Site-directed mutagenesis of ricin A-chain and implications for the mechanism of action

Ricin A-chain is an N-glycosidase that attacks ribosomal RNA at a highly conserved adenine residue. The enzyme is representative of a large family of medically significant proteins used in the design of anticancer agents and in the treatment of HIV infection. The x-ray structure has been used as a guide to create several active site mutations by directed mutagenesis of the cloned gene. Glu177 is a key catalytic residue, and conversion to Gln reduces activity 180-fold. Asn209 is shown to participate in substrate binding by kinetic analysis. Conversion to Ser increases Km sixfold but has no effect on kcat. Conversion of Tyr80 and Tyr123 to Phe decreases activity by 15- and 7-fold respectively. A mechanism of action is proposed that involves binding of the substrate adenine in a syn configuration that resembles the transition state; the putative oxycarbonium ion is probably stabilized by interaction with Glu177.     

Investigation of the role of Arg301 identified in the X-ray structure of phosphite dehydrogenase

Phosphite dehydrogenase (PTDH) from Pseudomonas stutzeri catalyzes the nicotinamide adenine dinucleotide-dependent oxidation of phosphite to phosphate. The enzyme belongs to the family of D-hydroxy acid dehydrogenases (DHDHs). A search of the protein databases uncovered many additional putative phosphite dehydrogenases. The genes encoding four diverse candidates were cloned and expressed, and the enzymes were purified and characterized. All oxidized phosphite to phosphate and had similar kinetic parameters despite a low level of pairwise sequence identity (39-72%). A recent crystal structure identified Arg301 as a residue in the active site that has not been investigated previously. Arg301 is fully conserved in the enzymes shown here to be PTDHs, but the residue is not conserved in other DHDHs. Kinetic analysis of site-directed mutants of this residue shows that it is important for efficient catalysis, with an ~100-fold decrease in k(cat) and an almost 700-fold increase in K(m,phosphite) for the R301A mutant. Interestingly, the R301K mutant displayed a slightly higher k(cat) than the parent PTDH, and a more modest increase in K(m) for phosphite (nearly 40-fold). Given these results, Arg301 may be involved in the binding and orientation of the phosphite substrate and/or play a catalytic role via electrostatic interactions. Three other residues in the active site region that are conserved in the PTDH orthologs but not DHDHs were identified (Trp134, Tyr139, and Ser295). The importance of these residues was also investigated by site-directed mutagenesis. All of the mutants had k(cat) values similar to that of the wild-type enzyme, indicating these residues are not important for catalysis.     

Mutational and crystallographic analyses of the active site residues of the Bacillus circulans xylanase.

Using site-directed mutagenesis we have investigated the catalytic residues in a xylanase from Bacillus circulans. Analysis of the mutants E78D and E172D indicated that mutations in these conserved residues do not grossly alter the structure of the enzyme and that these residues participate in the catalytic mechanism. We have now determined the crystal structure of an enzyme-substrate complex to 108 A resolution using a catalytically incompetent mutant (E172C). In addition to the catalytic residues, Glu 78 and Glu 172, we have identified 2 tyrosine residues, Tyr 69 and Tyr 80, which likely function in substrate binding, and an arginine residue, Arg 112, which plays an important role in the active site of this enzyme. On the basis of our work we would propose that Glu 78 is the nucleophile and that Glu 172 is the acid-base catalyst in the reaction.     

Structure-function analysis of the Rho-ADP-ribosylating exoenzyme C3stau2 from Staphylococcus aureus

Exoenzyme C3stau2 from Staphylococcus aureus is a new member of the family of C3-like ADP-ribosyltransferases that ADP-ribosylates RhoA, -B, and -C. Additionally, it modifies RhoE and Rnd3. Here we report on studies of the structure-function relationship of recombinant C3stau2 by site-directed mutagenesis. Exchange of Glu(180) with leucine caused a complete loss of both ADP-ribosyltransferase and NAD glycohydrolase activity. By contrast, exchange of the glutamine residue two positions upstream (Gln(178)) with lysine blocked ADP-ribosyltransferase activity without major changes in NAD glycohydrolase activity. NAD and substrate binding of this mutant protein was comparable to that of the recombinant wild type. Exchange of amino acid Tyr(175), which is part of the recently described "ADP-ribosylating toxin turn-turn" (ARTT) motif [Han, S., Arvai, A. S., Clancy, S. B., and Tainer, J. A. (2001) J. Mol.Biol. 305, 95-107], with alanine, lysine, or threonine caused a loss of or a decrease in ADP-ribosyltransferase activity but an increase in NAD glycohydrolase activity. Recombinant C3stau2 Tyr175Ala and Tyr175Lys were not precipitated by matrix-bound Rho, supporting a role of Tyr(175) in protein substrate recognition. Exchange of Arg(48) and/or Arg(85) resulted in a 100-fold reduced transferase activity, while the recombinant C3stau2 double mutant R48K/R85K was totally inactive. The data indicate that amino acid residues Arg(48), Arg(85), Tyr(175), Gln(178), and Glu(180) are essential for ADP-ribosyltransferase activity of recombinant C3stau2 and support the role of the ARTT motif in substrate recognition of RhoA by C3-like ADP-ribosyltransferases.     

Identification of a plasmin-interactive site within the A2 domain of the factor VIII heavy chain

Factor VIII is activated and inactivated by plasmin by limited proteolysis. In our one-stage clotting assay, these plasmin-catalyzed reactions were inhibited by the addition of isolated factor VIII A2 subunits and by Glu-Gly-Arg-active-site modified factor IXa. SDS-PAGE analysis showed that an anti-A2 monoclonal antibody, recognizing the factor IXa-interactive site (residues 484-509), blocked the plasmin-catalyzed cleavage at Arg(336) and Arg(372) but not at Arg(740). Surface plasmon resonance-based assays and ELISA demonstrated that the A2 subunit bound to active-site modified anhydro-plasmin with high affinity (K(d): 21 nM). Both an anti-A2 monoclonal antibody and a peptide comprising of A2 residues 479-504 blocked A2 binding by approximately 80% and approximately 55%, respectively. Mutant A2 molecules where the basic residues in A2 were converted to alanine were evaluated for binding of anhydro-plasmin. Among the tested mutants, the R484A A2 mutant possessed approximately 250-fold lower affinity than the wild-type A2. The affinities of K377A, K466A, and R471A mutants were decreased by 10-20-fold. The inhibitory effect of R484A mutant on plasmin-catalyzed inactivation of factor VIIIa was approximately 20% of that of wild-type A2. In addition, the inactivation rate by plasmin of factor VIIIa reconstituted with R484A mutant was approximately 3-fold lower than that with wild-type A2. These findings demonstrate that Arg(484) plays a key role within the A2 plasmin-binding site, responsible for plasmin-catalyzed factor VIII(a) inactivation.     

Substrate recognition mechanism of prolyl aminopeptidase from Serratia marcescens

Molecular cloning of the gene and the crystal structure of the prolyl aminopeptidase [EC 3.4.11.5] from Serratia marcescens have been studied by us [J. Biochem. 122, 601-605 (1997); ibid. 126, 559-565 (1999)]. Through these studies, Phe139, Tyr149, Glu204, and Arg136 were estimated to be concerned with substrate recognition. To elucidate the details of the mechanism for the substrate specificity, the site-directed mutagenesis method was applied. The F139A mutant showed an 80-fold decrease in catalytic efficiency (k(cat)/K(m)), but the Y149A mutant did not show a significant change in catalytic efficiency. The catalytic efficiency of the E204Q mutant was about 4% of that of the wild type. The peptidase activity of the mutant (R136A) was markedly decreased, however, arylamidase activity with Pyr-bNA was retained as in the wild-enzyme. From these results, it was clarified that the pyrrolidine ring and the amino group of proline at the S1 site were recognized by Phe139 and Glu204, respectively. P1' of a substrate was recognized by Arg136. On the other hand, the enzyme had two cysteine residues. Mutants C74A and C271A were inhibited by PCMB, but the double mutated enzyme (C74/271A) was resistant to it.     

Acidic residues C-terminal to the A2 domain facilitate thrombin-catalyzed activation of factor VIII

Factor VIII is activated by thrombin through proteolysis at Arg740, Arg372, and Arg1689. One region implicated in this exosite-dependent interaction is the factor VIII a2 segment (residues 711-740) separating the A2 and B domains. Residues 717-725 (DYYEDSYED) within this region consist of five acidic residues and three sulfo-Tyr residues, thus representing a high density of negative charge potential. The contributions of these residues to thrombin-catalyzed activation of factor VIII were assessed following mutagenesis of acidic residues to Ala or Tyr residues to Phe and expression and purification of the B-domainless proteins from stable-expressing cell lines. All mutations showed reduced specific activity from approximately 30% to approximately 70% of the wild-type value. While replacement of the Tyr residues showed little, if any, effect on rates of thrombin-catalyzed proteolysis of factor VIII and consequent activation, the acidic to Ala mutations Glu720Ala, Asp721Ala, Glu724Ala, and Asp725Ala showed decreased rates of proteolysis at each of the three P1 residues. Mutations at residues Glu724 and Asp725 were most affected with double mutations at these sites showing approximately 10-fold and approximately 30-fold reduced rates of cleavage at Arg372 and Arg1689, respectively. Factor VIII activation profiles paralleled the results assessing rates of proteolysis. Kinetic analyses revealed these mutations minimally affected apparent V max for thrombin-catalyzed cleavage but variably increased the K m for procofactor up to 7-fold, suggesting the latter parameter was dominant in reducing catalytic efficiency. These results suggest that residues Glu720, Asp721, Glu724, and Asp725 likely constitute an exosite-interactive region in factor VIII facilitating cleavages for procofactor activation.     

Structure-function studies of nerve growth factor: functional importance of highly conserved amino acid residues.

Selected amino acid residues in chicken nerve growth factor (NGF) were replaced by site-directed mutagenesis. Mutated NGF sequences were transiently expressed in COS cells and the yield of NGF protein in conditioned medium was quantified by Western blotting. Binding of each mutant to NGF receptors on PC12 cells was evaluated in a competition assay. The biological activity was determined by measuring stimulation of neurite outgrowth from chick sympathetic ganglia. The residues homologous to the proposed receptor binding site of insulin (Ser18, Met19, Val21, Asp23) were substituted by Ala. Replacement of Ser18, Met19 and Asp23 did not affect NGF activity. Modification of Val21 notably reduced both receptor binding and biological activity, suggesting that this residue is important to retain a fully active NGF. The highly conserved Tyr51 and Arg99 were converted into Phe and Lys respectively, without changing the biological properties of the molecule. However, binding and biological activity were greatly impaired after the simultaneous replacement of both Arg99 and Arg102 by Gly. The three conserved Trp residues at positions 20, 75 and 98 were substituted by Phe. The Trp mutated proteins retained 15-60% of receptor binding and 40-80% of biological activity, indicating that the Trp residues are not essential for NGF activity. However, replacement of Trp20 significantly reduced the amount of NGF in the medium, suggesting that this residue may be important for protein stability.     

X-ray analysis of substrate analogs in the ricin A-chain active site.

Ricin A-chain is an N-glycosidase that hydrolyzes the adenine ring from a specific adenosine of rRNA. Formycin monophosphate (FMP) and adenyl(3'-->5')guanosine (ApG) were bound to ricin A-chain and their structures elucidated by X-ray crystallography. The formycin ring stacks between tyrosines 80 and 123 and at least four hydrogen bonds are made to the adenine moiety. A residue invariant in this enzyme class, Arg180, appears to hydrogen bond to N-3 of the susceptible adenine. Three hypothetical models for binding a true hexanucleotide substrate, CGAGAG, are proposed. They incorporate adenine binding, shown by crystallography, but also include geometry likely to favor catalysis. For example, efforts have been made to orient the ribose ring in a way that allows solvent attack and oxycarbonium stabilization by the enzyme. The favored model is a simple perturbation of the tetraloop structure determined by nuclear magnetic resonance for similar polynucleotides. The model is attractive in that specific roles are defined for conserved protein residues. A mechanism of action is proposed. It invokes oxycarbonium ion stabilization on ribose by Glu177 in the transition state. Arg180 stabilizes anion development on the leaving adenine by protonation at N-3 and may activate a trapped water molecule that is the ultimate nucleophile in the depurination.     

Dissecting differential binding of fructose and phosphate as leaving group/nucleophile of glucosyl transfer catalyzed by sucrose phosphorylase

Site-directed mutagenesis was used to examine the specificity of Leuconostoc mesenteroides sucrose phosphorylase for utilization of fructose and phosphate as leaving group/nucleophile of the reaction. The largest catalytic defect in Arg(137)-->Ala (approximately 60-fold) and Tyr(340)-->Ala (approximately 2500-fold) concerned phosphate dependent half-reactions whereas that in Asp(338)-->Asn (approximately 7000-fold) derived from disruption of steps where fructose departs or attacks. The relative efficiencies for enzyme glucosylation by sucrose compared with alpha-d-glucose-1-phosphate and enzyme deglucosylation by phosphate compared with fructose were 5.5 and 6.2 for wild-type, 19 and 2.0 for Arg(137)-->Ala, 950 and 0.17 for Tyr(340)-->Ala, and 0.05 and 180 for Asp(338)-->Asn, respectively. Asp(338) and Tyr(340) have a key role in differential binding of fructose and phosphate, respectively.     

Enhanced bacteriolytic activity of hen egg-white lysozyme due to conversion of Trp62 to other aromatic amino acid residues

Tryptophan at the 62nd position (Trp62) of hen egg-white lysozyme is an amino acid residue whose action is essential for its enzymatic activity. Its indole ring may possibly come into direct contact with sugar residues of the substrate, and thus contribute significantly to substrate binding. For further elucidation of its role in catalytic processes, this amino acid was converted to other aromatic residues, such as Tyr, Phe, and His, by site-directed mutagenesis. All the mutations were found to enhance the bacteriolytic activity but to decrease the hydrolytic activity toward an artificial substrate, glycol chitin. Such a change in substrate preference appears remarkable considering the smaller size of the aromatic residue on the mutant enzyme at the 62nd position.     

Site-directed mutagenesis experiments on the putative deprotonation site of squalene-hopene cyclase from Alicyclobacillus acidocaldarius

To provide insight into the catalytic mechanism for the final deprotonation reaction of squalene-hopene cyclase (SHC) from Alicyclobacillus acidocaldarius, mutagenesis experiments were conducted for the following ten residues: Thr41, Glu45, Glu93, Arg127, Trp133, Gln262, Pro263, Tyr267, Phe434 and Phe437. An X-ray analysis of SHC has revealed that two types of water molecules ("front water" and "back waters") were involved around the deprotonation site. The results of these mutagenesis experiments allow us to propose the functions of these residues. The two residues of Gln262 and Pro263 probably work to keep away the isopropyl group of the hopanyl cation intermediate from the "front water molecule," that is, to place the "front water" in a favorable position, leading to the minimal production of by-products, i.e., hopanol and hop-21(22)-ene. The five residues of Thr41, Glu45, Glu93, Arg127 and Trp133, by which the hydrogen-bonded network incorporating the "back waters" is constructed, increase the polarization of the "front water" to facilitate proton elimination from the isopropyl moiety of the hopanyl cation, leading to the normal product, hop-22(29)-ene. The three aromatic residues of Tyr267, Phe434 and Phe437 are likely to play an important role in guiding squalene from the enzyme surface to the reaction cavity (substrate channeling) by the strong affinity of their aromatic residues to the squalene substrate.     

On the effects of replacing the carboxylate-binding arginine-171 by hydrophobic tyrosine or tryptophan residues in the L-lactate dehydrogenase from Bacillus stearothermophilus

For L-lactate dehydrogenases (LDH's), the interaction of the guanidinium group of their Arg 171 residue with the carboxylate group of an alpha-keto acid is of primary importance in orienting the substrate productively at the active site. LDH's such as that of Bacillus stearothermophilus (BSLDH) are of practical importance for the preparation of chiral 2-hydroxy acids used as synthons in asymmetric synthesis but would even be more valuable in this regard if their specificities were broader. With a view to tailoring the specificity of BSLDH toward carbonyl substrates that lack an alpha-carboxyl group such as ketones, site-directed mutagenesis has been applied to replace Arg 171 by the approximately isosteric, but hydrophobic, amino acids Tyr and Trp. The mutant enzymes exhibit remarkably good catalytic activities toward representative alpha-keto acids RCOCOOH, where R = Me, Et, n-Pr, n-Bu, and CH2OH, although for the mutant enzymes the kcat/KM's are lower by approximately 10(3)-10(4)-fold than those for native BSLDH. Surprisingly, the 171----Tyr/Trp enzymes are significantly more active than 171----Lys (Hart et al., 1987a), for which an interaction of a positively charged side chain with substrate COO- is retained. Preparative-scale 171----Trp catalyzed reduction of pyruvate gave optically pure L-lactate, showing that L stereospecificity of such LDH enzymes was unaffected by the loss of Arg 171. The retention of L stereospecificity is attributed to secondary polar or hydrogen-bonding associations of Arg 109 and Thr246, respectively, with the substrate COO-function that are of sufficient magnitude to maintain "normal" substrate orientation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Residues surrounding Arg336 and Arg562 contribute to the disparate rates of proteolysis of factor VIIIa catalyzed by activated protein C

Activated Protein C (APC) inactivates factor VIIIa by cleavage at Arg(336) and Arg(562) within the A1 and A2 subunits, respectively, with reaction at the former site occurring at a rate approximately 25-fold faster than the latter. Recombinant factor VIII variants possessing mutations within the P4-P3' sequences were used to determine the contributions of these residues to the disparate cleavage rates at the two P1 sites. Specific activity values for 336(P4-P3')562, 336(P4-P2)562, and 336(P1'-P3')562 mutants, where indicated residues surrounding the Arg(336) site were replaced with those surrounding Arg(562), were similar to wild type (WT) factor VIII; whereas 562(P4-P3')336 and 562(P4-P2)336 mutants showed specific activity values <1% the WT value. Inactivation rates for the 336 site mutants were reduced approximately 6-11-fold compared with WT factor VIIIa, and approached values attributed to cleavage at Arg(562). Cleavage rates at Arg(336) were reduced approximately 100-fold for 336(P4-P3')562, and approximately 9-16-fold for 336(P4-P2)562 and 336(P1'-P3')562 mutants. Inhibition kinetics revealed similar affinities of APC for WT factor VIIIa and 336(P4-P3')562 variant. Alternatively, the 562(P4-P3')336 variant showed a modest increase in cleavage rate ( approximately 4-fold) at Arg(562) compared with WT, whereas these rates were increased by approximately 27- and 6-fold for 562(P4-P3')336 and 562(P4-P2)336, respectively, using the factor VIII procofactor form as substrate. Thus the P4-P3' residues surrounding Arg(336) and Arg(562) make significant contributions to proteolysis rates at each site, apparently independent of binding affinity. Efficient cleavage at Arg(336) by APC is attributed to favorable P4-P3' residues at this site, whereas cleavage at Arg(562) can be accelerated following replacement with more optimal P4-P3' residues.     

Modeling and alanine scanning mutagenesis studies of recombinant pokeweed antiviral protein

The Phytolacca americana-derived naturally occurring ribosome inhibitory protein pokeweed antiviral protein (PAP) is an N-glycosidase that catalytically removes a specific adenine residue from the stem loop of ribosomal RNA. We have employed molecular modeling studies using a novel model of PAP-RNA complexes and site-directed mutagenesis combined with bioassays to evaluate the importance of the residues at the catalytic site and a putative RNA binding active center cleft between the catalytic site and C-terminal domain for the enzymatic deadenylation of ribosomal RNA by PAP. As anticipated, alanine substitutions by site-directed mutagenesis of the PAP active site residues Tyr(72), Tyr(123), Glu(176), and Arg(179) that directly participate in the catalytic deadenylation of RNA resulted in greater than 3 logs of loss in depurinating and ribosome inhibitory activity. Similarly, alanine substitution of the conserved active site residue Trp(208), which results in the loss of stabilizing hydrophobic interactions with the ribose as well as a hydrogen bond to the phosphate backbone of the RNA substrate, caused greater than 3 logs of loss in enzymatic activity. By comparison, alanine substitutions of residues (28)KD(29), (80)FE(81), (111)SR(112), (166)FL(167) that are distant from the active site did not significantly reduce the enzymatic activity of PAP. Our modeling studies predicted that the residues of the active center cleft could via electrostatic interactions contribute to both the correct orientation and stable binding of the substrate RNA molecule in the active site pocket. Notably, alanine substitutions of the highly conserved, charged, and polar residues of the active site cleft including (48)KY(49), (67)RR(68), (69)NN(70), and (90)FND(92) substantially reduced the depurinating and ribosome inhibitory activity of PAP. These results provide unprecedented evidence that besides the active site residues of PAP, the conserved, charged, and polar side chains located at its active center cleft also play a critical role in the PAP-mediated depurination of ribosomal RNA.     

Discrimination of esterase and peptidase activities of acylaminoacyl peptidase from hyperthermophilic Aeropyrum pernix K1 by a single mutation

It has been shown that highly conserved residues that form crucial structural elements of the catalytic apparatus may be used to account for the evolutionary history of enzymes. Using saturation mutagenesis, we investigated the role of a conserved residue (Arg(526)) at the active site of acylaminoacyl peptidase from hyperthermophilic Aeropyrum pernix K1 in substrate discrimination and catalytic mechanism. This enzyme has both peptidase and esterase activities. The esterase activity of the wild-type enzyme with p-nitrophenyl caprylate as substrate is approximately 7 times higher than the peptidase activity with Ac-Leu-p-nitroanilide as substrate. However, with the same substrates, this difference was increased to approximately 150-fold for mutant R526V. A more dramatic effect occurred with mutant R526E, which essentially completely abolished the peptidase activity but decreased the esterase activity only by a factor of 2, leading to a 785-fold difference in the enzyme activities. These results provide rare examples that illustrate how enzymes can be evolved to discriminate their substrates by a single mutation. The possible structural and energetic effects of the mutations on k(cat) and K(m) of the enzyme were discussed based on molecular dynamics simulation studies.     

Kinetic and structural studies of specific protein-protein interactions in substrate catalysis by Cdc25B phosphatase

Using a combination of steady-state and single-turnover kinetics, we probe substrate association, dissociation, and chemistry for the reaction of Cdc25B phosphatase with its Cdk2-pTpY/CycA protein substrate. The rate constant for substrate association for the wild-type enzyme is 1.3 x 10(6) M(-1) s(-1). The rate constant for dissociation is slow compared to the rate constant for phosphate transfer to form the phospho-enzyme intermediate (k2 = 1.1 s(-1)), making Cdk2-pTpY/CycA a sticky substrate. Compared to the wild type, all hotspot mutants of residues at the remote docking site that specifically affect catalysis with the protein substrate (Arg488, Arg492, and Tyr497 on Cdc25B and Asp206 on Cdk2) have greatly slowed rate constants of association (70- to 4500-fold), and some mutants have decreased k2 values compared to that of the wild type. Most dramatically, R492L, despite showing no significant changes in a crystal structure at 2.0 A resolution, has an approximately 100-fold decrease in k2 compared to that of wild-type Cdc25B. The active site C473S mutant binds tightly to and dissociates slowly from Cdk2-pTpY/CycA (Kd = 10 nM, k(off) = 0.01 s(-1)). In contrast, the C473D mutant, despite showing only localized perturbations in the active site at 1.6 A resolution, has a much weaker affinity and dissociates rapidly (Kd of 2 microM, k(off) > 2 s(-1)) from the protein substrate. Overall, we demonstrate that the association of Cdc25B with its Cdk2-pTpY/CycA substrate is governed to a significant extent by the interactions of the remote hotspot residues, whereas dissociation is governed by interactions at the active site.     

Conserved amino acid residues in ribosome-inactivating proteins from plants.

The amino acid sequences of eleven RIPs sequenced to date have been compared in the expectation that this would be useful in the location of functionally and/or structurally important sites of these molecules. In addition to several highly conserved hydrophobic amino acids, thirteen absolutely conserved residues have been found in ricin A-chain: Tyr21, Phe24, Arg29, Tyr80, Tyr123, Gly140, Ala165, Glu177, Ala178, Arg180, Glu208, Asn209 and Trp211. The role of these residues as well as of the C-terminal region have been discussed based on the results of chemical and enzymatic modifications, site-directed mutagenesis, and deletion studies.     

A structural factor responsible for substrate recognition by Bacillus sp. GL1 xanthan lyase that acts specifically on pyruvated side chains of xanthan

Xanthan is a bacterial heteropolysaccharide composed of pentasaccharide repeating units, i.e., a cellobiose as a backbone and a trisaccharide consisting of two mannoses and one glucuronic acid as a side chain. Nonreducing terminal mannose residues of xanthan side chains are partially pyruvated. Bacillus sp. GL1 xanthan lyase, a member of polysaccharide lyase family 8, acts specifically on pyruvated side chains of xanthan and yields pyruvated mannose through a beta-elimination reaction by using a single Tyr255 residue as base and acid catalysts. Here we show structural factors for substrate recognition by xanthan lyase through X-ray crystallographic and mutational analyses. The enzyme accommodates mannose and pyruvated mannose at the -1 subsite, although both inhibitor and dissociation constants of the two monosaccharides indicated that the affinity of pyruvated mannose for xanthan lyase is much higher than that of mannose. The high affinity of pyruvated mannose is probably due to the formation of additional hydrogen bonds between the carboxyl group of pyruvated mannose and amino acid residues of Tyr315 and Arg612. Site-directed mutagenesis of the two residues demonstrated that Arg612 is a key residue in recognizing pyruvated mannose. Arg612 is located in the protruding loop covering the substrate, suggesting that the loop functions as a lid that is responsible for the proper accommodation of the substrate at the active site.     

Structural and kinetic bases for the recognition of tRNATyr by tyrosyl-tRNA synthetase

The aminoacylation of transfer RNA is a key step of translation since it relates amino acids to anticodons. To understand how the tyrosyl-tRNA synthetase (TyrTS) from Bacillus stearothermophilus recognizes tRNA(Tyr), we constructed 14 new mutant TyrTS by site-directed mutagenesis, determined their kinetic properties and used these and previous data to construct a detailed structural model of the complex between TyrTS and the acceptor arm of tRNA(Tyr). In the model Arg207, Lys208, Asn 146 and Glu 152 interact with phosphate groups. A contact between guanine 1 and Trp 196 is unspecific. Adenine 73, the fourth base from the 3' end, is specifically recognized through Trp 196 and the main-chain carbonyl of Ala150. At the active site, adenine 76 might interact with Lys82 and Arg86. There is a tight complementarity in shape between the tRNA and the synthetase. TyrTS and tRNA(Tyr) form an additional contact, in the vicinity of adenine 73, when their complex goes from the initial state to the transition state. The rate of aminoacylation, through the precise recognition of adenine 73, could thus be an important factor of discrimination by TyrTS among tRNAs.