Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:4.1.2.13 (aldolase)
 3,461 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The halophilic archaea display a considerable extent of enzyme diversity. The presence or absence of certain enzymatic activities is closely linked with the taxonomic status of the strains investigated. Thus, Halobacterium species such as Hb. salinarium, Hb. halobium, and Hb. cutirubrum differ from most other Halobacteriaceae tested by the possession of an NAD(+)-dependent glycerol dehydrogenase, by the absence of methylglyoxal synthase activity, and the ability of fermentative growth on arginine. Species such as Hb. saccharovorum and Hb. sodomense, which are still classified within the genus Halobacterium, have an enzymatic machinery greatly different from that of the Hb. salinarium-Hb. halobium group, confirming the need for a taxonomic reappraisal of these species. The presence of NAD(+)-dependent D-lactate dehydrogenase is characteristic of representatives of the genus Haloarcula, which possess only low activities of NAD(+)-independent L- and D-lactate dehydrogenases, if at all. Other enzymes which show considerable diversity are fructose 1,6-bisphosphate aldolase, of which two classes exist, and ribulose 1,6-bisphosphate carboxylase, which is present in a limited number of species.
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PMID:Enzyme diversity in halophilic archaea. 787 98

Human erythrocyte band 3 inhibits glycolytic enzymes, including aldolase, by binding these cytoplasmic enzymes at its N-terminus. Phosphorylation of Y8 disrupts inhibition, and there is evidence that in vivo glycolysis levels in erythrocytes are regulated in part by a phosphorylation/dephosphorylation signaling pathway. The structural basis for control by phosphorylation has been investigated by NMR studies on a complex between aldolase and a synthetic peptide corresponding to the first 15 residues of band 3 (MEELQDDYEDMMEEN-NH2). The structure of this band 3 peptide (B3P) when it is bound to rabbit muscle aldolase was determined using the exchange-transferred nuclear Overhauser effect (ETNOE). Two hundred NMR structures for B3P were generated by simulated annealing molecular dynamics with NMR-derived distance restraints and excluding electrostatic terms. Twenty structures were further refined against a force field including full partial charges. The important conformational feature of B3P in the bound state is a folded loop structure involving residues 4-9 and M12 that surrounds Y8 and is stabilized by a hydrophobic cluster with the ring of Y8 sandwiched between the methyl groups of L4 and M12. Differential line broadening indicates that this loop structure binds aldolase in a relatively specific manner, while terminal regions are structurally heterogeneous. To better understand B3P inhibition of aldolase and the mechanism of phosphorylation control, a complex was modeled by docking B3P into the active site of aldolase and optimizing the fit using restrained molecular dynamics and energy minimization. The B3P loop is complementary in conformation to the beta-barrel central core containing the aldolase active site residues. Binding is electrostatic in nature with numerous ionic and hydrogen-bonding interactions involving several conserved lysine and arginine residues of aldolase. How phosphorylation of band 3 could disrupt inhibition was considered by modeling a phosphoryl moiety onto Y8 of B3P. An energetic analysis with respect to rigid phosphate rotation suggests that aldolase inhibition is reversed primarily because of electrostatic repulsion between B3P residues that destabilizes the B3P loop formed in the complex. This proposed intramolecular mechanism for blocking protein--protein association by electrostatic repulsion with the phosphoryl group may be applicable to other protein--protein signaling complexes.
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PMID:Solution structure of a band 3 peptide inhibitor bound to aldolase: a proposed mechanism for regulating binding by tyrosine phosphorylation. 852 30

We used site-directed mutagenesis of rabbit muscle aldolase, falling ball viscometry, co-sedimentation binding assays, and negative stain electron microscopy, to identify specific residues involved in the aldolase-actin interaction. Three mutants, R42A (Arg --> Ala), K107A (Lys --> Ala), and R148A (Arg --> Ala), had minimal actin binding activity relative to wild type (wt) aldolase, and one mutant, K229A (Lys --> Ala), had intermediate actin binding activity. A mutant with approximately 4,000-fold reduced catalytic activity, D33S (Asp --> Ser), had normal actin binding activity. The aldolase substrates and product, fructose 1,6-bisphosphate, fructose 1-phosphate, and dihydroxyacetone phosphate, reversed the gelling of wt aldolase and F-actin, consistent with at least partial overlap of catalytic and actin-binding sites on aldolase. Molecular modeling reveals that the actin-binding residues we have identified are clustered in or around the catalytic pocket of the molecule. These data confirm that the aldolase-actin interaction is due to specific binding, and they suggest that electrostatic interactions between specific residues, rather than net charge, mediate this interaction. Low concentration of wt and D33S aldolase caused formation of high viscosity actin gel networks, while high concentrations of wt and D33S aldolase resulted in solation of the gel by bundling actin filaments, consistent with a potential role for this enzyme in the regulation of cytoplasmic structure.
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PMID:The molecular nature of the F-actin binding activity of aldolase revealed with site-directed mutants. 863 11

Treatment of the Class II fructose-1,6-bisphosphate aldolase of Escherichia coli with the arginine-specific alpha-dicarbonyl reagents, butanedione or phenylglyoxal, results in inactivation of the enzyme. The enzyme is protected from inactivation by the substrate, fructose 1,6-bisphosphate, or by inorganic phosphate. Modification with [7-14C] phenylglyoxal in the absence of substrate demonstrates that enzyme activity is abolished by the incorporation of approximately 2 moles of reagent per mole of enzyme. Sequence alignment of the eight known Class II FBP-aldolases shows that only one arginine residue is conserved in all the known sequences. This residue, Arg-331, was mutated to either alanine or glutamic acid. The mutant enzymes were much less susceptible to inactivation by phenylglyoxal. Measurement of the steady-state kinetic parameters revealed that mutation of Arg-331 dramatically increased the K(m) for fructose 1,6-bisphosphate. Comparatively small differences in the inhibitor constant Ki for dihydroxyacetone phosphate or its analogue, 2-phosphoglycolate, were found between the wild-type and mutant enzymes. In contrast, the mutation caused large changes in the kinetic parameters when glyceraldehyde 3-phosphate was used as an inhibitor. Kinetic analysis of the oxidation of the carbanionic aldolase-substrate intermediate of the reaction by hexacyanoferrate (III) revealed that the K(m) for dihydroxyacetone phosphate was again unaffected, whereas that for fructose 1,6-bisphosphate was dramatically increased. Taken together, these results show that Arg-331 is critically involved in the binding of fructose bisphosphate by the enzyme and demonstrate that it interacts with the C-6 phosphate group of the substrate.
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PMID:Identification of arginine 331 as an important active site residue in the class II fructose-1,6-bisphosphate aldolase of Escherichia coli. 877 Dec 8

Cathepsin B was isolated from buffalo liver by salt fractionation, ion-exchange resin treatment, gel filtration and repeated ion-exchange chromatography using a linear salt gradient. The enzyme showed activity, against denatured hemoglobin (or ovalbumin), alpha-N-benzoyl-DL-arginine p-nitroanilide (BAPNA), and alpha-benzoyl-DL-arginine-naphthylamine (BANA). It inactivated buffalo muscle aldolase with a half life period of 21 min. The pH-activity profiles obtained for the digestion of hemoglobin (or ovalbumin) and aldolase inactivation by the enzyme were found to be different. The enzyme (mol wt 27,800 by SDS-PAGE) eluted in gel filtration with a molecular weight of 27,000 and a Stokes radius of 2.31 nm. The results showed buffalo cathepsin B to be a single-chain molecule. The N- and C-terminal amino acids of the enzyme were found to be leucine and aspartic acid, respectively. It contained 0.7% concanavalin A reactive neutral carbohydrate. The amino acid composition of buffalo cathepsin B was found to be similar to that of human liver cathepsin B. The optical properties of the buffalo enzyme were found consistent with its aromatic amino acid content. The isoionic pH of the enzyme was found to be 5.70 and the intrinsic viscosity was 3.48 ml/g whence the frictional ratio, f/f0 was computed to be 1.10 suggesting that the native enzyme conformation is compact and is globular in solution.
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PMID:Isolation, purification and properties of cathepsin B from buffalo liver. 893 19

Lys146 of rabbit aldolase A [D-fructose-1,6-bis(phosphate): D-glyceraldehyde-3-phosphate lyase, EC 4.1.2.13] was changed to arginine by site-directed mutagenesis. The kcat of the resulting mutant protein, K146R, was 500 times slower than wild-type in steady-state kinetic assays for both cleavage and condensation of fructose-1,6-bis(phosphate), while the K(m) for this substrate was unchanged. Analysis of the rate of formation of catalytic intermediates showed K146R was significantly different from the wild-type enzyme and other enzymes mutated at this site. Single-turnover experiments using acid precipitation to trap the Schiff base intermediate on the wild-type enzyme failed to show a build-up of this intermediate on K146R. However, K146R retained the ability to form the Schiff base intermediate as shown by the significant amounts of Schiff base intermediate trapped with NaBH4. In the single-turnover experiments it appeared that the Schiff base intermediate was converted to products more rapidly than it was produced. This suggested a maximal rate of Schiff base formation of 0.022 s-1, which was close to the value of kcat for this enzyme. This observation is strikingly different from the wild-type enzyme in which Schiff base formation is > 100 times faster than kcat. For K146R it appears that steps up to and including Schiff base formation are rate limiting for the catalytic reaction. The carbanion intermediate derived from either substrate or product, and the equilibrium concentrations of covalent enzyme-substrate intermediates, were much lower on K146R than on the wild-type enzyme. The greater bulk of the guanidino moiety may destabilize the covalent enzyme-substrate intermediates, thereby slowing the rate of Schiff base formation such that it becomes rate limiting. The K146R mutant enzyme is significantly more active than other enzymes mutated at this site, perhaps because it maintains a positively charged group at an essential position in the active site or perhaps the Arg functionally substitutes as a general acid/base catalyst in both Schiff base formation and in subsequent abstraction of the C4-hydroxyl proton.
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PMID:A lysine to arginine substitution at position 146 of rabbit aldolase A changes the rate-determining step to Schiff base formation. 905 4

A 2061 bp cDNA encoding a goldfish (Carassius auratus) aldolase was isolated from a goldfish brain library. The deduced 362 amino acid sequence is more similar to vertebrate brain (aldolase C) and muscle aldolases (aldolase A) than to the liver isozymes (aldolase B). Northern blot analysis indicates strong expression of the mRNA in brain but not in liver or muscle, which indicates that this is aldolase C rather than aldolase A. Analysis of all known vertebrate aldolase amino acid sequences reveals five residues; Leu-57, Arg-314, Thr-324, Glu-332, and Gly-350 that are present exclusively in aldolase Cs. The goldfish clone possesses all five residues. The residues are primarily located in the carboxyl-terminal region of the enzyme and may play a role in determining the neuronal isozyme-specific properties of the enzyme. Furthermore, the existence of an aldolase C in a teleost fish has implications with respect to the timing of genome duplication events that are thought to have been critical in vertebrate evolution.
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PMID:Identification of neuronal isozyme specific residues by comparison of goldfish aldolase C to other aldolases. 921 52

A low-specificity L-threonine aldolase (L-TA) gene from Pseudomonas sp. strain NCIMB 10558 was cloned and sequenced. The gene contains an open reading frame consisting of 1,041 nucleotides corresponding to 346 amino acid residues. The gene was overexpressed in Escherichia coli cells, and the recombinant enzyme was purified and characterized. The enzyme, requiring pyridoxal 5'-phosphate as a coenzyme, is strictly L specific at the alpha position, whereas it cannot distinguish between threo and erythro forms at the beta position. In addition to threonine, the enzyme also acts on various other L-beta-hydroxy-alpha-amino acids, including L-beta-3,4-dihydroxyphenylserine, L-beta-3,4-methylenedioxyphenylserine, and L-beta-phenylserine. The predicted amino acid sequence displayed less than 20% identity with those of low-specificity L-TA from Saccharomyces cerevisiae, L-allo-threonine aldolase from Aeromonas jandaei, and four relevant hypothetical proteins from other microorganisms. However, lysine 207 of low-specificity L-TA from Pseudomonas sp. strain NCIMB 10558 was found to be completely conserved in these proteins. Site-directed mutagenesis experiments showed that substitution of Lys207 with Ala or Arg resulted in a significant loss of enzyme activity, with the corresponding disappearance of the absorption maximum at 420 nm. Thus, Lys207 of the L-TA probably functions as an essential catalytic residue, forming an internal Schiff base with the pyridoxal 5'-phosphate of the enzyme to catalyze the reversible aldol reaction.
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PMID:Gene cloning, nucleotide sequencing, and purification and characterization of the low-specificity L-threonine aldolase from Pseudomonas sp. strain NCIMB 10558. 946 92

A simple purification scheme was developed for isolation and purification of cathepsin B from buffalo kidney. The use of CM-Sephadex and chromatofocusing helped in better and simultaneous separation of cathepsin B, H and L. As judged by PAGE and SDS-PAGE studies, the enzyme was found to be pure on the basis of charge and had a molecular mass of 25.5 kDa. The amino acid composition, number of free sulfhydryl groups and other major physico-chemical properties of the purified enzyme were similar to the properties reported for cathepsin B from other sources/tissues. However, the NH2-terminal amino acid residue of the enzyme was found to be Ala as against Leu reported from other tissues/species. The total carbohydrate content was also found to be significantly lower (3.6%) as compared to 7.0-7.6% reported for the enzyme from other sources. Thiol reducing compounds activated the enzyme whereas thiol blocking compounds inhibited it. The buffalo kidney enzyme hydrolyzed Z-Phe-Arg-MCA (Vmax/K(m) = 17.1) as the most efficient substrate followed by Z-Arg-Arg-MCA, BANA and BAPNA. Among the protein substrates, goat hemoglobin (Vmax/K(m) = 874) was found to be the most preferred. Rabbit muscle aldolase, usually considered to be a good substrate for cathepsin B, proved to be a poor substrate for this enzyme; only 25-30% inactivation of aldolase was observed. Antibodies raised against the enzyme recognised only cathepsin B and did not have any cross reactivity with cathepsin H or L from the same or different sources. These differences in the properties of the buffalo kidney enzyme vis-a-vis the same enzyme from other tissue/species have been attributed to specialized function of cathepsin B in diversified tissues.
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PMID:Purification and tissue/species dependence of the specificity of buffalo kidney cathepsin B. 959 26

Compartmentation of proteins in cells is important to proper cell function. Interactions of F-actin and glycolytic enzymes is one mechanism by which glycolytic enzymes can compartment. Brownian dynamics (BD) simulations of the binding of the muscle form of the glycolytic enzyme fructose-1,6-bisphosphate aldolase (aldolase) to F- or G-actin provide first-encounter snapshots of these interactions. Using x-ray structures of aldolase, G-actin, and three-dimensional models of F-actin, the electrostatic potential about each protein was predicted by solving the linearized Poisson-Boltzmann equation for use in BD simulations. The BD simulations provided solution complexes of aldolase with F- or G-actin. All complexes demonstrate the close contacts between oppositely charged regions of the protein surfaces. Positively charged surface regions of aldolase (residues Lys 13, 27, 288, 293, and 341 and Arg 257) are attracted to the negatively charged amino terminus (Asp 1 and Glu 2 and 4) and other patches (Asp 24, 25, and 363 and Glu 361, 364, 99, and 100) of actin subunits. According to BD results, the most important factor for aldolase binding to actin is the quaternary structure of aldolase and actin. Two pairs of adjacent aldolase subunits greatly add to the positive electrostatic potential of each other creating a region of attraction for the negatively charged subdomain 1 of the actin subunit that is exposed to solvent in the quaternary F-actin structure.
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PMID:Brownian dynamics simulations of interactions between aldolase and G- or F-actin. 987 19


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