Removing a hydrogen bond in the dimer interface of Escherichia coli manganese superoxide dismutase alters structure and reactivity

Among manganese superoxide dismutases, residues His30 and Tyr174 are highly conserved, forming part of the substrate access funnel in the active site. These two residues are structurally linked by a strong hydrogen bond between His30 NE2 from one subunit and Tyr174 OH from the other subunit of the dimer, forming an important element that bridges the dimer interface. Mutation of either His30 or Tyr174 in Escherichia coli MnSOD reduces the superoxide dismutase activity to 30--40% of that of the wt enzyme, which is surprising, since Y174 is quite remote from the active site metal center. The 2.2 A resolution X-ray structure of H30A-MnSOD shows that removing the Tyr174-->His30 hydrogen bond from the acceptor side results in a significant displacement of the main-chain segment containing the Y174 residue, with local rearrangement of the protein. The 1.35 A resolution structure of Y174F-MnSOD shows that disruption of the same hydrogen bond from the donor side has much greater consequences, with reorientation of F174 having a domino effect on the neighboring residues, resulting in a major rearrangement of the dimer interface and flipping of the His30 ring. Spectroscopic studies on H30A, H30N, and Y174F mutants show that (like the previously characterized Y34F mutant of E. coli MnSOD) all lack the high pH transition of the wt enzyme. This observation supports assignment of the pH sensitivity of MnSOD to coordination of hydroxide ion at high pH rather than to ionization of the phenolic group of Y34. Thus, mutations near the active site, as in the Y34F mutant, as well as at remote positions, as in Y174F, similarly affect the metal reactivity and alter the effective pK(a) for hydroxide ion binding. These results imply that hydrogen bonding of the H30 imidazole N--H group plays a key role in substrate binding and catalysis.     

Interrupting the hydrogen bond network at the active site of human manganese superoxide dismutase.

Histidine 30 in human manganese superoxide dismutase (MnSOD) is located at a site partially exposed to solvent with its side chain participating in a hydrogen-bonded network that includes the active-site residues Tyr(166) and Tyr(34) and extends to the manganese-bound solvent molecule. We have replaced His(30) with a series of amino acids and Tyr(166) with Phe in human MnSOD. The crystal structure of the mutant of MnSOD containing Asn(30) superimposed closely with the wild type, but the side chain of Asn(30) did not participate in the hydrogen-bonded network in the active site. The catalytic activity of a number of mutants with replacements at position 30 and for the mutant containing Phe(166) showed a 10-40-fold decrease in k(cat). This is the same magnitude of decrease in k(cat) obtained with the replacement of Tyr(34) by Phe, suggesting that interrupting the hydrogen-bonded active-site network at any of the sites of these three participants (His(30), Tyr(34), and Tyr(166)) leads to an equivalent decrease in k(cat) and probably less efficient proton transfer to product peroxide. The specific geometry of His(30) on the hydrogen bond network is essential for stability since the disparate mutations H30S, H30A, and H30Q reduce T(m) by similar amounts (10-16 degrees C) compared with wild type.     

Two distinct proton donors at the active site of Escherichia coli 2,4-dienoyl-CoA reductase are responsible for the formation of different products

NADPH-dependent 2,4-dienoyl-CoA reductase (DCR) is one of the auxiliary enzymes required for the beta-oxidation of unsaturated fatty acids. Mutants of Escherichia coli DCR were generated by site-directed mutagenesis to explore the molecular mechanism of this enzyme. The Tyr166Phe mutant, which was expected to be inactive due to the loss of its putative proton donor residue, exhibited 27% of the wild-type activity. However, the product of the reduction was 3-enoyl-CoA instead of 2-enoyl-CoA, the normal product. Glu164 seems to function as proton donor in the Tyr166Phe mutant, because the Tyr166Phe/ Glu164Gln double mutant was inactive whereas the Glu164Ala mutant exhibited low but significant activity. His252 is important for the efficient operation of Tyr166 because a His252Ala mutation by itself reduced the activity of DCR by 3 orders of magnitude, whereas the Tyr166Phe/His252Ala double mutation exhibited 4.4% of the wild-type activity. This data supports a mechanism that has Tyr166 with the assistance of His252 acting as proton donor in the wild-type enzyme to produce 2-enoyl-CoA, whereas Glu164 serves as the proton donor in the absence of Tyr166 to yield 3-enoyl-CoA. A Cys337Ala mutation, which resulted in the loss of most of the iron and acid-labile sulfur, decreased the reductase activity more than 1000-fold. This observation agrees with the proposed operation of an intramolecular electron transport chain that is essential for the effective catalysis of E. coli DCR.     

Redox properties of human manganese superoxide dismutase and active-site mutants

The redox potential of human manganese superoxide dismutase (MnSOD) has been difficult to determine because of the problem of finding suitable electron mediators. We have found that ferricyanide and pentacyanoaminoferrate can be used as electron mediators, although equilibration is very slow with a half-time near 6 h. Values of the midpoint potential were determined both by allowing enzyme and mediators to equilibrate up to 38 h and by reductive titration adding dithionite to enzyme and mediator. An overall value of the midpoint potential was found to be 393 +/- 29 mV. To elucidate the role of His30 and Tyr34 in the active site of human MnSOD, we have also measured the redox properties of the site-specific mutants His30Asn (H30N) and Tyr34Phe (Y34F) and compared them with the wild-type enzyme. Crystal structures have shown that each mutation interrupts a hydrogen bond network in the active site, and each causes a 10-fold decrease in the maximal velocity of catalysis of superoxide dismutation as compared with wild type. The present study shows that H30N and Y34F human MnSOD have very little effect, within experimental uncertainty, on the redox potential of the active-site metal. The redox potentials determined electrochemically were 365 +/- 28 mV for H30N and 435 +/- 30 mV for Y34F MnSOD. These results suggest that the role of His30 and Tyr34 is more in support of catalysis, probably proton transport, and not in the tuning of the redox potential.     

Removal of distal protein-water hydrogen bonds in a plant epoxide hydrolase increases catalytic turnover but decreases thermostability

A putative proton wire in potato soluble epoxide hydrolase 1, StEH1, was identified and investigated by means of site-directed mutagenesis, steady-state kinetic measurements, temperature inactivation studies, and X-ray crystallography. The chain of hydrogen bonds includes five water molecules coordinated through backbone carbonyl oxygens of Pro(186), Leu(266), His(269), and the His(153) imidazole. The hydroxyl of Tyr(149) is also an integrated component of the chain, which leads to the hydroxyl of Tyr(154). Available data suggest that Tyr(154) functions as a final proton donor to the anionic alkylenzyme intermediate formed during catalysis. To investigate the role of the putative proton wire, mutants Y149F, H153F, and Y149F/H153F were constructed and purified. The structure of the Y149F mutant was solved by molecular replacement and refined to 2.0 A resolution. Comparison with the structure of wild-type StEH1 revealed only subtle structural differences. The hydroxyl group lost as a result of the mutation was replaced by a water molecule, thus maintaining a functioning hydrogen bond network in the proton wire. All mutants showed decreased catalytic efficiencies with the R,R-enantiomer of trans-stilbene oxide, whereas with the S,S-enantiomer, k (cat)/K (M) was similar or slightly increased compared with the wild-type reactions. k (cat) for the Y149F mutant with either TSO enantiomer was increased; thus the lowered enzyme efficiencies were due to increases in K (M). Thermal inactivation studies revealed that the mutated enzymes were more sensitive to elevated temperatures than the wild-type enzyme. Hence, structural alterations affecting the hydrogen bond chain caused increases in k (cat) but lowered thermostability.     

Role of a glutamate bridge spanning the dimeric interface of human manganese superoxide dismutase

The function in the structure, stability, and catalysis of the interfaces between subunits in manganese superoxide dismutase (MnSOD) is currently under scrutiny. Glu162 in homotetrameric human MnSOD spans a dimeric interface and forms a hydrogen bond with His163 of an adjacent subunit which is a direct ligand of the manganese. We have examined the properties of two site-specific mutants of human MnSOD in which Glu162 is replaced with Asp (E162D) and Ala (E162A). The X-ray crystal structures of E162D and E162A MnSOD reveal no significant structural changes compared with the wild type other than the removal of the hydrogen bond interaction with His163 in E162A MnSOD. In the case of E162D MnSOD, an intervening solvent molecule fills the void created by the mutation to conserve the hydrogen bond interaction between His163 and residue 162. These mutants retain their tetrameric structure and their specificity for manganese over iron. Each has catalytic activity in the disproportionation of superoxide that is typically 5-25% of that of the wild-type enzyme and a level of product inhibition greater by approximately 2-fold. Differential scanning calorimetry indicates that the hydrogen bond between Glu162 and His163 contributes to the stability of MnSOD, with the major unfolding transition occurring at 81 degrees C for E162A compared to 90 degrees C for wild-type MnSOD. These results suggest that Glu162 at the tetrameric interface in human MnSOD supports stability and efficient catalysis and has a significant role in regulating product inhibition.     

Kinetic studies on drug-resistant variants of Escherichia coli thymidylate synthase: functional effects of amino acid substitutions at residue 4.

A naturally occurring mutant of human thymidylate synthase (hTS) that contains a Tyr to His mutation at residue 33 was found to confer 4-fold resistance to 5-fluoro-2'-deoxyuridine (FdUrd), a prodrug of 5-fluoro-2'-deoxyuridine 5'-monophosphate (FdUMP). The crystal structure of hTS implicated this Tyr residue in a drug resistance mechanistic role that may include both substrate binding and catalysis (Schiffer et al., Biochemistry, 34, 16279-16287, 1995). Because of the existence of a defined kinetic scheme and the development of a bacterial expression vector for the overproduction of Escherichia coli TS (ecTS), we chose to initially study the corresponding residue in the bacterial enzyme, Tyr 4 of ecTS. Nine mutant ecTS enzymes that differed in sequence at position 4 were generated. Mutants with a charged or polar side chain (Ser, Cys, Asp, and Arg) and Gly precipitated in the cell paste, resulting in no catalytic activity in cell-free extracts. Although most of the His 4 mutant precipitated, sufficient amounts remained in the cell-free extract to permit isolation to near homogeneity. Wild-type ecTS and mutants with a hydrophobic side chain (Phe, Ile, and Val) were expressed at nearly 30% of the total cellular protein. The k(cat) values for the isolatable mutants were 2- to 10-fold lower than that of the wild-type enzyme, while the K(m) values for 2'-deoxyuridylate (dUMP) and 5,10-methylenetetrahydrofolate (CH(2)H(4)folate) were similar for all the mutants. Dissociation constants for binary complex formation determined by stopped-flow spectroscopy were similar for the wild-type and mutant enzymes for both dUMP and 2'-deoxythymidylate, indicating that this mutation does not significantly alter the binding of the natural nucleotide ligands. However, each mutant enzyme had three- to 5-fold lower affinity for FdUMP in the binary complex compared with the wild-type enzyme, and only His 4 showed a lower affinity for FdUMP in the ternary complex. Analysis of k(burst) showed that the initial binding of CH(2)H(4)folate is weaker for each mutant compared to the wild-type enzyme and that lower k(cat) values were due to compromised rates that govern the chemical transformation of bound substrates to bound products.     

Role of hydrogen bonding in the active site of human manganese superoxide dismutase

The side chain of Gln143, a conserved residue in manganese superoxide dismutase (MnSOD), forms a hydrogen bond with the manganese-bound solvent and is critical in maintaining catalytic activity. The side chains of Tyr34 and Trp123 form hydrogen bonds with the carboxamide of Gln143. We have replaced Tyr34 and Trp123 with Phe in single and double mutants of human MnSOD and measured their catalytic activity by stopped-flow spectrophotometry and pulse radiolysis. The replacements of these side chains inhibited steps in the catalysis as much as 50-fold; in addition, they altered the gating between catalysis and formation of a peroxide complex to yield a more product-inhibited enzyme. The replacement of both Tyr34 and Trp123 in a double mutant showed that these two residues interact cooperatively in maintaining catalytic activity. The crystal structure of Y34F/W123F human MnSOD at 1.95 A resolution suggests that this effect is not related to a conformational change in the side chain of Gln143, which does not change orientation in Y34F/W123F, but rather to more subtle electronic effects due to the loss of hydrogen bonding to the carboxamide side chain of Gln143. Wild-type MnSOD containing Trp123 and Tyr34 has approximately the same thermal stability compared with mutants containing Phe at these positions, suggesting the hydrogen bonds formed by these residues have functional rather than structural roles.     

Mechanism of specific target recognition and RNA hydrolysis by ribonucleolytic toxin restrictocin

Restrictocin, a member of the fungal ribotoxin family, specifically cleaves a single phosphodiester bond in the 28S rRNA and potently inhibits eukaryotic protein synthesis. Residues Tyr47, His49, Glu95, Phe96, Pro97, Arg120, and His136 have been predicted to form the active site of restrictocin. In this study, we have individually mutated these amino acids to alanine to probe their role in restrictocin structure and function. The role of Tyr47, His49, Arg120, and His136 was further investigated by making additional mutants. Mutating Arg120 or His136 to alanine or the other amino acids rendered the toxin completely inactive, whereas mutating Glu95 to alanine only partially inactivated the toxin. Mutation of Phe96 and Pro97 to Ala had no effect on the activity of restrictocin. The Tyr47 to alanine mutant was inactive in inhibiting protein synthesis, and had a nonspecific ribonuclease activity on 28S rRNA similar to that shown previously for the His49 to Ala mutant. Unlike the His136 to Ala mutant, the double mutants containing Tyr47 or His49 mutated to alanine along with His136 did not compete with restrictocin to cause a significant reduction in the extent of cleavage of 28S rRNA. In a model of restrictocin and a 29-mer RNA substrate complex, residues Tyr47, His49, Glu95, Arg120, and His136 were found to be near the cleavage site on RNA. It is proposed that in restrictocin Glu95 and His136 are directly involved in catalysis, Arg120 is involved in the stabilization of the enzyme-substrate complex, Tyr47 provides structural stability to the active site, and His49 determines the substrate specificity.     

Structural response to mutation at a protein-protein interface

We have crystallised three mutants of the barnase-barstar complex in which interactions across the interface have been deleted by simultaneous mutation of both residues involved in the interaction. Each mutant deletes a different type of interaction at the interface: the first complex bnHis102-->Ala-bsTyr29-->Phe (bn, barnase; bs, barstar), deletes a van der Waals packing interaction; the second complex, bnLys27-->Ala-bsThr42-->Ala, deletes a hydrogen bond; the third, bnLys27-->Ala-bsAsp35-->Ala, deletes a long-range charge-charge interaction. The contribution of each of these side-chains to the stability of the complex is known; the coupling energy between the deleted side-chains is also known. Despite each of the double mutants being significantly destabilised compared with the wild-type, the effects of mutation are local. Only small movements in the main-chain surrounding the sites of mutation and some larger movements of neighbouring side-chains are observed in the mutant complexes. The exact response to mutation is context-dependent and for the same mutant can vary depending upon the environment within the crystal. In some double mutant complexes, interfacial pockets, which are accessible to bulk solvent are formed, whereas interfacial cavities which are isolated from bulk solvent, are formed in others. In all double mutants, water molecules fill the created pockets and cavities. These water molecules mimic the deleted side-chains by occupying positions close to the non-carbon atoms of truncated side-chains and re-making many hydrogen bonds made by the truncated side-chains in the wild-type. It remains extremely difficult, however, to correlate energetic and structural responses to mutation because of unknown changes in entropy and entropy-enthalpy compensation.     

Thermodynamics of ligand binding and denaturation for His64 mutants of tissue plasminogen activator kringle-2 domain

The contribution of His64 to the function and stability of tissue plasminogen activator (t-PA) kringle-2 domain (His244 in t-PA numbering) has been studied by using microcalorimetric methods to compare the ligand binding and thermal denaturation behavior of wild-type kringle-2 and mutants having His64 replaced with Tyr or Phe. This site was examined because modeling studies suggested that the His64 side chain could play an important role in ligand binding by forming an ion-pair with the carboxylate of the ligand, L-lysine. Kringle-2 domains were expressed by secretion of the 174-263 portion of t-PA in E. coli and purified as previously described for the wild-type domain. Both mutant proteins retain affinity for L-lysine, although reduced three- to four-fold relative to wild-type, demonstrating that His64 does not interact with the ligand carboxylate through an ion-pair interaction or by hydrogen bonding. The H64Y substitution does result in an altered specificity of the lysine binding site with the mutant domain having greatest affinity for a ligand of 6.8 A chain length, whereas the wild-type domain prefers an 8.8 A long ligand. For both wild-type and mutant, the binding of the optimal chain length ligand is dominated by enthalpic effects (delta H = -6,000 to -7,000 cal/mol) and T delta S accounts for less than 15% of delta G. In addition, the H64Y mutant differs from wild-type in the effect of ligand alpha-amino group modification on binding affinity. Based on examination of the x-ray structure recently determined for wild-type kringle-2, the specificity changes accompanying the H64Y substitution probably result from changes in side chain interactions in the lysine binding site. Thermal denaturation experiments show that the H64Y mutant is also more stable than the wild-type protein with the difference in stabilization free energy (delta delta G) equal to 2.7 kcal/mol at 25 degrees C and pH 3. The increased stability of the mutant appears to be related to the difference in hydrophobicity between His and Tyr.     

The utility of molecular dynamics simulations for understanding site-directed mutagenesis of glycine residues in biotin carboxylase

Biotin carboxylase from Escherichia coli catalyzes the ATP-dependent carboxylation of biotin and is one component of the multienzyme complex acetyl-CoA carboxylase, which catalyzes the committed step in long-chain fatty acid synthesis. Comparison of the crystal structures of biotin carboxylase in the absence and presence of ATP showed a central B-domain closure when ATP was bound. Peptidic NH groups from two active site glycine residues (Gly165 and Gly166) that form hydrogen bonds to the phosphate oxygens of ATP were postulated to act as a "trigger" for movement of the B-domain. The function of these two glycine residues in the catalytic mechanism was studied by disruption of the hydrogen bonds using site-directed mutagenesis. Both single (G165V) and (G166V) and double mutants (G165V-G166V) were constructed. The mutations did not affect the maximal velocity of a partial reaction, the bicarbonate-dependent ATPase activity. This suggests that the peptidic NH groups of Gly165 and Gly166 are not triggers for domain movement. However, the K(m) values for ATP for each of the mutants was increased over 40-fold when compared with wild-type indicating the peptidic NH groups of Gly165 and Gly166 play a role in binding ATP. Consistent with ATP binding, the maximal velocity for the biotin-dependent ATPase activity (i.e. the complete reaction) was decreased over 100-fold suggesting the mutations have misaligned the reactants for optimal catalysis. Molecular dynamics studies confirm perturbation of the hydrogen bonds from the mutated residues to ATP, whereas the double mutant exhibits antagonistic effects such that hydrogen bonding from residues 165 and 166 to ATP is similar to that in the wild-type. Consistent with the site-directed mutagenesis results the molecular dynamics studies show that ATP is misaligned in the mutants.     

Structural and kinetic analysis of proton shuttle residues in the active site of human carbonic anhydrase III

We report the X-ray crystal structures and rate constants for proton transfer in site-specific mutants of human carbonic anhydrase III (HCA III) that place a histidine residue in the active-site cavity: K64H, R67H, and K64H-R67N HCA III. Prior evidence from the exchange of 18O between CO2 and water measured by mass spectrometry shows each mutant to have enhanced proton transfer in catalysis compared with wild-type HCA III. However, His64 in K64H and K64H-R67N HCA III have at most a capacity for proton transfer that is only 13% that of His64 in HCA II. This reduced rate in mutants of HCA III is associated with a constrained side-chain conformation of His64, which is oriented outward, away from the active-site zinc in the crystal structures. This conformation appears stabilized by a prominent pi stacking interaction of the imidazole ring of His64 with the indole ring of Trp5 in mutants of HCA III. This single orientation of His64 in K64H HCA III predominates also in a double mutant K64H-R67N HCA III, indicating that the positive charge of Arg67 does not influence the observed conformation of His64 in the crystal structure. Hence, the structures and catalytic activity of these mutants of HCA III containing His64 account only in small part for the lower activity of this isozyme compared with HCA II. His67 in R67H HCA III was also shown to be a proton shuttle residue, having a capacity for proton transfer that was approximately four times that of His64 in K64H HCA III. This is most likely due to its proximity and orientation inward towards the zinc-bound solvent. These results emphasize the significance of side chain orientation and range of available conformational states as characteristics of an efficient proton shuttle in carbonic anhydrase.     

The role of double covalent flavin binding in chito-oligosaccharide oxidase from Fusarium graminearum

ChitO (chito-oligosaccharide oxidase) from Fusarium graminearum catalyses the regioselective oxidation of N-acetylated oligosaccharides. The enzyme harbours an FAD cofactor that is covalently attached to His94 and Cys154. The functional role of this unusual bi-covalent flavin-protein linkage was studied by site-directed mutagenesis. The double mutant (H94A/C154A) was not expressed, which suggests that a covalent flavin-protein bond is needed for protein stability. The single mutants H94A and C154A were expressed as FAD-containing enzymes in which one of the covalent FAD-protein bonds was disrupted relative to the wild-type enzyme. Both mutants were poorly active, as the k(cat) decreased (8.3- and 3-fold respectively) and the K(m) increased drastically (34- and 75-fold respectively) when using GlcNac as the substrate. Pre-steady-state analysis revealed that the rate of reduction in the mutant enzymes is decreased by 3 orders of magnitude when compared with wild-type ChitO (k(red)=750 s(-1)) and thereby limits the turnover rate. Spectroelectrochemical titrations revealed that wild-type ChitO exhibits a relatively high redox potential (+131 mV) and the C154A mutant displays a lower potential (+70 mV), while the H94A mutant displays a relatively high potential of approximately +164 mV. The results show that a high redox potential is not the only prerequisite to ensure efficient catalysis and that removal of either of the covalent bonds may perturb the geometry of the Michaelis complex. Besides tuning the redox properties, the bi-covalent binding of the FAD cofactor in ChitO is essential for a catalytically competent conformation of the active site.     

Probing the role of the fully conserved Cys126 in triosephosphate isomerase by site-specific mutagenesis--distal effects on dimer stability

Cys126 is a completely conserved residue in triosephosphate isomerase that is proximal to the active site but has been ascribed no specific role in catalysis. A previous study of the C126S and C126A mutants of yeast TIM reported substantial catalytic activity for the mutant enzymes, leading to the suggestion that this residue is implicated in folding and stability [Gonzalez-Mondragon E et al. (2004) Biochemistry 43, 3255-3263]. We re-examined the role of Cys126 with the Plasmodium falciparum enzyme as a model. Five mutants, C126S, C126A, C126V, C126M, and C126T, were characterized. Crystal structures of the 3-phosphoglycolate-bound C126S mutant and the unliganded forms of the C126S and C126A mutants were determined at a resolution of 1.7-2.1 ?. Kinetic studies revealed an approximately five-fold drop in k(cat) for the C126S and C126A mutants, whereas an approximately 10-fold drop was observed for the other three mutants. At ambient temperature, the wild-type enzyme and all five mutants showed no concentration dependence of activity. At higher temperatures (> 40 °C), the mutants showed a significant concentration dependence, with a dramatic loss in activity below 15 μM. The mutants also had diminished thermal stability at low concentration, as monitored by far-UV CD. These results suggest that Cys126 contributes to the stability of the dimer interface through a network of interactions involving His95, Glu97, and Arg98, which form direct contacts across the dimer interface.     

Proton transfer in the oxidative half-reaction of pentaerythritol tetranitrate reductase. Structure of the reduced enzyme-progesterone complex and the roles of residues Tyr186, His181, His184

The roles of His181, His184 and Tyr186 in PETN reductase have been examined by mutagenesis, spectroscopic and stopped-flow kinetics, and by determination of crystallographic structures for the Y186F PETN reductase and reduced wild-type enzyme-progesterone complex. Residues His181 and His184 are important in the binding of coenzyme, steroids, nitroaromatic ligands and the substrate 2-cyclohexen-1-one. The H181A and H184A enzymes retain activity in reductive and oxidative half-reactions, and thus do not play an essential role in catalysis. Ligand binding and catalysis is not substantially impaired in Y186F PETN reductase, which contrasts with data for the equivalent mutation (Y196F) in Old Yellow Enzyme. The structure of Y186F PETN reductase is identical to wild-type enzyme, with the obvious exception of the mutation. We show in PETN reductase that Tyr186 is not a key proton donor in the reduction of alpha/beta unsaturated carbonyl compounds. The structure of two electron-reduced PETN reductase bound to the inhibitor progesterone mimics the catalytic enzyme-steroid substrate complex and is similar to the structure of the oxidized enzyme-inhibitor complex. The reactive C1-C2 unsaturated bond of the steroid is inappropriately orientated with the flavin N5 atom for hydride transfer. With steroid substrates, the productive conformation is achieved by orientating the steroid through flipping by 180 degrees , consistent with known geometries for hydride transfer in flavoenzymes. Our data highlight mechanistic differences between Old Yellow Enzyme and PETN reductase and indicate that catalysis requires a metastable enzyme-steroid complex and not the most stable complex observed in crystallographic studies.     

Mutation of Tyr138 disrupts the structural coupling between the opposing domains in vertebrate calmodulin

We have used circular dichroism and frequency-domain fluorescence spectroscopy to determine how the site-specific substitution of Tyr138 with either Phe138 or Gln138 affects the structural coupling between the opposing domains of calmodulin (CaM). A double mutant was constructed involving conservative substitution of Tyr99 --> Trp99 and Leu69 --> Cys69 to assess the structural coupling between the opposing domains, as previously described [Sun, H., Yin, D., and Squier, T. C. (1999) Biochemistry 38, 12266-12279]. Trp99 acts as a fluorescence resonance energy transfer (FRET) donor in distance measurements to probe the conformation of the central helix. Cys69 provides a reactive group for the covalent attachment of 5-((((2-iodoacetyl)amino)ethyl)amino)naphthalene-1-sulfonic acid (IAEDANS), which functions as a FRET acceptor and permits the measurement of the rotational dynamics of the amino-terminal domain. These CaM mutants demonstrate normal calcium-dependent gel-mobility shifts and changes in their near-UV CD spectra, have similar secondary structures to wild-type CaM following calcium activation, and retain the ability to fully activate the plasma membrane Ca-ATPase. The global folds, therefore, of both the carboxyl- and amino-terminal domains in these CaM mutants are similar to that of wild-type CaM. However, in comparison to wild-type CaM, the substitution of Tyr138 with either Phe138 or Gln138 results in (i) alterations in the average spatial separation and increases in the conformational heterogeneity between the opposing globular domains and (ii) the independent rotational dynamics of the amino-terminal domain. These results indicate that alterations in either the hydrogen bond between Tyr138 and Glu82 or contact interactions between aromatic amino acid side chains have the potential to initiate the structural collapse of CaM normally associated with target protein binding and activation.     

Role of hydrogen bond networks and dynamics in positive and negative cooperative stabilization of a protein

Cooperativity mediated through hydrogen bond networks in yeast iso-1-cytochrome c was studied using a thermodynamic triple mutant cycle. Three known stabilizing mutations, Asn 26 to His, Asn 52 to Ile, and Tyr 67 to Phe, were used to construct the triple mutant cycle. The side chain of His 26, a wild-type residue, forms two hydrogen bonds that bridge two substructures of the wild-type protein, and Tyr 67 and Asn 52 are part of an extensive buried hydrogen bond network. The stabilities of all variants in the triple mutant cycle were determined by guanidine hydrochloride denaturation methods and used to determine the pairwise, Delta(2)G(int), and triple interaction energies. His 26 and Ile 52 interact cooperatively (Delta(2)G(int) is 1-2 kcal/mol), whereas the two other pairs of mutations interact anticooperatively (Delta(2)G(int) is -0.5 to -1.5 kcal/mol). Previously reported structural data for iso-1-cytochrome c variants containing these mutations show that changes in the strength of the His 26 to Glu 44 hydrogen bond, apparently caused by changes in main chain dynamics, provide a mechanism for the long distance (His 26 to Phe 67 and His 26 to Ile 52) propagation of pairwise interaction energies. Opposing changes in the strength of the His 26 to Glu 44 hydrogen bond caused by the N52I and Y67F mutations generate a negative triple interaction energy (-0.9 +/-0.7 kcal/mol) that combined with cancellation of cooperative and anticooperative pairwise interactions produce apparent additivity for the stabilizing effects of the single mutations in the triple mutant variant.     

Rupture of the hydrogen bond linking two Omega-loops induces the molten globule state at neutral pH in cytochrome c

His26Tyr and His33Tyr mutants were obtained from the Cys102Thr variant of yeast iso-1-cytochrome c. Spectroscopic studies show that a mutation at position 26 at pH 7.0 enhances flexibility of the peptide, alters the heme pocket region and the axial coordination to heme-iron, and reduces protein stability. The His26Tyr mutant shows properties typical of the molten globule. Further, formation of an axially misligated minor low spin species occurs with partial displacement of Met80, the axial ligand of the heme-iron in the native protein. The pK(a) determined for the alkaline transition of this mutant is 7.48 (+/- 0.05), approximately 0.5 lower than that of the wild-type protein. Hence, the alkaline conformer is populated at pH 7.0, and the sixth ligand of the misligated species is proposed to be a lysine. Furthermore, a reduction in catalytic activity indicates that the functional properties are altered. The results suggest that the structural and functional changes observed in the His26Tyr mutant are because the mutation frees the two Omega-loops that, in the native protein, are linked by the hydrogen bond between His26 and Glu44. Hence, one may infer that the His26-Glu44 hydrogen bond is essential for the rigidity and stability of the native protein. In its absence, the heightened flexibility of the peptide fold results in conversion of the macromolecule to a molten globule state, even at neutral pH. Ligand exchange at the sixth coordination position of the heme-iron(III) observed as the minor species (i.e., the alkaline conformer) is therefore induced by a long-range effect. This result is of interest since mutations reported to date, which stabilize the alkaline conformer, all occur in the loop including Met80. By contrast, only very minor spectroscopic (and, thus, structural) changes are observed for the His33Tyr mutant. This suggests that His33 does not form intramolecular bonds considered important for the protein structure and stability, and is consistent with the high variability of residues at position 33 in cytochromes c.