EC:1.5.1.3 - FACTA Search

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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)

To elucidate the role of a flexible loop (residues 64-72) in the stability and function of Escherichia coli dihydrofolate reductase, glycine-67 in this loop was substituted by site-directed mutagenesis with seven amino acids (Ala, Cys, Asp, Leu, Ser, Thr, and Val). The circular dichroism spectra suggested that the confirmation of the native structure was affected by the mutations in both the presence and absence of NADPH. The free energy change of unfolding by urea decreased in the order of G67A > G67S > or = wild-type > or = G67D > G67T > G67C > or = G67L > G67V. The steady-state kinetic parameters for the enzyme reaction, Km and kcat, were only slightly influenced, but the rate of the hydride transfer reaction was significantly changed by the mutations, as revealed by the deuterium isotope effect on the enzyme activity. These results suggest that site 67 in the flexible loop, being very far from the active site, plays an important role in the stability and function of this enzyme. The characteristics of the mutations were discussed in terms of the modified flexibility of the native structure, compared with the results of mutations at site 121 in another flexible loop.
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PMID:Effects of point mutations at the flexible loop glycine-67 of Escherichia coli dihydrofolate reductase on its stability and function. 874 72

Escherichia coli dihydrofolate reductase (ecDHFR, EC1.5.1.3) contains 5 tryptophan residues that have been replaced with 6-19F-tryptophan. Five native and four of the five unfolded tryptophan resonances can be resolved in the 1D 19F NMR spectra and have been assigned [Hoeltzli, S. D., & Frieden, C. (1994) Biochemistry 33, 5502-5509]. This resolution allows the behavior of the native and the unfolded resonances assigned to each individual tryptophan to be monitored during the unfolding or refolding process. We now use these assignments and stopped-flow NMR to investigate the real-time behavior of specific regions of the protein during refolding of DHFR after dilution from 4.6 to 2.3 M urea (midpoint of the transition = 3.8 M) at 5 degrees C. Approximately half of the intensity of each of the four unfolded resonances is present at the first measurable time point (1.5 s). Little native resonance intensity is detectable at this time. The remaining unfolded resonance intensities present then disappear in two phases, with rates similar to the two slowest phases observed by either stopped-flow fluorescence or circular dichroism spectroscopy upon refolding under the same conditions. Substantial total resonance intensity is missing during the first 20 s of the refolding process. The appearance of the majority of native resonance intensity (as assessed by the height of each of the five native tryptophan resonances) is slow and similar for all five tryptophans. In contrast, the largest amplitude changes observed by either stopped-flow far-UV circular dichroism spectroscopy or fluorescence spectroscopy, and the greatest loss of unfolded resonance intensity, occur much more rapidly. We conclude from these studies: (1) that, under these conditions, the unfolded state remains substantially populated after initiation of refolding; (2) that the early steps in refolding involve a solvent protected intermediate containing substantial secondary structure, but (3) that the stable native side chain interactions form slowly and are associated with the final rate-limiting phase of the refolding process. Preliminary analysis of the area of broadened native resonances suggests that these resonances may appear at different rates, indicating that some regions of the protein begin to sample a native-like side chain environment while side chain environment in other regions of the protein remains less ordered. The results of this study are consistent with the earlier studies demonstrating that mobility of side chains is an early step in unfolding [Hoeltzli, S. D., & Frieden, C. (1995) Proc. Natl. Acad. Sci. U.S.A. 92, 9318-9322] and that recovery of enzymatic activity occurs as a late step in the folding process [Frieden, C. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 4413-4416].
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PMID:Real-time refolding studies of 6-19F-tryptophan labeled Escherichia coli dihydrofolate reductase using stopped-flow NMR spectroscopy. 898 23

The interaction of GroEL with urea-unfolded dihydrofolate reductase (DHFR) has been studied in the presence of DHFR substrates by investigating the ability of GroES to release enzyme under conditions where a stable GroES-GroEL-DHFR ternary complex can be formed. In these circumstances, GroES could only partially discharge the DHFR if ADP was present in the solution and approximately half of the DHFR remained bound on the chaperonin. This bound DHFR could be rescued by addition of ATP and KCl into the refolding mixture. The stable ternary complex did not show any significant protection of bound DHFR against proteolysis by Proteinase K. These results are in contrast to those observed with the GroEL-DHFR complex formed by thermal inactivation of DHFR at 45 degrees C in which GroES addition leads to partial protection of bound DHFR. Thus, the method of presentation influences the properties of the bound intermediates. It is suggested that the ability of GroES to bind on the same side of the GroEL double toroid as the target protein and displace it into the central cavity depends on the way the protein-substrate is presented to the GroEL molecule. Therefore, the compact folding intermediate formed by thermal unfolding can be protected against proteolysis after GroES binds to form a ternary complex. In addition, structural changes within GroEL induced by the experimental conditions may contribute to differences in the properties of the complexes. The more open urea-unfolded DHFR binds on the surface of chaperonin and can be displaced into solution by the tighter binding GroES molecule. It is suggested that the state of the unfolded protein when it is presented to GroEL determines the detailed mechanism of its assisted refolding. It follows that individual proteins, having characteristic folding intermediates, can have different detailed mechanisms of chaperonin-assisted folding.
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PMID:Conditions of forming protein complexes with GroEL can influence the mechanism of chaperonin-assisted refolding. 899 21

Chinese hamster dihydrofolate reductase (ch-DHFR) was overexpressed in Escherichia coli DH5 alpha under the transcriptional control of PRPL promoters regulated by temperature-sensitive repressors. The desired recombinant product is soluble and constitutes about 30% of the total soluble proteins of the bacterial cell. With repeated cycles of freezing and thawing as a first step, the purification of the recombinant ch-DHFR to homogeneity requires only one further step, gel filtration on a Sephadex G-75 column with 85-90% enzyme recovery, two to three times higher than that obtained with the commonly used affinity chromatography on a methotrexate-Sepharose column. The purified enzyme migrates as a single protein band on SDS-polyacrylamide gel electrophoresis with approximate mass of 23 kDa, in accord with that calculated from the DNA sequence. The initiation methionine residue at the N-terminus of the enzyme is completely removed by E. coli methionine aminopeptidase as judged by amino-terminal analysis. The steady-state kinetic parameters, dissociation constants for binary complexes of dihydrofolate, NADPH, and methotrexate with ch-DHFR, and the inhibitor constant of methotrexate have also been determined. The enzyme is activated about 4-fold in 3 M urea and about 2.5-fold in 0.5 M guanidine hydrochloride.
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PMID:Soluble expression in Escherichia coli, one-step purification, and characterization of Chinese hamster dihydrofolate reductase. 905 90

The kinetic theory of substrate reaction during modification of enzyme activity has been applied to the study of inactivation kinetics of Chinese hamster dihydrofolate reductase by urea [Tsou (1988) Adv. Enzymol. Relat. Areas Mol. Biol. 61, 381-436]. On the basis of the kinetic equation of substrate reaction in the presence of urea, all microscopic kinetic constants for the free enzyme and enzyme-substrate binary and ternary complexes have been determined. The results of the present study indicate that the denaturation of dihydrofolate reductase by urea follows single-phase kinetics, and changes in enzyme activity and tertiary structure proceed simultaneously in the unfolding process. Both substrates, NADPH and 7,8-dihydrofolate, protect dihydrofolate reductase against inactivation, and enzyme-substrate complexes lose their activity less rapidly than the free enzyme.
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PMID:Inactivation kinetics of dihydrofolate reductase from Chinese hamster during urea denaturation. 918 96

Virtually all studies of the protein-folding reaction add either heat, acid, or a chemical denaturant to an aqueous protein solution in order to perturb the protein structure. When chemical denaturants are used, very high concentrations are usually necessary to observe any change in protein structure. In a solution with such high denaturant concentrations, both the structure of the protein and the structure of the solvent around the protein can be altered. X-ray crystallography is the obvious experimental technique to probe both types of changes. In this paper, we report the crystal structures of dihydrofolate reductase with urea and of ribonuclease A with guanidinium chloride. These two classic denaturants have similar effects on the native structure of the protein. The most important change that occurs is a reduction in the overall thermal factor. These structures offer a molecular explanation for the reduction in mobility. Although the reduction is observed only with the native enzyme in the crystal, a similar decrease in mobility has also been observed in the unfolded state in solution (Makhatadze G, Privalov PL. 1992. Protein interactions with urea and guanidinium chloride: A calorimetric study.
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PMID:The effect of denaturants on protein structure. 926 Feb 85

Molecular dissection was employed to identify minimal independent folding units in dihydrofolate reductase (DHFR) from Escherichia coli. Eight overlapping fragments of DHFR, spanning the entire sequence and ranging in size from 36 to 123 amino acids, were constructed by chemical cleavage. These fragments were designed to examine the effect of tethering multiple elements of secondary structure on folding and to test if the secondary structural domains represent autonomous folding units. CD and fluorescence spectroscopy demonstrated that six fragments containing up to a total of seven alpha-helices or beta-strands and, in three cases, the adenine binding domain (residues 37-86), are largely disordered. A stoichiometric mixture of the two fragments comprising the large discontinuous domain, 1-36 and 87-159, also showed no evidence for folding beyond that observed for the isolated fragments. A fragment containing residues 1-107 appears to have secondary and tertiary structure; however, spontaneous self-association made it impossible to determine if this structure solely reflects the behavior of the monomeric form. In contrast, a monomeric fragment spanning residues 37-159 possesses significant secondary and tertiary structure. The urea-induced unfolding of fragment 37-159 in the presence of 0.5 M ammonium sulfate was found to be a well-defined, two-state process. The observation that fragment 37-159 can adopt a stable native fold with unique, aromatic side-chain packing is quite striking because residues 1-36 form an integral part of the structural core of the full-length protein.
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PMID:Probing minimal independent folding units in dihydrofolate reductase by molecular dissection. 930 Apr 88

Precursor proteins made in the cytoplasm must be in an unfolded conformation during import into mitochondria. Some precursor proteins have tightly folded domains but are imported faster than they unfold spontaneously, implying that mitochondria can unfold proteins. We measured the import rates of artificial precursors containing presequences of varying length fused to either mouse dihydrofolate reductase or bacterial barnase, and found that unfolding of a precursor at the mitochondrial surface is dramatically accelerated when its presequence is long enough to span both membranes and to interact with mhsp70 in the mitochondrial matrix. If the presequence is too short, import is slow but can be strongly accelerated by urea-induced unfolding, suggesting that import of these 'short' precursors is limited by spontaneous unfolding at the mitochondrial surface. With precursors that have sufficiently long presequences, unfolding by the inner membrane import machinery can be orders of magnitude faster than spontaneous unfolding, suggesting that mhsp70 can act as an ATP-driven force-generating motor during protein import.
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PMID:Active unfolding of precursor proteins during mitochondrial protein import. 936 87

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.
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PMID:Refolding of [6-19F]tryptophan-labeled Escherichia coli dihydrofolate reductase in the presence of ligand: a stopped-flow NMR spectroscopy study. 942 60

The structure, stability, and enzymatic function of dihydrofolate reductase (DHFR) from Escherichia coli are influenced by point mutations at sites 67 and 121 in two flexible loops [Gekko et al. (1994) J. Biochem. 116, 34-41; Ohmae et al. (1996) J. Biochem. 119, 703-710]. In the present study, eight double mutants at sites 67 and 121 (G67V/G121S, G67V/G121A, G67V/G121C, G67V/G121D, G67V/G121V, G67V/G121H, G67V/G121L, and G67V/G121Y) were constructed in order to identify interactions between the two sites of DHFR. The far-ultraviolet circular dichroism spectra of double mutants were clearly different from those of the respective single mutants, with significant changes being observed for three mutants, G67V/G121A, G67V/G121L, and G67V/G121S. The Gibbs free energy change of urea unfolding of double mutants could not be expressed by the sum of those of the respective single mutants except for G67V/G121H. The steady-state kinetic experiments showed that the effect of double mutations manifests itself not in Km but in k(cat), and the transition-state stabilization energy for G67V/G121A, G67V/G121C, and G67V/G121L is not equal to the sum of those for the single mutants. These results indicate that the additivity rule essentially does not hold for these double mutants, and that long-range interactions occur between sites 67 and 121, even though they are separated by 27.7 A. This is evidence that the flexible loops play important roles in the stability and function of this enzyme through structural perturbations, in which a small alteration in local atomic packing due to amino acid substitution is cooperatively magnified over almost the whole molecule.
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PMID:Nonadditive effects of double mutations at the flexible loops, glycine-67 and glycine-121, of Escherichia coli dihydrofolate reductase on its stability and function. 950 6

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