EC:4.1.2.13 - FACTA Search

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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)

After a brief exposition to glucose, Thiobacillus acidophilus was isolated from a culture of iron-grown T. ferrooxidans. Physicochemical analysis of its DNA showed a G+C content of 62.9-63.2%. The new isolate grows best at 25-30 degrees C and at pH 3.0. Growth is possible between pH 1.5 and 6.0. Thiobacillus acidophilus is apparently strictly aerobic. Ammonium salts are the only suitable source of nitrogen. The bacterium is a facultative autotroph. In addition to elemental sulfur, it obtains energy from organic compounds such as D-glucose, D-galactose, D-fructose, D-mannitol, D-xylose, D-ribose, D-arabinose, L-arabinose, sucrose, sodium citrate, malic acid,dl-aspartic acid, and dl-glutamic acid. Thiobacillus acidophilus possesses the key enzymes of the tricarboxylic acid (TCA) cycle including NAD-and NADP-linked isocitric dehydrogenase and alpha-ketoglutarate dehydrogenase, and the key enzymes of the hexose monophosphate pathway (glucose-6-phosphate and 6-phosphogluconate dehydrogenase, and fructose 1,6-diphosphate aldolase). NADH oxidase has been found in particulate fraction of extracts. Rhodanese and thiosulfate oxidase have also been detected.
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PMID:Thiobacillus acidophilus sp. nov.; isolation and some physiological characteristics. 23 84

Pyridoxal 5'-phosphate (PLP) in aqueous solutions can form a Schiff base complex with 14 and 16 lysine residues of rabbit and sturgeon muscle aldolases (EC 4.1.2.13), respectively. Although the mechanism of their interaction with PLP should be the same, these residues can be differentiated into three families on the basis of their inhibition constant Ki and rate constant k. The lysine residues of one of these families do not react with PLP in the presence of the substrates. Therefore, they are assumed to be part of the active center. In the sturgeon muscle aldolase, 3.7 substrate protected lysine residues are present. Rabbit aldolase, although tetrameric, contains only 2.8 substrate protected lysine residues. This suggests that one active center of this enzyme may be 'buried'. Structural studies showed the following sequence around the substrate protected lysine residues, in the rabbit aldolase: Gly-(Gly2, Val3)-Pyridoxyl Lys-Ile-Asp-Lys.
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PMID:Differential effects of pyridoxal 5'-phosphate on lysine residues in rabbit and sturgeon muscle aldolases. 95 52

Alkyl glycolamido phosphoric esters (P-O-CH2-CO-NH-(CH2)n-CH3) and alkyl monoglycolate phosphoric esters (P-O-CH2-CO-O-(CH2)n-CH3), which are analogs of the aldolase substrate fructose-1-phosphate, were synthesized and use for probing the active site of rabbit muscle aldolase. The inhibition constants (Ki) were affected by the length of the alkyl groups of these compounds and a maximum value of Ki was observed between the number of methylene groups 2 and 4, depending on the type of compound. In the previous investigation, N-(omega-hydroxyalkyl)-glycolamido bisphosphoric esters (P-O-CH2-CO-NH-(CH2)n-O-P) and alkanediol monoglyclolate bisphosphoric esters (P-O-CH2-CO-O-(CH2)n-O-P) have a minimum Ki value between the number of methylene groups 1 and 4. The difference spectra of aldolase caused by binding of alkyl glycoamido phosphoric esters or alkyl monophosphates resembled that of their analogous bisphosphoric esters, but the intensity of absorbance was smaller than that of the bisphosphoric ester analogs. These results suggest that rabbit muscle aldolase has two binding sites for the phosphate groups on the entrance end of the active site cavity, the singly wound beta-barrel of the parallel alpha/beta class structure. The distance between the phosphate binding site Lys-107 in the beta-sheet structure (c) and Arg-148 in the beta-sheet structure (d) may possibly be expanded or contracted by the forms of the bending structure of the biphosphate compounds. Also, the change of distance between the beta-sheet structure (c) and (d) containing Trp-147, may have an effect on the environment of the tryptophan and cause a change of the absorbance of aldolase especially at 295-299 nm. On the other hand, the synthetic monophosphate compounds bind at only one of the two phosphate binding sites and have very little effect on the absorbance of Trp-147, in a similar manner as orthophosphate. The alkyl groups of monophosphate may be repelled by the ionic amino acid side chains, Asp-33, Lys-146, Glu-187 and/or Lys-229 in the middle of the active site cavity. However, the end of the long alkyl group of some monophosphates may possibly contact the hydrophobic bottom of the active site cavity without effect on the environment of Trp-147.
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PMID:An exploration of the binding site of aldolase using alkyl glycolamido phosphoric esters and alkyl monoglycolate phosphoric esters. 154 Jun 43

Enzymatic studies on aldolase isozymes have been carried out by techniques of protein engineering. Site-directed mutagenesis helps us to verify the roles of amino acid residues in catalytic reactions. Chimeric fusion proteins give us information about the regions which specify the characteristics of the isozymes. The results are: (1) In aldolase A, COOH terminal Tyr and Lys-107 residues play important roles in catalysis, especially in binding of FDP. (2) Aspartic acid at the 128th residue in aldolase A is essential to thermostability; no other residue such as glutamic acid can substitute for it. (3) Studies on chimeric fusion proteins indicate that the C-terminal region (including C-terminus Tyr) or aldolase A is responsible for its substrate specificity, which is not seen in aldolase B. (4) A region near NH2 terminus in aldolase B determines its specific structure. (5) The region including His-107, Asp-128, and Tyr-137 (B-A junction of BA137) is located in a turn which is exposed outward (a model architecture by Sygusch et al [1987]). In BA137, this region would be constrained, and play a significant role in catalysis, thermostability, etc. (6) Tertiary structure of aldolase B seems to be dissimilar to that of aldolase A.
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PMID:Structural studies on aldolase isozymes through protein engineering. 220 67

N-(omega-Hydroxyalkyl)glycolamidobisphosphoric esters (P-O-CH2-CO-NH-(CH2)n -O-P), which are analogues of the aldolase (D-fructose-1,6-bisphosphate D-glyceraldehyde-3-phosphate-lyase, EC 4.1.2.13) substrate fructose 1,6-bisphosphate, were synthesized and used for probing its active site. These phosphate compounds competitively inhibited aldolase activity. The Ki value was lowest when the maximum distance between the phosphorus atoms of the bisphosphate was brought close to that of fructose 1,6-bisphosphate. The inhibitor constants, Ki, were compared to those of alkanediol monoglycolate bisphosphoric esters and alkanediol bisphosphate compounds, which were reported previously by Ogata et al. The values of Ki for the bisphosphate compounds containing an amide group, the amide bisphosphate compounds, were smaller than those for the bisphosphate compounds containing an ester group, the ester bisphosphate compounds, and those for alkanediol bisphosphates were the largest for the same distance between phosphorus atoms in these bisphosphates. The difference spectra of aldolase caused by binding of a saturating concentration of N-(omega-hydroxypropyl)glycolamidobisphosphoric ester resembled that of butanediol monoglycolate bisphosphoric ester. However, the effects of the amide bisphosphate compounds on the absorption spectrum of aldolase were smaller than those of the ester bisphosphate compounds for the same distance between phosphorus atoms in these bisphosphate compounds. These results suggest that the synthesized phosphate compounds bind to aldolase at the active site and the -CO-NH- group of the compounds might be held more tightly than the -CO-O- group by hydrogen bonds, presumably with the amino acid residues in the active site, such as Lys-146 or -229 and Asp-33 or Glu-187. On the other hand, the -CO-O- group might be more effective in changing the environment of the Trp-147 residue in the active site of this enzyme.
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PMID:An exploration of the binding site of aldolase using N-(omega-hydroxyalkyl) glycolamidobisphosphoric esters. 226 71

Fructose-1,6-bisphosphate aldolase A (fructose-bisphosphate aldolase; EC 4.1.2.13) deficiency is an autosomal recessive disorder associated with hereditary hemolytic anemia. To clarify the molecular mechanism of the deficiency at the nucleotide level, we have cloned aldolase A cDNA from a patient's poly(A)+ RNA that was expressed in cultured lymphoblastoid cells. Nucleotide analysis of the patient's aldolase A cDNA showed a substitution of a single nucleotide (adenine to guanine) at position 386 in a coding region. As a result, the 128th amino acid, aspartic acid, was replaced with glycine (GAT to GGT). Furthermore, change of the second letter of the aspartic acid codon extinguished a F ok I restriction site (GGATG to GGGTG). Southern blot analysis of the genomic DNA showed the patient carried a homozygous mutation inherited from his parents. When compared with normal human aldolase A, the patient's enzyme from erythrocytes and from cultured lymphoblastoid cells was found to be highly thermolabile, suggesting that this mutation causes a functional defect of the enzyme. To further examine this possibility, the thermal stability of aldolase A of the patient and of a normal control, expressed in Escherichia coli using expression plasmids, was determined. The results of E. coli expression of the mutated aldolase A enzyme confirmed the thermolabile nature of the abnormal enzyme. The Asp-128 is conserved in aldolase A, B, and C of eukaryotes, including an insect, Drosophila, suggesting that the Asp-128 of the aldolase A protein is likely to be an amino acid residue with a crucial role in maintaining the correct spatial structure or in performing the catalytic function of the enzyme.
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PMID:Human aldolase A deficiency associated with a hemolytic anemia: thermolabile aldolase due to a single base mutation. 282 99

The complete amino acid sequence of FBP aldolase from Drosophila melanogaster has been determined. The enzyme contains four identical subunits of 360 amino acid residues. The primary structure of the monomer was established using automated Edman degradation on fragments prepared by CNBr-cleavage, by partial acid cleavage at the unique Asp-Pro bond and by oxidative cleavage at the three tryptophan residues. Manual Edman-Chang degradation was used on smaller peptides obtained by digestion with Staphylococcus aureus V8 protease, trypsin or chymotrypsin. The primary structure of Drosophila aldolase exhibits very extensive homology with the sequence of rabbit muscle aldolase (71% identity), thus explaining the early observation that Drosophila and mammalian aldolases form active interspecies hybrid quaternary structures (Brenner-Holzach, O. and Leuthardt, F., Eur. J. Biochem. (1972) 31, 423-426).
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PMID:Amino acid sequence of an invertebrate FBP aldolase (from Drosophila melanogaster). 391 28

Band 3 is the predominant membrane-spanning polypeptide and the mediator of anion transport in the human erythrocyte. In addition, it provides the sites of association for fructose 1,6-bisphosphate aldolase and other cytoplasmic proteins with the membrane. The aldolase-binding activity of water-soluble fragments of band 3 was measured by their inhibition of aldolase catalytic activity and by their displacement of aldolase from ghosts. At saturation, the binding of one band 3 or certain of its fragments per aldolase molecule partially inhibited the catalytic activity and band 3 binding of the unliganded subunits of the tetramer through an apparently cooperative mechanism. An NH2-terminal 23,000-dalton fragment generated by S-cyanylation of the cytoplasmic pole of band 3 was approximately 20% as avid in binding aldolase as was native band 3. Several fragments cleaved from the NH2-terminal portion of the 23,000-dalton peptide by trypsin, mild acid hydrolysis, and cyanogen bromide digestion all bound aldolase, while fragments from the rest of the polypeptide were essentially inactive. The first 31 residues of band 3 contained 16 Asp plus Glu, no basic residues, and a blocked alpha-amino terminus. The highly acidic composition of this region is consistent with the strongly electrostatic character of the interaction between band 3 and aldolase, presumably at the strongly basic catalytic center of the enzyme. We conclude that the NH2-terminal region of band 3 bears the membrane-binding site for aldolase.
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PMID:The aldolase-binding site of the human erythrocyte membrane is at the NH2 terminus of band 3. 728 63

We report the construction of subunit interface mutants of rabbit muscle aldolase A with altered quaternary structure. A mutation has been described that causes nonspherocytic hemolytic anemia and produces a thermolabile aldolase (Kishi H et al., 1987, Proc Natl Acad Sci USA 84:8623-8627). The disease arises from substitution of Gly for Asp-128, a residue at the subunit interface of human aldolase A. To elucidate the role of this residue in the highly homologous rabbit aldolase A, site-directed mutagenesis is used to replace Asp-128 with Gly, Ala, Asn, Gln, or Val. Rabbit aldolase D128G purified from Escherichia coli is found to be similar to human D128G by kinetic analysis, CD, and thermal inactivation assays. All of the mutant rabbit aldolases are similar to the wild-type rabbit enzyme in secondary structure and kinetic properties. In contrast, whereas the wild-type enzyme is a tetramer, chemical crosslinking and gel filtration indicate that a new dimeric species exists for the mutants. In sedimentation velocity experiments, the mutant enzymes as mixtures of dimer and tetramer at 4 degrees C. Sedimentation at 20 degrees C shows that the mutant enzymes are > 99.5% dimeric and, in the presence of substrate, that the dimeric species is active. Differential scanning calorimetry demonstrates that Tm values of the mutant enzymes are decreased by 12 degrees C compared to wild-type enzyme. The results indicate that Asp-128 is important for interface stability and suggest that 1 role of the quaternary structure of aldolase is to provide thermostability.
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PMID:Subunit interface mutants of rabbit muscle aldolase form active dimers. 783

The expression and purification of the rabbit muscle aldolase A (D-fructose 1,6-bisphosphate:D-glyceraldehyde-3-phosphate lyase, EC 4.1.2.13) from an expression plasmid in bacteria is described. The enzyme is produced in bacteria at a level of 300 mg/liter and is indistinguishable from the enzyme isolated from muscle in assays using fructose 1,6-bisphosphate and fructose 1-phosphate. The recombinant enzyme has the same primary, secondary, and quaternary structure as the muscle enzyme. Aspartic acid 33, found near the active site lysine in the crystal structure, is changed to alanine, serine, and glutamic acid by site-directed mutagenesis, resulting in the mutant proteins, D33A, D33S, and D33E, respectively. The mutant enzymes are purified by substrate affinity elution from carboxylmethyl-Sepharose, the same method as that used for the wild-type enzyme. The secondary and quaternary structure of D33A is identical to wild-type aldolase when analyzed by light scattering, gel filtration, and circular dichroism. Moreover, the hexose substrate can be fixed in the active site by reduction of the Schiff base with sodium borohydride, indicating that the active site is not drastically altered. These single mutations in the active site have a serious effect on the activity of the enzyme. In addition, the rate of carbanion oxidation for D33A is 17-29 times slower when the substrate is fructose 1,6-bisphosphate versus dihydroxyacetone phosphate, whereas in the wild-type there is no significant difference in these rates. This evidence and the conservation of this residue in other class I aldolases indicate that aspartic acid 33 is an essential residue in the catalytic mechanism, possibly involved in abstraction of the carbon 4 hydroxyl proton.
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PMID:Site-directed mutagenesis identifies aspartate 33 as a previously unidentified critical residue in the catalytic mechanism of rabbit aldolase A. 841 16

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