Jumpstarting the cytochrome P450 catalytic cycle with a hydrated electron.

Cytochrome P450cam (CYP101Fe3+) regioselectively hydroxylates camphor. Possible hydroxylating intermediates in the catalytic cycle of this well-characterized enzyme have been proposed on the basis of experiments carried out at very low temperatures and shunt reactions, but their presence has not yet been validated at temperatures above 0 °C during a normal catalytic cycle. Here, we demonstrate that it is possible to mimic the natural catalytic cycle of CYP101Fe3+ by using pulse radiolysis to rapidly supply the second electron of the catalytic cycle to camphor-bound CYP101[FeO2]2+ Judging by the appearance of an absorbance maximum at 440 nm, we conclude that CYP101[FeOOH]2+ (compound 0) accumulates within 5 µs and decays rapidly to CYP101Fe3+, with a k440 nm of 9.6 × 104 s-1 All processes are complete within 40 µs at 4 °C. Importantly, no transient absorbance bands could be assigned to CYP101[FeO2+por•+] (compound 1) or CYP101[FeO2+] (compound 2). However, indirect evidence for the involvement of compound 1 was obtained from the kinetics of formation and decay of a tyrosyl radical. 5-Hydroxycamphor was formed quantitatively, and the catalytic activity of the enzyme was not impaired by exposure to radiation during the pulse radiolysis experiment. The rapid decay of compound 0 enabled calculation of the limits for the Gibbs activation energies for the conversions of compound 0 → compound 1 → compound 2 → CYP101Fe3+, yielding a ΔG‡ of 45, 39, and 39 kJ/mol, respectively. At 37 °C, the steps from compound 0 to the iron(III) state would take only 4 µs. Our kinetics studies at 4 °C complement the canonical mechanism by adding the dimension of time.

Kinetic consequences of introducing a proximal selenocysteine ligand into cytochrome P450cam.

The structural, electronic, and catalytic properties of cytochrome P450cam are subtly altered when the cysteine that coordinates to the heme iron is replaced with a selenocysteine. To map the effects of the sulfur-to-selenium substitution on the individual steps of the catalytic cycle, we conducted a comparative kinetic analysis of the selenoenzyme and its cysteine counterpart. Our results show that the more electron-donating selenolate ligand has only negligible effects on substrate, product, and oxygen binding, electron transfer, catalytic turnover, and coupling efficiency. Off-pathway reduction of oxygen to give superoxide is the only step significantly affected by the mutation. Incorporation of selenium accelerates this uncoupling reaction approximately 50-fold compared to sulfur, but because the second electron transfer step is much faster, the impact on overall catalytic turnover is minimal. Density functional theory calculations with pure and hybrid functionals suggest that superoxide formation is governed by a delicate interplay of spin distribution, spin state, and structural effects. In light of the remarkably similar electronic structures and energies calculated for the sulfur- and selenium-containing enzymes, the ability of the heavier atom to enhance the rate of spin crossover may account for the experimental observations. Because the selenoenzyme closely mimics wild-type P450cam, even at the level of individual steps in the reaction cycle, selenium represents a unique mechanistic probe for analyzing the role of the proximal ligand and spin crossovers in P450 chemistry.

Two parallel pathways in the kinetic sequence of the dihydrofolate reductase from Mycobacterium tuberculosis.

Dihydrofolate reductase from Mycobacterium tuberculosis (MtDHFR) catalyzes the NAD(P)H-dependent reduction of dihydrofolate, yielding NAD(P)(+) and tetrahydrofolate, the primary one-carbon unit carrier in biology. Tetrahydrofolate needs to be recycled so that reactions involved in dTMP synthesis and purine metabolism can be maintained. Previously, steady-state studies revealed that the chemical step significantly contributes to the steady-state turnover number, but that a step after the chemical step was likely limiting the reaction rate. Here, we report the first pre-steady-state investigation of the kinetic sequence of the MtDHFR aiming to identify kinetic intermediates, and the identity of the rate-limiting steps. This kinetic analysis suggests a kinetic sequence comprising two parallel pathways with a rate-determining product release. Although product release is likely occurring in a random fashion, there is a slight preference for the release of THF first, a kinetic sequence never observed for a wild-type dihydrofolate reductase of any organism studied to date. Temperature studies were conducted to determine the magnitude of the energetic barrier posed by the chemical step, and the pH dependence of the chemical step was studied, demonstrating an acidic shift from the pK(a) observed at the steady state. The rate constants obtained here were combined with the activation energy for the chemical step to compare energy profiles for each kinetic sequence. The two parallel pathways are discussed, as well as their implications for the catalytic cycle of this enzyme.

Kinetic and chemical mechanism of the dihydrofolate reductase from Mycobacterium tuberculosis.

Dihydrofolate reductase from Mycobacterium tuberculosis (MtDHFR) catalyzes the NAD(P)-dependent reduction of dihydrofolate, yielding NAD(P)(+) and tetrahydrofolate, the primary one-carbon unit carrier in biology. Tetrahydrofolate needs to be recycled so that reactions involved in dTMP synthesis and purine metabolism are maintained. In this work, we report the kinetic characterization of the MtDHFR. This enzyme has a sequential steady-state random kinetic mechanism, probably with a preferred pathway with NADPH binding first. A pK(a) value for an enzymic acid of approximately 7.0 was identified from the pH dependence of V, and the analysis of the primary kinetic isotope effects revealed that the hydride transfer step is at least partly rate-limiting throughout the pH range analyzed. Additionally, solvent and multiple kinetic isotope effects were determined and analyzed, and equilibrium isotope effects were measured on the equilibrium constant. (D(2)O)V and (D(2)O)V/K([4R-4-(2)H]NADH) were slightly inverse at pH 6.0, and inverse values for (D(2)O)V([4R-4-(2)H]NADH) and (D(2)O)V/K([4R-4-(2)H]NADH) suggested that a pre-equilibrium protonation is occurring before the hydride transfer step, indicating a stepwise mechanism for proton and hydride transfer. The same value was obtained for (D)k(H) at pH 5.5 and 7.5, reaffirming the rate-limiting nature of the hydride transfer step. A chemical mechanism is proposed on the basis of the results obtained here.

Structure and mechanism of the 6-oxopurine nucleosidase from Trypanosoma brucei brucei.

Trypanosomes are purine-auxotrophic parasites that depend upon nucleoside hydrolase (NH) activity to salvage nitrogenous bases necessary for nucleic acid and cofactor synthesis. Nonspecific and purine-specific NHs have been widely studied, yet little is known about the 6-oxopurine-specific isozymes, although they are thought to play a primary role in the catabolism of exogenously derived nucleosides. Here, we report the first functional and structural characterization of the inosine-guanosine-specific NH from Trypanosoma brucei brucei. The enzyme shows near diffusion-limited efficiency coupled with a clear specificity for 6-oxopurine nucleosides achieved through a catalytic selection of these substrates. Pre-steady-state kinetic analysis reveals ordered product release, and a rate-limiting structural rearrangement that is associated with the release of the product, ribose. The crystal structure of this trypanosomal NH determined to 2.5 Å resolution reveals distinctive features compared to those of both purine- and pyrimidine-specific isozymes in the framework of the conserved and versatile NH fold. Nanomolar iminoribitol-based inhibitors identified in this study represent important lead compounds for the development of novel therapeutic strategies against trypanosomal diseases.

Crystal structures of T. vivax nucleoside hydrolase in complex with new potent and specific inhibitors.

Diseases caused by parasitic protozoa remain a major health problem, mainly due to old toxic drugs and rising drug resistance. Nucleoside hydrolases are key enzymes of the purine salvage pathway of parasites from the Trypanosomatidae family and are considered as possible drug targets. N-Arylmethyl substituted iminoribitols have been developed as selective nanomolar affinity inhibitors against the purine-specific nucleoside hydrolase of Trypanosoma vivax. The current paper describes the crystal structures of the T. vivax nucleoside hydrolase in complex with two of these inhibitors, to 1.3 and 1.85 A resolution. These high resolution structures provide an accurate picture of the mode of binding of these inhibitors and their mechanism of transition-state mimicry, and are valuable tools to guide further inhibitor design. Comparison of the current structures with previously solved structures of the enzyme in complex with ground-state and transition-state-analogue inhibitors also allows for the elucidation of a detailed molecular mechanism of active-site loop opening/closing. These loop movements can be coupled to the complex kinetic mechanism of the T. vivax nucleoside hydrolase.

A flexible loop as a functional element in the catalytic mechanism of nucleoside hydrolase from Trypanosoma vivax.

The nucleoside hydrolase of Trypanosoma vivax hydrolyzes the N-glycosidic bond of purine nucleosides. Structural and kinetic studies on this enzyme have suggested a catalytic role for a flexible loop in the vicinity of the active sites. Here we present the analysis of the role of this flexible loop via the combination of a proline scan of the loop, loop deletion mutagenesis, steady state and pre-steady state analysis, and x-ray crystallography. Our analysis reveals that this loop has an important role in leaving group activation and product release. The catalytic role involves the entire loop and could only be perturbed by deletion of the entire loop and not by single site mutagenesis. We present evidence that the loop closes over the active site during catalysis, thereby ordering a water channel that is involved in leaving group activation. Once chemistry has taken place, the loop dynamics determine the rate of product release.

Multiple transients in the pre-steady-state of nucleoside hydrolase reveal complex substrate binding, product base release, and two apparent rates of chemistry.

We have investigated the transient kinetics of the nucleoside hydrolase from Trypanosoma vivax (TvNH) at low temperatures (5 degrees C). Three novel absorbance transients (termed tau1, tau3, and tau4) were detected during multiple-guanosine turnover stopped-flow absorbance spectroscopy, in addition to a transient (tau2) that had been observed previously at 35 degrees C. At 5 degrees C, TvNH displays full-sites activity and not half-of-the-sites activity as is apparent at 35 degrees C. Both tau1 and tau2 are assigned to chemistry based on rapid-quench results. For tau1, the rate of chemistry is ca. 3000-fold faster than kcat (1-2 orders of magnitude greater than previous estimates). The pH dependencies of the burst amplitudes for tau1 and tau2 indicate that these transients arise from the formation of two different dimeric TvNH.substrate complexes and not from TvNH that contains kinetically asymmetric monomers. The saturating burst rates for tau1 and tau2 are surprisingly pH-independent, given the prominent role of acid-base chemistry in the proposed mechanism for TvNH. tau3 and tau4 are assigned to the substrate binding and base release processes, respectively, and shown to be equivalent to two fluorescence transients (tau3 and tau4, respectively) observed previously by stopped-flow methods at 35 degrees C. The rate of base release is shown to be an apparent rate. Together with steady-state product inhibition results, the data indicate that TvNH follows an ordered uni-bi kinetic mechanism with a TvNH.base dead-end complex, and not the rapid equilibrium random uni-bi mechanism proposed for other NHs. Two applicable kinetic models are presented and their implications for future mechanistic studies discussed.

Substrate-assisted leaving group activation in enzyme-catalyzed N-glycosidic bond cleavage.

In enzymatic depurination of nucleosides, the 5'-OH group of the ribose moiety of the substrate is often shown to contribute substantially to catalysis. The purine-specific nucleoside hydrolase from Trypanosoma vivax (TvNH) fixes the 5'-OH group in a gauche,trans orientation about the C4'-C5' bond, enabling the 5'-oxygen to accept an intramolecular hydrogen bond from the C8-atom of the purine leaving group. High level ab initio quantum chemical calculations indicate that this interaction promotes protonation of the purine at N7. Steady state kinetics comprising engineered substrates confirm that a considerable fraction of the catalytic 5'-OH effect can be attributed to leaving group activation.

Leaving group activation by aromatic stacking: an alternative to general acid catalysis.

General acid catalysis is a powerful and widely used strategy in enzymatic nucleophilic displacement reactions. For example, hydrolysis/phosphorolysis of the N-glycosidic bond in nucleosides and nucleotides commonly involves the protonation of the leaving nucleobase concomitant with nucleophilic attack. However, in the nucleoside hydrolase of the parasite Trypanosoma vivax, crystallographic and mutagenesis studies failed to identify a general acid. This enzyme binds the purine base of the substrate between the aromatic side-chains of Trp83 and Trp260. Here, we show via quantum chemical calculations that face-to-face stacking can raise the pKa of a heterocyclic aromatic compound by several units. Site-directed mutagenesis combined with substrate engineering demonstrates that Trp260 catalyzes the cleavage of the glycosidic bond by promoting the protonation of the purine base at N-7, hence functioning as an alternative to general acid catalysis.

Pre-steady-state analysis of the nucleoside hydrolase of Trypanosoma vivax. Evidence for half-of-the-sites reactivity and rate-limiting product release.

The nucleoside hydrolase (NH) of the Trypanosoma vivax parasite catalyzes the hydrolysis of the N-glycosidic bond in ribonucleosides according to the following reaction: beta-purine (or pyrimidine) nucleoside + H(2)O --> purine (pyrimidine) base + ribose. The reaction follows a highly dissociative nucleophilic displacement reaction mechanism with a ribosyl oxocarbenium-like transition state. This paper describes the first pre-steady-state analysis of the conversion of a number of purine nucleosides. The NH exhibits burst kinetics and behaves with half-of-the-sites reactivity. The analysis suggests that the NH of T. vivax follows a complex multistep mechanism in which a common slow step different from the chemical hydrolysis is rate limiting. Stopped-flow fluorescence binding experiments with ribose indicate that a tightly bound enzyme-ribose complex accumulates during the enzymatic hydrolysis of the common purine nucleosides. This is caused by a slow isomerization between a tight and a loose enzyme-ribose complex forming the rate-limiting step on the reaction coordinate.