Kinetic and hydrodynamic studies of the NodL O-acetyl transferase of Rhizobium leguminosarum: a random-order ternary complex mechanism for acetyl transfer by a roughly spherical trimeric protein.

The nodL gene product of Rhizobium leguminosarum is required for O-acetylation of diffusible lipo-oligosaccharide signalling factors which are involved in the host-specific nodulation of legume roots. Kinetic studies of the forward reaction, using the substrate analogues chitosan pentaose and chitosan tetraose and the acyl donors acetyl-CoA and propionyl-CoA, and the dead-end inhibitor EtCoA are consistent with a steady-state random-order ternary complex mechanism in which the off rate of the O-acetyl chitosan oligomer appears to be partially rate-determining. Moreover, the linearity of primary double-reciprocal plots favours the view that the interconversion of the ternary complex of NodL and its substrates with that of enzyme and bound products is not significantly faster than k(cat). Dissociation constants for coenzyme A and acetyl-CoA were determined by titration microcalorimetry to be 16.5 and 7.2 microM respectively, the latter in agreement with the kinetically derived value of 7.0 microM. The physical state of purified NodL, as determined by equilibrium centrifugation, velocity sedimentation and quasi-elastic light scattering, is that of a roughly spherical, trimeric protein with little tendency to self-associate.

Serine acetyltransferase from Escherichia coli is a dimer of trimers.

Equilibrium sedimentation studies show that the serine acetyltransferase (SAT) of Escherichia coli is a hexamer. The results of velocity sedimentation and quasi-elastic light scattering experiments suggest that the identical subunits are loosely packed and/or arranged in an ellipsoidal fashion. Chemical cross-linking studies indicate that the fundamental unit of quaternary structure is a trimer. The likelihood, therefore, is that in solution SAT exists as an open arrangement of paired trimers. Crystals of SAT have 32 symmetry, consistent with such an arrangement, and the cell density function is that expected for a hexamer. Electron microscopy with negative staining provides further evidence that SAT has an ellipsoidal subunit organization, the dimensions of the particles consistent with the proposed paired trimeric subunit arrangement. A bead model analysis supports the view that SAT has a low packing density and, furthermore, indicates that the monomers may have an ellipsoidal shape. Such a view is in keeping with the ellipsoidal subunit shape of trimeric LpxA, an acyltransferase with which SAT shares contiguous repeats of a hexapeptide motif.

Purification and characterization of phosphopantetheine adenylyltransferase from Escherichia coli.

Phosphopantetheine adenylyltransferase (PPAT) catalyzes the penultimate step in coenzyme A (CoA) biosynthesis: the reversible adenylation of 4'-phosphopantetheine yielding 3'-dephospho-CoA and pyrophosphate. Wild-type PPAT from Escherichia coli was purified to homogeneity. N-terminal sequence analysis revealed that the enzyme is encoded by a gene designated kdtB, purported to encode a protein involved in lipopolysaccharide core biosynthesis. The gene, here renamed coaD, is found in a wide range of microorganisms, indicating that it plays a key role in the synthesis of 3'-dephospho-CoA. Overexpression of coaD yielded highly purified recombinant PPAT, which is a homohexamer of 108 kDa. Not less than 50% of the purified enzyme was found to be associated with CoA, and a method was developed for its removal. A steady state kinetic analysis of the reverse reaction revealed that the mechanism of PPAT involves a ternary complex of enzyme and substrates. Since purified PPAT lacks dephospho-CoA kinase activity, the two final steps of CoA biosynthesis in E. coli must be catalyzed by separate enzymes.

Missense translation errors in Saccharomyces cerevisiae.

We describe the development of a novel plasmid-based assay for measuring the in vivo frequency of misincorporation of amino acids into polypeptide chains in the yeast Saccharomyces cerevisiae. The assay is based upon the measurement of the catalytic activity of an active site mutant of type III chloramphenicol acetyl transferase (CATIII) expressed in S. cerevisiae. A His195(CAC)-->Tyr195(UAC) mutant of CATIII is completely inactive, but catalytic activity can be restored by misincorporation of histidine at the mutant UAC codon. The average error frequency of misincorporation of histidine at this tyrosine UAC codon in wild-type yeast strains was measured as 0. 5x10(-5) and this frequency was increased some 50-fold by growth in the presence of paromomycin, a known translational-error-inducing antibiotic. A detectable frequency of misincorporation of histidine at a mutant Ala195 GCU codon was also measured as 2x10(-5), but in contrast to the Tyr195-->His195 misincorporation event, the frequency of histidine misincorporation at Ala195 GCU was not increased by paromomycin, inferring that this error did not result from miscognate codon-anticodon interaction. The His195 to Tyr195 missense error assay was used to demonstrate increased frequencies of missense error at codon 195 in SUP44 and SUP46 mutants. These two mutants have previously been shown to exhibit a translation termination error phenotype and the sup44+ and sup46+ genes encode the yeast ribosomal proteins S4 and S9, respectively. These data represent the first accurate in vivo measurement of a specific mistranslation event in a eukaryotic cell and directly confirm that the eukaryotic ribosome plays an important role in controlling missense errors arising from non-cognate codon-anticodon interactions.

The conformation of coenzyme A bound to chloramphenicol acetyltransferase determined by transferred NOE experiments.

The conformation of coenzyme A bound to chloramphenicol acetyltransferase has been studied in solution by NMR methods. Transferred nuclear Overhauser enhancement (NOE) and rotating frame NOE (ROE) experiments were used to determine the conformation of the bound coenzyme. Experiments were carried out at five mixing times and two temperatures, and with normal and perdeuterated enzyme, to ensure (1) that the fast exchange condition was satisfied and (2) that the results were not complicated by spin diffusion involving enzyme protons. The data were analysed using a general approach involving combined exchange and relaxation matrices. For the binary complex of coenzyme A (CoA) and enzyme, the conformation of CoA was calculated by using distance constraints derived from the intensities of 71 NOE and 33 ROE cross-peaks between coenzyme protons. The conformation of the adenosine moiety of CoA in the structure deduced by NMR is very close to that seen in the crystal structure of this complex, while the pantetheine moiety is clearly less extended. Essentially the same conformation was obtained whether or not the calculations included the protein (with appropriate intermolecular energy terms). The difference between the NMR and X-ray structures is interpreted in terms of the existence of two conformations of the CoA-enzyme complex. Support for this model comes from measurements of the coenzyme dissociation rate constant; NMR (lineshape analysis and transferred NOE experiments) gives estimates of koff approximately 3700 s-1 at 298 K and approximately 500 s-1 at 280 K, both significantly greater than estimates by fluorescence stopped-flow measurements. For the ternary complex of CoA, chloramphenicol and enzyme, 71 NOE cross peaks between protons of coenzyme A and a further ten cross-peaks between protons of coenzyme A and chloramphenicol were measured. Starting with a model derived from the crystal structures of the two binary complexes (in the absence of crystallographic data for the ternary complex) the conformations and relative positions of the two ligands were refined using the distance constraints derived from these NOEs. The conformation of the adenosine part of CoA is the same as in the binary complex, while the pantetheine arm is more extended and approaches close to the bound chloramphenicol molecule. The model of the ternary complex is discussed in terms of the information available on the mechanism of the enzyme.

Crystallization and preliminary diffraction studies of NodL, a rhizobial O-acetyl-transferase involved in the host-specific nodulation of legume roots.

The NodL specified O-acetyltransferase from the microbial symbiont Rhizobium leguminosarum has been over-expressed in Escherichia coli and purified using affinity-elution dye chromatography as the key step. The protein has been crystallized at 20 degrees C in 18% PEG 600, 0.1 M Tris/HCl buffer, pH 8.5, containing 1% dioxane, 0.25% octyl-beta-glucoside, and 5 mM coenzyme A using the hanging drop vapor diffusion method. Ambient temperature X-ray diffraction studies reveal the space group to be hexagonal (P6(3)22) with lattice constants a = b = 77.08 A, c = 160.6 A, and alpha = beta = 90 degrees, gamma = 120 degrees. Crystals that are flash-frozen to 120 K diffract beyond 2.7 A.

Determination of sequence specificity between a plasmid replication initiator protein and the origin of replication.

Staphylococcal plasmids of the pT181 family replicate by a rolling circle mechanism, requiring the activities of a plasmid-specified Rep protein. The initiation event involves site-specific phosphodiester bond cleavage by Rep within the replication origin, ori. In vitro the Rep proteins also display type-I topoisomerase activity specific for this plasmid family. Although the single site of bond cleavage, ICR II, is conserved among all members of the pT181 family, the plasmid-specific Rep proteins are able to discriminate between family members in vivo, initiating replication only from the cognate origin. The basis of such specificity is believed to be due to a non-covalent binding interaction between Rep and a DNA sequence adjacent to the site of phosphodiester bond cleavage. Using the RepD protein specified by plasmid pC221, we present data for the physical parameters of RepD:oriD complex formation. Quantification of the relative strengths of the non-covalent interactions for different but related ori target sequences, measured by gel mobility shift experiments, has yielded data that are in accord with the known specificity of the protein in vivo. Oligonucleotide competition experiments demonstrate that this interaction is indeed attributable to the specificity determinant, ICR III. Protein-DNA crosslinking methods show that a carboxyl-terminal proteolytic fragment of RepD makes a specific interaction with the ICR III region of its cognate replication origin. Analysis of topoisomerase rates indicates that the interaction between ICR III and the carboxyl terminus of the protein is required before a productive interaction, namely the phosphodiester bond cleavage at the ICR II, can occur.

Steroid recognition by chloramphenicol acetyltransferase: engineering and structural analysis of a high affinity fusidic acid binding site.

The antibiotic fusidic acid and certain closely related steroidal compounds are potent competitive inhibitors of the type I variant of chloramphenicol acetyltransferase (CATI). In the absence of crystallographic data for CATI, the structural determinants of steroid binding were identified by (1) construction in vitro of genes encoding chimaeric enzymes containing segments of CATI and the related type III variant (CATIII) and (2) site-directed mutagenesis of the gene encoding CATIII, followed by kinetic characterisation of the substituted variants. Replacement of four residues of CATIII (Gln92, Asn146, Tyr168 and Ile172) by their equivalents from CATI yields an enzyme variant that is susceptible to competitive inhibition by fusidate with respect to chloramphenicol (Ki = 5.4 microM). The structure of the complex of fusidate and the Q92C/N146F/Y168F/I172V variant, determined at 2.2 A resolution by X-ray crystallography, reveals the inhibitor bound deep within the chloramphenicol binding site and in close proximity to the side-chain of His195, an essential catalytic residue. The aromatic side-chain of Phe146 provides a critical hydrophobic surface which interacts with non-polar substituents of the steroid. The remaining three substitutions act in concert both to maintain the appropriate orientation of Phe 146 and via additional interactions with the bound inhibitor. The substitution of Gln92 by Cys eliminates a critical hydrogen bond interaction which constrains a surface loop (residues 137 to 142) of wild-type CATIII which must move in order for fusidate to bind to the enzyme. Only two hydrogen bonds are observed in the CAT-fusidate complex, involving the 3-alpha-hydroxyl of the A-ring and both hydroxyl of Tyr25 and NE2 of His195, both of which are also involved in hydrogen bonds with substrate in the CATIII-chloramphenicol complex. In the acetyl transfer reaction catalysed by CAT, NE2, of His195 serves as a general base in the abstraction of a proton from the 3-hydroxyl of chloramphenicol as the first chemical step in catalysis. The structure of the CAT-inhibitor complex suggests that deprotonation of the 3-alpha-hydroxyl of bound fusidate by this mechanism could produce an oxyanion nucleophile analogous to that seen with chloramphenicol, but one which is incorrectly positioned to attack the thioester carbonyl of acetyl-CoA, accounting for the observed failure of CAT to acetylate fusidate.

Kinetic mechanism of chloramphenicol acetyltransferase: the role of ternary complex interconversion in rate determination.

Chloramphenicol acetyltransferase (CAT) catalyzes the acetyl-CoA-dependent acetylation of chloramphenicol (Cm) by a ternary complex mechanism and with a random order of addition of substrates. A closer examination of the mechanism of the reaction catalyzed by the type III CAT variant (CATIII) has included the measurement of the individual rate constants by stopped-flow fluorimetry at 5 degrees C. Under all conditions employed, product release from the binary complexes in both forward and reverse reactions was found to be too slow to account for the observed overall rate of turnover for the reaction. Additional, faster routes for product release are achieved via the formation of the nonproductive ternary complexes (CAT:3-acetyl-Cm:acetyl-CoA and CAT:CoA:Cm). The release of 3-acetyl-Cm from the binary complex is 5-fold slower than kcat (135 s-1 at 5 degrees C), whereas the dissociation rate constants of 3-acetyl-Cm from the ternary complexes with CoA and acetyl-CoA are 120 and 200 s-1, respectively. Arrhenius plots of dissociation rate constants indicate a slow release of products over a broad temperature range. Computer simulations based on the rate constants of CATIII applied to a ternary complex mechanism, assuming random order of substrate addition and product release, yielded nonlinear initial rates of product formation unless both nonproductive ternary complexes were included in the model. Simulated steady-state kinetic analyses based on the latter assumption yielded kinetic parameters that compared favorably with those determined experimentally.(ABSTRACT TRUNCATED AT 250 WORDS)

Inactivation of chloramphenicol by O-phosphorylation. A novel resistance mechanism in Streptomyces venezuelae ISP5230, a chloramphenicol producer.

Plasmid pJV4, containing a 2.4-kilobase pair insert of genomic DNA from the chloramphenicol (Cm) producer Streptomyces venezuelae ISP5230, confers resistance when introduced by transformation into the Cm-sensitive host Streptomyces lividans M252 (Mosher, R. H. Ranade, N. P., Schrempf, H., and Vining, L. C. (1990) J. Gen. Microbiol. 136, 293-301). Transformants rapidly metabolized Cm to one major product, which was isolated and purified by reversed phase chromatography. The metabolite was identified by nuclear magnetic resonance spectroscopy and mass spectrometry as 3'-O-phospho-Cm, and was shown to have negligible inhibitory activity against Cm-sensitive Micrococcus luteus. The nucleotide sequence of the S. venezuelae DNA insert in pJV4 contains an open reading frame (ORF) that encodes a polypeptide (19 kDa) with a consensus motif at its NH2 terminus corresponding to a nucleotide-binding amino acid sequence (motif A or P-loop; Walker, J. E., Saraste, M., Runswick, M. J., and Gay, N. J. (1982) EMBO J. 1, 945-951). When a recombinant vector containing this ORF as a 1.6-kilobase pair SmaI-SmaI fragment was used to transform S. lividans M252, uniformly Cm-resistant transformants were obtained. A strain of S. lividans transformed by a vector in which the ORF had been disrupted by an internal deletion yielded clones that were unable to phosphorylate Cm, and exhibited normal susceptibility to the antibiotic. The results implicate the product of the ORF from S. venezuelae as an enzymic effector of Cm resistance in the producing organism by 3'-O-phosphorylation. We suggest the trivial name chloramphenicol 3'-O-phosphotransferase for the enzyme.

Structural and mechanistic studies of galactoside acetyltransferase, the Escherichia coli LacA gene product.

Escherichia coli galactoside acetyltransferase (GAT) is a member of a large family of acetyltransferases that O-acetylate dissimilar substrates but share limited sequence homology. Steady-state kinetic analysis of over-expressed GAT demonstrated that it accepted a range of substrates, including glucosides and lactosides which were acetylated at rates comparable to galactosides. GAT was shown to be a trimeric acetyltransferase by cross-linking with dimethyl suberimidate. Fluorometric analysis of coenzyme A binding showed that there is a fluorescence quench associated with acetyl-CoA binding whereas CoA has no effect. This difference was exploited to measure dissociation rates for both CoA and acetyl-CoA by stopped-flow fluorometry. The rate of dissociation of CoA (2500 s-1) is at least 170-fold faster than kcat for any substrate tested. The fluorescence response to acetyl-CoA binding is entirely due to Trp-139 since replacement by phenylalanine completely abolished the fluorescence quench. Treatment of GAT by [14C]iodoacetamide resulted in complete inactivation of the enzyme and the incorporation of label into histidyl and cysteinyl residues to approximately equal extents. Following replacement of His-115 by alanine, label was incorporated solely into cysteinyl residues. Furthermore, the substitution results in an 1800-fold decrease in kcat suggesting that His-115 has an important catalytic role in GAT.

Properties of hybrid active sites in oligomeric proteins: kinetic and ligand binding studies with chloramphenicol acetyltransferase trimers.

Alteration of the charge of surface lysyl residues of chloramphenicol acetyltransferase (CAT) by site-directed mutagenesis was used to increase the charge difference between the subunits of two naturally occurring enzyme variants (CATI and CATIII). The introduced charge change greatly facilitates the purification of CATI/CATIII and CATIII/CATIII hybrid trimers by ion-exchange chromatography. Hybrids containing only one functional active site per trimer were generated in vitro by reversible denaturation of mixtures of "active" subunits (retention of a catalytic histidine at position 195) and "inactive" subunits (with alanine replacing histidine 195). Such hybrids were used (1) to demonstrate that the previously observed novel binding of a steroidal antibiotic (fusidic acid) by CATI involves amino acid residues at each subunit interface and (2) to identify specific residues contributing to such interactions. A pre-steady-state kinetic characterization of homotrimers containing the H195A substitution also revealed that fusidate binding to CATI may, like chloramphenicol binding, involve a hydrogen bond with the catalytic histidine residue. In addition, confirmation of the fact that His-195 interacts with chloramphenicol in CATI as well as in CATIII makes it likely that it is essential for the catalytic mechanism of all naturally occurring variants of CAT, as first suggested by structural evidence for the type III enzyme (Leslie, 1990).

Tryptophan fluorescence of chloramphenicol acetyltransferase: resolution of individual excited-state lifetimes by site-directed mutagenesis and multifrequency phase fluorometry.

Multifrequency phase fluorometry, in conjunction with site-directed mutagenesis, has allowed the determination of the fluorescence lifetimes of each of the three tryptophan residues of the type III variant of chloramphenicol acetyltransferase (CATIII). The mutant proteins retaining a single tryptophan yield lifetimes of 1.36, 2.00, and 1.17 ns for Trp-16, -86, and -152, respectively. Binding of chloramphenicol shortens the fluorescence lifetimes of all three tryptophans to some extent, in particular those of Trp-86 and Trp-152 (decreases of 51% and 39%, respectively). The mechanism of fluorescence quenching is believed to be radiationless energy transfer. Estimates of Trp-chloramphenicol distances by energy-transfer calculations are in good agreement with those determined from the crystal structure of CATIII. Despite binding at the same site in wild-type CATIII, CoA and ethyl-S-CoA produce different responses in global lifetime measurements--increases of 8% and 31%, respectively. Examination of each of the one-Trp CATIII variants, generated by site-directed mutagenesis, yields a variety of responses. Trp-152, located within the CoA binding site, responds to both CoA and its thioalkyl derivative with a 27-30% increase in fluorescence lifetime. Trp-16, distant from the CoA site, does not differentiate between the two ligands (7% increase in lifetime). However, Trp-86 shows a striking difference in binding responses, only a 4% decrease with CoA but a 14% reduction with ethyl-S-CoA. Each of the two-Trp CAT variants shows little change in global fluorescence lifetime on association with CoA.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of hydrogen bonding in enzyme-substrate complexes of chloramphenicol acetyltransferase by infrared spectroscopy and site-directed mutagenesis.

Chloramphenicol acetyltransferase (CAT) reversibly transfers an acetyl group between CoA and the 3-hydroxyl of either chloramphenicol (Cm) or 1-acetylchloramphenicol (1AcCm). The products of the forward reactions, 3-acetylchloramphenicol (3-AcCm) and 1,3-diacetylchloramphenicol (1,3Ac2-Cm), are the substrates for the reverse reaction. The role of the 3-acetyl carbonyl group in the binding of the substrates 3AcCm and 1,3Ac2Cm to CAT has been investigated using infrared spectroscopy. Comparison of difference spectra (3-[12C = O]acetyl- minus 3-[13C = O]acetyl-) obtained for the binary complexes of 3AcCm with wild-type CAT, and with a variant wherein serine-148 is replaced by alanine (S148A), reveals a large (9 cm-1) down frequency shift for the 3-acetyl carbonyl stretch in the wild-type complex, indicative of a hydrogen bond between this carbonyl and the hydroxyl group of Ser-148. The carbonyl bandwidth in the wild-type complex is reduced by 33% compared to that for the complex with S148A, indicating restriction of carbonyl mobility and dispersion in the former, an observation consistent with the proposed hydrogen bond between the ester carbonyl and the hydroxyl of Ser-148. Repetition of the experiment using 1,3Ac2Cm as the ligand reveals a frequency shift of only 3 cm-1 between wild-type and S148A complexes, indicating only a small change in the strength of carbonyl interaction.(ABSTRACT TRUNCATED AT 250 WORDS)

Replacement of catalytic histidine-195 of chloramphenicol acetyltransferase: evidence for a general base role for glutamate.

The imidazole N epsilon 2 of His-195 plays an essential part in the proposed general base mechanism of chloramphenicol acetyltransferase (CAT), hydrogen bonding to and a abstracting a proton from the primary hydroxyl group of chloramphenicol. Replacement of His-195 by alanine or glutamine results in apparent decreases in kcat of (9 x 10(5)- and (3 x 10(5))-fold, respectively, whereas Km values for both substrates (chloramphenicol and acetyl-CoA) are similar to those of wild-type CAT. The structure of Gln-195 CAT has been solved at 2.5-A resolution and is largely isosteric with that of wild-type CAT. Substitution of His-195 by glutamate resulted in a (5 x 10(4))-fold decrease in kcat together with a 3-fold increase in the Km for chloramphenicol. Direct determination of binding constants for both substrates demonstrated that these substitutions result in only small decreases in the affinity of CAT for acetyl-CoA (Kd values increased 2- to 3-fold), whereas chloramphenicol Kd values are elevated 26-, 20-, and 53-fold for Ala-195 CAT, Gln-195 CAT and Glu-195 CAT, respectively. The pH dependence of kcat/Km yields apparent pKa values of 6.5 and 6.7 for Ala-195 CAT and Gln-195 CAT, respectively, which are very similar to that (6.6) determined for the ionization of His-195 in wild-type CAT. In contrast, the pH dependence of kcat/Km for Glu-195 CAT (pKa = 8.3) is very different from that of wild-type CAT.(ABSTRACT TRUNCATED AT 250 WORDS)

Transition state stabilization by chloramphenicol acetyltransferase. Role of a water molecule bound to threonine 174.

The structure of the type III variant of chloramphenicol acetyltransferase reveals that Thr-174, a conserved residue, is hydrogen-bonded to a bound water molecule (water 252). Modeling studies (P. C. E. Moody and A. G. W. Leslie, unpublished data) suggested that water 252 could play a part in transition state stabilization via a hydrogen bond to the oxyanion of the putative tetrahedral intermediate. In addition, water 252 is one of three bound water molecules hydrogen-bonded to the 1-hydroxyl group of chloramphenicol in the chloramphenicol acetyltransferase-chloramphenicol binary complex. A combination of site-directed mutagenesis and the use of an alternative substrate has allowed the quantitation of the energetic contribution of each of the interactions made by water 252 to catalysis. Thr-174 was replaced by alanine, valine, and isoleucine, each substitution removing the hydroxyl group hydrogen-bonded to water 252. Steady-state kinetic analysis of the mutant enzymes was carried out using both chloramphenicol and 1-deoxy-chloramphenicol as acetyl acceptors. The substitutions at Thr-174 result in a fall in kcat and in decreased affinities for each acetyl acceptor in the binary complexes and also in the ternary complexes with acetyl-CoA. From the calculated free energies in the transition state, the hydrogen bond between water 252 and the oxyanion of the tetrahedral intermediate can be estimated to contribute 0.9 kcal mol-1 toward transition state stabilization, whereas the free energy of the hydrogen bonds between the 1-hydroxyl of chloramphenicol and three bound water molecules provides 1.6 kcal mol-1.

The pKa of the catalytic histidine residue of chloramphenicol acetyltransferase.

A catalytically essential histidine residue (His-195) of chloramphenicol acetyltransferase (CAT) acts as a general base in catalysis, abstracting a proton from the primary hydroxy group of chloramphenicol. The pKa of His-195 has been determined from the pH-dependence of chemical modification. Both methyl 4-nitrobenzenesulphonate and iodoacetamide inactivate CAT by irreversible modification of His-195. The kinetics of inactivation by methyl 4-nitrobenzenesulphonate are pseudo-first-order, and the pH-dependence of inactivation yields a pKa value of 6.60. Iodoacetamide inactivation proceeds with second-order kinetics and a pKa value of 6.80. An alternative site of modification at the active site of CAT is the thiol group of Cys-31, a residue which has no catalytic role. On replacement of Cys-31 with alanine (Ala-31 CAT), the pH-dependence of iodoacetamide inactivation gives a pKa value of 6.66. The pKa values derived from chemical-modification experiments directed at His-195 are in agreement with the pKa values of 6.62 and 6.61 determined for wild-type and Ala-31 CAT respectively from the pH-dependence of kcat/Km.

Analysis of the binding of 1,3-diacetylchloramphenicol to chloramphenicol acetyltransferase by isotope-edited 1H NMR and site-directed mutagenesis.

The binary complex of diacetylchloramphenicol and chloramphenicol acetyltransferase (CAT) has been studied by a combination of isotope-edited 1H NMR spectroscopy and site-directed mutagenesis. One-dimensional HMQC spectra of the complex between 1,3-[2-13C]diacetylchloramphenicol and the type III natural variant of CAT revealed the two methyl 1H signals arising from each 13C-labeled carbon atom in the acetyl groups of the bound ligand. Slow hydrolysis of the 3-acetyl group by the enzyme precluded further analysis of this binary complex. It was possible to slow down the rate of hydrolysis by use of the catalytically defective S148A mutant of CATIII (Lewendon et al., 1990); in the complex of diacetylchloramphenicol with S148A CATIII, the chemical shifts of the acetyl groups of the bound ligand were the same as in the wild-type complex. The acetyl signals were individually assigned by repeating the experiment using 1-[2-13C],3-[2-12C]diacetylchloramphenicol, where only one signal from the bound ligand was observed. A two-dimensional 1H, 1H NOESY experiment, with 13C(omega 2) half-filter, on the 1,3-[2-13C]diacetylchloramphenicol/S148A CATIII complex showed a number of intermolecular NOEs from each methyl group in the ligand to residues in the chloramphenicol binding site. The 3-acetyl group showed strong NOEs to two aromatic signals which were selected for assignment. The possibility that the NOEs originated from the aromatic protons of diacetylchloramphenicol itself was eliminated by assignment of the signals from enzyme-bound diacetylchloramphenicol and chloramphenicol using perdeuterated CATIII. Examination of the X-ray crystal structure of the chloramphenicol/CATIII binary complex indicated four plausible candidate aromatic residues: Y25, F33, F103, and F158.(ABSTRACT TRUNCATED AT 250 WORDS)