Inhibitor binding studies on enoyl reductase reveal conformational changes related to substrate recognition.

Enoyl acyl carrier protein reductase (ENR) is involved in fatty acid biosynthesis. In Escherichia coli this enzyme is the target for the experimental family of antibacterial agents, the diazaborines, and for triclosan, a broad spectrum antimicrobial agent. Biochemical studies have suggested that the mechanism of diazaborine inhibition is dependent on NAD(+) and not NADH, and resistance of Brassica napus ENR to diazaborines is thought to be due to the replacement of a glycine in the active site of the E. coli enzyme by an alanine at position 138 in the plant homologue. We present here an x-ray analysis of crystals of B. napus ENR A138G grown in the presence of either NAD(+) or NADH and the structures of the corresponding ternary complexes with thienodiazaborine obtained either by soaking the drug into the crystals or by co-crystallization of the mutant with NAD(+) and diazaborine. Analysis of the ENR A138G complex with diazaborine and NAD(+) shows that the site of diazaborine binding is remarkably close to that reported for E. coli ENR. However, the structure of the ternary ENR A138G-NAD(+)-diazaborine complex obtained using co-crystallization reveals a previously unobserved conformational change affecting 11 residues that flank the active site and move closer to the nicotinamide moiety making extensive van der Waals contacts with diazaborine. Considerations of the mode of substrate binding suggest that this conformational change may reflect a structure of ENR that is important in catalysis.     

A study of the structure-activity relationship for diazaborine inhibition of Escherichia coli enoyl-ACP reductase

Enoyl acyl carrier protein (ACP) reductase catalyses the last reductive step of fatty acid biosynthesis, reducing the enoyl group of a growing fatty acid chain attached to ACP to its acyl product using NAD(P)H as the cofactor. This enzyme is the target for the diazaborine class of antibacterial agents, the biocide triclosan, and one of the targets for the front-line anti-tuberculosis drug isoniazid. The structures of complexes of Escherichia coli enoyl-ACP reductase (ENR) from crystals grown in the presence of NAD+ and a family of diazaborine compounds have been determined. Analysis of the structures has revealed that a mobile loop in the structure of the binary complex with NAD+ becomes ordered on binding diazaborine/NAD+ but displays a different conformation in the two subunits of the asymmetric unit. The work presented here reveals how, for one of the ordered conformations adopted by the mobile loop, the mode of diazaborine binding correlates well with the activity profiles of the diazaborine family. Additionally, diazaborine binding provides insights into the pocket on the enzyme surface occupied by the growing fatty acid chain.     

Structural basis and mechanism of enoyl reductase inhibition by triclosan.

The enoyl-acyl carrier protein reductase (ENR) is involved in bacterial fatty acid biosynthesis and is the target of the antibacterial diazaborine compounds and the front-line antituberculosis drug isoniazid. Recent studies suggest that ENR is also the target for the broad-spectrum biocide triclosan. The 1.75 A crystal structure of EnvM, the ENR from Escherichia coli, in complex with triclosan and NADH reveals that triclosan binds specifically to EnvM. These data provide a molecular mechanism for the antibacterial activity of triclosan and substantiate the hypothesis that its activity results from inhibition of a specific cellular target rather than non-specific disruption of the bacterial cell membrane. This has important implications for the emergence of drug-resistant bacteria, since triclosan is an additive in many personal care products such as toothpastes, mouthwashes and soaps. Based on this structure, rational design of triclosan derivatives is possible which might be effective against recently identified triclosan-resistant bacterial strains.     

Homology of Escherichia coli B glutathione synthetase with dihydrofolate reductase in amino acid sequence and substrate binding site

Glutathione synthetase from Escherichia coli B showed amino acid sequence homology with mammalian and bacterial dihydrofolate reductases over 40 residues, although these two enzymes are different in their reaction mechanisms and ligand requirements. The effects of ligands of dihydrofolate reductase on the reaction of E. coli B glutathione synthetase were examined to find resemblances in catalytic function to dihydrofolate reductase. The E. coli B enzyme was potently inhibited by 7,8-dihydrofolate, methotrexate, and trimethoprim. Methotrexate was studied in detail and proved to bind to an ATP binding site of the E. coli B enzyme with K1 value of 0.1 mM. The homologous portion of the amino acid sequence in dihydrofolate reductases, which corresponds to the portion coded by exon 3 of mammalian dihydrofolate reductase genes, provided a binding site of the adenosine diphosphate moiety of NADPH in the crystal structure of dihydrofolate reductase. These analyses would indicate that the homologous portion of the amino acid sequence of the E. coli B enzyme provides the ATP binding site. This report gives experimental evidence that amino acid sequences related by sequence homology conserve functional similarity even in enzymes which differ in their catalytic mechanisms.     

New properties of Bacillus subtilis succinate dehydrogenase altered at the active site. The apparent active site thiol of succinate oxidoreductases is dispensable for succinate oxidation.

Mammalian and Escherichia coli succinate dehydrogenase (SDH) and E. coli fumarate reductase apparently contain an essential cysteine residue at the active site, as shown by substrate-protectable inactivation with thiol-specific reagents. Bacillus subtilis SDH was found to be resistant to this type of reagent and contains an alanine residue at the amino acid position equivalent to the only invariant cysteine in the flavoprotein subunit of E. coli succinate oxidoreductases. Substitution of this alanine, at position 252 in the flavoprotein subunit of B. subtilis SDH, by cysteine resulted in an enzyme sensitive to thiol-specific reagents and protectable by substrate. Other biochemical properties of the redesigned SDH were similar to those of the wild-type enzyme. It is concluded that the invariant cysteine in the flavoprotein of E. coli succinate oxidoreductases corresponds to the active site thiol. However, this cysteine is most likely not essential for succinate oxidation and seemingly lacks an assignable specific function. An invariant arginine in juxtaposition to Ala-252 in the flavoprotein of B. subtilis SDH, and to the invariant cysteine in the E. coli homologous enzymes, is probably essential for substrate binding.     

Divergent allosteric patterns verify the regulatory paradigm for aspartate transcarbamylase

The native Escherichia coli aspartate transcarbamoylase (ATCase, E.C. 2.1.3.2) provides a classic allosteric model for the feedback inhibition of a biosynthetic pathway by its end products. Both E. coli and Erwinia herbicola possess ATCase holoenzymes which are dodecameric (2(c3):3(r2)) with 311 amino acid residues per catalytic monomer and 153 and 154 amino acid residues per regulatory (r) monomer, respectively. While the quaternary structures of the two enzymes are identical, the primary amino acid sequences have diverged by 14 % in the catalytic polypeptide and 20 % in the regulatory polypeptide. The amino acids proposed to be directly involved in the active site and nucleotide binding site are strictly conserved between the two enzymes; nonetheless, the two enzymes differ in their catalytic and regulatory characteristics. The E. coli enzyme has sigmoidal substrate binding with activation by ATP, and inhibition by CTP, while the E. herbicola enzyme has apparent first order kinetics at low substrate concentrations in the absence of allosteric ligands, no ATP activation and only slight CTP inhibition. In an apparently important and highly conserved characteristic, CTP and UTP impose strong synergistic inhibition on both enzymes. The co-operative binding of aspartate in the E. coli enzyme is correlated with a T-to-R conformational transition which appears to be greatly reduced in the E. herbicola enzyme, although the addition of inhibitory heterotropic ligands (CTP or CTP+UTP) re-establishes co-operative saturation kinetics. Hybrid holoenzymes assembled in vivo with catalytic subunits from E. herbicola and regulatory subunits from E. coli mimick the allosteric response of the native E. coli holoenzyme and exhibit ATP activation. The reverse hybrid, regulatory subunits from E. herbicola and catalytic subunits from E. coli, exhibited no response to ATP. The conserved structure and diverged functional characteristics of the E. herbicola enzyme provides an opportunity for a new evaluation of the common paradigm involving allosteric control of ATCase.     

cDNA cloning of rice lipoxygenase L-2 and characterization using an active enzyme expressed from the cDNA in Escherichia coli.

A full-length cDNA of rice lipoxygenase L-2 was cloned from 3-day-old seedlings. The identity of the clone was determined by amino acid sequencing of selected peptides of the purified enzyme and immunological characterization of an active enzyme that was produced from the cDNA in Escherichia coli by cultivation at 15 degrees C. The nucleotide sequence showed a strong bias toward G and C in the selection of nucleotides, especially at the third position of the codons (93% G/C). The complete amino acid sequence of the enzyme was deduced from the nucleotide sequence. The molecular mass of the enzyme was calculated to be 96,657 Da based on 865 amino acids. The amino acid sequence shares similarity with those of dicot lipoxygenases throughout the enzyme at a level of 50%. A hydropathy profile calculated from the amino acid sequence resembled those of dicot lipoxygenases, suggesting conservation of the secondary structure of these enzymes. The active enzyme, expressed in Escherichia coli, was characterized for pH dependence of the enzyme activity, intramolecular specificity, heat stability and Km. The enzyme had the same properties as the L-2 enzyme that was isolated from seedlings, but differed from the lipoxygenase L-3 isolated from mature plants.     

Effect of substrate binding loop mutations on the structure, kinetics, and inhibition of enoyl acyl carrier protein reductase from Plasmodium falciparum

Enoyl acyl carrier protein reductase (ENR), which catalyzes the final and rate limiting step of fatty acid elongation, has been validated as a potential drug target. Triclosan is known to be an effective inhibitor for this enzyme. We mutated the substrate binding site residue Ala372 of the ENR of Plasmodium falciparum (PfENR) to Methionine and Valine which increased the affinity of the enzyme towards triclosan to almost double, close to that of Escherichia coli ENR (EcENR) which has a Methionine at the structurally similar position of Ala372 of PfENR. Kinetic studies of the mutants of PfENR and the crystal structure analysis of the A372M mutant revealed that a more hydrophobic environment enhances the affinity of the enzyme for the inhibitor. A triclosan derivative showed a threefold increase in the affinity towards the mutants compared to the wild type, due to additional interactions with the A372M mutant as revealed by the crystal structure. The enzyme has a conserved salt bridge which stabilizes the substrate binding loop and appears to be important for the active conformation of the enzyme. We generated a second set of mutants to check this hypothesis. These mutants showed loss of function, except in one case, where the crystal structure showed that the substrate binding loop is stabilized by a water bridge network.     

Crystallographic analysis of triclosan bound to enoyl reductase

Molecular genetic studies with strains of Escherichia coli resistant to triclosan, an ingredient of many anti-bacterial household goods, have suggested that this compound works by acting as an inhibitor of enoyl reductase (ENR) and thereby blocking lipid biosynthesis. We present structural analyses correlated with inhibition data, on the complexes of E. coli and Brassica napus ENR with triclosan and NAD(+) which reveal how triclosan acts as a site-directed, picomolar inhibitor of the enzyme by mimicking its natural substrate. Elements of both the protein and the nucleotide cofactor play important roles in triclosan recognition, providing an explanation for the factors controlling its tight binding to the enzyme and for the emergence of triclosan resistance.     

Altering of the metal specificity of Escherichia coli alkaline phosphatase

Analysis of sequence alignments of alkaline phosphatases revealed a correlation between metal specificity and certain amino acid side chains in the active site that are metal-binding ligands. The Zn(2+)-requiring Escherichia coli alkaline phosphatase has an Asp at position 153 and a Lys at position 328. Co(2+)-requiring alkaline phosphatases from Thermotoga maritima and Bacillus subtilis have a His and a Trp at these positions, respectively. The mutations D153H, K328W, and D153H/K328W were induced in E. coli alkaline phosphatase to determine whether these residues dictate the metal dependence of the enzyme. The wild-type and D153H enzymes showed very little activity in the presence of Co(2+), but the K328W and especially the D153H/K328W enzymes effectively use Co(2+) for catalysis. Isothermal titration calorimetry experiments showed that in all cases except for the D153H/K328W enzyme, a possible conformation change occurs upon binding Co(2+). These data together indicate that the active site of the D153H/K328W enzyme has been altered significantly enough to allow the enzyme to utilize Co(2+) for catalysis. These studies suggest that the active site residues His and Trp at the E. coli enzyme positions 153 and 328, respectively, at least partially dictate the metal specificity of alkaline phosphatase.     

Mutational analysis of amino acid residues involved in catalytic activity of a family 18 chitinase from tulip bulbs

We expressed chitinase-1 (TBC-1) from tulip bulbs (Tulipa bakeri) in E. coli cells and used site-directed mutagenesis to identify amino acid residues essential for catalytic activity. Mutations at Glu-125 and Trp-251 completely abolished enzyme activity, and activity decreased with mutations at Asp-123 and Trp-172 when glycolchitin was the substrate. Activity changed with the mutations of Trp-251 to one of several amino acids with side-chains of little hydrophobicity, suggesting that hydrophobic interaction of Trp-251 is important for the activity. Molecular dynamics (MD) simulation analysis with hevamine as the model compound showed that the distance between Asp-123 and Glu-125 was extended by mutation of Trp-251. Kinetic studies of Trp-251-mutated chitinases confirmed these various phenomena. The results suggested that Glu-125 and Trp-251 are essential for enzyme activity and that Trp-251 had a direct role in ligand binding.     

Characterization of a novel enoyl-acyl carrier protein reductase of diazaborine-resistant Rhodobacter sphaeroides mutant

Rhodobacter sphaeroides contains two enoyl-acyl carrier protein (ACP) reductases, FabI(1) and FabI(2). However, FabI(1) displays most of the cellular enzyme activity. The spontaneous diazaborine-resistant mutation was mapped as substitution of glutamine for proline 155 (P155Q) of FabI(1). The mutation of FabI(1)[P155Q] increased the specificity constants (k(cat)/K(m)) for crotonyl-ACP and NADH by more than 2-fold, while the site-directed mutation G95S (FabI(1)[G95S]), corresponding to the well-known G93 mutation of Escherichia coli FabI, rather decreased the values. Inhibition kinetics of the enzymes revealed that triclosan binds to the enzyme in the presence of NAD(+), while the diazaborine appears to interact with NADH and NAD(+) in the enzyme active site. The apparent inhibition constant K(i)(') of triclosan for FabI(1)[P155Q] and FabI(1)[G95S] at saturating NAD(+) were approximately 80- and 3-fold higher than that for the wild-type enzyme, respectively, implying that the inhibition was remarkably impaired by the P155Q mutation. The similar levels of K(i)(') of diazaborine for the mutant enzymes were also observed with respect to NAD(+). Thus, the novel mutation P155Q appears to disturb the binding of inhibitors to the enzyme without affecting the catalytic efficiency.     

Site-directed mutagenesis of the phosphate-binding consensus sequence in Escherichia coli adenylosuccinate synthetase.

Adenylosuccinate synthetases from different sources contain an N-terminal glycine-rich sequence GDEGKGK, which is homologous to the conserved sequence GXXXXGK found in many other guanine nucleotide-binding proteins or enzymes. To determine the role of this sequence in the structure and function of Escherichia coli adenylosuccinate synthetase, site-directed mutagenesis was performed to generate five mutant enzymes: G12V (Gly12----Val), G15V (Gly15----Val), G17V (Gly17----Val), K18R (Lys18----Arg), and I19T (Ile19----Thr). Comparison of the kinetic properties of the wild-type enzyme and those of the mutant enzymes revealed that the sequence is critical for enzyme activity. Replacement of Gly12, Gly15, or Gly17 with Val, or replacement of Lys18 with Arg, resulted in significant decreases in the kcat/Km values of the enzyme. Because the consensus sequence GXXXXGK(T/S) has been found in many GTP-binding proteins, isoleucine at position 19 in the E. coli adenylosuccinate synthetase was changed to threonine to produce the sequence GDEGKGKT. This mutation, which more closely resembles the consensus sequence, resulted in a 160-fold increase in the Km value for substrate GTP; however, there were no great changes for the other two substrates, IMP and aspartate. Based on these data, we suggest that the N-terminal glycinerich sequence in E. coli adenylosuccinate synthetase plays a more important role in enzyme catalysis than in substrate binding. In addition, a hydrophobic amino acid residue such as isoleucine, leucine, or valine, rather than threonine, may play a critical role in GTP binding in adenosuccinate synthetase. These findings suggest that the glycine-rich sequence in adenylosuccinate synthetase functions differently relative to those in other GTP binding proteins or enzymes.     

Characterization of two independent amino acid substitutions that disrupt the DNA repair functions of the yeast Apn1

The members of the Endo IV family of DNA repair enzymes, including Saccharomyces cerevisiae Apn1 and Escherichia coli endonuclease IV, possess the capacity to cleave abasic sites and to remove 3'-blocking groups at single-strand breaks via apurinic/apyrimidinic (AP) endonuclease and 3'-diesterase activities, respectively. In addition, Endo IV family members are able to recognize and incise oxidative base damages on the 5'-side of such lesions. We previously identified eight amino acid substitutions that prevent E. coli endonuclease IV from repairing damaged DNA in vivo. Two of these substitutions were glycine replacements of Glu145 and Asp179. Both Glu145 and Asp179 are among nine amino acid residues within the active site pocket of endonuclease IV that coordinate the position of a trinuclear Zn cluster required for efficient phosphodiester bond cleavage. We now report the first structure-function analysis of the eukaryotic counterpart of endonuclease IV, yeast Apn1. We show that glycine substitutions at the corresponding conserved amino acid residues of yeast Apn1, i.e., Glu158 and Asp192, abolish the biological function of this enzyme. However, these Apn1 variants do not exhibit the same characteristics as the corresponding E. coli mutants. Indeed, the Apn1 Glu158Gly mutant, but not the E. coli endonuclease IV Glu145Gly mutant, is able to bind DNA. Moreover, Apn1 Asp192Gly completely lacks enzymatic activity, while the activity of the E. coli counterpart Asp179Gly is reduced by approximately 40-fold. The data suggest that although yeast Apn1 and E. coli endonuclease IV exhibit a high degree of structural and functional similarity, differences exist within the active site pockets of these two enzymes.     

Substrate recognition and selectivity of peptide deformylase. Similarities and differences with metzincins and thermolysin.

The substrate specificity of Escherichia coli peptide deformylase was investigated by measuring the efficiency of the enzyme to cleave formyl- peptides of the general formula Fo-Xaa-Yaa-NH2, where Xaa represents a set of 27 natural and unusual amino acids and Yaa corresponds to a set of 19 natural amino acids. Substrates with bulky hydrophobic side-chains at the P1' position were the most efficiently cleaved, with catalytic efficiencies greater by two to five orders of magnitude than those associated with polar or charged amino acid side-chains. Among hydrophobic side-chains, linear alkyl groups were preferred at the P1' position, as compared to aryl-alkyl side-chains. Interestingly, in the linear alkyl substituent series, with the exception of norleucine, deformylase exhibits a preference for the substrate containing Met in the P1' position. Next, the influence in catalysis of the second side-chain was studied after synthesis of 20 compounds of the formula Fo-Nle-Yaa-NH2. Their deformylation rates varied within a range of only one order of magnitude. A 3D model of the interaction of PDF with an inhibitor was then constructed and revealed indeed the occurrence of a deep and hydrophobic S1' pocket as well as the absence of a true S2' pocket. These analyses pointed out a set of possible interactions between deformylase and its substrates, which could be the ground driving substrate specificity. The validity of this enzyme:substrate docking was further probed with the help of a set of site-directed variants of the enzyme. From this, the importance of residues at the bottom of the S1' pocket (Ile128 and Leu125) as well as the hydrogen bond network that the main chain of the substrate makes with the enzyme were revealed. Based on the numerous homologies that deformylase displays with thermolysin and metzincins, a mechanism of enzyme:substrate recognition and hydrolysis could finally be proposed. Specific features of PDF with respect to other members of the enzymes with motif HEXXH are discussed.     

Glutamic acid residues as metal ligands in the active site of Escherichia coli alkaline phosphatase

Four independent mutations were introduced to the Escherichia coli alkaline phosphatase active site, and the resulting enzymes characterized to study the effects of Glu as a metal ligand. The mutations D51E and D153E were created to study the effects of lengthening the carboxyl group by one methylene unit at the metal interaction site. The D51E enzyme had drastically reduced activity and lost one zinc per active site, demonstrating importance of the position of Asp(51). The D153E enzyme had an increased k(cat) in the presence of high concentrations of Mg(2+), along with a decreased Mg(2+) affinity as compared to the wild-type enzyme. The H331E and H412E enzymes were created to probe the requirement for a nitrogen-containing metal ligand at the Zn(1) site. The H331E enzyme had greatly decreased activity, and lost one zinc per active site. In the absence of high concentrations of Zn(2+), dephosphorylation occurs at an extremely reduced rate for the H412E enzyme, and like the H331E enzyme, metal affinity is reduced. Except at the 153 position, Glu is not an acceptable metal chelating amino acid at these positions in the E. coli alkaline phosphatase active site.     

envM genes of Salmonella typhimurium and Escherichia coli.

Conjugation and bacteriophage P1 transduction experiments in Escherichia coli showed that resistance to the antibacterial compound diazaborine is caused by an allelic form of the envM gene. The envM gene from Salmonella typhimurium was cloned and sequenced. It codes for a 27,765-dalton protein. The plasmids carrying this DNA complemented a conditionally lethal envM mutant of E. coli. Recombinant plasmids containing gene envM from a diazaborine-resistant S. typhimurium strain conferred the drug resistance phenotype to susceptible E. coli cells. A guanine-to-adenine exchange in the envM gene changing a Gly codon to a Ser codon was shown to be responsible for the resistance character. Upstream of envM a small gene coding for a 10,445-dalton protein was identified. Incubating a temperature-sensitive E. coli envM mutant at the nonpermissive temperature caused effects on the cells similar to those caused by treatment with diazaborine, i.e., inhibition of fatty acid, phospholipid, and lipopolysaccharide biosynthesis, induction of a 28,000-dalton inner membrane protein, and change in the ratio of the porins OmpC and OmpF.     

Comparison of the aspartate transcarbamoylases from Serratia marcescens and Escherichia coli

The aspartate transcarbamoylases (ATCase, EC 2.1.3.2) of Escherichia coli and Serratia marcescens have similar dodecameric enzyme structures (2(c3):3(r2] but differ in both regulatory and catalytic characteristics. The catalytic cistrons (pyrB) of the ATCases from E. coli and S. marcescens encode polypeptides of 311 and 306 amino acids, respectively; there is a 76% identity between the DNA sequences and an overall amino acid homology of 88% (38 differences). The regulatory cistrons (pyrI) of these ATCases encode polypeptides of 153 and 154 amino acids, respectively, and there is a 75% identity between the DNA sequences and an overall amino acid homology of 77% (36 differences). In both species, the two genes are arranged as a bicistronic operon, with pyrB promoter proximal. A comparison of the deduced amino acid sequences reveals that the active site and the allosteric binding sites, as well as most of the intrasubunit interactions and intersubunit associations, are conserved in the E. coli and the S. marcescens enzymes; however, there are specific differences which undoubtedly contribute to the catalytic and regulatory differences between the enzymes of the two species. These differences include residues that have been implicated in the T-R transition, c1:r1 interface interactions, and the CTP binding site. A hybrid ATCase assembled in vivo with catalytic subunits from E. coli and regulatory subunits from S. marcescens has a 6 mM requirement for aspartate at half-maximal saturation, similar to the 5.5 mM aspartate requirement of the native E. coli holoenzyme at half-maximal saturation. However, the heterotropic response of this hybrid enzyme is characteristic of the heterotropic response of the native S. marcescens holoenzyme: ATP activation and CTP activation. Activation by both allosteric effectors indicates that the heterotropic response of this hybrid holoenzyme (Cec:Rsm) is determined by the associated S. marcescens regulatory subunits.     

Aminoacylation of tRNAs as critical step of protein biosynthesis.

Isoleucyl-tRNA synthetases isolated from commercial baker's yeast and E coli were investigated for their sequences of substrate additions and product releases. The results show that aminoacylation of tRNA is catalyzed by these enzymes in different pathways, eg isoleucyl-tRNA synthetase from yeast can act with four different catalytic cycles. Amino acid specificities are gained by a four-step recognition process consisting of two initial binding and two proofreading steps. Isoleucyl-tRNA synthetase from yeast rejects noncognate amino acids with discrimination factors of D = 300-38000, isoleucyl-tRNA synthetase from E coli with factors of D = 600-68000. Differences in Gibbs free energies of binding between cognate and noncognate amino acids are related to different hydrophobic interaction energies and assumed conformational changes of the enzyme. A simple hypothetical model of the isoleucine binding site is postulated. Comparison of gene sequences of isoleucyl-tRNA synthetase from yeast and E coli exhibits only 27% homology. Both genes show the 'HIGH'- and 'KMSKS'-regions assigned to binding of ATP and tRNA. Deletion of 250 carboxyterminal amino acids from the yeast enzyme results in a fragment which is still active in the pyrophosphate exchange reaction but does not catalyze the aminoacylation reaction. The enzyme is unable to catalyze the latter reaction if more than 10 carboxyterminal residues are deleted.     

Structural studies on aspartate aminotransferase from Escherichia coli. Covalent structure

The amino acid sequence of aspartate aminotransferase from Escherichia coli was established by sequence analysis and alignment of 39 tryptic peptides and 7 cyanogen bromide peptides. The total number of amino acid residues of the subunit was 396, and the molecular weight was calculated to be 43,573. A comparison of the primary structure of the E. coli enzyme with all known sequences of the two types of isoenzyme (mitochondrial and cytosolic enzymes) in vertebrates revealed that approximately 25% of all residues are invariant. The amino acid residues which were proposed from crystallographic studies on the vertebrate enzymes to be essential for the enzymic action are well conserved in the E. coli enzyme. The E. coli enzyme shows a similar degree of sequence homology to both the mitochondrial and cytosolic isoenzymes (close to 40%). The finding that the positions of deletions introduced into the sequence of E. coli enzyme to give the maximum homology agree well with those of the mitochondrial enzymes supports the endosymbiotic hypothesis of mitochondrial origin.