Functional Importance of Bacteriophage ?29 DNA Polymerase Residue Tyr148 in Primer-terminus Stabilisation at the 3′-5′ Exonuclease Active Site

Recent crystallographic resolution of ?29 DNA polymerase complexes with ssDNA at its 3′-5′ exonuclease active site has allowed the identification of residues Pro129 and Tyr148 as putative ssDNA ligands, the latter being conserved in the Kx₂h motif of proofreading family B DNA polymerases. Single substitution of ?29 DNA polymerase residue Tyr148 to Ala rendered an enzyme with a reduced capacity to stabilize the binding of the primer terminus at the 3′-5′ exonuclease active site, not having a direct role in the catalysis of the reaction. Analysis of the 3′-5′ exonuclease on primer/template structures showed a critical role for residue Tyr148 in the proofreading of DNA polymerisation errors. In addition, Tyr148 is not involved in coupling polymerisation to strand displacement in contrast to the catalytic residues responsible for the exonuclease reaction, its role being restricted to stabilisation of the frayed 3′ terminus at the exonuclease active site. Altogether, the results lead us to extend the consensus sequence of the above motif of proofreading family B DNA polymerases into Kx₂hxA. The different solutions adopted by proofreading DNA polymerases to stack the 3′ terminus at the exonuclease site are discussed. In addition, the results obtained with mutants at ?29 DNA polymerase residue Pro129 allow us to rule out a functional role as ssDNA ligand for this residue.     

Crystal structures of Streptococcus mutans 2'-deoxycytidylate deaminase and its complex with substrate analog and allosteric regulator dCTP x Mg2+

2′-Deoxycytidylate deaminase [or deoxycytidine-5′-monophosphate (dCMP) deaminase, dCD] catalyzes the deamination of dCMP to deoxyuridine-5′-monophosphate to provide the main nucleotide substrate for thymidylate synthase, which is important in DNA synthesis. The activity of this homohexameric enzyme is allosterically regulated by deoxycytidine-5′-triphosphate (dCTP) as an activator and by deoxythymidine-5′-triphosphate as an inhibitor. In this article, we report the crystal structures of dCMP deaminase from Streptococcus mutans and its complex with dCTP and an intermediate analog at resolutions of 3.0 and 1.66 Å. The protein forms a hexamer composed of subunits adopting a three-layer α/β/α sandwich fold. The positive allosteric regulator dCTP mainly binds at the interface between two monomers in a molar ratio of 1:1 and rearranges the neighboring interaction networks. Structural comparisons and sequence alignments revealed that dCMP deaminase from Streptococcus mutans belongs to the cytidine deaminase superfamily, wherein the proteins exhibit a similar catalytic mechanism. In addition to the two conserved motifs involved in the binding of Zn^2 +, a new conserved motif, (G⁴³YNG⁴⁶), related to the binding of dCTP was also identified. N-terminal Arg4, a key residue located between two monomers, binds strongly to the γ phosphate group of dCTP. The regulation signal was transmitted by Arg4 from the allosteric site to the active site via modifications in the interactions at the interface where the substrate-binding pocket was involved and the relocations of Arg26, His65, Tyr120, and Arg121 to envelope the active site in order to stabilize substrate binding in the complex. Based on the enzyme-regulator complex structure observed in this study, we propose an allosteric mechanism for dCD regulation.     

Structure and mechanism of a cysteine sulfinate desulfinase engineered on the aspartate aminotransferase scaffold

The joint substitution of three active-site residues in Escherichia colil-aspartate aminotransferase increases the ratio of l-cysteine sulfinate desulfinase to transaminase activity 10⁵-fold. This change in reaction specificity results from combining a tyrosine-shift double mutation (Y214Q/R280Y) with a non-conservative substitution of a substrate-binding residue (I33Q). Tyr214 hydrogen bonds with O3 of the cofactor and is close to Arg374 which binds the α-carboxylate group of the substrate; Arg280 interacts with the distal carboxylate group of the substrate; and Ile33 is part of the hydrophobic patch near the entrance to the active site, presumably participating in the domain closure essential for the transamination reaction. In the triple-mutant enzyme, k_cat′ for desulfination of l-cysteine sulfinate increased to 0.5 s^− 1 (from 0.05 s^− 1 in wild-type enzyme), whereas k_cat′ for transamination of the same substrate was reduced from 510 s^− 1 to 0.05 s^− 1. Similarly, k_cat′ for β-decarboxylation of l-aspartate increased from < 0.0001 s^− 1 to 0.07 s^− 1, whereas k_cat′ for transamination was reduced from 530 s^− 1 to 0.13 s^− 1. l-Aspartate aminotransferase had thus been converted into an l-cysteine sulfinate desulfinase that catalyzes transamination and l-aspartate β-decarboxylation as side reactions. The X-ray structures of the engineered l-cysteine sulfinate desulfinase in its pyridoxal-5′-phosphate and pyridoxamine-5′-phosphate form or liganded with a covalent coenzyme-substrate adduct identified the subtle structural changes that suffice for generating desulfinase activity and concomitantly abolishing transaminase activity toward dicarboxylic amino acids. Apparently, the triple mutation impairs the domain closure thus favoring reprotonation of alternative acceptor sites in coenzyme-substrate intermediates by bulk water.     

The structures of L-rhamnose isomerase from Pseudomonas stutzeri in complexes with L-rhamnose and D-allose provide insights into broad substrate specificity

Pseudomonas stutzeril-rhamnose isomerase (P. stutzeri L-RhI) can efficiently catalyze the isomerization between various aldoses and ketoses, showing a broad substrate specificity compared to L-RhI from Escherichia coli (E. coli L-RhI). To understand the relationship between structure and substrate specificity, the crystal structures of P. stutzeri L-RhI alone and in complexes with l-rhamnose and d-allose which has different configurations of C4 and C5 from l-rhamnose, were determined at a resolution of 2.0 Å, 1.97 Å, and 1.97 Å, respectively. P. stutzeri L-RhI has a large domain with a (β/α)₈ barrel fold and an additional small domain composed of seven α-helices, forming a homo tetramer, as found in E. coli L-RhI and d-xylose isomerases (D-XIs) from various microorganisms. The β1-α1 loop (Gly60-Arg76) of P. stutzeri L-RhI is involved in the substrate binding of a neighbouring molecule, as found in D-XIs, while in E. coli L-RhI, the corresponding β1-α1 loop is extended (Asp52-Arg78) and covers the substrate-binding site of the same molecule. The complex structures of P. stutzeri L-RhI with l-rhamnose and d-allose show that both substrates are nicely fitted to the substrate -binding site. The part of the substrate-binding site interacting with the substrate at the 1, 2, and 3 positions is equivalent to E. coli L-RhI, and the other part interacting with the 4, 5, and 6 positions is similar to D-XI. In E. coli L-RhI, the β1-α1 loop creates an unique hydrophobic pocket at the the 4, 5, and 6 positions, leading to the strictly recognition of l-rhamnose as the most suitable substrate, while in P. stutzeri L-RhI, there is no corresponding hydrophobic pocket where Phe66 from a neighbouring molecule merely forms hydrophobic interactions with the substrate, leading to the loose substrate recognition at the 4, 5, and 6 positions.     

Structure and Activity of Human Mitochondrial Peptide Deformylase, a Novel Cancer Target

Peptide deformylase proteins (PDFs) participate in the N-terminal methionine excision pathway of newly synthesized peptides. We show that the human PDF (HsPDF) can deformylate its putative substrates derived from mitochondrial DNA-encoded proteins. The first structural model of a mammalian PDF (1.7 Å), HsPDF, shows a dimer with conserved topology of the catalytic residues and fold as non-mammalian PDFs. The HsPDF C-terminus topology and the presence of a helical loop (H2 and H3), however, shape a characteristic active site entrance. The structure of HsPDF bound to the peptidomimetic inhibitor actinonin (1.7 Å) identified the substrate-binding site. A defined S1′ pocket, but no S2′ or S3′ substrate-binding pockets, exists. A conservation of PDF-actinonin interaction across PDFs was observed. Despite the lack of true S2′ and S3′ binding pockets, confirmed through peptide binding modeling, enzyme kinetics suggest a combined contribution from P2′and P3′ positions of a formylated peptide substrate to turnover.     

Crystal structure of CYP199A2, a para-substituted benzoic acid oxidizing cytochrome P450 from Rhodopseudomonas palustris

CYP199A2, a cytochrome P450 enzyme from Rhodopseudomonas palustris, oxidatively demethylates 4-methoxybenzoic acid to 4-hydroxybenzoic acid. 4-Ethylbenzoic acid is converted to a mixture of predominantly 4-(1-hydroxyethyl)-benzoic acid and 4-vinylbenzoic acid, the latter being a rare example of CC bond dehydrogenation of an unbranched alkyl group. The crystal structure of CYP199A2 has been determined at 2.0-Å resolution. The enzyme has the common P450 fold, but the B′ helix is missing and the G helix is broken into two (G and G′) by a kink at Pro204. Helices G and G′ are bent back from the extended BC loop and the I helix to open up a clearly defined substrate access channel. Channel openings in this region of the P450 fold are rare in bacterial P450 enzymes but more common in eukaryotic P450 enzymes. The channel is hydrophobic except for the basic residue Arg246 at the entrance, which probably plays a role in the specificity of this enzyme for charged benzoates over neutral phenols and benzenes. The substrate binding pocket is hydrophobic, with Ser97 and Ser247 being the only polar residues. Computer docking of 4-ethylbenzoic acid into the active site suggests that the substrate carboxylate oxygens interact with Ser97 and Ser247, and the β-methyl group is located over the heme iron by Phe185, the side chain of which is only 6.35 Å above the iron in the native structure. This binding orientation is consistent with the observed product profile of exclusive attack at the para substituent. Putidaredoxin of the CYP101A1 system from Pseudomonas putida supports substrate oxidation by CYP199A2 at ∼6% of the activity of the physiological ferredoxin. Comparison of the heme proximal faces of CYP199A2 and CYP101A1 suggests that charge reversal surrounding the surface residue Leu369 in CYP199A2 may be a significant factor in this low cross-activity.     

Molecular determinants of substrate specificity in plant 5'-methylthioadenosine nucleosidases

5′-Methylthioadenosine (MTA)/S-adenosylhomocysteine (SAH) nucleosidase (MTAN) is essential for cellular metabolism and development in many bacterial species. While the enzyme is found in plants, plant MTANs appear to select for MTA preferentially, with little or no affinity for SAH. To understand what determines substrate specificity in this enzyme, MTAN homologues from Arabidopsis thaliana (AtMTAN1 and AtMTAN2, which are referred to as AtMTN1 and AtMTN2 in the plant literature) have been characterized kinetically. While both homologues hydrolyze MTA with comparable kinetic parameters, only AtMTAN2 shows activity towards SAH. AtMTAN2 also has higher catalytic activity towards other substrate analogues with longer 5′-substituents. The structures of apo AtMTAN1 and its complexes with the substrate- and transition-state-analogues, 5′-methylthiotubercidin and formycin A, respectively, have been determined at 2.0-1.8 Å resolution. A homology model of AtMTAN2 was generated using the AtMTAN1 structures. Comparison of the AtMTAN1 and AtMTAN2 structures reveals that only three residues in the active site differ between the two enzymes. Our analysis suggests that two of these residues, Leu181/Met168 and Phe148/Leu135 in AtMTAN1/AtMTAN2, likely account for the divergence in specificity of the enzymes. Comparison of the AtMTAN1 and available Escherichia coli MTAN (EcMTAN) structures suggests that a combination of differences in the 5′-alkylthio binding region and reduced conformational flexibility in the AtMTAN1 active site likely contribute to its reduced efficiency in binding substrate analogues with longer 5′-substituents. In addition, in contrast to EcMTAN, the active site of AtMTAN1 remains solvated in its ligand-bound forms. As the apparent pK_a of an amino acid depends on its local environment, the putative catalytic acid Asp225 in AtMTAN1 may not be protonated at physiological pH and this suggests the transition state of AtMTAN1, like human MTA phosphorylase and Streptococcus pneumoniae MTAN, may be different from that found in EcMTAN.     

Nucleotide Binding States of Subunit A of the A-ATP Synthase and the Implication of P-Loop Switch in Evolution

The crystal structures of the nucleotide-empty (A_E), 5′-adenylyl-β,γ-imidodiphosphate (A_PNP)-bound, and ADP (A_DP)-bound forms of the catalytic A subunit of the energy producer A₁A_O ATP synthase from Pyrococcus horikoshii OT3 have been solved at 2.47 Å and 2.4 Å resolutions. The structures provide novel features of nucleotide binding and depict the residues involved in the catalysis of the A subunit. In the A_E form, the phosphate analog SO₄²⁻ binds, via a water molecule, to the phosphate binding loop (P-loop) residue Ser238, which is also involved in the phosphate binding of ADP and 5′-adenylyl-β,γ-imidodiphosphate. Together with amino acids Gly234 and Phe236, the serine residue stabilizes the arched P-loop conformation of subunit A, as shown by the 2.4-Å structure of the mutant protein S238A in which the P-loop flips into a relaxed state, comparable to the one in catalytic β subunits of F₁F_O ATP synthases. Superposition of the existing P-loop structures of ATPases emphasizes the unique P-loop in subunit A, which is also discussed in the light of an evolutionary P-loop switch in related A₁A_O ATP synthases, F₁F_O ATP synthases, and vacuolar ATPases and implicates diverse catalytic mechanisms inside these biological motors.     

Phage display and crystallographic analysis reveals potential substrate/binding site interactions in the protein secretion chaperone CsaA from Agrobacterium tumefaciens

The protein CsaA has been proposed to function as a protein secretion chaperone in bacteria that lack the Sec-dependent protein-targeting chaperone SecB. CsaA is a homodimer with two putative substrate-binding pockets, one in each monomer. To test the hypothesis that these cavities are indeed substrate-binding sites able to interact with other polypeptide chains, we selected a peptide that bound to CsaA from a random peptide library displayed on phage. Presented here is the structure of CsaA from Agrobacterium tumefaciens (AtCsaA) solved in the presence and absence of the selected peptide. To promote co-crystallization, the sequence for this peptide was genetically fused to the amino-terminus of AtCsaA. The resulting 1.65 Å resolution crystal structure reveals that the tethered peptide from one AtCsaA molecule binds to the proposed substrate-binding pocket of a symmetry-related molecule possibly mimicking the interaction between a pre-protein substrate and CsaA. The structure shows that the peptide lies in an extended conformation with alanine, proline and glutamine side chains pointing into the binding pocket. The peptide interacts with the atoms of the AtCsaA-binding pocket via seven direct hydrogen bonds. The side chain of a conserved pocket residue, Arg76, has an “up” conformation when the CsaA-binding site is empty and a “down” conformation when the CsaA-binding site is occupied, suggesting that this residue may function to stabilize the peptide in the binding cavity. The presented aggregation assays, phage-display analysis and structural analysis are consistent with AtCsaA being a general chaperone. The properties of the proposed CsaA-binding pocket/peptide interactions are compared to those from other structurally characterized molecular chaperones.     

2′,3′-cAMP hydrolysis by metal-dependent phosphodiesterases containing DHH, EAL, and HD domains is non-specific: Implications for PDE screening

The recent report of 2′,3′-cAMP isolated from rat kidney is the first proof of its biological existence, which revived interest in this mysterious molecule. 2′,3′-cAMP serves as an extracellular adenosine source, but how it is degraded remains unclear. Here, we report that 2′,3′-cAMP can be hydrolyzed by six phosphodiesterases containing three different families of hydrolytic domains, generating invariably 3′-AMP but not 2′-AMP. The catalytic efficiency (k_cat/K_m) of each enzyme against 2′,3′-cAMP correlates with that against the widely used non-specific substrate bis(p-nitrophenyl)phosphate (bis-pNPP), indicating that 2′,3′-cAMP is a previously unknown non-specific substrate for PDEs. Furthermore, we show that the exclusive formation of 3′-AMP is due to the P-O2′ bond having lower activation energy and is not the result of steric exclusion at enzyme active site. Our analysis provides mechanistic basis to dissect protein function when 2′,3′-cAMP hydrolysis is observed.     

Biochemical and structural characterization of 5′-methylthioadenosine nucleosidases from Arabidopsis thaliana

5′-Methylthioadenosine (MTA) and S-adenosylhomocysteine (SAH) are important metabolites in all living organisms. Two similar nucleosidases for hydrolyzing MTA in Arabidopsis thaliana (AtMTAN1 and AtMTAN2) exist, but only AtMTAN2 shows markedly broad substrate specificity for hydrolysis of SAH. To examine the biochemical characteristics of AtMTAN2, it was over-expressed in Escherichia coli and purified to homogeneity. Spectroscopic assays confirm AtMTAN2 catalyzes MTA as well as SAH hydrolysis, compared to AtMTAN1 which only hydrolyzes MTA. In addition, crystal structure of the AtMTAN2 enzyme in complex with, adenine was determined at 2.9 Å resolution. Finally, a structural comparison of AtMTAN2 performed with previously determined structures of AtMTAN1 and an E. coli homolog provides clues for the substrate specificity of MTA nucleosidases in A. thaliana.     

The X-ray crystal structure of APR-B,an atypical adenosine 5′-phosphosulfate reductase from Physcomitrella patens

Sulfonucleotide reductases catalyse the first reductive step of sulfate assimilation. Their substrate specificities generally correlate with the requirement for a [Fe₄S₄] cluster, where adenosine 5′-phosphosulfate (APS) reductases possess a cluster and 3′-phosphoadenosine 5′-phosphosulfate reductases do not. The exception is the APR-B isoform of APS reductase from the moss Physcomitrella patens, which lacks a cluster. The crystal structure of APR-B, the first for a plant sulfonucleotide reductase, is consistent with a preference for APS. Structural conservation with bacterial APS reductase rules out a structural role for the cluster, but supports the contention that it enhances the activity of conventional APS reductases.     

Mutations of Trp275 and Trp397 altered the binding selectivity of Vibrio carchariae chitinase A

Point mutations of the active-site residues Trp168, Tyr171, Trp275, Trp397, Trp570 and Asp392 were introduced to Vibrio carchariae chitinase A. The modeled 3D structure of the enzyme illustrated that these residues fully occupied the substrate binding cleft and it was found that their mutation greatly reduced the hydrolyzing activity against pNP-[GlcNAc]₂ and colloidal chitin. Mutant W397F was the only exception, as it instead enhanced the hydrolysis of the pNP substrate to 142% and gave no activity loss towards colloidal chitin. The kinetic study with the pNP substrate demonstrated that the mutations caused impaired K_m and k_cat values of the enzyme. A chitin binding assay showed that mutations of the aromatic residues did not change the binding equilibrium. Product analysis by thin layer chromatography showed higher efficiency of W275G and W397F in G4–G6 hydrolysis over the wild type enzyme. Though the time course of colloidal chitin hydrolysis displayed no difference in the cleavage behavior of the chitinase variants, the time course of G6 hydrolysis exhibited distinct hydrolytic patterns between wild-type and mutants W275G and W397F. Wild type initially hydrolyzed G6 to G4 and G2, and finally G2 was formed as the major end product. W275G primarily created G2–G5 intermediates, and later G2 and G3 were formed as stable products. In contrast, W397F initially produced G1–G5, and then the high-M_r intermediates (G3–G5) were broken down to G1 and G2 end products. This modification of the cleavage patterns of chitooligomers suggested that residues Trp275 and Trp397 are involved in defining the binding selectivity of the enzyme to soluble substrates.     

Binding of 2′-Amino-2′-Deoxycytidine-5′-Triphosphate to Norovirus Polymerase Induces Rearrangement of the Active Site

Crystal structures of a genogroup II.4 human norovirus polymerase bound to an RNA primer-template duplex and the substrate analogue 2′-amino-2′-deoxycytidine-5′-triphosphate have been determined to 1.8 Å resolution. The alteration of the substrate-binding site that is required to accommodate the 2′-amino group leads to a rearrangement of the polymerase active site and a disruption of the coordination shells of the active-site metal ions. The mode of binding seen for 2′-amino-2′-deoxycytidine-5′-triphosphate suggests a novel molecular mechanism of inhibition that may be exploited for the design of inhibitors targeting viral RNA polymerases.     

Structural insights into the cofactor-assisted substrate recognition of yeast methylglyoxal/isovaleraldehyde reductase Gre2

Saccharomyces cerevisiae Gre2 (EC1.1.1.283) serves as a versatile enzyme that catalyzes the stereoselective reduction of a broad range of substrates including aliphatic and aromatic ketones, diketones, as well as aldehydes, using NADPH as the cofactor. Here we present the crystal structures of Gre2 from S. cerevisiae in an apo-form at 2.00 Å and NADPH-complexed form at 2.40 Å resolution. Gre2 forms a homodimer, each subunit of which contains an N-terminal Rossmann-fold domain and a variable C-terminal domain, which participates in substrate recognition. The induced fit upon binding to the cofactor NADPH makes the two domains shift toward each other, producing an interdomain cleft that better fits the substrate. Computational simulation combined with site-directed mutagenesis and enzymatic activity analysis enabled us to define a potential substrate-binding pocket that determines the stringent substrate stereoselectivity for catalysis.     

PDE7A1 hydrolyzes cCMP

The degradation and biological role of the cyclic pyrimidine nucleotide cCMP is largely elusive. We investigated nucleoside 3′,5′-cyclic monophosphate (cNMP) specificity of six different recombinant phosphodiesterases (PDEs) by using a highly-sensitive HPLC–MS/MS detection method. PDE7A1 was the only enzyme that hydrolyzed significant amounts of cCMP. Enzyme kinetic studies using purified GST-tagged truncated PDE7A1 revealed a cCMP K_M value of 135 ± 19 μM. The V_max for cCMP hydrolysis reached 745 ± 27 nmol/(min mg), which is about 6-fold higher than the corresponding velocity for adenosine 3′,5′-cyclic monophosphate (cAMP) degradation. In summary, PDE7A is a high-speed and low-affinity PDE for cCMP.     

Crystal structure of human cholesterol sulfotransferase (SULT2B1b) in the presence of pregnenolone and 3'-phosphoadenosine 5'-phosphate. Rationale for specificity differences between prototypical SULT2A1 and the SULT2BG1 isoforms

The gene for human hydroxysteroid sulfotransferase (SULT2B1) encodes two peptides, SULT2B1a and SULT2B1b, that differ only at their amino termini. SULT2B1b has a predilection for cholesterol but is also capable of sulfonating pregnenolone, whereas SULT2B1a preferentially sulfonates pregnenolone and only minimally sulfonates cholesterol. We have determined the crystal structure of SULT2B1a and SULT2B1b bound to the substrate donor product 3'-phosphoadenosine 5'-phosphate at 2.9 and 2.4 A, respectively, as well as SULT2B1b in the presence of the acceptor substrate pregnenolone at 2.3 A. These structures reveal a different catalytic binding orientation for the substrate from a previously determined structure of hydroxysteroid sulfotransferase (SULT2A1) binding dehydroepiandrosterone. In addition, the amino-terminal helix comprising residues Asp19 to Lys26, which determines the specificity difference between the SULT2B1 isoforms, becomes ordered upon pregnenolone binding, covering the substrate binding pocket.     

Structural insights into unique substrate selectivity of Thermoplasma acidophilum D-aldohexose dehydrogenase

The d-aldohexose dehydrogenase from the thermoacidophilic archaea Thermoplasma acidophilum (AldT) belongs to the short-chain dehydrogenase/reductase (SDR) superfamily and catalyzes the oxidation of several monosaccharides with a preference for NAD⁺ rather than NADP⁺ as a cofactor. It has been found that AldT is a unique enzyme that exhibits the highest dehydrogenase activity against d-mannose. Here, we describe the crystal structures of AldT in ligand-free form, in complex with NADH, and in complex with the substrate d-mannose, at 2.1 Å, 1.65 Å, and 1.6 Å resolution, respectively. The AldT subunit forms a typical SDR fold with an unexpectedly long C-terminal tail and assembles into an intertwined tetramer. The d-mannose complex structure reveals that Glu84 interacts with the axial C2 hydroxyl group of the bound d-mannose. Structural comparison with Bacillus megaterium glucose dehydrogenase (BmGlcDH) suggests that the conformation of the glutamate side-chain is crucial for discrimination between d-mannose and its C2 epimer d-glucose, and the conformation of the glutamate side-chain depends on the spatial arrangement of nearby hydrophobic residues that do not directly interact with the substrate. Elucidation of the d-mannose recognition mechanism of AldT further provides structural insights into the unique substrate selectivity of AldT. Finally, we show that the extended C-terminal tail completely shuts the substrate-binding pocket of the neighboring subunit both in the presence and absence of substrate. The elaborate inter-subunit interactions between the C-terminal tail and the entrance of the substrate-binding pocket imply that the tail may play a pivotal role in the enzyme activity.     

Structural Basis of Substrate Specificity of Plant 12-Oxophytodienoate Reductases

12-Oxophytodienoate reductase 3 (OPR3) is a FMN-dependent oxidoreductase that catalyzes the reduction of the cyclopentenone (9S,13S)-12-oxophytodienoate [(9S,13S)-OPDA] to the corresponding cyclopentanone in the biosynthesis of the plant hormone jasmonic acid. In vitro, however, OPR3 reduces the jasmonic acid precursor (9S,13S)-OPDA as well as the enantiomeric (9R,13R)-OPDA, while its isozyme OPR1 is highly selective, accepting only (9R,13R)-OPDA as a substrate. To uncover the molecular determinants of this remarkable enantioselectivity, we determined the crystal structures of OPR1 and OPR3 in complex with the ligand p-hydroxybenzaldehyde. Structural comparison with the OPR1:(9R,13R)-OPDA complex and further biochemical and mutational analyses revealed that two active-site residues, Tyr78 and Tyr246 in OPR1 and Phe74 and His244 in OPR3, are critical for substrate filtering. The relatively smaller OPR3 residues allow formation of a wider substrate binding pocket that is less enantio-restrictive. Substitution of Phe74 and His244 by the corresponding OPR1 tyrosines resulted in an OPR3 mutant showing enhanced, OPR1-like substrate selectivity. Moreover, sequence analysis of the OPR family supports the filtering function of Tyr78 and Tyr246 and allows predictions with respect to substrate specificity and biological function of thus far uncharacterized OPR isozymes. The discovered structural features may also be relevant for other stereoselective proteins and guide the rational design of stereospecific enzymes for biotechnological applications.