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)
Some physical, catalytic, and regulatory properties of ketopantoate hydroxymethyltransferase (5,10-methylenetetrahydrofolate: alpha-ketoisovalerate hydroxymethyltranferase) from Escherichia coli are described. This enzyme catalyzes the reversible synthesis of ketopantoate (Reaction 1), an essential precursor of pantothenic acid. (1) HC(CH3)2COCOO- + 5,10-methylene
tetrahydrofolate
f in equilibrium r HOCH2C(CH3)2COCOO- +
tetrahydrofolate
It has a molecular weight by sedimentation equilibrium of 255,000, a sedimentation coefficient (S20,w) of 11 S, a partial specific volume of 0.74 ml/g, an isoelectric point of 4.4, and an absorbance, (see article), of 0.85. Polyacrylamide gel electrophoresis in sodium dodecyl sulfate and amino acid analyses give a subunit molecular weight of 27,000 and 25,700, respectively; both procedures indicate the presence of 10 identical subunits. The NH2-terminal sequence is Met-Tyr---. The enzyme is stable and active over a broad pH range, with an optimum from 7.0 to 7.6. It requires Mg2+ for activity; Mn2+, Co2+, Zn2+ are progressively less active. The enzyme is not inactivated by borohydride reduction in the presence of excess substrates, i.e. it is a Class II
aldolase
. Reaction 1f is partially inhibited by concentrations of formaldehyde (0.8 mM) and
tetrahydrofolate
(0.38 mM) below or near the Km values, apparent Km values are 0.18, 1.1 and 5.9 mM for
tetrahydrofolate
, alpha-ketoisovalerate, and formaldehyde, respectively. For Reaction 1r, apparent Km values are 0.16 and 0.18 mM, respectively, for ketopantoate and
tetrahydrofolate
, and the saturation curves for both substrates show positive cooperativity. Forward and reverse reactions occur at similar maximum velocities (Vmax approximately equal to 8 mumol of ketopantoate formed or decomposed per min per mg of enzyme at 37 degrees). Only 1-
tetrahydrofolate
is active in Reaction 1; d-
tetrahydrofolate
, folate, and methotrexate were neither active nor inhibitory. However, 1-
tetrahydrofolate
was effectively replaced with conjugates containing 1 to 6 additional glutamate residues; of these, tetrahydropterolpenta-, tetra-, and triglutamate were effective at lower concentrations than
tetrahydrofolate
itself; they were also the predominant conjugates of
tetrahydrofolate
present in E. coli. Alpha-Ketobutyrate, alpha-ketovalerate, and alpha-keto-beta-methylvalerate replaced alpha-ketoisovalerate as substrates; pyruvate was inactive as a substrate, but like isovalerate, 3-methyl-2-butanone and D- or L-valine, inhibited Reaction 1. the transferase has regulatory properties expected of an enzyme catalyzing the first committed step in a biosynthetic pathway. Pantoate (greater than or equal to 500 muM) and coenzyme A (above 1 mM) all inhibit; the Vmax is decreased, Km is increased, and the cooperativity for substrate (ketopantoate) is enhanced. Catalytic activity of the transferase is thus regulated by the products of the reaction path of which it is one component; transferase synthesis is not repressed by growth in the presence of pantothenate.
...
PMID:Ketopantoate hydroxymethyltransferase. II. Physical, catalytic, and regulatory properties. 0 63
L-allo-Threonine
aldolase
(L-allo-threonine acetaldehyde-lyase), which exhibited specificity for L-allo-threonine but not for L-threonine, was purified from a cell-free extract of Aeromonas jandaei DK-39. The purified enzyme catalyzed the aldol cleavage reaction of L-allo-threonine (K(m) = 1.45 mM, Vmax = 45.2 mumol min-1 mg-1). The activity of the enzyme was inhibited by carbonyl reagents, which suggests that pyridoxal-5'-phosphate participates in the enzymatic reaction. The enzyme does not act on either L-serine or L-threonine, and thus it can be distinguished from serine hydroxy-methyltransferase (L-serine:
tetrahydrofolate
5,10-hydroxy-methyltransferase, EC 2.1.2.1) or L-threonine aldolase (EC 4.1.2.5).
...
PMID:Purification and characterization of L-allo-threonine aldolase from Aeromonas jandaei DK-39. 922 60
An open reading frame located at 69.0 kilobases on the Escherichia coli chromosome was shown to code for dihydroneopterin aldolase, catalyzing the conversion of 7,8-dihydroneopterin to 6-hydroxymethyl-7,8-dihydropterin in the biosynthetic pathway of
tetrahydrofolate
. The gene was subsequently designated folB. The FolB protein shows 30% identity to the paralogous dihydroneopterin-triphosphate epimerase, which is specified by the folX gene located at 2427 kilobases on the E. coli chromosome. The folX and folB gene products were both expressed to high yield in recombinant E. coli strains, and the recombinant proteins were purified to homogeneity. Both enzymes form homo-octamers. Aldolase can use L-threo-dihydroneopterin and D-erythro-dihydroneopterin as substrates for the formation of 6-hydroxymethyldihydropterin, but it can also catalyze the epimerization of carbon 2' of dihydroneopterin and dihydromonapterin at appreciable velocity. Epimerase catalyzes the epimerization of carbon 2' in the triphosphates of dihydroneopterin and dihydromonapterin. However, the enzyme can also catalyze the cleavage of the position 6 side chain of several pteridine derivatives at a slow rate. Steady-state kinetic parameters are reported for the various enzyme-catalyzed reactions. We propose that the polarization of the 2'-hydroxy group of the substrate could serve as the initial reaction step for the
aldolase
as well as for the epimerase activity. A deletion mutant obtained by targeting the folX gene of E. coli has normal growth properties on complete medium as well as on minimal medium. Thus, the physiological role of the E. coli epimerase remains unknown. The open reading frame ygiG of Hemophilus influenzae specifies a protein with the catalytic properties of an
aldolase
. However, the genome of H. influenzae does not specify a dihydroneopterin-triphosphate epimerase.
...
PMID:Biosynthesis of pteridines in Escherichia coli. Structural and mechanistic similarity of dihydroneopterin-triphosphate epimerase and dihydroneopterin aldolase. 965 28
7,8-Dihydroneopterin
aldolase
catalyzes the formation of the
tetrahydrofolate
precursor, 6-hydroxymethyl-7,8-dihydropterin, and is a potential target for antimicrobial and anti-parasite chemotherapy. The last step of the enzyme-catalyzed reaction is believed to involve the protonation of an enol type intermediate. In order to study the stereochemical course of that reaction step, [1',2',3',6,7-13C5]dihydroneopterin was treated with
aldolase
in deuterated buffer. The resulting, partially deuterated [6alpha,6,7-13C3]6-hydroxymethyl-7,8-dihydropterin was converted to partially deuterated 6-(R)-[6,7,9,11-13C4]5,10-methylenetetrahydropteroate by a sequence of three enzyme-catalyzed reactions followed by treatment with [13C]formaldehyde. The product was analyzed by multinuclear NMR spectroscopy. The data show that the carbinol group of enzymatically formed 6-hydroxymethyl-dihydropterin contained 2H predominantly in the pro-S position.
...
PMID:Biosynthesis of tetrahydrofolate. Stereochemistry of dihydroneopterin aldolase. 1203 64
Dihydroneopterin aldolase (DHNA) catalyses a retroaldol reaction yielding 6-hydroxymethyl-7,8-dihydropterin, a biosynthetic precursor of the vitamin,
tetrahydrofolate
. The enzyme is a potential target for antimicrobial and anti-parasite chemotherapy. A gene specifying a dihydroneopterin aldolase from Arabidopsis thaliana was expressed in a recombinant Escherichia coli strain. The recombinant protein was purified to apparent homogeneity and crystallised using polyethylenglycol as the precipitating agent. The crystal structure was solved by X-ray diffraction analysis at 2.2A resolution. The enzyme forms a D(4)-symmetric homooctamer. Each polypeptide chain is folded into a single domain comprising an antiparallel four-stranded beta-sheet and two long alpha-helices. Four monomers are arranged in a tetrameric ring, and two of these rings form a hollow cylinder. Well defined purine derivatives are found at all eight topologically equivalent active sites. The subunit fold of the enzyme is related to substructures of dihydroneopterin triphosphate epimerase, GTP cyclohydrolase I, and pyruvoyltetrahydropterin synthase, which are all involved in the biosynthesis of pteridine type cofactors, and to urate oxidase, although some members of that superfamily have no detectable sequence similarity. Due to structural and mechanistical differences of DHNA in comparison with class I and class II aldolases, a new
aldolase
class is proposed.
...
PMID:Biosynthesis of tetrahydrofolate in plants: crystal structure of 7,8-dihydroneopterin aldolase from Arabidopsis thaliana reveals a novel adolase class. 1516 63
By screening microorganisms that are capable of assimilating alpha-methyl-DL-serine, we detected alpha-methylserine
aldolase
in Ralstonia sp. strain AJ110405, Variovorax paradoxus AJ110406, and Bosea sp. strain AJ110407. A homogeneous form of this enzyme was purified from Ralstonia sp. strain AJ110405, and the gene encoding the enzyme was cloned and expressed in Escherichia coli. The enzyme appeared to be a homodimer consisting of identical subunits, and its molecular mass was found to be 47 kDa. It contained 0.7 to 0.8 mol of pyridoxal 5'-phosphate per mol of subunit and could catalyze the interconversion of alpha-methyl-L-serine to L-alanine and formaldehyde in the absence of
tetrahydrofolate
. Formaldehyde was generated from alpha-methyl-L-serine but not from alpha-methyl-D-serine, L-serine, or D-serine. Alpha-methyl-L-serine synthesis activity was detected when L-alanine was used as the substrate. In contrast, no activity was detected when D-alanine was used as the substrate. In the alpha-methyl-L-serine synthesis reaction, the enzymatic activity was inhibited by an excess amount of formaldehyde, which was one of the substrates. We used cells of E. coli as a whole-cell catalyst to express the gene encoding alpha-methylserine
aldolase
and effectively obtained a high yield of optically pure alpha-methyl-L-serine using L-alanine and formaldehyde.
...
PMID:Purification and gene cloning of alpha-methylserine aldolase from Ralstonia sp. strain AJ110405 and application of the enzyme in the synthesis of alpha-methyl-L-serine. 1895 81
Tetrahydrofolate cofactors are required for one carbon transfer reaction involved in the synthesis of purines, amino acids, and thymidine. Inhibition of
tetrahydrofolate
biosynthesis is a powerful therapeutic strategy in the treatment of several diseases, and the possibility of using antifolates to inhibit enzymes from Mycobacterium tuberculosis has been explored. This work focuses on the study of the first enzyme in
tetrahydrofolate
biosynthesis that is unique to bacteria, dihydroneopterin aldolase (MtDHNA). This enzyme requires no metals or cofactors and does not form a protein-mediated Schiff base with the substrate, unlike most aldolases. Here, we were able to demonstrate that the reaction catalyzed by MtDHNA generates three different pterin products, one of which is not produced by other wild-type DHNAs. The enzyme-substrate complex partitions 51% in the first turnover to form the
aldolase
products, 24% to the epimerase product and 25% to the oxygenase products. The
aldolase
reaction is strongly pH dependent, and apparent pK(a) values were obtained for the first time for this class of enzyme. Furthermore, chemistry is rate limiting for the
aldolase
reaction, and the analysis of solvent kinetic isotope effects in steady-state and pre-steady-state conditions, combined with proton inventory studies, revealed that two protons and a likely solvent contribution are involved in formation and breakage of a common intermediate. This study provides information about the plasticity required from a catalyst that possesses high substrate specificity while being capable of utilizing two distinct epimers with the same efficiency to generate five distinct products.
...
PMID:One substrate, five products: reactions catalyzed by the dihydroneopterin aldolase from Mycobacterium tuberculosis. 2315 Sep 85
Glycine cleavage system (GCS) occupies a key position in one-carbon (C1) metabolic pathway and receives great attention for the use of C1 carbons like formate and CO
2
via synthetic biology. In this work, we demonstrate that formaldehyde exists as a substantial byproduct of the GCS reaction cycle. Three causes are identified for its formation. First, the principal one is the decomposition of
N
5
,N
10
-methylene-
tetrahydrofolate
(5,10-CH
2
-
THF
) to form formaldehyde and
THF
. Increasing the rate of glycine cleavage promotes the formation of 5,10-CH
2
-
THF
, thereby increasing the formaldehyde release rate. Next, formaldehyde can be produced in the GCS even in the absence of
THF
. The reason is that T-protein of the GCS can degrade methylamine-loaded H-protein (H
int
) to formaldehyde and ammonia, accompanied with the formation of dihydrolipoyl H-protein (H
red
), but the reaction rate is less than 0.16% of that in the presence of
THF
. Increasing T-protein concentration can speed up the release rate of formaldehyde by H
int
. Finally, a certain amount of formaldehyde can be formed in the GCS due to oxidative degradation of
THF
. Based on a formaldehyde-dependent
aldolase
, we elaborated a glycine-based one carbon metabolic pathway for the biosynthesis of 1,3-propanediol (1,3-PDO) in vitro. This work provides quantitative data and mechanistic understanding of formaldehyde formation in the GCS and a new biosynthetic pathway of 1,3-PDO.
...
PMID:Formaldehyde formation in the glycine cleavage system and its use for an aldolase-based biosynthesis of 1,3-prodanediol. 3246 27
Glycine cleavage system (GCS) occupies a key position in one-carbon (C1) metabolic pathway and receives great attention for the use of C1 carbons like formate and CO
2
via synthetic biology. In this work, we demonstrate that formaldehyde exists as a substantial byproduct of the GCS reaction cycle. Three causes are identified for its formation. First, the principal one is the decomposition of N
5
,N
10
-methylene-
tetrahydrofolate
(5,10-CH
2
-
THF
) to form formaldehyde and
THF
. Increasing the rate of glycine cleavage promotes the formation of 5,10-CH
2
-
THF
, thereby increasing the formaldehyde release rate. Next, formaldehyde can be produced in the GCS even in the absence of
THF
. The reason is that T-protein of the GCS can degrade methylamine-loaded H-protein (H
int
) to formaldehyde and ammonia, accompanied with the formation of dihydrolipoyl H-protein (H
red
), but the reaction rate is less than 0.16% of that in the presence of
THF
. Increasing T-protein concentration can speed up the release rate of formaldehyde by H
int
. Finally, a certain amount of formaldehyde can be formed in the GCS due to oxidative degradation of
THF
. Based on a formaldehyde-dependent
aldolase
, we elaborated a glycine-based one carbon metabolic pathway for the biosynthesis of 1,3-propanediol (1,3-PDO) in vitro. This work provides quantitative data and mechanistic understanding of formaldehyde formation in the GCS and a new biosynthetic pathway of 1,3-PDO.
...
PMID:Formaldehyde formation in the glycine cleavage system and its use for an aldolase-based biosynthesis of 1,3-propanediol. 3329 16
