Amplification and modification of dihydrofolate reductase in Escherichia coli. Nucleotide sequence of fol genes from mutationally altered plasmids

Light producing reporter plasmids for Escherichia coli K-12 that can be integrated into the chromosome

Plasmid vectors using the Photorhabdus luminescenslux operon can be used for real time measurements of promoter activity. We have generated a series of lux vectors that have a conditional origin of replication, different selectable markers and the attP sequence from λ. Single copies of these plasmids can be integrated into the λ attachment site in the Escherichia coli chromosome. We constructed reporter derivatives and compared light production when the plasmids were present in multiple copies and in single copies. We also demonstrated that expression could be induced under the appropriate conditions.

folA, a new member of the TyrR regulon in Escherichia coli K-12

The folA gene was identified as a new member of the TyrR regulon by genomic SELEX. Binding of TyrR to two sites in folA activated its transcription. Mutations in the N-terminal or central domain of TyrR, the alpha subunit of RNA polymerase, or integration host factor all abolished activation of the folA promoter.

Overexpression of inhA, but not kasA, confers resistance to isoniazid and ethionamide in Mycobacterium smegmatis, M. bovis BCG and M. tuberculosis

The inhA and kasA genes of Mycobacterium tuberculosis have each been proposed to encode the primary target of the antibiotic isoniazid (INH). Previous studies investigating whether overexpressed inhA or kasA could confer resistance to INH yielded disparate results. In this work, multicopy plasmids expressing either inhA or kasA genes were transformed into M. smegmatis, M. bovis BCG and three different M. tuberculosis strains. The resulting transformants, as well as previously published M. tuberculosis strains with multicopy inhA or kasAB plasmids, were tested for their resistance to INH, ethionamide (ETH) or thiolactomycin (TLM). Mycobacteria containing inhA plasmids uniformly exhibited 20-fold or greater increased resistance to INH and 10-fold or greater increased resistance to ETH. In contrast, the kasA plasmid conferred no increased resistance to INH or ETH in any of the five strains, but it did confer resistance to thiolactomycin, a known KasA inhibitor. INH is known to increase the expression of kasA in INH-susceptible M. tuberculosis strains. Using molecular beacons, quantified inhA and kasA mRNA levels showed that increased inhA mRNA levels corre--lated with INH resistance, whereas kasA mRNA levels did not. In summary, analysis of strains harbouring inhA or kasA plasmids yielded the same conclusion: overexpressed inhA, but not kasA, confers INH and ETH resistance to M. smegmatis, M. bovis BCG and M. tuberculosis. Therefore, InhA is the primary target of action of INH and ETH in all three species.

Dihydropteridine reductase from Escherichia coli exhibits dihydrofolate reductase activity

E. coli Dihydropteridine reductase, known to have a pterin-independent oxidoreductase activity with potassium ferricyanide as electron donor, has now been shown to possess also dihydrofolate reductase activity. The kinetic parameters for dihydrofolate reductase activity have been determined. The ratio of the three activities, dihydropteridine reductase, dihydrofolate reductase and pterin-independent oxidoreductase activity is 1.0, 0.05 and 4.3, respectively. The enzyme, a flavoprotein which is unstable in the presence of dithiothreitol, was shown to be a monomer with a molecular mass of 25.7 kDa. The apparent lack of discrimination between hydride transfer from the pyridine nucleotide to N5 of the pterin in the dihydropteridine reductase reaction and C6 of folate in the dihydrofolate reaction suggested that the FAD prosthetic group may be involved in the hydride transfers. The flavoprotein inhibitor N,N- dimethylpropargylamine inhibited the dihydropteridine reductase and oxidoreductase reactions differently and did not affect the dihydrofolate reductase activity however.

A second-site mutation at phenylalanine-137 that increases catalytic efficiency in the mutant aspartate-27----serine Escherichia coli dihydrofolate reductase

The adaptability of Escherichia coli dihydrofolate reductase (DHFR) is being explored by identifying second-site mutations that can partially suppress the deleterious effect associated with removal of the active-site proton donor aspartic acid-27. The Asp27----serine mutant DHFR (D27S) was previously characterized and the catalytic activity found to be greatly decreased at pH 7.0 [Howell et al. (1986) Science 231, 1123-1128]. Using resistance to trimethoprim (a DHFR inhibitor) in a genetic selection procedure, we have isolated a double-mutant DHFR gene containing Asp27----Ser and Phe137----Ser mutations (D27S+F137S). The presence of the F137S mutation increases kcat approximately 3-fold and decreases Km(DHF) approximately 2-fold over D27S DHFR values. The overall effect on kcat/Km(DHF) is a 7-fold increase. The D27S+F137S double-mutant DHFR is still 500-fold less active than wild-type DHFR at pH 7. Surprisingly, Phe137 is approximately 15 A from residue 27 in the active site and is part of a beta-bulge. We propose the F137S mutation likely causes its catalytic effect by slightly altering the conformation of D27S DHFR. This supposition is supported by the observation that the F137S mutation does not have the same kinetic effect when introduced into the wild-type and D27S DHFRs, by the altered distribution of two conformers of free enzyme [see Dunn et al. (1990)] and by a preliminary difference Fourier map comparing the D27S and D27S+F137S DHFR crystal structures.

Primary structure of the thermostable formyltetrahydrofolate synthetase from Clostridium thermoaceticum

The complete nucleotide sequence of the Clostridium thermoaceticum formyltetrahydrofolate synthetase (FTHFS) was determined and the primary structure of the protein predicted. The gene was 1680 nucleotides long, encoding a protein of 559 amino acid residues with a calculated subunit molecular weight of 59,983. The initiation codon was UUG, with a probable ribosome binding site 11 bases upstream. A putative ATP binding domain was identified. Two Cys residues likely to be involved in subunit aggregation were tentatively identified. No characterization of the tetrahydrofolate (THF) binding domain was possible on the basis of the sequence. A high level of amino acid sequence conservation between the C. thermoaceticum FTHFS and the published sequences of C. acidiurici FTHFS and the FTHFS domains of the Saccharomyces cerevisiae C1-THF synthases was found. Of the 556 residues shared between the two clostridial sequences, 66.4% are identical. If conservative substitutions are allowed, this percentage rises to 75%. Over 47% of the residues shared between the C. thermoaceticum FTHFS and the yeast C1-THF synthases are identical, 57.4% if conservative substitutions are allowed. Hydrophobicity profiles of the C. acidiurici and C. thermoaceticum enzymes were very similar and did not support the idea that large hydrophobic domains play an important role in thermostabilizing the C. thermoaceticum FTHFS.

Mechanism of the reaction catalyzed by dihydrofolate reductase from Escherichia coli: pH and deuterium isotope effects with NADPH as the variable substrate

The variations with pH of the kinetic parameters and primary deuterium isotope effects for the reaction of NADPH with dihydrofolate reductase from Escherichia coli have been determined. The aims of the investigations were to elucidate the chemical mechanism of the reaction and to obtain information about the location of the rate-limiting steps. The V and V/KNADPH profiles indicate that a single ionizing group at the active center of the enzyme must be protonated for catalysis, whereas the Ki profiles show that the binding of NADPH to the free enzyme and of ATP-ribose to the enzyme-dihydrofolate complex is pH independent. From the results of deuterium isotope effects on V/KNADPH, it is concluded that NADPH behaves as a sticky substrate. It is this stickiness that raises artificially the intrinsic pK value of 6.4 for the Asp-27 residue of the enzyme-dihydrofolate complex [Howell, E. E., Villafranca, J. E., Warren, M. S., Oatley, S. J., & Kraut, J. (1986) Science (Washington, D.C.) 231, 1123] to an observed value of 8.9. Thus, the binary enzyme complex is largely protonated at neutral pH. The elevation of the intrinsic pK value of 6.4 for the ternary enzyme-NADPH-dihydrofolate complex to 8.5 is not due to the kinetic effects of substrates. Rather, it is the consequence of the lower, pH-independent rate of product release and the faster pH-dependent catalytic step. At neutral pH, the proportion of enzyme present as a protonated ternary enzyme-substrate complex is sufficient to keep catalysis faster than product release.(ABSTRACT TRUNCATED AT 250 WORDS)

Dihydrofolate reductase from Escherichia coli: the kinetic mechanism with NADPH and reduced acetylpyridine adenine dinucleotide phosphate as substrates

Kinetic studies on the reaction catalyzed by dihydrofolate reductase from Escherichia coli have been undertaken with the aim of characterizing further the kinetic mechanism of the reaction. For this purpose, the kinetic properties of substrates were determined by measurement of (a) initial velocities over a wide range of substrate concentrations and (b) the stickiness of substrates in ternary enzyme complexes. Stickiness is defined as the rate at which a substrate reacts to give products relative to the rate at which that substrate dissociates. Stickiness was determined by varying the viscosity of reaction mixtures and the concentration of one substrate in the presence of a saturating concentration of the other substrate. The results indicate that NADPH is sticky in the enzyme-NADPH-dihydrofolate complex, while dihydrofolate is much less sticky in this complex. At higher concentrations, NADPH functions as an activator through the formation of an enzyme-NADPH-tetrahydrofolate from which tetrahydrofolate is released more rapidly than from an enzyme-tetrahydrofolate complex. Higher concentrations of dihydrofolate also cause enzyme activation, and it appears that this effect is due to the ability of dihydrofolate to displace tetrahydrofolate from a binary enzyme complex through the formation of a transitory enzyme-tetrahydrofolate-dihydrofolate complex. As NADPH and dihydrofolate function as activators and as NADPH behaves as a sticky substrate, the kinetic mechanism of the dihydrofolate reductase reaction with the natural substrates is steady-state random. By contrast with NADPH, reduced 3-acetylpyridine adenine dinucleotide phosphate exhibits only slight stickiness and does not function as an activator.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanism of inhibition of dihydrofolate reductases from bacterial and vertebrate sources by various classes of folate analogues

Different classes of folate analogues have been examined with respect to the mechanism of their inhibition of dihydrofolate reductases from Escherichia coli and chicken liver. In addition, the degree of synergism between the binding of these compounds and NADPH has been investigated. Methotrexate acts as a slow, tight-binding inhibitor of both enzymes whereas trimethoprim is a slow, tight-binding inhibitor of the enzyme from E. coli and a classical inhibitor of the chicken-liver enzyme. Pyrimethamine, 2,4-diamino-6,7-dimethylpteridine, a phenyltriazine, folate and folinate exhibit classical inhibition. The degree of synergism between the binding of NADPH and the inhibitor varied from low for pyrimethamine and folate to very large for the phenyltriazine which binds to the chicken-liver enzyme almost 50 000-times more tightly in the presence of NADPH. The degree of synergism is reflected in the type of inhibition that the folate analogues yield with respect to NADPH. Compounds which exhibit slight synergism give noncompetitive inhibition whereas those with a high degree of synergism yield uncompetitive inhibition. With the exception of folinate, all compounds that act as classical inhibitors give rise to competitive inhibition with respect to dihydrofolate. Folinate exhibits competitive inhibition against NADPH and noncompetitive inhibition against dihydrofolate. These results are consistent with the formation of an enzyme-dihydrofolate-folinate complex. The (6S, alphaS)-diastereoisomer of folinate was bound at least 1000-times more tightly than the (6R, alphaS)-diastereoisomer. Consideration has been given to the possible interactions that occur between residues on the enzyme and groups on the inhibitor that give rise to slow-binding inhibition.

Amino acid substitutions that reduce the affinity of penicillin-binding protein 3 of Escherichia coli for cephalexin

The location of amino acid substitutions that allow an enzyme to discriminate between the binding of its normal substrate and a substrate analogue may be used to identify regions of the polypeptide that fold to form the substrate binding site. We have isolated a large number of cephalexin-resistant mutants of Escherichia coli in which the resistance is due to the production of altered forms of penicillin-binding protein 3 that have reduced affinity for the antibiotic. Using three mutagens, and a variety of selection procedures, we obtained only five classes of mutants which could be distinguished by their patterns of cross-resistance to other beta-lactam antibiotics. The three classes of mutants that showed the highest levels of resistance to cephalexin were cross-resistant to several other cephalosporins but not to penicillins or to the monobactam, aztreonam. The penicillin-binding protein 3 gene from 46 independent mutants was cloned and sequenced. Each member of the five classes of cephalexin-resistant mutants had the same amino acid substitution in penicillin-binding protein 3. The mutants that showed the highest levels of resistance to cephalexin had alterations of either Thr-308 to Pro, Val-344 to Gly, or Asn-361 to Ser. The Thr-308 to Pro substitution had occurred within the beta-lactam-binding site since the adjacent residue (Ser-307) has been shown to be acylated by benzylpenicillin. The Asn-361 to Ser change occurred in a region that showed substantial similarity to regions in both penicillin-binding protein 1A and 1B and may also define a residue that is located within the beta-lactam-binding site in the three-dimensional structure of the enzyme.

Cloning of aroG, the gene coding for phospho-2-keto-3-deoxy-heptonate aldolase(phe), in Escherichia coli K-12, and subcloning of the aroG promoter and operator in a promoter-detecting plasmid

Defective transducing phages carrying aroG, the structural gene for phenylalanine (phe)-inhibitable phospho-2-keto-heptonate aldolase (EC 4.1.2.15; previously known as 3-deoxy-D-arabinoheptulosonate-7-phosphate synthetase[phe]), have been isolated, and DNA from two of these phages has been used to construct a restriction map of the region from att lambda to aroG. A 7.6-kb PstI-HindIII fragment from one of these phages was cloned into pBR322 and shown to contain aroG. The location of aroG within the 7.6 kb was established by subcloning and Tn3 transpositional mutagenesis. A fragment carrying the aroG promoter and operator has been cloned into a high copy number promoter-cloning vector (pMC489), and the resulting aroGpo-LacZ' (alpha) fusion subcloned in a low copy number vector. Strains with this fusion on the low copy number vector exhibit negative regulation of beta-galactosidase expression by both phenylalanine and tryptophan and positive regulation by tyrosine in a tyrR+ background.

Regulatory changes in the formation of chromosomal dihydrofolate reductase causing resistance to trimethoprim

High resistance to trimethoprim mediated by the several hundredfold overproduction of the drug target enzyme, dihyrofolate reductase, in a clinically isolated Escherichia coli strain, 1810, was cloned onto several vector plasmids and seemed to be comprised of a single dihydrofolate reductase gene, which by DNA-DNA hybridization and restriction enzyme digestion mapping was very similar to the corresponding gene of E. coli K-12. Determination of mRNA formation in the originally isolated resistant strain and strains with cloned trimethoprim resistance determinant demonstrated an about 15-fold increase in production of dihydrofolate reductase mRNA compared with that in E. coli K-12. This was explained by the occurrence of a promoter up mutation in the resistant isolate accompanied by changes in the restriction enzyme digestion pattern found by comparison with the corresponding pattern from E. coli K-12.

Catalytic mechanism of the dihydrofolate reductase reaction as determined by pH studies

The variation with pH of the kinetic parameters of the reaction catalyzed by dihydrofolate reductase from Escherichia coli has been determined with the aim of elucidating the chemical mechanism of the reaction. The (V/K)DHF and V profiles indicated that protonation enhances the observed rate of interaction of dihydrofolate (DHF) with the enzyme-NADPH complex as well as the maximum velocity of the reaction. The pKa value of 8.09 observed in the (V/K)DHF profile is similar to that of 7.9 observed in the Ki profile for 2,4-diamino-6,7-dimethylpteridine while the pKa value of the V profile is displaced to 8.4. From the magnitude of the pH-independent value for (V/K)DHF, it is concluded that unprotonated dihydrofolate must react, at neutral pH, with the protonated form of the enzyme. The D(V/K)DHF value is independent of pH and equal to unity whereas the DV value varies as a wave function of pH with limiting values of 1.5 and 1.0 at low and high pH, respectively. It is proposed that dihydrofolate reacts with the unprotonated enzyme-NADPH complex to form a dead-end complex and with the protonated form of the same complex to form a productive complex. Further, it is considered that the protonated carboxyl of Asp-27 at the active site of the enzyme is responsible for the protonation of the N-5 nitrogen of dihydrofolate and that this protonation precedes and facilitates hydride transfer.

The use of mini-Gal plasmids for rapid incompatibility grouping of conjugative R plasmids

The galactose operon of Escherichia coli K-12 has been used as a phenotypic marker for miniplasmids derived in vitro from R plasmids representing six incompatibility groups. This has enabled the development of a rapid incompatibility typing scheme in which the miniplasmids are used as incompatibility exemplars, their presence in strains being monitored on galactose fermentation indicator media.

Recognition of messenger RNA during translational initiation in Escherichia coli

The structural aspects of recognition by E. coli ribosomes of translational initiation regions on homologous messenger RNAs have been reviewed. Also discussed is the location of initiation region on mRNA, its confines, typical nucleotide sequences responsible for initiation signal, and the influence of RNA macrostructure on protein synthesis initiation. Most of the published DNA nucleotide sequences surrounding the start of various E. coli genes and those of its phages have been collected.

Nucleotide sequence of dihydrofolate reductase genes from trimethoprim-resistant mutants of Escherichia coli. Evidence that dihydrofolate reductase interacts with another essential gene product

We report the construction of recombinant plasmids containing the dihydrofolate reductase structural gene (fol) from several trimethoprim-resistant mutants of Escherichia coli. Strains carrying some of these plasmids produced approximately 6% of their soluble cell protein as dihydrofolate reductase and are therefore excellent sources of the purified enzyme for inhibitor binding or mechanistic studies. The nucleotide sequence of the fol region from each of the plasmids was determined. A plasmid derived from a Ki mutant which produced a dihydrofolate reductase with lowered affinity for trimethoprim contained a mutation in the structural gene that altered the sequence of the polypeptide in a conserved region which is adjacent to the dihydrofolate binding site. Two other independently-isolated mutants which overproduced dihydrofolate reductase had a mutation in the -35 region of the fol promoter. One of them, strain RS35, was also temperature-sensitive for growth in minimal medium. This phenotype was shown to be the result of an additional mutation in a locus unlinked to fol by P1 transduction. The fol regions from two temperature-independent revertants of strain RS35 were sequenced. One of these had a mutation within the dihydrofolate reductase structural gene which altered some properties of the enzyme. This confirmed some previous enzymological data which suggested that some revertants of strain RS35 had mutations in fol (Sheldon 1977). These results suggest that dihydrofolate reductase interacts physically with some other essential gene product in E. coli.