Use of peptide antibodies to probe for the mitoxantrone resistance-associated protein MXR/BCRP/ABCP/ABCG2

Previous kinetic characterization of Escherichia coli fructose 1,6-bisphosphatase (FBPase) was performed on enzyme with an estimated purity of only 50%. Contradictory kinetic properties of the partially purified E. coli FBPase have been reported in regard to AMP cooperativity and inactivation by fructose-2,6-bisphosphate. In this investigation, a new purification for E. coli FBPase has been devised yielding enzyme with purity levels as high as 98%. This highly purified E. coli FBPase was characterized and the data compared to that for the pig kidney enzyme. Also, a homology model was created based upon the known three-dimensional structure of the pig kidney enzyme. The kcat of the E. coli FBPase was 14.6 s(-1) as compared to 21 s(-1) for the pig kidney enzyme, while the K(m) of the E. coli enzyme was approximately 10-fold higher than that of the pig kidney enzyme. The concentration of Mg2+ required to bring E. coli FBPase to half maximal activity was estimated to be 0.62 mM Mg2+, which is twice that required for the pig kidney enzyme. Unlike the pig kidney enzyme, the Mg2+ activation of the E. coli FBPase is not cooperative. AMP inhibition of mammalian FBPases is cooperative with a Hill coefficient of 2; however, the E. coli FBPase displays no cooperativity. Although cooperativity is not observed, the E. coli and pig kidney enzymes show similar AMP affinity. The quaternary structure of the E. coli enzyme is tetrameric, although higher molecular mass aggregates were also observed. The homology model of the E. coli enzyme indicated slight variations in the ligand-binding pockets compared to the pig kidney enzyme. The homology model of the E. coli enzyme also identified significant changes in the interfaces between the subunits, indicating possible changes in the path of communication of the allosteric signal.     

High-level expression of fully active yeast flavocytochrome b2 in Escherichia coli.

Wild-type flavocytochrome b2 (L-lactate dehydrogenase) from the yeast Saccharomyces cerevisiae and three singly substituted mutant forms (F254, R349 and K376) have been expressed in the bacterium Escherichia coli. The enzyme expressed in E. coli contains the protohaem IX and flavin mononucleotide (FMN) prosthetic groups found in the enzyme isolated from yeast, has an electronic absorption spectrum identical with that of the yeast protein and an identical Mr value of 57,500 estimated by SDS/polyacrylamide-gel electrophoresis. N-Terminal amino-acid-sequence data indicate that the flavocytochrome b2 isolated from E. coli begins at position 6 (methionine) when compared with mature flavocytochrome b2 from yeast. The absence of the first five amino acid residues appears to have no effect on the enzyme-catalysed oxidation of L-lactate, since Km values for the yeast- and E. coli-expressed wild-type enzymes were identical within experimental error. The F254 mutant enzyme expressed in E. coli also showed kinetic parameters essentially the same as those found for the enzyme from yeast. The R349 and K376 mutant enzymes had no activity when expressed in either yeast or E. coli. The yield of flavocytochrome b2 from E. coli is estimated to be between 500- and 1000-fold more than from a similar wet weight of yeast (this high level of expression results in E. coli cells which are pink in colour). The increased yield has allowed us to verify the presence of FMN in the R349 mutant enzyme. The advantages of E. coli as an expression system for flavocytochrome b2 are discussed.     

Characterization of mutant TMK368K pig citrate synthase expressed in and isolated from Escherichia coli

A cDNA that encodes pig citrate synthase (PCS) was inserted into a plasmid T7 vector and was expressed in an E. coli gltA mutant. Up to 10 mg of purified PCS was obtained from 2 liters of E. coli. The mammalian protein produced in E. coli comigrated with the enzyme purified from pig heart on a SDS-polyacrylamide gel (SDS-PAGE) with an Mr of 50,000, and reacted with a polyclonal antibody directed against pig heart citrate synthase. The Vmax and Km of the expressed PCS were indistinguishable from those of the pig heart enzyme. The PCS produced in E. coli did not contain the trimethylation modification of Lys 368, characteristic of the pig heart enzyme. These data suggest that the PCS protein produced in E. coli is catalytically similar to the enzyme purified from pig heart and methylation of Lys 368 is not essential for catalysis.     

Human bisphosphoglycerate mutase expressed in E coli: purification, characterization and structure studies

Bisphosphoglycerate mutase (EC 5.4.2.4.) is an erythrocyte-specific enzyme whose main function is to synthesize 2,3-diphosphoglycerate (glycerate-2,3-P2) an effector of the delivery of O2 in the tissues. In addition to its main synthase activity the enzyme displays phosphatase and mutase activities both involving 2,3-diphosphoglycerate in their reaction. Using a prokaryotic expression system, we have developed a recombinant system producing human bisphosphoglycerate mutase in E coli. The expressed enzyme has been extracted and purified to homogeneity by 2 chromatographic steps. Purity of this enzyme was checked with sodium dodecyl sulfate polyacrylamide gel and Cellogel electrophoresis and structural studies. The bisphosphoglycerate mutase expressed in E coli was found to be very similar to that of human erythrocytes and showed identical trifunctionality, thermostability, immunological and kinetics' properties. However, the absence of a blocking agent on the N-terminus results in a slight difference of the electrophoretic mobility of the enzyme expressed in E coli compared to that of the erythrocyte.     

Extracellular production of phospholipase A2 from Streptomyces violaceoruber by recombinant Escherichia coli

Phospholipase A(2) (PLA(2)) from Streptomyces violaceoruber was successfully produced extracellularly in an active form by using a recombinant strain of Escherichia coli. The PLA(2) gene, which was artificially synthesized with optimized codons for E. coli and fused with pelB signal sequence, was expressed in E. coli using pET system. Most of the enzyme activity was detected in the culture supernatant with negligible activity in the cells. The recombinant enzyme was purified to homogeneity from the culture supernatant simply by ammonium sulfate precipitation and an anion exchange chromatography. The purified enzyme showed a specific activity comparable to that of the authentic enzyme. The recombinant enzyme had the same N-terminal amino acid sequence to that of the mature protein, indicating the correct removal of the signal peptide. An inactive PLA(2) with a mutation at the catalytic center was also secreted to the culture medium, suggesting that the observed secretion was not dependent on enzymatic activity. A simple screening method for the PLA(2)-producing colonies was established by detecting clear zone formation around the colonies on agar media containing lecithin. This is the first example of direct extracellular production of active PLA(2) by recombinant E. coli.     

Biosynthesis of bacterial glycogen. Kinetic studies of a glucose-1-phosphate adenylyltransferase (EC 2.7.7.27) from a glycogen-deficient mutant of Escherichia coli B.

An Escherichia coli B mutant, SG14, accumulates glycogen at 28% the rate observed for the parent E. coli B strain. The glycogen accumulated in the mutant is similar to the glycogen isolated from the parent strain with respect to alpha- and beta-amylosis, chain length determination, and I2-complex absorption spectra. The SG14 mutant contains normal glycogen synthase and branching enzyme activity but has an ADP-glucose pyrophosphorylase with altered kinetic and allosteric properties. The mutant enzyme has been partially purified and requires a 12-fold higher concentration of fructose-P2 or a 26 fold higher concentration of pyridoxal-P than the parent type enzyme for 50% of maximal allosteric activation. TPNH, an effective activator of the E. coli B enzyme, does not activate the SG14 ADP-glucose pyrophosphorylase. Other studies show that for the SG14 enzyme the concentrations of ATP and Mg2+ in the synthesis direction and the concentrations of ADP-glucose and PPi in the pyrophosphorolysis direction required to give 50% of maximal activity are 3- to 6-fold higher than those observed for the parent E. coli B ADP-glucose pyrophosphorylase. The Km for alpha-glucose-1-P at saturating to half-saturating concentrations of the activator, fructose-P2, are about the same for both enzymes. However, in the presence of no activator, the concentration of glucose-1-P required for half-maximal activity is about 1.8-fold higher for the SG14 enzyme. Thus SG14 ADP-glucose pyrophosphorylase has lower affinity for its substrates than does the parent enzyme. Previously the SG14 enzyme had been shown to be less sensitive to inhibition by 5'-AMP than the E. coli B enzyme. This ensensitivity to inhibition renders the SG14 enzyme less responsive to energy charge than the E. coli B ADP-glucose pyrophosphorylase. On the basis of the above results and taking into account the reported concentrations of fructose-P2, of pyridoxal-P, and of the adenine nucleotide pool and its energy charge in E. coli strains, it is concluded that furctose-P2 is the important physiological allosteric activator of E. coli ADP-glucose pyrophosphorylase. Furthermore, the 1.7-fold increased rate of accumulation of glycogen observed when E. coli B or SG14 shifts from exponential phase to stationary phase of growth in nitrogen-limiting media can be accounted for by the 2.4-fold increase of the levels of the glycogen biosynthetic enzymes, glycogen synthase, and ADP-glucose pyrophosphorylase. Thus both allosteric regulation of the ADP-glucose pyrophosphorylase as well as the genetic regulation of the biosynthesis of the glycogen biosynthetic enzymes are involved in the regulation of glycogen accumulation in E. coli B.     

Properties of D-arabinose isomerase purified from two strains of Escherichia coli

d-Arabinose isomerase (EC 5.3.1.3) has been isolated from l-fucose-induced cultures of Escherichia coli K-12 and d-arabinose-induced cultures of E. coli B/r. Both enzymes were homogeneous in an ultracentrifuge and migrated as single bands upon disc electrophoresis in acrylamide gels. The s(20,w) was 14.5 x 10(-13) sec for the E. coli K-12 enzyme and 14.3 x 10(-13) sec for the E. coli B/r enzyme. The molecular weight, determined by high-speed sedimentation equilibrium, was 3.55 +/- 0.06 x 10(5) for the E. coli K-12 enzyme and 3.42 +/- 0.04 x 10(5) for the enzyme isolated from E. coli B/r. Both enzyme preparations were active wth l-fucose or d-arabinose as substrates and showed no activity on any of the other aldopentoses or aldohexoses tested. With the E. coli K-12 enzyme, the K(m) was 2.8 x 10(-1)m for d-arabinose and 4.5 x 10(-2)m for l-fucose; with the E. coli B/r enzyme, the K(m) was 1.7 x 10(-1)m for d-arabinose and 4.2 x 10(-2)m for l-fucose. Both enzymes were inhibited by several of the polyalcohols tested, ribitol, l-arabitol, and dulcitol being the strongest. Both enzymes exhibited a broad plateau of optimal catalytic activity in the alkaline range. Both enzymes were stimulated by the presence of Mn(2+) or Co(2+) ions, but were strongly inhibited by the presence of Cd(2+) ions. Both enzymes were precipitated by antisera prepared against either enzyme preparation. The amino acid composition for both proteins has been determined; a striking similarity has been detected. Both enzymes could be dissociated, by protonation at pH 2 or by dialysis against buffer containing 8 m urea, into subunits that were homogeneous in an ultracentrifuge and migrated as single bands on disc electrophoresis in acrylamide gels containing urea. The molecular weight of the subunit, determined by high-speed sedimentation equilibrium, was 9.09 +/- 0.2 x 10(4) for the enzyme from E. coli K-12 and 8.46 +/- 0.1 x 10(4) for the enzyme from E. coli B/r. On the basis of biophysical studies, both isomerases appear to be oligomeric proteins consisting of four identical subunits.     

“Host Shutoff” Function of Bacteriophage T7: Involvement of T7 Gene 2 and Gene 0.7 in the Inactivation of Escherichia coli RNA Polymerase

The "host shutoff" function of bacteriophage T7 involves an inactivation of the host Escherichia coli RNA polymerase by an inhibitor protein bound to the enzyme. When this inhibitor protein, termed I protein, was removed from the inactive RNA polymerase complex prepared from T7-infected cells by glycerol gradient centrifugation in the presence of 1 M KCl, the enzyme recovered its activity equivalent to about 70 to 80% of the activity of the enzyme from uninfected cells. Analysis of the activity of E. coli RNA polymerase from E. coli cells infected with various T7 mutant phages indicated that the T7 gene 2 codes for the inhibitor I protein. The activity of E. coli RNA polymerase from gene 2 mutant phage-infected cells, which was about 70% of that from uninfected cells, did not increase after glycerol gradient centrifugation in the presence of 1 M KCl, indicating that the salt-removable inhibitor was not present with the enzyme. It was found that the reduction in E. coli RNA polymerase activity in cells infected with T7(+) or gene 2 mutant phage, i.e., about 70% of the activity of the enzyme compared to that from uninfected cells after glycerol gradient centrifugation in the presence of 1 M KCl, results from the function of T7 gene 0.7. E. coli RNA polymerase from gene 0.7 mutant phage-infected cells was inactive but recovered a full activity equivalent to that from uninfected cells after removal of the inhibitor I protein with 1 M KCl. E. coli RNA polymerase from the cells infected with newly constructed mutant phages having mutations in both gene 2 and gene 0.7 retained the full activity equivalent to that from uninfected cells with or without treatment of the enzyme with 1 M KCl. From these results, we conclude that both gene 2 and gene 0.7 of T7 are involved in accomplishing complete shutoff of the host E. coli RNA polymerase activity in T7 infection.     

Mutation of an essential glutamate residue in folylpolyglutamate synthetase and activation of the enzyme by pteroate binding

Site-directed mutagenesis was performed on Glu143, an essential amino acid in Lactobacillus casei folylpolyglutamate synthetase (FPGS) and the structurally equivalent residue, Glu146, in Escherichia coli FPGS. Glu143 is positioned near the P-loop and interacts with the Mg(2+) of Mg NTP-binding proteins. We have solved the structure of the E143A mutant of L. casei FPGS in the presence of AMPPCP and Mg(2+). The structure showed a water molecule at the place where Mg(2+) bound to the wild type enzyme. Mutant proteins E143A, and even E143D and E143Q with conservative mutations, lacked enzyme activity and failed to complement the methionine auxotrophy of the E. coli folC mutant SF4, showing that Glu143 is an essential residue. Both the L. casei and the E. coli FPGS mutant proteins bound methylene-tetrahydrofolate diglutamate and dihydropteroate normally. The E. coli E146Q mutant FPGS bound ADP with the same affinity as the wild type enzyme but bound ATP with much lower affinity and had higher ATPase activity than the wild type enzyme. The mutant enzyme was defective in forming the acyl-phosphate reaction intermediate from ATP and dihydropteroate. The E. coli FPGS requires activation by dihydropteroate or tetrahydrofolate binding to allow full activity. In the absence of a pteroate substrate, only 30% of the total enzyme binds ATP. We suggest that dihydropteroate causes a conformational change to allow increased ATP binding. The mutant enzyme was similarly activated by dihydropteroate resulting in increased ADP binding.     

Expression of the phospholipid-dependent Escherichia coli sn-1,2-diacylglycerol kinase in COS cells perturbs cellular lipid composition

The Escherichia coli sn-1,2-diacylglycerol (DAG) kinase has been successfully expressed in COS cells. The E. coli dgkA locus which contains the coding sequences for DAG kinase was subcloned into an eukaryotic expression vector, pMT2. COS cells transfected with the vector pMT2dgk expressed the DAG kinase as shown by Western analysis. Immunofluorescence studies revealed that the E. coli DAG kinase was prominently but not exclusively located in the endoplasmic reticulum. In addition, mixed micellar assays in beta-octyl glucoside revealed that membranes prepared from pMT2dgk-transfected COS cells contained over a 1500-fold increase in DAG kinase activity: 107 nmol/min/mg compared with only 0.067 nmol/min/mg for controls. DAG kinase activity from the E. coli enzyme was distinguished from endogenous COS cell activity based on differences in thermolability and the ability of the E. coli enzyme to use ceramide as a substrate. No ceramide kinase activity was detected in control COS cells, so the activity detected in pMT2dgk transfectants must have resulted from the expressed E. coli DAG kinase. The Km values for DAG kinase derived from E. coli and COS cells were nearly identical. Finally, transfected COS cells were labeled with [32P]Pi to investigate possible perturbations in lipid composition induced by the action of the E. coli DAG kinase. Ceramide (generated by the action of sphingomyelinase) was also used to clearly implicate the E. coli enzyme. Levels of ceramide phosphate increased more than 150-fold in pMT2dgk-transfected cells relative to controls. The results of these studies show that the E. coli enzyme expressed in COS cells is active and perturbs lipid composition in the intact cell system; the absolute lipid cofactor requirement of E. coli DAG kinase can be satisfied in COS cells.     

Structure of glutathione reductase from Escherichia coli at 1.86 A resolution: comparison with the enzyme from human erythrocytes.

The crystal structure of the dimeric flavoenzyme glutathione reductase from Escherichia coli was determined and refined to an R-factor of 16.8% at 1.86 A resolution. The molecular 2-fold axis of the dimer is local but very close to a possible crystallographic 2-fold axis; the slight asymmetry could be rationalized from the packing contacts. The 2 crystallographically independent subunits of the dimer are virtually identical, yielding no structural clue on possible cooperativity. The structure was compared with the well-known structure of the homologous enzyme from human erythrocytes with 52% sequence identity. Significant differences were found at the dimer interface, where the human enzyme has a disulfide bridge, whereas the E. coli enzyme has an antiparallel beta-sheet connecting the subunits. The differences at the glutathione binding site and in particular a deformation caused by a Leu-Ile exchange indicate why the E. coli enzyme accepts trypanothione much better than the human enzyme. The reported structure provides a frame for explaining numerous published engineering results in detail and for guiding further ones.     

Phenylalanine dehydrogenase of Bacillus badius. Purification, characterization and gene cloning

Phenylalanine dehydrogenase produced by Bacillus badius IAM 11059 was purified from the crude extract of B. badius to homogeneity, as judged by disc gel electrophoresis. The enzyme has an isoelectric point of 3.5 and a relative molecular mass, Mr, of 310,000-360,000. The enzyme is composed of identical subunits with an Mr 41,000-42,000. The substrate specificity of the enzyme in the oxidative deamination reaction was high for L-phenylalanine, but rather low in the reductive amination reaction, with phenylpyruvate, p-hydroxyphenylpyruvate, and 2-oxohexanoate. The gene for the enzyme was cloned into Escherichia coli with plasmid pBR322 as a vector. The enzyme was expressed in high level in E. coli. The enzyme produced by E. coli transformant was purified to homogeneity and shown to be identical to that of B. badius IAM 11,059 with respect to the specific activity, Mr, subunit structure and amino acid composition.     

Phospholipid dependence of homogeneous, reconstituted sn-glycerol-3-phosphate acyltransferase of Escherichia coli

A novel mixed micelle assay for the sn-glycerol-3-phosphate acyltransferase of Escherichia coli was developed using the nonionic detergent octaethylenegly-coldodecyl ether. The assay permitted investigation of the phospholipid dependence of enzyme activity at phospholipid/detergent ratios of 5:1 (w/w) to 2:1 depending on the phospholipid employed. The higher ratio yielded maximal activity when E. coli phospholipids were used; the lower ratio was observed with cardiolipin(E. coli). Phosphatidylglycerol(E. coli) and phosphatidylethanolamine(E. coli) also restored enzyme activity. Activation by phosphatidylethanolamine(E. coli) was pH-dependent and relatively inefficient. The synthetic, disaturated (1,2-palmitoyl)phosphatidylglycerol reconstituted only 25% of the total enzyme activity as that observed with the monounsaturated (1-palmitoyl, 2-oleoyl) species. Full activation of enzyme was achieved with (1,2-dioleoyl)phosphatidylglycerol. Phosphatidylcholine and phosphatidic acid were unable to reconstitute enzyme activity. Chromatographic sizing of the sn-glycerol-3-phosphate acyltransferase, following reconstitution in cardiolipin(E. coli)/octaethyleneglycoldodecyl ether mixed micelles, suggested that the monomeric form of the enzyme was active.     

Cation-induced thermostability of yeast and Escherichia coli pyrophosphatases

Inorganic pyrophosphatases (PPiases) from both yeast and Escherichia coli were found to be stable against heat denaturation in the presence of Mg2+, as previously observed with the enzymes from thermophilic bacteria. No loss of activity was observed after 1 h of incubation at 50 degrees C and pHs between 6 and 9 in the yeast enzyme, and at 60 degrees C and pHs between 7.2 and 9.2 in the E. coli enzyme. Such an induced thermostability of the E. coli enzyme was detected when Mn2+, Co2+, Ca2+, Cd2+, and Zn2+ were added in place of Mg2+. On the other hand, the degree of induced thermostability of the yeast enzyme was dependent upon the divalent cations used, and Ni2+ and Cu2+ accelerated the heat inactivation. On adding the divalent cations, the difference spectra of the E. coli enzyme always showed negative peaks in the ultraviolet region, but those of the yeast enzyme changed again depending upon the divalent cations. The circular dichroism spectra in the near ultraviolet region of both enzymes greatly differed from each other, but both were not affected so much by adding the divalent cations unlike the thermophilic enzymes from Bacillus stearothermophilus and thermophilic bacterium PS-3. Yeast and E. coli PPiases did not cross-link with the anti-immunoglobulin G's from the thermophilic enzymes, but the thermophilic enzymes did with each other's antisera. The results in the present study indicated that the conformation of PPiase, in which the aromatic amino acid residues were buried in the interior of the protein molecule, was very important for the thermostability and also that the protein structures of PPiases from B. stearothermophilus and thermophilic bacterium PS-3 were very similar to each other, but were very different from those of the mesophilic enzymes.     

Cloning and nucleotide sequence of a heat-stable amylase gene from an anaerobic thermophile, Dictyoglomus thermophilum

A highly heat-stable amylase gene from an obligately anaerobic and extremely thermophilic bacterium, Dictyoglomus thermophilum, was cloned and expressed in Escherichia coli. The nucleotide sequence of the amylase gene predicts a 686-amino-acid protein of relative molecular mass 81,200, which is consistent with that determined by sodium dodecyl sulfate/polyacrylamide gel electrophoresis of the purified enzyme. The NH2-terminal sequence determined using the enzyme purified from E. coli cells corresponds precisely to that predicted from the nucleotide sequence, except for the absence of the NH2-terminal methionine in the mature protein. When the amylase gene was expressed in E. coli cells, the enzyme was localized in the cytoplasmic fraction; this is probably explained by the absence of the signal sequence for secretion. By using the amylase purified from the E. coli transformant, some enzymatic properties, such as optimum pH, optimum temperature, pH-stability and heat-stability, were examined. The amylase was found to be a highly liquefying-type.     

Purification and characterization of the hydantoin racemase of Pseudomonas sp. strain NS671 expressed in Escherichia coli.

The hydantoin racemase gene of Pseudomonas sp. strain NS671 had been cloned and expressed in Escherichia coli. Hydantoin racemase was purified from the cell extract of the E. coli strain by phenyl-Sepharose, DEAE-Sephacel, and Sephadex G-200 chromatographies. The purified enzyme had an apparent molecular mass of 32 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. By gel filtration, a molecular mass of about 190 kDa was found, suggesting that the native enzyme is a hexamer. The optimal conditions for hydantoin racemase activity were pH 9.5 and a temperature of 45 degrees C. The enzyme activity was slightly stimulated by the addition of not only Mn2+ or Co2+ but also metal-chelating agents, indicating that the enzyme is not a metalloenzyme. On the other hand, Cu2+ and Zn2+ strongly inhibited the enzyme activity. Kinetic studies showed substrate inhibition, and the Vmax values for D- and L-5-(2-methylthioethyl)hydantoin were 35.2 and 79.0 mumol/min/mg of protein, respectively. The purified enzyme did not racemize 5-isopropylhydantoin, whereas the cells of E. coli expressing the enzyme are capable of racemizing it. After incubation of the purified enzyme with 5-isopropylhydantoin, the enzyme no longer showed 5-(2-methylthioethyl)hydantoin-racemizing activity. However, in the presence of 5-(2-methylthioethyl)hydantoin, the purified enzyme racemized 5-isopropylhydantoin completely, suggesting that 5-(2-methylthioethyl)hydantoin protects the enzyme from inactivation by 5-isopropylhydratoin. Thus, we examined the protective effect of various compounds and found that divalent-sulfur-containing compounds (R-S-R' and R-SH) have this protective effect.     

A comparison of the citrate synthases of Escherichia coli and Acinetobacter anitratum

Citrate synthase has been purified to homogeneity from a strain of the Gram-negative aerobic bacterium Acinetobacter anitratum in a form which retains its sensitivity to the allosteric inhibitor NADH. In subunit size, amino acid composition, and antigenic reactivity the enzyme shows a marked structural resemblance to the citrate synthase of the Gram-negative facultative anaerobe Escherichia coli. Whereas the E. coli enzyme is subject to a strong, hyperbolic inhibition by NADH (Hill's number n = 1.0, Ki = 2 microM), the A. anitratum enzyme shows a weak, sigmoid response (n = 1.6, I0.5 = 140 microM) to this nucleotide. With E. coli, NADH inhibition is competitive with acetyl-CoA, and noncompetitive with oxaloacetate; with A. anitratum, NADH is noncompetitive with both substrates. Acinetobacter anitratum citrate synthase shows hyperbolic saturation with acetyl-CoA (n = 1.8). The finding of Weitzman and Jones (Nature (London) 219, 270 (1968) that NADH inhibition of the enzyme from Acinetobacter spp. is reversible by AMP, while that from E. coli is not, is explained by the much greater affinity of the E. coli enzyme for NADH. Unlike E. coli citrate synthase, the A. anitratum enzyme does not react with the sulfhydryl reagent 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) in the absence of denaturation. With a second sulfhydryl reagent, 4,4'-dithiodipyridine (4,4'-PDS), the A. anitratum enzyme reacts with 1 equiv. of subunit; this modification induces a partial activity loss (attributable to a arise in the Km for acetyl-CoA) and an increase in the sensitivity to NADH. With the E. coli enzyme, 4,4'-PDS causes complete inactivation. Acinetobacter anitratum citrate synthase is much more resistant to urea denaturation than the E. coli enzyme is; the resistance of both enzymes to urea is greatly improved in the presence of 1 M KCl. It is suggested that the amino acid sequences of the subunits of the citrate synthases of these two bacteria are about 90% homologous, and that the 10% differences are in key residues, perhaps largely in the subunit contact regions, which account for the differences in allosteric properties.     

Amino acid composition and N-terminal sequence of the NADP-linked glutamate dehydrogenase from Trypanosoma cruzi

Abstract The NADP-linked glutamate dehydrogenase (NADP-GDH) from epimastigotes of Trypanosoma cruzi , Tul 2 stock, has been purified by an improved procedure. The enzyme has subunit molecular weight (47 kDa), amino acid composition and N-terminal sequence similar to those of the NADP-GDH from Escherichia coli , including the N-terminal extension of 15 amino acids present in the E. coli enzyme, but not in the NADP-GDH from Neurospora crassa .