Stable proline box motif at the N-terminal end of alpha-helices.

We describe a novel N-terminal alpha-helix local motif that involves three hydrophobic residues and a Pro residue (Pro-box motif). Database analysis shows that when Pro is the N-cap of an alpha-helix the distribution of amino acids in adjacent positions changes dramatically with respect to the average distribution in an alpha-helix, but not when Pro is at position N1. N-cap Pro residues are usually associated to Ile and Leu, at position N', Val at position N3 and a hydrophobic residue (h) at position N4. The side chain of the N-cap Pro packs against Val, while the hydrophobic residues at positions N' and N4 make favorable interactions. To analyze the role of this putative motif (sequence fingerprint hPXXhh), we have synthesized a series of peptides and analyzed them by circular dichroism (CD) and NMR. We find that this motif is formed in peptides, and that the accompanying hydrophobic interactions contribute up to 1.2 kcal/mol to helix stability. The fact that some of the residues in this fingerprint are not good N-cap and helix formers results in a small overall stabilization of the alpha-helix with respect to other peptides having Gly as the N-cap and Ala at N3 and N4. This suggests that the Pro-box motif will not specially contribute to protein stability but to the specificity of its fold. In fact, 80% of the sequences that contain the fingerprint sequence in the protein database are adopting the described structural motif, and in none of them is the helix extended to place Pro at the more favorable N1 position.     

Role of the histidine triad-like motif in nucleotide hydrolysis by the rotavirus RNA-packaging protein NSP2

Octamers formed by the nonstructural protein NSP2 of rotavirus are proposed to function as molecular motors in the packaging of the segmented double-stranded RNA genome. The octamers have RNA binding, helix unwinding, and Mg(2+)-dependent NTPase activities and play a crucial role in assembly of viral replication factories (viroplasms). Comparison of x-ray structures has revealed significant structural homology between NSP2 and the histidine triad (HIT) family of nucleotidyl hydrolases, which in turn has suggested the location of the active site for NTP hydrolysis in NSP2. Consistent with the structural predictions, we show here using site-specific mutagenesis and ATP docking simulations that the active site for NTP hydrolysis is localized to residues within a 25-A-deep cleft between the C- and N-terminal domains of the NSP2 monomer. Although lacking the precise signature HIT motif (H?H?H?? where ? is a hydrophobic residue), our analyses demonstrate that histidines (His(221) and His(225)) represent critical residues of the active site. Similar to events occurring during nucleotide hydrolysis by HIT proteins, NTP hydrolysis by NSP2 was found to produce a short lived phosphorylated intermediate. Evaluation of the biological importance of the NTPase activity of NSP2 by transient expression in mammalian cells showed that such activity has no impact on the ability of NSP2 to induce the hyperphosphorylation of NSP5 or to interact with NSP5 to form viroplasm-like structures. Hence the NTPase activity of NSP2 probably has a role subsequent to the formation of viroplasms, consistent with its suspected involvement in RNA packaging and/or replication.     

Direct Determination of Protonation States of Histidine Residues in a 2 Å Neutron Structure of Deoxy-Human Normal Adult Hemoglobin and Implications for the Bohr Effect

We have investigated the protonation states of histidine residues (potential Bohr groups) in the deoxy form (T state) of human hemoglobin by direct determination of hydrogen (deuterium) positions with the neutron protein crystallography technique. The reversible binding of protons is key to the allosteric regulation of human hemoglobin. The protonation states of 35 of the 38 His residues were directly determined from neutron scattering omit maps, with 3 of the remaining residues being disordered. Protonation states of 5 equivalent His residues—αHis20, αHis50, αHis89, βHis143, and βHis146—differ between the symmetry-related globin subunits. The distal His residues, αHis58 and βHis63, are protonated in the α1β1 heterodimer and are neutral in α2β2. Buried residue αHis103 is found to be protonated in both subunits. These distal and buried residues have the potential to act as Bohr groups. The observed protonation states of His residues are compared to changes in their pK_a values during the transition from the T to the R state and the results provide some new insights into our understanding of the molecular mechanism of the Bohr effect.     

His ... Asp catalytic dyad of ribonuclease A: histidine pKa values in the wild-type, D121N, and D121A enzymes

Bovine pancreatic ribonuclease A (RNase A) has a conserved His ... Asp catalytic dyad in its active site. Structural analyses had indicated that Asp121 forms a hydrogen bond with His119, which serves as an acid during catalysis of RNA cleavage. The enzyme contains three other histidine residues including His12, which is also in the active site. Here, 1H-NMR spectra of wild-type RNase A and the D121N and D121A variants were analyzed thoroughly as a function of pH. The effect of replacing Asp121 on the microscopic pKa values of the histidine residues is modest: none change by more than 0.2 units. There is no evidence for the formation of a low-barrier hydrogen bond between His119 and either an aspartate or an asparagine residue at position 121. In the presence of the reaction product, uridine 3'-phosphate (3'-UMP), protonation of one active-site histidine residue favors protonation of the other. This finding is consistent with the phosphoryl group of 3'-UMP interacting more strongly with the two active-site histidine residues when both are protonated. Comparison of the titration curves of the unliganded enzyme with that obtained in the presence of different concentrations of 3'-UMP shows that a second molecule of 3'-UMP can bind to the enzyme. Together, the data indicate that the aspartate residue in the His ... Asp catalytic dyad of RNase A has a measurable but modest effect on the ionization of the adjacent histidine residue.     

A conserved "hydrophobic staple motif" plays a crucial role in the refolding of human glutathione transferase P1-1

The specific (i, i+5) hydrophobic staple interaction involving a helix residue and a second residue located in the turn preceding the helix is a recurrent motif at the N terminus of alpha-helices. This motif is strictly conserved in the core of all soluble glutathione transferases (GSTs) as well as in other protein structures. Human GSTP1-1 variants mutated in amino acid Ile(149) and Tyr(154) of the hydrophobic staple motif of the alpha6-helix were analyzed. In particular, a double mutant cycle analysis has been performed to evaluate the role of the hydrophobic staple motif in the refolding process. The results show that this local interaction, by restricting the number of conformations of the alpha6-helix relative to the alpha1-helix, favors the formation of essential interdomain interactions and thereby accelerates the folding process. Thus, for the first time it is shown that the hydrophobic staple interaction has a role in the folding process of an intact protein. In P(i) class GSTs, Tyr(154) appears to be of particular structural importance, since it interacts with conserved residues Leu(21), Asp(24), and Gln(25) of the adjacent alpha1-helix which contributes to the active site. Human GSTP1-1 variants L21A and Y154F have also been analyzed in order to distinguish the role of interdomain interactions from that of the hydrophobic staple. The experimental results reported here suggest that the strict conservation of the hydrophobic staple motif reflects an evolutionary pressure for proteins to fold rapidly.     

Characterization of a buried neutral histidine residue in Bacillus circulans xylanase: NMR assignments, pH titration, and hydrogen exchange.

Bacillus circulans xylanase contains two histidines, one of which (His 156) is solvent exposed, whereas the other (His 149) is buried within its hydrophobic core. His 149 is involved in a network of hydrogen bonds with an internal water and Ser 130, as well as a potential weak aromatic-aromatic interaction with Tyr 105. These three residues, and their network of interactions with the bound water, are conserved in four homologous xylanases. To probe the structural role played by His 149, NMR spectroscopy was used to characterize the histidines in BCX. Complete assignments of the 1H, 13C, and 15N resonances and tautomeric forms of the imidazole rings were obtained from two-dimensional heteronuclear correlation experiments. An unusual spectroscopic feature of BCX is a peak near 12 ppm arising from the nitrogen bonded 1H epsilon 2 of His 149. Due to its solvent inaccessibility and hydrogen bonding to an internal water molecule, the exchange rate of this proton (4.0 x 10(-5) s-1 at pH*7.04 and 30 degrees C) is retarded by > 10(6)-fold relative to an exposed histidine. The pKa of His 156 is unperturbed at approximately 6.5, as measured from the pH dependence of the 15N- and 1H-NMR spectra of BCX. In contrast, His 149 has a pKa < 2.3, existing in the neutral N epsilon 2H tautomeric state under all conditions examined. BCX unfolds at low pH and 30 degrees C, and thus His 149 is never protonated significantly in the context of the native enzyme. The structural importance of this buried histidine is confirmed by the destablizing effect of substituting a phenylalanine or glutamine at position 149 in BCX.     

Molecular dissection,tissue localization and Ca2+ binding of the ryanodine receptor of Caenorhabditis elegans

We investigated the possible role of residues at the Ccap position in an alpha-helix on protein stability. A set of 431 protein alpha-helices containing a C'-Gly from the Protein Data Bank (PDB) was analyzed, and the normalized frequencies for finding particular residues at the Ccap position, the average fraction of buried surface area, and the hydrogen bonding patterns of the Ccap residue side-chain were calculated. We found that on average the Ccap position is 70% buried and noted a significant correlation (R=0.8) between the relative burial of this residue and its hydrophobicity as defined by the Gibbs energy of transfer from octanol or cyclohexane to water. Ccap residues with polar side-chains are commonly involved in hydrogen bonding. The hydrogen bonding pattern is such that, the longer side-chains of Glu, Gln, Arg, Lys, His form hydrogen bonds with residues distal (>+/-4) in sequence, while the shorter side-chains of Asp, Asn, Ser, Thr exhibit hydrogen bonds with residues close in sequence (<+/-4), mainly involving backbone atoms. Experimentally we determined the thermodynamic propensities of residues at the Ccap position using the protein ubiquitin as a model system. We observed a large variation in the stability of the ubiquitin variants depending on the nature of the Ccap residue. Furthermore, the measured changes in stability of the ubiquitin variants correlate with the hydrophobicity of the Ccap residue. The experimental results, together with the statistical analysis of protein structures from the PDB, indicate that the key hydrophobic capping interactions between a helical residue (C3 or C4) and a residue outside the helix (C", C3' or C4') are frequently enhanced by the hydrophobic interactions with Ccap residues.     

The role of a clinically important mutation in the fold and RNA-binding properties of KH motifs

We have investigated the role in the fold and RNA-binding properties of the KH modules of a hydrophobic to asparagine mutation of clinical importance in the fragile X syndrome. The mutation involves a well-conserved hydrophobic residue close to the N terminus of the second helix of the KH fold (alpha2(3) position). The effect of the mutation has been long debated: Although the mutant has been shown to disrupt the three-dimensional fold of several KH domains, the residue seems also to be directly involved in RNA binding, the main function of the KH module. Here we have used the KH3 of Nova-1, whose structure is known both in isolation and in an RNA complex, to study in detail the role of the alpha2(3) position. A detailed comparison of Nova KH3 structure with its RNA/KH complex and with other KH structures suggests a dual role for the alpha2(3) residue, which is involved both in stabilizing the hydrophobic core and in RNA contacts. We further show by nuclear magnetic resonance (NMR) studies in solution that L447 of Nova-1 in position alpha2(3) is in exchange in the absence of RNA, and becomes locked in a more rigid conformation only upon formation of an RNA complex. This implies that position alpha2(3) functions as a "gate" in the mechanism of RNA recognition of KH motifs based on the rigidification of the fold upon RNA binding.     

Architecture of the catalytic HPN motif is conserved in all E2 conjugating enzymes

E2 conjugating enzymes are the central enzymes in the ubiquitination pathway and are responsible for the transfer of ubiquitin and ubiquitin-like proteins on to target substrates. The secondary structural elements of the catalytic domain of these enzymes is highly conserved, including the sequence conservation of a three-residue HPN (His-Pro-Asn) motif located upstream of the active-site cysteine residue used for ubiquitin conjugation. Despite the vast structural knowledge of E2 enzymes, the catalytic mechanism of these enzymes remains poorly understood, in large part due to variation in the arrangements of the residues in the HPN motif in existing E2 structures. In the present study, we used the E2 enzyme HIP2 to probe the structures of the HPN motif in several other E2 enzymes. A combination of chemical-shift analysis, determination of the histidine protonation states and amide temperature coefficients were used to determine the orientation of the histidine ring and hydrogen-bonding arrangements within the HPN motif. Unlike many three-dimensional structures, we found that a conserved hydrogen bond between the histidine imidazole ring and the asparagine backbone amide proton, a common histidine protonation state, and a common histidine orientation exists for all E2 enzymes examined. These results indicate that the histidine within the HPN motif is orientated to structurally stabilize a tight turn motif in all E2 enzymes and is not orientated to interact with the asparagine side chain as proposed in some mechanisms. These results suggest that a common catalysis mechanism probably exists for all E2 conjugating enzymes to facilitate ubiquitin transfer.     

Contribution of glycine 146 to a conserved folding module affecting stability and refolding of human glutathione transferase p1-1

In human glutathione transferase P1-1 (hGSTP1-1) position 146 is occupied by a glycine residue, which is located in a bend of a long loop that together with the alpha6-helix forms a substructure (GST motif II) maintained in all soluble GSTs. In the present study G146A and G146V mutants were generated by site-directed mutagenesis in order to investigate the function played by this conserved residue in folding and stability of hGSTP1-1. Crystallographic analysis of the G146V variant, expressed at the permissive temperature of 25 degrees C, indicates that the mutation causes a substantial change of the backbone conformation because of steric hindrance. Stability measurements indicate that this mutant is inactivated at a temperature as low as 32 degrees C. The structure of the G146A mutant is identical to that of the wild type with the mutated residue having main-chain bond angles in a high energy region of the Ramachandran plot. However even this Gly --> Ala substitution inactivates the enzyme at 37 degrees C. Thermodynamic analysis of all variants confirms, together with previous findings, the critical role played by GST motif II for overall protein stability. Analysis of reactivation in vitro indicates that any mutation of Gly-146 alters the folding pathway by favoring aggregation at 37 degrees C. It is hypothesized that the GST motif II is involved in the nucleation mechanism of the protein and that the substitution of Gly-146 alters this transient substructure. Gly-146 is part of the buried local sequence GXXh(T/S)XXDh (X is any residue and h is a hydrophobic residue), conserved in all GSTs and related proteins that seems to behave as a characteristic structural module important for protein folding and stability.     

Completely buried, non-ion-paired glutamic acid contributes favorably to the conformational stability of pyrrolidone carboxyl peptidases from hyperthermophiles

Pyrrolidone carboxyl peptidases (PCPs) from hyperthermophiles have a structurally conserved and completely buried Glu192 in the hydrophobic core; in contrast, the corresponding residue in the mesophile protein is a hydrophobic residue, Ile. Does the buried ionizable residue contribute to stabilization or destabilization of hyperthermophile PCPs? To elucidate the role of the buried glutamic acid in stabilizing PCP from hyperthermophiles, we constructed five Glu192 mutants of PCP-0SH (C142S/C188S, Cys-free double mutant of PCP) from Pyrococcus furiosus and examined their thermal and pH-induced unfolding and crystal structures and compared them with those of PCP-0SH. The stabilities of apolar (E192A/I/V) and polar (E192D/Q) mutants were less than PCP-0SH at acidic pH values. In the alkaline region, the mutant proteins, except for E192D, were more stable than PCP-0SH. The thermal stability data and theoretical calculations indicated an apparent pKa value > or = 7.3 for Glu192. Present results confirmed that the protonated Glu192 in PCP-0SH forms strong hydrogen bonds with the carbonyl oxygen and peptide nitrogen of Pro168. New intermolecular hydrogen bonds in the E --> A/D mutants were formed by a water molecule introduced into the cavity created around position 192, whereas the hydrogen bonds disappeared in the E --> I/V mutants. Structure-based empirical stability of mutant proteins was in good agreement with the experimental results. The results indicated that (1) completely buried Glu192 contributes to the stabilization of PCP-0SH because of the formation of strong intramolecular hydrogen bonds and (2) the hydrogen bonds by the nonionized and buried Glu can contribute more than the burial of hydrophobic groups to the conformational stability of proteins.     

Are the histidine residues of glutathione S-transferase important in catalysis? An assessment by 13C NMR spectroscopy and site-specific mutagenesis

To test the proposition that a histidine residue is essential in the catalytic mechanism of glutathione S-transferase, rat liver isoenzyme 3-3 specifically labeled with [ring-2-13C]histidine was prepared. The 13C NMR spectrum of the labeled enzyme revealed four resonances corresponding to the 4 histidine residues in the mu gene class type 3 subunit. Titration of the four resonances in the range of pH 4-9 both in the presence and absence of glutathione gave pK alpha values of much less than 4, 5.2, 7.1, and 7.8 for the four side chains that were identified by site-specific mutagenesis as His14, His83, His84, and His167, respectively. The magnetic resonance properties and titration behavior of His14 suggest that this residue is buried in a hydrophobic environment. Conservative replacement of each histidine with asparagine results in mutant enzymes that have catalytic properties very close to the native protein as assessed with three different substrates, 1-chloro-2,4-dinitrobenzene, 4-phenyl-3-buten-2-one, and phenanthrene 9,10-oxide. The results indicate clearly that none of the histidine residues of isoenzyme 3-3 is essential for stabilization of the bound glutathione thiolate or for any other aspect of catalysis.     

Two-dimensional NMR studies of the zinc finger motif: solution structures and dynamics of mutant ZFY domains containing aromatic substitutions in the hydrophobic core.

Solution structures of mutant Zn fingers containing aromatic substitutions in the hydrophobic core are determined by 2D-NMR spectroscopy and distance-geometry/simulated annealing (DG/SA). The wild-type domain (designated ZFY-6) is derived from the human male-associated protein ZFY and represents a sequence motif (Cys-X2-Cys-X-Ar-X7-Leu-X2-His-X4-His) that differs from the consensus (Cys-X2,4-Cys-X3-Phe-X5-Leu-X2-His-X3-His) in the location ("aromatic swap") and diversity (Ar = tyrosine, phenylalanine, or histidine) of the central aromatic residue (underlined). In a given ZFY domain the choice of a particular aromatic residue is invariant among vertebrates, suggesting that alternative "swapped" aromatic residues are functionally inequivalent. 2D-NMR studies of analogues containing tyrosine, phenylalanine, or histidine at the swapped site yield the following results. (i) The three DG/SA structures each retain the beta beta alpha motif and exhibit similar staggered-horizontal packing between the variant aromatic residue and the proximal histidine in the hydrophobic core. (ii) The structures and stabilities of the tyrosine and phenylalanine analogues are essentially identical, differing only by local exposure of polar (Tyr p-OH) or nonpolar (Phe p-H) surfaces. (iii) The dynamic stability of the histidine analogue is reduced as indicated by more rapid protein-deuterium exchange of hydrogen bonds related to secondary structure and amide-sulfur coordination (slowly exchanging amide resonances in D2O) and by more extensive averaging of main-chain dihedral angles (3J alpha NH coupling constants). An aspartic acid in the putative DNA recognition surface, whose configuration is well-defined as a possible helix N-cap in the tyrosine and phenylalanine analogues, exhibits multiple weak main-chain contacts in the NOESY spectrum of the histidine analogue; such NOEs are geometrically inconsistent and so provide complementary evidence for structural fluctuations. (iv) Because the three DG ensembles have similar apparent precision, the finding of reduced dynamic stability in the histidine analogue emphasizes the importance of experiments that directly probe fluctuations at several time scales. Our results provide insight into the design of biological metal-binding sites and the relationship of protein sequence to structure and dynamics.     

Determining the molecular basis for the pH-dependent interaction between the link module of human TSG-6 and hyaluronan

TSG-6 is an inflammation-associated hyaluronan (HA)-binding protein that has anti-inflammatory and protective functions in arthritis and asthma as well as a critical role in mammalian ovulation. The interaction between TSG-6 and HA is pH-dependent, with a marked reduction in affinity on increasing the pH from 6.0 to 8.0. Here we have investigated the mechanism underlying this pH dependence using a combined approach of site-directed mutagenesis, NMR, isothermal titration calorimetry and microtiter plate assays. Analysis of single-site mutants of the TSG-6 Link module indicated that the loss in affinity above pH 6.0 is mediated by the change in ionization state of a histidine residue (His(4)) that is not within the HA-binding site. To understand this in molecular terms, the pH-dependent folding profile and the pK(a) values of charged residues within the Link module were determined using NMR. These data indicated that His(4) makes a salt bridge to one side-chain oxygen atom of a buried aspartate residue (Asp(89)), whereas the other oxygen is simultaneously hydrogen-bonded to a key HA-binding residue (Tyr(12)). This molecular network transmits the change in ionization state of His(4) to the HA-binding site, which explains the loss of affinity at high pH. In contrast, simulations of the pH affinity curves indicate that another histidine residue, His(45), is largely responsible for the gain in affinity for HA between pH 3.5 and 6.0. The pH-dependent interaction of TSG-6 with HA (and other ligands) provides a means of differentially regulating the functional activity of this protein in different tissue microenvironments.     

Catalytic and structural role of a metal-free histidine residue in bovine Cu-Zn superoxide dismutase

Cu-Zn superoxide dismutase (SOD) contains a conserved, metal-free His residue at an opening of the backbone beta-barrel in addition to six Cu- and/or Zn-bound His residues in the active site. We examined the protonation and hydrogen bonding state of the metal-free His residue (His41) in bovine SOD by UV Raman spectroscopy. Analysis of the His Raman intensity at 1406 cm(-1) in a D2O solution has shown that His41 has a pKa of 9.4, consistent with the NMR and X-ray structures at acidic to neutral pH, in which two imidazole nitrogen atoms of cationic His41 are hydrogen bonded to the main chain C=O groups of Thr37 and His118. Upon deprotonation of His41 at pH 9.4, the Thr37-His41-His118 hydrogen bond bridge breaks on the His118 side and SOD loses 70% of its activity. Concomitantly, hydrogen-deuterium exchange is accelerated for amide groups of beta-strands, indicating an increased conformational fluctuation of the beta-barrel. Thr37 and His41 are in direct contact with Leu36, whose hydrophobic side chain closes off the opening of the beta-barrel, while His118 is indirectly connected to Arg141 that assists the docking of superoxide to Cu. These Raman findings strongly suggest that the His41-mediated hydrogen bond bridge plays a crucial role in keeping the protein structure suitable for highly efficient catalytic reactions. The catalytic and structural role of His41 is consistent with the observation that the mutation of His43 in human SOD (equivalent to His41 in bovine SOD) to Arg largely reduces the dismutase activity and the protein structural stability.     

Native-state conformational dynamics of GART: a regulatory pH-dependent coil-helix transition examined by electrostatic calculations

Glycinamide ribonucleotide transformylase (GART) undergoes a pH-dependent coil-helix transition with pK(a) approximately 7. An alpha-helix is formed at high pH spanning 8 residues of a 21-residue-long loop, comprising the segment Thr120-His121-Arg122-Gln123-Ala124-Leu125-Glu126-Asn127. To understand the electrostatic nature of this loop-helix, called the activation loop-helix, which leads to the formation and stability of the alpha-helix, pK(a) values of all ionizable residues of GART have been calculated, using Poisson-Boltzmann electrostatic calculations and crystallographic data. Crystallographic structures of high and low pH E70A GART have been used in our analysis. Low pK(a) values of 5.3, 5.3, 3.9, 1.7, and 4.7 have been calculated for five functionally important histidines, His108, His119, His121, His132, and His137, respectively, using the high pH E70A GART structure. Ten theoretical single and double mutants of the high pH E70A structure have been constructed to identify pairwise interactions of ionizable residues, which have aided in elucidating the multiplicity of electrostatic interactions of the activation loop-helix, and the impact of the activation helix on the catalytic site. Based on our pK(a) calculations and structural data, we propose that: (1) His121 forms a molecular switch for the coil-helix transition of the activation helix, depending on its protonation state; (2) a strong electrostatic interaction between His132 and His121 is observed, which can be of stabilizing or destabilizing nature for the activation helix, depending on the relative orientation and protonation states of the rings of His121 and His132; (3) electrostatic interactions involving His119 and Arg122 play a role in the stability of the activation helix; and (4) the activation helix contains the helix-promoting sequence Arg122-Gln123-Ala124-Leu125-Glu126, but its alignment relative to the N and C termini of the helix is not optimal, and is possibly of a destabilizing nature. Finally, we provide electrostatic evidence that the formation and closure of the activation helix create a hydrophobic environment for catalytic-site residue His108, to facilitate catalysis.     

Ionization of His 55 at the dimer interface of dynein light-chain LC8 is coupled to dimer dissociation

LC8 is a highly conserved light-chain subunit of cytoplasmic dynein that interacts with a wide variety of cellular proteins and is presumed to play a fundamental role in dynein assembly and cargo recruitment and in the assembly of protein complexes unrelated to dynein. LC8 is a dimer at physiological pH but dissociates to a folded monomer at pH < 4.8. We have suggested that acid-induced dimer dissociation is due to protonation of His 55, which is stacked against His 55' and completely buried in the dimer interface. In this work, we show that the pH-induced dissociation is reversible and indeed governed by the ionization state of His 55. Mutagenesis of His 55 to Lys results in a monomer in the pH range of 3-8, while the mutation to Ala results in a dimer in the same pH range. Mutations that disrupt intermolecular hydrogen bonds between Tyr 65 and Lys 44' and His 55 and Thr 67' do not change the association state of the dimer. Titration curves for His 55 and the two other histidines, His 72 and 68, were determined by (13)C-(1)H NMR for H55K and for WT-LC8 in the monomeric and dimeric states. The pK(a) values of His 72 and His 68 are 6 in the WT dimer and 6.2-6.5 in monomeric H55K, while the pK(a) of His 55 is about 4.5 in the WT dimer. These results indicate that deprotonation of His 55 is linked to dimer formation and that mutation of His 55 to a small neutral residue or to a positively charged residue uncouples the protonation and dissociation processes.     

Crystal structure of a pH-stabilized mutant of villin headpiece

Villin-type headpiece domains are compact F-actin-binding motifs that have been used extensively as a model system to investigate protein folding by both experimental and computational methods. Villin headpiece (HP67) harbors a highly helical, thermostable, and autonomously folding subdomain in the C terminus (HP35), and because of this feature, HP67 is usually considered to be composed of a N- and C-terminal subdomain. Unlike the C-terminal subdomain, the N-terminal subdomain consists mainly of loops and turns, and the folding is dependent upon the presence of the C-terminal subdomain. The pH sensitivity of this subdomain is thought to arise from, at least partially, protonation of H41 buried in the hydrophobic core. Substitution of this histidine with tyrosine, another permissive residue at this position for naturally occurring sequences, increases not only the pH stability of HP67 but also the thermal stability and the cooperativity of thermal unfolding over a wide pH range (0.9-7.5). The crystal structures of wild-type HP67 and the H41Y mutant, determined under the same conditions, indicate that the H41Y substitution causes only localized rearrangement around the mutated residue. The F-actin-binding motif remains essentially the same after the mutation, accounting for the negligible effect of the mutation on F-actin affinity. The hydrogen bond formed between the imidazole ring of H41 and the backbone carbonyl of E14 of HP67 is eliminated by the H41Y mutation, which renders the extreme N terminus of H41Y more mobile; the hydrogen bond formed between the imidazole ring of H41 and the backbone nitrogen of D34 is replaced with that between the hydroxyl group of Y41 and the backbone nitrogen of D34 after the H41Y substitution. The increased hydrophobicity of tyrosine compensates for the loss of hydrogen bonds in the extreme N terminus and accounts for the increased stability and cooperativity of the H41Y mutant.     

The role of a conserved histidine residue, His324, in Trigonopsis variabilisd-amino acid oxidase

To investigate the functional role of an invariant histidine residue in Trigonopsis variabilis D-amino acid oxidase (DAAO), a set of mutant enzymes with replacement of the histidine residue at position 324 was constructed and their enzymatic properties were examined. Wild-type and mutant enzymes have been purified to homogeneity using the His-bound column and the molecular masses were determined to be 39.2 kDa. Western blot analysis revealed that the in vivo synthesized mutant enzymes are immuno-identical with that of the wild-type DAAO. The His324Asn and His324Gln mutants displayed comparable enzymatic activity to that of the wild-type enzyme, while the other mutant DAAOs showed markedly decreased or no detectable activity. The mutants, His324/Asn/Gln/Ala/Tyr/Glu, exhibited 38-181% increase in Km and a 2-10-fold reduction in kcat/Km. Based on the crystal structure of a homologous protein, pig kidney DAAO, it is suggested that His324 might play a structural role for proper catalytic function of T. variabilis DAAO.