Localization of the active site of type II dehydroquinases. Identification of a common arginine-containing motif in the two classes of dehydroquinases

A novel method based on electrospray mass spectrometry (Krell, T., Pitt, A. R., and Coggins, J. R. (1995) FEBS Lett. 360, 93-96) has been used to localize active site residues in the type I and type II dehydroquinases. Both enzymes have essential hyper-reactive arginine residues, and the type II enzymes have an essential tyrosine residue. The essential hyper-reactive Arg-23 of the Streptomyces coelicolor type II enzyme has been replaced by lysine, glutamine, and alanine residues. The mutant enzymes were purified and shown by CD spectroscopy to be structurally similar to the wild-type enzyme. All three mutant enzymes were much less active, for example the kcat of the R23A mutant was 30,000-fold reduced. The mutants all had reduced Km values, indicating stronger substrate binding, which was confirmed by isothermal titration calorimetry experiments. A role for Arg-23 in the stabilization of a carbanion intermediate is proposed. Comparison of the amino acid sequence around the hyper-reactive arginine residues of the two classes of enzymes indicates that there is a conserved structural motif that might reflect a common substrate binding fold at the active center of these two classes of enzyme.     

Separation of the two reactions, oxidation and isomerization, catalyzed by Streptomyces cholesterol oxidase

Site-directed mutagenesis was used to identify key amino acid residues of the cholesterol oxidase from Streptomyces sp., which catalyzes the oxidation of cholesterol and the isomerization of 5-cholesten-3-one. Eight mutant enzymes were constructed and the following amino acid substitutions were identified: N318A, N318H, E356A, E356D, H441A, H441N, N480A and N480Q. Mutants N318A and N318H retained both oxidation and isomerization activities. The mutant E356D retained oxidation but not isomerization activity. On the other hand, mutants N480A and N480Q showed no oxidation activity but retained their isomerization activities. The two catalytic reactions, oxidation and isomerization, in cholesterol oxidase were thus successfully separated. When the H441A or H441N mutation was introduced, both the oxidase and isomerase activities were completely lost. The H441, E356 and N480 residues thus appear to participate in the catalysis of cholesterol oxidase, whereas N318 does not. An analysis of the products of these mutant enzymes suggested that the previously proposed 6-hydroxylation reaction by cholesterol oxidase is actually autooxidation from 5-cholesten-3-one. Kinetic studies of the purified wild-type and mutant enzymes showed that the k(cat)/Km values for oxidation in E356D and for isomerization in N480A increased six- and threefold, respectively, over those in the wild-type. These mutational effects and the reaction mechanisms are discussed in terms of the three-dimensional structure of the enzyme constructed on the basis of homology modeling.     

Purification and properties of sulfite oxidase from human liver

Sulfite oxidase has been purified to near homogeneity from human liver. Properties of the molecule have been investigated and compared to those of the rat liver enzyme which has been isolated in a pure form. Both proteins exist as dimeric molecules with one molybdenum and one cytochrome b5-type heme per sub-unit. The human enzyme has a slightly larger subunit molecular weight (61,100 vs. 57,200 daltons) and is a more negatively charged molecule. Decreased reactivity of the human enzyme with various electron acceptors suggests the presence of nonfunctional molybdenum centers in a portion of the molecules isolated. Human liver sulfite oxidase cross-reacts strongly with antibody prepared against the rat liver enzyme. Human enzyme activity is precipitated by antibody at concentrations about twofold greater than required for comparable complexation of rat sulfite oxidase.     

Mutations of conserved arginines in the membrane domain of erythroid band 3 lead to a decrease in membrane-associated band 3 and to the phenotype of hereditary spherocytosis

To elucidate the molecular basis of band 3 deficiency in a recently defined subset of patients with autosomal dominant hereditary spherocytosis (HS), we screened band 3 cDNA for single-strand conformation polymorphism (SSCP). In 5 of 17 (29%) unrelated HS subjects with band 3 deficiency, we detected substitutions R760W, R760Q, R808C, and R870W that were all coinherited with the HS phenotype. The involved arginines are highly conserved throughout evolution. To examine whether or not the product of the mutant allele is inserted into the membrane, we studied one HS subject who was doubly heterozygous for the R760Q mutation and the K56E (band 3sMEMPHIS) polymorphism that results in altered electrophoretic mobility of the band 3 Memphis proteolytic fragments. We detected only the band 3MEMPHIS in the erythrocyte membrane indicating that the protein product of the mutant, R760Q, band 3 allele is absent from the red blood cell membrane. These findings suggest that the R760Q substitution, and probably the other arginine subsitutions, produce band 3 deficiency either by precluding incorporation of the mutant protein into the red blood cell membrane or by leading to loss of mutant protein from differentiating erythroid precursors.     

Site-directed mutagenesis of the active site glutamate in human matrilysin: investigation of its role in catalysis

Glu-198 of human matrilysin is a conserved residue in the matrix metalloproteinases and is considered to play an important role in catalysis by acting as a general base catalyst toward the zinc-bound water molecule, on the basis of mechanistic proposals for other zinc proteases. In the present study, Glu-198 is mutated into Asp, Cys, Gln, and Ala, and the zinc binding properties, kinetic parameters, and pH dependence of each mutant are determined in order to examine the role of Glu-198 in catalysis. The mutations chosen either modify (C and D) or eliminate (A and Q) the general base properties of residue-198. All the mutants bind 2 mol of zinc per mol of enzyme, indicating that Glu-198 is not crucial to the binding of the catalytic zinc to the enzyme. The value of kcat/Km for the E198D mutant is only 4-fold lower than that of wild-type enzyme at the pH optimum of 7.5, while that for the E198C mutant is decreased by 160-fold. The E198Q and E198A enzymes containing the mutations that have eliminated the nucleophilic and acid/base properties of the residue are still active, having lower kcat/Km values of 590- and 1900-fold, respectively. The decrease in activity of all the mutants is essentially due to a decrease in kcat. The kcat/Km values of the mutants as a function of pH display broad bell-shaped curves that are similar to the wild-type enzyme. The acidic pKa value is not greatly affected by the change in the chemical properties of residue-198. The similarity in the pH profiles for the mutant and wild-type enzymes indicates that the ionization of Glu-198 is not responsible for the acidic pKa. Ionization of the zinc-bound water may be responsible for this pKa since the three His ligands and the scaffolding of the matrilysin catalytic zinc site are different from that observed in carboxypeptidase A and would predict a lower pKa for the metal-bound water. If the zinc-bound water is the nucleophile in the reaction, the role of Glu-198 in catalysis may be to stabilize the transition state or act as a general acid catalyst after the rate-determining step.     

A new remote subsite in ribonuclease A

The interaction between bovine pancreatic ribonuclease A (RNase A) and its RNA substrate extends beyond the scissile bond. Enzymic subsites interact with the bases and the phosphoryl groups of a bound substrate. We evaluated the four cationic residues closest to known subsites for their abilities to interact with a bound nucleic acid. Lys-37, Arg-39, Arg-85, and Lys-104 were replaced individually by an alanine residue, and the resulting enzymes were assayed as catalysts of poly(cytidylic acid) (poly(C)) cleavage. The values of Km and kcat/Km for poly(C) cleavage were affected only by replacing Arg-85. Moreover, the contribution of Arg-85 to the binding of the ground state and the transition state was uniform---Km increased by 15-fold and kcat/Km decreased by 10-fold. The contribution of Arg-85 to binding was also apparent in the values of Kd for complexes with oligonucleotides of different length. This contribution was dependent on salt concentration, as expected from a coulombic interaction between a cationic side chain and an anionic phosphoryl group. Together, these data indicate that Arg-85 interacts with a particular phosphoryl group of a bound nucleic acid. We propose that Arg-85 comprises a new distal subsite in RNase A---the P(-1) subsite.     

Rhodopsin arginine-135 mutants are phosphorylated by rhodopsin kinase and bind arrestin in the absence of 11-cis-retinal

Arginine-135, located at the border between the third transmembrane domain and the second cytoplasmic loop of rhodopsin, is one of the most highly conserved amino acids in the family of G protein-coupled receptors. The effect of mutation at Arg-135 on the ability of rhodopsin to undergo desensitization was investigated. Four mutants, R135K, R135Q, R135A, and R135L, were examined for their ability to be phosphorylated by rhodopsin kinase, to bind arrestin, and to activate the rod cell G protein, transducin (Gt). All of the mutants were phosphorylated, bound arrestin, and were able to activate Gt when reconstituted with 11-cis-retinal. Surprisingly, several of the mutants could be phosphorylated by rhodopsin kinase and could bind arrestin in the absence of 11-cis-retinal but were not able to activate Gt. These observations represent the first demonstration of a mutant G protein-coupled receptor that assumes a conformation able to interact with its G protein-coupled receptor kinase and arrestin, but not with its G protein, in the absence of ligand.     

Infectious disease and sociodemographic characteristics of foreign immigrants in the Central Penitentiary for Men in Barcelona

A number of thrombin mutants have been constructed to investigate the role of Trp96 and the beta-insertion loop for the specificity of thrombin. Thrombin(60D) consists of the replacement of the beta-insertion loop (14 amino acid residues from 59 to 63, including a 9-residue insertion at position 60) with the corresponding four residues in trypsin, Tyr-Lys-Ser-Gly; thrombin(GGG) is a smaller loop mutation in which the residues Tyr(60A)Pro(60B)Pro(60C)Trp(60D) Asp(60E)Lys(60F) of the beta-insertion loop were replaced by Gly-Gly-Gly; thrombin(96S) consists of a point mutation Trp96 --> Ser; and thrombin(GGG/96S) is the double mutant incorporating both changes. Thrombin(96S) clots fibrinogen approximately 3 times more slowly than thrombin, with the two beta-insertion loop mutants, thrombin(GGG) and thrombin(GGG/96S), reacting approximately 3000- and 1300-fold more slowly, respectively. The specificity constant kcat/Km for the cleavage of fibrinopeptide A and fibrinopeptide B by thrombin(96S) was 2.6 and 0.35 microM(-1) s(-1), respectively, compared to 10 and 2.5 microM(-1) s(-1) for wild-type recombinant thrombin, respectively. Kinetic constants were determined for the hydrolysis of H-D-phenylalanyl-L-pipecolyl-L-arginine-p-nitroaniline. The Michaelis constant Km increased approximately 6-fold for thrombin(96S) and >200-fold for thrombin(GGG) and thrombin(GGG/96S) when compared to wild-type recombinant thrombin, while the catalytic constant kcat remained approximately the same. All mutants were more susceptible to inhibition by BPTI than wild-type recombinant thrombin. Clearly, the beta-insertion loop is important for thrombin activity. But the mutation of Trp96 --> Ser can compensate somewhat for the loss of binding at the beta-insertion loop. The deletion of the hydrophobic interaction between Trp96 and Pro(60B)Pro(60C) appears to decrease the stability of the beta-insertion loop, thereby causing a decrease in binding efficiency.     

Effect of an amino acid insertion into the omega loop region of a class C beta-lactamase on its substrate specificity

The extended-substrate specificity of Enterobacter cloacae GC1 beta-lactamase is entirely due to a three amino acid insertion after position 207. To clarify the reason for the extended-substrate specificity, Ala, Ala-Ala, Ala-Ala-Ala, and Ala-Ala-Ala-Ala were inserted after position 207 on the basis of the class C beta-lactamase from E. cloacae P99, respectively. The kcat and Km values of all the mutant enzymes for cephalothin, benzylpenicillin and ampicillin were almost the same as those of the wild-type enzyme, except for those of P99-210-4A which were decreased 4-15-fold. On the other hand, the kcat and Km values for oxyimino beta-lactams such as cefuroxime, ceftazidime, and aztreonam increased with increasing numbers of inserted alanines. The kcat values of the mutant enzymes for cefroxime increased 140-7400-fold compared with that of the wild-type. The Km values also increased with almost the same magnitude, resulting in about the same kcat/Km values as that of the wild-type. On progressive inhibition analysis of aztreonam of the mutant enzymes, two kinds of inactive acyl-enzyme with distinct stabilities were observed, and the proportion of the less stable inactive enzyme increased with increasing numbers of inserted alanines. This suggests that the extension of the substrate specificity is due to instability of the acyl-intermediate caused by an increased deacylation rate in the reaction process.     

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.     

Regulation of rat 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase. Role of the NH2-terminal region

The role of the NH2-terminal region of the liver and skeletal muscle 6-phosphofructo-2-kinase/fructose 2,6-bisphosphatases was investigated, as well that of a mutant of the liver isoform lacking the first 22 amino acids, by the overexpression of these enzymes in Escherichia coli and the comparison of their kinetic properties. The muscle isoform and the deletion mutant had Km values for fructose 6-phosphate which were 50- and 20-fold higher, respectively, than that of the liver isoform, and the bisphosphatase maximal velocity of the liver deletion mutant was 4-fold higher than that of the native liver isoform. Phosphorylation of the liver isoform increased bisphosphatase activity by 2-3-fold and the Km for fructose 6-phosphate of the 6-phosphofructo-2-kinase by 10-15-fold, but these kinetic effects were greatly diminished for the deletion mutant despite equivalent phosphorylation by cAMP-dependent protein kinase. Arg-173 of the skeletal muscle isoform was found to be functionally equivalent to the residue corresponding to the essential fructose 6-phosphate binding residue of the liver kinase domain, Arg-195. The results suggest that 1) the NH2-terminal regions of the liver and skeletal muscle isoforms are important determinants of fructose 6-phosphate affinity, and 2) the initial 22 amino acids of the liver isoform exert an inhibitory influence on the bisphosphatase and mediate, at least in part, the response of both activities of the enzyme to cAMP-dependent phosphorylation.     

Conversion of tyrosine phenol-lyase to dicarboxylic amino acid beta-lyase, an enzyme not found in nature

Tyrosine phenol-lyase (TPL), which catalyzes the beta-elimination reaction of L-tyrosine, and aspartate aminotransferase (AspAT), which catalyzes the reversible transfer of an amino group from dicarboxylic amino acids to oxo acids, both belong to the alpha-family of vitamin B6-dependent enzymes. To switch the substrate specificity of TPL from L-tyrosine to dicarboxylic amino acids, two amino acid residues of AspAT, thought to be important for the recognition of dicarboxylic substrates, were grafted into the active site of TPL. Homology modeling and molecular dynamics identified Val-283 in TPL to match Arg-292 in AspAT, which binds the distal carboxylate group of substrates and is conserved among all known AspATs. Arg-100 in TPL was found to correspond to Thr-109 in AspAT, which interacts with the phosphate group of the coenzyme. The double mutation R100T/V283R of TPL increased the beta-elimination activity toward dicarboxylic amino acids at least 10(4)-fold. Dicarboxylic amino acids (L-aspartate, L-glutamate, and L-2-aminoadipate) were degraded to pyruvate, ammonia, and the respective monocarboxylic acids, e.g. formate in the case of L-aspartate. The activity toward L-aspartate (kcat = 0.21 s-1) was two times higher than that toward L-tyrosine. beta-Elimination and transamination as a minor side reaction (kcat = 0.001 s-1) were the only reactions observed. Thus, TPL R100T/V283R accepts dicarboxylic amino acids as substrates without significant change in its reaction specificity. Dicarboxylic amino acid beta-lyase is an enzyme not found in nature.     

Role for Pro-13 in directing high-affinity binding of anthopleurin B to the voltage-sensitive sodium channel

Anthopleurin A (ApA) and B (ApB) are 49-amino acid polypeptide toxins from the Pacific sea anemone Anthopleura xanthogrammica that interfere with inactivation of voltage-gated sodium channels. ApA, which differs from ApB in seven of the 49 amino acids, displays markedly enhanced isoform selectivity compared with ApB, acting preferentially on cardiac over neuronal sodium channels. Previous studies in this lab have indicated the importance of two unique charged residues in ApB, Arg-12 and Lys-49, in this toxin's ability to discriminate between neuronal and cardiac sodium channels. Likewise, a double mutant (R12S/K49Q) recently characterized in this lab (Khera et al., 1995) displays a greatly reduced affinity for neuronal channels, essentially restoring the discriminatory ability of ApA. When the remaining five residues unique to ApB are individually converted to those of ApA, only ApB (Pro-13) shows a major effect, reducing the affinity of the new mutant toxin (P13V) against both channel isoforms approximately 10-fold. This effect is most likely the result of a conformational rearrangement within the surrounding cationic cluster which includes Arg-12 and -14, as well as Lys-49. However, when placed into the context of the double mutant R12S/K49Q a unique effect is observed: the new triple mutant (R12S/P13V/K49Q) is no longer able to discriminate effectively between channel isoforms. Its affinity for the neuronal sodium channel is significantly enhanced compared to either P13V or to the double mutant R12S/K49Q. These results are consistent both with our proposed model (Khera et al., 1995) and with the recently reported solution structure of ApB, which implicate the cationic cluster in both affinity and channel isoform selectivity. We suggest that the P13V mutation results in a shift in the relative orientation of cationic residues within the large flexible loop between residues 9-18, thus strengthening their interactions with target sequences of the neuronal sodium channel.     

Functional evaluation of invariant arginines situated in the mobile lid domain of phosphoribulokinase

Rhodobacter sphaeroides phosphoribulokinase contains four invariant arginines (R49, R168, R173, and R187). The high-resolution structure of this enzyme [Harrison, D. H. T., Runquist, J. A., Holub, A., and Miziorko, H. M. (1998) Biochemistry (submitted for publication)] reveals that it folds in a manner similar to that of adenylate kinase. Three invariant arginines (R168, R173, and R187) as well as arginine-186, which is conserved in prokaryotic phosphoribulokinases, have not been previously functionally evaluated. These arginine residues map within the mobile lid domain that is a distinctive feature of the adenylate kinase family of proteins. Precedent for the significant function of arginines in phosphotransferase reactions prompted substitution of glutamine for each of these three invariant arginines. Solution state characterization of the isolated mutant proteins indicated that they retained a high degree of structural integrity, as indicated by their stoichiometric binding of an alternative nucleotide substrate (trinitrophenyl-ATP) as well as the allosteric effector (NADH). Kinetic characterization indicated > 10(4)-fold diminution in V/KRu5P for R168Q, attributable to a > 300-fold decrease in catalytic efficiency and an increase (approximately 50-fold) in Km Ru5P. For R173Q, a 15-fold diminution in Vmax and a 100-fold increase in Km Ru5P were observed. These observations implicate new components of the ribulose 5-phosphate binding site. Additionally, they confirm assignment of the mobile lid domain as part of the phosphoribulokinase active site, even though this region is well separated from other active site elements in the structure of the open form of the protein. Characterization of R186Q and R187Q mutants suggests that they influence the cooperativity of substrate binding.     

Heterogeneity in recombinant HIV-1 integrase corrected by site-directed mutagenesis: the identification and elimination of a protease cleavage site

We describe a type of mild hypermethioninemia due to a point mutation in the MATA1 gene, which was inherited dominantly in a family. Three patients coming from the same family pedigree were detected by the presence of isolated hypermethioninemia on a mass-screening program. The measurement of methionine adenosyltransferase (MAT) activity in a patient's liver revealed a partial deficiency of hepatic MAT with a reduction in the Km for methionine. Single strand conformation polymorphism (SSCP) analysis and direct sequencing of the patients' genomic DNA revealed a G to A mutation at nucleotide 791 that converts Arg-264 to His (R264H) in one allele of MATA1 gene. The other allele was normal in all the patients examined. Gene tracking in the family revealed that the hypermethioninemia is associated with heterozygosity for the R264H mutation in the MATA1 gene.     

Identification of a residue involved in transition-state stabilization in the ATPase reaction of DNA gyrase

Examination of the X-ray crystal structure of the 43 kDa N-terminal domain of the DNA gyrase B protein (GyrB) shows that the majority of the interactions with bound ATP are made with subdomain 1 (residues 2-220). However, two residues from subdomain 2, Gln335 and Lys337, interact with the gamma-phosphate of ATP. The proposed roles for these residues include nucleotide binding, transition-state stabilization, and triggering protein conformational changes. We have used site-directed mutagenesis to convert Gln335 to Asn and Ala and Lys337 to Gln and Ala in the N-terminal domain of GyrB. Two of the resultant mutant proteins, GyrB43(Q335A) and GyrB43(K337Q), were shown to be correctly folded, and their interactions with ATP have been analyzed in detail. The Q335A protein is apparently unchanged with regard to nucleotide binding and hydrolysis, whereas the K337Q protein shows a modest decrease in nucleotide binding and a drastic reduction in ATPase activity. This is manifested by a approximately 10(3)-fold decrease in kcat. When the two mutations were moved into full-length GyrB, the Q335A mutation again showed little or no effect on activity, whereas the K337Q mutation had undetectable supercoiling and ATPase activities. We conclude that Gln335 is dispensable for ATP binding and hydrolysis by the gyrase B protein, whereas Lys337 has a critical role in the ATPase reaction and is likely to be a key residue in transition-state stabilization.     

Effects of lysine-to-glycine mutations in the ATP-binding consensus sequences in the AddA and AddB subunits on the Bacillus subtilis AddAB enzyme activities

The N-terminal regions of both subunits AddA and AddB of the Bacillus subtilis AddAB enzyme contain amino acid sequences, designated motif I, which are commonly found in ATP-binding enzymes. The functional significance of the motif I regions was studied by replacing the highly conserved lysine residues of the regions in both subunits by glycines and by examination of the resulting mutant enzymes with respect to their enzymatic properties. This study shows that the mutation in subunit AddB hardly affected the ATPase, helicase, and exonuclease activities of the AddAB enzyme. However, the mutation in subunit AddA drastically reduced these activities, as well as the kcat for ATP hydrolysis. The apparent Km for ATP in ATP hydrolysis did not significantly deviate from that of the wild-type enzyme. These results suggest that the lysine residue in motif I of subunit AddA of the AddAB enzyme is not essential for the binding of the nucleotide but has a role in ATP hydrolysis, which is required for the exonuclease and helicase activities of the enzyme.     

Site-directed mutations of the 4Fe-ferredoxin from the hyperthermophilic archaeon Pyrococcus furiosus: role of the cluster-coordinating aspartate in physiological electron transfer reactions

Ferredoxin from the hyperthermophilic archaeon Pyrococcus furiosus is a monomeric protein (7.5 kDa) that contains a single [4Fe-4S]1+, 2+ cluster. The protein is unusual in that its cluster is coordinated by three Cys and one Asp residue, rather than by the typical four Cys residues. Site-directed mutagenesis has been used to obtain mutant forms in which the cluster-coordinating Asp was replaced by Cys (D14C) and also by Ser (D14S), together with a third mutant (A1K) which contained N-Met-Lys at the N-terminus instead of N-Ala. Analyses using UV-visible absorption, far-UV circular dichroism, and EPR spectroscopy showed that there were no gross structural differences between the native and the three mutant forms and that they each contained a [4Fe-4S] cluster. The reduction potentials, determined by direct electrochemistry (at 23 degrees C, pH 8.0), of the D14S, D14C, and A1K mutants were -490, -422, and -382 mV, respectively, which compare with values of -375 mV for native [4Fe-4S]-containing ferredoxin and -160 mV for the [3Fe-4S]-containing form. The native, D14C, and A1K proteins functioned as electron acceptors in vitroat 80 degrees C for pyruvate ferredoxin oxidoreductase (POR) and aldehyde ferredoxin oxidoreductase (AOR) from P. furiosus using pyruvate and crotonaldehyde as substrates, respectively. The calculated kcat/Km values were similar for the three proteins when ferredoxin reduction was measured either directly by visible absorption or indirectly by coupling ferredoxin reoxidation to the reduction of metronidazole. In contrast, using the D14S mutant and the 3Fe-form of the native ferredoxin as electron acceptors, the activity with AOR was virtually undetectable, and with POR the calculated kcat/Km values were at least 3-fold lower than those obtained with the native (4Fe-), D14C, and A1K proteins. The ability of this 4Fe-ferredoxin to accept electrons from two oxidoreductases of the same organism is therefore not absolutely dependent upon Asp14, as this residue can be effectively replaced by Cys. However, the efficiency of electron transfer is compromised if Asp14 is replaced by Ser, or if the 4Fe-cluster is converted to the 3Fe-form, but Asp14 does not appear to offer any kinetic advantage over the expected Cys.     

Protoporphyrinogen oxidase of Myxococcus xanthus. Expression, purification, and characterization of the cloned enzyme

Protoporphyrinogen oxidase (EC 1.3.3.4) catalyzes the six electron oxidation of protoporphyrinogen IX to protoporphyrin IX. The enzyme from the bacterium Myxococcus xanthus has been cloned, expressed, purified, and characterized. The protein has been expressed in Escherichia coli using a Tac promoter-driven expression plasmid and purified to apparent homogeneity in a rapid procedure that yields approximately 10 mg of purified protein per liter of culture. Based upon the deduced amino acid sequence the molecular weight of a single subunit is 49,387. Gel permeation chromatography in the presence of 0.2% n-octyl-beta-D-glucopyranoside yields a molecular weight of approximately 100,000 while SDS gel electrophoresis shows a single band at 50,000. The native enzyme is, thus, a homodimer. The purified protein contains a non-covalently bound FAD but no detectable redox active metal. The M. xanthus enzyme utilizes protoporphyrinogen IX, but not coproporphyrinogen III, as substrate and produces 3 mol of H2O2/mol of protoporphyrin. The apparent Km and kcat for protoporphyrinogen in assays under atmospheric concentrations of oxygen are 1.6 microM and 5.2 min-1, respectively. The diphenyl ether herbicide acifluorfen at 1 microM strongly inhibits the enzyme's activity.     

Random sequence mutagenesis and resistance to 5-fluorouridine in human thymidylate synthases

Thymidylate synthase (TS) catalyzes the methylation of dUMP to dTMP and is the target for the widely used chemotherapeutic agent 5-fluorouracil. We used random sequence mutagenesis to replace 13 codons within the active site of TS and obtain variants that are resistant to 5-fluorodeoxyuridine (5-FdUR). The resulting random library was selected for its ability to complement a TS-deficient Escherichia coli strain, and sequence analysis of survivors found multiple substitutions to be tolerable within the targeted region. An independent selection of the library was carried out in the presence of 5-FdUR, resulting in a more limited spectrum of mutations. One specific mutation, C199L, was observed in more than 46% of 5-FdUR-resistant clones. A 5-FdUR-resistant triple mutant, A197V/L198I/C199F, was purified to apparent homogeneity. Kinetic studies with the substrate dUMP indicate that this mutant is similar to the wild type in regards to kcat and Km values for dUMP and the cosubstrate CH2H4-folate. In contrast, equilibrium binding studies with the inhibitor, FdUMP, demonstrate that the dissociation constant (Kd) for FdUMP binding into the ternary complex was 20-fold higher than values obtained for the wild-type enzyme. This 5-FdUMP-resistant mutant, or others similarly selected, is a candidate for use in gene therapy to render susceptible normal cells resistant to the toxic effects of systemic 5-fluorouracil.