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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 formation and dissociation of the
aldolase
-dihydroxyacetone phosphate complex were studied by following changes in A240 [Topper, Mehler & Bloom (1957), Science 126, 1287-1289]. It was shown that the enzyme-substrate complex (ES) slowly isomerizes according to the following reaction: (formula: see text) the two first-order rate constants for the isomerization step being k+2 = 1.3s-1 and k-2 = 0.7s-1 at 20 degrees C and pH 7.5. The dissociation of the ES complex was provoked by the addition of the competitive inhibitor
hexitol
1,6-bisphosphate. At 20 degrees C and pH 7.5, k+1 was 4.7 X 10(6)M-1-S-1 and k-1 was 30s-1. Both the ES and the ES* complexes react rapidly with 1.7 mM-glyceraldehyde 3-phosphate, the reaction being practically complete in 40 ms. This shows that the ES* complex is not a dead-end complex. Evidence was also provided that
aldolase
binds and utilizes only the keto form of dihydroxyacetone phosphate.
...
PMID:Fructose 1,6-bisphosphate aldolase from rabbit muscle. The isomerization of the enzyme-dihydroxyacetone phosphate complex. 59 48
Steady-state kinetic measurements have shown that 8-azido-1,N6-ethenoadenosine 5'-triphosphate (8-N3-epsilon ATP) can be noncovalently bound to rabbit muscle fructose 1,6-bisphosphate
aldolase
with Ki = 0.075 mM at pH 8.5. This binding is purely competitive with substrate and occurs at the strong binding site for mononucleotides. Photoaffinity labeling of
aldolase
in the presence of 8-azido-1,N6-ethenoadenosine 5'-triphosphate results in inactivation of the enzyme. Aldolase is protected against modification in the presence of the inhibitors
hexitol
1,6-bisphosphate or ATP. The labeling is saturable, and a good correlation is observed between the loss of enzymatic activity and the incorporation of 8-N3-epsilon ATP into
aldolase
. In addition,
aldolase
loses its ability to bind to phosphocellulose following modification. Digestion of labeled protein with trypsin, chymotrypsin, and cyanogen bromide revealed substantial modification of peptide 259-269. Thr-265 was identified as the residue that was covalently modified by 8-N3-epsilon ATP. On the basis of these results and other data we propose a model for the mononucleotide binding site.
...
PMID:Photoaffinity labeling of rabbit muscle fructose-1,6-bisphosphate aldolase with 8-azido-1,N6-ethenoadenosine 5'-triphosphate. 365 92
A temperature-induced non-denaturing conformational transition in rabbit muscle
aldolase
has been as subject of discussion and controversy for some period of time. In this study the temperature dependence of the reactivity of
aldolase
SH groups is investigated in order to detect subtle changes in the enzyme conformation. For model thiol-containing systems such as cysteine, glutathione and bovine serum albumin, linear Arrhenius plots have been obtained for the reaction with 5,5'-dithiobis(2-nitrobenzoic acid). On the other hand, for rabbit muscle pyruvate kinase, a protein which undergoes temperature-induced conformational transition, the plot obtained is nonlinear with a break at the temperature (18 degrees C) close to that reported earlier. In the case of
aldolase
the Arrhenius plots for three slowly reacting SH groups (Cys-72, 289, 338) and a fast reacting group (Cys-239) are nonlinear with a break at about 26-27 degrees C. The fluorescence measurements show that a plot of the fluorescence intensity of tryptophan residues versus temperature exhibits a break at the same temperature. It is shown that the observed conformational change is fully reversible. In the presence of the competitive inhibitor
hexitol
1,6-bisphosphate, which is known to protect Cys-72 and Cys-338 from chemical modification, the Arrhenius plot exhibits a break for the fast reacting Cys-239 residue and is linear for the slowly reacting Cys-289. It is found that 0.6 M urea increases the transition temperature for all exposed SH groups of
aldolase
. The above results show that at several points in the
aldolase
molecule, including the active-site region, an abrupt change of microenvironments takes place with temperature. The competitive inhibitor protects a portion of
aldolase
molecule against the thermal transition.
...
PMID:Temperature-induced conformational transition in rabbit muscle aldolase studied by temperature dependence of sulfhydryl reactivity. 402 38
An additional indication in favour of interaction between sequential glycolytic enzymes is provided by the mutual enhancement of
aldolase
and glyceraldehyde 3-phosphate dehydrogenase activities. The efficiency of
aldolase
as the activator is progressively affected by the presence of its substrate, fructose-1,6-diphosphate, and its structural analogue,
hexitol
-1,6-diphosphate. Such interrelation of two sequential glycolytic enzymes can originate from their conformational interadjustment for the subsequent metabolic channeling between them.
...
PMID:Some evidence in favour of the partnership between rabbit muscle aldolase and glyceraldehyde 3-phosphate dehydrogenase in the consecutive reactions. 778 86
In enteric bacteria, the
hexitol
galactitol (Gat) (formerly dulcitol) is taken up through enzyme II (II(Gat)) of the phosphoenolpyruvate-dependent phosphotransferase system (PTS), and accumulated as galactitol 1-phosphate (Gat1P). The gat genes involved in galactitol metabolism have been isolated from the wild-type isolate Escherichia coli EC3132 and cloned on a 7.8-kbp PstI DNA fragment. They comprise six complete open reading frames and one truncated open reading frame in the order gatYZABCDR'. The genes gatABC code for the proteins GatA (150 residues) and GatB (94 residues), which correspond to the hydrophilic domains IIA(Gat) and IIB(Gat), and GatC, which represents a membrane-bound transporter domain IIC(Gat) (35 kDa, 427 residues). The three polypeptides together constitute a II(Gat) of average size (671 residues). Gene gatD codes for a Gat1P-specific NAD-dependent dehydrogenase (38 kDa, 346 residues), gatZ codes for a protein (42 kDa, 378 residues) of unknown function, and gatY (31 kDa, 286 residues) codes for a D-tagatose-1,6-bisphosphate
aldolase
with similarity to other known ketose-bisphosphate aldolases. The truncated gatR' gene, whose product shows similarity to the glucitol repressor GutR, closely resembles a gatR gene fragment from E. coli K-12. The gat genes map in both organisms at similar positions, in E. coli K-12, where they are transcribed counterclockwise at precisely 46.7 min or 2,173 to 2,180 kbp. The genes are expressed constitutively in both strains, probably due to a mutation(s) in gatR. Transcription initiation sites for the gatYp and the gatRp promoters were determined by primer extension analysis.
...
PMID:Molecular analysis of the gat genes from Escherichia coli and of their roles in galactitol transport and metabolism. 895 98
Crystal structures were determined to 1.8 A resolution of the glycolytic enzyme fructose-1,6-bis(phosphate)
aldolase
trapped in complex with its substrate and a competitive inhibitor, mannitol-1,6-bis(phosphate). The enzyme substrate complex corresponded to the postulated Schiff base intermediate and has reaction geometry consistent with incipient C3-C4 bond cleavage catalyzed Glu-187, which is adjacent by to the Schiff base forming Lys-229. Atom arrangement about the cleaved bond in the reaction intermediate mimics a pericyclic transition state occurring in nonenzymatic aldol condensations. Lys-146 hydrogen-bonds the substrate C4 hydroxyl and assists substrate cleavage by stabilizing the developing negative charge on the C4 hydroxyl during proton abstraction.
Mannitol
-1,6-bis(phosphate) forms a noncovalent complex in the active site whose binding geometry mimics the covalent carbinolamine precursor. Glu-187 hydrogen-bonds the C2 hydroxyl of the inhibitor in the enzyme complex, substantiating a proton transfer role by Glu-187 in catalyzing the conversion of the carbinolamine intermediate to Schiff base. Modeling of the acyclic substrate configuration into the active site shows Glu-187, in acid form, hydrogen-bonding both substrate C2 carbonyl and C4 hydroxyl, thereby aligning the substrate ketose for nucleophilic attack by Lys-229. The multifunctional role of Glu-187 epitomizes a canonical mechanistic feature conserved in Schiff base-forming aldolases catalyzing carbohydrate metabolism. Trapping of tagatose-1,6-bis(phosphate), a diastereoisomer of fructose 1,6-bis(phosphate), displayed stereospecific discrimination and reduced ketohexose binding specificity. Each ligand induces homologous conformational changes in two adjacent alpha-helical regions that promote phosphate binding in the active site.
...
PMID:High resolution reaction intermediates of rabbit muscle fructose-1,6-bisphosphate aldolase: substrate cleavage and induced fit. 1587 69
The essential and ubiquitous enzyme fructose bisphosphate aldolase (FBPA) has been a good target for controlling the various types of infections caused by pathogens and parasites. The parasitic infections of nematodes are the major concern of scientific community, leading to biochemical characterization of this enzyme. In this work we have developed a small dataset of all types of FBPA sequences collected from publically available databases (EMBL, NCBI and Uni-Port). The Phylogenetic study shows that evolutionary relationships among sequences of FBPA are clustered into three main groups. FBPA sequences of Globodera rostochiensis (FBPA_GR) and Heterodera glycines (FBPA_HG) are placed in group II, sharing the similar evolutionary relationship. The catalytic mechanism of these enzymes depends upon which class of
aldolase
, it belongs. The class of enzyme has been confirmed on the basis of sequences and structural similarity with template structure of class I FBPA. To confirm catalytic mechanism of above said model structures, the known substrate fructose-1, 6-bisphosphate (FBP) and competitive inhibitor
Mannitol
-1, 6 bisphosphate (MBP) were docked at known catalytic site of enzyme of interest. The comparative docking analysis shows that enzyme-substrate complex is forming similar Schiff base intermediate and conducts C(3)-C(4) bond cleavage by forming Hydrogen bonding with reaction catalyzing Glu-191, reactive Lys-150, and Schiff base forming Lys-233. On the other hand enzymeinhibitor noncovalent complex is forming cabinolamine precursor and the proton transfer by the formation of hydrogen bond between MBP O(2) with Glu191 enabling stabilization of cabinolamine transition state, which confirms the similar inhibition mechanism. Thus we conclude that Plant Parasitic Nematodes (PPNs) have evolutionary and functional relationship with the class I
aldolase
enzyme. Hence, FBPA can be targeted to control plant parasitic nematodes.
...
PMID:Evolutionary and functional analysis of fructose bisphosphate aldolase of plant parasitic nematodes. 2339 Mar 37
