EC:3.2.1.26 - FACTA Search

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Query: EC:3.2.1.26 (invertase)
4,927 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Two forms of secreted invertase have been purified from Aspergillus nidulans by ion-exchange and gel-filtration chromatography. S-invertase gave a single, broad, glycoprotein band on PAGE and SDS-PAGE corresponding in size to 185 and 78 kDa, respectively, compared with 94 and 110 kDa for F-invertase. The carbohydrate of S-invertase contained mainly mannose (14%) and less galactose (5%) whereas the F-form yielded mainly galactose (29%) and less mannose (12%). Three sharp bands of enzymically active glycoprotein for both the S-form (pI 4.9-5.2) and the F-form (pI 3-4.2) were observed after isoelectric focusing. Deglycosylation with Endo H simplified this pattern to one enzymically active protein band (pI 5.2). The aglycoenzymes gave narrow bands on PAGE and SDS-PAGE corresponding to 115 kDa and 60 kDa respectively for both S- and F-forms. The specific activity of S-invertase was three-fold higher than that of F-invertase both before and after deglycosylation. The Km values of the two forms of invertase were very similar. Significant homology existed between the N-terminal amino-acid sequences of S-invertase (and of internal peptides derived from it) and sequences of invertase from other species. It is suggested that the higher carbohydrate content in F-invertase results in the native enzyme existing as a monomer and having a greater negative charge and lower specific enzyme activity compared with the dimeric S-enzyme.
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PMID:Purification and partial characterization of the high and low molecular weight form (S- and F-form) of invertase secreted by Aspergillus nidulans. 881 28

beta-Fructofuranosidase [EC 3.2.1.26] in Clostridium perfringens was induced in the presence of sucrose and suppressed in the presence of glucose or maltose. The enzyme seems to be present in protoplasm in a soluble state. The beta-fructofuranosidase from C. perfringens cells grown on sucrose was purified by ammonium sulfate precipitation. DEAE-cellulose chromatography, Sephadex G-150 gel filtration, and hydroxylapatite chromatography to a homogeneous state. The molecular weight was 37,000 by gel filtration using Sephadex G-150 and by SDS-polyacrylamide gel electrophoresis. The amino acid composition is not much different from those of other microorganisms, but the Glx content was a little higher. The enzyme was inhibited by heavy metals, such as Hg2+, Cu2+, and Ag+, as well as pCMB; the activity was restored by incubating with mercaptoethanol. Fructose and amines including Tris and aniline had inhibitory effects.
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PMID:Purification and properties of beta-fructofuranosidase from Clostridium perfringens. 914 17

Acid trehalase (AT) has always been reported to be copurified with invertase (I) and a 40 kDa additional protein. Glucose grown stationary phase cells of Saccharomyces cerevisiae contained least I activity. So, it was attempted to purify AT from these cells (I:AT = 10.83). Studies on specific activity, percent recovery and I:AT ratio of different pools, collected during purification of AT, indicated that samples containing ratio I:AT < 2.2 were unstable. Purification methodology favouring association (DEAE-Sephadex chromatography) resulted in gaining total activity while methodology favouring dissociation (HPGPLC) resulted in tremendous loss in recovery. Active pool (Pool 1X) appeared to be electrophoretically homogeneous but dissociated into 175, 90, 68, 61, 57 (minor bands) and 37-41 (major band) molar mass (kDa) bands on SDS-PAGE. Inactive pools (Pools 1Y, 3X, 3Y) did not contain the 37-41 kDa major band. So, association of both I and a 37-41 kDa protein with AT appeared to be essential. Two bands of isoelectric pH (pI) 4.6 and 4.7 were present in pool 1X enzyme preparation. All SDS-PAGE-resolved bands of pool 1X, in an average, contained high aspartate/asparagine and low cysteine residues. AT activity appeared to be highly sensitive to the change in pH and also to agents affecting ionisation of protein, e.g., betaine, NaCl, acetate, etc. Association of AT components in presence of NaCl was demonstrated spectrophotometrically. Specific activity of AT decreased with dilution. Substrate mediated allosterism for this enzyme preparation suggested that AT existed as an equilibrium mixture of protomer-oligomer. It was suggested that reversible association-dissociation was a mechanism for the regulation of AT activity.
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PMID:Regulation of acid trehalase activity by association-dissociation in Saccharomyces cerevisiae. 952 60

An mAb was raised to the C5 phagosomal antigen in Paramecium multimicronucleatum. To determine its function, the cDNA and genomic DNA encoding C5 were cloned. This antigen consisted of 315 amino acid residues with a predicted molecular weight of 36,594, a value similar to that determined by SDS-PAGE. Sequence comparisons uncovered a low but significant homology with a Schizosaccharomyces pombe protein and the C-terminal half of the beta-fructofuranosidase protein of Zymomonas mobilis. Lacking an obvious transmembrane domain or a possible signal sequence at the N terminus, C5 was predicted to be a soluble protein, whereas immunofluorescence data showed that it was present on the membranes of vesicles and digestive vacuoles (DVs). In cells that were minimally permeabilized but with intact DVs, C5 was found to be located on the cytosolic surface of the DV membranes. Immunoblotting of proteins from the purified and KCl-washed DVs showed that C5 was tightly bound to the DV membranes. Cryoelectron microscopy also confirmed that C5 was on the cytosolic surface of the discoidal vesicles, acidosomes, and lysosomes, organelles known to fuse with the membranes of the cytopharynx, the DVs of stages I (DV-I) and II (DV-II), respectively. Although C5 was concentrated more on the mature than on the young DV membranes, the striking observation was that the cytopharyngeal membrane that is derived from the discoidal vesicles was almost devoid of C5. Approximately 80% of the C5 was lost from the discoidal vesicle-derived membrane after this membrane fused with the cytopharyngeal membrane. Microinjection of the mAb to C5 greatly inhibited the fusion of the discoidal vesicles with the cytopharyngeal membrane and thus the incorporation of the discoidal vesicle membranes into the DV membranes. Taken together, these results suggest that C5 is a membrane protein that is involved in binding and/or fusion of the discoidal vesicles with the cytopharyngeal membrane that leads to DV formation.
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PMID:Cloning and sequencing of a protein involved in phagosomal membrane fusion in Paramecium. 1019 55

An unusual lectin possessing two distinctly different types of carbohydrate-combining sites was purified from tubers of Xanthosoma sagittifolium L. by consecutive passage through two affinity columns, i.e. asialofetuin-Sepharose and invertase-Sepharose. SDS-polyacrylamide gel electrophoresis, N-terminal amino acid sequencing, and gel filtration chromatography of the purified lectin showed that the X. sagittifolium lectin is a heterotetrameric protein composed of four 12-kDa subunits (alpha(2)beta(2)) linked by noncovalent bonds. The results obtained by quantitative precipitation and hapten inhibition assays revealed that the lectin has two different types of carbohydrate-combining sites: one type for oligomannoses, which preferentially binds to a cluster of nonreducing terminal alpha1,3-linked mannosyl residues, and the other type for complex N-linked carbohydrates, which best accommodates a non-sialylated, triantennary oligosaccharide with N-acetyllactosamine (i.e. Galbeta1,4GlcNAc-) or lacto-N-biose (i.e. Galbeta1,3GlcNAc-) groups at its three nonreducing termini.
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PMID:Xanthosoma sagittifolium tubers contain a lectin with two different types of carbohydrate-binding sites. 1055 6

Immobilization of invertase in thiophene-capped poly(methylmethacrylate)/polypyrrole matrices was achieved by constant potential electrolysis using different supporting electrolytes. Optimum reaction conditions such as substrate concentration, temperature, and pH for the enzyme electrodes were determined. The temperature and pH were found to be 60 degrees C and 4.8, respectively. The effect of supporting electrolyte on the enzyme activity revealed that SDS was the best in the immobilization procedure. Michaelis-Menten constant and the maximum reaction rate in PMMA/PPy matrices were of the order of that of pristine polypyrrole. However, in terms of repeated use, the copolymer matrices were superior to polypyrrole.
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PMID:Immobilization of invertase in conducting thiophene-capped poly(methylmethacrylate)/polypyrrole matrices. 1067 18

Fructosyltransferase (EC.2.4.1.9) and invertase (EC.3.2.1.26) have been purified from the crude extract of Aspergillus niger AS0023 by successive chromatographies on DEAE-sephadex A-25, sepharose 6B, sephacryl S-200, and concanavalin A-Sepharose 4B columns. On acrylamide electrophoresis the two enzymes, in native and denatured forms, gave diffused glycoprotein bands with different electrophoretic mobility. On native-PAGE and SDS-PAGE, both enzymes migrated as polydisperse aggregates yielding broad and diffused bands. This result is typical of heterogeneous glycoproteins and the two enzymes have proved their glycoprotein nature by their adsorption on concanavalin A lectin. Fructosyltransferase (FTS) on native PAGE migrated as two enzymatically active bands with different electrophoretic mobility, one around 600 kDa and the other from 193 to 425 kDa. On SDS-PAGE, these two fractions yielded one band corresponding to a molecular weight range from 81 to 168 kDa. FTS seems to undergo association-dissociation of its glycoprotein subunits to form oligomers with different degrees of polymerization. Invertase (INV) showed higher mobility corresponding to a molecular range from 82 to 251 kDa, on native PAGE, and from 71 to 111 kDa on SDS-PAGE. The two enzymes exhibited distinctly different pH and temperature profiles. The optimum pH and temperature for FTS were found to be 5.8 and 50 degrees C, respectively, while INV showed optimum activity at pH 4.4 and 55 degrees C. Metal ions and other inhibitors had different effects on the two enzyme activities. FTS was completely abolished with 1 mM Hg(2+) and Ag(2+), while INV maintained 72 and 66% of its original activity, respectively. Furthermore, the two enzymes exhibited distinctly different kinetic constants confirming their different nature. The K(m) and V(m) values for each enzyme were calculated to be 44.38 mM and 1030 micromol ml(-1)min(-1) for FTS and 35.67 mM and 398 micromol ml(-1) min(-1) for INV, respectively. FTS and INV catalytic activity was dependent on sucrose concentration. FTS activity increased with increasing sucrose concentrations, while INV activity decreased markedly with increasing sucrose concentration. Furthermore, INV exhibited only hydrolytic activity producing exclusively fructose and glucose from sucrose, while FTS catalyzed exclusively fructosyltransfer reaction producing glucose, 1-kestose, nystose and fructofuranosyl nystose. In addition, at 50% sucrose concentration FTS produced fructooligosaccharides at the yield of 62% against 54% with the crude extract.
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PMID:Purification and partial characterization of fructosyltransferase and invertase from Aspergillus niger AS0023. 1093 62

This work describes a new invertase proteinaceous inhibitor from Cyphomandra betacea Sendt. (tomate de arbol) fruits. The proteinaceous inhibitor was isolated and purified from a cell wall preparation. The pH stability, kinetics of the inhibition of the C. betacea invertase, inhibition of several higher plant invertases and lectin nature of the inhibitor were studied. The inhibitor structure involves a single polypeptide (Mr = 19000), as shown by gel filtration and SDS-PAGE determinations. N-terminal aminoacid sequence was determined. The properties and some structural features of the inhibitor are compared with the proteinaceous inhibitors from several plant species (Beta vulgaris L., Ipomoea batatas L. and Lycopersicon esculentum Mill.). All these inhibitors share lectinic properties, some common epitopes, some aminoacid sequences and a certain lack of specificity towards invertases of different species, genera and even plant family. In consequence, the inhibitors appear to belong to the same lectin family. It is now known that some lectins are part of the defence mechanism of higher plants against fungi and bacteria and this is a probable role of the proteinaceous inhibitors.
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PMID:Invertase proteinaceous inhibitor of Cyphomandra betacea Sendt fruits. 1114 Jun 13

We purified sucrase-isomaltase and sucrase-free isomaltase from a normal and a sucrase-deficient line, respectively, of the house musk shrew Suncus murinus and examined the effects of mutation on enzyme structure and activities. Recent cDNA cloning studies have predicted that sucrase-free mutant isomaltase lacks the C-terminal 69 amino acids of normal isomaltase, as well as the entire sucrase. On SDS-polyacrylamide gel electrophoresis purified sucrase-free isomaltase gave a single protein band of 103 kDa, while sucrase-isomaltase gave two major protein bands of 106 and 115 kDa. The 115, but not 106, kDa band was quite similar to the 103 kDa band on Western blotting with Aleuria aurantia lectin and antibody against shrew sucrase-isomaltase, suggesting that the 115 and 103 kDa bands are due to normal and mutant isomaltases, respectively, in accordance with the above prediction. Purified isomaltase and sucrase-isomaltase were similar in Km and Vmax (based on isomaltase mass) values for isomaltose hydrolysis and in inhibition of isomaltase activity by antibody against rabbit sucrase-isomaltase, suggesting that the enzymatic properties of isomaltase are mostly unaffected by mutation.
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PMID:Comparison of sucrase-free isomaltase with sucrase-isomaltase purified from the house musk shrew Suncus murinus. 1134 43

Extracellular sucrase (S) of Termitomyces clypeatus was aggregated with cellobiase (C) in culture filtrate and coaggregates of sucrase to cellobiase with different activity ratios (S/C) were obtained during purification. Specific activity of the enzyme decreased significantly, after purification of sucrase free from cellobiase. Purified sucrase was characterized as a glycoprotein of molar mass around 55kDa as indicated by SDS-PAGE and HPGPLC. K(m) and V(max) of the purified enzyme were determined as 34.48 mM and 13.3 U/mg, respectively, at optimum temperature (45 degrees C) and pH (5.0). Substrate affinity and reaction velocity of the purified enzyme, free from cellobiase, was lowered by approximately 3.5 and 55 times, respectively, than that of the enzyme obtained from culture filtrate. The instant regain of sucrase activity up to the extent of 41% was obtained on in vitro addition of cellobiase (free from sucrase) to the enzyme in incubation mixture. Conformation of the enzyme free from cellobiase appeared to be significantly different from that of the coaggregate, as analyzed by circular dichroic and light scattering spectroscopy. It was concluded that activity and conformation of sucrase is regulated (altered) by heteroaggregation with cellobiase in the fungus.
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PMID:Regulation (alteration) of activity and conformation of sucrase by coaggregation with cellobiase in culture medium of Termitomyces clypeatus. 1193 14

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