A comparison of the crystallographic structures of two catalytic antibodies with esterase activity

The crystallographic structure of the Fab fragment of the catalytic antibody, 29G11, complexed with an (S)-norleucine phenyl phosphonate transition state analog was determined at 2.2 A resolution. The antibody catalyzes the hydrolysis of norleucine phenyl ester with (S)-enantioselectivity. The shape and charge complementarity of the binding pocket for the hapten account for the preferential binding of the (S)-enantiomer of the substrate. The structure is compared to that of the more catalytically efficient antibody, 17E8, induced by the same hapten transition state analog. 29G11 has different residues from 17E8 at eight positions in the heavy chain, including four substitutions in the hapten-binding pocket: A33V, S95G, S99R and Y100AN, and four substitutions at positions remote from the catalytic site, I28T, R40K, V65G and F91L. The two antibodies show large differences in the orientations of their variable and constant domains, reflected by a 32 degrees difference in their elbow angles. The VL and VH domains in the two antibodies differ by a rotation of 8.8 degrees. The hapten binds in similar orientations and locations in 29G11 and 17E8, which appear to have catalytic groups in common, though the changes in the association of the variable domains affect the precise positioning of residues in the hapten-binding pocket.     

Potential roles of conserved amino acids in the catalytic domain of the cGMP-binding cGMP-specific phosphodiesterase

The known mammalian 3':5'-cyclic nucleotide phosphodiesterases (PDEs) contain a conserved region located toward the carboxyl terminus, which constitutes a catalytic domain. To identify amino acids that are important for catalysis, we introduced substitutions at 23 conserved residues within the catalytic domain of the cGMP-binding cGMP-specific phosphodiesterase (cGB-PDE; PDE5). Wild-type and mutant proteins were compared with respect to Km for cGMP, kcat, and IC50 for zaprinast. The most dramatic decrease in kcat was seen with H643A and D754A mutants with the decrease in free energy of binding (DeltaDeltaGT) being about 4.5 kcal/mol for each, which is within the range predicted for loss of a hydrogen bond involving a charged residue. His643 and Asp754 are conserved in all known PDEs and are strong candidates to be directly involved in catalysis. Substitutions of His603, His607, His647, Glu672, and Asp714 also produced marked changes in kcat, and these residues are likely to be important for efficient catalysis. The Y602A and E775A mutants exhibited the most dramatic increases in Km for cGMP, with calculated DeltaDeltaGT of 2.9 and 2.8 kcal/mol, respectively, that these two residues are important for cGMP binding in the catalytic site. Zaprinast is a potent competitive inhibitor of cGB-PDE, but the key residues for its binding differ significantly from those that bind cGMP.     

The calcium-binding sites of heparinase I from Flavobacterium heparinum are essential for enzymatic activity

In the accompanying paper (Shriver, Z., Liu, D., Hu, Y., and Sasisekharan, R. (1999) J. Biol. Chem. 274, 4082-4088), we have shown that calcium binds specifically to heparinase I and have identified two major calcium-binding sites (CB-1 and CB-2) that partly conform to the EF-hand calcium-binding motif. In this study, through systematic site-directed mutagenesis, we have confirmed the accompanying biochemical studies and have shown that both CB-1 and CB-2 are involved in calcium binding and enzymatic activity. More specifically, we identified critical residues (viz. Asp210, Asp212, Gly213, and Thr216 in CB-1 and Asn375, Tyr379, and Glu381 in CB-2) that are important for calcium binding and heparinase I enzymatic activity. Mutations in CB-1 resulted in a lower kcat, but did not change the product profile of heparinase I action on heparin; conversely, mutations in CB-2 not only altered the kcat for heparinase I, but also resulted in incomplete degradation, leading to longer saccharides. Fluorescence competition experiments along with heparin affinity chromatography suggested that mutations in CB-1 alter heparinase I activity primarily through decreasing the enzyme's affinity for its calcium cofactor without altering heparin binding to heparinase I. Compared with CB-1 mutations, mutations in CB-2 affected calcium binding to a lesser extent, but they had a more pronounced effect on heparinase I activity, suggesting a different role for CB-2 in the enzymatic action of heparinase I. These results, taken together with our accompanying study, led us to propose a model for calcium binding to heparinase I that includes both CB-1 and CB-2 providing critical interactions, albeit via a different mechanism. Through binding to CB-1 and/or CB-2, we propose that calcium may play a role in the catalytic mechanism and/or in the exolytic processive mechanism of heparin-like glycosaminoglycan depolymerization by heparinase I.     

Functional roles of conserved amino acid residues in DNA methyltransferases investigated by site-directed mutagenesis of the EcoRV adenine-N6-methyltransferase

All DNA methyltransferases (MTases) have similar catalytic domains containing nine blocks of conserved amino acid residues. We have investigated by site-directed mutagenesis the function of 17 conserved residues in the EcoRV alpha-adenine-N6-DNA methyltransferase. The structure of this class of MTases has been predicted recently. The variants were characterized with respect to their catalytic activities and their abilities to bind to DNA and the S-adenosylmethionine (AdoMet) cofactor. Amino acids located in motifs X, I, and II are shown to be involved in AdoMet binding (Lys16, Glu37, Phe39, and Asp58). Some of the mutants defective in AdoMet binding are also impaired in DNA binding, suggesting allosteric interactions between the AdoMet and DNA binding site. Asp78 (motif III), which was supposed to form a hydrogen bond to the AdoMet on the basis of the structure predictions, turned out not to be important for AdoMet binding, suggesting that motif III has not been identified correctly. R128A and N130A, having mutations in the putative DNA binding domain, are unable to bind to DNA. Residues located in motifs IV, V, VI, and VIII are involved in catalysis (Asp193, Tyr196, Asp211, Ser229, Trp231, and Tyr258), some of them presumably in binding the flipped target base, because mutations at these residues fail to significantly interfere with DNA and AdoMet binding but strongly reduce catalysis. Our results are in substantial agreement with the structure prediction for EcoRV alpha-adenine-N6-methyltransferase and x-ray structures of other MTases.     

Histidine77, glutamic acid81, glutamic acid123, threonine126, asparagine194, and tryptophan197 of the human emopamil binding protein are required for in vivo sterol delta 8-delta 7 isomerization

The human emopamil binding protein (hEBP) exhibits sterol Delta8-Delta7 isomerase activity (EC 5.3.3.5) upon heterologous expression in a sterol Delta8-Delta7 isomerization-deficient erg2-3 yeast strain. Ala scanning mutagenesis was used to identify residues in the four putative transmembrane alpha-helices of hEBP that are required for catalytic activity. Isomerization was assayed in vivo by spectrophotometric quantification of Delta5,7-sterols. Out of 64 Ala mutants of hEBP only H77A-, E81A-, E123A-, T126A-, N194A-, and W197A-expressing yeast strains contained 10% or less of wild-type (wt) Delta5,7-sterols. All substitutions of these six residues with functionally or structurally similar amino acid residues failed to fully restore catalytic activity. Mutants E81D, T126S, N194Q, and W197F, but not H77N and E123D, still bound the enzyme inhibitor 3H-ifenprodil. Changed equilibrium and kinetic binding properties of the mutant enzymes confirmed our previous suggestion that residues required for catalytic activity are also involved in inhibitor binding [Moebius et al. (1996) Biochemistry 35, 16871-16878]. His77, Glu81, Glu123, Thr126, Asn194, and Trp197 are localized in the cytoplasmic halves of the transmembrane segments 2-4 and are proposed to line the catalytic cleft. Ala mutants of Trp102, Tyr105, Asp109, Arg111, and Tyr112 in a conserved cytoplasmic domain (WKEYXKGDSRY) between transmembrane segments 2 and 3 contained less than 10% of wt Delta5,7-sterols, implying that this region also could be functionally important. The in vivo complementation of enzyme-deficient yeast strains with mutated cDNAs is a simple and sensitive method to rapidly analyze the functional consequences of mutations in sterol modifying enzymes.     

Kinetic and spectroscopic investigations of wild-type and mutant forms of apple 1-aminocyclopropane-1-carboxylate synthase

Two catalytically inactive mutant forms of 1-aminocyclopropane-1-carboxylate (ACC) synthase, Y85A and K273A, were mixed in low concentrations of guanidine hydrochloride (GdnHCl). About 15% of the wild-type activity was recovered (theoretical 25% for a binomial distribution), proving that the functional unit of the enzyme is a dimer, or theoretically, a higher order oligomer. The enzyme catalyzes the conversion of S-adenosyl-L-methionine (SAM) to ACC. The value of kcat/KM is 1.2 x 10(6) M-1 s-1 at pH 8.3. Viscosity variation experiments with glycerol and sucrose as viscosogenic reagents showed that this reaction is nearly 100% diffusion controlled. The sensitivity to viscosity for the corresponding reaction of the less reactive Y233F mutant is much reduced, thus the latter reaction serves as a control for that of the wild-type enzyme. The kcat/KM vs pH profile for wild-type enzyme exhibits pKa values of 7.5 and 8.9. The former is assigned to the pKa of the alpha-amino group of SAM, while the latter corresponds to the independently determined spectrophotometric pKa of the internal aldimine. The kcat vs pH profile exhibits similar pKas, which means that the above pKa values are not perturbed in the Michaelis complex. The phenolic hydroxyl group of Tyr233 forms a hydrogen bond to the 3'-O- of PLP. The spectral and kinetic pKa (kcat/KM) values of the Y233F mutant are not identical (spectral 10.2, kinetic 8.7). A model that accounts quantitatively for these data posits two parallel pathways to the external aldimine for this mutant, the minor one has the alpha-amino group free base form of SAM reacting with the protonated imine form of the enzyme with kcat/KM approximately 6.0 x 10(3) M-1 s-1, while the major pathway involves reaction of the aldehyde form of PLP with SAM with kcat/KM approximately 7.0 x 10(5) M-1 s-1. The spectral pKa is defined only by the less reactive species.     

Site-directed mutagenesis of active site contact residues in a hydrolytic abzyme: evidence for an essential histidine involved in transition state stabilization

Specific molecular interactions involved in catalysis by antibody 6D9 were investigated by site-directed mutagenesis. The catalytic antibody 6D9, which was generated against a transition state analog (III), hydrolyzes a non-bioactive chloramphenicol monoester derivative (I) to produce chloramphenicol (II). Construction of a three-dimensional molecular model of 6D9 and sequence comparison within a panel of related antibodies suggested candidates for catalytic residues, His (L27d), Tyr (L32), Tyr (H58) and Arg (H100b); these were targeted for the site-directed mutagenesis study. The Y-H58-F and R-H100b-A mutants possessed catalytic activities comparable to that of the wild-type, and the Y-H58-H and Y-L32-F mutant displayed an approximately fivefold decrease in k(cat)/Km. In the transition state analysis, the plots of logK(TSA) versus log(k(cat)/Km) for the mutants are linear, with a slope of approximately 1.0, indicating that the entire hapten-binding energy in the mutants is also utilized to bind the transition state and to accelerate the catalysis. In addition, a dramatic change in the catalytic activity was observed when the histidine residue (27d) in the CDR1 light chain was replaced with alanine. The H-L27d-A mutant had no detectable catalytic activity. This mutation led to a large, 40-fold reduction in transition state binding, with no change in substrate binding. Coupled with the previous kinetic studies and chemical modifications of the intact 6D9 antibody, this mutagenesis study has demonstrated that His L27d plays an essential role in stabilization of the transition state, the mechanism of catalysis by the 6D9 antibody.     

Mutational analysis of the major loop of Bacillus 1,3-1,4-beta-D-glucan 4-glucanohydrolases. Effects on protein stability and substrate binding

The carbohydrate-binding cleft of Bacillus licheniformis 1,3-1, 4-beta-D-glucan 4-glucanohydrolase is partially covered by the surface loop between residues 51 and 67, which is linked to beta-strand-(87-95) of the minor beta-sheet III of the protein core by a single disulfide bond at Cys61-Cys90. An alanine scanning mutagenesis approach has been applied to analyze the role of loop residues from Asp51 to Arg64 in substrate binding and stability by means of equilibrium urea denaturation, enzyme thermotolerance, and kinetics. The DeltaDeltaGU between oxidized and reduced forms is approximately constant for all mutants, with a contribution of 5.3 +/- 0.2 kcal.mol-1 for the disulfide bridge to protein stability. A good correlation is observed between DeltaGU values by reversible unfolding and enzyme thermotolerance. The N57A mutant, however, is more thermotolerant than the wild-type enzyme, whereas it is slightly less stable to reversible urea denaturation. Mutants with a <2-fold increase in Km correspond to mutations at residues not involved in substrate binding, for which the reduction in catalytic efficiency (kcat/Km) is proportional to the loss of stability relative to the wild-type enzyme. Y53A, N55A, F59A, and W63A, on the other hand, show a pronounced effect on catalytic efficiency, with Km > 2-fold and kcat < 5% of the wild-type values. These mutated residues are directly involved in substrate binding or in hydrophobic packing of the loop. Interestingly, the mutation M58A yields an enzyme that is more active than the wild-type enzyme (7-fold increase in kcat), but it is slightly less stable.     

Redesigning the substrate specificity of an enzyme by cumulative effects of the mutations of non-active site residues

Directed evolution was used to change the substrate specificity of aspartate aminotransferase. A mutant enzyme with 17 amino acid substitutions was generated that shows a 2.1 x 10(6)-fold increase in the catalytic efficiency (kcat/Km) for a non-native substrate, valine. The absorption spectrum of the bound coenzyme, pyridoxal 5'-phosphate, is also changed significantly by the mutations. Interestingly, only one of the 17 residues appears to be able to contact the substrate, and none of them interact with the coenzyme. The three-dimensional structure of the mutant enzyme complexed with a valine analog, isovalerate (determined to 2.4-A resolution by x-ray crystallography), provides insights into how the mutations affect substrate binding. The active site is remodeled; the subunit interface is altered, and the enzyme domain that encloses the substrate is shifted by the mutations. The present results demonstrate clearly the importance of the cumulative effects of residues remote from the active site and represent a new line of approach to the redesign of enzyme activity.     

A two-year prospective study of the effect of ursodeoxycholic acid on urinary bile acid excretion and liver morphology in cystic fibrosis-associated liver disease

Mice constitutively express glutathione S-transferase mGSTA3-3 in liver. This isoform possesses uniquely high conjugating activity toward aflatoxin B1-8,9-epoxide (AFBO), thereby protecting mice from aflatoxin B1-induced hepatocarcinogenicity. In contrast, rats constitutively express a closely related GST isoenzyme, rGSTA3-3, with low AFBO activity and, therefore, are sensitive to aflatoxin B1 exposure. Although the two GSTs share 86% sequence identity and have similar catalytic activities toward 1-chloro-2,4-dinitrobenzene (CDNB), they have an approximately 1000-fold difference in catalytic activity toward AFBO. To identify amino acids that confer high activity toward AFBO, non-conserved rGSTA3-3 residues were replaced with mGSTA3-3 residues in two regions believed to form the substrate binding site. Twenty-one mutant rGSTA3-3 enzymes were generated by site-directed mutagenesis using combinations of nine different residues. Except for the E208D mutant, single mutations of rGSTA3-3 produced enzymes with no detectable AFBO activity. Generally, AFBO conjugation activity increased in additive fashion as mGSTA3-3 residues were introduced into the rGSTA3-3 enzyme with the six site mutant E104I/H108Y/Y111H/L207F/E208D/V217K displaying the highest AFBO activity (40 nmol/mg/min) of all the mutant enzymes. When this mutant enzyme was further modified by three additional substitutions (D103E/I105M/V106I) AFBO conjugation activity decreased 14-fold to 2. 8 nmol/mg/min. Although wild-type mGSTA3-3 AFBO conjugation activity (265 nmol/mg/min) could not be obtained by our rGSTA3-3 mutants, we were able to identify six mGSTA3-3 residues; Ile104, Tyr108, His111, Phe207, Asp208, and Lys217 that, when collectively substituted into rGSTA3-3, substantially increased (>200-fold) glutathione conjugation activity toward AFBO.     

Probing the mechanism of Bacillus 1,3-1,4-beta-D-glucan 4-glucanohydrolases by chemical rescue of inactive mutants at catalytically essential residues

The role of the key catalytic residues Glu134 and Glu138 in the retaining 1,3-1,4-beta-glucanase from Bacillus licheniformis is probed by a chemical rescue methodology based on enzyme activation of inactive mutants by the action of added nucleophiles. While Glu134 was proposed as the catalytic nucleophile on the basis of affinity labeling experiments, no functional proof supported the assignment of Glu138 as the general acid-base catalyst. Alanine replacements are prepared by site-directed mutagenesis to produce the inactive E138A and E134A mutants. Addition of azide reactivates the mutants in a concentration-dependent manner using an activated 2, 4-dinitrophenyl glycoside substrate. The chemical rescue operates by a different mechanism depending on the mutant as deduced from 1H NMR monitoring and kinetic analysis of enzyme reactivation. E138A yields the beta-glycosyl azide product arising from nucleophilic attack of azide on the glycosyl-enzyme intermediate, thus proving that Glu138 is the general acid-base residue. Azide activates the deglycosylation step (increasing kcat), but it also has a large effect on a previous step (as seen by the large decrease in KM, the increase in kcat/KM, and the pH dependence of activation), probably increasing the rate of glycosylation through Bronsted acid catalysis by enzyme-bound HN3. By contrast, azide reactivates the E134A mutant through a single inverting displacement to give the alpha-glycosyl azide product, consistent with Glu134 being the catalytic nucleophile. Formate as an exogenous nucleophile has no effect on the E138A mutant, whereas it is a better activator of E134A than azide. Although the reaction yields the normal hydrolysis product, a transient compound was detected by 1H NMR, tentatively assigned to the alpha-glycosyl formate adduct. This is the first case where a nonmodified sugar gives a long-lived covalent intermediate that mimics the proposed glycosyl-enzyme intermediate of retaining glycosidases.     

Binding of peptides naturally presented by HLA-B27 to the differentially disease-associated B*2704 and B*2706 subtypes, and to mutants mimicking their polymorphism

B*2704 and B*2706 are closely related HLA-B27 subtypes of which the former but not the latter is associated to ankylosing spondylitis. Their peptide specificity relative to other disease-associated subtypes was analyzed by testing binding of self-peptides naturally presented by B*2705 or B*2702, and synthetic analogs, to B*2704, B*2706, and site-specific mutants mimicking their changes. Peptides with basic, aliphatic or aromatic C-terminal residues bound to B*2705 with similar affinity. In B*2704 C-terminal aliphatic/ aromatic residues were preferred. B*2706 discriminated drastically between polar and nonpolar C-terminal residues, showing strong preference for Leu and Phe, and less than B*2704 for basic and Tyr residues. Loss of single acidic charges (D > S77, D > Y116) increased preference for C-terminal Leu and Phe, but allowed efficient binding of peptides with basic residues or Tyr. Their gain (V > E152, H > D114) maintained wide C-terminal specificity, but severely impaired binding, presumably by disrupting interactions with internal peptide residues. This was compensated by Y116 in the double D114Y116 mutant. The specificity of B*2704 and B*2706 was explained only partially by the separate effects of single mutations, indicating that novel properties arise from concomitant changes at various positions. For instance, specificity of B*2706 for nonpolar C-terminal residues required simultaneous removal of Asp77 and Asp116. B*2706 differed from B*2705, B*2702, and B*2704 in its lower suitability for C-terminal Tyr, suggesting that this feature might be relevant for HLA-B27 association to spondyloarthropathy.     

Crystal structure of Y34F mutant human mitochondrial manganese superoxide dismutase and the functional role of tyrosine 34

Tyrosine 34 is a prominent and conserved residue in the active site of the manganese superoxide dismutases in organisms from bacteria to man. We have prepared the mutant containing the replacement Tyr 34 --> Phe (Y34F) in human manganese superoxide dismutase (hMnSOD) and crystallized it in two different crystal forms, orthorhombic and hexagonal. Crystal structures of hMnSOD Y34F have been solved to 1.9 A resolution in a hexagonal crystal form, denoted as Y34Fhex, and to 2.2 A resolution in an orthorhombic crystal form, denoted as Y34Fortho. Both crystal forms give structures that are closely superimposable with that of wild-type hMnSOD, with the phenyl rings of Tyr 34 in the wild type and Phe 34 in the mutant very similar in orientation. Therefore, in Y34F, a hydrogen-bonded relay that links the metal-bound hydroxyl to ordered solvent (Mn-OH to Gln 143 to Tyr 34 to H2O to His 30) is broken. Surprisingly, the loss of the Tyr 34 hydrogen bonds resulted in large increases in stability (measured by Tm), suggesting that the Tyr 34 hydroxyl does not play a role in stabilizing active-site architecture. The functional role of the side chain hydroxyl of Tyr 34 can be evaluated by comparison of the Y34F mutant with the wild-type hMnSOD. Both wild-type and Y34F had kcat/Km near 10(9) M-1 s-1, close to diffusion-controlled; however, Y34F showed kcat for maximal catalysis smaller by 10-fold than the wild type. In addition, the mutant Y34F was more susceptible to product inhibition by peroxide than the wild-type enzyme. This activity profile and the breaking of the hydrogen-bonding chain at the active site caused by the replacement Tyr 34 --> Phe suggest that Tyr 34 is a proton donor for O2* - reduction to H2O2 or is involved indirectly by orienting solvent or other residues for proton transfer. Up to 100 mM buffers in solution failed to enhance catalysis by either Y34F or the wild-type hMnSOD, suggesting that protonation from solution cannot enhance the release of the inhibiting bound peroxide ion, likely reflecting the enclosure of the active site by conserved residues as shown by the X-ray structures. The increased thermostability of the mutant Y34F and equal diffusion-controlled activity of Y34F and wild-type enzymes with normal superoxide levels suggest that evolutionary conservation of active-site residues in metalloenzymes reflects constraints from extreme rather than average cellular conditions. This new hypothesis that extreme rather than normal substrate concentrations are a powerful constraint on residue conservation may apply most strongly to enzyme defenses where the ability to meet extreme conditions directly affects cell survival.     

The axial tyrosinate Fe3+ ligand in protocatechuate 3,4-dioxygenase influences substrate binding and product release: evidence for new reaction cycle intermediates

The essential active site Fe3+ of protocatechuate 3,4-dioxygenase [3, 4-PCD, subunit structure (alphabetaFe3+)12] is bound by axial ligands, Tyr447 (147beta) and His462 (162beta), and equatorial ligands, Tyr408 (108beta), His460 (160beta), and a solvent OH- (Wat827). Recent X-ray crystallographic studies have shown that Tyr447 is dissociated from the Fe3+ in the anaerobic 3,4-PCD complex with protocatechuate (PCA) [Orville, A. M., Lipscomb, J. D., and Ohlendorf, D. H. (1997) Biochemistry 36, 10052-10066]. The importance of Tyr447 to catalysis is investigated here by site-directed mutation of this residue to His (Y447H), the first such mutation reported for an aromatic ring cleavage dioxygenase containing Fe3+. The crystal structure of Y447H (2.1 A resolution, R-factor of 0.181) is essentially unchanged from that of the native enzyme outside of the active site region. The side chain position of His447 is stabilized by a His447(N)delta1-Pro448(O) hydrogen bond, placing the Nepsilon2 atom of His447 out of bonding distance of the iron ( approximately 4.3 A). Wat827 appears to be replaced by a CO32-, thereby retaining the overall charge neutrality and coordination number of the Fe3+ center. Quantitative metal and amino acid analysis shows that Y447H binds Fe3+ in approximately 10 of the 12 active sites of 3,4-PCD, but its kcat is nearly 600-fold lower than that of the native enzyme. Single-turnover kinetic analysis of the Y447H-catalyzed reaction reveals that slow substrate binding accounts for the decreased kcat. Three new kinetically competent intermediates in this process are revealed. Similarly, the product dissociation from Y447H is slow and occurs in two resolved steps, including a previously unreported intermediate. The final E.PCA complex (ES4) and the putative E.product complex (ESO2*) are found to have optical spectra that are indistinguishable from those of the analogous intermediates of the wild-type enzyme cycle, while all of the other observed intermediates have novel spectra. Once the E.S complex is formed, reaction with O2 is fast. These results suggest that dissociation of Tyr447 occurs during turnover of 3,4-PCD and is important in the substrate binding and product release processes. Once Tyr447 is removed from the Fe3+ in the final E.PCA complex by either dissociation or mutagenesis, the O2 attack and insertion steps proceed efficiently, suggesting that Tyr447 does not have a large role in this phase of the reaction. This study demonstrates a novel role for Tyr in a biological system and allows evaluation and refinement of the proposed Fe3+ dioxygenase mechanism.     

Peptidylglycine alpha-hydroxylating monooxygenase: active site residues, disulfide linkages, and a two-domain model of the catalytic core

Peptidylglycine alpha-hydroxylating monooxygenase (PHM) is a copper, ascorbate, and molecular oxygen dependent enzyme that catalyzes the first step leading to the C-terminal amidation of glycine-extended peptides. The catalytic core of PHM (PHMcc), refined to residues 42-356 of the PHM protein, was expressed at high levels in CHO (DG44) (dhfr-) cells. PHMcc has 10 cysteine residues involved in 5 disulfide linkages. Endoprotease Lys-C digestion of purified PHMcc under nonreducing conditions cleaved the protein at Lys219, indicating that the protein consists of separable N- and C-terminal domains with internal disulfide linkages, that are connected by an exposed linker region. Disulfide-linked peptides generated by sequential CNBr and pepsin treatment of radiolabeled PHMcc were separated by reverse phase HPLC and identified by Edman degradation. Three disulfide linkages occur in the N-terminal domain (Cys47-Cys186, Cys81-Cys126, and Cys114-Cys131), along with three of the His residues critical to catalytic activity (His107, His108, and His172). Two disulfide linkages (Cys227-Cys334 and Cys293-Cys315) occur in the C-terminal domain, along with the remaining two essential His residues (His242, His244) and Met314, thought to be essential in binding one of the two nonequivalent copper atoms. Substitution of Tyr79 or Tyr318 with Phe increased the Km of PHM for its peptidylglycine substrate without affecting the Vmax. Replacement of Glu313 with Asp increased the Km 8-fold and decreased the kcat 7-fold, again identifying this region of the C-terminal domain as critical to catalytic activity. Taking into account information on the copper ligands in PHM, we propose a two-domain model with a copper site in each domain that allows spatial proximity between previously described copper ligands and residues identified as catalytically important.     

Engineering steroid 5 beta-reductase activity into rat liver 3 alpha-hydroxysteroid dehydrogenase

Delta 4-3-Ketosteroid-5 beta-reductase (5 beta-reductase) precedes 3 alpha-hydroxysteroid dehydrogenase (3 alpha-HSD) in steroid hormone metabolism. Both enzymes are members of the aldo-keto reductase (AKR) superfamily and possess catalytic tetrads differing by a single amino acid. In 3 alpha-HSD, the tetrad consists of Tyr55, Lys84, Asp50, and His117, but a glutamic acid replaces His117 in 5 beta-reductase. By introducing the H117E point mutation into 3 alpha-HSD, we engineered 5 beta-reductase activity into the dehydrogenase. Homogeneous H117E 3 alpha-HSD reduced the double bond in testosterone to form 5 beta-dihydrotestosterone with kcat = 0.25 min-1 and Km = 19.0 microM and reduced the double bond in progesterone to generate 5 beta-dihydroprogesterone with kcat = 0.97 min-1 and Km = 33.0 microM. These kinetic parameters were similar to those reported for homogeneous rat liver 5 beta-reductase [Okuda, A., and Okuda, R. (1984) J. Biol. Chem. 259, 7519-7524]. The H117E mutant also reduced 5beta-dihydrosteroids to 5 beta, 3 alpha-tetrahydrosteroids with a 600-1000-fold decrease in kcat/Km versus wild-type 3 alpha-HSD. The ratio of 5 beta-reductase:3 alpha-HSD activity in the H117E mutant was approximately 1:1. Although the H117A mutant reduced Delta 4-3-ketosteroids, the 3 alpha-HSD activity predominated because the 5 beta-dihydrosteroids were rapidly converted to the 5 beta,3 alpha-tetrahydrosteroids. The pH-rate profiles for carbon-carbon double-bond and ketone reduction catalyzed by the H117E mutant were superimposable, suggesting a common titratable group (pKb = 6.3) for both reactions. In wild-type 3 alpha-HSD, the titratable group responsible for 3-ketosteroid reduction has a pKb = 6.9 and is assignable to Tyr55. The pH-rate profiles for 3-ketosteroid reduction by the H117A mutant were pH-independent. Our data indicate that Tyr55 functions as a general acid for both 3 alpha-HSD and 5 beta-reductase activities. We suggest that a protonated Glu117 increases the acidity of Tyr55 to promote acid-catalyzed enolization of the Delta 4-3-ketosteroid substrate. Further, the identity of amino acid 117 determines whether an AKR can function as a 5 beta-reductase by reorienting the substrate relative to the nicotinamide cofactor. This study provides functional evidence that utilization of modified catalytic residues on an identical protein scaffold is important for evolution of enzymatic activities within the same metabolic pathway.     

Role of active site tyrosine residues in catalysis by human glutathione reductase

Tyr114 and Tyr197 are highly conserved residues in the active site of human glutathione reductase, Tyr114 in the glutathione disulfide (GSSG) binding site and Tyr197 in the NADPH site. Mutation of either residue has profound effects on catalysis. Y197S and Y114L have 17% and 14% the activity of the wild-type enzyme, respectively. Mutation of Tyr197, in the NADPH site, leads to a decrease in Km for GSSG, and mutation of Tyr114, in the GSSG site, leads to a decrease in Km for NADPH. This behavior is predicted for enzymes operating by a ping-pong mechanism where both half-reactions partially limit turnover. Titration of the wild-type enzyme or Y114L with NADPH proceeds in two phases, Eox to EH2 and EH2 to EH2-NADPH. In contrast, Y197S reacts monophasically, showing that excess NADPH fails to enhance the absorbance of the thiolate-FAD charge-transfer complex, the predominant EH2 form of glutathione reductase. The reductive half-reactions of the wild-type enzyme and of Y114L are similar; FAD reduction is fast (approximately 500 s-1 at 4 degreesC) and thiolate-FAD charge-transfer complex formation has a rate of 100 s-1. In Y197S, these rates are only 78 and 5 s-1, respectively. The oxidative half-reaction, the rate of reoxidation of EH2 by GSSG, of the wild-type enzyme is approximately 4-fold faster than that of Y114L. These results are consistent with Tyr197 serving as a gate in the binding of NADPH, and they indicate that Tyr114 assists the acid catalyst His467'.     

Catalytic defects in mutants of class II histidyl-tRNA synthetase from Salmonella typhimurium previously linked to decreased control of histidine biosynthesis regulation

The expression of histidine biosynthetic genes in enteric bacteria is regulated by an attenuation mechanism in which the level of histidyl-tRNA serves as a key sensor of the intracellular histidine pool. Among the early observations that led to the formation of this model for Salmonella typhimurium were the identification of mutants in the gene (hisS) encoding histidyl-tRNA synthetase. We report here the detailed biochemical characterization of five of these S. typhimurium bradytrophic mutants isolated by selection for resistance to histidine analogs, including identification of the deduced amino acid substitutions and determination of the resulting effects on the kinetics of adenylation and aminoacylation. Using the crystal structure of the closely related Escherichia coli histidyl-tRNA synthetase (HisRS) as a guide, two mutants were mapped to a highly conserved proline residue in motif 2 (P117S, P117Q), and were correlated with a fivefold decrease in the kcat for the pyrophosphate exchange reaction, as well as a tenfold increase in the Km for tRNA in the aminoacylation reaction. Another mutant substitution (A302T) mapped to a residue adjacent to the histidine binding pocket, leading to a tenfold increase in Km for histidine in the pyrophosphate exchange reaction. The remaining two mutants (S167F, N254T) substitute residues in or directly adjacent to the hinge region, which joins the insertion domain between motif 2 and motif 3 to the catalytic core, and cause the Km for tRNA to increase four- to tenfold. The kinetic analysis of these mutants establishes a direct link between critical interactions within the active site of HisRS and regulation of histidine biosynthesis, and provides further evidence for the importance of local conformational changes during the catalytic cycle.     

Antibody VH domains as small recognition units

To develop immunoglobulin based recognition units of minimum size, a human heavy chain variable domain (VH) was designed for selection of phage displayed VH. Non-specific binding of the VH through its interface for the light chain variable domain (VL) was prevented through three mutations (G44E, L45R and W47G) in this interface. These mutations were introduced to mimic camelid antibody heavy chains naturally devoid of light chain partners. The third hypervariable loop of the modified VH was then randomised to yield a repertoire of 2 x 10(8) independent clones, which was displayed on phage and selected through antigen binding. VH clones specific for hapten and protein antigens were isolated. Soluble VH was expressed with an isoleucine residue at position 47 to improve expression and stability compared to VH containing a glycine residue at this position, which however was preferable for phage selection. Affinities of soluble VH for hapten were between 100 nM and 400 nM. The VH domains were highly specific, stable and well expressed in Escherichia coli. These positive biophysical properties and their small size make them attractive for biotechnological applications.     

The CorA Mg2+ transport protein of Salmonella typhimurium. Mutagenesis of conserved residues in the third membrane domain identifies a Mg2+ pore

The CorA transport system is the major Mg2+ influx pathway for bacteria and the Archaea. CorA contains three C-terminal transmembrane segments. No conserved charged residues are apparent within the membrane, suggesting that Mg2+ influx does not involve electrostatic interactions. We have mutated conserved residues within the third transmembrane segment to identify sites involved in transport. Mutation of conserved aromatic residues at either end of the membrane segment to alternative aromatic amino acids did not affect total cation uptake or cation affinity. Mutation to alanine greatly diminished uptake with little change in cation affinity implying that the conserved aromatic residues play a structural role in stabilizing this membrane segment of CorA at the interface between the bilayer and the aqueous environment. In contrast, mutation of Tyr292, Met299, and Tyr307 greatly altered the transport properties of CorA. Y292F, Y292S, Y292C, or Y292I mutations essentially abolished transport, without effect on expression or membrane insertion. M299C and M299A mutants exhibited a decrease in cation affinity for Mg2+, Co2+, or Ni2+ of 10-50-fold without a significant change in uptake capacity. Mutations at Tyr307 had no significant effect on cation uptake capacity; however, the affinity of Y307F and Y307A mutations for Mg2+ and Co2+ was decreased 3-10-fold, while affinity for Ni2+ was unchanged compared with the wild type CorA. In contrast, the affinity of the Y307S mutant for all three cations was decreased 2-5-fold. Projection of the third transmembrane segment as an alpha-helix suggests that Tyr292, Met299, and Tyr307 all reside on the same face of the alpha-helix. We interpret the transport data to suggest that a hydroxyl group is important at Tyr307, and that these three residues interact with Mg2+ during transport, forming part of the cation pore or channel within CorA.