The structure of the Met144Leu mutant of copper nitrite reductase from <Emphasis Type="Italic">Alcaligenes xylosoxidans</Emphasis> provides the first glimpse of a protein–protein complex with azurin II

Cu-containing nitrite reductases (NiRs) perform the reduction of nitrite to NO via an ordered mechanism in which the delivery of a proton and an electron to the catalytic type 2 Cu site is highly orchestrated. Electron transfer from a redox partner protein, azurin or pseudoazurin, to the type 1 Cu site is assumed to occur through the formation of a protein-protein complex. We report here a new crystal form in space group P2(1)2(1)2(1) of the Met144Leu mutant of NiR from Alcaligenes xylosoxidans (AxNiR), revealing a head-to-head packing motif involving residues around the hydrophobic patch of domain 1. Superposition of the structure of azurin II with that of domain 1 of one of the Met144Leu molecules provides the first glimpse of an azurin II-NiR protein-protein complex. Mutations of two of the residues of AxNiR, Trp138His (Barrett et al. in Biochemistry 43:16311-16319, 2004) and Met87Leu, highlighted in the AxNiR-azurin complex, results in substantially decreased activity when azurin is used as the electron donor instead of methyl viologen, providing direct evidence for the importance of this region for complex formation.     

Involvement of the hydrophobic patch of azurin in the electron-transfer reactions with cytochrome C551 and nitrite reductase

The electron-transfer reactions of site-specific mutants of the blue copper protein azurin from Pseudomonas aeruginosa with its presumed physiological redox partners cytochrome c551 and nitrite reductase were investigated by temperature-jump and stopped-flow experiments. In the hydrophobic patch of azurin Met44 was replaced by Lys, and in the His35 patch His35 was replaced by Phe, Leu and Gln. Both patches were previously thought to be involved in electron transfer. 1H-NMR spectroscopy revealed only minor changes in the three-dimensional structure of the mutants compared to wild-type azurin. Observed changes in midpoint potentials could be attributed to electrostatic effects. The slow relaxation phase observed in temperature-jump experiments carried out on equilibrium mixtures of wild-type azurin and cytochrome c551 was definitively shown to be due to a conformational relaxation involving His35. Analysis of the kinetic data demonstrated the involvement of the hydrophobic but not the His35 patch of azurin in the electron transfer reactions with both cytochrome c551 and nitrite reductase.     

The structure of the complex between a branched pentasaccharide and Thermobacillus xylanilyticus GH-51 arabinofuranosidase reveals xylan-binding determinants and induced fit

The crystal structure of the family GH-51 alpha- l-arabinofuranosidase from Thermobacillus xylanilyticus has been solved as a seleno-methionyl derivative. In addition, the structure of an inactive mutant Glu176Gln is presented in complex with a branched pentasaccharide, a fragment of its natural substrate xylan. The overall structure shows the two characteristic GH-51 domains: a catalytic domain that is folded into a (beta/alpha) 8-barrel and a C-terminal domain that displays jelly roll architecture. The pentasaccharide is bound in a groove on the surface of the enzyme, with the mono arabinosyl branch entering a tight pocket harboring the catalytic dyad. Detailed analyses of both structures and comparisons with the two previously determined structures from Geobacillus stearothermophilus and Clostridium thermocellum reveal important details unique to the Thermobacillus xylanilyticus enzyme. In the absence of substrate, the enzyme adopts an open conformation. In the substrate-bound form, the long loop connecting beta-strand 2 to alpha-helix 2 closes the active site and interacts with the substrate through residues His98 and Trp99. The results of kinetic and fluorescence titration studies using mutants underline the importance of this loop, and support the notion of an interaction between Trp99 and the bound substrate. We suggest that the changes in loop conformation are an integral part of the T. xylanilyticus alpha- l-arabinofuranosidase reaction mechanism, and ensure efficient binding and release of substrate.     

Ligand replacement study at the His120 site of purple CuA azurin

The CuA center is a dinuclear Cu2S2(Cys) electron transfer center found in cytochrome c oxidase and nitrous oxide reductase. In a previous investigation of the equatorial histidine ligands' effect on the reduction potential, electron transfer and spectroscopic properties of the CuA center, His120 in the engineered CuA azurin was mutated to Asn, Asp, and Ala. The identical absorption and EPR spectra of these mutants indicate that a common ligand is bound to the copper center. To identify this replacement ligand, the His120Gly CuA azurin mutant was constructed and purified. Absorption and X-band EPR spectra show that His120Gly is similar to the other His120X (X = Asn, Asp, Ala) mutant proteins. Titrations with chloride, imidazole, and azide suggest that the replacement ligand is not exchangeable with exogenous ligands. The possibility of an internal amino acid acting as the replacement ligand for His120 in the His120X mutant proteins was investigated by analyzing the CuA azurin crystal structure and then converting the likely internal ligand, Asn 119, to Asp, Ser, or Ala in the His120Gly mutant. The double mutants H120G/Asn 119X (X = Asp, Ser, or Ala) displayed UV-Vis absorption and EPR spectra that are identical to His120Gly and the other His120X mutants, indicating that Asn119 is not the internal ligand replacing His120 in the His120X mutant proteins. These results demonstrate the remarkable stability of the dinuclear His120 mutants of CuA azurin.     

Conversion of the proximal histidine ligand to glutamine restores activity to an inactive mutant of cytochrome c peroxidase.

Using site-directed mutagenesis, a double mutant in yeast cytochrome c peroxidase (CCP) has been constructed where the proximal ligand, His175, has been converted to glutamine and the neighboring Trp191 has been converted to phenylalanine. The refined 2.4-A crystal structure of the double mutant shows that the Gln175 side chain is within coordination distance of the heme iron atom and that Phe191 occupies the same position as Trp191 in the native enzyme with very little rearrangement outside the immediate vicinity of the mutations. Consistent with earlier work, we find that the single mutant, His175-->Gln, is fully active under steady state assay conditions and that as reported earlier (Mauro et al., 1988), the Trp191-->Phe mutant exhibits only < 0.05% activity. However, the double mutant, His175-->Gln/Phe191-->Phe, exhibits 20% wild type activity. Since it is known that the Trp191-->Phe mutant is inactive because it can no longer transfer electrons from ferrocytochrome c, changing the nature of the proximal ligand is able to restore this activity. These results raise interesting questions regarding the mechanism of interprotein electron transfer reactions.     

Domain swing upon His to Ala mutation in nitrite reductase of Pseudomonas aeruginosa

The nitrite reductase (NIR) from Pseudomonas aeruginosa (NIR-Pa) is a soluble enzyme catalysing the reduction of nitrite (NO2(-)) to nitric oxide (NO). The enzyme is a 120 kDa homodimer, in which the monomers carry a c-heme domain and a d(1)-heme domain. The structures of the enzyme in both the oxidised and reduced state were solved previously and indicate His327 and His369 as putative catalytic residues. The kinetic characterisation of site-directed mutants has shown that the substitution of either one of these two His with Ala dramatically reduces the physiologically relevant reactivity towards nitrite, leaving the reactivity towards oxygen unaffected. The three-dimensional structures of P. aeruginosa NIR mutant H327A, and H369A in complex with NO have been solved by multiple wavelength anomalous dispersion (MAD), using the iron anomalous signal, and molecular replacement techniques. In both refined crystal structures the c-heme domain, whilst preserving its classical c-type cytochrome fold, has undergone a 60 degrees rigid-body rotation around an axis parallel with the pseudo 8-fold axis of the beta-propeller, and passing through residue Gln115. Even though the distance between the Fe ions of the c and d(1)-heme remains 21 A, the edge-to-edge distance between the two hemes has increased by 5 A. Furthermore the distal side of the d(1)-heme pocket appears to have undergone structural re-arrangement and Tyr10 has moved out of the active site. In the H369A-NO complex, the position and orientation of NO is significantly different from that of the NO bound to the reduced wild-type structure. Our results provide insight into the flexibility of the enzyme and the distinction between nitrite and oxidase reduction mechanisms. Moreover they demonstrate that the two histidine residues play a crucial role in the physiological activity of nitrite reduction, ligand binding and in the structural organisation of nitrite reductase from P. aeruginosa.     

Probing copper ligands in denatured <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> azurin: unfolding His117Gly and His46Gly mutants

Azurin is a single-domain beta-barrel protein with a redox-active copper cofactor. Upon Pseudomonas aeruginosa azurin unfolding, the cofactor remains bound to the polypeptide, coordinating three ligands: cysteine-112, one histidine imidazole, and a third, unknown ligand. In order to identify which histidine (histidine-117 and histidine-46 both coordinate copper in native azurin) is involved in copper coordination in denatured azurin, two single-site (histidine to glycine) mutants, His117Gly and His46Gly azurin, are investigated here. Equilibrium denaturation experiments of His46Gly azurin loaded with copper demonstrate that copper remains bound to this mutant in high urea concentrations where the protein's secondary structure is lost. In contrast, for copper-loaded His117Gly azurin, copper does not stay coordinated upon polypeptide unfolding. The copper absorption at 370 nm in denatured His46Gly azurin agrees with that for copper in complex with a peptide corresponding to residues 111-123 in azurin, suggesting similar metal coordination. We conclude that histidine-117 (and not histidine-46) is the histidine copper ligand in denatured azurin. This is also in accord with the proximity of histidine-117 to cysteine-112 in the primary sequence.     

Protein engineering of the high-alkaline serine protease PB92 from Bacillus alcalophilus: functional and structural consequences of mutation at the S4 substrate binding pocket.

Serine endoproteases such as trypsins and subtilisins are known to have an extended substrate binding region that interacts with residues P6 to P3' of a substrate. In order to investigate the structural and functional effects of replacing residues at the S4 substrate binding pocket, the serine protease from the alkalophilic Bacillus strain PB92, which shows homology with the subtilisins, was mutated at positions 102 and 126-128. Substitution of Val102 by Trp results in a 12-fold increase in activity towards succinyl-L-Ala-L-Ala-L-Pro-L-Phe-p-nitroanilide (sAAPFpNA). An X-ray structure analysis of the V102W mutant shows that the Trp side chain occupies a hydrophobic pocket at the surface of the molecule leaving a narrow crevice for the P4 residue of a substrate. Better binding of sAAPFpNA by the mutant compared with the wild type protein as indicated by the kinetic data might be due to the hydrophobic interaction of Ala P4 of the substrate with the introduced Trp102 side chain. The observed difference in binding of sAAPFpNA by protease PB92 and thermitase, both of which possess a Trp at position 102, is probably related to the amino acid substitutions at positions 105 and 126 (in the protease PB92 numbering). Kinetic data for the variants obtained by random mutation of residues Ser126, Pro127 and Ser128 reveal that the activity towards sAAPFpNA increases when a hydrophobic residue is introduced at position 126.(ABSTRACT TRUNCATED AT 250 WORDS)     

The structural role of the copper-coordinating and surface-exposed histidine residue in the blue copper protein azurin

Copper K-edge extended X-ray absorption fine structure (EXAFS) spectroscopy and (15)N NMR relaxation studies were performed on samples of a variant azurin in which the surface-exposed histidine ligand of the copper atom (His117) has been replaced by glycine. The experiments were performed to probe the structure of the active site and the protein dynamics. The cavity in the protein structure created by the His-->Gly replacement could be filled by external ligands, which can either restore the spectroscopic properties of the original type-1 copper site or create a new type-2 copper site. The binding of external ligands occurs only when the copper atom is in its oxidised state. In the reduced form, the binding is abolished. From the EXAFS experiments, it is concluded that for the oxidised type-1 copper sites the protein plus external ligand (L) provide an NSS*L donor set deriving from His46, Cys112, Met121 and the external ligand. The type-2 copper site features an S(N/O)(3) donor set in which the S-donor derives from Cys112, one N-donor from His46 and the remaining two N or O donors from one or more external ligands. Upon reduction of the type-1 as well as the type-2 site, the external ligand drops out of the copper site and the coordination reduces to 3-fold with an SS*N donor set deriving from His46, Cys112 and Met121. The Cu-S(delta)(Met) distance is reduced from about 3.2 to 2.3 A. Analysis of the NMR data shows that the hydrophobic patch around His117 has gained fluxionality when compared to wild-type azurin, which may explain why the His117Gly variant is able to accommodate a variety of external ligands of different sizes and with different chelating properties. On the other hand, the structure and dynamics of the beta-sandwich, which comprises the main body of the protein, is only slightly affected by the mutation. The unusually high reduction potential of the His117Gly azurin is discussed in light of the present results.     

A novel heme and peroxide-dependent tryptophan-tyrosine cross-link in a mutant of cytochrome c peroxidase

The crystal structure of a cytochrome c peroxidase mutant where the distal catalytic His52 is converted to Tyr reveals that the tyrosine side-chain forms a covalent bond with the indole ring nitrogen atom of Trp51. We hypothesize that this novel bond results from peroxide activation by the heme iron followed by oxidation of Trp51 and Tyr52. This hypothesis has been tested by incorporation of a redox-inactive Zn-protoporphyrin into the protein, and the resulting crystal structure shows the absence of a Trp51-Tyr52 cross-link. Instead, the Tyr52 side-chain orients away from the heme active-site pocket, which requires a substantial rearrangement of residues 72-80 and 134-144. Additional experiments where heme-containing crystals of the mutant were treated with peroxide support our hypothesis that this novel Trp-Tyr cross-link is a peroxide-dependent process mediated by the heme iron.     

The mechanism of aubstrate eecognition of pyroglutamyl-peptidase I from Bacillus amyloliquefaciens as determined by X-ray crystallography and site-directed mutagenesis

Pyroglutamyl-peptidase is able to specifically remove the amino-terminal pyroglutamyl residue protecting proteins or peptides from aminopeptidases. To clarify the mechanism of substrate recognition for the unique structure of the pyrrolidone ring, x-ray crystallography and site-directed mutagenesis were applied. The crystal structure of pyroglutamyl-peptidase bound to a transition state analog inhibitor (Inh), pyroglutaminal, was determined. Two hydrogen bonds were located between the main chain of the enzyme and the inhibitor (71:O.H-N:Inh and Gln71:N-H.OE:Inh), and the pyrrolidone ring of the inhibitor was inserted into the hydrophobic pocket composed of Phe-10, Phe-13, Thr-45, Ile-92, Phe-142, and Val-143. To study in detail the hydrophobic pocket, Phe-10, Phe-13, and Phe-142 were selected for mutation experiments. The k(cat) value of the F10Y mutant decreased, but the two phenylalanine mutants F13Y and F142Y did not exhibit significant changes in kinetic parameters compared with the wild-type enzyme. The catalytic efficiencies (k(cat)/K(m)) for the F13A and F142A mutants were less than 1000-fold that of the wild-type enzyme. The x-ray crystallographic study of the F142A mutant showed no significant change except for a minor one in the hydrophobic pocket compared with the wild type. These findings indicate that the molecular recognition of pyroglutamic acid is achieved through two hydrogen bonds and an insertion in the hydrophobic pocket. In the pocket, Phe-10 is more important to the hydrophobic interaction than is Phe-142, and furthermore Phe-13 serves as an "induced fit" mechanism.     

Role of two histidines in the (6-4) photolyase reaction

The reaction mechanism of Xenopus (6-4) photolyase was investigated using several mutant enzymes. In the active site, which is homologous between the cis,syn-cyclobutane pyrimidine dimer and (6-4) photolyases, four amino acid residues that are specific to (6-4) photolyase, Gln(288), His(354), Leu(355), and His(358), and two conserved tryptophans, Trp(291) and Trp(398), were substituted with alanine. Only the L355A mutant had a lower affinity for the substrate, which suggested a hydrophobic interaction with the (6-4) photoproduct. Both the H354A and H358A mutations resulted in an almost complete loss of the repair activity, although the Trp(291) and Trp(398) mutants retained some activity. Taking the pH profile of the (6-4) photolyase reaction into consideration with this observation, we propose a mechanism in which these histidines catalyze the formation of the four-membered ring intermediate in the repair process of this enzyme. When deuterium oxide was used as a solvent, the repair activity was decreased. The proton transfer shown by this isotope effect supports the proposed mechanism. The substrate binding and the reaction mechanism are discussed in detail using a molecular model.     

Controlling ligand binding in myoglobin by mutagenesis.

A quadruple mutant of sperm whale myoglobin was constructed to mimic the structure found in Ascaris suum hemoglobin. The replacements include His(E7)-->Gln, Leu(B10)-->Tyr, Thr(E10)--> Arg, and Ile(G8)-->Phe. Single, double, and triple mutants were characterized to dissect out the effects of the individual substitutions. The crystal structures of the deoxy and oxy forms of the quadruple mutant were determined and compared with that of native Ascaris hemoglobin. Tyr(B10) myoglobin displays low O(2) affinity, high dissociation rate constants, and heterogeneous kinetic behavior, suggesting unfavorable steric interactions between the B10 phenol side chain and His(E7). In contrast, all mutants containing the Tyr(B10)/Gln(E7) pair show high O(2) affinity, low dissociation rate constants, and simple, monophasic kinetic behavior. Replacement of Ile(107) with Phe enhances nanosecond geminate recombination singly and in combination with the Tyr(B10)/Gln(E7)/Arg(E10) mutation by limiting access to the Xe4 site. These kinetic results and comparisons with native Ascaris hemoglobin demonstrate the importance of distal pocket cavities in governing the kinetics of ligand binding. The approximately 150-fold higher O(2) affinity of Ascaris hemoglobin compared with that for Tyr(B10)/Gln(E7)-containing myoglobin mutants appears to be the result of favorable proximal effects in the Ascaris protein, due to a staggered orientation of His(F8), the lack of a hydrogen bonding lattice between the F4, F7, and F8 residues, and the presence of a large polar Trp(G5) residue in the interior portion of the proximal heme pocket.     

Identification of His5,Trp7,Tyr8-GnRH (chicken GnRH II) in amphibian brain

GnRH immunoreactive and bioactive peptides in Xenopus laevis brain extract were investigated by high performance liquid chromatography (HPLC), radioimmunoassay with region-specific antisera raised against GnRH (mammalian), His5,Trp7,Tyr8-GnRH (chicken II) and Tyr3,Leu5,Glu6,Trp7,Lys8-GnRH (lamprey), and by assessment of biological activity. Two immunoreactive peptides eluted in the same positions as GnRH and His5,Trp7,Tyr8-GnRH respectively in HPLC systems which were specifically designed to separate four known natural vertebrate GnRHs (mammalian, chicken I and II, salmon). The immunological properties of these two immunoreactive peaks, determined by relative interaction with three region-specific antisera raised against mammalian GnRH and two specific His5,Trp7,Tyr8-GnRH antisera, were identical to those of GnRH and His5,Trp7,Tyr8-GnRH. The immunoreactive peak co-eluting with His5,Trp7,Tyr8-GnRH represented approximately one-third of the total brain GnRH. Both immunoreactive peaks stimulated luteinizing hormone (LH) release in a chicken dispersed pituitary cell bioassay, and the amounts of LH release stimulated by the two peaks were appropriate for these peaks being GnRH and His5,Trp7,Tyr8-GnRH. A small hydrophobic peak with GnRH immunoreactivity eluted in the same position as Trp7,Leu8-GnRH (salmon), while Gln8-GnRH (chicken I) and lamprey GnRH were not detected. Two additional rather hydrophilic peptides cross-reacted with a COOH-terminus-directed antiserum and had LH-releasing activity. LH-releasing activity was also detected in hydrophobic HPLC fractions. In summary, these data provide evidence for the presence of both GnRH and a second peptide with properties identical to His5,Trp7,Tyr8-GnRH in X. laevis brain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structure and mechanism of tripeptidyl activity of prolyl tripeptidyl aminopeptidase from Porphyromonas gingivalis

The crystal structure of prolyl tripeptidyl aminopeptidase from Porphyromonas gingivalis was determined. Prolyl tripeptidyl aminopeptidase consists of beta-propeller and catalytic domains, and a large cavity between the domains; this structure is similar to dipeptidyl aminopeptidase IV. A catalytic triad (Ser603, His710, and Asp678) was located in the catalytic domain; this triad was virtually identical to that of the enzymes belonging to the prolyl oligopeptidase family. The structure of an inactive S603A mutant enzyme complexed with a substrate was also determined. The pyrrolidine ring of the proline residue appeared to fit into a hydrophobic pocket composed of Tyr604, Val629, Trp632, Tyr635, Tyr639, Val680, and Val681. There were characteristic differences in the residues of the beta-propeller domain, and these differences were related to the substrate specificity of tripeptidyl activity. The N-terminal amino group was recognized by salt bridges, with two carboxyl groups of Glu205 and Glu206 from a helix in dipeptidyl aminopeptidase IV. In prolyl tripeptidyl aminopeptidase, however, the Glu205 (located in the loop) and Glu636 were found to carry out this function. The loop structure provides sufficient space to accommodate three N-terminal residues (Xaa-Xaa-Pro) of substrates. This is the first report of the structure and substrate recognition mechanism of tripeptidyl peptidase.     

Filling a hole in cytochrome P450 BM3 improves substrate binding and catalytic efficiency

Cytochrome P450BM3 (CYP102A1) from Bacillus megaterium, a fatty acid hydroxylase, is a member of a very large superfamily of monooxygenase enzymes. The available crystal structures of the enzyme show non-productive binding of substrates with their omega-end distant from the iron in a hydrophobic pocket at one side of the active site. We have constructed and characterised mutants in which this pocket is filled by large hydrophobic side-chains replacing alanine at position 82. The mutants having phenylalanine or tryptophan at this position have very much (approximately 800-fold) greater affinity for substrate, with a greater conversion of the haem iron to the high-spin state, and similarly increased catalytic efficiency. The enzyme as isolated contains bound palmitate, reflecting this much higher affinity. We have determined the crystal structure of the haem domain of the Ala82Phe mutant with bound palmitate; this shows that the substrate is binding differently from the wild-type enzyme but still distant from the haem iron. Detailed analysis of the structure indicates that the tighter binding in the mutant reflects a shift in the conformational equilibrium of the substrate-free enzyme towards the conformation seen in the substrate complex rather than differences in the enzyme-substrate interactions. On this basis, we outline a sequence of events for the initial stages of the catalytic cycle. The Ala82Phe and Ala82Trp mutants are also very much more effective catalysts of indole hydroxylation than the wild-type enzyme, suggesting that they will be valuable starting points for the design of mutants to catalyse synthetically useful hydroxylation reactions.     

Role of the axial ligand in type 1 Cu centers studied by point mutations of met148 in rusticyanin.

Type 1 Cu centers in cupredoxins, nitrite reductases, and multi-copper oxidases utilize the same trigonal core ligation to His-Cys-His, with a weak axial ligand generally provided by a Met sulfur. In azurin, an additional axial ligand, a carbonyl oxygen from a Gly, is present. The importance of these axial ligands and in particular the Met has been debated extensively in terms of their role in fine-tuning the redox potential, spectroscopic properties, and rack-induced or entatic state properties of the copper sites. Extensive site-directed mutagenesis of the Met ligand has been carried out in azurin, but the presence of an additional carbonyl oxygen axial ligand has made it difficult to interpret the effects of these substitutions. Here, the axial methionine ligand (Met148) in rusticyanin is replaced with Leu, Gln, Lys, and Glu to examine the effect on the redox potential, acid stability, and copper site geometry. The midpoint redox potential varies from 363 (Met148Lys) to 798 mV (Met148Leu). The acid stability of the oxidized proteins is reduced except for the Met148Gln mutant. The Gln mutant remains blue at all pH values between 2.8 and 8, and has a redox potential of 563 mV at pH 3.2. The optical and rhombic EPR properties of this mutant closely resemble those of stellacyanin, which has the lowest redox potential among single-type 1 copper proteins (185 mV). The Met148Lys mutant exhibits type 2 Cu EPR and optical spectra in this pH range. The Met148Glu mutant exhibits a type 2 Cu EPR spectrum above pH 3 and a mixture of type 1 and type 2 Cu spectra at lower pH. The Met148Leu mutant exhibits the highest redox potential ( approximately 800 mV at pH 3.2) which is similar to the values in fungal laccase and in the type 1 Cu site of ceruloplasmin where this axial ligand is also a Leu.     

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.     

The homologous tryptophan critical for cytochrome c peroxidase function is not essential for ascorbate peroxidase activity

The crystal structures of ascorbate peroxidase (APX) and cytochrome c peroxidase (CCP) show that the active site structures are nearly identical. Both enzymes contain a His-Asp-Trp catalytic triad in the proximal pocket. The proximal Asp residue hydrogen bonds with both the His proximal heme ligand and the indole ring nitrogen of the proximal Trp. The Trp is stacked parallel to and in contact with the proximal His ligand. This Trp is known to be the site of free radical formation in CCP compound I and also is essential for activity. However, APX forms a porphyrin radical and not a Trp-centered radical, even though the His-Asp-Trp triad structure is the same in both peroxidases. We found that conversion of the proximal Trp to Phe has no effect on APX enzyme activity and that the mutant crystal structure shows that changes in the structure are confined to the site of mutation. This indicates that the paths of electron transfer in CCP and APX are distinctly different. The Trp-to-Phe mutant does alter the stability of the APX compound I porphyrin radical, by a factor of two. Electrostatic calculations and modeling studies show that a potassium cation located about 8?Å from the proximal Trp in APX, but absent in CCP, makes a significant contribution to the stability of a cation Trp radical. This underscores the importance of long-range electrostatic effects in enzyme catalyzed reactions.     

Characterization of the acyl substrate binding pocket of acetyl-CoA synthetase

AMP-forming acetyl-CoA synthetase [ACS; acetate:CoA ligase (AMP-forming), EC 6.2.1.1] catalyzes the activation of acetate to acetyl-CoA in a two-step reaction. This enzyme is a member of the adenylate-forming enzyme superfamily that includes firefly luciferase, nonribosomal peptide synthetases, and acyl- and aryl-CoA synthetases/ligases. Although the structures of several superfamily members demonstrate that these enzymes have a similar fold and domain structure, the low sequence conservation and diversity of the substrates utilized have limited the utility of these structures in understanding substrate binding in more distantly related enzymes in this superfamily. The crystal structures of the Salmonella enterica ACS and Saccharomyces cerevisiae ACS1 have allowed a directed approach to investigating substrate binding and catalysis in ACS. In the S. enterica ACS structure, the propyl group of adenosine 5'-propylphosphate, which mimics the acyl-adenylate intermediate, lies in a hydrophobic pocket. Modeling of the Methanothermobacter thermautotrophicus Z245 ACS (MT-ACS1) on the S. cerevisiae ACS structure showed similar active site architecture, and alignment of the amino acid sequences of proven ACSs indicates that the four residues that compose the putative acetate binding pocket are well conserved. These four residues, Ile312, Thr313, Val388, and Trp416 of MT-ACS1, were targeted for alteration, and our results support that they do indeed form the acetate binding pocket and that alterations at these positions significantly alter the enzyme's affinity for acetate as well as the range of acyl substrates that can be utilized. In particular, Trp416 appears to be the primary determinant for acyl chain length that can be accommodated in the binding site.