Salt-induced formation of the A-state of ferricytochrome c--effect of the anion charge on protein structure

Structural information on partially folded forms is important for a deeper understanding of the folding mechanism(s) and the factors affecting protein stabilization. The non-native compact state of equine cytochrome c stabilized by salts in an acidic environment (pH 2.0-2.2), called the A-state, is considered a suitable model for the molten globule of cytochrome c, as it possesses a native-like alpha-helix conformation but a fluctuating tertiary structure. In this article, we extend our knowledge on anion-induced protein stabilization by determining the effect of anions carrying a double negative charge; unlike monovalent anions (which are thought to exert an 'ionic atmosphere' effect on the macromolecule), divalent anions are thought to bind to the protein at specific surface sites. Our data indicate that divalent anions, in comparison to monovalent ions, have a greater tendency to stabilize the native-like M-Fe(III)-H coordinated state of the protein. The possibility that divalent anions may bind to the protein at the same sites previously identified for polyvalent anions was evaluated. To investigate this issue, the behavior of the K88E, K88E/T89K and K13N mutants was investigated. The data obtained indicate that the mutated residues, which contribute to form the binding sites of polyanions, are important for stabilization of the native conformation; the mutants investigated, in fact, all show an increased amount of the misligated H-Fe(III)-H state and, with respect to wild-type cytochrome c, appear to be less sensitive to the presence of the anion. These residues also modulate the conformation of unfolded cytochrome c, influencing its spin state and the coordination to the prosthetic group.     

Anion concentration modulates the conformation and stability of the molten globule of cytochrome<Emphasis Type="Italic"> c</Emphasis>

Anions induce collapse of acid-denatured cytochrome c into a compact state, the A-state, showing molten globule character. Since structural information on partially folded forms of proteins is important for a deeper understanding of folding mechanisms and of the factors affecting protein stabilization, in this paper we have investigated in detail the effects of anions on the tertiary conformation of the A-state. We have found that the salt-induced collapse of acid-denatured cytochrome c leads to a number of equilibria between high-spin and low-spin heme states and between two types of low-spin states. The two latter states are characterized by conformations leading to a native-like Met-Fe-His axial coordination and a bis-His configuration. The equilibrium between these two A-states is dependent on the concentration and/or size of the anions (i.e. the bigger the anion, the greater its effect). Further, on the basis of fast kinetic data, a kinetic model of the folding process from the acid-unfolded protein to the A-state (at low and high anion concentration) is described.     

Studies on the phenazine methosulphate--tetrazolium salt capture reaction in NAD(P)+-dependent dehydrogenase cytochemistry. III. The role of superoxide in tetrazolium reduction

Summary A study was made of the involvement of superoxide anions in the aerobic reduction of tetrazolium salts by NAD(P)H and phenazine methosulphate (PMS). On the basis of experiments with superoxide dismutase two mechanisms of tetrazolium reduction could be distinguished-one in which fully reduced PMS (PMSH) is the reducer and one in which superoxide anion is the reducer of tetrazolium salts. It is proposed that superoxide anion is formed after a PMSH-PMS⁺ dismutation reaction. The relative contributions of the two distinct pathways to tetrazolium salt reduction are controlled by the PMS redox state and the oxygen tension. The consequences of the presence of superoxide anions and scavengers of superoxide anions for quantitative dehydrogenase cytochemistry are discussed.     

Anions stabilize a metarhodopsin II-like photoproduct with a protonated Schiff base.

In rhodopsin, the retinal chromophore is covalently bound to the apoprotein by a protonated Schiff base, which is stabilized by the negatively charged counterion Glu113, conferring upon it a pK(a) of presumably >16. Upon photoexcitation and conformational relaxation of the initial photoproducts, the Schiff base proton neutralizes the counterion, a step that is considered a prerequisite for formation of the active state of the receptor, metarhodopsin II (MII). We show that the pK(a) of the Schiff base drops below 2.5 in MII. In the presence of solute anions, however, it may be increased considerably, thereby leading to the formation of a MII photoproduct with a protonated Schiff base (PSB) absorbing at 480 nm. This PSB is not stabilized by Glu113, which is shown to be neutral, but by stoichiometric binding of an anion near the Schiff base. Protonation of the Schiff base in MII changes neither coupling to G protein, as assessed by binding to a transducin-derived peptide, nor the conformation of the protein, as judged by FTIR and UV spectroscopy. A PSB and an active state conformation are therefore compatible, as suggested previously by mutants of rhodopsin. The anion specificity of the stabilization of the PSB follows the series thiocyanate > iodide > nitrate > bromide > chloride > sulfate in order of increasing efficiency. This specificity correlates inversely with the strength of hydration of the respective anion species in solution and seems therefore to be determined mainly by its partitioning into the considerably less polar protein interior.     

Glycerol-induced formation of the molten globule from acid-denatured cytochrome c: implication for hierarchical folding

At high concentration (98% or higher, v/v), glycerol induces collapse of acid-denatured cytochrome c into a compact state, the G_U state, showing a molten globule character. The G_U state possesses a nativelike -helix structure but a tertiary conformation less packed with respect to the native state. The spectroscopic properties of the G_U state closely resemble those of the molten globule stabilized by the organic solvent from the native protein (called the G_N state), indicating that glycerol can stabilize the molten globule of cytochrome c either from the native or the acid-denatured protein. The G_U and the G_N states show spectroscopic (and, thus, structural) properties and stabilities comparable to those of molten globules stabilized by different effectors, despite the fact that the mechanisms involved in the molten globule formation may significantly differ. This implies in cytochrome c a hierarchy for the rupture (native-to-molten globule) or the formation (unfolded-to-molten globule) of intramolecular interactions leading to the stabilization of the molten globule state of the protein, independently from the effector responsible for the structural transition, in accord with the sequential model proposed by Englander and collaborators.     

Effects of anions on the molecular basis of the Bohr effect of hemoglobin

High-resolution 1H-NMR spectroscopy has been used to investigate the molecular basis of the Bohr effect in human normal adult hemoglobin in the presence of anions which serve as heterotropic effectors, i.e., Cl-, Pi, and 2,3-diphosphoglycerate. The individual H+ equilibria of 22-26 histidyl residues of hemoglobin in both deoxy and carbonmonoxy forms have been measured under buffer conditions chosen to demonstrate the effects of anion binding. The results indicate that beta 2His residues are binding sites for Cl- and Pi in both deoxy and carbonmonoxy forms, and that the affinity of this site for these anions is greater in the deoxy form. Recently assigned, the resonance of beta 146His does not show evidence of involvement in anion binding. The results also indicate that the binding of 2,3-diphosphoglycerate at the central cavity between the two beta-chains in deoxyhemoglobin involves the beta 2His residues, and that the 2,3-diphosphoglycerate-binding site in carbonmonoxyhemoglobin may remain similar to that in deoxyhemoglobin. The interactions of Cl-, Pi and 2,3-diphosphoglycerate also result in changes in the pK values for other surface histidyl residues which vary in both magnitude and direction. The array of pK changes is specific for the interaction of each effector. The participation of beta 2His in the Bohr effect demonstrates that this residue can release or capture protons, depending on its protonation properties and its linkage to anion binding, and therefore provides an excellent illustration of the variable roles of a given amino acid. Although beta 146His does not bind anions, its contributions to the Bohr effect are substantially affected by the presence of anions. These results demonstrate that long-range electrostatic and/or conformational effects of anions binding play significant roles in the molecular basis of the Bohr effect of hemoglobin.     

Demonstration of two independently folding domains in the alpha subunit of bacterial luciferase by preferential ligand binding-induced stabilization

The alpha subunit of bacterial luciferase unfolds and refolds reversibly by a three-state mechanism in urea-containing buffer. It has been proposed that the three-state unfolding of the alpha subunit arises from a stepwise unfolding of a C-terminal folding domain at lower concentrations of urea, followed by unfolding of the N-terminal domain at higher concentrations of urea (Noland, B. W., Dangott, L. J., and Baldwin, T. O. (1999) Biochemistry 38, 16136-16145). The location of an anion binding site in the proposed N-terminal folding domain allowed the folding mechanism to be probed in the context of the intact polypeptide. Anions preferentially stabilized the N-terminal domain in a concentration-dependent manner. The polyvalent anions sulfate and phosphate were found to be more stabilizing than monovalent chloride ion. Cations did not show a similar stabilizing effect, demonstrating that the stabilization was due to the anions alone. The purified N-terminal domain prepared by limited proteolysis and anion exchange chromatography was found to refold cooperatively with a midpoint approximately that of the second unfolding transition of the alpha subunit. Phosphate ion stabilized this fragment to roughly the same extent as it did the alpha subunit. The results presented are consistent with the proposed two-domain folding model and demonstrate that anion binding to the N-terminal folding domain stabilizes the alpha subunit of bacterial luciferase.     

Electrochemical recognition of anions by 1,1'-N,N'-ferrocenoylbisamino acid esters

A series of novel ferrocene-based receptors, 1,1'-N,N'-ferrocenoylbisamino acid methyl esters 2-5 have been prepared and their electrochemical properties determined. The amino acids employed were glycine (2), beta-alanine (3), gamma-aminobutyric acid (4) and l-norleucine (5). These receptors are composed of an electroactive core and two parallel strands of amino acids that can interact with anions via electrostatic interactions in the oxidized state as well as secondary interactions, such as hydrogen bonding and hydrophobic interactions. Furthermore, the semi-rigid molecular clefts between the two strands of amino acids in these receptors are capable of discerning anions of different geometries and sizes. The anion sensing capabilities of receptors 2-5 were studied using cyclic voltammetry (CV). The anions studied were chloride (Cl-), nitrate (NO3-), dihydrogen phosphate (H(2)PO(4)-), hydrogen sulfate (HSO(4)-), acetate (CH(3)COO-) and neurologically important anions such as lactate (CH(3)CH(OH)COO-), pyruvate (CH(3)COCOO-) and glutamate (HOOC-CH(NH2)CH(2)CH(2)COO-). The receptors 2-5 exhibit selectivity towards chloride, dihydrogen phosphate and acetate, over hydrogen sulfate and nitrate ions and generate a redox response in organic media. Also, binding studies of receptor 3 with neurologically important anions show it displays selectivity towards lactate and pyruvate, over glutamate ions and generates a redox response. However the response is ill defined in all cases, with poorly separated "free" and "ion-pair" peaks, which preclude accurate measurement of the response by CV. These results emphasize the considerations required for the design of ferrocene-based receptors and the necessary parameters for efficient electrochemical recognition of small anions by CV.     

Functional importance of tyrosine 294 and the catalytic selectivity for the bis-Fe(IV) state of MauG revealed by replacement of this axial heme ligand with histidine

The diheme enzyme MauG catalyzes the posttranslational modification of a precursor protein of methylamine dehydrogenase (preMADH) to complete the biosynthesis of its protein-derived tryptophan tryptophylquinone (TTQ) cofactor. It catalyzes three sequential two-electron oxidation reactions which proceed through a high-valent bis-Fe(IV) redox state. Tyr294, the unusual distal axial ligand of one c-type heme, was mutated to His, and the crystal structure of Y294H MauG in complex with preMADH reveals that this heme now has His-His axial ligation. Y294H MauG is able to interact with preMADH and participate in interprotein electron transfer, but it is unable to catalyze the TTQ biosynthesis reactions that require the bis-Fe(IV) state. This mutation affects not only the redox properties of the six-coordinate heme but also the redox and CO-binding properties of the five-coordinate heme, despite the 21 ? separation of the heme iron centers. This highlights the communication between the hemes which in wild-type MauG behave as a single diheme unit. Spectroscopic data suggest that Y294H MauG can stabilize a high-valent redox state equivalent to Fe(V), but it appears to be an Fe(IV)═O/π radical at the five-coordinate heme rather than the bis-Fe(IV) state. This compound I-like intermediate does not catalyze TTQ biosynthesis, demonstrating that the bis-Fe(IV) state, which is stabilized by Tyr294, is specifically required for this reaction. The TTQ biosynthetic reactions catalyzed by wild-type MauG do not occur via direct contact with the Fe(IV)═O heme but via long-range electron transfer through the six-coordinate heme. Thus, a critical feature of the bis-Fe(IV) species may be that it shortens the electron transfer distance from preMADH to a high-valent heme iron.     

Concentration-dependent effects of anions on the anaerobic oxidation of hemoglobin and myoglobin

The redox potentials of hemoglobin and myoglobin and the shapes of their anaerobic oxidation curves are sensitive indicators of globin alterations surrounding the active site. This report documents concentration-dependent effects of anions on the ease of anaerobic oxidation of representative hemoglobins and myoglobins. Hemoglobin (Hb) oxidation curves reflect the cooperative transition from the T state of deoxyHb to the more readily oxidized R-like conformation of metHb. Shifts in the oxidation curves for Hb A(0) as Cl(-) concentrations are increased to 0.2 m at pH 7.1 indicate preferential anion binding to the T state and destabilization of the R-like state of metHb, leading to reduced cooperativity in the oxidation process. A dramatic reversal of trend occurs above 0.2 m Cl(-) as anions bind to lower affinity sites and shift the conformational equilibrium toward the R state. This pattern has been observed for various hemoglobins with a variety of small anions. Steric rather than electronic effects are invoked to explain the fact that no comparable reversal of oxygen affinity is observed under identical conditions. Evidence is presented to show that increases in hydrophilicity in the distal heme pocket can decrease oxygen affinity via steric hindrance effects while increasing the ease of anaerobic oxidation.     

Identification of the residues involved in stabilization of the semiquinone radical in the high-affinity ubiquinone binding site in cytochrome bo(3) from Escherichia coli by site-directed mutagenesis and EPR spectroscopy

During turnover of cytochrome bo(3) from Escherichia coli, a semiquinone radical is stabilized in a high-affinity binding site. To identify binding partners of this radical, site-directed mutants have been designed on the basis of a recently modeled quinone binding site (Abramson et al., 2000). The R71H, H98F, D75H, and I102W mutant enzymes were found to show very little or no quinol oxidase activity. The thermodynamic and EPR spectroscopic properties of semiquinone radicals in these mutants were characterized. For the H98F and the R71H mutants, no EPR signal of the semiquinone radical was observed in the redox potential range from -100 to 250 mV. During potentiometric titration of the D75H mutant enzyme, a semiquinone signal was detected in the same potential range as that of the wild-type enzyme. However, the EPR spectrum of the D75H mutant lacks the characteristic hyperfine structure of the semiquinone radical signal observed in the wild-type oxidase, indicating that D75 or the introduced His, interacts with the semiquinone radical. For the I102W mutant, a free radical signal was observed with a redox midpoint potential downshifted by about 200 mV. On the basis of these observations, it is suggested that R71, D75, and H98 residues are involved in the stabilization of the semiquinone state in the high-affinity binding site. Details of the possible binding motif and mechanistic implications are discussed.     

Sulfate anion stabilization of native ribonuclease A both by anion binding and by the Hofmeister effect

Data are reported for T(m), the temperature midpoint of the thermal unfolding curve, of ribonuclease A, versus pH (range 2-9) and salt concentration (range 0-1 M) for two salts, Na(2)SO(4) and NaCl. The results show stabilization by sulfate via anion-specific binding in the concentration range 0-0.1 M and via the Hofmeister effect in the concentration range 0.1-1.0 M. The increase in T(m) caused by anion binding at 0.1 M sulfate is 20 degrees at pH 2 but only 1 degree at pH 9, where the net proton charge on the protein is near 0. The 10 degrees increase in T(m) between 0.1 and 1.0 M Na(2)SO(4), caused by the Hofmeister effect, is independent of pH. A striking property of the NaCl results is the absence of any significant stabilization by 0.1 M NaCl, which indicates that any Debye screening is small. pH-dependent stabilization is produced by 1 M NaCl: the increase in T(m) between 0 and 1.0 M is 14 degrees at pH 2 but only 1 degree at pH 9. The 14 degree increase at pH 2 may result from anion binding or from both binding and Debye screening. Taken together, the results for Na(2)SO(4) and NaCl show that native ribonuclease A is stabilized at low pH in the same manner as molten globule forms of cytochrome c and apomyoglobin, which are stabilized at low pH by low concentrations of sulfate but only by high concentrations of chloride.     

Crystallographic determination of reduced bovine superoxide dismutase at pH 5.0 and of anion binding to its active site

The crystal structures of dithionite-reduced bovine Cu(I),Zn superoxide dismutase and of its adducts with the inorganic anions azide and thyocyanide have been determined in a C222₁ crystal form obtained at pH?5.0. This crystal form is characterized by a high solvent content (72%) and by having the two Cu,ZnSOD monomers (A and B) in different crystal environments. One of them (B) is involved in few intermolecular crystal contacts so that it is in a more "solution like" environment, as indicated by average temperature factors which are about twice those of the other monomer. The differences in crystal packing affect the active site structures. While in the A monomer the Cu(I) is coordinated to all four histidine residues, in the B monomer the bridging His61 side chain is found disordered, implying partial detachment from copper. The same effect occurs in the structures of the anion complexes. The inorganic anions are found bound in the active site cavity, weakly interacting with copper at distances ranging from 2.5 to 2.8?Å. The copper site in the A subunit of the native enzyme structure displays significant electron density resembling a diatomic molecule, bound side-on at about 2.8?Å from the metal, which cannot be unambiguously interpreted. The crystallographic data suggest that the existence of the His61 bridge between copper and zinc is dominated by steric more than electronic factors and that the solution state favors the His61 detachment. These structures confirm the existence of an energetically available state for Cu(I) in Cu,ZnSOD where the histidinato bridge to zinc is maintained. This state appears to be favored by tighter crystal contacts. The binding of the anions in the active site cavity is different from that observed in the oxidized enzyme and it appears to be dominated by electrostatic interactions within the cavity. The anion binding mode observed may model the substrate interaction with the reduced enzyme during catalysis.     

Redox potentials of flavocytochromes c from the phototrophic bacteria, Chromatium vinosum and Chlorobium thiosulfatophilum.

The redox potentials of flavocytochromes c (FC) from Chromatium vinosum and Chlorobium thiosulfatophilum have been studied as a function of pH. Chlorobium FC has a single heme which has a redox potential of +98 mV at pH 7 (N = 1) that is independent of pH between 6 and 8. The average two-electron redox potential of the flavin extrapolated to pH 7 is +28 mV and decreases 35 mV/pH between pH 6 and 7. The anionic form of the flavin semiquinone is stabilized above pH 6. The redox potential of Chromatium FC is markedly lower than for Chlorobium. The two hemes in Chromatium FC appear to have a redox potential of 15 mV at pH 7 (N = 1), although they reside in very different structural environments. The hemes of Chromatium FC have a pH-dependent redox potential, which can be fit in the simplest case by a single ionization with pK = 7.05. The flavin in Chromatium FC has an average two-electron redox potential of -26 mV at pH 7 and decreases 30 mV/pH between pH 6 and 8. As with Chlorobium, the anionic form of the flavin semiquinone of Chromatium FC is stabilized above pH 6. The unusually high redox potential of the flavin, a stabilized anion radical, and sulfite binding to the flavin in both Chlorobium and Chromatium FCs are characteristics shared by the flavoprotein oxidases. By analogy with glycolate oxidase and lactate dehydrogenase for which there are three-dimensional structures, the properties of the FCs are likely to be due to a positively charged amino acid side chain in the vicinity of the N1 nitrogen of the flavin.     

Probing the limits of electrostatic catalysis by uracil DNA glycosylase using transition state mimicry and mutagenesis

The DNA repair enzyme uracil DNA glycosylase (UDG) hydrolyzes the glycosidic bond of deoxyuridine in DNA by a remarkable mechanism involving formation of a positively charged oxacarbenium ion-uracil anion intermediate. We have proposed that the positively charged intermediate is stabilized by being sandwiched between the combined negative charges of the anionic uracil leaving group and a conserved aspartate residue that are located on opposite faces of the sugar ring. Here we establish that a duplex DNA oligonucleotide containing a cationic 1-aza-deoxyribose (I) oxacarbenium ion mimic is a potent inhibitor of UDG that binds tightly to the enzyme-uracil anion (EU(-)) product complex (K(D) of EU(-) = 110 pm). The tight binding of I to the EU(-) complex results from its extremely slow off rate (k(off) = 0.0008 s(-1)), which is 25,000-fold slower than substrate analogue DNA. Removal of Asp(64) and His(187), which are involved in stabilization of the cationic sugar and the anionic uracil leaving group, respectively, specifically weakens binding of I to the UDG-uracil complex by 154,000-fold, without significantly affecting substrate or product binding. These results suggest that electrostatic effects can effectively stabilize such an intermediate by at least -7 kcal/mol, without leading to anticatalytic stabilization of the substrate and products.     

Folding of Aplysia limacina apomyoglobin involves an intermediate in common with other evolutionarily distant globins

In the globin family, similarities in the folding mechanism have been found among different mammalian apomyoglobins (apoMb). The best-characterized intermediate of sperm whale apoMb, called I(AGH), is mainly stabilized by nativelike contacts among the A, G, and H helices involving a cluster of hydrophobic residues that includes two conserved tryptophans. To verify the hypothesis of a common intermediate in the folding of all members of the globin family, we have extensively studied a site-directed mutant of the myoglobin from Aplysia limacina, distantly related to the mammalian counterpart, in which one of the two tryptophans in the A-G-H cluster [i.e., Trp(H8)130] has been mutated to tyrosine. The results presented here show that this mutation destabilizes both the native state and the acid intermediate I(A) but exerts little or no effect on the thermally stable core of an intermediate species (called I(T)) peculiar to Aplysia apomyoglobin. Dynamic quenching of Trp emission by acrylamide provides information on the accessibility of the chromophores at the native and the intermediate states of wild-type and mutant Aplysia apomyoglobin, consistent with the thermodynamics. Our results agree well with those obtained for the corresponding topological position of apomyoglobin from sperm whale and clearly show that the H8 position is involved in the stabilization of the main intermediate in both apoproteins. This residue thus plays a role which is evolutionarily conserved in the globin family from invertebrates to mammals; our results support the contention that the A-G-H cluster is important in the folding pathway of different globins.     

A new scheme of symbiosis: ligand- and voltage-gated anion channels in plants and animals.

Anion channels in the plasma membrane of both plant and animal cells participate in a number of important cellular functions such as volume regulation, trans-epithelial transport, stabilization of the membrane potential and excitability. Only very recently attention has turned to the presence of anion channels in higher plant cells. A dominant theme among recent discoveries is the role of Ca2+ in activating or modulating channel current involved in signal transduction. The major anion channel of stomatal guard cell protoplasts is a 32-40 pS channel which is highly selective for anions, in particular NO3-, Cl- and malate. These channels are characterized by a steep voltage dependence. Anion release is elicited upon depolarization and restricted to a narrow voltage span of -100 mV to the reversal potential of anions. During prolonged activation the current slowly inactivates. A rise in cytoplasmic calcium in the presence of nucleotides evokes activation of the anion channels. Following activation they catalyse anion currents 10-20 times higher than in the inactivated state thereby shifting the resting potential of the guard cell from a K(+)-conducting to an anion-conducting state. Patch-clamp studies have also revealed that growth hormones directly affect voltage-dependent activity of the anion channel in a dose-dependent manner. Auxin binding resulted in a shift of the activation potential towards the resting potential. Auxin-dependent gating of the anion channel is side- and hormone-specific. Its action is also channel-specific as K+ channels coexisting in the same membrane patch were insensitive to this ligand.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fluorine-19 NMR studies on the acid state of the intestinal fatty acid binding protein

The intestinal fatty acid binding protein (IFABP) is composed of two beta-sheets with a large hydrophobic cavity into which ligands bind. After eight 4-(19)F-phenylalanines were incorporated into the protein, the acid state of both apo- and holo-IFABP (at pH 2.8 and 2.3) was characterized by means of (1)H NMR diffusion measurements, circular dichroism, and (19)F NMR. Diffusion measurements show a moderately increased hydrodynamic radius while near- and far-UV CD measurements suggest that the acid state has substantial secondary structure as well as persistent tertiary interactions. At pH 2.8, these tertiary interactions have been further characterized by (19)F NMR and show an NOE cross-peak between residues that are located on different beta-strands. Side chain conformational heterogeneity on the millisecond time scale was captured by phase-sensitive (19)F-(19)F NOESY. At pH 2.3, native NMR peaks are mostly gone, but the protein can still bind fatty acid to form the holoprotein. An exchange cross-peak of one phenylalanine in the holoprotein is attributed to increased motional freedom of the fatty acid backbone caused by the slight opening of the binding pocket at pH 2.8. In the acid environment Phe128 and Phe17 show dramatic line broadening and chemical shift changes, reflecting greater degrees of motion around these residues. We propose that there is a separation of specific regions of the protein that gives rise to the larger radius of hydration. Temperature and urea unfolding studies indicate that persistent hydrophobic clusters are nativelike and may account for the ability of ligand to bind and induce nativelike structure, even at pH 2.3.     

Heteronuclear NMR and crystallographic studies of wild-type and H187Q Escherichia coli uracil DNA glycosylase: electrophilic catalysis of uracil expulsion by a neutral histidine 187.

The nature of the putative general acid His187 in the reaction catalyzed by Escherichia coli uracil DNA glycosylase (UDG) was investigated using X-ray crystallography and NMR spectroscopy. The crystal structures of H187Q UDG, and its complex with uracil, have been solved at 1.40 and 1.60 A resolution, respectively. The structures are essentially identical to those of the wild-type enzyme, except that the side chain of Gln187 is turned away from the uracil base and cannot interact with uracil O2. This result provides a structural basis for the similar kinetic properties of the H187Q and H187A enzymes. The ionization state of His187 was directly addressed with (1)H-(15)N NMR experiments optimized for histidine ring spin systems, which established that His187 is neutral in the catalytically active state of the enzyme (pK(a) <5.5). These NMR experiments also show that His187 is held in the N(epsilon)()2-H tautomeric form, consistent with the crystallographic observation of a 2.9 A hydrogen bond from the backbone nitrogen of Ser189 to the ring N(delta)()1 of His187. The energetic cost of breaking this hydrogen bond may contribute significantly to the low pK(a) of His187. Thus, the traditional view that a cationic His187 donates a proton to uracil O2 is incorrect. Rather, we propose a concerted mechanism involving general base catalysis by Asp64 and electrophilic stabilization of the developing enolate on uracil O2 by a neutral His187.