Most of the branched oligosaccharides examined were hydrolyzed at a lower rate, 10% or less of the rate of hydrolysis of amylopectin. (2) Maltosyl branches are hydrolyzed off by Ps. isoamylase very slowly in comparison with maltotriosyl branches. (3)Pr. isoamylase requires a minimum of three D-glucose residues in the B- or C-chain.     

Antisense inhibition of isoamylase alters the structure of amylopectin and the physicochemical properties of starch in rice endosperm

This is the first report on regulation of the isoamylase1 gene to modify the structure of amylopectin and properties of starch by using antisense technology in plants. The reduction of isoamylase1 protein by about 94% in rice endosperm changed amylopectin into a water-insoluble modified amylopectin and a water-soluble polyglucan (WSP). As compared with wild-type amylopectin, the modified amylopectin had more short chains with a degree of polymerization of 5-12, while their molecular sizes were similar. The WSP, which structurally resembled the phytoglycogen in isoamylase-deficient sugary-1 mutants, accounted for about 16% of the total alpha-polyglucans in antisense endosperm, and it was distributed throughout the whole endosperm unlike in sugary-1 mutant. The reduction of isoamylase activity markedly lowered the gelatinization temperature from 54 to 43 degrees C and the viscosity, and modified X-ray diffraction pattern and the granule morphology of the starch. The activity of pullulanase, the other type of starch debranching enzyme, in the antisense endosperm was similar to that in wild-type, whereas it is deficient in sugary-1 mutants. These results indicate that the isoamylase1 is essential for amylopectin biosynthesis in rice endosperm, and that alteration of the isoamylase activity is an effective means to modify the physicochemical properties and granular structure of starch.     

Biochemical and genetic analysis of the effects of amylose-extender mutation in rice endosperm

Biochemical analysis of amylose-extender (ae) mutant of rice (Oryza sativa) revealed that the mutation in the gene for starch-branching enzyme IIb (BEIIb) specifically altered the structure of amylopectin in the endosperm by reducing short chains with degree of polymerization of 17 or less, with the greatest decrease in chains with degree of polymerization of 8 to 12. The extent of such change was correlated with the gelatinization properties of the starch granules, as determined in terms of solubility in urea solution. The ae mutation caused a dramatic reduction in the activity of BEIIb. The activity of soluble starch synthase I (SSI) in the ae mutant was significantly lower than in the wild type, suggesting that the mutation had a pleiotropic effect on the SSI activity. In contrast, the activities of BEI, BEIIa, ADP-Glc pyrophosphorylase, isoamylase, isoamylase, pullulanase, and Suc synthase were not affected by the mutation. Therefore, it is stressed that the function of BEIIb cannot be complemented by BEIIa and BEI. These results strongly suggest that BEIIb plays a specific role in the transfer of short chains, which might then be extended by SS to form the A and B(1) chains of amylopectin cluster in rice endosperm.     

Multiple branching in glycogen and amylopectin

The β-amylase limit dextrins of glycogen and amylopectin are completely debranched by joint action of isoamylase and pullulanase. Action of isoamylase alone results in incomplete debranching as a consequence of the inability of this enzyme to hydrolyze those A-chains that are two glucose units in length (half the total number of A-chains). From the reducing powers released by isoamylase acting (a) alone and (b) in conjunction with pullulanase, the relative numbers of A- (unsubstituted) and B- (substituted) chains in the β-dextrins, and therefore in the native polysaccharides themselves, can be calculated. Examination of a series of glycogens and amylopectins in this way showed that the ratio of A-chains: B-chains is markedly higher in amylopectins (1.5–2.6:1) than in glycogens (0.6–1.2:1). Glycogen typically contains A-chains and B-chains in approximately equal numbers; amylopectin typically contains approximately twice as many A-chains as B-chains. These polysaccharides therefore differ in degree of multiple branching as well as in average chain length. A consequence of these findings is that amylopectin cannot be formed in vivo by debranching of a glycogen precursor, as proposed by Erlander, since it is impossible to increase the A:B chain ratio by action of a debranching enzyme.     

Purification of pullulanase from <Emphasis Type="Italic">Aureobasidium pullulan</Emphasis>s

Purification and characterization of pullulanase from Aureobasidium pullulans. Pullulanase was purified by using gel—filtration column then on ion exchange using Q-sepharose column yielding a single peak. Purification was further carried out on SP-sepharose column. Molecular weight of pullulanase from A. pullulans was found to be about 73 KDa on the SDS-PAGE 10%. Native-PAGE 10% showed the activity of pullulanase, using polyacrylamide gel containing pullulan. Hydrolysis products from pullulanase activity with soluble starch, glycogen and pullulan on thin layer chromatography appeared as one band which is maltotriose, while α-amylase with soluble starch and glycogen showed two bands which are maltose and maltotriose but α-amylase gave negative result with pullulan on TLC chromatography only. Pullulanase could degrade α-1,6 glycosidic linkage of the previous substrates, while amylase could degrade α-1,4 glycosidic linkage of glycogen, soluble starch and pullulan. MALDI-Ms was employed to deduce protein sequence of pullulanase.     

Purification,Crystallization and Some Properties of Intracellular Pullulanase from Aerobacter aerogenes

Intracellular pullulanase was entirely extracted with sodium dodecylsulfate from the cells and was purified by means of ammonium sulfate fractionation and DEAE-cellulose and Sephadex chromatography. Crystalline pullulanase was precipitated with saturated ammonium sulfate solution. Intracellular pullulanase was purified over 150 fold in 17% yield to a final specific activity of 7000 per mg protein from the enzyme solution obtained by SDS-extraction. On ultracentrifugation analysis, the enzyme showed a symmetrical peak. The sedimentation coefficient, s_{20, w} was 6.29 S. Polyacrylamide disc electrophoresis gave a main band and a sub-band, and both showed activity. Molecular weight of intracellular pullulanase was estimated to be (8±1) × 10,000 from gel filtration with Sephadex G-200 and to be (9±1) × 10,000 from sedimentation equilibrium. These values were higher than that (6~7 × 10,000) of extracellular pullulanase. Both enzymes differed slightly in thermal- and pH-stabilities.     

A novel type I thermostable pullulanase isolated from a thermophilic starch enrichment culture

In this paper we report identification, cloning and characterization of a novel thermostable pullulanase type I. Pullulanase AmyA1 was detected in a sample of extracellular proteins of thermophilic enrichment culture, growing on starch. The zone of enzymatic activity in zymogram was aligned with the corresponding band on the equivalent gel without substrate. The band was excised from SDS/polyacrylamide gel and subjected to liquid chromatography/mass spectrometry (LC/MS) analysis. LC/MS-based analysis identified thermostable pullulanases, homologues to type I pullulanases of Geobacillus thermodenitrificans NG80-2 and Geobacillus sp. G11MC16. Nucleotide sequences of these two pullulanases were used for design of primers for PCR with DNA from enrichment culture, leaded to 2181 bp PCR product, coding a 726 amino acids protein, named pullulanase AmyA1. Molecular weight of AmyA1 was calculated to be 81.7 kDa. AmyA1 was cloned and expressed in Escherichia coli. Recombinant pullulanase was purified by two chromatographic separation steps. Pullulanase AmyA1 was active against pullulan, glycogen and soluble starch. It was active in the temperature range of 4–95°C, optimum temperature was determined to be 60°C. The highest activity of the recombinant pullulanase was observed at pH 6. Divalent cations Mg²⁺ and Mn²⁺ as well as dithiothreitol, Brij 35 and Brij 58 had a stimulating effect on the enzymatic activity. Pullulanase AmyA1 was stable during incubation in the presence of 4 M urea. After removal of the His-tag, addition of Ca²⁺ stimulated activity of the enzyme suggesting the native pullulanase activity to be dependent on Ca²⁺. Thermostability of AmyA1 was not enhanced by the addition of Ca²⁺.     

Crystal structure of pullulanase: evidence for parallel binding of oligosaccharides in the active site

The crystal structures of Klebsiella pneumoniae pullulanase and its complex with glucose (G1), maltose (G2), isomaltose (isoG2), maltotriose (G3), or maltotetraose (G4), have been refined at around 1.7-1.9A resolution by using a synchrotron radiation source at SPring-8. The refined models contained 920-1052 amino acid residues, 942-1212 water molecules, four or five calcium ions, and the bound sugar moieties. The enzyme is composed of five domains (N1, N2, N3, A, and C). The N1 domain was clearly visible only in the structure of the complex with G3 or G4. The N1 and N2 domains are characteristic of pullulanase, while the N3, A, and C domains have weak similarity with those of Pseudomonas isoamylase. The N1 domain was found to be a new type of carbohydrate-binding domain with one calcium site (CBM41). One G1 bound at subsite -2, while two G2 bound at -1 approximately -2 and +2 approximately +1, two G3, -1 approximately -3 and +2 approximately 0', and two G4, -1 approximately -4 and +2 approximately -1'. The two bound G3 and G4 molecules in the active cleft are almost parallel and interact with each other. The subsites -1 approximately -4 and +1 approximately +2, including catalytic residues Glu706 and Asp677, are conserved between pullulanase and alpha-amylase, indicating that pullulanase strongly recognizes branched point and branched sugar residues, while subsites 0' and -1', which recognize the non-reducing end of main-chain alpha-1,4 glucan, are specific to pullulanase and isoamylase. The comparison suggested that the conformational difference around the active cleft, together with the domain organization, determines the different substrate specificities between pullulanase and isoamylase.     

Cell-associated pullulanase from Bacteroides thetaiotaomicron: cloning, characterization, and insertional mutagenesis to determine role in pullulan utilization.

We have cloned a pullulanase gene from Bacteroides thetaiotaomicron. The pullulanase expressed from this clone in Escherichia coli was cell associated and soluble and had a molecular mass of 72 kilodaltons by gel filtration. Maxicell analysis of proteins coded by the cloned insert showed that a 71.6- to 73.2-kilodalton doublet was associated with pullulanase activity. Thus, the pullulanase is probably a monomer. The cloned pullulanase produced maltotriose as an end product of pullulan digestion. In B. thetaiotaomicron the pullulanase activity was cell associated. Approximately 80% of the activity was soluble, and 16 to 18% was membrane associated. The molecular mass of the soluble pullulanase was 77 kilodaltons by gel filtration. To determine whether the cloned pullulanase gene was essential for pullulan utilization, we used directed insertional mutagenesis to inactivate the B. thetaiotaomicron pullulanase gene. The pullulanase specific activity of the mutant was approximately 45% of that of wild-type B. thetaiotaomicron. However, the pullulanase-negative insertional mutant 95-1 was still able to grow on pullulan at a rate similar to that of wild-type B. thetaiotaomicron. Thus, there must be a second pullulanase in B. thetaiotaomicron.     

Detection of protease activity with a fluorescence-labelled peptide substrate on a TLC plate

A small amount of peptidase activity could be detected using an amine derivatizing reagent, fluorescein isothiocyanate (FITC), which has been used to produce a fluorogenic peptide. The substrate produced, FITC-peptide, gave a clear spot on a silica gel sheet upon exposure to UV light. The peptidase activity of angiotensin-converting enzyme (ACE), trypsin, chymotrypsin, cucumisin, and that of some plant tissues were detected by using a fluorogenic angiotensin I. This showed that the substrate specificity of proteolytic enzymes can be distinguished from the others by this procedure.     

Isolation and characteristics of thermostable pullulanase from Clostridium thermohydrosulfuricum produced by Escherichia coli cells

The expressed gene (pul) for a thermostable pullulanase from Clostridium thermohydrosulfuricum was cloned into Escherichia coli. The enzyme was purified from cell extracts of E. coli by thermoinactivation, ammonium sulphate precipitation and gel exclusion. The purified enzyme was characterized as monomer with both pullulanase and glucoamylase activities. The general physico-chemical and catalytic properties of this enzyme were obtained. In particular, pullulanase and glucoamylase activities were stable and optimally active at 65 degrees C. The pH optimum for activity was 5.8. The amino acid composition and amino acid sequence of N-terminal end were estimated.     

An activity gel assay for the detection of DNA helicases and nucleases from cell-free extracts.

An activity gel assay was developed for the detection of DNA helicases in crude extracts. The assay was based on the ability of DNA helicases to unwind radioactive fragments from single-stranded M13 circles that were immobilized in an SDS polyacrylamide gel. The displaced radioactive strands were detected by blotting them to a filter and visualizing the resulting bands by autoradiography. Experiments with purified proteins demonstrated that DNA helicases, endonucleases and exonucleases could produce activity bands. A one-dimensional gel assay was sufficiently sensitive to allow detection of DNA helicase I, DNA helicase II, DNA helicase IV, the RecQ helicase as well as 3 unidentified putative DNA helicases in crude extracts of Escherichia coli. Exonuclease and endonuclease activities from crude extracts could be distinguished from DNA helicase activities by their ATP-independence and from each other by their band morphologies.     

Magnetite-alginate beads for purification of some starch degrading enzymes

Starch degrading enzymes, viz., β-amylase, glucoamylase, and pullulanase, were purified using magnetite-alginate beads. In each case, the enzyme activity was eluted by using 1.0 M maltose. β-Amylase (sweet potato), glucoamylase (Aspergillus niger), and pullulanase (Bacillus acidopullulyticus) from their crude preparations were purified 37-, 31-, and 49-fold with 86, 87, and 95% activity recovery, respectively. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis showed single band in each case.