Deletion mapping of the ilvGOEDAC genes of Escherichia coli K-12

Physical identification of an internal promoter, ilvAp, in the distal portion of the ilvGMEDA operon

It has been previously demonstrated that the ilvGMEDA operon is expressed in vivo from the promoters ilvGp2 and ilvEp. An additional internal promoter is identified and designated ilvAp. This internal promoter, which allows independent expression of ilvA, has been analyzed both in vivo and in vitro. Our results indicate that: (1) ilvAp exists in both Escherichia coli K-12 and Salmonella typhimurium, as demonstrated by fusion to the galK reporter gene; (2) ilvAp is located in the distal coding sequence of ilvD; (3) the ilvAp sequences are not identical for these two bacterial species; (4) transcription from ilvAp of E. coli K-12 was demonstrated; (5) expression from ilvAp responds to the availability of oxygen; (6) potential 3' 5'-cyclic AMP receptor protein binding sites exist adjacent to ilvAp.

Internal promoter in the ilvGEDA transcription unit of Escherichia coli K-12

Segments of the ilvGEDA transcription unit have been cloned into the promoter tester plasmid pMC81. This vector contains cloning sites situated upstream of the lacZ gene coding for beta-galactosidase. Using this method we have quantitatively evaluated in vivo (i) the activity of previously described promoter, pG, preceding ilvG; (ii) the relative activity of pE promoter, previously postulated to be located between ilvG and ilvE; and (iii) the effect of the frameshift site present in the wild-type ilvG gene by comparison with mutant derivatives lacking this frameshift site. Isogenic derivatives of strain MC1000 were constructed by transduction with phage P1 grown on rho-120, delta(ilvGEDA), delta(ilvED), and ilvA538 hosts. The potential effects of these alleles that were previously postulated to affect ilvGEDA expression were assessed in vivo by monitoring beta-galactosidase production directed by ilv DNA fragments. Cloned ilv segments were also tested for activity in vitro with a DNA-directed coupled transcription and translation system. The production in vitro of ilv-directed ilv gene expression and beta-galactosidase expression with ara-ilv-lac fusions paralleled the in vivo activity.

Location of the rho gene and characterization of lambda ilv-gal derivatives of lambda ilv-rho bacteriophage

The location of the rho gene and its position relative to the ilv genes of Escherichia coli K-12 was analyzed using genetic criteria, restriction enzyme cleavage, and maxicell analysis. Plasmids were constructed with deletions of the rho gene introduced in vitro, and lambda ilv-gal derivatives of lambda ilv-rho bacteriophage were isolated by recombination in vivo. A HindIII restriction fragment of 8 kilobases (kb) previously shown to contain at least part of the rho gene (Gray et al. 1981) was cloned into plasmid pMC81. This vector has transcription stop sites that present read-through expression of cloned genes from either direction, and cloning sites upstream of the lacZ gene coding for beta-galactosidase. The position of the rho gene and flanking sequences required for its expression were further localized to a region of approximately 2 kb by introducing deletions using restriction enzyme treatment of these plasmids. A promoter in the rho region was found to direct beta-galactosidase synthesis in these plasmid derivatives. Derivatives of lambda ilv-rho phage were isolated in vivo by pyrophosphate chelation selection for phage with reduced genome size. Restriction enzyme analysis of twelve of these derivatives revealed an unexpected bias towards phage recombinants as opposed to simple internal deletions.

Relative map location of the rep and rho genes of Escherichia coli

The rep gene of Escherichia coli was mapped between ilvC and rho by three-factor P1 transductional crosses and also by complementation with a set of lambda transducing phages that contain known amounts of bacterial DNA linked to ilvC. The physical distance between ilvC and rep and between rep and rho were calculated with an accuracy of +/- 0.4 kilobase to be 0 less than or equal to ilvC-rep less than or equal to 3.4 kilobases and 2.0 less than or equal to rep-rho less than or equal to 6.0 kilobases. It was shown that rho-15 is Gro+ for phage ST-1. An ilv::Tn10 mutation was located in ilvY.

Absence of significant membrane localization of the proteins coded by the ilvGEDAC genes of Escherichia coli K-12

We previously characterized a set of lambda dilv phages by genetic, restriction enzyme, and heteroduplex analyses and tentatively correlated isoleucine-valine gene products with specific ilv DNA segments by using cloned ilv segments in maxicells and lambda dilv phage infection of UV-irradiated cells. In this work, the identity of the ilvC gene product, alpha-acetohydroxy acid isomeroreductase, was confirmed by demonstrating its induction by the physiological inducers alpha-acetolactate and alpha-acetohydroxybutyrate. The identity of the ilvE gene product, transaminase, B, was confirmed by antibody precipitation of the purified enzyme. Phage derivatives with ilv regulatory mutations were found to have the predicted effect upon the ilvGEDA and ilvC protein products. The distribution of the ilvGEDA and ilvC gene products in the soluble, periplasmic, inner membrane, and outer membrane fractions was examined, and no significant membrane association was observed. The expression of the ilv genes in the lambda dilv phage from ilv and phage lambda promoters was compared in order to determine the fractional contribution of each to ilv gene expression. An additional protein of 54,000 daltons that was not detected in the previous analysis was observed to be coded by a bacterial gene but was produced only by readthrough from phage promoters.

Identification of a protein of 15,000 daltons related to isoleucine-valine biosynthesis in Escherichia coli K-12

The effect of the ilvG671, ilvG468, and ilvG603 mutations (phenotype, IlvG+ Valr; formerly ilvO) upon proteins synthesized was determined by infection of irradiated Escherichia coli K-12 cells, using specifically constructed derivatives of lambda dilv phage. These ilvG alleles are similar to the previously studied ilvG2096(Valr) allele in that they activate the latent ilvG gene which is present in the wild-type strain, leading to the synthesis of a 62,000-dalton protein. In addition, all of these ilvG (Valr) alleles increase the synthesis of a 15,000-dalton protein. To localize the gene coding for the 15,000-dalton protein, the proteins produced in maxicells containing plasmids with specific deletions of ilv and rrnX DNA segments were analyzed. The gene coding for the 15,000-dalton protein was located within a region about 1,000 base pairs long between ilv and trpT. The function of the 15,000-dalton protein is not known.

Cloning of the ilvA538 gene coding for feedback-hypersensitive threonine deaminase from Escherichia coli K-12

A variety of experimental results implicate the ilvA gene product, threonine deaminase, as an autoregulatory protein that affects the expression of its own gene and those coding for some related proteins. Some of the most direct evidence comes from the analysis of mutations in the ilvA gene with pleiotropic genetic regulatory effects. The most extensively documented mutation, ilvA538, lowers the expression of and abolishes repression control of the ilvGEDA transcription unit. A pleiotropic effect of the ilvA538 mutation, which may be either incidental or mechanistically related to the loss of repression control, renders threonine deaminase feedback hypersensitive to the inhibition of catalytic activity by the pathway end product, isoleucine. We transferred this mutation to lambda dilv phage and pBR322 derivatives. Direct enzyme assay of the plasmid- and phage-coded ilvA538 gene product in delta ilv hosts confirmed the feedback hypersensitivity of the enzyme product. In conjunction with the ilvG671 (phenotype, ILvG+ Valr; previously designated ilvO671) allele located in cis, high levels of the plasmid and lambda dilv phage-coded mutant enzyme suitable for protein purification were observed. Deletion mapping experiments with lambda dilv phage confirmed that the ilvA538 mutation, and not mutations promoter proximal to ilvD (transcription is from ilvG to ilvA), confer a loss of repression control. These genetic mapping studies indicate, however, that an additional mutation(s) may be present that contributes, at least in part, to the reduced enzyme levels in strains with the ilvA538 mutation.

Physical and genetic localization of ilv regulatory sites in lambda ilv bacteriophages

A set of nine lambda dilv phages were used to transduce bacterial recipients containing point mutations or deletions in the ilv genes located at 84 min on the Escherichia coli K-12 chromosome. This genetic analysis indicated that two phages carry the entire ilvGEDAC cluster; others carry the complete ilvC gene and, in addition, bacterial DNA that extends to a termination point between ilvA and ilvC, within ilvD, within ilvE, or within ilvG. DNA extracted from the lambda dilv phages was digested with EcoRI, HindIII, KpnI, PstI, SalI, and SmaI. The restriction maps revealed that these phages were generated after insertion at four distinct insertion sites downstream (clockwise) of ilvC. The physical relationships between the various phages were further examined by electron microscopic heteroduplex analysis. The physical maps of the phages thus generated were straightforward and in complete accord with the genetic data. No evidence for genetic rearrangements of ilv DNA in the phage was obtained, thus validating conclusions based on the use of these phages in previous and ongoing research projects. Bacterial cells with deletions of the ilv genes were made lysogenic with lambda dilv phage to examine the regulation of ilv genes present in the phage. The results confirm previous studies showing that one site for control by repression and derepression is upstream (counterclockwise) of ilvG. It was shown, in addition, that the activities of dihydroxy acid dehydrase and threonine deaminase were increased when the prototrophic lysogens were grown with 20 mM leucine. Since this increase was exhibited even when the ilvG-linked control region was not carried by the lambda dilv phage, additional control sites must be located within the ilvEDA region of the ilvGEDA transcription unit.

DNA sequence fine-structure analysis of ilvG (IlvG+) mutations of Escherichia coli K-12

Six ilvG (IlvG+) mutations of Escherichia coli K-12 were transferred to recombinant plasmids, and the DNA sequence of each mutation was determined. This analysis confirmed that expression of the ilvG gene product (acetohydroxy acid synthase II) requires the deletion of a single base pair or the addition of two base pairs within ilvG to displace a frameshift site present in wild-type E. coli K-12. This system should be useful in the analysis of potential frameshift mutagens.

Identification of the protein products of the rrnC, ilv, rho region of the Escherichia coli K-12 chromosome

Two methods have been used to identify the protein products of the Escherichia coli K-12 ilv region at 84 min and the flanking rrnC (counterclockwise) and rho (clockwise) loci. First, a set of lambda dilv specialized transducing phages, including some phages that carry rho and others that carry part of rrnC, was used to infect UV irradiated cells. The proteins produced by the infecting lambda dilv phage were selectively labelled with radioactivity amino acids and identified by SDS gel electrophoresis and autoradiography. Second, restriction enzyme fragments were cloned from the lambda dilv phage into pBR322 and the plasmid specific gene products produced in maxicells were similarly identified by SDS gel electrophoresis and autoradiography. The proteins produced were correlated with specific genes and restriction enzyme fragments present in the lambda dilv phage and the pBR322 derivatives. Several ilv gene products that have previously been refractory to protein purification attempts have been identified for the first time by this technique. The presence of mutations at the ilvO site is shown to activate the cryptic ilvG gene and to result in the production of a 62,000 dalton protein. A 15,000 dalton protein of unknown function is synthesized from a DNA segment between ilv and rrnC. The rho gene was cloned from lambda dilv phage into pBR322 and shown to be dominant to a rho mutation on the host chromosome. The rho gene product and four additional proteins coded by genes near or between rho and ilv have been detected.

Genetical and structural analysis of a group of lambda ilv and lambda rho transducing phages

Eight lambda ilv C transducing phages generated from E. coli K12 secondary site lysogens have been analysed genetically and physically. Two of them carry, in addition, the rho gene and its promotor region, but not the cya gene. The ilv O 603 mutation has been located between ilv G and ilv E. Electrophoretic analysis of the proteins synthesized by these phages in a system of UV irradiated cells allowed us to assign molecular weights of 55000 and 66000 daltons to the ilv C and the ilv D gene products, respectively, and to show that an ilv G-encoded polypeptide of 60000 daltons is made from an ilv O- but not from an ilv O+ phage. The expression of the ilv G gene is discussed in the light of the recent finding of a promoter-attenuator region lying upstream to ilv G. Finally, we have found that one of the lambda ilv phages does not have the classical structure of a transducing phage.

Molecular basis of valine resistance in Escherichia coli K-12

The relationship of valine resistance to the expression of the ilvGEDA operon of Escherichia coli K-12 has been determined. DNA sequence and in vivo protein analyses indicate that in wild-type E. coli K-12 there is a frameshift site within the gene (ilvG) for valine resistance. The ilvG+2096 (formerly designated ilv02096) mutation displaces this frameshift site, resulting in the expression of ilvG and the relief of transcriptional polarity on the distal genes of this operon. Thus, the "ilv0" mutation, which concomitantly confers valine resistance and increased expression of the ilvEDA genes, is, in fact, the "reversion" of a polar site within the first structural gene of the ilvGEDA operon.

The ilvG gene is expressed in Escherichia coli K-12

Three genes code for isozymes of acetohydroxy acid synthase (AHAS) in Escherichia coli K-12. To test the previously published supposition that one of them, ilvG, is silent in ilvO+ strains, we isolated mutants which had deletions of various lengths in the ilvGEDA operon. Some of these mutants have severely reduced levels of AHAS activity. We conclude that ilvG is expressed in ilvO+ strains but is deleted in these mutants. In addition, we find that AHAS II, the ilvG gene product, is sensitive to feedback inhibition by valine. We hypothesize that ilvO- mutations are ilvG frameshift mutations which render AHAS II valine resistant and enhance transcription of distal genes.

Regulation of ilvEDA expression occurs upstream of ilvG in Escherichia coli: additional evidence for an ilvGEDA operon

A low-copy-number plasmid was prepared that contained the entire ilv gene cluster of Escherichia coli. The introduction of an ilvO mutation allowed the ilvG gene of the plasmid to be expressed and imparted valine resistance to strains carrying it. Insertion of Tn10 into the ilvG gene of the plasmid resulted in a strong polar effect on ilv genes E, D, and A. Replacement of a region of ilv deoxyribonucleic acid between two KpnI sites on the high-copy-number plasmid carrying the entire ilv gene cluster with a KpnI fragment carrying an ilv-lac fusion but not extending into the ilv-specific control region resulted in a plasmid expressing the lacZ gene under ilv control when the fusion had been inserted in its normal orientation but not when it had been inserted in the opposite orientation. These experiments indicate that ilv-specific control over ilvE, ilvD, and ilvA expression is dependent on these genes being continguous with deoxyribonucleic acid that lies upstream of ilvG. The results also add further support to the concept of an ilvGEDA operon in E. coli.

Physical location of the ilvO determinant in Escherichia coli K-12 deoxyribonucleic acid

A plasmid carrying the 4,6-kilobase (kb) HindIII-derived fragment from an ilvO mutant derivative of lambda h80dilv imparted a valine-resistant phenotype on strains it carried. This fragment carries a small amount of the promoter-proximal end of ilvE, the ilvO determinant, and apparently the entire ilvG gene, which specifies the valine-insensitive acetohydroxy acid synthase. Comparable deoxyribonucleic acid (DNA) from the original lambda h80dilv did not carry the valine resistance marker. The valine-resistant phenotype was always correlated with the formation of the resistant enzymes. The ilvO determinant was shown to be carried within an approximately 600-based-pair region lying between the SalI and KpnI sites on the HindIII fragment and perhaps within the ilvG gene itself. Ribonucleic acid that hybridizes with the DNA corresponding to the ilvG gene is formed in wild-type K-12 cells. This fact, coupled with the fact that ilvG is transcribed from the same DNA strand as the ilvE, D, and A genes, led to the idea that transcription is normally initiated upstream from ilvG in both wild-type and ilvO strains. In wild-type strains either the formation or the translation of the transcript would be terminated with the ilvG gene, thus preventing expression of that gene.

Salmonella typhimurium mutants defective in acetohydroxy acid synthases I and II

An analysis of transposon-induced mutants shows that Salmonella typhimurium possesses two major isozymes of acetohydroxy acid synthase, the enzymes which mediate the first common step in isoleucine and valine biosynthesis. A third (minor) acetohydroxy acid synthase is present, but its significance in isoleucine and valine synthesis may be negligible. Mutants defective in acetohydroxy acid synthase II (ilvG::Tn10) require isoleucine, alpha-ketobutyrate, or threonine for growth, a mutant defective in acetohydroxy acid synthase I (ilvB::Tn5) is a prototroph, and a double mutant (ilvG::Tn10 ilvB::Tn5) requires isoleucine plus valine for growth.

Transaminase B from Escherichia coli: quaternary structure, amino-terminal sequence, substrate specificity, and absence of a separate valine-alpha-ketoglutarate activity

Transaminase B (branched-chain amino acid aminotransferase, EC 2.6.1.42), the ilvE gene product, was purified to apparent homogeneity from an Escherichia coli K-12 strain which carries the ilvE gene both on the host chromosome and on a plasmid. The oligomeric structure of the enzyme, as determined by analytical ultracentrifugation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis, was confirmed to be that of a hexamer with a molecular weight of about 182,000 and apparently identical subunits. Cross-linking with dimethylsuberimidate yielded trimers, dimers, and monomers, but essentially no species of higher molecular weight. These results are consistent with a double-trimer arrangement of the subunits in native enzyme. The amino-terminal sequence was found to be: Gly Thr Lys Lys Ala Asp Tyr Ile (Trp) Phe Asn Gly (Thr) (Met) Val. Purified transaminase B catalyzed transamination between alpha-ketoglutarate and l-isoleucine, l-leucine, l-valine, and, to a lesser extent, l-phenylalanine and l-tyrosine, the latter reacting very sluggishly. The enzyme was free of aspartate transaminase and of transaminase C. The apparent K(m) values for the branched-chain alpha-ketoacids were smaller than those for the corresponding amino acids. The lowest K(m) was recorded for dl-alpha-keto-beta-methyl-n-valerate, and the highest was recorded for l-valine. The ratio of the valine- and isoleucine-alpha-ketoglutarate activities did not change significantly during purification, and both activities were quantitatively removed from crude extract by antibody raised against purified transaminase B. These observations argue against the existence of a separate valine-alpha-ketoglutarate transaminase. Anti-E. coli transaminase B antibody cross-reacted with crude extract from Salmonella typhimurium, but not with extract obtained from Pseudomonas aeruginosa.

Mutations affecting the formation of acetohydroxy acid synthase II in Escherichia coli K-12

Genetic mapping experiments have established that two recently isolated valine-resistant mutants of the K-12 strain of Escherichia coli have lesions lying between ilvE and rbs. These lesions allowed expression of the ilvG gene, specifying the valine-insensitive acetohydroxy acid synthase (synthase II) and an increased expression of the ilvEDA operon. In this respect, they resembled an earlier described ilvO lesion that was reported to lie between ilvA and ilvC. All three lesions were cis-dominant in cis-trans tests. Reexamination of the earlier studied ilvO lesion revealed that it, too, lies between ilvE and rbs. Valine-sensitive derivatives with lesions presumed to be in ilvG were selected from each of the valine-resistant strains. In two of the valine-resistant strains, the ilvG mutations were on the rbs side of ilvO, indicating a gene order rbs-ilvG-ilvO-ilvE-ilvD-ilvA-ilvC. In one of the recently isolated valine-resistant stocks, however, the apparent ilvG mutation was found to be between ilvE and the aline resistance marker. This finding suggests that either ilvO and ilvG mutations are interspersed or there is another locus, ilvR, that behaves phenotypically like ilvO and which lies between ilvG and rbs.