Mutational analysis of the nucleotide binding site of Escherichia coli dCTP deaminase

In Escherichia coli and Salmonella typhimurium about 80% of the dUMP used for dTMP synthesis is derived from deamination of dCTP. The dCTP deaminase produces dUTP that subsequently is hydrolyzed by dUTPase to dUMP and diphosphate. The dCTP deaminase is regulated by dTTP that inhibits the enzyme by binding to the active site and induces an inactive conformation of the trimeric enzyme. We have analyzed the role of residues previously suggested to play a role in catalysis. The mutant enzymes R115Q, S111C, S111T and E138D were all purified and analyzed for activity. Only S111T and E138D displayed detectable activity with a 30- and 140-fold reduction in k_cat, respectively. Furthermore, S111T and E138D both showed altered dTTP inhibition compared to wild-type enzyme. S111T was almost insensitive to the presence of dTTP. With the E138D enzyme the dTTP dependent increase in cooperativity of dCTP saturation was absent, although the dTTP inhibition itself was still cooperative. Modeling of the active site of the S111T enzyme indicated that this enzyme is restricted in forming the inactive dTTP binding conformer due to steric hindrance by the additional methyl group in threonine. The crystal structure of E138D in complex with dUTP showed a hydrogen bonding network in the active site similar to wild-type enzyme. However, changes in the hydrogen bond lengths between the carboxylate and a catalytic water molecule as well as a slightly different orientation of the pyrimidine ring of the bound nucleotide may provide an explanation for the reduced activity.     

Mechanism of dTTP inhibition of the bifunctional dCTP deaminase:dUTPase encoded by Mycobacterium tuberculosis

Recombinant deoxycytidine triphosphate (dCTP) deaminase from Mycobacterium tuberculosis was produced in Escherichia coli and purified. The enzyme proved to be a bifunctional dCTP deaminase:deoxyuridine triphosphatase. As such, the M. tuberculosis enzyme is the second bifunctional enzyme to be characterised and provides evidence for bifunctionality of dCTP deaminase occurring outside the Archaea kingdom. A steady-state kinetic analysis revealed that the affinity for dCTP and deoxyuridine triphosphate as substrates for the synthesis of deoxyuridine monophosphate were very similar, a result that contrasts that obtained previously for the archaean Methanocaldococcus jannaschii enzyme, which showed approximately 10-fold lower affinity for deoxyuridine triphosphate than for dCTP.The crystal structures of the enzyme in complex with the inhibitor, thymidine triphosphate, and the apo form have been solved. Comparison of the two shows that upon binding of thymidine triphosphate, the disordered C-terminal arranges as a lid covering the active site, and the enzyme adapts an inactive conformation as a result of structural changes in the active site. In the inactive conformation dephosphorylation cannot take place due to the absence of a water molecule otherwise hydrogen-bonded to O2 of the α-phosphate.     

Inductions of superoxide dismutases in Escherichia coli under anaerobic conditions. Accumulation of an inactive form of the manganese enzyme

Escherichia coli growing anaerobically respond to NO3- with a 3-fold induction of the iron-containing superoxide dismutase. Mutants lacking nitrate reductase do not show this response. Anaerobically grown cells also contain an inactive form of the manganese-containing superoxide dismutase (MnSOD) which can be activated by addition of Mn(II) salts in the presence of acidic guanidinium chloride, followed by dialysis against neutral buffer. Direct addition of Mn(II) to a neutral solution of the inactive MnSOD does not impart activity. This inactive MnSOD thus behaves as would the apoenzyme or the enzyme bearing a metal other than Mn(II) at its active sites. Terminal electron acceptors, such as NO3- or trimethylamine N-oxide, increase the amount of inactive MnSOD produced by anaerobic E. coli. Paraquat, which is itself ineffective in this regard, markedly augments the effect of these terminal electron acceptors. It appears that flow of electrons to sinks such as NO3- or trimethylamine N-oxide, facilitated by paraquat, is sufficient to elicit biosynthesis of the MnSOD protein and that O2- is not needed for this process. Yet, oxygenation and concomitant O2- production do appear important for the insertion of manganese into the growing MnSOD polypeptide, possibly because O-2 oxidizes Mn(II) to Mn(III), and the latter is the valence state most effective in combining with the apoenzyme.     

Cobalamin-dependent methionine synthase from Escherichia coli B: electron paramagnetic resonance spectra of the inactive form and the active methylated form of the enzyme

Cobalamin-dependent methionine synthase (5-methyltetrahydrofolate-homocysteine methyltransferase, EC 2.1.1.13) has been isolated from Escherichia coli B in homogeneous form. The enzyme is isolated in an inactive form with the visible absorbance properties of cob(II)alamin. The inactive enzyme exhibits an electron paramagnetic resonance (EPR) spectrum at 38 K that is characteristic of cob(II)alamin at acid pH, where the protonated dimethylbenzimidazole substituent is not coordinated with the cobalt nucleus (base-off cobalamin). An additional, variable component of the EPR spectrum of the inactive enzyme has the characteristics of a cob(III)alamin-superoxide complex. Previous work by others [Taylor, R.T., & Weissbach, H. (1969) Arch. Biochem. Biophys. 129, 745-766. Fujii, K., & Huennekens, F.M. (1979) in Biochemical Aspects of Nutrition (Yagi, K., Ed.) pp 173-183, Japan Scientific Societies, Tokyo] has demonstrated that the enzyme can be activated by reductive methylation using adenosylmethionine as the methyl donor. We present data indicating that the conversion of inactive to methylated enzyme is correlated with the disappearance of the EPR spectrum as expected for the conversion of paramagnetic cob(II)alamin to diamagnetic methylcobalamin. When the methyl group is transferred from the methylated enzyme to homocysteine under aerobic conditions, cob(II)alamin/cob(III)alamin-superoxide enzyme is regenerated as indicated by the return of the visible absorbance properties of the initially isolated enzyme and partial return of the EPR spectrum. Our enzyme preparations contain copper in approximately 1:1 stoichiometry with cobalt as determined by atomic absorption spectroscopy.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphofructokinases from Escherichia coli. Purification and characterization of the nonallosteric isozyme.

The main phosphofructokinase of Escherichia coli (PFK I) is an extensively studied allosteric enzyme specified by the pfkA gene. A nonallosteric phosphofructokinase was reported (Fraenkel, D.G., Kotlarz, D., and Bluc, H. (1973) J. Biol. Chem. 248, 4865-4866) in strains carrying the pfkB1 mutation, a suppressor of pfkA mutants, and very low levels of this enzyme have also been detected in strains not carrying the suppressor (i.e. pfkB+). The nonallosteric protein has now been prepared pure from three strains, one carrying pfkB1 and pfkA+, one carrying pfkB1 and completely deleted for pfkA, and one carrying pfkB+ and also deleted for pfkA. It is apparently the same enzyme (PFK II) in all three strains, which shows that pfkB1 is a mutation affecting the amount of a normally minor isozyme. PFK II is a tetramer of slightly larger subunit molecular weight than PFK I (36,000 and 34,000, respectively). No immunological cross-reactivity was detected between PFK II and PFK I. Unlike PFK I, PFK II does not show cooperative interactions with fructose-6-P, inhibition by P-enolpyruvate, or activation by ADP. Also unlike PFK I, PFK II is somewhat sensitive to inhibition by fructose-1,6-P2 and can use tagatose-6-P as substrate. Both enzymes can perform the reverse reaction, fructose-6-P + ATP from fructose-1,6-P2 + ADP in vitro, but not in vivo. The normal function of PFK II is not known.     

tadA,an essential tRNA-specific adenosine deaminase from Escherichia coli

We report the characterization of tadA, the first prokaryotic RNA editing enzyme to be identified. Escherichia coli tadA displays sequence similarity to the yeast tRNA deaminase subunit Tad2p. Recombinant tadA protein forms homodimers and is sufficient for site-specific inosine formation at the wobble position (position 34) of tRNA(Arg2), the only tRNA having this modification in prokaryotes. With the exception of yeast tRNA(Arg), no other eukaryotic tRNA substrates were found to be modified by tadA. How ever, an artificial yeast tRNA(Asp), which carries the anticodon loop of yeast tRNA(Arg), is bound and modified by tadA. Moreover, a tRNA(Arg2) minisubstrate containing the anticodon stem and loop is sufficient for specific deamination by tadA. We show that nucleotides at positions 33-36 are sufficient for inosine formation in mutant Arg2 minisubstrates. The anticodon is thus a major determinant for tadA substrate specificity. Finally, we show that tadA is an essential gene in E.coli, underscoring the critical function of inosine at the wobble position in prokaryotes.     

Threonine deaminase from Escherichia coli: feedback-hypersensitive enzyme from a genetic regulatory mutant.

A mutation, ilvA538, in the gene coding for the biosynthetic L-threonine deaminase of Escherichia coli K-12 has previously been demonstrated to have pleiotropic regulatory effects leading to low and invariant expression of some of the isoleucine-valine biosynthetic enzyme, and altered expression of the branched-chain aminoacyl-tRNA synthetases. Strain PS187, which carries the ilvA538 allele, has a partial growth requirement for L-isoleucine and is characterized by a sensitivity to growth inhibition by L-leucine. The experiments reported here demonstrate that the L-threonine deaminase produced by strain PS187 is hypersensitive to inhibition by the pathway end product L-isoleucine. In addition, L-leucine, which acts at relatively high concentrations in vitro as an inhibitor of L-threonine deaminase from the wild type, is a more potent inhibitor of the activity of the mutant enzyme. Forty-six derivatives of strain PS187 were isolated as spontaneous mutants resistant to the growth-inhibitory effects of L-leucine. Two of these, strains MSR14 and MSR16, produce an L-threonine deaminase that is more resistant than the wild type to L-isoleucine inhibition, and intermediate between the wild type and strain PS187 with respect to L-leucine inhibition. Strains MSR14 and MSR16 produce L-threonine deaminase and dihydroxyacid dehydrase, the ilvD gene product, at the low levels characteristic of the parent strain. Other L-leucine-resistant derivatives of strain PS187 produce higher levels of the feedback-hypersensitive L-threonine deaminase. Thus, the sensitivity to growth inhibition by L-leucine observed with strain PS187 appears to be related both to the hypersensitivity of L-threonine deaminase to inhibition of catalytic activity and to the low level of ilv gene expression. The results reported here indicated that L-threonine deaminase is structurally altered in strain PS187, and thus provide further support for the proposal that L-threonine deaminase participates as a genetic regulatory element for the expression of the branched-chain amino acid biosynthetic enzymes.     

Regulation of particulate guanylate cyclase by Escherichia coli heat-stable enterotoxin: receptor binding and enzyme kinetics

1. Escherichia coli heat-stable enterotoxin (ST) induces a secretory diarrhea by binding to receptors on brush borders of intestinal villus cells, activating particulate guanylate cyclase and increasing intracellular concentrations of guanosine 3',5'-cyclic monophosphate (cyclic GMP). 2. However, little is known concerning coupling of receptor-ligand interaction to enzyme activation. 3. This study compares the kinetics of toxin-receptor binding and enzyme activation to better understand this transmembrane signal cascade. 4. Toxin receptor binding was linear and saturable with 50% of maximum displacement of [125I]ST by unlabeled toxin observed at 1.1 x 10(-7) M. ST increased the maximum velocity (Vmax) of guanylate cyclase with magnesium or manganese as the cation substrate without altering the affinity of the enzyme for its substrate or its positive cooperativity. 5. The concentration of toxin yielding half-maximum stimulation of guanylate cyclase was 1.2 x 10(-6) M, 10-fold higher than the affinity of the ligand for its receptor. 6. These data are consistent with the suggestion that ST-receptor interaction is coupled to activation of particulate guanylate cyclase. 7. However, the discrepancy between the affinity of ST for its receptor and its efficacy in activating the enzyme suggests that this coupling is complex. 8. Possible mechanisms underlying this coupling are discussed.     

De novo synthesis of thymidylate via deoxycytidine in dcd (dCTP deaminase) mutants of Escherichia coli.

dcd (dCTP deaminase) mutants of Escherichia coli were reported not to require thymidine for growth even though most of the thymidylate that is synthesized de novo arises from cytosine nucleotides through a pathway involving dCTP deaminase. We found, however, that the fresh introduction of dcd mutations into many strains of E. coli produced a requirement for thymidine for optimum aerobic growth, but the mutants readily reverted to prototrophy via mutations in other genes. One such mutation was in deoA, the gene for deoxyuridine phosphorylase. However, a dcd deo mutant became thymidine dependent once again if a cdd mutation (affecting deoxycytidine deaminase) were introduced. The results indicate that dcd mutants utilize an alternative pathway of TMP synthesis in which deoxycytidine and deoxyuridine are intermediates. A cdd mutation blocks the pathway by preventing the conversion of deoxycytidine to deoxyuridine, whereas a deoA mutation enhances it by sparing deoxyuridine from catabolism. The deoxycytidine must arise from dCTP or dCDP via unknown steps. It is not known to what extent this pathway is utilized in wild-type cells, which, unlike the dcd mutants, do not accumulate dCTP.     

Zinc binding and its trapping by allosteric transition in glucosamine-6-phosphate deaminase from Escherichia coli

Glucosamine-6-phosphate isomerase deaminase from Escherichia coli, a typical allosteric enzyme, becomes less cooperative and 50% inhibited when treated with zinc. This metal cation behaving as a tight-bound and slow partial inhibitor. Modification of a pair of vicinal reactive thiols with some sulfhydryl reagents mimics this effect. On the other hand, sulfhydryl reactivity disappears in the presence of saturating concentrations of Zn2+, which does not modify the kinetics of S-methylated enzyme, a finding that indicates that vicinal thiols are an essential part of the zinc-binding site. Allosteric activation of the deaminase causes trapping of the metal, which cannot be released by dialysis against a buffer containing EDTA. Cadmium and nickel(II) cations also produce a similar effect.     

Investigation into the nature of substrate binding to the dipyrromethane cofactor of Escherichia coli porphobilinogen deaminase

The formation of the dipyrromethane cofactor of Escherichia coli porphobilinogen deaminase was shown to depend on the presence of 5-aminolevulinic acid. A hemA- mutant formed inactive deaminase when grown in the absence of 5-aminolevulinic acid since this strain was unable to biosynthesize the dipyrromethane cofactor. The mutant formed normal levels of deaminase, however, when grown in the presence of 5-aminolevulinic acid. Porphobilinogen, the substrate, interacts with the free alpha-position of the dipyrromethane cofactor to give stable enzyme-intermediate complexes. Experiments with regiospecifically labeled intermediate complexes have shown that, in the absence of further substrate molecules, the complexes are interconvertible by the exchange of the terminal pyrrole ring of each complex. The formation of enzyme-intermediate complexes is accompanied by the exposure of a cysteine residue, suggesting that substantial conformational changes occur on binding substrate. Specific labeling of the dipyrromethane cofactor by growth of the E. coli in the presence of 5-amino[5-14C]levulinic acid has confirmed that the cofactor is not subject to catalytic turnover. Experiments with the alpha-substituted substrate analogue alpha-bromoporphobilinogen have provided further evidence that the cofactor is responsible for the covalent binding of the substrate at the catalytic site. On the basis of these cumulative findings, it has been possible to construct a mechanistic scheme for the deaminase reaction involving a single catalytic site which is able to catalyze the addition or removal of either NH3 or H2O. The role of the cofactor both as a primer and as a means for regulating the number of substrates bound in each catalytic cycle is discussed.     

Role of aspartate 27 of dihydrofolate reductase from Escherichia coli in interconversion of active and inactive enzyme conformers and binding of NADPH

The apoenzyme of wild-type (WT) dihydrofolate reductase (DHRF) from Escherichia coli exists in two conformational states, Et and Ew, which differ in affinity for NADPH and in kinetic competence. Dissociation constants for the binary complex of NADPH with the two conformers differ by over 100-fold (KDt = 0.17 microM, KDw = 22 microM). Rate constants governing the interconversion of conformers are small (t1/2 for Ew----Et = 71 s), and since Ew is not catalytically competent, this conversion is accompanied by an increase in catalytic velocity. The equilibrium proportion of Et in the absence of ligands is 63%, but binding of NADPH greatly increases this proportion, and t1/2 for conversion of Ew.NADPH to Et.NADPH is 30 s. This conformational equilibrium has also been examined in mutant enzyme in which aspartate 27 is replaced by asparagine (D27N E. coli DHFR). Although ASp27 is an active site residue, it does not interact directly with bound NADPH, and in the mutant the rate constant for NADPH binding to Et is unchanged as are the dissociation constants for NADPH complexes with Et or Ew. However, for mutant apoenzyme, the proportion of Et is decreased to 18% in the absence of ligands so that the overall KD for NADPH is increased (0.15 microM for WT E. coli DHFR, 0.68 microM for D27N E. coli DHFR). The lower proportion of Et is due to a decreased rate for Ew----Et (t1/2 = 221 s) and an increased rate for Et----Ew (t1/2 = 50 s versus 120 s for WT E. coli DHFR).