Inhibitors designed for the active site of dihydroorotase

Four new compounds have been synthesized as potential inhibitors of dihydroorotase from Escherichia coli. NMR spectroscopy was used to show that 4,6-dioxo-piperidine-2(S)-carboxylic acid (3), exists in solution as a mixture of the hydrate (7), enol (8), and enolate (9) tautomeric forms. This compound was found to be a competitive inhibitor versus dihydroorotate and thio-dihydroorotate at pH values of 7-9. The K(i) of 76 microM was lowest at pH7.0 where the ketone and hydrate forms of the inhibitor 3 predominate in solution. Compound 3 was reduced to the two diastereomeric 4-hydroxy derivatives (4 and 5) and then dehydrated to yield the alkene derivative, 1,2,3,6-tetrahydro-6-oxopyridine-2(S)-carboxylic acid (6). Compounds 4-6 were competitive inhibitors versus thio-dihydroorotate at pH 8.0 with K(i) values of 3.0, 1.6, and 2.3 mM. Dihydroorotase was unable to dehydrate the 4-hydroxy derivative 4 or 5 to the alkene 6 or catalyze the reverse reaction.     

Crystal structure of Methanococcus jannaschii dihydroorotase

In this paper, we report the structural analysis of dihydroorotase (DHOase) from the hyperthermophilic and barophilic archaeon Methanococcus jannaschii. DHOase catalyzes the reversible cyclization of N-carbamoyl-l -aspartate to l -dihydroorotate in the third step of de novo pyrimidine biosynthesis. DHOases form a very diverse family of enzymes and have been classified into types and subtypes with structural similarities and differences among them. This is the first archaeal DHOase studied by x-ray diffraction. Its structure and comparison with known representatives of the other subtypes help define the structural features of the archaeal subtype. The M. jannaschii DHOase is found here to have traits from all subtypes. Contrary to expectations, it has a carboxylated lysine bridging the two Zn ions in the active site, and a long catalytic loop. It is a monomeric protein with a large β sandwich domain adjacent to the TIM barrel. Loop 5 is similar to bacterial type III and the C-terminal extension is long.     

Mercaptan and dicarboxylate inhibitors of hamster dihydroorotase

In mammals, dihydroorotase is part of a trifunctional protein, dihydroorotate synthetase, which catalyzes the first three reactions of de novo pyrimidine biosynthesis. Dihydroorotase catalyzes the formation of a peptide-like bond between the terminal ureido nitrogen and the beta-carboxyl group of N-carbamyl-L-aspartate to yield heterocyclic L-dihydroorotate. A variety of evidence suggests that dihydroorotase may have a catalytic mechanism similar to that of a zinc protease [Christopherson, R. I., & Jones, M. E. (1980) J. Biol. Chem. 255, 3358-3370]. Tight-binding inhibitors of the zinc proteases, carboxypeptidase A, thermolysin, and angiotensin-converting enzyme have been synthesized that combine structural features of the substrates with a thiol or carboxyl group in an appropriate position to coordinate a zinc atom bound at the catalytic site. We have synthesized (4R)-2-oxo-6-thioxohexahydropyrimidine-4-carboxylate (L-6-thiodihydroorotate) and have found that this analogue is a potent competitive inhibitor of dihydroorotase with a dissociation constant (Ki) in the presence of excess Zn2+ ion of 0.17 +/- 0.02 microM at pH 7.4. The potency of inhibition by L-6-thiodihydroorotate in the presence of divalent metal ions decreases in the order Zn2+ greater than Ca2+ greater than Co2+ greater than Mn2+ greater than Ni2+; L-6-thiodihydroorotate alone is less inhibitory and has a Ki of 0.85 +/- 0.14 microM. 6-Thioorotate has a Ki of 82 +/- 8 microM which decreases to 3.8 +/- 1.4 microM in the presence of Zn2+. Zn2+ alone is a moderate inhibitor of dihydroorotase and does not enhance the potency of other inhibitors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Divalent metal derivatives of the hamster dihydroorotase domain.

Dihydroorotase (DHOase, EC 3.5.2.3) is a zinc enzyme that catalyzes the reversible cyclization of N-carbamyl-L-aspartate to L-dihydroorotate in the third reaction of the de novo pathway for biosynthesis of pyrimidine nucleotides. The recombinant hamster DHOase domain from the trifunctional protein, CAD, was overexpressed in Escherichia coli and purified. The DHOase domain contained one bound zinc atom at the active site which was removed by dialysis against the chelator, pyridine-2,6-dicarboxylate, at pH 6.0. The apoenzyme was reconstituted with different divalent cations at pH 7.4. Co(II)-, Zn(II)-, Mn(II)-, and Cd(II)-substituted DHOases had enzymic activity, but replacement with Ni(2+), Cu(2+), Mg(2+), or Ca(2+) ions did not restore activity. Atomic absorption spectroscopy showed binding of one Co(II), Zn(II), Mn(II), Cd(II), Ni(II), or Cu(II) to the enzyme, while Mg(II) and Ca(II) were not bound. The maximal enzymic activities of the active, reconstituted DHOases were in the following order: Co(II) --> Zn(II) --> Mn(II) --> Cd(II). These metal substitutions had major effects upon values for V(max); effects upon the corresponding K(m) values were less pronounced. The pK(a) values of the Co(II)-, Mn(II)-, and Cd(II)-substituted enzymes derived from pH-rate profiles are similar to that of Zn(II)-DHOase, indicating that the derived pK(a) value of 6.56 obtained for Zn-DHOase is not due to ionization of an enzyme-metal aquo complex, but probably a histidine residue at the active site. The visible spectrum of Co(II)-substituted DHOase exhibits maxima at 520 and 570 nm with molar extinction coefficients of 195 and 210 M(-1) cm(-1), consistent with pentacoordination of Co(II) at the active site. The spectra at high and low pH are different, suggesting that the environment of the metal binding site is different at these pHs where the reverse and forward reactions, respectively, are favored.     

Radioassay of dihydroorotase utilizing ion-exchange chromatography.

Carbamyl-l-aspartate and l-dihydroorotate have been clearly separated from each other by ion-exchange chromatography on polyethyleneimine-cellulose thin layers. Highly purified lithium [¹⁴C]carbamyl-l-aspartate has been synthesized as a substrate for dihydroorotase (EC 3.5,2.3) from mouse Ehrlich ascites carcinoma. Utilizing the chromatographic procedures developed, an assay procedure for dihydroorotase is described which enables one to measure rapidly and sensitively the amounts of both carbamyl-l-aspartate and l-dihydroorotate. This permits determination of equilibrium constants and reaction velocities in either the biosynthetic or degradative directions.     

Purification and characterization of dihydroorotase fromPseudomonas putida

Dihydroorotase was purified to homogeneity fromPseudomonas putida. The relative molecular mass of the native enzyme was 82 kDa and the enzyme consisted of two identical subunits with a relative molecular mass of 41 kDa. The enzyme only hydrolyzed dihydro-l-orotate and its methyl ester, and the reactions were reversible. The apparentK _m andV _max values for dihydro-l-orotate hydrolysis (at pH 7.4) were 0.081 mM and 18 μmol min⁻¹ mg⁻¹, respectively; and those forN-carbamoyl-dl-aspartate (at pH 6.0) were 2.2 mM and 68 μmol min⁻¹ mg⁻¹, respectively. The enzyme was inhibited by metal ion chelators and activated by Zn²⁺. However, excessive Zn²⁺ was inhibitory. The enzyme was inhibited by sulfhydryl reagents, and competitively inhibited byN-carbamoylamino acids such asN-carbamoylglycine, with aK _i value of 2.7 mM. The enzyme was also inhibited noncompetitively by pyrimidine-metabolism intermediates such as dihydrouracil and orotate, with aK _i value of 3.4 and 0.75 mM, respectively, suggesting that the enzyme activity is regulated by pyrimidine-metabolism intermediates and that dihydroorotase plays a role in the control of pyrimidine biosynthesis.     

Mechanism of the thrombin-platelet reaction]

In the course of investigations concerning the mechanism of the thrombin platelet interaction the conditions for the appearance of a refractory behaviour of platelets towards thrombin were examined. As investigation of the platelet reactivity by determining the amine liberation showed that a continuous or discontinuous addition of slight amounts of thrombin will cause the refractory condition. The findings were analyzed in view of the interaction between the dissolved enzyme and the fixed substrate. It is assumed that the number of receptors diminished after the first thrombin contact will cause a decrease of the receptor occupation speed on the platelet surface, thus leading to a decreased platelet reactivity.     

Mechanism of the glutamate dehydrogenase reaction

The data concerning the chemical and kinetic mechanisms of the glutamate dehydrogenase reaction have been reviewed. Based on the differences between two catalytically active glutamate dehydrogenase conformations induced by the substrates as well as on some other evidence, it has been proposed that the amino groups of lysine residues 27 and 126 in the beef liver enzyme are interchangeable depending on the direction of the glutamate dehydrogenase reaction.     

Mechanism of the microtubule GTPase reaction

The rate of GTP hydrolysis by microtubules has been measured at tubulin subunit concentrations where microtubules undergo net disassembly. This was made possible by using microtubules stabilized against disassembly by reaction with ethylene glycol bis-(succinimidylsuccinate) (EGS) as sites for the addition of tubulin-GTP subunits. The tubulin subunit concentration was varied from 25 to 90% of the steady state concentration, and there was no net elongation of stabilized microtubule seeds. The GTPase rate with EGS microtubules was linearly proportional to the tubulin-GTP subunit concentration when this concentration was varied by dilution and by using GDP to compete with GTP for the tubulin E-site. The linear dependence of the rate is consistent with a GTP mechanism in which hydrolysis is coupled to the tubulin-GTP subunit addition to microtubule ends. It is inconsistent with reaction schemes in which: microtubules are capped by a single tubulin-GTP subunit, which hydrolyzes GTP when a tubulin-GTP subunit adds to the end; hydrolysis occurs primarily in subunits at the interface of a tubulin-GTP cap and the tubulin-GDP microtubule core; hydrolysis is not coupled to subunit addition and occurs randomly in subunits in a tubulin-GTP cap. It was also found that GDP inhibition of the microtubule GTPase rate results from GDP competition for GTP at the tubulin subunit E-site. There is no additional effect of GDP on the GTPase rate resulting from exchange into tubulin subunits at microtubule ends.     

Location of the dihydroorotase domain within trifunctional hamster dihydroorotate synthetase

Mammalian dihydroorotase (DHOase, EC 3.5.2.3) is part of a trifunctional protein, dihydroorotate synthetase which catalyzes the first three reactions of de novo pyrimidine biosynthesis. We have subcloned a portion of the cDNA from the plasmid pCAD142 and obtained a nucleotide sequence which extends 2.1 kb in the 5' direction from the sequence encoding the aspartate transcarbamoylase (ATCase) domain at the 3'-end of the cDNA. The DHOase and ATCase domains have been purified from an elastase digest of the trifunctional protein and subjected to amino acid (aa) sequencing from their N termini. The sequence of the N-terminal 24 aa of the DHOase domain has been obtained and aligned with the cDNA sequence. The C-terminal residues of the DHOase domain have been identified as Leu followed by Val which, when taken with partial sequences of the CNBr fragments of this domain, defines the coding sequence of the active, globular DHOase domain released by proteolysis. Prediction of protein secondary structure from the deduced aa sequence showed that the DHOase domain (Mr 37,751) is separated from the C-terminal ATCase domain (Mr 34,323) by a bridging sequence (Mr 12,532) consisting of multiple beta-turns.     

Noncompetitive inhibition by substituted sulfonamides of dihydroorotase from Zymobacterium oroticum

Dihydroorotase from $\text{Zymobacterium}$$\text{oroticum}$ ss noncompetitively inhibited with respect to L-USA by a series of substituted sulfonamides which have the general structure, R₁-SO₂-NHR₂. Values of K_i, determined from double reciprocal plots of 1/initial velocity versus 1/ [L-ureidosuccinate] are approximately 0.10 to 1.0 $\text{mM}$ for the various sulfonamides tested. These data are compared to similar data for carbonic anhydrase which also requires either Zn⁺⁺ or Co⁺⁺ for catalytic activity.     

Evidence for a pH-dependent isomerization of Clostridium oroticum dihydroorotase

Analytical gel permeation chromatography on both Sephadex and polyacrylamide columns shows that Clostridium oroticum dihydroorotase (L-5,6-dihydroorotate amidohydrolase, EC 3.5.2.3) undergoes a large decrease in molecular size when the pH is decreased from 8 to 6. The Stokes radius decreases from about 40 A to 36 A. Neither the molecular size nor kinetic properties are dependent on protein concentration. Thus, the decreased molecular size reflects a pH dependent isomerization of the enzyme.