Evolution of enzymatic activities in the enolase superfamily: L-fuconate dehydratase from Xanthomonas campestris

Many members of the mechanistically diverse enolase superfamily have unknown functions. In this report we use both genome (operon) context and screening of a library of acid sugars to assign the L-fuconate dehydratase (FucD) function to a member of the mandelate racemase (MR) subgroup of the superfamily encoded by the Xanthomonas campestris pv. campestris str. ATCC 33913 genome (GI:21233491). Orthologues of FucD are found in both bacteria and eukaryotes, the latter including the rTS beta protein in Homo sapiens that has been implicated in regulating thymidylate synthase activity. As suggested by sequence alignments and confirmed by high-resolution structures in the presence of active site ligands, FucD and MR share the same active site motif of functional groups: three carboxylate ligands for the essential Mg2+ located at the ends of the third, fourth, and fifth beta-strands in the (beta/alpha)7beta-barrel domain (Asp 248, Glu 274, and Glu 301, respectively), a Lys-x-Lys motif at the end of the second beta-strand (Lys 218 and Lys 220), a His-Asp dyad at the end of the seventh and beta-strands (His 351 and Asp 324, respectively), and a Glu at the end of the eighth beta-strand (Glu 382). The mechanism of the FucD reaction involves initial abstraction of the 2-proton by Lys 220, acid catalysis of the vinylogous beta-elimination of the 3-OH group by His 351, and stereospecific ketonization of the resulting enol, likely by the conjugate acid of Lys 220, to yield the 2-keto-3-deoxy-L-fuconate product. Screening of the library of acid sugars revealed substrate and functional promiscuity: In addition to L-fuconate, FucD also catalyzes the dehydration of L-galactonate, D-arabinonate, D-altronate, L-talonate, and D-ribonate. The dehydrations of L-fuconate, L-galactonate, and D-arabinonate are initiated by abstraction of the 2-protons by Lys 220. The dehydrations of L-talonate and D-ribonate are initiated by abstraction of the 2-protons by His 351; however, protonation of the enediolate intermediates by the conjugate acid of Lys 220 yields L-galactonate and D-arabinonate in competition with dehydration. The functional promiscuity discovered for FucD highlights possible structural mechanisms for evolution of function in the enolase superfamily.     

Evolution of enzymatic activities in the enolase superfamily: L-rhamnonate dehydratase

The l-rhamnonate dehydratase (RhamD) function was assigned to a previously uncharacterized family in the mechanistically diverse enolase superfamily that is encoded by the genome of Escherichia coli K-12. We screened a library of acid sugars to discover that the enzyme displays a promiscuous substrate specificity: l-rhamnonate (6-deoxy- l-mannonate) has the "best" kinetic constants, with l-mannonate, l-lyxonate, and d-gulonate dehydrated less efficiently. Crystal structures of the RhamDs from both E. coli K-12 and Salmonella typhimurium LT2 (95% sequence identity) were obtained in the presence of Mg (2+); the structure of the RhamD from S. typhimurium was also obtained in the presence of 3-deoxy- l-rhamnonate (obtained by reduction of the product with NaBH 4). Like other members of the enolase superfamily, RhamD contains an N-terminal alpha + beta capping domain and a C-terminal (beta/alpha) 7beta-barrel (modified TIM-barrel) catalytic domain with the active site located at the interface between the two domains. In contrast to other members, the specificity-determining "20s loop" in the capping domain is extended in length and the "50s loop" is truncated. The ligands for the Mg (2+) are Asp 226, Glu 252 and Glu 280 located at the ends of the third, fourth and fifth beta-strands, respectively. The active site of RhamD contains a His 329-Asp 302 dyad at the ends of the seventh and sixth beta-strands, respectively, with His 329 positioned to function as the general base responsible for abstraction of the C2 proton of l-rhamnonate to form a Mg (2+)-stabilized enediolate intermediate. However, the active site does not contain other acid/base catalysts that have been implicated in the reactions catalyzed by other members of the MR subgroup of the enolase superfamily. Based on the structure of the liganded complex, His 329 also is expected to function as the general acid that both facilitates departure of the 3-OH group in a syn-dehydration reaction and delivers a proton to carbon-3 to replace the 3-OH group with retention of configuration.     

Evolution of enzymatic activities in the enolase superfamily: L-talarate/galactarate dehydratase from Salmonella typhimurium LT2

We assigned l-talarate dehydratase (TalrD) and galactarate dehydratase (GalrD) functions to a group of orthologous proteins in the mechanistically diverse enolase superfamily, focusing our characterization on the protein encoded by the Salmonella typhimurium LT2 genome (GI:16766982; STM3697). Like the homologous mandelate racemase, l-fuconate dehydratase, and d-tartrate dehydratase, the active site of TalrD/GalrD contains a general acid/base Lys 197 at the end of the second beta-strand in the (beta/alpha)7beta-barrel domain, Asp 226, Glu 252, and Glu 278 as ligands for the essential Mg2+ at the ends of the third, fourth, and fifth beta-strands, a general acid/base His 328-Asp 301 dyad at the ends of the seventh and sixth beta-strands, and an electrophilic Glu 348 at the end of the eighth beta-strand. We discovered the function of STM3697 by screening a library of acid sugars; it catalyzes the efficient dehydration of both l-talarate (kcat = 2.1 s-1, kcat/Km = 9.1 x 10(3) M-1 s-1) and galactarate (kcat = 3.5 s-1, kcat/Km = 1.1 x 10(4) M-1 s-1). Because l-talarate is a previously unknown metabolite, we demonstrated that S. typhimurium LT2 can utilize l-talarate as carbon source. Insertional disruption of the gene encoding STM3697 abolishes this phenotype; this disruption also diminishes, but does not eliminate, the ability of the organism to utilize galactarate as carbon source. The dehydration of l-talarate is accompanied by competing epimerization to galactarate; little epimerization to l-talarate is observed in the dehydration of galactarate. On the basis of (1) structures of the wild type enzyme complexed with l-lyxarohydroxamate, an analogue of the enolate intermediate, and of the K197A mutant complexed with l-glucarate, a substrate for exchange of the alpha-proton, and (2) incorporation of solvent deuterium into galactarate in competition with dehydration, we conclude that Lys 197 functions as the galactarate-specific base and His 328 functions as the l-talarate-specific base. The epimerization of l-talarate to galactarate that competes with dehydration can be rationalized by partitioning of the enolate intermediate between dehydration (departure of the 3-OH group catalyzed by the conjugate acid of His 328) and epimerization (protonation on C2 by the conjugate acid of Lys 197). The promiscuous catalytic activities discovered for STM3697 highlight the evolutionary potential of a "conserved" active site architecture.     

Evolution of enzymatic activities in the orotidine 5'-monophosphate decarboxylase suprafamily: crystallographic evidence for a proton relay system in the active site of 3-keto-L-gulonate 6-phosphate decarboxylase

3-Keto-L-gulonate 6-phosphate decarboxylase (KGPDC), a member of the orotidine monophosphate decarboxylase (OMPDC) suprafamily, catalyzes the Mg(2+)-dependent decarboxylation of 3-keto-L-gulonate 6-phosphate to L-xylulose 5-phosphate. Structural and biochemical evidence suggests that the KGPDC reaction proceeds via a Mg(2+)-stabilized 1,2-cis-enediolate intermediate. Protonation of the enediolate intermediate occurs in a nonstereospecific manner to form L-xylulose 5-phosphate. Although the exact mechanism of proton delivery is not known, Glu112, His136, and Arg139 have been implicated in this process [Yew, W. S., Wise, E., Rayment, I., and Gerlt, J. A. (2004) Biochemistry 43, 6427-6437]. Surprisingly, single amino acid substitutions of these positions do not substantially reduce catalytic activity but rather alter the stereochemical course of the reaction. Here, we report the X-ray crystal structures of four mutants, K64A, H136A, E112Q, and E112Q/H136A, each determined in the presence of L-threonohydroxamate 4-phosphate, an analogue of the enediolate intermediate, to 1.7, 1.9, 1.8, and 1.9 A resolution, respectively. These structures reveal that substitutions of Lys64, Glu112, and His136 cause changes in the positions of the intermediate analogue and two active site water molecules that were previously identified as possible proton donors. These changes correlate with the observed alterations in the reaction stereochemistry for these mutants, thereby supporting a reaction mechanism in which water molecules competitively shuttle protons from the side chains of His136 and Arg139 to alternate faces of the cis-enediolate intermediate. These studies further underscore the wide variation in the reaction mechanisms in the OMPDC suprafamily.     

Simple model for the effect of Glu165----Asp165 mutation on the rate of catalysis in triose phosphate isomerase

We present an ab-initio self-consistent field calculation with a 4-31G basis set on a simple model for proton abstraction from hydroxyacetone (a model for dihydroxyacetone phosphate; DHAP) by formate, which is a model for Glu165 in triose phosphate isomerase. Earlier, we showed that the electrophilic groups on the enzyme (the NH3+ of Lys13 and the NH of His95) were essential to efficient catalysis by triose phosphate isomerase. These groups stabilized the enediolate formed by proton abstraction from the DHAP model so that proton transfer from this molecule to Glu165 became likely. In this study, we carry this analysis one step further. First, we re-examine the energy profile for proton transfer, using the fact that our earlier calculations showed that the combined effect of His95 and Lys13 on the reactant DHAP and intermediate enediolate was to make them equal in energy. Then, we analyze the likely effect of changing Glu165 to Asp165 and relate this to experiments on the kinetics of enzyme catalysis by the Glu165----Asp165 mutant.     

Evolution of enzymatic activities in the enolase superfamily: D-Mannonate dehydratase from Novosphingobium aromaticivorans

The d-mannonate dehydratase (ManD) function was assigned to a group of orthologous proteins in the mechanistically diverse enolase superfamily by screening a library of acid sugars. Structures of the wild type ManD from Novosphingobium aromaticivorans were determined at pH 7.5 in the presence of Mg2+ and also in the presence of Mg2+ and the 2-keto-3-keto-d-gluconate dehydration product; the structure of the catalytically active K271E mutant was determined at pH 5.5 in the presence of the d-mannonate substrate. As previously observed in the structures of other members of the enolase superfamily, ManD contains two domains, an N-terminal alpha+beta capping domain and a (beta/alpha)7beta-barrel domain. The barrel domain contains the ligands for the essential Mg2+, Asp 210, Glu 236, and Glu 262, at the ends of the third, fourth, and fifth beta-strands of the barrel domain, respectively. However, the barrel domain lacks both the Lys acid/base catalyst at the end of the second beta-strand and the His-Asp dyad acid/base catalyst at the ends of the seventh and sixth beta-strands, respectively, that are found in many members of the superfamily. Instead, a hydrogen-bonded dyad of Tyr 159 in a loop following the second beta-strand and Arg 147 at the end of the second beta-strand are positioned to initiate the reaction by abstraction of the 2-proton. Both Tyr 159 and His 212, at the end of the third beta-strand, are positioned to facilitate both syn-dehydration and ketonization of the resulting enol intermediate to yield the 2-keto-3-keto-d-gluconate product with the observed retention of configuration. The identities and locations of these acid/base catalysts as well as of cationic amino acid residues that stabilize the enolate anion intermediate define a new structural strategy for catalysis (subgroup) in the mechanistically diverse enolase superfamily. With these differences, we provide additional evidence that the ligands for the essential Mg2+ are the only conserved residues in the enolase superfamily, establishing the primary functional importance of the Mg2+-assisted strategy for stabilizing the enolate anion intermediate.     

Evolution of enzymatic activities in the enolase superfamily: structure of a substrate-liganded complex of the L-Ala-D/L-Glu epimerase from Bacillus subtilis

The members of the mechanistically diverse enolase superfamily share a bidomain structure formed from a (beta/alpha)7beta-barrel domain [a modified (beta/alpha)8- or TIM-barrel] and a capping domain formed from N- and C-terminal segments of the polypeptide. The active sites are located at the interface between the C-terminal ends of the beta-strands in the barrel domain and two flexible loops in the capping domain. Within this structure, the acid/base chemistry responsible for formation and stabilization of an enediolate intermediate derived from a carboxylate anion substrate and the processing of it to product is "hard-wired" by functional groups at the C-terminal ends of the beta-strands in the barrel domain; the identity of the substrate is determined in part by the identities of residues located at the end of the eighth beta-strand in the barrel domain and two mobile loops in the capping domain. On the basis of the identities of the acid/base functional groups at the ends of the beta-strands, the currently available structure-function relationships derived from functionally characterized members are often sufficient for "deciphering" the identity of the chemical reaction catalyzed by sequence-divergent members discovered in genome projects. However, insufficient structural information for liganded complexes for specifying the identity of the substrate is available. In this paper, the structure of the complex of L-Ala-L-Glu with the L-Ala-D/L-Glu epimerase from Bacillus subtilis is reported. As expected for the 1,1-proton transfer reaction catalyzed by this enzyme, the alpha-carbon of the substrate is located between Lys 162 and Lys 268 at the ends of the second and sixth beta-strands in the barrel domain. The alpha-ammonium group of the l-Ala moiety is hydrogen bonded to both Asp 321 and Asp 323 at the end of the eighth beta-strand, revealing a novel strategy for substrate recognition in the superfamily. The delta-carboxylate group of the Glu moiety is hydrogen bonded to Arg 24 in one of the flexible loops in the capping domain, thereby providing a structural explanation for the restricted substrate specificity of this epimerase [Schmidt, D. M., Hubbard, B. K., and Gerlt, J. A. (2001) Biochemistry 40, 15707-15715]. These studies provide important new information about the structural bases for substrate specificity in the enolase superfamily.     

Evolution of enzymatic activity in the enolase superfamily: structural and mutagenic studies of the mechanism of the reaction catalyzed by o-succinylbenzoate synthase from Escherichia coli

o-Succinylbenzoate synthase (OSBS) from Escherichia coli, a member of the enolase superfamily, catalyzes an exergonic dehydration reaction in the menaquinone biosynthetic pathway in which 2-succinyl-6-hydroxy-2,4-cyclohexadiene-1-carboxylate (SHCHC) is converted to 4-(2'-carboxyphenyl)-4-oxobutyrate (o-succinylbenzoate or OSB). Our previous structural studies of the Mg(2+).OSB complex established that OSBS is a member of the muconate lactonizing enzyme subgroup of the superfamily: the essential Mg(2+) is coordinated to carboxylate ligands at the ends of the third, fourth, and fifth beta-strands of the (beta/alpha)(7)beta-barrel catalytic domain, and the OSB product is located between the Lys 133 at the end of the second beta-strand and the Lys 235 at the end of the sixth beta-strand [Thompson, T. B., Garrett, J. B., Taylor, E. A, Meganathan, R., Gerlt, J. A., and Rayment, I. (2000) Biochemistry 39, 10662-76]. Both Lys 133 and Lys 235 were separately replaced with Ala, Ser, and Arg residues; all six mutants displayed no detectable catalytic activity. The structure of the Mg(2+).SHCHC complex of the K133R mutant has been solved at 1.62 A resolution by molecular replacement starting from the structure of the Mg(2+).OSB complex. This establishes the absolute configuration of SHCHC: the C1-carboxylate and the C6-OH leaving group are in a trans orientation, requiring that the dehydration proceed via a syn stereochemical course. The side chain of Arg 133 is pointed out of the active site so that it cannot function as a general base, whereas in the wild-type enzyme complexed with Mg(2+).OSB, the side chain of Lys 133 is appropriately positioned to function as the only acid/base catalyst in the syn dehydration. The epsilon-ammonium group of Lys 235 forms a cation-pi interaction with the cyclohexadienyl moiety of SHCHC, suggesting that Lys 235 also stabilizes the enediolate anion intermediate in the syn dehydration via a similar interaction.     

Structural evidence for a 1,2-enediolate intermediate in the reaction catalyzed by 3-keto-L-gulonate 6-phosphate decarboxylase, a member of the orotidine 5'-monophosphate decarboxylase suprafamily

3-Keto-L-gulonate 6-phosphate decarboxylase (KGPDC) and orotidine 5'-phosphate decarboxylase (OMPDC) are members of an enzyme suprafamily, the OMPDC suprafamily, because they are homologous enzymes that catalyze mechanistically distinct reactions using different substrates. KGPDC catalyzes the Mg(2+) ion-dependent decarboxylation of 3-keto-L-gulonate 6-phosphate to yield L-xylulose 5-phosphate and CO(2); OMPDC catalyzes the metal ion-independent decarboxylation of OMP to UMP and CO(2). Structural studies have shown that KGPDC and OMPDC share several strictly conserved active site residues that are used differently by each enzyme to catalyze their mechanistically distinct reactions. Although the mechanism of the KGPDC-catalyzed reaction has yet to be elucidated, it is thought to proceed via a Mg(2+) ion-stabilized 1,2-enediolate intermediate. Here we report the crystal structures of KGPDC complexed with L-gulonate 6-phosphate, L-threonohydroxamate 4-phosphate, and L-xylitol 5-phosphate, analogues of the substrate, enediolate intermediate, and product, as well as with the product, L-xylulose 5-phosphate, at 1.2, 1.8, 1.7, and 1.8 A resolution, respectively. These structures support a mechanism that involves the formation of a cis-1,2-enediolate intermediate. Contrary to expectations, the geometry of the intermediate does not involve bidentate coordination of both enediolate oxygen atoms to the Mg(2+) ion but rather involves only the coordination of the oxygen on C2 to the Mg(2+) ion. The oxygen atom on C1 instead forms hydrogen bonds to both Lys64 and Asp67, two strictly conserved active site residues. Lys64 also interacts with the oxygen on C2 and may serve to stabilize a cis conformation of the 1,2-enediolate. These structures also implicate His136 to be the general acid that protonates the 1,2-enediolate intermediate. This study further demonstrates that multiple unrelated enzyme functions can evolve from a single active site architecture without regard for substrate binding affinity or mechanism.     

Reassessing the type I dehydroquinate dehydratase catalytic triad: Kinetic and structural studies of Glu86 mutants

Dehydroquinate dehydratase (DHQD) catalyzes the third reaction in the biosynthetic shikimate pathway. Type I DHQDs are members of the greater aldolase superfamily, a group of enzymes that contain an active site lysine that forms a Schiff base intermediate. Three residues (Glu86, His143, and Lys170 in the Salmonella enterica DHQD) have previously been proposed to form a triad vital for catalysis. While the roles of Lys170 and His143 are well defined—Lys170 forms the Schiff base with the substrate and His143 shuttles protons in multiple steps in the reaction—the role of Glu86 remains poorly characterized. To probe Glu86′s role, Glu86 mutants were generated and subjected to biochemical and structural study. The studies presented here demonstrate that mutant enzymes retain catalytic proficiency, calling into question the previously attributed role of Glu86 in catalysis and suggesting that His143 and Lys170 function as a catalytic dyad. Structures of the Glu86Ala (E86A) mutant in complex with covalently bound reaction intermediate reveal a conformational change of the His143 side chain. This indicates a predominant steric role for Glu86, to maintain the His143 side chain in position consistent with catalysis. The structures also explain why the E86A mutant is optimally active at more acidic conditions than the wild‐type enzyme. In addition, a complex with the reaction product reveals a novel, likely nonproductive, binding mode that suggests a mechanism of competitive product inhibition and a potential strategy for the design of therapeutics.     

Evolution of enzymatic activities in the enolase superfamily: crystallographic and mutagenesis studies of the reaction catalyzed by D-glucarate dehydratase from Escherichia coli

D-Glucarate dehydratase (GlucD) from Escherichia coli catalyzes the dehydration of both D-glucarate and L-idarate as well as their interconversion via epimerization. GlucD is a member of the mandelate racemase (MR) subgroup of the enolase superfamily, the members of which catalyze reactions that are initiated by abstraction of the alpha-proton of a carboxylate anion substrate. Alignment of the sequence of GlucD with that of MR reveals a conserved Lys-X-Lys motif and a His-Asp dyad homologous to the S- and R-specific bases in the active site of MR. Crystals of GlucD have been obtained into which the substrate D-glucarate and two competitive inhibitors, 4-deoxy-D-glucarate and xylarohydroxamate, could be diffused; D-glucarate is converted to the dehydration product, 5-keto-4-deoxy-D-glucarate (KDG). The structures of these complexes have been determined and reveal the identities of the ligands for the required Mg(2+) (Asp(235), Glu(266), and Asn(289)) as well as confirm the expected presence of Lys(207) and His(339), the catalytic bases that are properly positioned to abstract the proton from C5 of L-idarate and D-glucarate, respectively. Surprisingly, the C6 carboxylate group of KDG is a bidentate ligand to the Mg(2+), with the resulting geometry of the bound KDG suggesting that stereochemical roles of Lys(207) and His(339) are reversed from the predictions made on the basis of the established structure-function relationships for the MR-catalyzed reaction. The catalytic roles of these residues have been examined by characterization of mutant enzymes, although we were unable to use these to demonstrate the catalytic independence of Lys(207) and His(339) as was possible for the homologous Lys(166) and His(297) in the MR-catalyzed reaction.     

Anaerobiospirillum succiniciproducens phosphoenolpyruvate carboxykinase. Mutagenesis at metal site 1

Anaerobiospirillum succiniciproducens phosphoenolpyruvate (PEP) carboxykinase catalyses the reversible metal-dependent formation of oxaloacetate (OAA) and ATP from PEP, ADP and CO(2). Mutations of PEP carboxykinase have been constructed where the residues His(225) and Asp(263), two residues of the enzyme's putative Mn(2+) binding site, were altered. Kinetic studies of the His225Glu, and Asp263Glu PEP carboxykinases show 600- and 16,800-fold reductions in V(max) relative to the wild-type enzyme, respectively, with minor alterations in K(m) for Mn(2+). Molecular modeling of wild-type and mutant enzymes suggests that the lower catalytic efficiency of the Asp263Glu enzyme could be explained by a movement of the lateral chain of Lys(248), a critical catalytic residue, away from the reaction center. The effect on catalysis of introducing a negatively charged oxygen atom in place of N(epsilon-2) at position 225 is discussed in terms of altered binding energy of the intermediate enolpyruvate.     

Reaction mechanism of glyoxalase I explored by an X-ray crystallographic analysis of the human enzyme in complex with a transition state analogue.

The structures of human glyoxalase I in complexes with S-(N-hydroxy-N-p-iodophenylcarbamoyl)glutathione (HIPC-GSH) and S-p-nitrobenzyloxycarbonylglutathione (NBC-GSH) have been determined at 2.0 and 1.72 A resolution, respectively. HIPC-GSH is a transition state analogue mimicking the enediolate intermediate that forms along the reaction pathway of glyoxalase I. In the structure, the hydroxycarbamoyl function is directly coordinated to the active site zinc ion. In contrast, the equivalent group in the NBC-GSH complex is approximately 6 A from the metal in a conformation that may resemble the product complex with S-D-lactoylglutathione. In this complex, two water molecules occupy the liganding positions at the zinc ion occupied by the hydroxycarbamoyl function in the enediolate analogue complex. Coordination of the transition state analogue to the metal enables a loop to close down over the active site, relative to its position in the product-like structure, allowing the glycine residue of the glutathione moiety to hydrogen bond with the protein. The structure of the complex with the enediolate analogue supports an "inner sphere mechanism" in which the GSH-methylglyoxal thiohemiacetal substrate is converted to product via a cis-enediolate intermediate. The zinc ion is envisioned to play an electrophilic role in catalysis by directly coordinating this intermediate. In addition, the carboxyl of Glu 172 is proposed to be displaced from the inner coordination sphere of the metal ion during substrate binding, thus allowing this group to facilitate proton transfer between the adjacent carbon atoms of the substrate. This proposal is supported by the observation that in the complex with the enediolate analogue the carboxyl group of Glu 172 is 3.3 A from the metal and is in an ideal position for reprotonation of the transition state intermediate. In contrast, Glu 172 is directly coordinated to the zinc ion in the complexes with S-benzylglutathione and with NBC-GSH.     

Identification of residues critical for activity of the wound-induced leucine aminopeptidase (LAP-A) of tomato.

The importance of two putative Zn2+-binding (Asp347, Glu429) and two catalytic (Arg431, Lys354) residues in the tomato leucine aminopeptidase (LAP-A) function was tested. The impact of substitutions at these positions, corresponding to the bovine LAP residues Asp255, Glu334, Arg336, and Lys262, was evaluated in His6-LAP-A fusion proteins expressed in Escherichia coli. Sixty-five percent of the mutant His6-LAP-A proteins were unstable or had complete or partial defects in hexamer assembly or stability. The activity of hexameric His6-LAP-As on Xaa-Leu and Leu-Xaa dipeptides was tested. Most substitutions of Lys354 (a catalytic residue) resulted in His6-LAP-As that cleaved dipeptides at slower rates. The Glu429 mutants (a Zn2+-binding residue) had more diverse phenotypes. Some mutations abolished activity and others retained partial or complete activity. The E429D His6-LAP-A enzyme had Km and kcat values similar to the wild-type His6-LAP-A. One catalytic (Arg431) and one Zn-binding (Asp347) residue were essential for His6-LAP-A activity, as most R431 and D347 mutant His6-LAP-As did not hydrolyze dipeptides. The R431K His6-LAP-A that retained the positive charge had partial activity as reflected in the 4.8-fold decrease in kcat. Surprisingly, while the D347E mutant (that retained a negative charge at position 347) was inactive, the D347R mutant that introduced a positive charge retained partial activity. A model to explain these data is proposed.     

Evolution of enzymatic activities in the enolase superfamily: identification of the general acid catalyst in the active site of D-glucarate dehydratase from Escherichia coli

D-Glucarate dehydratase from Escherichia coli (GlucD), a member of the enolase superfamily, catalyzes the dehydration of both D-glucarate and L-idarate to form 5-keto-4-deoxy-D-glucarate (KDG). Previous mutagenesis and structural studies identified Lys 207 and the His 339-Asp 313 dyad as the general basic catalysts that abstract the C5 proton from L-idarate and D-glucarate, respectively, thereby initiating the reaction by formation of a stabilized enediolate anion intermediate [Gulick, A. M., Hubbard, B. K., Gerlt, J. A., and Rayment, I. (2000) Biochemistry 39, 4590-4602]. The vinylogous elimination of the 4-OH group from this intermediate presumably requires a general acid catalyst. The structure of GlucD with KDG and 4-deoxy-D-glucarate bound in the active site revealed that only His 339 and Asn 341 are proximal to the presumed position of the 4-OH leaving group. The N341D and N341L mutants of GlucD were constructed and subjected to both mechanistic and structural analyses. The N341L but not N341D mutant catalyzed the dehydrofluorination of 4-deoxy-4-fluoro-D-glucarate, demonstrating that in this mutant the initial proton abstraction from C5 can be decoupled from elimination of the leaving group from C4. The kinetic properties and structures of these mutants suggest that either Asn 341 participates in catalysis as the general acid that facilitates the departure of the 4-leaving group or is essential for proper positioning of His 339. In the latter scenario, His 339 would function not only as the general base that abstracts the C5 proton from D-glucarate but also as the general acid that catalyzes both the departure of the 4-OH group and the stereospecific incorporation of solvent hydrogen with retention of configuration to form the KDG product. The involvement of a single functional group in this reaction highlights the plasticity of the active site design in members of the enolase superfamily.     

Atomic resolution crystallography of a complex of triosephosphate isomerase with a reaction‐intermediate analog: New insight in the proton transfer reaction mechanism

Enzymes achieve their catalytic proficiency by precisely positioning the substrate and catalytic residues with respect to each other. Atomic resolution crystallography is an excellent tool to study the important details of these geometric active‐site features. Here, we have investigated the reaction mechanism of triosephosphate isomerase (TIM) using atomic resolution crystallographic studies at 0.82‐Å resolution of leishmanial TIM complexed with the well‐studied reaction‐intermediate analog phosphoglycolohydroxamate (PGH). Remaining unresolved aspects of the reaction mechanism of TIM such as the protonation state of the first reaction intermediate and the properties of the hydrogen‐bonding interactions in the active site are being addressed. The hydroxamate moiety of PGH interacts via unusually short hydrogen bonds of its N1? O1 moiety with the carboxylate group of the catalytic glutamate (Glu167), for example, the distance of N1(PGH)‐OE2(Glu167) is 2.69 ± 0.01 Å and the distance of O1(PGH)‐OE1(Glu167) is 2.60 ± 0.01 Å. Structural comparisons show that the side chain of the catalytic base (Glu167) can move during the reaction cycle in a small cavity, located above the hydroxamate plane. The structure analysis suggests that the hydroxamate moiety of PGH is negatively charged. Therefore, the bound PGH mimics the negatively charged enediolate intermediate, which is formed immediately after the initial proton abstraction from DHAP by the catalytic glutamate. The new findings are discussed in the context of the current knowledge of the TIM reaction mechanism. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Mechanistic diversity in the RuBisCO superfamily: the "enolase" in the methionine salvage pathway in Geobacillus kaustophilus

D-Ribulose 1,5-bisphosphate carboxylase/oxygenase (RuBisCO), the most abundant enzyme, is the paradigm member of the recently recognized mechanistically diverse RuBisCO superfamily. The RuBisCO reaction is initiated by abstraction of the proton from C3 of the d-ribulose 1,5-bisphosphate substrate by a carbamate oxygen of carboxylated Lys 201 (spinach enzyme). Heterofunctional homologues of RuBisCO found in species of Bacilli catalyze the tautomerization ("enolization") of 2,3-diketo-5-methylthiopentane 1-phosphate (DK-MTP 1-P) in the methionine salvage pathway in which 5-methylthio-d-ribose (MTR) derived from 5'-methylthioadenosine is converted to methionine [Ashida, H., Saito, Y., Kojima, C., Kobayashi, K., Ogasawara, N., and Yokota, A. (2003) A functional link between RuBisCO-like protein of Bacillus and photosynthetic RuBisCO, Science 302, 286-290]. The reaction catalyzed by this "enolase" is accomplished by abstraction of a proton from C1 of the DK-MTP 1-P substrate to form the tautomerized product, a conjugated enol. Because the RuBisCO- and "enolase"-catalyzed reactions differ in the regiochemistry of proton abstraction but are expected to share stabilization of an enolate anion intermediate by coordination to an active site Mg2+, we sought to establish structure-function relationships for the "enolase" reaction so that the structural basis for the functional diversity could be established. We determined the stereochemical course of the reaction catalyzed by the "enolases" from Bacillus subtilis and Geobacillus kaustophilus. Using stereospecifically deuterated samples of an alternate substrate derived from d-ribose (5-OH group instead of the 5-methylthio group in MTR) as well as of the natural DK-MTP 1-P substrate, we determined that the "enolase"-catalyzed reaction involves abstraction of the 1-proS proton. We also determined the structure of the activated "enolase" from G. kaustophilus (carboxylated on Lys 173) liganded with Mg2+ and 2,3-diketohexane 1-phosphate, a stable alternate substrate. The stereospecificity of proton abstraction restricts the location of the general base to the N-terminal alpha+beta domain instead of the C-terminal (beta/alpha)8-barrel domain that contains the carboxylated Lys 173. Lys 98 in the N-terminal domain, conserved in all "enolases", is positioned to abstract the 1-proS proton. Consistent with this proposed function, the K98A mutant of the G. kaustophilus "enolase" is unable to catalyze the "enolase" reaction. Thus, we conclude that this functionally divergent member of the RuBisCO superfamily uses the same structural strategy as RuBisCO for stabilizing the enolate anion intermediate, i.e., coordination to an essential Mg2+, but the proton abstraction is catalyzed by a different general base.     

Functional and structural changes due to a serine to alanine mutation in the active-site flap of enolase

Crystallographic and kinetic methods have been used to characterize a site-specific variant of yeast enolase in which Ser 39 in the active-site flap has been changed to Ala. In the wild-type enzyme, the carbonyl and hydroxyl groups of Ser 39 chelate the second equivalent of divalent metal ion, effectively anchoring the flap over the fully liganded active site. With Mg(2+) as the activating cation, S39A enolase has <0.01% of wild-type activity as reported previously [J.M. Brewer, C.V. Glover, M.J. Holland, L. Lebioda, Biochim. Biophys. Acta 1383 (2) (1998) 351-355]. Measurements of (2)H kinetic isotope effects indicate that the proton abstraction from 2-phosphoglycerate (2-PGA) is significantly rate determining. Analysis of the isotope effects provides information on the relative rates of formation and breakdown of the enolate intermediate. Moreover, assays with different species of divalent metal ions reveal that with S39A enolase (unlike the case of wild-type enolase), more electrophilic metal ions promote higher activities. The kinetic results with the S39A variant support the notions that a rate-limiting product release lowers the activity of wild-type enolase with more electrophilic metal ions and that the metal ions are used to acidify the C2-proton of 2-PGA. The S39A enolase was co-crystallized with Mg(2+) and the inhibitor phosphonoacetohydroxamate (PhAH). The structure was solved and refined at a resolution of 2.1 A. The structure confirms the conjecture that the active-site flap is opened in the mutant protein. PhAH chelates to both Mg ions as in the corresponding structure of the wild-type complex. Positions of the side chains of catalytic groups, Lys 345 and Glu 211, and of "auxiliary" residues Glu 168 and Lys 396 are virtually unchanged relative to the complex with the wild-type protein. His 159, which hydrogen bonds to the phosphonate oxygens in the wild-type complex, is 5.7 A from the closest phosphonate oxygen, and the loop (154-166) containing His 159 is shifted away from the active center. A peripheral loop, Glu 251-Gly 275, also moves to open access to the active site.