Kinetics of the inhibition of bovine liver dihydrofolate reductase by tea catechins: origin of slow-binding inhibition and pH studies

Dihydrofolate reductase (DHFR) is the subject of intensive investigation since it appears to be the primary target enzyme for "antifolate" drugs, such as methotrexate and trimethoprim. Fluorescence quenching and stopped-flow fluorimetry show that the ester bond-containing tea polyphenols (-)-epigallocatechin gallate (EGCG) and (-)-epicatechin gallate (ECG) are potent and specific inhibitors of DHFR with inhibition constants (K(I)) of 120 and 82 nM, respectively. Both tea compounds showed the characteristics of slow-binding inhibitors of bovine liver DHFR. In this work, we have determined a complete kinetic scheme to explain the slow-binding inhibition and the pH effects observed during the inhibition of bovine liver DHFR by these tea polyphenols. Experimental data, based on fluorimetric titrations, and transient phase and steady-state kinetic studies confirm that EGCG and ECG are competitive inhibitors with respect to 7,8-dihydrofolate, which bind preferentially to the free form of the enzyme. The origin of their slow-binding inhibition is proposed to be the formation of a slow dissociation ternary complex by the reaction of NADPH with the enzyme-inhibitor complex. The pH controls both the ionization of critical catalytic residues of the enzyme and the protonation state of the inhibitors. At acidic pH, EGCG and ECG are mainly present as protonated species, whereas near neutrality, they evolve toward deprotonated species due to ionization of the ester-bonded gallate moiety (pK = 7.8). Although DHFR exhibits different affinities for the protonated and deprotonated forms of EGCG and ECG, it appears that the ionization state of Glu-30 in DHFR is critical for its inhibition. The physiological implications of these pH dependencies are also discussed.     

Structure and function of alternative proton-relay mutants of dihydrofolate reductase.

Using site-specific mutagenesis, we have constructed two mutants of Escherichia coli dihydrofolate reductase (ecDHFR) to investigate further the function of a weakly acidic side chain at position 27 in substrate protonation: Asp27-->Glu (D27E) and Asp27-->Cys (D27C). The crystal structure of D27E ecDHFR in a binary complex with methotrexate shows that the side-chain oxygen atoms of Glu27 are in almost precisely the same location as those of Asp27 in the wild-type enzyme. Kinetic evidence indicates that Glu27 can indeed function efficiently in the proton relay to dihydrofolate. Even though vertebrate DHFRs all have a glutamic acid at the structurally equivalent position, the kinetic properties of Glu27 ecDHFR more closely resemble those of wild-type bacterial DHFRs than of vertebrate DHFRs. The D27C mutation produced an enzyme still capable of relaying a proton to dihydrofolate, but with the intrinsic pKa in its pH-activity profiles shifted upward to values characteristic of the more basic thiolate group. The crystal structure of the binary complex with methotrexate reveals two unexpected features: (1) the Cys27 sulfhydryl group does not point toward the pteridine-binding site, but the side chain of this residue is instead rotated 120 degrees to interact with a tyrosine side chain projecting from a neighboring beta-strand; (2) a bound ethanol molecule occupies a cavity adjacent to methotrexate. Ethanol is a component of the crystallization medium.     

Enzyme polarization of substrates of dihydrofolate reductase by different theoretical methods

We have investigated the importance of polarization by the enzyme dihydrofolate reductase (DHFR) on its substrates, folate and dihydrofolate, using a series of quantum mechanical (QM) techniques (Hartree-Fock (HF), M?ller-Plesset second-order perturbation theory (MP2), local density approximation (LDA) and generalized gradient approximation (GGA) density functional theory (DFT) calculations) in which the bulk enzyme is included in the calculations as point charges. Polarization, in terms of both charges on components (residues) of the folate and dihydrofolate molecules and changes in the electron density, particularly of the pterin ring of the substrates, and the implications for the catalytic reduction are discussed. Significant differences in polarization behavior are observed for the different theoretical methods employed. The consequences of this, particularly for choosing an appropriate model for quantum mechanical/molecular mechanical (QM/MM) calculations, are pointed out. The HF and MP2 QM methods show small polarizations (approximately 0.04 electrons) of the pterin ring but quite large polarizations with both LDA and GGA DFT methods (0.3-0.5 electrons). This large difference in polarization for both folate and dihydrofolate arises as a result of substantial differences between the charge distributions for the gasphase DFT and HF calculations, specifically the charges on the dianionic glutamate side chain. Some recent literature reports of incorrect representation of anionic systems by DFT methods are noted. The DFT results are similar to the previously reported LDA DFT results of Bajorath et al. predicting a large polarization of the pterin ring of folate (Proteins 9:217-224, 1991) and dihydrofolate (PNAS 88:6423-6426, 1991) of approximately 0.5-0.6 electrons.     

Dismutation of dihydrofolate by dihydrofolate reductase

Degradation of 7,8-dihydrofolate (H2folate) in the presence of dihydrofolate reductase (DHFR) has been shown due not to an oxygenase activity of the reductase as previously reported but to dismutation of H2folate to folate and 5,6,7,8-tetrahydrofolate (H4folate). The reaction can be followed spectrophotometrically or by analysis of the reaction mixture by high-performance liquid chromatography (HPLC). The products have also been isolated and characterized. Oxygen uptake during the reaction is much less than stoichiometric with H2folate disappearance and is attributed to autoxidation of the H4folate formed. The dismutation activity is a property of highly purified Streptococcus faecium DHFR isoenzyme 2 (but not isoenzyme 1) and of Lactobacillus casei DHFR, but not of bovine liver DHFR. The activity is dependent on tightly bound NADP+ and/or NADPH. Removal of the nucleotide results in loss of dismutation activity, which is restored by adding NADP+ or NADPH. Maximum activity is obtained when approximately 1 mol equiv of nucleotide is added per mol of DHFR. It is proposed that in the dismutation reaction bound NADP(H) is alternately reduced and oxidized by incoming molecules of H2folate with release of folate and H4folate, respectively. The relatively slow rate of folate formation presumably limits the rate of the overall reaction. The equilibrium constant for the dismutation reaction is 19.4 +/- 7.4 at 22 degrees C and pH 7.0. Calculation of standard oxidation-reduction potentials at pH 7 gave values of -0.230 V for the H2folate/H4 folate pair and -0.268 V for the folate/H2folate pair. The mechanism by which NADP+ is retained by the enzyme from some sources during purification procedures is unclear.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vivo measurement of dihydrofolate reductase and its inhibition by antifolates

The ability of the enzyme dihydrofolate reductase to catalyze the formation of tetrahydrobiopterin from dihydrobiopterin was used to develop a method for measuring the activity of this enzyme in vivo. This method can be used to determine the activity of the enzyme in tissues as well as the extent and duration of inhibition of the enzyme by antifolates. Sepiapterin, which is converted to dihydrobiopterin by the enzyme sepiapterin reductase, was as effective a precursor as dihydrobiopterin and has been used in these studies because of its greater stability relative to dihydrobiopterin. Assay conditions must be established for each tissue and enzyme activity can be determined either by measuring the rate of disappearance of dihydrobiopterin or the rate of formation of tetrahydrobiopterin.     

Catalytic mechanism of the dihydrofolate reductase reaction as determined by pH studies

The variation with pH of the kinetic parameters of the reaction catalyzed by dihydrofolate reductase from Escherichia coli has been determined with the aim of elucidating the chemical mechanism of the reaction. The (V/K)DHF and V profiles indicated that protonation enhances the observed rate of interaction of dihydrofolate (DHF) with the enzyme-NADPH complex as well as the maximum velocity of the reaction. The pKa value of 8.09 observed in the (V/K)DHF profile is similar to that of 7.9 observed in the Ki profile for 2,4-diamino-6,7-dimethylpteridine while the pKa value of the V profile is displaced to 8.4. From the magnitude of the pH-independent value for (V/K)DHF, it is concluded that unprotonated dihydrofolate must react, at neutral pH, with the protonated form of the enzyme. The D(V/K)DHF value is independent of pH and equal to unity whereas the DV value varies as a wave function of pH with limiting values of 1.5 and 1.0 at low and high pH, respectively. It is proposed that dihydrofolate reacts with the unprotonated enzyme-NADPH complex to form a dead-end complex and with the protonated form of the same complex to form a productive complex. Further, it is considered that the protonated carboxyl of Asp-27 at the active site of the enzyme is responsible for the protonation of the N-5 nitrogen of dihydrofolate and that this protonation precedes and facilitates hydride transfer.     

硒蛋白TrxR1介导甲萘醌还原：催化特性和抑制作用

硫氧还蛋白还原酶 (Thioredoxin reductase,TrxR) 是一类重要的抗氧化硒蛋白,参与调控肿瘤发生发展。研究表明,萘醌类分子可以靶向抑制TrxR1活性并经由TrxR1介导产生活性氧,导致细胞氧化还原失衡,使其成为潜在的肿瘤化疗药物。本文旨在通过生物化学及质谱分析,探究硒蛋白TrxR1与萘醌化合物甲萘醌的相互作用,进一步揭示TrxR1催化萘醌分子还原的机理和萘醌分子抑制TrxR1活性的机制。通过对TrxR1催化残基的定点突变和突变体的重组表达,我们测定TrxR1突变体介导甲萘醌还原稳态动力学参数,并分析甲萘醌对TrxR1活性抑制,最后通过质谱分析鉴定甲萘醌与TrxR1相互作用。结果表明,硒蛋白TrxR1的Sec498催化甲萘醌还原,但是U498C突变使甲萘醌还原更加高效,表明了甲萘醌还原主要呈现非硒依赖性。突变实验发现C端Cys498发挥主要催化还原作用,而N端Cys64对甲萘醌还原的影响稍强于Cys59。LC-MS结果发现TrxR1存在1分子甲萘醌加合物,推测其不可逆修饰硒蛋白C末端高反应活性的硒代半胱氨酸。本研究揭示了TrxR1可以非硒依赖方式催化甲萘醌还原,同时其活性会受到甲萘醌的不可逆抑制,为靶向TrxR1的萘醌类抗癌药物研发提供有益参考。     

Recombinant bovine dihydrofolate reductase produced by mutagenesis and nested PCR of murine dihydrofolate reductase cDNA

Recent reports of the slow-tight binding inhibition of bovine liver dihydrofolate reductase (bDHFR) in the presence of polyphenols isolated from green tea leaves has spurred renewed interest in the biochemical properties of bDHFR. Earlier studies were done with native bDHFR but in order to validate models of polyphenol binding to bDHFR, larger quantities of bDHFR are necessary to support structural studies. Bovine DHFR differs from its closest sequence homologue, murine DHFR, by 19 amino acids. To obtain the bDHFR cDNA, murineDHFR cDNA was transformed by a series of nested PCRs to reproduce the amino acid coding sequence for bovine DHFR. The bovine liver DHFR cDNA has an open reading frame of 561 base pairs encoding a protein of 187 amino acids that has a high level of conservation at the primary sequence level with other DHFR enzymes, and more so for the amino acid residues in the active site of the mammalian DHFR enzymes. Expression of the bovine DHFR cDNA in bacterial cells produced a stable recombinant protein with high enzymatic activity and kinetic properties similar to those previously reported for the native protein.     

On the substrate specificity of bovine liver dihydrofolate reductase: new unconjugated dihydropterin substrates

The substrate specificity of dihydrofolate reductase from cells of different origin has been thought to be quite narrow, and unconjugated dihydropterins such as 6-methyl-dihydropterin are known to be very poor substrates. We have reinvestigated the substrate specificity of several dihydropterins and, in addition, have observed that in a new series of unconjugated dihydropterins of the general structure 6-CH2O(CH2)nCH3 several compounds are excellent substrates for the bovine liver enzyme, but none of them bind as well as dihydrofolate. The substrate activity (apparent Vmax) of these compounds increases from 17 to 110% that of the natural substrate, dihydrofolate, as n is increased from 0 to 3. In contrast, these unconjugated dihydropterins are very poor substrates for the Escherichia coli enzyme.     

Methotrexate, a high-affinity pseudosubstrate of dihydrofolate reductase.

Investigations have been made of the slow, tight-binding inhibition by methotrexate of the reaction catalyzed by dihydrofolate reductase from Streptococcus faecium A. Quantitative analysis has shown that progress curve data are in accord with a mechanism that involves the rapid formation of an enzyme-NADPH-methotrexate complex that subsequently undergoes a relatively slow, reversible isomerization reaction. From the Ki value for the dissociation of methotrexate from the E-NADPH-methotrexate complex (23 nM) and values of 5.1 and 0.013 min-1 for the forward and reverse rate constants of the isomerization reaction, the overall inhibition constant for methotrexate was calculated to be 58 pM. The formation of an enzyme-methotrexate complex was demonstrated by means of fluorescence quenching, and a value of 0.36 muM was determined for its dissociation constant. The same technique was used to determine dissociation constants for the reaction of methotrexate with the E-NADP and E-NADPH complexes. The results indicate that in the presence of either NADPH or NADP there is enhancement of the binding of methotrexate to the enzyme. It is proposed that methotrexate behaves as a pseudosubstrate for dihydrofolate reductase.     

Dihydropteridine reductase as an alternative to dihydrofolate reductase for synthesis of tetrahydrofolate in Thermus thermophilus

A strategy devised to isolate a gene coding for a dihydrofolate reductase from Thermus thermophilus DNA delivered only clones harboring instead a gene (the T. thermophilus dehydrogenase [DH(Tt)] gene) coding for a dihydropteridine reductase which displays considerable dihydrofolate reductase activity (about 20% of the activity detected with 6,7-dimethyl-7,8-dihydropterine in the quinonoid form as a substrate). DH(Tt) appears to account for the synthesis of tetrahydrofolate in this bacterium, since a classical dihydrofolate reductase gene could not be found in the recently determined genome nucleotide sequence (A. Henne, personal communication). The derived amino acid sequence displays most of the highly conserved cofactor and active-site residues present in enzymes of the short-chain dehydrogenase/reductase family. The enzyme has no pteridine-independent oxidoreductase activity, in contrast to Escherichia coli dihydropteridine reductase, and thus appears more similar to mammalian dihydropteridine reductases, which do not contain a flavin prosthetic group. We suggest that bifunctional dihydropteridine reductases may be responsible for the synthesis of tetrahydrofolate in other bacteria, as well as archaea, that have been reported to lack a classical dihydrofolate reductase but for which possible substitutes have not yet been identified.     

Mechanism of the reaction catalyzed by dihydrofolate reductase from Escherichia coli: pH and deuterium isotope effects with NADPH as the variable substrate

The variations with pH of the kinetic parameters and primary deuterium isotope effects for the reaction of NADPH with dihydrofolate reductase from Escherichia coli have been determined. The aims of the investigations were to elucidate the chemical mechanism of the reaction and to obtain information about the location of the rate-limiting steps. The V and V/KNADPH profiles indicate that a single ionizing group at the active center of the enzyme must be protonated for catalysis, whereas the Ki profiles show that the binding of NADPH to the free enzyme and of ATP-ribose to the enzyme-dihydrofolate complex is pH independent. From the results of deuterium isotope effects on V/KNADPH, it is concluded that NADPH behaves as a sticky substrate. It is this stickiness that raises artificially the intrinsic pK value of 6.4 for the Asp-27 residue of the enzyme-dihydrofolate complex [Howell, E. E., Villafranca, J. E., Warren, M. S., Oatley, S. J., & Kraut, J. (1986) Science (Washington, D.C.) 231, 1123] to an observed value of 8.9. Thus, the binary enzyme complex is largely protonated at neutral pH. The elevation of the intrinsic pK value of 6.4 for the ternary enzyme-NADPH-dihydrofolate complex to 8.5 is not due to the kinetic effects of substrates. Rather, it is the consequence of the lower, pH-independent rate of product release and the faster pH-dependent catalytic step. At neutral pH, the proportion of enzyme present as a protonated ternary enzyme-substrate complex is sufficient to keep catalysis faster than product release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binary and ternary complexes of dihydrofolate reductase with substrates, coenzymes and inhibitors. Circular dichroic and magnetic circular dichroic studies.

Interaction of several representative folate, quinazoline and pyridine nucleotide derivatives with dihydrofolate reductase from amethopterin-resistant Lactobacillus casei induces dramatic changes in its circular dichroic spectral properties. The binding of dihydrofolate induces a large extrinsic Cotton effect at 295 nm ([theta] = 113 800 deg . cm2 . dm-1). The generation of this band by dihydrofolate is strictly dependent on complex formation with a single substrate binding site and a KD = 7 . 10(-6) M. The other binary complexes examined include the enzyme . NADPH, enzyme . amethopterin, enzyme . folate, and enzyme . methasquin. All such complexes differ in spectral detail, the negative ellipticity at 330 nm being characteristic of the "folate site" complexes. The circular dichroic spectrum of the ternary complex of reductase . NADPH . methotrexate shows a positive symmetrical band centered at 360 nm ([theta] - 32 000 deg . cm2 . dm-1). Since both of the corresponding binary complexes exhibit negative bands in this region, this induced band represents a unique molecular property of the ternary complex. Chemical modification of a single tryptophan residue of the enzyme, as determined from magnetic circular dichroism spectra, results in a complete loss in the ability to bind either dihydrofolate or NADPH.     

Inhibition of Pneumocystis dihydrofolate reductase by analogs of pyrimethamine, methotrexate and trimetrexate.

Dihydrofolate reductase was obtained from Pneumocystis carinii isolated from heavily infected lungs of female Sprague-Dawley rats infected by transtracheal inoculation. The enzyme differed significantly from other forms of dihydrofolate reductase in response to KCl and to antifolate drugs. Dihydrofolate reductase from P. carinii was used to assess activity of analogs of pyrimethamine, methotrexate, and trimetrexate. One pyrimethamine analog was selective for P. carinii dihydrofolate reductase; potency was in the micromolar range. In contrast, 21 methotrexate analogs and 2 trimetrexate analogs were selective for P. carinii dihydrofolate reductase; potencies for these were in the nanomolar range.     

Kinetics of tetrahydrobiopterin synthesis by rabbit brain dihydrofolate reductase.

Product identification and kinetic data are presented for the conversion of 7,8-dihydrobiopterin into tetrahydrobiopterin by purified rabbit brain dihydrofolate reductase.     

Vibrational structure of dihydrofolate bound to R67 dihydrofolate reductase.

R67 is a Type II dihydrofolate reductase (DHFR) that catalyzes the reduction of dihydrofolate (DHF) to tetrahydrofolate by facilitating the addition of a proton to N5 of DHF and the transfer of a hydride ion from NADPH to C6. Because this enzyme is a plasmid-encoded DHFR from trimethoprim-resistant bacteria, extensive studies on R67 with various methods have been performed to elucidate its reaction mechanism. Here, Raman difference measurements, conducted on the ternary complex of R67.NADP(+).DHF believed to be an accurate mimic of the productive DHFR.NADPH.DHF complex, show that the pK(a) of N5 in the complex is less than 4. This is in clear contrast to the behavior observed in Escherichia coli DHFR, a substantially more efficient enzyme, where the pK(a) of bound DHF at N5 is increased to 6.5 compared with its solution value of 2.6. A comparison of the ternary complexes in R67 and E. coli DHFRs suggests that enzymic raising of the pK(a) at N5 can significantly increase the catalytic efficiency of the hydride transfer step. However, R67 shows that even without such a strategy an effective DHFR can still be designed.