Effects of coenzyme binding on histidine residues of Lactobacillus casei dihydrofolate reductase

Interaction of calmodulin with the phosphofructokinase target sequence

Ca4.calmodulin (Ca4.CaM) inhibits the glycolytic enzyme phosphofructokinase, by preventing formation of its active tetramer. Fluorescence titrations show that the affinity of complex formation of Ca4.CaM with the key 21-residue target peptide increases 1000-fold from pH 9.0 to 4.8, suggesting the involvement of histidine and carboxylic acid residues. 1H NMR pH titration indicates a marked increase in pKa of the peptide histidine on complex formation and HSQC spectra show related pH-dependent changes in the conformation of the complex. This unusually strong sensitivity of a CaM-target complex to pH suggests a potential functional role for Ca4.CaM in regulation of the glycolytic pathway.

NMR studies of interactions of ligands with dihydrofolate reductase

NMR spectroscopy is a useful technique for studying interactions, conformations and dynamic processes within ligand-protein complexes. Several examples of the application of the method to studies of complexes of anti-folate drugs with their target enzyme, dihydrofolate reductase, are discussed.

Dihydrofolate reductase. 1H resonance assignments and coenzyme-induced conformational changes

Lactobacillus casei dihydrofolate reductase has been studied in solution by one and two-dimensional 1H nuclear magnetic resonance (n.m.r.) spectroscopy at 500 MHz. By using a combination of n.m.r. methods in conjunction with the crystal structure of the enzyme-methotrexate-NADPH complex, resonances have been assigned for 32 of the 162 residues of the enzyme. These are widely distributed throughout the structure of the protein, and include all the histidine and tyrosine residues, as well as several valine, leucine, isoleucine and phenylalanine residues. The assignments have been made for the enzyme-methotrexate and enzyme-methotrexate-NADP+ complexes as well as the enzyme-methotrexate-NADPH complex. Comparison of assigned resonances in the spectra of the three complexes has permitted a preliminary assessment of structural differences between them. The beta-sheet "core" of the protein is unaffected by coenzyme binding, but two regions of the structure that undergo coenzyme-induced conformation changes have been identified. These are the loop comprising residues 13 to 23, and alpha-helix C (residues 42 to 49).

Mechanism of inhibition of dihydrofolate reductases from bacterial and vertebrate sources by various classes of folate analogues

Different classes of folate analogues have been examined with respect to the mechanism of their inhibition of dihydrofolate reductases from Escherichia coli and chicken liver. In addition, the degree of synergism between the binding of these compounds and NADPH has been investigated. Methotrexate acts as a slow, tight-binding inhibitor of both enzymes whereas trimethoprim is a slow, tight-binding inhibitor of the enzyme from E. coli and a classical inhibitor of the chicken-liver enzyme. Pyrimethamine, 2,4-diamino-6,7-dimethylpteridine, a phenyltriazine, folate and folinate exhibit classical inhibition. The degree of synergism between the binding of NADPH and the inhibitor varied from low for pyrimethamine and folate to very large for the phenyltriazine which binds to the chicken-liver enzyme almost 50 000-times more tightly in the presence of NADPH. The degree of synergism is reflected in the type of inhibition that the folate analogues yield with respect to NADPH. Compounds which exhibit slight synergism give noncompetitive inhibition whereas those with a high degree of synergism yield uncompetitive inhibition. With the exception of folinate, all compounds that act as classical inhibitors give rise to competitive inhibition with respect to dihydrofolate. Folinate exhibits competitive inhibition against NADPH and noncompetitive inhibition against dihydrofolate. These results are consistent with the formation of an enzyme-dihydrofolate-folinate complex. The (6S, alphaS)-diastereoisomer of folinate was bound at least 1000-times more tightly than the (6R, alphaS)-diastereoisomer. Consideration has been given to the possible interactions that occur between residues on the enzyme and groups on the inhibitor that give rise to slow-binding inhibition.

19F-n.m.r. studies of 3',5'-difluoromethotrexate binding to Lactobacillus casei dihydrofolate reductase. Molecular motion and coenzyme-induced conformational changes

19F-n.m.r. spectroscopy was used to study the binding of 3',5'-difluoromethotrexate to dihydrofolate reductase (tetrahydrofolate dehydrogenase) from Lactobacillus casei. The benzoyl ring of the bound difluoromethotrexate was found to 'flip' about its symmetry axis, and the rate (7.3 X 10(3) s-1 at 298 K) and activation parameters for this process were determined by lineshape analysis of the 19F-n.m.r. spectrum at a series of temperatures in the range 273-308 K. The contributions to the barrier for this process are discussed. Addition of NADP+ or NADPH to form the enzyme-difluoromethotrexate-coenzyme ternary complex led to an increase in the rate of benzoyl ring flipping by a factor of 2.6-2.8-fold, and to substantial changes in the 19F-n.m.r. chemical shifts. The possible nature of the coenzyme-induced conformational changes responsible for these effects is discussed.

A 1H n.m.r. study of the role of the glutamate moiety in the binding of methotrexate to Lactobacillus casei dihydrofolate reductase

The binding of a series of amide derivatives of methotrexate to Lactobacillus casei dihydrofolate reductase has been studied by inhibition constant measurements and by 1H n.m.r. spectroscopy. Amide modification of the alpha-carboxylate of methotrexate was found to prevent interaction of the gamma-carboxylate with the imidazole of His 28. Estimates of the contributions to the binding energy from the alpha-carboxylate-Arg 57 and gamma-carboxylate-His 28 interactions have been made from a combination of inhibition and n.m.r. data.

Molecular cloning of the gene for dihydrofolate reductase from Lactobacillus casei

The Lactobacillus casei gene for dihydrofolate reductase has been cloned in Escherichia coli using the multicopy vector pBR322. A restriction map of the cloned DNA has been prepared. The cloned DNA directs the synthesis of L. casei dihydrofolate reductase in E. coli and confers trimethoprim and methotrexate resistance.

Negative cooperativity between folinic acid and coenzyme in their binding to Lactobacillus casei dihydrofolate reductase

The binding of folinic acid (5-formyl-5,6,7,8-tetrahydrofolate) to Lactobacillus casei dihydrofolate reductase has been measured. The natural 6S, alpha S diastereoisomer has a binding constant of 1.3 (+/- 0.6) X 10(8) M-1 at pH 6.0, 25 degrees C; the 6R, alpha S diastereoisomer binds approximately 10(4)-fold more weakly. The natural diastereoisomer of folinic acid binds negatively cooperatively with the coenzymes NADP+ and NADPH, binding 3 times more weakly in the presence of NADP+ and 600 times more weakly in the presence of NADPH than to the enzyme alone. Negative cooperativity has been unequivocally distinguished from competition by measurements of coenzyme binding as a function of folinic acid concentration, of the effects of folinic acid on the 1H and 31P chemical shifts of the bound coenzyme, and of the effects of folinic acid on the coenzyme dissociation rate constant. The latter experiments also give evidence for the coexistence of two slowly interconverting conformational forms of the ternary enzyme-coenzyme-folinic acid complex. Small changes in structure of the oxidized coenzymes have substantial effects on the cooperativity with folinic acid, with the thionicotinamide analogue showing positive rather than negative cooperativity. The changes in environment of the bound coenzyme produced by folinic acid, as revealed by 1H and 31P NMR, demonstrate clearly that the negative cooperativity shown by NADP+ and NADPH, respectively, arises by two structurally distinct mechanisms.

Nuclear magnetic resonance study of dihydrofolate reductase labeled with [gamma-13C]tryptophan

Dihydrofolate reductase isozyme 2 of Streptococcus faecium has been labeled with 13C in the C gamma position of tryptophan residues by growing the organism on a defined medium containing L-[gamma-13C]tryptophan (90% 13C). The 13C nuclear magnetic resonance (NMR) spectrum of the enzyme shows four well-resolved resonances which have nuclear Overhauser enhancements of 1.1-1.3. Values of T1 (spin-lattice relaxation time) and T2 (spin-spin relaxation time) are significantly less than predicted for an isotropically rotating, rigid sphere with no intermolecular dipole-dipole interactions. Three of the resonances have chemical shifts downfield from the 13C resonance of urea-denatured enzyme by amounts up to 1.43 ppm. The chemical shift of resonance 4 in the spectrum is 4.0 ppm upfield from Trp C gamma of urea-denatured enzyme. This large upfield shift is attributed to electric field effects generated by polar side chains. The two more upfield peaks both provide evidence that the corresponding tryptophan residues, WC and WD, each undergo chemical exchange between alternative microenvironments. In the case of WC, which gives a resonance with two components, exchange is slow (ve, exchange rate much less than 55 s-1), and the relative populations of the two stable states are in the ratio 2:3. WD is apparently in intermediate to fast exchange on the NMR time scale. With a two-state model, ve increases from approximately 90 to 150 s-1 as the temperature is increased from 5 to 25 degrees C. This increases in temperature is also accompanied by an increase in the fractional population of the minor downfield state(s), from about 0.062 at 5 degrees C to 0.24 at 25 degrees C. However, the data may also be interpreted as a temperature-dependent equilibrium between a continuum of many states. WD is tentatively identified with Trp-22 since comparison of the sequences of Lactobacillus casei dihydrofolate reductase and S. faecium dihydrofolate reductase and inspection of the crystal structure of the L. casei enzyme indicate that Trp-6, Trp-115, and Trp-160 are probably all involved in regions of beta sheet whereas Trp-22 is in a loop joining beta A to alpha B. Earlier crystallographic evidence for the Escherichia coli reductase suggests that in the methotrexate complex with this enzyme the corresponding loop has a good deal of flexibility. It is probable that in the uncomplexed S. faecium reductase the motion of this loop is the major mechanism for the exchange process involving Trp-22. The upfield chemical shift of resonance 4 is attributed to electric field effects on C gamma of Trp-22 produced by the carboxylate groups of Asp-27 and Asp-9. On the basis of the small difference between the chemical shift of resonance 3 and that of tryptophan C gamma in urea-denatured reductase, it is suggested that WC may be identified with Trp-6.