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Query: EC:1.5.1.3 (
dihydrofolate reductase
)
5,819
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We report here the Raman spectra of NADPH,
NADP+
, 3-acetylpyridine adenine dinucleotide (AcPdADP+), NADH and a fragment of these molecules, 2'-phospho-adenosine-5'-diphosphoribose (Ado2'p5'ppRib), bound to Escherichia coli
dihydrofolate reductase
(
DHFR
). The positions that are observed for the bound adenosine 'triplet' bands are consistent with a protein binding pocket for this group which is quite hydrophobic in nature. No binding effect is observed on Raman bands associated with the nicotinamide group of
NADP+
as a binary complex with
DHFR
, suggesting very loose, if any, binding of this group. In contrast, changes in the Raman spectrum of the nicotinamide group of
NADP+
bound to an inhibitor (trimethoprim) ternary complex of
DHFR
are clearly observed which indicate substantial binding interaction. The carboxamide group of bound NADPH (and NADH) adopts the trans conformation. A 35-cm-1 upshift is observed in the rocking motion of the carboxamide -NH2 group of NADPH, and a 5-cm-1 upward shift is seen in the C=O stretch mode of AcPdADP+ upon binding to the enzyme-trimethoprim complex. These results suggest that the -NH2 group of the carboxamide moiety is more tightly hydrogen bonded in the protein binding pocket than in solution while that of the C=O group is less tightly hydrogen bonded; these hydrogen bonds would appear to be responsible for holding the nicotinamide headgroup in place properly for catalysis. We have compared this with the results obtained previously in other protein complexes, and interpret the observed shifts in these bands as a measure of the hydrogen bonding enthalpy of the -NH2 and C=O groups with their protein environments. Perhaps surprisingly, the magnitude of the hydrogen bonding enthalpy takes on a limited number of discrete values over five protein complexes rather than over a continuous range. The effect that this has on the catalytic properties of
DHFR
and the other NAD dehydrogenases that we have studied to date, particularly their stereochemistry, is discussed. A small downward shift is observed for the P = O stretch of the 2'-phosphate moiety of
NADP
. This indicates that the 2'-phosphate moiety binds to
DHFR
in the dianionic form. Furthermore, the local enthalpic interaction that the 2'-phosphate group has with protein is stronger than its interaction with water.
...
PMID:A study of the binding of NADP coenzymes to dihydrofolate reductase by raman difference spectroscopy. 834 89
We report the frequent occurrence in proteins of motifs consisting of either 9-membered or 11-membered rings that involve the side-chain amide groups of asparagine and glutamine residues. The syn CO and NH groups of these amide groups are hydrogen-bonded to the main-chain NH and CO groups of other amino acid residues. The main-chain part of both the 9-membered and 11-membered rings has the conformation of a beta-strand. One such ring motifs occurs, on average, in half of all the proteins we examined. Similar conformations are found for most examples of the 9-membered and 11-membered rings. One of the 11-membered rings is distinct, compared to the others, in that its main-chain part has a mirror-image conformation. Another of the 11-membered rings occurs at the interior of the variable domains of some antibodies and assists in linking the two beta-sheets. We observe one 9-membered ring structure in a
dihydrofolate reductase
complex in which the amide in the nicotinamide group of the ligand
NADP
is bound to the enzyme. Groups that can form hydrogen bonds in a similar way to amide groups occur in several nucleotide bases; we find one example of a 9-membered ring involving adenine and main-chain atoms in the FAD-protein complex of glutathione reductase. Both have conformations like those of the other 9-membered rings.
...
PMID:Common ring motifs in proteins involving asparagine or glutamine amide groups hydrogen-bonded to main-chain atoms. 851 58
The reaction catalyzed by Escherichia coli
dihydrofolate reductase
(ecDHFR) cycles through five detectable kinetic intermediates: holoenzyme, Michaelis complex, ternary product complex, tetrahydrofolate (THF) binary complex, and THF.NADPH complex. Isomorphous crystal structures analogous to these five intermediates and to the transition state (as represented by the methotrexate-NADPH complex) have been used to assemble a 2.1 A resolution movie depicting loop and subdomain movements during the catalytic cycle (see Supporting Information). The structures suggest that the M20 loop is predominantly closed over the reactants in the holoenzyme, Michaelis, and transition state complexes. But, during the remainder of the cycle, when nicotinamide is not bound, the loop occludes (protrudes into) the nicotinamide-ribose binding pocket. Upon changing from the closed to the occluded conformation, the central portion of the loop rearranges from beta-sheet to 3(10) helix. The change may occur by way of an irregularly structured open loop conformation, which could transiently admit a water molecule into position to protonate N5 of dihydrofolate. From the Michaelis to the transition state analogue complex, rotation between two halves of ecDHFR, the adenosine binding subdomain and loop subdomain, closes the (p-aminobenzoyl)glutamate (pABG) binding crevice by approximately 0.5 A. Resulting enhancement of contacts with the pABG moiety may stabilize puckering at C6 of the pteridine ring in the transition state. The subdomain rotation is further adjusted by cofactor-induced movements (approximately 0.5 A) of helices B and C, producing a larger pABG cleft in the THF.NADPH analogue complex than in the THF analogue complex. Such movements may explain how THF release is assisted by NADPH binding. Subdomain rotation is not observed in vertebrate
DHFR
structures, but an analogous loop movement (residues 59-70) appears to similarly adjust the pABG cleft width, suggesting that these movements are important for catalysis. Loop movement, also unobserved in vertebrate
DHFR
structures, may preferentially weaken
NADP+
vs NADPH binding in ecDHFR, an evolutionary adaptation to reduce product inhibition in the
NADP+
rich environment of prokaryotes.
...
PMID:Loop and subdomain movements in the mechanism of Escherichia coli dihydrofolate reductase: crystallographic evidence. 901 74
The ternary complex of Lactobacillus casei
dihydrofolate reductase
(
DHFR
) with folate and
NADP+
exists as a mixture of three interconverting forms (I, IIa and IIb) whose relative populations are pH dependent, with an effective pK of approx. 6. To investigate the role of Asp26 in this pH dependence we have measured the 13C chemical shifts of [2,4a,7,9-(13)C4]folate in its complex with the mutant
DHFR
Asp26 --> Asn and
NADP+
. Only a single form of the complex is detected and this has the characteristics of form I, an enol form with its N1 unprotonated. A study of the pH dependence of the 13C chemical shifts of
DHFR
selectively labelled with [4-(13)C]aspartic acid in its complex with folate and
NADP+
indicates that no Asp residue has a pK value greater than 5.4. Two of the Asp CO2 signals appear as non-integral signals with chemical shifts typical of non-ionised COOH groups and with a pH dependence characteristic of the slow exchange equilibria previously characterised for signals in forms I and IIb (or IIa). It is proposed that the protonation/deprotonation controlling the equilibria involves the O4 position of the folate and that Asp26 influences this indirectly by binding in its CO2 form to the protonated N1 group of folate in forms I and IIa thus reducing the pK involving protonation at the O4 position to approx. 6. These findings indicate that, in forms I and IIa of the ternary complex, folate binds to
DHFR
in a very similar way to methotrexate.
...
PMID:The influence of aspartate 26 on the tautomeric forms of folate bound to Lactobacillus casei dihydrofolate reductase. 903 86
We have employed deuterium NMR techniques to determine the dynamics of trimethoprim (TMP) in a binary complex with
dihydrofolate reductase
(
DHFR
) or in a ternary complex with
DHFR
and cofactor
NADP+
in the fully hydrated state. TMP was deuterated at the following positions: (2',6'-D2)TMP, (3'-Ome-D3)TMP and (3',4'-Ome-D6)TMP. Dynamics of TMP were deduced from lineshape simulation and relaxation measurements of the deuterium NMR powder spectra of the three samples obtained at various temperatures. The results showed that in the polycrystalline state the TMP molecule is very rigid. The only detectable motion is the methyl group rotation at a rate of 10(10) s-1 at 25 degrees C, as determined from simulation of the partially relaxed powder patterns. When bound to
DHFR
a residual deuterium quadrupole splitting of 140 kHz was observed for (2',6'-D2)TMP at temperatures up to 30 degrees C, suggesting that the benzyl ring in the bound state is also very rigid. In contrast, in the binary complex with
DHFR
the methoxyl groups of TMP undergo librational motion of 10(7) s-1 about the C3-O bond at an amplitude of 54 degrees for the meta methoxyl group and about the C4-O bond at an amplitude of 70 degrees and similar rate for the para methoxyl group at 30 degrees C. The presence of the cofactor,
NADP+
, appears to tighten up the binding pocket such that the motion freedom of TMP is more restricted. The rigidity of TMP in a protein complex as revealed by our deuterium NMR results is in accord with the tight binding of TMP to
DHFR
.
...
PMID:Dynamics of trimethoprim bound to dihydrofolate reductase--a deuterium NMR study. 905 Jan 57
Two-dimensional heteronuclear (1H-15N) nuclear magnetic relaxation studies of
dihydrofolate reductase
(
DHFR
) from Escherichia coli have demonstrated that glycine-121 which is 19 A from the catalytic center of the enzyme has large-amplitude backbone motions on the nanosecond time scale [Epstein, D. M., Benkovic, S. J., and Wright, P. E. (1995) Biochemistry 34, 11037-11048]. In order to probe the dynamic-function relationships of this residue, we constructed a mutant enzyme in which this glycine was changed to valine. Equilibrium binding studies indicated that the Val-121 mutant retained wild-type binding properties with respect to dihydrofolate and tetrahydrofolate; however, binding to NADPH and
NADP+
was decreased by 40-fold and 2-fold, respectively, relative to wild-type
DHFR
. Single-turnover experiments indicated that hydride transfer was reduced by 200-fold to a rate of 1.3 s-1 and was the rate-limiting step in the steady state. Interestingly, pre-steady-state kinetic analysis of the Val-121 mutant revealed a conformational change which preceded chemistry that occurred at a rate of 3.5 s-1. If this step exists in the kinetic mechanism of the wild-type enzyme, then it would be predicted to occur at a rate of approximately 2000 s-1. Glycine-121 was also changed to alanine, serine, leucine, and proline. While the Ala-121 and Ser-121 mutants behaved similar to wild-type
DHFR
, the Leu-121 and Pro-121 mutants behaved like Val-121
DHFR
in that hydride transfer was the rate-limiting step in the steady state and a conformational change preceding chemistry was observed. Finally, insertion of a glycine or valine between amino acids 121 and 122 produced mutant enzymes with properties similar to wild-type or Val-121 DHFRs, respectively. Taken together, these results provide compelling evidence for dynamic coupling of a remote residue to kinetic events at the active site of
DHFR
.
...
PMID:Evidence for a functional role of the dynamics of glycine-121 of Escherichia coli dihydrofolate reductase obtained from kinetic analysis of a site-directed mutant. 939 9
Escherichia coli
dihydrofolate reductase
contains five tryptophan residues that are spatially distributed throughout the protein and located in different secondary structural elements. When these tryptophans are replaced with [6-19F]tryptophan, distinct native and unfolded resonances can be resolved in the 1-D 19F NMR spectra. Using site-directed mutagenesis, these resonances have been assigned to individual tryptophans [Hoeltzli, S. D., and Frieden, C. (1994) Biochemistry 33, 5502-5509], allowing both the native and unfolded environments of each tryptophan to be monitored during the refolding process. We have previously used these assignments and stopped-flow NMR to investigate the behavior of specific regions of the protein during refolding of apo
dihydrofolate reductase
from urea in real time. These studies now have been extended to investigate the real time behavior of specific regions of the protein during refolding of
dihydrofolate reductase
in the presence of either
NADP+
or dihydrofolate. As observed for the apoprotein, in the presence of either ligand, unfolded resonance intensities present at the first observed time point (1.5 s) disappear in two phases similar to those monitored by either stopped-flow fluorescence or circular dichroism spectroscopy. The existence of unfolded resonances which disappear slowly indicates that an equilibrium exists between the unfolded side chain environment and one or more intermediates, and that formation of at least one intermediate is cooperative. The results of this study are consistent with previous fluorescence studies demonstrating that dihydrofolate binds at an earlier step in the folding process than does
NADP+
[Frieden, C. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 4413-4416] and provide a structural interpretation of the previous results. In the apoprotein as well as in the presence of either ligand, the protein folds via at least one cooperatively formed, solvent-protected intermediate which contains secondary structure. In the presence of
NADP+
, a stable native-like side chain environment forms in the regions around tryptophans 30, 133, and 47 in an intermediate which cannot bind
NADP+
tightly. Native side chain environment forms in the regions around tryptophans 22 and 74 only in the structure which is able to bind
NADP+
tightly. In the presence of dihydrofolate, stable native-like side chain environment forms cooperatively in the regions around each tryptophan in a non-native intermediate which must undergo a conformational change prior to binding
NADP+
. The presence of ligands influences the processes which occur during the folding of
dihydrofolate reductase
, and the ligand may in effect serve as part of the hydrophobic core.
...
PMID:Refolding of [6-19F]tryptophan-labeled Escherichia coli dihydrofolate reductase in the presence of ligand: a stopped-flow NMR spectroscopy study. 942 60
Pteridine reductase 1 (PTR1) is a novel broad spectrum enzyme of pterin and folate metabolism in the protozoan parasite Leishmania. Overexpression of PTR1 confers methotrexate resistance to these protozoa, arising from the enzyme's ability to reduce dihydrofolate and its relative insensitivity to methotrexate. The kinetic mechanism and stereochemical course for the catalyzed reaction confirm PTR1's membership within the short chain dehydrogenase/reductase (SDR) family. With folate as a substrate, PTR1 catalyzes two rounds of reduction, yielding 5,6,7, 8-tetrahydrofolate and oxidizing 2 equiv of NADPH. Dihydrofolate accumulates transiently during folate reduction and is both a substrate and an inhibitor of PTR1. PTR1 transfers the pro-S hydride of NADPH to carbon 6 on the si face of dihydrofolate, producing the same stereoisomer of THF as does
dihydrofolate reductase
. Product inhibition and isotope partitioning studies support an ordered ternary complex mechanism, with NADPH binding first and
NADP+
dissociating after the reduced pteridine. Identical kinetic mechanisms and NAD(P)H hydride chirality preferences are seen with other SDRs. An observed tritium effect upon V/K for reduction of dihydrofolate arising from isotopic substitution of the transferred hydride was suppressed at a high concentration of dihydrofolate, consistent with a steady-state ordered kinetic mechanism. Interestingly, half of the binary enzyme-NADPH complex appears to be incapable of rapid turnover. Fluorescence quenching results also indicate the existence of a nonproductive binary enzyme-dihydrofolate complex. The nonproductive complexes observed between PTR1 and its substrates are unique among members of the SDR family and may provide leads for developing antileishmanial therapeutics.
...
PMID:Leishmania major pteridine reductase 1 belongs to the short chain dehydrogenase family: stereochemical and kinetic evidence. 952 31
Analysis of the
dihydrofolate reductase
(
DHFR
) complex with folate by two-dimensional heteronuclear (1H-15N) nuclear magnetic relaxation revealed that isolated residues exhibit diverse backbone fluctuations on the nanosecond to picosecond time scale [Epstein, D. M., Benkovic, S. J., and Wright, P. E. (1995) Biochemistry 34, 11037-11048]. These dynamical features may be significant in forming the Michaelis complex. Of these residues, glycine 121 displays large-amplitude backbone motions on the nanosecond time scale. This amino acid, strictly conserved for prokaryotic DHFRs, is located at the center of the betaF-betaG loop. To investigate the catalytic importance of this residue, we report the effects of Gly121 deletion and glycine insertion into the modified betaF-betaG loop. Relative to wild type, deletion of Gly121 dramatically decreases the rate of hydride transfer 550-fold and the strength of cofactor binding 20-fold for NADPH and 7-fold for
NADP+
. Furthermore, DeltaG121
DHFR
requires conformational changes dependent on the initial binary complex to attain the Michaelis complex poised for hydride transfer. Surprisingly, the insertion mutants displayed a significant decrease in both substrate and cofactor binding. The introduction of glycine into the modified betaF-betaG loop, however, generally eliminated conformational changes required by DeltaG121
DHFR
to attain the Michaelis complex. Taken together, these results suggest that the catalytic role for the betaF-betaG loop includes formation of liganded complexes and proper orientation of substrate and cofactor. Through a transient interaction with the Met20 loop, alterations of the betaF-betaG loop can orchestrate proximal and distal effects on binding and catalysis that implicate a variety of enzyme conformations participating in the catalytic cycle.
...
PMID:Deletion of a highly motional residue affects formation of the Michaelis complex for Escherichia coli dihydrofolate reductase. 957 47
In several species of protozoa, the catalytic activities for the enzymes
dihydrofolate reductase
(
DHFR
) and thymidylate synthase (TS) reside on a single polypeptide chain constituting a bifunctional thymidylate synthase-
dihydrofolate reductase
enzyme. In most other species, however, these enzymes occur as monofunctional catalytic activities on separate enzymes. In this study, the kinetic reaction scheme for the
dihydrofolate reductase
activity from the bifunctional thymidylate synthase-
dihydrofolate reductase
(TS-DHFR) isolated from the parasite Leishmania major is compared to that of the monofunctional
DHFR
purified from Escherichia coli. Examination using pre-steady-state kinetic methods reveals interesting differences between the bifunctional and monofunctional forms of the
dihydrofolate reductase
enzymes. The rate-limiting step in the kinetic pathway for the monofunctional E. coli enzyme is the release of product, tetrahydrofolate. In contrast, for the L. major bifunctional enzyme, the kinetic step which limits the steady-state turnover is a conformational change associated with the release of
NADP+
. A complete kinetic description for the
dihydrofolate reductase
reaction pathway for the bifunctional enzyme is presented.
...
PMID:Kinetic reaction scheme for the dihydrofolate reductase domain of the bifunctional thymidylate synthase-dihydrofolate reductase from Leishmania major. 972 34
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