Combined participation of hydroxylase active site residues and effector protein binding in a para to ortho modulation of toluene 4-monooxygenase regiospecificity

Toluene 4-monooxygenase (T4MO) is a diiron hydroxylase that exhibits high regiospecificity for para hydroxylation. This fidelity provides the basis for an assessment of the interplay between active site residues and protein complex formation in producing an essential biological outcome. The function of the T4MO catalytic complex (hydroxylase, T4moH, and effector protein T4moD) is evaluated with respect to effector protein concentration, the presence of T4MO electron-transfer components (Rieske ferredoxin, T4moC, and NADH oxidoreductase), and use of mutated T4moH isoforms with different hydroxylation regiospecificities. Steady-state kinetic analyses indicate that T4moC and T4moD form complexes of similar affinity with T4moH. At low T4moD concentrations, the steady-state hydroxylation rate is linearly dependent on T4moD-T4moH complex formation, whereas regiospecificity and the coupling efficiency between NADH consumption and hydroxylation are associated with intrinsic properties of the T4moD-T4moH complex. The optimized complex gives both efficient coupling and high regiospecificity with p-cresol representing >96% of total products from toluene. Similar coupling and regiospecificity for para hydroxylation are obtained with T3buV (an effector protein from a toluene 3-monooxygenase), demonstrating that effector protein binding does not uniquely determine or alter the regiospecificity of toluene hydroxylation. The omission of T4moD causes an approximately 20-fold decrease in hydroxylation rate, nearly complete uncoupling, and a decrease in regiospecificity so that p-cresol represents approximately 60% of total products. Similar shifts in regiospecificity are observed in oxidations of alternative substrates in the absence or upon the partial removal of either T4moD or T3buV from toluene oxidations. The mutated T4moH isoforms studied have apparent V(max)/K(M) specificities differing by approximately 2-4-fold and coupling efficiencies ranging from 88% to 95%, indicating comparable catalytic function, but also exhibit unique regiospecificity patterns for all substrates tested, suggesting unique substrate binding preferences within the active site. The G103L isoform has enhanced selectivity for ortho hydroxylation with all substrates tested except nitrobenzene, which gives only m-nitrophenol. The regiospecificity of the G103L isoform is comparable to that observed from naturally occurring variants of the toluene/benzene/o-xylene monooxygenase subfamily. Evolutionary and mechanistic implications of these findings are considered.     

Threonine 201 in the diiron enzyme toluene 4-monooxygenase is not required for catalysis

The diiron enzyme toluene 4-monooxygenase from Pseudomonas mendocina KR1 catalyzes the NADH- and O(2)-dependent hydroxylation of toluene. A combination of sequence alignments and spectroscopic studies indicate that T4MO has an active site structure closely related to the crystallographically characterized methane monooxygenase hydroxylase. In the methane monooxygenase hydroxylase, active site residue T213 has been proposed to participate in O(2) activation by analogy to certain proposals made for cytochrome P450. In this work, mutagenesis of the comparable residue in the toluene 4-monooxygenase hydroxylase, T201, has been used to investigate the role of an active site hydroxyl group in catalysis. Five isoforms (T201S, T201A, T201G, T201F, and T201K) that retain catalytic activity based on an in vivo indigo formation assay were identified, and detailed characterizations of the purified T201S, T201A, and T201G variants are reported. These isoforms have k(cat) values of 1.2, 1.0, and 0.6 s(-)(1), respectively, and k(cat)/K(M) values that vary by only approximately 4-fold relative to that of the native isoform. Moreover, these isoforms exhibit 80-90% coupling efficiency, which also compares favorably to the >94% coupling efficiency determined for the native isoform. For the T201S, T201A, and T201G isoforms, the regiospecificity of toluene hydroxylation was nearly identical to that of the natural isoform, with p-cresol representing 90-95% of the total product distribution. In contrast, the T201F isoform caused a substantial shift in the product distribution, and gave o- and p-cresol in a 1:1 ratio. In addition, the amount of benzyl alcohol was increased approximately 10-fold with the T201F isoform. For reaction with p-xylene, previous studies have shown that the native isoform reacted to give 4-methybenzyl alcohol and 2, 5-dimethylphenol in a 4:1 ratio [Pikus, J. D., Studts, J. M., McClay, K., Steffan, R. J., and Fox, B. G. (1997) Biochemistry 36, 9283-9289]. For comparison, the T201S, T201A, and T201F isoforms gave a slightly relaxed 3:1 ratio of these products, while the T201G isoform gave a dramatically relaxed 1:1 ratio. On the basis of these studies, we conclude that the hydroxyl group of T201 is not essential to maintaining the turnover rate or the coupling of the toluene 4-monooxygenase complex. However, changing the volume occupied by the side chain at the position of T201 can lead to alterations in the regiospecificity of the hydroxylation, presumably by producing different orientations for substrate binding during catalysis.     

Tuning the specificity of the recombinant multicomponent toluene o-xylene monooxygenase from Pseudomonas sp. strain OX1 for the biosynthesis of tyrosol from 2-phenylethanol

Biocatalysis is today a standard technology for the industrial production of several chemicals, and the number of biotransformation processes running on a commercial scale is constantly increasing. Among biocatalysts, bacterial multicomponent monooxygenases (BMMs), a diverse group of nonheme diiron enzymes that activate dioxygen, are of primary interest due to their ability to catalyze a variety of complex oxidations, including reactions of mono- and dihydroxylation of phenolic compounds. In recent years, both directed evolution and rational design have been successfully used to identify the molecular determinants responsible for BMM regioselectivity and to improve their activity toward natural and nonnatural substrates. Toluene o-xylene monooxygenase (ToMO) is a BMM isolated from Pseudomonas sp. strain OX1 which hydroxylates a wide spectrum of aromatic compounds. In this work we investigate the use of recombinant ToMO for the biosynthesis in recombinant cells of Escherichia coli strain JM109 of 4-hydroxyphenylethanol (tyrosol), an antioxidant present in olive oil, from 2-phenylethanol, a cheap and commercially available substrate. We initially found that wild-type ToMO is unable to convert 2-phenylethanol to tyrosol. This was explained by using a computational model which analyzed the interactions between ToMO active-site residues and the substrate. We found that residue F176 is the major steric hindrance for the correct positioning of the reaction intermediate leading to tyrosol production into the active site of the enzyme. Several mutants were designed and prepared, and we found that the combination of different mutations at position F176 with mutation E103G allows ToMO to convert up to 50% of 2-phenylethanol into tyrosol in 2 h.     

Control of substrate specificity by active-site residues in nitrobenzene dioxygenase

Nitrobenzene 1,2-dioxygenase from Comamonas sp. strain JS765 catalyzes the initial reaction in nitrobenzene degradation, forming catechol and nitrite. The enzyme also oxidizes the aromatic rings of mono- and dinitrotoluenes at the nitro-substituted carbon, but the basis for this specificity is not understood. In this study, site-directed mutagenesis was used to modify the active site of nitrobenzene dioxygenase, and the contribution of specific residues in controlling substrate specificity and enzyme performance was evaluated. The activities of six mutant enzymes indicated that the residues at positions 258, 293, and 350 in the alpha subunit are important for determining regiospecificity with nitroarene substrates and enantiospecificity with naphthalene. The results provide an explanation for the characteristic specificity with nitroarene substrates. Based on the structure of nitrobenzene dioxygenase, substitution of valine for the asparagine at position 258 should eliminate a hydrogen bond between the substrate nitro group and the amino group of asparagine. Up to 99% of the mononitrotoluene oxidation products formed by the N258V mutant were nitrobenzyl alcohols rather than catechols, supporting the importance of this hydrogen bond in positioning substrates in the active site for ring oxidation. Similar results were obtained with an I350F mutant, where the formation of the hydrogen bond appeared to be prevented by steric interference. The specificity of enzymes with substitutions at position 293 varied depending on the residue present. Compared to the wild type, the F293Q mutant was 2.5 times faster at oxidizing 2,6-dinitrotoluene while retaining a similar Km for the substrate based on product formation rates and whole-cell kinetics.     

Role of aromatic stacking interactions in the modulation of the two-electron reduction potentials of flavin and substrate/product in Megasphaera elsdenii short-chain acyl-coenzyme A dehydrogenase.

The effects of aromatic stacking interactions on the stabilization of reduced flavin adenine dinucleotide (FAD) and substrate/product have been investigated in short-chain acyl-coenzyme A dehydrogenase (SCAD) from Megasphaera elsdenii. Mutations were made at the aromatic residues Phe160 and Tyr366, which flank either face of the noncovalently bound flavin cofactor. The electrochemical properties of the mutants were then measured in the presence and absence of a butyryl-CoA/crotonyl-CoA mixture. Results from these redox studies suggest that the phenylalanine and tyrosine both engage in favorable pi-sigma interactions with the isoalloxazine ring of the flavin to help stabilize formation of the anionic flavin hydroquinone. Disruption of these interactions by replacing either residue with a leucine (F160L and Y366L) causes the midpoint potential for the oxidized/hydroquinone couple (E(ox/hq)) to shift negative by 44-54 mV. The E(ox/hq) value was also found to decrease when aromatic residues containing electron-donating heteroatoms were introduced at the 160 position. Potential shifts of -32 and -43 mV for the F160Y and F160W mutants, respectively, are attributed to increased pi-pi repulsive interactions between the ring systems. This study also provides evidence for thermodynamic regulation of the substrate/product couple in the active site of SCAD. Binding to the wild-type enzyme caused the midpoint potential for the butyryl-CoA/crotonyl-CoA couple (E(BCoA/CCoA)) to shift 14 mV negative, stabilizing the oxidized product. Formation of product was found to be even more favorable in complexes with the F160Y and F160W mutants, suggesting that the electrostatic environment around the flavin plays a role in substrate/product activation.     

X-ray structure of a hydroxylase-regulatory protein complex from a hydrocarbon-oxidizing multicomponent monooxygenase, Pseudomonas sp. OX1 phenol hydroxylase

Phenol hydroxylase (PH) belongs to a family of bacterial multicomponent monooxygenases (BMMs) with carboxylate-bridged diiron active sites. Included are toluene/o-xylene (ToMO) and soluble methane (sMMO) monooxygenase. PH hydroxylates aromatic compounds, but unlike sMMO, it cannot oxidize alkanes despite having a similar dinuclear iron active site. Important for activity is formation of a complex between the hydroxylase and a regulatory protein component. To address how structural features of BMM hydroxylases and their component complexes may facilitate the catalytic mechanism and choice of substrate, we determined X-ray structures of native and SeMet forms of the PH hydroxylase (PHH) in complex with its regulatory protein (PHM) to 2.3 A resolution. PHM binds in a canyon on one side of the (alphabetagamma)2 PHH dimer, contacting alpha-subunit helices A, E, and F approximately 12 A above the diiron core. The structure of the dinuclear iron center in PHH resembles that of mixed-valent MMOH, suggesting an Fe(II)Fe(III) oxidation state. Helix E, which comprises part of the iron-coordinating four-helix bundle, has more pi-helical character than analogous E helices in MMOH and ToMOH lacking a bound regulatory protein. Consequently, conserved active site Thr and Asn residues translocate to the protein surface, and an approximately 6 A pore opens through the four-helix bundle. Of likely functional significance is a specific hydrogen bond formed between this Asn residue and a conserved Ser side chain on PHM. The PHM protein covers a putative docking site on PHH for the PH reductase, which transfers electrons to the PHH diiron center prior to O2 activation, suggesting that the regulatory component may function to block undesired reduction of oxygenated intermediates during the catalytic cycle. A series of hydrophobic cavities through the PHH alpha-subunit, analogous to those in MMOH, may facilitate movement of the substrate to and/or product from the active site pocket. Comparisons between the ToMOH and PHH structures provide insights into their substrate regiospecificities.     

Functional analysis of active site residues of Bacillus thuringiensis WB7 chitinase by site-directed mutagenesis

To investigate the roles of the active site residues in the catalysis of Bacillus thuringiensis WB7 chitinase, twelve mutants, F201L, F201Y, G203A, G203D, D205E, D205N, D207E, D207N, W208C, W208R, E209D and E209Q were constructed by site-directed mutagenesis. The results showed that the mutants F201L, G203D, D205N, D207E, D207N, W208C and E209D were devoid of activity, and the loss of the enzymatic activities for F201Y, G203A, D205E, W208R and E209Q were 72, 70, 48, 31 and 29%, respectively. The pH-activity profiles indicated that the optimum pH for the mutants as well as for the wildtype enzyme was 8.0. E209Q exhibited a broader active pH range while D205E, G203A and F201Y resulted in a narrower active pH range. The pH range of activity reduced 1 unit for D205E, and 2 units for G203A and F201Y. The temperature-activity profiles showed that the optimum temperature for other mutants as well as wildtype enzyme was 60°C, but 50°C for G203A, which suggested that G203A resulted in a reduction of thermostability. The study indicated that the six active site residues involving in mutagenesis played an important part in WB7 chitinase. In addition, the catalytic mechanisms of the six active site residues in WB7 chitinase were discussed.     

Control of Substrate Specificity by Active-Site Residues in Nitrobenzene Dioxygenase

Nitrobenzene 1,2-dioxygenase from Comamonas sp. strain JS765 catalyzes the initial reaction in nitrobenzene degradation, forming catechol and nitrite. The enzyme also oxidizes the aromatic rings of mono- and dinitrotoluenes at the nitro-substituted carbon, but the basis for this specificity is not understood. In this study, site-directed mutagenesis was used to modify the active site of nitrobenzene dioxygenase, and the contribution of specific residues in controlling substrate specificity and enzyme performance was evaluated. The activities of six mutant enzymes indicated that the residues at positions 258, 293, and 350 in the α subunit are important for determining regiospecificity with nitroarene substrates and enantiospecificity with naphthalene. The results provide an explanation for the characteristic specificity with nitroarene substrates. Based on the structure of nitrobenzene dioxygenase, substitution of valine for the asparagine at position 258 should eliminate a hydrogen bond between the substrate nitro group and the amino group of asparagine. Up to 99% of the mononitrotoluene oxidation products formed by the N258V mutant were nitrobenzyl alcohols rather than catechols, supporting the importance of this hydrogen bond in positioning substrates in the active site for ring oxidation. Similar results were obtained with an I350F mutant, where the formation of the hydrogen bond appeared to be prevented by steric interference. The specificity of enzymes with substitutions at position 293 varied depending on the residue present. Compared to the wild type, the F293Q mutant was 2.5 times faster at oxidizing 2,6-dinitrotoluene while retaining a similar K_m for the substrate based on product formation rates and whole-cell kinetics.     

Sequencing and analysis of the Mmethylococcus capsulatus (Bath) solublemethane monooxygenase genes.

The soluble methane monooxygenase (sMMO) hydroxylase is a prototypical member of the class of proteins with non-heme carboxylate-bridged diiron sites. The sMMO subclass of enzyme systems has several distinguishing characteristics, including the ability to catalyze hydroxylation or epoxidation chemistry, a multisubunit hydroxylase containing diiron centers in its alpha subunits, and the requirement of a coupling protein for optimal activity. Sequence homology alignment of known members of the sMMO family was performed in an effort to identify protein regions giving rise to these unique features. DNA sequencing of the Methylococcus capsulatus (Bath) sMMO genes confirmed previously identified sequencing errors and corrected two additional errors, each of which was confirmed by at least one independent method. Alignments of homologous proteins from sMMO, phenol hydroxylase, toluene 2-, 3-, and 4-monooxygenases, and alkene monooxygenase systems revealed an interesting set of absolutely conserved amino-acid residues, including previously unidentified residues located outside the diiron active site of the hydroxylase. By mapping these residues on to the M. capsulatus (Bath) sMMO hydroxylase crystal structure, functional and structural roles were proposed for the conserved regions. Analysis of the active site showed a highly conserved hydrogen-bonding network on one side of the diiron cluster but little homology on the opposite side, where substrates are presumed to bind. It is suggested that conserved residues on the hydroxylase surface may be important for protein-protein interactions with the reductase and coupling ancillary proteins and/or serve as part of an electron-transfer pathway. A possible way by which binding of the coupling protein at the surface of the hydroxylase might transfer information to the diiron active site at the interior is proposed.     

Crystal structures of the cellulase Cel48F in complex with inhibitors and substrates give insights into its processive action

Cellulase Cel48F from Clostridium cellulolyticum was described as a processive endo-cellulase. The active site is composed of a 25 A long tunnel which is followed by an open cleft. During the processive action, the cellulose substrate has to slide through the tunnel to continuously supply the leaving group site with sugar residues after the catalytic cleavage. To study this processive action in the tunnel, the native catalytic module of Cel48F and the inactive mutant E55Q, have been cocrystallized with cellobiitol, two thio-oligosaccharide inhibitors (PIPS-IG3 and IG4) and the cello-oligosaccharides cellobiose, -tetraose and -hexaose. Seven sub-sites in the tunnel section of the active center could be identified and three of the four previously reported sub-sites in the open cleft section were reconfirmed. The sub-sites observed for the thio-oligosaccharide inhibitors and oligosaccharides, respectively, were located at two different positions in the tunnel corresponding to a shift in the chain direction of about a half sugar subunit. These two positions have different patterns of stacking interactions with aromatic residues present in the tunnel. Multiple patterns are not observed in nonprocessive endo-cellulases, where only one sugar position is favored by aromatic stacking. It is therefore proposed that the aromatic residues serve as lubricating agents to reduce the sliding barrier in the processive action.     

Characterization of active-site aromatic residues in xylanase A from Streptomyces lividans

The role of four aromatic residues (W85, Y172, W266 and W274) in the structure-function relationship in xylanase A from Streptomyces lividans (XlnA) was investigated by site-directed mutagenesis where each residue was subjected to three substitutions (W85A/H/F; W266A/H/F; W274A/H/F and Y172A/F/S). These four amino acids are highly conserved among family 10 xylanases and structural data have implicated them in substrate binding at the active site. Far-UV circular dichroism spectroscopy was used to show that the overall structure of XlnA was not affected by any of these mutations. High-performance liquid chromatographic analysis of the hydrolysis products of birchwood xylan and xylopentaose showed that mutation of these aromatic residues did not alter the enzyme's mode of action. As expected, though, it did reduce the affinity of XlnA for birchwood xylan. A comparison of the kinetic parameters of different mutants at the same position demonstrated the importance of the aromatic nature of W85, Y172 and W274 in substrate binding. Replacement of these residues by a phenylalanine resulted in mutant proteins with a K(M) closer to that of the wild-type protein in comparison with the other mutations analyzed. The kinetic analysis of the mutant proteins at position W266 indicated that this amino acid is important for both substrate binding and efficient catalysis by XlnA. These studies also demonstrated the crucial role of these active site aromatic residues for the thermal stability of XlnA.     

Homology modelling and site-directed mutagenesis studies of the epoxide hydrolase from Phanerochaete chrysosporium

Three-dimensional structural model of epoxide hydrolase (PchEHA) from Phanerochaete chrysosporium was constructed based on X-ray structure of Agrobacterium radiobacter AD1 sEH using SWISS-MODEL server. Conserved residues constituting the active site cavity were identified, of which the functional roles of 14 residues were determined by site-directed mutagenesis. In catalytic triad, Asp105 and His308 play a leading role in alkylation and hydrolysis steps, respectively. Distance between Asp105 and epoxide ring of substrate may determine the regiospecificity in the substrate docking model. Asp277 located at the entrance of substrate tunnel is concerned with catalysis but not essential. D307E had the highest activity and lower enantioselectivity among 14 mutants, suggesting Asp307 may be involved in choice of substrate configuration. Y159F and Y241F almost exhibited no activity, indicating that they are essential to bind substrate and facilitate opening of epoxide ring. Besides, His35-Gly36-Asn37-Pro38, Trp106 and Trp309 surrounding Asp105, may coordinate the integration of active site cavity and influence substrate binding. Especially, W106I reversed the enantioselectivity, perhaps due to more deteriorative impact on the preferred (R)-styrene oxide. Gly65 and Gly67 occurring at β-turns and Gly36 are vital in holding protein conformation. Conclusively, single conserved residue around the active sites has an important impact on catalytic properties.     

The study of the bacteriophage T5 deoxynucleoside monophosphate kinase active site by site-directed mutagenesis

The amino acid residues essential for the enzymatic activity of bacteriophage T5 deoxyribonucleoside monophosphate kinase were determined using a computer model of the enzyme active site. By site-directed mutagenesis, cloning, and gene expression in E. coli, a series of proteins were obtained with single substitutions of the conserved active site amino acid residues—S13A, D16N, T17N, T17S, R130K, K131E, Q134A, G137A, T138A, W150F, W150A, D170N, R172I, and E176Q. After purification by ion exchange and affine chromatography electrophoretically homogeneous preparations were obtained. The study of the enzymatic activity with natural acceptors of the phosphoryl group (dAMP, dCMP, dGMP, and dTMP) demonstrated that the substitutions of charged amino acid residues of the NMP binding domain (R130, R172, D170, and E176) caused nearly complete loss of enzymatic properties. It was found that the presence of the OH-group at position 17 was also important for the catalytic activity. On the basis of the analysis of specific activity variations we assumed that arginine residues at positions 130 and 172 were involved in the binding to the donor γ-phosphoryl and acceptor α-phosphoryl groups, as well as the aspartic acid residue at position 16 of the ATP-binding site (P-loop), in the binding to some acceptors, first of all dTMP. Disproportional changes in enzymatic activities of partially active mutants, G137A, T138A, T17N, Q134A, S13A, and D16N, toward different substrates may indicate that different amino acid residues participate in the binding to various substrates.     

Application of peptide-mediated ring current shifts to the study of neurophysin-peptide interactions: a partial model of the neurophysin-peptide complex

Perdeuteriated peptides were synthesized that are capable of binding to the hormone binding site of neurophysin but that differ in the position of aromatic residues. The binding of these peptides to bovine neurophysin I and its des-1-8 derivative was studied by proton nuclear magnetic resonance spectroscopy in order to identify protein residues near the binding site through the observation of differential ring current effects on assignable protein resonances. Phenylalanine in position 3 of bound peptides was shown to induce significant ring current shifts in several resonances assignable to the 1-8 sequence, including those of Leu-3 and/or Leu-5, but was without effect on Tyr-49 ring protons. The magnitude of these shifts was dependent on the identity of peptide residue 1. By contrast, the sole demonstrable direct effect of an aromatic residue in position 1 was a downfield shift in Tyr-49 ring protons. Study of peptide binding to des-1-8-neurophysin demonstrated similar conformations of native and des-1-8 complexes except for the environment of Tyr-49, confirmed the peptide-induced ring current shift assignments in native neurophysin, and indicated an effect of binding on Thr-9. These observations are integrated with other results to provide a partial model of neurophysin-peptide complexes that places the ring of Tyr-49 at a distance 5-10 A from residue 1 of bound peptide and that places both the 1-8 sequence and the protein backbone region containing Tyr-49 proximal to each other and to peptide residue 3.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alteration of the regiospecificity of human heme oxygenase-1 by unseating of the heme but not disruption of the distal hydrogen bonding network

Heme oxygenase regiospecifically oxidizes heme at the alpha-meso position to give biliverdin IXalpha, CO, and iron. The heme orientation within the active site, which is thought to determine the oxidation regiospecificity, is shown here for the human enzyme (hHO1) to be largely determined by interactions between the heme carboxylic acid groups and residues Arg183 and Lys18 but not Tyr134. Mutation of either Arg183 or Lys18 individually does not significantly alter the NADPH-cytochrome P450 reductase-dependent reaction regiochemistry but partially shifts the oxidation to the beta/delta-meso positions in the reaction supported by ascorbic acid. Mutation of Glu29 to a lysine, which places a positive charge where it can interact with a heme carboxyl if the heme rotates by approximately 90 degrees, causes a slight loss of regiospecificity but combined with the R183E and K18E mutations results primarily in beta/delta-meso oxidation of the heme under all conditions. NMR analysis of heme binding to the triple K18E/E29K/R183E mutant confirms rotation of the heme in the active site. Kinetic studies demonstrate that mutations of Arg183 greatly impair the rate of the P450 reductase-dependent reaction, in accord with the earlier finding that Arg183 is involved in binding of the reductase to hHO1, but have little effect on the ascorbate reaction. Mutations of Asp140 and Tyr58 that disrupt the active site hydrogen bonding network impair catalytic rates but do not influence the oxidation regiochemistry. The results indicate both that the oxidation regiochemistry is largely controlled by ionic interactions of the heme propionic acid groups with the protein and that shifts in regiospecificity involve rotation of the heme about an axis perpendicular to the heme plane.     

Crystal structure of rabbit phosphoglucose isomerase complexed with its substrate D-fructose 6-phosphate.

Phosphoglucose isomerase (PGI, EC 5.3.1.9) catalyzes the interconversion of D-glucose 6-phosphate (G6P) and D-fructose 6-phosphate (F6P) and plays important roles in glycolysis and gluconeogenesis. Biochemical characterization of the enzyme has led to a proposed multistep catalytic mechanism. First, the enzyme catalyzes ring opening to yield the open chain form of the substrate. Then isomerization proceeds via proton transfer between C2 and C1 of a cis-enediol(ate) intermediate to yield the open chain form of the product. Catalysis proceeds in both the G6P to F6P and F6P to G6P directions, so both G6P and F6P are substrates. X-ray crystal structure analysis of rabbit and bacterial PGI has previously identified the location of the enzyme active site, and a recent crystal structure of rabbit PGI identified Glu357 as a candidate functional group for transferring the proton. However, it was not clear which active site amino acid residues catalyze the ring opening step. In this paper, we report the X-ray crystal structure of rabbit PGI complexed with the cyclic form of its substrate, D-fructose 6-phosphate, at 2.1 A resolution. The location of the substrate relative to the side chains of His388 suggest that His388 promotes ring opening by protonating the ring oxygen. Glu216 helps to position His388, and a water molecule that is held in position by Lys518 and Thr214 accepts a proton from the hydroxyl group at C2. Comparison to a structure of rabbit PGI with 5PAA bound indicates that ring opening is followed by loss of the protonated water molecule and conformational changes in the substrate and the protein so that a helix containing amino acids 513-520 moves in toward the substrate to form additional hydrogen bonds with the substrate.     

Biochemical analysis and structure determination of Paucimonas lemoignei poly(3‐hydroxybutyrate) (PHB) depolymerase PhaZ7 muteins reveal the PHB binding site and details of substrate–enzyme interactions

Five amino acids (Y105, Y176, Y189, Y189, W207) that constitute the substrate binding site of PHB depolymerase PhaZ7 were identified. All residues are located at a single surface‐exposed location of PhaZ7. Exchange of these amino acids by less hydrophobic, hydrophilic or negatively charged residues reduced binding of PhaZ7 to PHB. Modifications of other residues at the PhaZ7 surface (F9, Y66, Y103, Y124, Y169, Y172, Y173, F198, Y203, Y204, F251, W252) had no effect on substrate binding. The PhaZ7 wild‐type protein, three muteins with single amino acid exchanges (Y105A, Y105E, Y190E), a PhaZ7 variant with deletion of residues 202–208, and PhaZ7 in which the active‐site serine had been replaced by alanine (S136A) were crystallized and their structures were determined at 1.6–2.0 Å resolution. The structures were almost identical but revealed flexibility of some regions. Structural analysis of PhaZ7 (S136A) with bound 3‐hydroxybutyrate tetramer showed that the substrate binds in a cleft that is composed of Y105, Y176, Y189 and Y190 and thus confirmed the data obtained by site‐directed mutagenesis. To the best of our knowledge this is the first example in which the substrate binding site of a PHB depolymerase is documented at a molecular and structural level.     

Human ferrochelatase: characterization of substrate-iron binding and proton-abstracting residues

The terminal step in heme biosynthesis, the insertion of ferrous iron into protoporphyrin IX to form protoheme, is catalyzed by the enzyme ferrochelatase (EC 4.99.1.1). A number of highly conserved residues identified from the crystal structure of human ferrochelatase as being in the active site were examined by site-directed mutagenesis. The mutants Y123F, Y165F, Y191H, and R164L each had an increased K(m) for iron without an altered K(m) for porphyrin. The double mutant R164L/Y165F had a 6-fold increased K(m) for iron and a 10-fold decreased V(max). The double mutant Y123F/Y191F had low activity with an elevated K(m) for iron, and Y123F/Y165F had no measurable activity. The mutants H263A/C/N, D340N, E343Q, E343H, and E343K had no measurable enzyme activity, while E343D, E347Q, and H341C had decreased V(max)s without significant alteration of the K(m)s for either substrate. D340E had near-normal kinetic parameters, while D383A and H231A had increased K(m)s for iron. On the basis of these data and the crystal structure of human ferrochelatase, it is proposed that residues E343, H341, and D340 form a conduit from H263 in the active site to the protein exterior and function in proton extraction from the porphyrin macrocycle. The role of H263 as the porphyrin proton-accepting residue is central to catalysis since metalation only occurs in conjunction with proton abstraction. It is suggested that iron is transported from the exterior of the enzyme at D383/H231 via residues W227 and Y191 to the site of metalation at residues R164 and Y165 which are on the opposite side of the active site pocket from H263. This model should be general for mitochondrial membrane-associated eucaryotic ferrochelatases but may differ for bacterial ferrochelatases since the spatial orientation of the enzyme within prokaryotic cells may differ.     

The region from phenylalanine-17 to phenylalanine-28 of a yeast mitochondrial ATPase inhibitor is essential for its ATPase inhibitory activity.

Mitochondrial ATP synthase (F(1)F(o)-ATPase) is regulated by an intrinsic ATPase inhibitor protein. In the present study, we investigated the structure-function relationship of the yeast ATPase inhibitor by amino acid replacement. A total of 22 mutants were isolated and characterized. Five mutants (F17S, R20G, R22G, E25A, and F28S) were entirely inactive, indicating that the residues, Phe17, Arg20, Arg22, Glu25, and Phe28, are essential for the ATPase inhibitory activity of the protein. The activity of 7 mutants (A23G, R30G, R32G, Q36G, L37G, L40S, and L44G) decreased, indicating that the residues, Ala23, Arg30, Arg32, Gln36, Leu37, Leu40, and Leu44, are also involved in the activity. Three mutants, V29G, K34Q, and K41Q, retained normal activity at pH 6.5, but were less active at pH 7.2, indicating that the residues, Val29, Lys34, and Lys41, are required for the protein's action at higher pH. The effects of 6 mutants (D26A, E35V, H39N, H39R, K46Q, and K49Q) were slight or undetectable, and the residues Asp26, Glu35, His39, Lys46, and Lys49 thus appear to be dispensable. The mutant E21A retained normal ATPase inhibitory activity but lacked pH-sensitivity. Competition experiments suggested that the 5 inactivated mutants (F17S, R20G, R22G, E25A, and F28S) could still bind to the inhibitory site on F(1)F(o)-ATPase. These results show that the region from the position 17 to 28 of the yeast inhibitor is the most important for its activity and is required for the inhibition of F(1), rather than binding to the enzyme.     

Crystal structure and site-specific mutagenesis of pterin-bound human phenylalanine hydroxylase

The crystal structure of the dimeric catalytic domain (residues 118-424) of human PheOH (hPheOH), cocrystallized with the oxidized form of the cofactor (7,8-dihydro-L-biopterin, BH(2)), has been determined at 2.0 A resolution. The pterin binds in the second coordination sphere of the catalytic iron (the C4a atom is 6.1 A away), and interacts through several hydrogen bonds to two water molecules coordinated to the iron, as well as to the main chain carbonyl oxygens of Ala322, Gly247, and Leu249 and the main chain amide of Leu249. Some important conformational changes are seen in the active site upon pterin binding. The loop between residues 245 and 250 moves in the direction of the iron, and thus allows for several important hydrogen bonds to the pterin ring to be formed. The pterin cofactor is in an ideal orientation for dioxygen to bind in a bridging position between the iron and the pterin. The pterin ring forms an aromatic pi-stacking interaction with Phe254, and Tyr325 contributes to the positioning of the pterin ring and its dihydroxypropyl side chain by hydrophobic interactions. Of particular interest in the hPheOH x BH(2) binary complex structure is the finding that Glu286 hydrogen bonds to one of the water molecules coordinated to the iron as well as to a water molecule which hydrogen bonds to N3 of the pterin ring. Site-specific mutations of Glu286 (E286A and E286Q), Phe254 (F254A and F254L), and Tyr325 (Y325F) have confirmed the important contribution of Glu286 and Phe254 to the normal positioning of the pterin cofactor and catalytic activity of hPheOH. Tyr325 also contributes to the correct positioning of the pterin, but has no direct function in the catalytic reaction, in agreement with the results obtained with rat TyrOH [Daubner, S. C., and Fitzpatrick, P. F. (1998) Biochemistry 37, 16440-16444]. Superposition of the binary hPheOH.BH(2) complex onto the crystal structure of the ligand-free rat PheOH (which contains the regulatory and catalytic domains) [Kobe, B., Jennings, I. G., House, C. M., Michell, B. J., Goodwill, K. E., Santarsiero, B. D., Stevens, R. C., Cotton, R. G. H., and Kemp, B. E. (1999) Nat. Struct. Biol. 6, 442-448] reveals that the C2'-hydroxyl group of BH(2) is sufficiently close to form hydrogen bonds to Ser23 in the regulatory domain. Similar interactions are seen with the hPheOH.adrenaline complex and Ser23. These interactions suggest a structural explanation for the specific regulatory properties of the dihydroxypropyl side chain of BH(4) (negative effector) in the full-length enzyme in terms of phosphorylation of Ser16 and activation by L-Phe.