Biochemical characterization of recombinant acetyl xylan esterase from Aspergillus awamori expressed in Pichia pastoris: mutational analysis of catalytic residues

We engineered an acetyl xylan esterase (AwaxeA) gene from Aspergillus awamori into a heterologous expression system in Pichia pastoris. Purified recombinant AwAXEA (rAwAXEA) displayed the greatest hydrolytic activity toward alpha-naphthylacetate (C2), lower activity toward alpha-naphthylpropionate (C3) and no detectable activity toward acyl-chain substrates containing four or more carbon atoms. Putative catalytic residues, Ser(119), Ser(146), Asp(168) and Asp(202), were substituted for alanine by site-directed mutagenesis. The biochemical properties and kinetic parameters of the four mutant enzymes were examined. The S119A and D202A mutant enzymes were catalytically inactive, whereas S146A and D168A mutants displayed significant hydrolytic activity. These observations indicate that Ser(119) and Asp(202) are important for catalysis. The S146A mutant enzyme showed lower specific activity toward the C2 substrate and higher thermal stability than wild-type enzyme. The lower activity of S146A was due to a combination of increased K(m) and decreased k(cat). The catalytic efficiency of S146A was 41% lower than that of wild-type enzyme. The synthesis of ethyl acetate was >10-fold than that of ethyl n-hexanoate synthesis for the wild-type, S146A and D168A mutant enzymes. However, the D202A showed greater synthetic activity of ethyl n-hexanoate as compared with the wild-type and other mutants.     

Site-directed mutagenesis of the phosphorylatable serine (Ser8) in C4 phosphoenolpyruvate carboxylase from sorghum. The effect of negative charge at position 8.

The properties of the dephospho and in vitro phosphorylated forms of recombinant sorghum phosphoenolpyruvate carboxylase have been compared with those of the authentic dark (dephospho) and light (phospho) leaf enzyme forms and two mutant enzymes in which the phosphorylatable serine residue (Ser8) has been changed by site-directed mutagenesis to Cys (S8C) or Asp (S8D). Kinetic analysis of the purified recombinant, mutant, and leaf enzyme forms at pH 8.0 indicated virtually identical Vmax, apparent Km (phosphoenolpyruvate), and half-maximal activation (glucose 6-P) values of about 44 units/mg, 1.1 mM, and 0.23 mM, respectively. In contrast, the Ser8, S8C, and dark leaf enzymes were about 3-fold more sensitive to inhibition by L-malate at pH 7.3 than the Ser8-P, S8D, and light leaf enzyme forms. These comparative results indicate that: (i) Ser8 is an important determinant in the regulation of sorghum phosphoenolpyruvate carboxylase activity by negative (L-malate), but not positive (glucose 6-phosphate) metabolite effectors, (ii) phosphorylation of this target residue can be functionally mimicked by Asp, but not Cys, and (iii) negative charge contributes to the effect of regulatory phosphorylation on this C4-photosynthesis enzyme.     

Analyzing the catalytic mechanism of protein tyrosine phosphatase PtpB from Staphylococcus aureus through site-directed mutagenesis

Protein tyrosine phosphatase B (PtpB) from Staphylococcus aureus, MRSA 252, is a low molecular weight protein tyrosine phosphatase involved in its pathogenicity. PtpB has been modeled in silico and site-directed mutagenesis performed to ascertain the importance of active site residues Cys8, Arg14, Ser15 and Asp120 in its catalytic mechanism. Kinetic characterization of wild-type and the mutant PtpBs, C8S, R14A, S15T, S15A, D120A, D120E, D120N revealed the reaction mechanism followed by this LMWPTPase. The mutations caused major changes in the local environment resulting in significant decrease of its catalytic activity. Inhibition kinetics for the wild-type enzyme was performed with maleimide and maleimidobutyric acid.     

Function of disulflde bond Cys45-Cys50 of prochymosin

The conditions (temperature, time, pH) for solubilizing inclusion bodies of prochymosin mutant, Cys45Asp/Cys50Ser, are identical with those for the wild type. Moreover, they have similar oxidative refolding behavior. Under the same renaturation conditions both of them can undergo correct refolding leading to the formation of activable molecules. This is quite different from the mutant with deletion of Cys250-Cys283, indicating that Cys45-Cys50 contributes less to the correct refolding of prochymosin than Cys250- Cys283. However, deletion of Cys45-Cys50 results in a remarkable decrease of the thermostability of pseudochymosin, suggesting that this disulfide bond plays an important role in stabilizing enzyme conformation. The proteolytic (P) and milk-dotting (C) activities of the mutant of pseudochymosin, Cys45Asp/Cys50Ser, are lower than those of its wild counterpart. The C/P ratio of the former is onefold higher than that of the latter.     

A mutagenic study of beta-1,4-galactosyltransferases from Neisseria meningitidis

N-terminal His-tagged recombinant beta-1,4-galactosyltransferase from Neisseria meningitidis was expressed and purified to homogeneity by column chromatography using Ni-NTA resin. Mutations were introduced to investigate the roles of, Ser68, His69, Glu88, Asp90, and Tyr156, which are components of a highly conserved region in recombinant beta-1,4 galactosyltransferase. Also, the functions of three other cysteine residues, Cys65, Cys139, and Cys205, were investigated using site-directed mutagenesis to determine the location of the disulfide bond and the role of the sulfhydryl groups. Purified mutant galactosyltransferases, His69Phe, Glu88Gln and Asp90Asn completely shut down wild-type galactosyltransferase activity (1-3 %). Also, Ser68Ala showed much lower activity than wild-type galactosyltransferase (19 %). However, only the substitution of Tyr156Phe resulted in a slight reduction in galactosyltransferase activity (90 %). The enzyme was found to remain active when the cysteine residues at positions 139 and 205 were replaced separately with serine. However, enzyme reactivity was found to be markedly reduced when Cys65 was replaced with serine (27 %). These results indicate that conserved amino acids such as Cys65, Ser68, His69, Glu88, and Asp90 may be involved in the binding of substrates or in the catalysis of the galactosyltransferase reaction.     

Structural consequences of the active site substitution Cys181 ==> Ser in metallo-beta-lactamase from Bacteroides fragilis

The metallo-beta-lactamases require divalent cations such as zinc or cadmium for hydrolyzing the amide bond of beta-lactam antibiotics. The crystal structure of the Zn2+ -bound enzyme from Bacteroides fragilis contains a binuclear zinc center in the active site. A hydroxide, coordinated to both zinc atoms, is proposed as the moiety that mounts the nucleophilic attack on the carbonyl carbon atom of the beta-lactam bond of the substrate. It was previously reported that the replacement of the active site Cys181 by a serine residue severely impaired catalysis while atomic absorption measurements indicated that binding of the two zinc ions remained intact. Contradicting data emerge from recent mass spectrometry results, which show that only a single zinc ion binds to the C181S metallo-beta-lactamase. In the current study, the C181S mutant enzyme was examined at the atomic level by determining the crystal structure at 2.6 A resolution. The overall structure of the mutant enzyme is the same as that of the wild-type enzyme. At the mutation site, the side chain of Ser181 occupies the same position as that of the side chain of Cys181 in the wild-type protein. One zinc ion, Zn1, is present in the crystal structure; however, the site of the second zinc ion, Zn2 is unoccupied. A water molecule is associated with Zn1, reminiscent of the hydroxide seen in the structure of the wild-type enzyme but farther from the metal. The position of the water molecule is off the plane of the carboxylate group of Asp103; therefore, the water molecule may be less nucleophilic than a water molecule which is coplanar with the carboxylate group.     

A theoretical study of the active sites of papain and S195C rat trypsin: implications for the low reactivity of mutant serine proteinases.

The serine and cysteine proteinases represent two important classes of enzymes that use a catalytic triad to hydrolyze peptides and esters. The active site of the serine proteinases consists of three key residues, Asp...His...Ser. The hydroxyl group of serine functions as a nucleophile and the imidazole ring of histidine functions as a general acid/general base during catalysis. Similarly, the active site of the cysteine proteinases also involves three key residues: Asn, His, and Cys. The active site of the cysteine proteinases is generally believed to exist as a zwitterion (Asn...His+...Cys-) with the thiolate anion of the cysteine functioning as a nucleophile during the initial stages of catalysis. Curiously, the mutant serine proteinases, thiol subtilisin and thiol trypsin, which have the hybrid Asp...His...Cys triad, are almost catalytically inert. In this study, ab initio Hartree-Fock calculations have been performed on the active sites of papain and the mutant serine proteinase S195C rat trypsin. These calculations predict that the active site of papain exists predominately as a zwitterion (Cys-...His+...Asn). However, similar calculations on S195C rat trypsin demonstrate that the thiol mutant is unable to form a reactive thiolate anion prior to catalysis. Furthermore, structural comparisons between native papain and S195C rat trypsin have demonstrated that the spatial juxtapositions of the triad residues have been inverted in the serine and cysteine proteinases and, on this basis, I argue that it is impossible to convert a serine proteinase to a cysteine proteinase by site-directed mutagenesis.     

Identification and characterization of the functional amino acids at the active center of pig liver thioltransferase by site-directed mutagenesis

By using site-directed mutagenesis techniques, the essential amino acids at the catalytic center of porcine thioltransferase (glutaredoxin) were determined. Seven oligonucleotides were designed, synthesized, and used to construct mutants, ETT-C22S, ETT-C25S, ETT-C25A, ETT-R26V, ETT-K27Q, ETT-R26V: K27Q, and ETT-C78S:C82S, by altering their codons in pig liver thioltransferase cDNA/M13mp18 clones. Each of the thioltransferases was purified to homogeneity and its dithiol-disulfide exchange, and dehydroascorbate reductase activities were compared with those of the wild-type (ETT). Evidence was obtained that Cys22 was essential for catalytic activity, and the extremely low pKa value of its sulfhydryl group was facilitated primarily by Arg26. The role of Lys27 at the active center was different from that of Arg26 and may be important in stabilizing the E.S intermediate by electrostatic forces. The second pair of cysteines, Cys78 and Cys82, nearer the C terminus, were not directly involved in the active center, but may play a role in defining the native protein structure. The replacement of the original Cys with a Ser at position 25 increased rather than decreased the enzyme activity, suggesting that the proposed intramolecular disulfide bond between Cys22 and Cys25 is not necessary for the catalytic mechanism of the Ser25 mutant, but does not rule out such a mechanism for the wild-type enzyme.     

Identification of the cysteine residue exposed by the conformational change in pig heart succinyl-CoA:3-ketoacid coenzyme A transferase on binding coenzyme A

Succinyl-CoA:3-ketoacid CoA transferase (SCOT) transfers CoA from succinyl-CoA to acetoacetate via a thioester intermediate with its active site glutamate residue, Glu 305. When CoA is linked to the enzyme, a cysteine residue can now be rapidly modified by 5,5'-dithiobis(2-nitrobenzoic acid), reflecting a conformational change of SCOT upon formation of the thioester. Since either Cys 28 or Cys 196 could be the target, each was mutated to Ser to distinguish between them. Like wild-type SCOT, the C196S mutant protein was modified rapidly in the presence of acyl-CoA substrates. In contrast, the C28S mutant protein was modified much more slowly under identical conditions, indicating that Cys 28 is the residue exposed on binding CoA. The specific activity of the C28S mutant protein was unexpectedly lower than that of wild-type SCOT. X-ray crystallography revealed that Ser adopts a different conformation than the native Cys. A chloride ion is bound to one of four active sites in the crystal structure of the C28S mutant protein, mimicking substrate, interacting with Lys 329, Asn 51, and Asn 52. On the basis of these results and the studies of the structurally similar CoA transferase from Escherichia coli, YdiF, bound to CoA, the conformational change in SCOT was deduced to be a domain rotation of 17 degrees coupled with movement of two loops: residues 321-329 that bury Cys 28 and interact with succinate or acetoacetate and residues 374-386 that interact with CoA. Modeling this conformational change has led to the proposal of a new mechanism for catalysis by SCOT.     

Functional implication of disulfide bond, Cys250 -Cys283, in bovine chymosin.

The reduction, carboxymethylation and mercuration of disulfide bond, Cys250-Cys283, located on the surface of bovine chymosin molecule resulted in the loss of about 25% of enzyme activity, suggesting that Cys250-Cys283 is not intimately involved in catalytic mechanism. Cys250 and Cys283 were substituted with Asp. and Ser. by site- directed mutagenesis of the structural gene coding for bovine prochymosin B. All three mutants (C250D/C283S, C250D, C283S) failed to be activated to chymosin in acid, indicating that Cys250-Cys283 might have some contribution to the correct refolding of the unfolded prochymosin.     

3C-like proteinase from SARS coronavirus catalyzes substrate hydrolysis by a general base mechanism

SARS 3C-like proteinase has been proposed to be a key enzyme for drug design against SARS. Lack of a suitable assay has been a major hindrance for enzyme kinetic studies and a large-scale inhibitor screen for SARS 3CL proteinase. Since SARS 3CL proteinase belongs to the cysteine protease family (family C3 in clan CB) with a chymotrypsin fold, it is important to understand the catalytic mechanism of SARS 3CL proteinase to determine whether the proteolysis proceeds through a general base catalysis mechanism like chymotrypsin or an ion pair mechanism like papain. We have established a continuous colorimetric assay for SARS 3CL proteinase and applied it to study the enzyme catalytic mechanism. The proposed catalytic residues His41 and Cys145 were confirmed to be critical for catalysis by mutating to Ala, while the Cys145 to Ser mutation resulted in an active enzyme with a 40-fold lower activity. From the pH dependency of catalytic activity, the pK(a)'s for His41 and Cys145 in the wild-type enzyme were estimated to be 6.38 and 8.34, while the pK(a)'s for His41 and Ser145 in the C145S mutant were estimated to be 6.15 and 9.09, respectively. The C145S mutant has a normal isotope effect in D(2)O for general base catalysis, that is, reacts slower in D(2)O, while the wild-type enzyme shows an inverse isotope effect which may come from the lower activation enthalpy. The pK(a) values measured for the active site residues and the activity of the C145S mutant are consistent with a general base catalysis mechanism and cannot be explained by a thiolate-imidazolium ion pair model.     

Role of disulphide bonds in a thermophilic serine protease aqualysin I from Thermus aquaticus YT-1

A thermophilic serine protease, Aqualysin I, from Thermus aquaticus YT-1 has two disulphide bonds, which are also found in a psychrophilic serine protease from Vibrio sp. PA-44 and a proteinase K-like enzyme from Serratia sp. at corresponding positions. To understand the significance of these disulphide bonds in aqualysin I, we prepared mutants C99S, C194S and C99S/C194S (WSS), in which Cys69-Cys99, Cys163-Cys194 and both of these disulphide bonds, respectively, were disrupted by replacing Cys residues with Ser residues. All mutants were expressed stably in Escherichia coli. The C99S mutant was 68% as active as the wild-type enzyme at 40 degrees C in terms of k(cat) value, while C194S and WSS were only 6 and 3%, respectively, as active, indicating that disulphide bond Cys163-Cys194 is critically important for maintaining proper catalytic site conformation. Mutants C194S and WSS were less thermostable than wild-type enzyme, with a half-life at 90 degrees C of 10 min as compared to 45 min of the latter and with transition temperatures on differential scanning calorimetry of 86.7 degrees C and 86.9 degrees C, respectively. Mutant C99S was almost as stable as the wild-type aqualysin I. These results indicate that the disulphide bond Cys163-Cys194 is more important for catalytic activity and conformational stability of aqualysin I than Cys67-Cys99.     

枯草蛋白酶E的突变体

Ser236位于横贯枯草蛋白酶E的α螺旋末端,远离催化活性中心,Ser236的突变不会对酶的活性产生大的影响。用定点突变的方法对枯草蛋白酶E的基因进行改造引入Ser236Cys,可能会形成分子间二硫键,有利于提高酶的稳定性。Ser236Cys变体酶(BP1)活性是野生型蛋白酶E的15倍,热稳定性提高3倍;进一步在其他位点引入突变的变体酶BU1(A1a15Asp/Gly20His/Ser236Cys)和BW1(Ser24His/Lys27Asp/Ser236Cys)活性都比野生型蛋白酶E低,但BW1的稳定性稍高于野生型蛋白酶E。     

Functional conservation in the putative substrate binding site of the sucrose permease from Escherichia coli

The sucrose (CscB) permease is the only member of the oligosaccharide:H(+) symporter family in the Major Facilitator Superfamily that transports sucrose but not lactose or other galactosides. In lactose permease (lac permease), the most studied member of the family, three residues have been shown to participate in galactoside binding: Cys148 hydrophobically interacts with the galactosyl ring, while Glu126 and Arg144 are charge paired and form H-bonds with specific galactosyl OH groups. In the present study, the role of the corresponding residues in sucrose permease, Asp126, Arg144, and Ser148, is investigated using a functional Cys-less mutant (see preceding paper). Replacement of Ser148 with Cys has no significant effect on transport activity or expression, but transport becomes highly sensitive to the sulfhydryl reagent N-ethylmaleimide (NEM) in a manner similar to that of lac permease. However, in contrast to lac permease, substrate affords no protection whatsoever against NEM inactivation of transport or alkylation with [(14)C]NEM. Neutral (Ala, Cys) mutations of Asp126 and Arg144 abolish sucrose transport, while membrane expression is not affected. Similarly, combination of two Ala mutations within the same molecule (Asp126-->Ala/Arg144-->Ala) yields normally expressed, but completely inactive permease. Conservative replacements result in highly active molecules: Asp126-->Glu permease catalyzes sucrose transport comparable to Cys-less permease, while mutant Arg144-->Lys exhibits decreased but significant activity. The observations demonstrate that charge pair Asp126-Arg144 plays an essential role in sucrose transport and suggest that the overall architecture of the substrate binding sites is conserved between sucrose and lac permeases.     

Kinetic properties and metal content of the metallo-beta-lactamase CcrA harboring selective amino acid substitutions.

The crystal structure of the metallo-beta-lactamase CcrA3 indicates that the active site of this enzyme contains a binuclear zinc center. To aid in assessing the involvement of specific residues in beta-lactam hydrolysis and susceptibility to inhibitors, individual substitutions of selected amino acids were generated. Substitution of the zinc-ligating residue Cys181 with Ser (C181S) resulted in a significant reduction in hydrolytic activity; kcat values decreased 2-4 orders of magnitude for all substrates. Replacement of His99 with Asn (H99N) significantly reduced the hydrolytic activity for penicillin and imipenem. Replacement of Asp103 with Asn (D103N) showed reduced hydrolytic activity for cephaloridine and imipenem. Deletion of amino acids 46-51 dramatically reduced both the hydrolytic activity and affinity for all beta-lactams. The metal binding capacity of each mutant enzyme was examined using nondenaturing electrospray ionization mass spectrometry. Two zinc ions were observed for the wild-type enzyme and most of the mutant enzymes. However, for the H99N, C181S, and D103N enzymes, three different zinc content patterns were observed. These enzymes contained two zinc molecules, one zinc molecule, and a mixture of one or two zinc molecules/enzyme molecule, respectively. Two enzymes with substitutions of Cys104 or Cys104 and Cys155 were also composed of mixed enzyme populations.     

Characterization of catalytic centre mutants of macrophage migration inhibitory factor (MIF) and comparison to Cys81Ser MIF.

Macrophage migration inhibitory factor (MIF) displays both cytokine and enzyme activities, but its molecular mode of action is still unclear. MIF contains three cysteine residues and we showed recently that the conserved Cys57-Ala-Leu-Cys60 (CALC) motif is critical for the oxidoreductase and macrophage-activating activities of MIF. Here we probed further the role of this catalytic centre by expression, purification, and characterization of the cysteine-->serine mutants Cys60Ser, Cys57Ser/Cys60Ser, and Cys81Ser of human MIF and of mutants Ala58Gly/Leu59Pro and Ala58Gly/Leu59His, containing a thioredoxin (Trx)-like and protein disulphide isomerase (PDI)-like dipeptide, respectively. The catalytic centre mutants formed inclusion bodies and the resultant mutant proteins Cys57Ser/Cys60Ser, Ala58Gly/Leu59Pro, and Als58Gly/Leu59His were only soluble in organic solvent or 6 m GdmHCl when reconstituted at concentrations above 1 microgram.mL-1. This made it necessary to devise new purification methods. By contrast, mutant Cys81Ser was soluble. Effects of pH, solvent, and ionic strength conditions on the conformation of the mutants were analysed by far-UV CD spectropolarimetry and mutant stability was examined by denaturant-induced unfolding. The mutants, except for mutant Cys81Ser, showed a close conformational similarity to wild-type (wt) MIF, and stabilization of the mutants was due mainly to acid pH conditions. Intramolecular disulphide bond formation at the CALC region was confirmed by near-UV CD of mutant Cys60Ser. Mutant Cys81Ser was not involved in disulphide bond formation, yet had decreased stability. Analysis in the oxidoreductase and a MIF-specific cytokine assay revealed that only substitution of the active site residues led to inactivation of MIF. Mutant Cys60Ser had no enzyme and markedly reduced cytokine activity, whereas mutant Cys81Ser was active in both tests. The Trx-like variant showed significant enzyme activity but was less active than wtMIF; PDI-like MIF was enzymatically inactive. However, both variants had full cytokine activity. Together with the low but nonzero cytokine activity of mutant Cys60Ser, this indicated that the cytokine activity of MIF may not be tightly regulated by redox effects or that a distinguishable receptor mechanism exists. This study provides evidence for a role of the CALC motif in the oxidoreductase and cytokine activities of MIF, and suggests that Cys81 could mediate conformational effects. Availability and characterization of the mutants should greatly aid in the further elucidation of the mechanism of action of the unusual cytokine MIF.     

Mutational evidence of transition state stabilization by serine 88 in Escherichia coli type I signal peptidase

Type I signal peptidase (SPase I) catalyzes the hydrolytic cleavage of the N-terminal signal peptide from translocated preproteins. SPase I belongs to a novel class of Ser proteases that utilize a Ser/Lys dyad catalytic mechanism instead of the classical Ser/His/Asp triad found in most Ser proteases. Recent X-ray crystallographic studies indicate that the backbone amide nitrogen of the catalytic Ser 90 and the hydroxyl side chain of Ser 88 might participate as H-bond donors in the transition-state oxyanion hole. In this work, contribution of the side-chain Ser 88 in Escherichia coli SPase I to the stabilization of the transition state was investigated through in vivo and in vitro characterizations of Ala-, Cys-, and Thr-substituted mutants. The S88T mutant maintains near-wild-type activity with the substrate pro-OmpA nuclease A. In contrast, substitution with Cys at position 88 results in more than a 740-fold reduction in activity (k(cat)) whereas S88A retains much less activity (>2440-fold decrease). Measurements of the kinetic constants of the individual mutant enzymes indicate that these decreases in activity are attributed mainly to decreases in k(cat) while effects on K(m) are minimal. Thermal inactivation and CD spectroscopic analyses indicate no global conformational perturbations of the Ser 88 mutants relative to the wild-type E. coli SPase I enzyme. These results provide strong evidence for the stabilization by Ser 88 of the oxyanion intermediate during catalysis by E. coli SPase I.     

Site-directed mutagenesis of the Streptomyces R61 DD-peptidase. Catalytic function of the conserved residues around the active site and a comparison with class-A and class-C beta-lactamases.

The importance of various residues in the Streptomyces R61 penicillin-sensitive DD-peptidase has been assessed by site-directed mutagenesis. The replacement of the active Ser62 by a Cys residue yielded an inactive protein which was also unable to recognize penicillin. The activity of the Lys65----Arg mutant with the peptide and thiolester substrates was decreased 100-200-fold and the rate of penicillin inactivation was decreased 20,000-fold or more. The mutant thus behaved as a poor, but penicillin-resistant, DD-peptidase. The other studied mutations, the mutations Phe58----Leu, Tyr90----Asn, Thr101----Asn, Phe164----Ala, Asp225----Glu and Asp225----Asn had little influence on the catalytic and penicillin-binding properties. The Asp225 mutants did not exhibit an increased sensitivity to cefotaxime. The Phe164----Ala mutant was significantly more unstable than the wild-type enzyme.     

Crystal structures of aconitase with isocitrate and nitroisocitrate bound.

The crystal structures of mitochondrial aconitase with isocitrate and nitroisocitrate bound have been solved and refined to R factors of 0.179 and 0.161, respectively, for all observed data in the range 8.0-2.1 A. Porcine heart enzyme was used for determining the structure with isocitrate bound. The presence of isocitrate in the crystals was corroborated by M?ssbauer spectroscopy. Bovine heart enzyme was used for determining the structure with the reaction intermediate analogue nitroisocitrate bound. The inhibitor binds to the enzyme in a manner virtually identical to that of isocitrate. Both compounds bind to the unique Fe atom of the [4Fe-4S] cluster via a hydroxyl oxygen and one carboxyl oxygen. A H2O molecule is also bound, making Fe six-coordinate. The unique Fe is pulled away approximately 0.2 A from the corner of the cubane compared to the position it would occupy in a symmetrically ligated [4Fe-4S] cluster. At least 23 residues from all four domains of aconitase contribute to the active site. These residues participate in substrate recognition (Arg447, Arg452, Arg580, Arg644, Gln72, Ser166, Ser643), cluster ligation and interaction (Cys358, Cys421, Cys424, Asn258, Asn446), and hydrogen bonds supporting active site side chains (Ala74, Asp568, Ser571, Thr567). Residues implicated in catalysis are Ser642 and three histidine-carboxylate pairs (Asp100-His101, Asp165-His147, Glu262-His167). The base necessary for proton abstraction from C beta of isocitrate appears to be Ser642; the O gamma atom is proximal to the calculated hydrogen position, while the environment of O gamma suggests stabilization of an alkoxide (an oxyanion hole formed by the amide and side chain of Arg644). The histidine-carboxylate pairs appear to be required for proton transfer reactions involving two oxygens bound to Fe, one derived from solvent (bound H2O) and one derived from substrate hydroxyl. Each oxygen is in contact with a histidine, and both are in contact with the side chain of Asp165, which bridges the two sites on the six-coordinate Fe.     

Ser(214) is crucial for substrate binding to serine proteases

Highly conserved amino acids that form crucial structural elements of the catalytic apparatus can be used to account for the evolutionary history of serine proteases and the cascades into which they are organized. One such evolutionary marker in chymotrypsin-like proteases is Ser(214), located adjacent to the active site and forming part of the primary specificity pocket. Here we report the mutation of Ser(214) in thrombin to Ala, Thr, Cys, Asp, Glu, and Lys. None of the mutants seriously compromises active site catalytic function as measured by the kinetic parameter k(cat). However, the least conservative mutations result in large increases in K(m) because of lower rates of substrate diffusion into the active site. Therefore, the role of Ser(214) is to promote the productive formation of the enzyme-substrate complex. The S214C mutant is catalytically inactive, which suggests that during evolution the TCN-->AGY codon transitions for Ser(214) occurred through Thr intermediates.