Measuring the orientation of taurine in the active site of the non-heme Fe(II)/α-ketoglutarate-dependent taurine hydroxylase (TauD) using electron spin echo envelope modulation (ESEEM) spectroscopy.

The position and orientation of taurine near the non-heme Fe(II) center of the α-ketoglutarate (α-KG)-dependent taurine hydroxylase (TauD) was measured using Electron Spin Echo Envelope Modulation (ESEEM) spectroscopy. TauD solutions containing Fe(II), α-KG, and natural abundance taurine or specifically deuterated taurine were prepared anaerobically and treated with nitric oxide (NO) to make an S = 3/2 {FeNO}(7) complex that is suitable for robust analysis with EPR spectroscopy. Using ratios of ESEEM spectra collected for TauD samples having natural abundance taurine or deuterated taurine, (1)H and (14)N modulations were filtered out of the spectra and interactions with specific deuterons on taurine could be studied separately. The Hamiltonian parameters used to calculate the amplitudes and line shapes of frequency spectra containing isolated deuterium ESEEM were obtained with global optimization algorithms. Additional statistical analysis was performed to validate the interpretation of the optimized parameters. The strongest (2)H hyperfine coupling was to a deuteron on the C1 position of taurine and was characterized by an effective dipolar distance of 3.90 ± 0.25 Å from the {FeNO}(7) paramagnetic center. The principal axes of this C1-(2)H hyperfine coupling and nuclear quadrupole interaction tensors were found to make angles of 26 ± 5 and 52 ± 17°, respectively, with the principal axis of the {FeNO}(7) zero-field splitting tensor. These results are discussed within the context of the orientation of substrate taurine prior to the initiation of hydrogen abstraction.

Insight into the mechanism of an iron dioxygenase by resolution of steps following the FeIV=HO species.

Iron oxygenases generate elusive transient oxygen species to catalyze substrate oxygenation in a wide range of metabolic processes. Here we resolve the reaction sequence and structures of such intermediates for the archetypal non-heme Fe(II) and alpha-ketoglutarate-dependent dioxygenase TauD. Time-resolved Raman spectra of the initial species with (16)O(18)O oxygen unequivocally establish the Fe(IV) horizontal lineO structure. (1)H/(2)H substitution reveals direct interaction between the oxo group and the C1 proton of substrate taurine. Two new transient species were resolved following Fe(IV) horizontal lineO; one is assigned to the nu(FeO) mode of an Fe(III) horizontal line O(H) species, and a second is likely to arise from the vibration of a metal-coordinated oxygenated product, such as Fe(II) horizontal line O horizontal line C(1) or Fe(II) horizontal line OOCR. These results provide direct insight into the mechanism of substrate oxygenation and suggest an alternative to the hydroxyl radical rebinding paradigm.

Metal and substrate binding to an Fe(II) dioxygenase resolved by UV spectroscopy with global regression analysis.

The addition of divalent metal ions or substrate taurine to TauD, an alpha-ketoglutarate-dependent dioxygenase, alters its UV absorption, as clearly observed by monitoring the protein's difference spectra. Binding of metal ions leads to a decrease in absorption at approximately 297 nm and modulation of other features. A separate signature with enhanced absorption at approximately 295 nm is identified for binding of taurine. These narrow ( approximately 700 cm(-1)) and intense ( approximately 0.5mM(-1) cm(-1)) spectral changes are attributed to ligand-induced protein conformational changes affecting the environment of aromatic residues. The changes in the UV difference spectra were exploited to assess directly the thermodynamics and kinetics of ligand interactions in wild-type TauD and selected variants. This approach holds promise as a new tool to probe ligand-induced conformational changes in a wide range of other proteins. Experimental and quantification approaches for a reliable analysis of protein absorption below 320 nm are presented.

Cr(II) reactivity of taurine/alpha-ketoglutarate dioxygenase.

The interaction of CrII with taurine/alpha-ketoglutarate (alphaKG) dioxygenase (TauD) was examined. CrII replaces FeII and binds stoichiometrically with alphaKG to the FeII/alphaKG binding site of the protein, with additional CrII used to generate a chromophore attributed to a CrIII-semiquinone in a small percentage of the sample. Formation of the latter oxygen-sensitive species requires the dihydroxyphenylalanine (DOPA) quinone form of Tyr-73. This preformed side chain is generated by intracellular self-hydroxylation of Tyr-73 to form DOPA, which is subsequently oxidized to the quinone. No chromophore is generated when using NaBH4-treated sample, protein isolated from anaerobically grown cells, inactive TauD variants that are incapable of self-hydroxylation, or the Y73F active mutant of TauD. A CrIII-DOPA semiquinone also was observed in the herbicide hydroxylase SdpA.

Kinetic isotope effects for alkaline phosphatase reactions: implications for the role of active-site metal ions in catalysis.

Enzyme-catalyzed phosphoryl transfer reactions have frequently been suggested to proceed through transition states that are altered from their solution counterparts, with the alterations presumably arising from interactions with active-site functional groups. In particular, the phosphate monoester hydrolysis reaction catalyzed by Escherichia coli alkaline phosphatase (AP) has been the subject of intensive scrutiny. Recent linear free energy relationship (LFER) studies suggest that AP catalyzes phosphate monoester hydrolysis through a loose transition state, similar to that in solution. To gain further insight into the nature of the transition state and active-site interactions, we have determined kinetic isotope effects (KIEs) for AP-catalyzed hydrolysis reactions with several phosphate monoester substrates. The LFER and KIE data together provide a consistent picture for the nature of the transition state for AP-catalyzed phosphate monoester hydrolysis and support previous models suggesting that the enzymatic transition state is similar to that in solution. Moreover, the KIE data provides unique information regarding specific interactions between the transition state and the active-site Zn2+ ions. These results provide strong support for a model in which electrostatic interactions between the bimetallo Zn2+ site and a nonbridging phosphate ester oxygen atom make a significant contribution to the large rate enhancement observed for AP-catalyzed phosphate monoester hydrolysis.

Probing the iron-substrate orientation for taurine/alpha-ketoglutarate dioxygenase using deuterium electron spin echo envelope modulation spectroscopy.

The structural relationship between substrate taurine and the non-heme Fe(II) center of taurine/alpha-ketoglutarate (alphaKG) dioxygenase (TauD) was measured using electron spin echo envelope modulation (ESEEM) spectroscopy. Studies were conducted on TauD samples treated with NO, cosubstrate alphaKG, and either protonated or specifically deuterated taurine. Stimulated echo ESEEM data were divided to eliminate interference from 1H and 14N modulations and accentuate modulations from 2H. For taurine that was deuterated at the C1 position (adjacent to the sulfonate group), 2H ESEEM spectra show features that arise from dipole-dipole and deuterium nuclear quadrupole interactions from a single deuteron. Parallel measurements taken for taurine deuterated at both C1 and C2 show an additional ESEEM feature at the deuterium Larmor frequency. Analysis of these data at field positions ranging from g = 4 to g = 2 have allowed us to define the orientation of substrate taurine with respect to the magnetic axes of the Fe(II)-NO, S = 3/2, paramagnetic center. These results are discussed in terms of previous X-ray crystallographic studies and the proposed catalytic mechanism for this family of enzymes.

Metal ligand substitution and evidence for quinone formation in taurine/alpha-ketoglutarate dioxygenase.

The three metal-binding ligands of the archetype Fe(II)/alpha-ketoglutarate (alphaKG)-dependent hydroxylase, taurine/alphaKG dioxygenase (TauD), were systematically mutated to examine the effects of various ligand substitutions on enzyme activity and metallocenter properties. His99, coplanar with alphaKG and Fe(II), is unalterable in terms of maintaining an active enzyme. Asp101 can be substituted only by a longer carboxylate, with the D101E variant exhibiting 22% the k(cat) and threefold the K(m) of wild-type enzyme. His255, located opposite the O(2)-binding site, is less critical for activity and can be substituted by Gln or even the negatively charged Glu (81% and 33% active, respectively). Transient kinetic studies of the three highly active mutant proteins reveal putative Fe(IV)-oxo intermediates as reported in wild-type enzyme, but with distinct kinetics. Supplementation of the buffer with formate enhances activity of the D101A variant, consistent with partial chemical rescue of the missing metal ligand. Upon binding Fe(II), anaerobic samples of wild-type TauD and the three highly active variants generate a weak green chromophore resembling a catecholate-Fe(III) species. Evidence is presented that the quinone oxidation state of dihydroxyphenylalanine, formed by aberrant self-hydroxylation of a protein side chain of TauD during aerobic bacterial growth, reacts with Fe(II) to form this species. The spectra associated with Fe(II)-TauD and Co(II)-TauD in the presence of alphaKG and taurine were examined for all variants to gain additional insights into perturbations affecting the metallocenter. These studies present the first systematic mutational analysis of metallocenter ligands in an Fe(II)/alphaKG-dependent hydroxylase.

An assay for Fe(II)/2-oxoglutarate-dependent dioxygenases by enzyme-coupled detection of succinate formation.

The Fe(II)/2-oxoglutarate-dependent dioxygenases are a catalytically diverse family of nonheme iron enzymes that oxidize their primary substrates while decomposing the 2-oxoglutarate cosubstrate to form succinate and CO(2). We report a generic assay for these enzymes that uses succinyl-coenzyme A synthetase, pyruvate kinase, and lactate dehydrogenase to couple the formation of the product succinate to the conversion of reduced nicotinamide adenine dinucleotide to nicotinamide adenine dinucleotide. We demonstrate the utility of this new method by measuring the kinetic parameters of two bacterial Fe(II)/2-oxoglutarate-dependent dioxygenases. Significantly, this method can be used to investigate both the productive turnover reactions and the nonproductive "uncoupled" decarboxylation reactions of this enzyme family, as demonstrated by using wild-type and variant forms of 2-oxoglutarate-dependent taurine dioxygenase. This assay is amenable to miniaturization and easily adapted to a format suitable for high-throughput screening; thus, it will be a valuable tool to study Fe(II)/2-oxoglutarate-dependent dioxygenases.

Kinetic and spectroscopic investigation of CoII, NiII, and N-oxalylglycine inhibition of the FeII/alpha-ketoglutarate dioxygenase, TauD.

Co(II), Ni(II), and N-oxalylglycine (NOG) are well-known inhibitors of Fe(II)/alpha-ketoglutarate (alphaKG)-dependent hydroxylases, but few studies describe their kinetics and no spectroscopic investigations have been reported. Using taurine/alphaKG dioxygenase (TauD) as a paradigm for this enzyme family, time-dependent inhibition assays showed that Co(II) and Ni(II) follow slow-binding inhibition kinetics. Whereas Ni(II)-substituted TauD was non-chromophoric, spectroscopic studies of the Co(II)-substituted enzyme revealed a six-coordinate site (protein alone or with alphaKG) that became five-coordinate upon taurine addition. The Co(II) spectrum was not perturbed by a series of anions or oxidants, suggesting the Co(II) is inaccessible and could be used to stabilize the protein. NOG competed weakly (Ki approximately 290 microM) with alphaKG for binding to TauD, with the increased electron density of NOG yielding electronic transitions for NOG-Fe(II)-TauD and taurine-NOG-Fe(II)-TauD at 380 nm (epsilon380 90-105 M(-1) cm(-1)). The spectra of the NOG-bound TauD species did not change significantly upon oxygen exposure, arguing against the formation of an oxygen-bound state mimicking an early intermediate in catalysis.

Steady-state and transient kinetic analyses of taurine/alpha-ketoglutarate dioxygenase: effects of oxygen concentration, alternative sulfonates, and active-site variants on the FeIV-oxo intermediate.

Taurine/alpha-ketoglutarate (alphaKG) dioxygenase (TauD), an archetype alphaKG-dependent hydroxylase, is a non-heme mononuclear Fe(II) enzyme that couples the oxidative decarboxylation of alphaKG with the conversion of taurine to aminoacetaldehyde and sulfite. The crystal structure of taurine-alphaKG-Fe(II)TauD is known, and spectroscopic studies have kinetically defined the early steps in catalysis and identified a high-spin Fe(IV)-oxo reaction intermediate. The present analysis extends our understanding of TauD catalysis by investigating the steady-state and transient kinetics of wild-type and variant forms of the enzyme with taurine and alternative sulfonates. TauD proteins substituted at residues surrounding the active site were shown to fold properly based on their abilities to form a diagnostic chromophore associated with the anaerobic Fe(II)-alphaKG chelate complex and to generate a tyrosyl radical upon subsequent reaction with oxygen. Steady-state studies of mutant proteins confirmed the importance of His 70 and Arg 270 in binding the sulfonate moiety of taurine and indicated the participation of Asn 95 in recognizing the substrate amine group. The N97A and S158A variants are likely to undergo an increase in hydrophobicity and expansion of the substrate-binding pocket, thus accounting for their decreased K(m) toward pentanesulfonic acid compared to wild-type TauD. Stopped-flow UV-visible spectroscopic examination of the reaction of oxygen with taurine-alphaKG-Fe(II)TauD confirmed a minimal three-step sequence of reactions attributed to Fe(IV)-oxo formation (k(1)), bleaching to the Fe(II) state upon substrate hydroxylation (k(2)), rebinding of excess substrates (k(3)), and indicated that none of the steps exhibit detectable solvent k(H)/k(D) isotope effects. This demonstrates that no protons are involved in the rate-determining step of Fe(IV)-oxo formation, in contrast to heme iron oxygenases. The Fe(IV)-oxo species is likely to be utilized in conversion of the alternative substrates pentanesulfonic acid and 3-N-morpholinopropanesulfonic acid; however, this spectroscopic intermediate was not detected because of the decreased k(1)/k(2) ratio. With taurine, k(1) was shown to depend on the oxygen concentration allowing calculation of a second-order rate constant of 1.58 x 10(5) M(-)(1) s(-)(1) for this irreversible reaction. Stopped-flow analyses of TauD variants provided several insights into how the protein environment influences the rates of Fe(IV)-oxo formation and decay. The Fe(IV)-oxo species was not detected in the N95D or N95A variants because of a reduced k(1)/k(2) ratio, likely related to a decreased substrate-dependent conversion of the six-coordinate to five-coordinate metal site.

Probing the transition-state structure of dual-specificity protein phosphatases using a physiological substrate mimic.

Dual-specificity phosphatases (DSPs) belong to the large family of protein tyrosine phosphatases that contain the active-site motif (H/V)CxxGxxR(S/T), but unlike the tyrosine-specific enzymes, DSPs are able to catalyze the efficient hydrolysis of both phosphotyrosine and phosphoserine/threonine found on signaling proteins, as well as a variety of small-molecule aryl and alkyl phosphates. It is unclear how DSPs accomplish similar reaction rates for phosphoesters, whose reactivity (i.e., pK(a) of the leaving group) can vary by more than 10(8). Here, we utilize the alkyl phosphate m-nitrobenzyl phosphate (mNBP), leaving-group pK(a) = 14.9, as a physiological substrate mimic to probe the mechanism and transition state of the DSP, Vaccinia H1-related (VHR). Detailed pH and kinetic isotope effects of the V/K value for mNBP indicates that VHR reacts with the phosphate dianion of mNBP and that the nonbridge phosphate oxygen atoms are unprotonated in the transition state. (18)O and solvent isotope effects indicate differences in the respective timing of the proton transfer to the leaving group and P-O fission; with the alkyl ester substrate, protonation is ahead of P-O fission, while with the aryl substrate, the two processes are more synchronous. Kinetic analysis of the general-acid mutant D92N with mNBP was consistent with the requirement of Asp-92 in protonating the ester oxygen, either in a step prior to significant P-O bond cleavage or in a concerted but asynchronous mechanism in which protonation is ahead of P-O bond fission. Collectively, the data indicate that VHR and likely all DSPs can match leaving-group potential with the timing of the proton transfer to the ester oxygen, such that diverse aryl and alkyl phosphoesters are turned over with similar catalytic efficiency.

Mechanistic studies of protein tyrosine phosphatases YopH and Cdc25A with m-nitrobenzyl phosphate.

Protein tyrosine phosphatases (PTPs) constitute a large family of signaling enzymes that include both tyrosine specific and dual-specificity phosphatases that hydrolyze pSer/Thr in addition to pTyr. Previous mechanistic studies of PTPs have relied on the highly activated substrate p-nitrophenyl phosphate (pNPP), an aryl phosphate with a leaving group pK(a) of 7. In the study presented here, we employ m-nitrobenzyl phosphate (mNBP), an alkyl phosphate with a leaving group pK(a) of 14.9, which mimics the physiological substrates of the PTPs. We have carried out pH dependence and kinetic isotope effect measurements to characterize the mechanism of two important members of the PTP superfamily: Yersinia PTP (YopH) and Cdc25A. Both YopH and Cdc25A exhibit bell-shaped pH-rate profiles for the hydrolysis of mNBP, consistent with general acid catalysis. The slightly inverse (18)(V/K)(nonbridge) isotope effects (0.9999 for YopH and 0.9983 for Cdc25A) indicate a loose transition state with little nucleophilic participation for both enzymes. The smaller (18)(V/K)(bridge) primary isotope effects (0.9995 for YopH and 1.0012 for Cdc25A) relative to the corresponding isotope effects for pNPP hydrolysis suggest that protonation of the leaving group oxygen at the transition state by the general acid is ahead of P-O bond fission with the alkyl substrate, while general acid catalysis of pNPP by YopH is more synchronous with P-O bond fission. The isotope effect data also confirm findings from previous studies that Cdc25A utilizes general acid catalysis for substrates with a leaving group pK(a) of >8, but not for pNPP. Interestingly, the difference in the kinetic isotope effects for the reactions of aryl phosphate pNPP and alkyl phosphate mNBP by the PTPs parallels what is observed in the uncatalyzed reactions of their monoanions. In these reactions, the leaving group is protonated in the transition state, as is the case in PTP-catalyzed reactions. Also, the phosphoryl group in the transition states of the enzymatic reactions does not differ substantially from those of the uncatalyzed reactions. These results provide further evidence that these enzymes do not change the transition state but simply stabilize it.

Transition state differences in hydrolysis reactions of alkyl versus aryl phosphate monoester monoanions.

Although aryl phosphates have been the subject of numerous experimental studies, far less data bearing on the mechanism and transition states for alkyl phosphate reactions have been presented. Except for esters with very good leaving groups such as 2,4-dinitrophenol, the monoanion of phosphate esters is more reactive than the dianion. Several mechanisms have been proposed for the hydrolysis of the monoanion species. (18)O kinetic isotope effects in the nonbridging oxygen atoms and in the P-O(R) ester bond, and solvent deuterium isotope effects, have been measured for the hydrolysis of m-nitrobenzyl phosphate. The results rule out a proposed mechanism in which the phosphoryl group deprotonates water and then undergoes attack by hydroxide. The results are most consistent with a preequilibrium proton transfer from the phosphoryl group to the ester oxygen atom, followed by rate-limiting P-O bond fission, as originally proposed by Kirby and co-workers in 1967. The transition state for m-nitrobenzyl phosphate (leaving group pK(a) 14.9) exhibits much less P-O bond fission than the reaction of the more labile p-nitrophenyl phosphate (leaving group pK(a) = 7.14). This seemingly anti-Hammond behavior results from weakening of the P-O(R) ester bond resulting from protonation, an effect which calculations have shown is much more pronounced for aryl phosphates than for alkyl ones.

Generality of solvation effects on the hydrolysis rates of phosphate monoesters and their possible relevance to enzymatic catalysis.

Previous work by Kirby and co-workers revealed a significant acceleration of the rate of hydrolysis of p-nitrophenyl phosphate by added dipolar solvents such as DMSO. Activation parameters and kinetic isotope effects have been measured to ascertain the origin of this effect. The generality of this phenomenon was examined with a series of esters with more basic leaving groups. Computational analyses of the effects of desolvation of dianionic phosphate monoesters were carried out, and the possible effect of the transfer from water to the active site of alkaline phosphatase was modeled. The results are consistent with a desolvation-induced weakening of the P-O ester bond in the ground state. Other aryl phosphate esters show similar rate accelerations at high fractions of DMSO, but phenyl and methyl phosphates do not, and their hydrolysis reactions are actually slowed by these conditions.