Crystal structures of creatininase reveal the substrate binding site and provide an insight into the catalytic mechanism

Creatininase from Pseudomonas putida is a member of the urease-related amidohydrolase superfamily. The crystal structure of the Mn-activated enzyme has been solved by the single isomorphous replacement method at 1.8A resolution. The structures of the native creatininase and the Mn-activated creatininase-creatine complex have been determined by a difference Fourier method at 1.85 A and 1.6 A resolution, respectively. We found the disc-shaped hexamer to be roughly 100 A in diameter and 50 A in thickness and arranged as a trimer of dimers with 32 (D3) point group symmetry. The enzyme is a typical Zn2+ enzyme with a binuclear metal center (metal1 and metal2). Atomic absorption spectrometry and X-ray crystallography revealed that Zn2+ at metal1 (Zn1) was easily replaced with Mn2+ (Mn1). In the case of the Mn-activated enzyme, metal1 (Mn1) has a square-pyramidal geometry bound to three protein ligands of Glu34, Asp45, and His120 and two water molecules. Metal2 (Zn2) has a well-ordered tetrahedral geometry bound to the three protein ligands of His36, Asp45, and Glu183 and a water molecule. The crystal structure of the Mn-activated creatininase-creatine complex, which is the first structure as the enzyme-substrate/inhibitor complex of creatininase, reveals that significant conformation changes occur at the flap (between the alpha5 helix and the alpha6 helix) of the active site and the creatine is accommodated in a hydrophobic pocket consisting of Trp174, Trp154, Tyr121, Phe182, Tyr153, and Gly119. The high-resolution crystal structure of the creatininase-creatine complex enables us to identify two water molecules (Wat1 and Wat2) that are possibly essential for the catalytic mechanism of the enzyme. The structure and proposed catalytic mechanism of the creatininase are different from those of urease-related amidohydrolase superfamily enzymes. We propose a new two-step catalytic mechanism possibly common to creatininases in which the Wat1 acts as the attacking nucleophile in the water-adding step and the Wat2 acts as the catalytic acid in the ring-opening step.     

A site-directed mutagenesis study on Escherichia coli inorganic pyrophosphatase. Glutamic acid-98 and lysine-104 are important for structural integrity, whereas aspartic acids-97 and -102 are essential for catalytic activity

Analysis of the conservation of functional residues between yeast and Escherichia coli inorganic pyrophosphatases (PPases) suggested that Asp-97, Glu-98, Asp-102, and Lys-104 are important for the action of E. coli PPase [Lahti, R., Kolakowski, L. F., Heinonen, J., Vihinen, M., Pohjanoksa, K., & Cooperman, B. S. (1990) Biochim. Biophys. Acta 1038, 338-345]. We replaced these four residues by oligonucleotide-directed mutagenesis, giving variant PPases DV97, DE97, EV98, DV102, DE102, KI104, and KR104. PPase variants DV97, DV102, and KI104 had no enzyme activity, whereas PPase variants DE97, EV98, DE102, and KR104 had 22%, 33%, 3%, and 3% of the wild-type PPase activity, respectively. This suggests that Asp-97, Asp-102, and Lys-104 are essential for the catalytic activity of E. coli PPase. PPase variants DV98 and KR104 also had an increased sensitivity to heat denaturation; incubation of these mutant PPases at 75 degrees C for 15 min in the presence of 5 mM magnesium ion decreased the activity to 20% and 1%, respectively, of the initial value while 74% of the activity was observed with wild-type PPase. Furthermore, these thermolabile mutant PPases displayed the most profound conformational changes of the PPase variants examined, as demonstrated by the binding of the fluorescent dye Nile red that monitors the hydrophobicity of protein surfaces. Accordingly, Glu-98 and Lys-104 seem to be important for the structural integrity of E. coli PPase.     

Probing the function of conserved residues in the serine/threonine phosphatase PP2Calpha

Human PP2Calpha is a metal-dependent phosphoserine/phosphothreonine protein phosphatase and is the representative member of the large PPM family. The X-ray structure of human PP2Calpha has revealed an active site containing a dinuclear metal ion center that is coordinated by several invariant carboxylate residues. However, direct evidence for the catalytic function of these and other active-site residues has not been established. Using site-directed mutagenesis and enzyme kinetic analyses, we probed the roles of conserved active-site amino acids within PP2Calpha. Asp-60 bridges metals M1 and M2, and Asp-239 coordinates metal M2, both of which were replaced individually to asparagine residues. These point mutations resulted in >or=1000-fold decrease in k(cat) and >or=30-fold increase in K(m) value for Mn(2+). Mutation of Asp-282 to asparagine caused a 100-fold decrease in k(cat), but no significant effect on K(m) values for metal and substrate, consistent with Asp-282 activating a metal-bound water nucleophile. Mutants T128A, E37Q, D38N, and H40A displayed little or no alterations on k(cat) and K(m) values for substrate or metal ion (Mn(2+)). Analysis of H62Q and R33A yielded k(cat) values that were 20- and 2-fold lower than wild-type, respectively. The mutant R33A showed a 8-fold higher K(m) for substrate, while the K(m) observed with H62Q was unaffected. A pH-rate profile of the H62Q mutant showed loss of the ionization that must be protonated for activity. Br?nsted analysis of substrate leaving group pK(a) values for H62Q indicated a greater dependency (slope -0.84) on leaving group pK(a) in comparison to wild-type (slope -0.33). These data provide strong evidence that His-62 acts as a general acid during the cleavage of the P-O bond.     

Small-angle X-ray scattering studies on yeast inorganic pyrophosphatase and its interactions with divalent metal ions, inorganic phosphate, and hydroxymethane bisphosphonate

Small-angle x-ray scattering studies have been carried out on the enzyme yeast inorganic pyrophosphatase (PPase), and its overall conformational changes on interaction with divalent metal ions (Mg²⁺ and Mn²⁺) and with phosphoryl ligands [inorganic phosphate (P_i) and hydroxymethane bisphosphonate (PCHOHP), a nonhydrolyzable inorganic pyrophosphate analog] were assessed. The enzyme undergoes an apparent reduction in size on simultaneous addition of Mg²⁺ and high P_i concentration, although neithough neither Mg²⁺ nor P_i added separately induced any measurable conformational changes. By contrast, simultaneous addition of Mn²⁺ and P_i to PPase does not result in an observable conformational change. However, the overall structure of the enzyme appears to enlarge in the simultaneous presence of Mn²⁺ ions and PCHOHP. The significance of the structural changes seen in PPase under various conditions is discussed.     

The electrophilic and leaving group phosphates in the catalytic mechanism of yeast pyrophosphatase

Binding of pyrophosphate or two phosphate molecules to the pyrophosphatase (PPase) active site occurs at two subsites, P1 and P2. Mutations at P2 subsite residues (Y93F and K56R) caused a much greater decrease in phosphate binding affinity of yeast PPase in the presence of Mn(2+) or Co(2+) than mutations at P1 subsite residues (R78K and K193R). Phosphate binding was estimated in these experiments from the inhibition of ATP hydrolysis at a sub-K(m) concentration of ATP. Tight phosphate binding required four Mn(2+) ions/active site. These data identify P2 as the high affinity subsite and P1 as the low affinity subsite, the difference in the affinities being at least 250-fold. The time course of five "isotopomers" of phosphate that have from zero to four (18)O during [(18)O]P(i)-[(16)O]H(2)O oxygen exchange indicated that the phosphate containing added water is released after the leaving group phosphate during pyrophosphate hydrolysis. These findings provide support for the structure-based mechanism in which pyrophosphate hydrolysis involves water attack on the phosphorus atom located at the P2 subsite of PPase.     

Substitution of Glu122 by Glutamine Revealed the Function of the Second Water Molecule as a Proton Donor in the Binuclear Metal Enzyme Creatininase

Creatininase is a binuclear zinc enzyme and catalyzes the reversible conversion of creatinine to creatine. It exhibits an open-closed conformational change upon substrate binding, and the differences in the conformations of Tyr121, Trp154, and the loop region containing Trp174 were evident in the enzyme-creatine complex when compared to those in the ligand-free enzyme. We have determined the crystal structure of the enzyme complexed with a 1-methylguanidine. All subunits in the complex existed as the closed form, and the binding mode of creatinine was estimated. Site-directed mutagenesis revealed that the hydrophobic residues that show conformational change upon substrate binding are important for the enzyme activity.We propose a catalytic mechanism of creatininase in which two water molecules have significant roles. The first molecule is a hydroxide ion (Wat1) that is bound as a bridge between the two metal ions and attacks the carbonyl carbon of the substrate. The second molecule is a water molecule (Wat2) that is bound to the carboxyl group of Glu122 and functions as a proton donor in catalysis. The activity of the E122Q mutant was very low and it was only partially restored by the addition of ZnCl₂ or MnCl₂. In the E122Q mutant, k_cat is drastically decreased, indicating that Glu122 is important for catalysis. X-ray crystallographic study and the atomic absorption spectrometry analysis of the E122Q mutant-substrate complex revealed that the drastic decrease of the activity of the E122Q was caused by not only the loss of one Zn ion at the Metal1 site but also a critical function of Glu122, which most likely exists for a proton transfer step through Wat2.     

Helicity of short E-R/K peptides

Understanding the secondary structure of peptides is important in protein folding, enzyme function, and peptide‐based drug design. Previous studies of synthetic Ala‐based peptides (>12 a.a.) have demonstrated the role for charged side chain interactions involving Glu/Lys or Glu/Arg spaced three (i, i + 3) or four (i, i + 4) residues apart. The secondary structure of short peptides (<9 a.a.), however, has not been investigated. In this study, the effect of repetitive Glu/Lys or Glu/Arg side chain interactions, giving rise to E‐R/K helices, on the helicity of short peptides was examined using circular dichroism. Short E‐R/K–based peptides show significant helix content. Peptides containing one or more E‐R interactions display greater helicity than those with similar E‐K interactions. Significant helicity is achieved in Arg‐based E‐R/K peptides eight, six, and five amino acids long. In these short peptides, each additional i + 3 and i + 4 salt bridge has substantial contribution to fractional helix content. The E‐R/K peptides exhibit a strongly linear melt curve indicative of noncooperative folding. The significant helicity of these short peptides with predictable dependence on number, position, and type of side chain interactions makes them an important consideration in peptide design.     

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.     

UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase functions through a general acid-base catalyst pair mechanism

UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase (LpxC) is a zinc-dependent enzyme that catalyzes the deacetylation of UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine to form UDP-3-O-(R-hydroxymyristoyl)glucosamine and acetate. The structural similarity of the active site of LpxC to metalloproteases led to the proposal that LpxC functions via a metalloprotease-like mechanism. The pH dependence of k(cat)/Km catalyzed by Escherichia coli and Aquifex aeolicus LpxC displayed a bell-shaped curve (EcLpxC yields apparent pKa values of 6.4+/-0.1 and 9.1+/-0.1), demonstrating that at least two ionizations are important for maximal activity. Metal substitution and mutagenesis experiments suggest that the basic limb of the pH profile is because of deprotonation of a zinc-coordinated group such as the zinc-water molecule, whereas the acidic limb of the pH profile is caused by protonation of either Glu78 or His265. Furthermore, the magnitude of the activity decreases and synergy observed for the active site mutants suggest that Glu78 and His265 act as a general acid-base catalyst pair. Crystal structures of LpxC complexed with cacodylate or palmitate demonstrate that both Glu78 and His265 hydrogen-bond with the same oxygen atom of the tetrahedral intermediate and the product carboxylate. These structural features suggest that LpxC catalyzes deacetylation by using Glu78 and His265 as a general acid-base pair and the zinc-bound water as a nucleophile.     

Novel inhibitor for prolyl tripeptidyl aminopeptidase from Porphyromonas gingivalis and details of substrate-recognition mechanism

A new inhibitor, H-Ala-Ile-pyrrolidin-2-yl boronic acid, was developed as an inhibitor against prolyl tripeptidyl aminopeptidase with a K_i value of 88.1 nM. The structure of the prolyl tripeptidyl aminopeptidase complexed with the inhibitor (enzyme-inhibitor complex) was determined at 2.2 Å resolution. The inhibitor was bound to the active site through a covalent bond between Ser603 and the boron atom of the inhibitor. This structure should closely mimic the structure of the reaction intermediate between the enzyme and substrate. We previously proposed that two glutamate residues, Glu205 and Glu636, are involved in the recognition of substrates. In order to clarify the function of these glutamate residues in substrate recognition, three mutant enzymes, E205A, E205Q, and E636A were generated by site-directed mutagenesis. The E205A mutant was expressed as an inclusion body. The E205Q mutant was expressed in soluble form, but no activity was detected. Here, the structures of the E636A mutant and its complex with the inhibitor were determined. The inhibitor was located at almost the same position as in the wild-type enzyme-inhibitor complex. The amino group of the inhibitor interacted with Glu205 and the main-chain carbonyl group of Gln203. In addition, a water molecule in the place of Glu636 of the wild-type enzyme interacted with the amino group of the inhibitor. This water molecule was located near the position of Glu636 in the wild-type and formed a hydrogen bond with Gln203. The k_cat/K_M values of the E636A mutant toward the two substrates used were smaller than those of the wild-type by two orders of magnitude. The K_i value of our inhibitor for the E636A mutant was 48.8 μM, which was 554-fold higher than that against the wild-type enzyme. Consequently, it was concluded that Glu205 and Glu636 are significant residues for the N-terminal recognition of a substrate.     

Probing the 2,4-dichlorophenoxyacetate/alpha-ketoglutarate dioxygenase substrate-binding site by site-directed mutagenesis and mechanism-based inactivation

TfdA is an Fe(II)- and alpha-ketoglutarate- (alphaKG-) dependent dioxygenase that hydroxylates the herbicide 2,4-dichlorophenoxyacetic acid (2,4-D) producing a hemiacetal that spontaneously decomposes to 2,4-dichlorophenol and glyoxylate. On the basis of a recently published TfdA structural model [Elkins et al. (2002) Biochemistry 41, 5185-5192], His214, Lys71, Arg278, and the backbone amide of Ser117 are suggested to bind the 2,4-D carboxylate; Lys95 and possibly Lys71 are hypothesized to interact with the 2,4-D ether atom; and Arg274 and Thr141 are suspected to bind alphaKG. TfdA variants with substitutions at these and other positions were purified and characterized in order to explore the roles of these residues in catalysis. The K71L, K71Q, K95L, K95Q, R274Q, R274L, and R278Q variants exhibited significantly increased 2,4-D K(m), alphaKG K(m), and alphaKG K(d) values, consistent with their proposed roles in substrate binding. A protease-sensitive site was successfully eliminated in the R78Q variant, which also exhibited decreased affinity for 2,4-D. In contrast, the Y81F, Y126F, T141V, Y169F, and Y244F variants showed only modest changes in their kinetics. An observed 4-fold lower K(m) of the K95L variant compared to wild-type protein with the alternative substrate 2,4-dichlorocinnamic acid provided additional evidence for an interaction between Lys95 and the 2,4-D ether atom. Phenylpropiolic acid was identified as a mechanism-based inactivator of the enzyme [K(i) = 38.1 +/- 6.0 microM and k(inact)(max) = 2.3 +/- 0.1 min(-1)]. This acetylenic compound covalently modifies a peptide (166-AEHYALNSR-174) that is predicted to form one side of the substrate-binding pocket. The K95L variant of TfdA was not inactivated by phenylpropiolic acid, providing added support that Lys95 is present at the active site. These results support the identity of suspected substrate-binding residues derived from structural modeling studies and extend our understanding of the oxidative chemistry carried out by TfdA.     

X-Ray Crystallographic and Kinetic Analysis of Human Purine Nucleoside Phosphorylase Complexes with 1-β-D-Ribofuranosyl-1,2,4-triazole-3-carobxamide and 1-β-D-Ribofuranosyl-1,2,4-triazole-3-carboxamidine

Abstract

The three-dimensional structures of the complexes between human erythrocytic purine nucleoside phosphorylase (PNP) and both 1-β-D-ribofuranosyl-1,2,4-triazole-3-carboxamide (ribavirin) and 1-β-D-ribofuranosyl-1,2,4-triazole-3-carboxamidine (TCNR) have been determined using X-ray crystallographic techniques. The structures have been refined at 2.9 Å resolution using simulated annealing and conjugate-gradient minimization techniques to an R value of 21.8% for ribavirin and 20.8% for TCNR. Ribavirin and TCNR are truncated nucleosides corresponding to adenosine and inosine, respectively, and are of potential interest as PNP inhibitors. Kinetic parameters have been determined for recombinant wild-type PNP and for a mutant PNP in which Asn 243 is converted to Asp. The K_i value for ribavirin is 4.9 mM with wild-type PNP and 4.7 mM with the Asn243Asp mutant, while the K_i values for TCNR are 17.6 μM and 3.8 μM with wild-type and mutant, respectively. X-ray crystallographic studies showed that the binding geometry for both of these substrate analogues was similar to that seen for natural substrates. The glycosidic torsion angles (χ) were ?34° for ribavirin and ?39° for TCNR which are in good agreement with values seen for other studied nucleoside complexes with PNP, but which are unusual when compared to those seen for free nucleic acid derivatives. Based upon the three-dimensional structure, interactions of Asn 243 and Glu 201 with a protonated carboxamidine of TCNR explain the stronger inhibition of PNP observed for TCNR over ribavirin.     

Site-specific effects of zinc on the activity of family II pyrophosphatase

Family II pyrophosphatases (PPases), recently found in bacteria and archaebacteria, are Mn(2+)-containing metalloenzymes with two metal-binding subsites (M1 and M2) in the active site. These PPases can use a number of other divalent metal ions as the cofactor but are inactive with Zn(2+), which is known to be a good cofactor for family I PPases. We report here that the Mg(2+)-bound form of the family II PPase from Streptococcus gordonii is nearly instantly activated by incubation with equimolar Zn(2+), but the activity thereafter decays on a time scale of minutes. The activation of the Mn(2+)-form by Zn(2+) was slower but persisted for hours, whereas activation was not observed with the Ca(2+)- and apo-forms. The bound Zn(2+) could be removed from PPase by prolonged EDTA treatment, with a complete recovery of activity. On the basis of the effect of Zn(2+) on PPase dimerization, the Zn(2+) binding constant appeared to be as low as 10(-12) M for S. gordonii PPase. Similar effects of Zn(2+) and EDTA were observed with the Mg(2+)- and apo-forms of Streptococcus mutans and Bacillus subtilis PPases. The effects of Zn(2+) on the apo- and Mg(2+)-forms of HQ97 and DE15 B. subtilis PPase variants (modified M2 subsite) but not of HQ9 variant (modified M1 subsite) were similar to that for the Mn(2+)-form of wild-type PPase. These findings can be explained by assuming that (a) the PPase tightly binds Mg(2+) and Mn(2+) at the M2 subsite; (b) the activation of the corresponding holoenzymes by Zn(2+) results from its binding to the M1 subsite; and (c) the subsequent inactivation of Mg(2+)-PPase results from Zn(2+) migration to the M2 subsite. The inability of Zn(2+) to activate apo-PPase suggests that Zn(2+) binds more tightly to M2 than to M1, allowing direct binding to M2. Zn(2+) is thus an efficient cofactor at subsite M1 but not at subsite M2.     

The R117A variant of the Escherichia coli transacylase FabD synthesizes novel acyl-(acyl carrier proteins)

The commercial impact of fermentation systems producing novel and biorenewable chemicals will flourish with the expansion of enzymes engineered to synthesize new molecules. Though a small degree of natural variability exists in fatty acid biosynthesis, the molecular space accessible through enzyme engineering is fundamentally limitless. Prokaryotic fatty acid biosynthesis enzymes build carbon chains on a functionalized acyl carrier protein (ACP) that provides solubility, stability, and a scaffold for interactions with the synthetic enzymes. Here, we identify the malonyl-coenzyme A (CoA)/holo-ACP transacylase (FabD) from Escherichia coli as a platform enzyme for engineering to diversify microbial fatty acid biosynthesis. The FabD R117A variant produced novel ACP-based primer and extender units for fatty acid biosynthesis. Unlike the wild-type enzyme that is highly specific for malonyl-CoA to produce malonyl-ACP, the R117A variant synthesized acetyl-ACP, succinyl-ACP, isobutyryl-ACP, 2-butenoyl-ACP, and β-hydroxybutyryl-ACP among others from holo-ACP and the corresponding acyl-CoAs with specific activities from 3.7 to 120 nmol min⁻¹ mg⁻¹. FabD R117A maintained K _M values for holo-ACP (~ 40 μM) and displayed small changes in K _M for acetoacetyl-CoA (110 ± 30 μM) and acetyl-CoA (200 ± 70 μM) when compared to malonyl-CoA (80 ± 30 μM). FabD R117A represents a novel catalyst that synthesizes a broad range of acyl-acyl-ACPs.

     

Effects of active site mutations on the metal binding affinity, catalytic competence, and stability of the family II pyrophosphatase from Bacillus subtilis

Family II inorganic pyrophosphatases (PPases) have been recently found in a variety of bacteria. Their primary and tertiary structures differ from those of the well-known family I PPases, although both have a binuclear metal center directly involved in catalysis. Here, we examined the effects of mutating one Glu, four His, and five Asp residues forming or close to the metal center on Mn(2+) binding affinity, catalysis, oligomeric structure, and thermostability of the family II PPase from Bacillus subtilis (bsPPase). Mutations H9Q, D13E, D15E, and D75E in two metal-binding subsites caused profound (10(4)- to 10(6)-fold) reductions in the binding affinity for Mn(2+). Most of the mutations decreased k(cat) for MgPP(i) by 2-3 orders of magnitude when measured with Mn(2+) or Mg(2+) bound to the high-affinity subsite and Mg(2+) bound to both the low-affinity subsite and pyrophosphate. In the E78D variant, the k(cat) for the Mn-bound enzyme was decreased 120-fold, converting bsPPase from an Mn-specific to an Mg-specific enzyme. K(m) values were less affected by the mutations, and, interestingly, were decreased in most cases. Mutations of His(97) and His(98) residues, which lie near the subunit interface, greatly destabilized the bsPPase dimer, whereas most other mutations stabilized it. Mn(2+), in sharp contrast to Mg(2+), conferred high thermostability to wild-type bsPPase, although this effect was reduced by all of the mutations except D203E. These results indicate that family II PPases have a more integrated active site structure than family I PPases and are consequently more sensitive to conservative mutations.     

Mono- and bimetallic gold(I) and silver(I) pentafluoropropionates and related compounds

A series of eight new carboxylate complexes of the general type (L)_nMOC(O)R (L=PMe₃; n=1; M=Ag, Au; R=C₂F₅. L=PPh₃; n=1-3; M=Ag; R=C₂F₅, t-Bu) have been prepared in high yields. Crystal and molecular structures have been determined for three representative examples. The crystal structure of (Ph₃P)AgOC(O)C₂F₅ contains dimers in which the silver atoms are bridged by the carboxylate oxygen atoms. This bridging resembles the structural motif found in silver carboxylates without ligand support. Usage of the smaller phosphine PMe₃ leads to the formation of a polymeric chain structure in (Me₃P)AgOC(O)C₂F₅ with bridging carboxylate anions and short Ag-Ag contacts holding the monomers together. The reaction of (4-Me₂N-C₆H₄)Ph₂ PAuCl with two equivalents of C₂F₅CO₂Ag leads to the formation of a mixed metal product containing both gold and silver. The crystal structure analysis of this compound revealed a tetranuclear complex containing a central dimeric silver pentafluoropropionate unit which is chelated by the (triarylphosphine)gold(I) pentafluoropropionate molecules via Ag-Au metallophilic contacts and Ag-O donor/acceptor interactions.     

Probing the catalytically essential residues of the alpha-L-fucosidase from the hyperthermophilic archaeon Sulfolobus solfataricus

Retaining glycosidases promote the hydrolysis of the substrate by following a double-displacement mechanism involving a covalent intermediate. The catalytic residues are a general acid/base catalyst and the nucleophile. Experimental identification of these residues in a specific glycosidase allows for the assigning of the corresponding residues in all of the other enzymes belonging to the same family. By means of sequence alignment, mutagenesis, and detailed kinetic studies of the alpha-fucosidase from Sulfolobus solfataricus (Ssalpha-fuc) (family 29), we show here that the residues, invariant in this family, have the function inferred from the analysis of the 3D structure of the enzyme from Thermotoga maritima (Tmalpha-fuc). These include in Ssalpha-fuc the substrate-binding residues His46 and His123 and the nucleophile of the reaction, previously described. The acid/base catalyst could be assigned less easily. The k(cat) of the Ssalpha-fucGlu292Gly mutant, corresponding to the acid/base catalyst of Tmalpha-fuc, is reduced by 154-fold but could not be chemically rescued. Instead, the Ssalpha-fucGlu58Gly mutant revealed a 4000-fold reduction of k(cat)/K(M) if compared to the wild-type and showed the rescue of the k(cat) by sodium azide at wild-type levels. Thus, our data suggest that a catalytic triad, namely, Glu58, Glu292, and Asp242, is involved in catalysis. Glu58 and Glu292 cooperate in the role of acid/base catalyst, while Asp242 is the nucleophile of the reaction. Our data suggest that in glycosidase family 29 alpha-fucosidases promoting the retaining mechanism with slightly different catalytic machineries coexist.     

Base catalysis of chromophore formation in Arg96 and Glu222 variants of green fluorescent protein

In green fluorescent protein (GFP), chromophore biosynthesis is initiated by a spontaneous main-chain condensation reaction. Nucleophilic addition of the Gly67 amide nitrogen to the Ser65 carbonyl carbon is catalyzed by the protein fold and leads to a heterocyclic intermediate. To investigate this mechanism, we substituted the highly conserved residues Arg96 and Glu222 in enhanced GFP (EGFP). In the R96M variant, the rate of chromophore formation is greatly reduced (time constant = 7.5 x 10(3) h, pH 7) and exhibits pH dependence. In the E222Q variant, the rate is also attenuated at physiological pH (32 h, pH 7) but is accelerated severalfold beyond that of EGFP at pH 9-10. In contrast, EGFP maturation is pH-independent and proceeds with a time constant of 1 h (pH 7-10). Mass spectrometric results for R96M and E222Q indicate accumulation of the pre-cyclization state, consistent with rate-limiting backbone condensation. The pH-rate profile implies that the Glu222 carboxylate titrates with an apparent pK(a) of 6.5 in R96M and that the Gly67 amide nitrogen titrates with an apparent pK(a) of 9.2 in E222Q. These data suggest a model for GFP chromophore synthesis in which the carboxylate of Glu222 plays the role of a general base, facilitating proton abstraction from the Gly67 amide nitrogen or the Tyr66 alpha-carbon. Arg96 fulfills the role of an electrophile by lowering the respective pK values and stabilizing the alpha-enolate. Modulating the base strength of the proton-abstracting group may aid in the design of fast-maturing GFPs with improved characteristics for real-time monitoring of cellular events.     

Lysine 194 Is Functional in Isocitrate Lyase from Escherichia coli

Lysine 194 in conserved stretch 1 of tetrameric isocitrate lyase from Escherichia coli has been replaced by using the restriction-enzyme-site elimination method of directed mutagenesis. Expression of subunits of each variant and of wild-type (wt) enzyme was equivalent and all variants assembled into tetrameric proteins. The variants K194R and K194H had k_cat values relative to that of wt enzyme taken as 100 of 11 and 7, respectively. K _m values for Mg²⁺-D_s-isocitrate (in mM units) were: 0.13 for wt-enzyme; 0.12 for the K194R variant; and 0.55 for the K194H variant. Substitution at position 194 of Leu or Glu resulted in zero catalytic activity. These results establish that Lys 194 is another functional residue in conserved stretch one of isocitrate lyase from E. coli besides H184, K193, C195, and H197. Because K194 can be specifically replaced by the basic residues His and Arg with resultant lowered activity and by His with an increased K _m value, it may contribute to a cation center and facilitate substrate binding as well as orientation of the developing transition state. Received: 3 December 1996 / Accepted: 18 December 1996