Genetic fine structure of the leucine operon of Escherichia coli K-12

High-level and -yield production of L-leucine in engineered Escherichia coli by multistep metabolic engineering

L-leucine is an essential amino acid widely used in food and pharmaceutical industries. However, the relatively low production efficiency limits its large-scale application. In this study, we rationally developed an efficient L-leucine-producing Escherichia coli strain. Initially, the L-leucine synthesis pathway was enhanced by overexpressing feedback-resistant 2-isopropylmalate synthase and acetohydroxy acid synthase both derived from Corynebacterium glutamicum, along with two other native enzymes. Next, the pyruvate and acetyl-CoA pools were enriched by deleting competitive pathways, employing the nonoxidative glycolysis pathway, and dynamically modulating the citrate synthase activity, which significantly promoted the L-leucine production and yield to 40.69 g/L and 0.30 g/g glucose, respectively. Then, the redox flux was improved by substituting the native NADPH-dependent acetohydroxy acid isomeroreductase, branched chain amino acid transaminase, and glutamate dehydrogenase with their NADH-dependent equivalents. Finally, L-leucine efflux was accelerated by precise overexpression of the exporter and deletion of the transporter. Under fed-batch conditions, the final strain LXH-21 produced 63.29 g/L of L-leucine, with a yield and productivity of 0.37 g/g glucose and 2.64 g/(L h), respectively. To our knowledge, this study achieved the highest production efficiency of L-leucine to date. The strategies presented here will be useful for engineering E. coli strains for producing L-leucine and related products on an industrial scale.

Regulation of the Leucine Metabolism in Mortierella alpina

The oleaginous fungus Mortierella alpina is a safe source of polyunsaturated fatty acids (PUFA) in industrial food and feed production. Besides PUFA production, pharmaceutically relevant surface-active and antimicrobial oligopeptides were isolated from this basal fungus. Both production of fatty acids and oligopeptides rely on the biosynthesis and high turnover of branched-chain-amino acids (BCAA), especially l-leucine. However, the regulation of BCAA biosynthesis in basal fungi is largely unknown. Here, we report on the regulation of the leucine, isoleucine, and valine metabolism in M. alpina. In contrast to higher fungi, the biosynthetic genes for BCAA are hardly transcriptionally regulated, as shown by qRT-PCR analysis, which suggests a constant production of BCAAs. However, the enzymes of the leucine metabolism are tightly metabolically regulated. Three enzymes of the leucine metabolism were heterologously produced in Escherichia coli, one of which is inhibited by allosteric feedback loops: The key regulator is the α-isopropylmalate synthase LeuA1, which is strongly disabled by l-leucine, α-ketoisocaproate, and propionyl-CoA, the precursor of the odd-chain fatty acid catabolism. Its gene is not related to homologs from higher fungi, but it has been inherited from a phototrophic ancestor by horizontal gene transfer.

The chemical mechanisms of the enzymes in the branched-chain amino acids biosynthetic pathway and their applications

l-Valine, l-isoleucine, and l-leucine are three key proteinogenic amino acids, and they are also the essential amino acids required for mammalian growth, possessing important and to some extent, special physiological and biological functions. Because of the branched structures in their carbon chains, they are also named as branched-chain amino acids (BCAAs). This review will highlight the advance in studies of the enzymes involved in the biosynthetic pathway of BCAAs, concentrating on their chemical mechanisms and applications in screening herbicides and antibacterial agents. The uses of some of these enzymes in lab scale organic synthesis are also discussed.

The genetic basis for adaptation of model-designed syntrophic co-cultures

Understanding the fundamental characteristics of microbial communities could have far reaching implications for human health and applied biotechnology. Despite this, much is still unknown regarding the genetic basis and evolutionary strategies underlying the formation of viable synthetic communities. By pairing auxotrophic mutants in co-culture, it has been demonstrated that viable nascent E. coli communities can be established where the mutant strains are metabolically coupled. A novel algorithm, OptAux, was constructed to design 61 unique multi-knockout E. coli auxotrophic strains that require significant metabolite uptake to grow. These predicted knockouts included a diverse set of novel non-specific auxotrophs that result from inhibition of major biosynthetic subsystems. Three OptAux predicted non-specific auxotrophic strains—with diverse metabolic deficiencies—were co-cultured with an L-histidine auxotroph and optimized via adaptive laboratory evolution (ALE). Time-course sequencing revealed the genetic changes employed by each strain to achieve higher community growth rates and provided insight into mechanisms for adapting to the syntrophic niche. A community model of metabolism and gene expression was utilized to predict the relative community composition and fundamental characteristics of the evolved communities. This work presents new insight into the genetic strategies underlying viable nascent community formation and a cutting-edge computational method to elucidate metabolic changes that empower the creation of cooperative communities.

Many basic characteristics underlying the establishment of cooperative growth in bacterial communities have not been studied in detail. The presented work sought to understand the adaptation of syntrophic communities by first employing a new computational method to generate a comprehensive catalog of E. coli auxotrophic mutants. Many of the knockouts in the catalog had the predicted effect of disabling a major biosynthetic process. As a result, these strains were predicted to be capable of growing when supplemented with many different individual metabolites (i.e., a non-specific auxotroph), but the strains would require a high amount of metabolic cooperation to grow in community. Three such non-specific auxotroph mutants from this catalog were co-cultured with a proven auxotrophic partner in vivo and evolved via adaptive laboratory evolution. In order to successfully grow, each strain in co-culture had to evolve under a pressure to grow cooperatively in its new niche. The non-specific auxotrophs further had to adapt to significant homeostatic changes in cell’s metabolic state caused by knockouts in metabolic genes. The genomes of the successfully growing communities were sequenced, thus providing unique insights into the genetic changes accompanying the formation and optimization of the viable communities. A computational model was further developed to predict how finite protein availability, a fundamental constraint on cell metabolism, could impact the composition of the community (i.e., the relative abundances of each community member).

Bacterial Branched-Chain Amino Acid Biosynthesis: Structures, Mechanisms, and Drugability

The eight enzymes responsible for the biosynthesis of the three branched-chain amino acids (l-isoleucine, l-leucine, and l-valine) were identified decades ago using classical genetic approaches based on amino acid auxotrophy. This review will highlight the recent progress in the determination of the three-dimensional structures of these enzymes, their chemical mechanisms, and insights into their suitability as targets for the development of antibacterial agents. Given the enormous rise in bacterial drug resistance to every major class of antibacterial compound, there is a clear and present need for the identification of new antibacterial compounds with nonoverlapping targets to currently used antibacterials that target cell wall, protein, mRNA, and DNA synthesis.

A growth- and bioluminescence-based bioreporter for the in vivo detection of novel biocatalysts

The use of bioreporters in high-throughput screening for small molecules is generally laborious and/or expensive. The technology can be simplified by coupling the generation of a desired compound to cell survival, causing only positive cells to stay in the pool of generated variants. Here, a dual selection/screening system was developed for the in vivo detection of novel biocatalysts. The sensor part of the system is based on the transcriptional regulator AraC, which controls expression of both a selection reporter (LeuB or KmR; enabling growth) for rapid reduction of the initially large library size and a screening reporter (LuxCDABE; causing bioluminescence) for further quantification of the positive variants. Of four developed systems, the best system was the medium copy system with KmR as selection reporter. As a proof of principle, the system was tested for the selection of cells expressing an l-arabinose isomerase derived from mesophilic Escherichia coli or thermophilic Geobacillus thermodenitrificans. A more than a millionfold enrichment of cells with l-arabinose isomerase activity was demonstrated by selection and exclusion of false positives by screening. This dual selection/screening system is an important step towards an improved detection method for small molecules, and thereby for finding novel biocatalysts.

Subdomain II of α-isopropylmalate synthase is essential for activity: inferring a mechanism of feedback inhibition

The committed step of leucine biosynthesis, converting acetyl-CoA and α-ketoisovalerate into α-isopropylmalate, is catalyzed by α-isopropylmalate synthase (IPMS), an allosteric enzyme subjected to feedback inhibition by the end product L-leucine. We characterized the short form IPMS from Leptospira biflexa (LbIPMS2), which exhibits a catalytic activity comparable with that of the long form IPMS (LbIPMS1) and has a similar N-terminal domain followed by subdomain I and subdomain II but lacks the whole C-terminal regulatory domain. We found that partial deletion of the regulatory domain of LbIPMS1 resulted in a loss of about 50% of the catalytic activity; however, when the regulatory domain was deleted up to Arg-385, producing a protein that is almost equivalent to the intact LbIPMS2, about 90% of the activity was maintained. Moreover, in LbIPMS2 or LbIPMS1, further deletion of several residues from the C terminus of subdomain II significantly impaired or completely abolished the catalytic activity, respectively. These results define a complete and independently functional catalytic module of IPMS consisting of both the N-terminal domain and the two subdomains. Structural comparison of LbIPMS2 and the Mycobacterium tuberculosis IPMS revealed two different conformations of subdomain II that likely represent two substrate-binding states related to cooperative catalysis. The biochemical and structural analyses together with the previously published hydrogen-deuterium exchange data led us to propose a conformation transition mechanism for feedback inhibition mediated by subdomains I and II that might associated with alteration of the binding affinity toward acetyl-CoA.

Extracellular recombinant protein production under continuous culture conditions with Escherichia coli using an alternative plasmid selection mechanism

The secretion of recombinant proteins into the extracellular space by Escherichia coli presents advantages like easier purification and protection from proteolytic degradation. The controlled co-expression of a bacteriocin release protein aids in moving periplasmic proteins through the outer membrane. Since such systems have rarely been applied in continuous culture it seemed to be attractive to study the interplay between growth-phase regulated promoters controlling release protein genes and the productivity of a chemostat process. To avoid the use of antibiotics and render this process more sustainable, alternative plasmid selection mechanisms were required. In the current study, the strain E. coli JM109 harboring plasmid p582 was shown to stably express and secrete recombinant β-glucanase in continuous culture using a minimal medium. The segregational instability of the plasmid in the absence of antibiotic selection pressure was demonstrated. The leuB gene, crucial in the leucine biosynthetic pathway, was cloned onto plasmid p582 and the new construct transformed into an E. coli Keio (ΔleuB) knockout strain. The ability of the construct to complement the leucine auxotrophy was initially tested in shake-flasks and batch cultivation. Later, this strain was successfully grown for more than 200 h in a chemostat and was found to be able to express the recombinant protein. Significantly, it showed a stable maintenance of the recombinant plasmid in the absence of any antibiotics. The plasmid stability in a continuously cultivated E. coli fermentation, in the absence of antibiotics, with extracellular secretion of recombinant protein provides an interesting model for further improvements.

Increased production of pyruvic acid by Escherichia coli RNase G mutants in combination with cra mutations

The Escherichia coli RNase G is known as an endoribonuclease responsible for the 5'-end maturation of 16S rRNA and degradation of several specific mRNAs such as adhE and eno mRNAs. In this study, we found that an RNase G mutant derived from the MC1061 strain did not grow on a glucose minimal medium. Genetic analysis revealed that simultaneous defects of cra and ilvIH, encoding a transcriptional regulator of glycolysis/gluconeogenesis and one of isozymes of acetohydroxy acid synthase, respectively, were required for this phenomenon to occur. The results of additional experiments presented here indicate that the RNase G mutation, in combination with cra mutation, caused the increased production of pyruvic acid from glucose, which was then preferentially converted to valine due to the ilvIH mutation, resulting in depletion of isoleucine. In fact, the rng cra double mutant produced increased amount of pyruvate in the medium. These results suggest that the RNase G mutation could be applied in the breeding of producer strains of pyruvate and its derivatives such as valine.

Two Arabidopsis genes (IPMS1 and IPMS2) encode isopropylmalate synthase, the branchpoint step in the biosynthesis of leucine

Heterologous expression of the Arabidopsis (Arabidopsis thaliana) IPMS1 (At1g18500) and IPMS2 (At1g74040) cDNAs in Escherichia coli yields isopropylmalate synthases (IPMSs; EC 2.3.3.13). These enzymes catalyze the first dedicated step in leucine (Leu) biosynthesis, an aldol-type condensation of acetyl-coenzyme A (CoA) and 2-oxoisovalerate yielding isopropylmalate. Most biochemical properties of IPMS1 and IPMS2 are similar: broad pH optimum around pH 8.5, Mg2+ as cofactor, feedback inhibition by Leu, Km for 2-oxoisovalerate of approximately 300 microM, and a Vmax of approximately 2 x 10(3) micromol min(-1) g(-1). However, IPMS1 and IPMS2 differ in their Km for acetyl-CoA (45 microM and 16 microM, respectively) and apparent quaternary structure (dimer and tetramer, respectively). A knockout insertion mutant for IPMS1 showed an increase in valine content but no changes in Leu content; two insertion mutants for IPMS2 did not show any changes in soluble amino acid content. Apparently, in planta each gene can adequately compensate for the absence of the other, consistent with available microarray and reverse transcription-polymerase chain reaction data that show that both genes are expressed in all organs at all developmental stages. Both encoded proteins accept 2-oxo acid substrates in vitro ranging in length from glyoxylate to 2-oxohexanoate, and catalyze at a low rate the condensation of acetyl-CoA and 4-methylthio-2-oxobutyrate, i.e. a reaction involved in glucosinolate chain elongation normally catalyzed by methylthioalkylmalate synthases. The evolutionary relationship between IPMS and methylthioalkylmalate synthase enzymes is discussed in view of their amino acid sequence identity (60%) and overlap in substrate specificity.

Expression of a Brassica isopropylmalate synthase gene in Arabidopsis perturbs both glucosinolate and amino acid metabolism

Isopropylmalate synthase (IPMS) is a key enzyme in the biosynthesis of the essential amino acid leucine, and thus primary metabolism. In Arabidopsis, the functionally similar enzyme, methythiolalkylmalate synthase (MAM), is an important enzyme in the elongation of methionine prior to glucosinolate (GSL) biosynthesis, as part of secondary metabolism. We describe the cloning of an IPMS gene from Brassica, BatIMS, and its functional characterisation by heterologous expression in E. coli and Arabidopsis. Over expression of BatIMS in Arabidopsis resulted in plants with an aberrant phenotype, reminiscent of mutants in GSL biosynthesis. Metabolite analyses showed that these plants had both perturbed amino acid metabolism and enhanced levels of GSLs. Microarray profiling showed that BatIMS over expression caused up regulation of the genes for methionine-derived GSL biosynthesis, and down regulation of genes involved in leucine catabolism, in addition to perturbed expression of genes involved in auxin and ethylene metabolism. The results illustrate the cross talk that can occur between primary and secondary metabolism within transgenic plants.

Isoleucine biosynthesis in Leptospira interrogans serotype lai strain 56601 proceeds via a threonine-independent pathway

Three leuA-like protein-coding sequences were identified in Leptospira interrogans. One of these, the cimA gene, was shown to encode citramalate synthase (EC 4.1.3.-). The other two encoded alpha-isopropylmalate synthase (EC 4.1.3.12). Expressed in Escherichia coli, the citramalate synthase was purified and characterized. Although its activity was relatively low, it was strictly specific for pyruvate as the keto acid substrate. Unlike the citramalate synthase of the thermophile Methanococcus jannaschii, the L. interrogans enzyme is temperature sensitive but exhibits a much lower K(m) (0.04 mM) for pyruvate. The reaction product was characterized as (R)-citramalate, and the proposed beta-methyl-d-malate pathway was further confirmed by demonstrating that citraconate was the substrate for the following reaction. This alternative pathway for isoleucine biosynthesis from pyruvate was analyzed both in vitro by assays of leptospiral isopropylmalate isomerase (EC 4.2.1.33) and beta-isopropylmalate dehydrogenase (EC 1.1.1.85) in E. coli extracts bearing the corresponding clones and in vivo by complementation of E. coli ilvA, leuC/D, and leuB mutants. Thus, the existence of a leucine-like pathway for isoleucine biosynthesis in L. interrogans under physiological conditions was unequivocally proven. Significant variations in either the enzymatic activities or mRNA levels of the cimA and leuA genes were detected in L. interrogans grown on minimal medium supplemented with different levels of the corresponding amino acids or in cells grown on serum-containing rich medium. The similarity of this metabolic pathway in leptospires and archaea is consistent with the evolutionarily primitive status of the eubacterial spirochetes.

Glucosinolate and amino acid biosynthesis in Arabidopsis

Enzymes that catalyze the condensation of acetyl coenzyme A and 2-oxo acids are likely to be important in two distinct metabolic pathways in Arabidopsis. These are the synthesis of isopropylmalate, an intermediate of Leu biosynthesis in primary metabolism, and the synthesis of methylthioalkylmalates, intermediates of Met elongation in the synthesis of aliphatic glucosinolates (GSLs), in secondary metabolism. Four Arabidopsis genes in the ecotype Columbia potentially encode proteins that could catalyze these reactions. MAM1 and MAML are adjacent genes on chromosome 5 at the Gsl-elong locus, while MAML-3 and MAML-4 are at opposite ends of chr 1. The isopropylmalate synthase activity of each member of the MAM-like gene family was investigated by heterologous expression in an isopropylmalate synthase-null Escherichia coli mutant. Only the expression of MAML-3 restored the ability of the mutant to grow in the absence of Leu. A MAML knockout line (KO) lacked long-chain aliphatic GSLs, which were restored when the KO was transformed with a functional MAML gene. Variation in expression of MAML did not alter the total levels of Met-derived GSLs, but just the ratio of chain lengths. MAML overexpression in Columbia led to an increase in long-chain GSLs, and an increase in 3C GSLs. Moreover, plants overexpressing MAML contained at least two novel amino acids. One of these was positively identified via MS/MS as homo-Leu, while the other, with identical mass and fragmentation patterns, was likely to be homo-Ile. A MAML-4 KO did not exhibit any changes in GSL profile, but had perturbed soluble amino acid content.

The organization of the leuC, leuD and leuB genes of the extreme thermophile Thermus thermophilus

3-Isopropylmalate dehydrogenase is encoded by leuB gene while leuC and leuB genes encode the large and small subunits of isopropylmalate isomerase in leucine biosynthetic pathway, respectively. Organization of the leuB, leuC and leuD genes of an extreme thermophile, Thermus thermophilus, was investigated by sequence analysis. Location of the genes was also tested by complementation analysis of leu deficiency of the thermophile and Escherichia coli. The order was the leuC, leuD, and leuB genes and, in contrast to a previous report, they did not overlap with each other. Sequence analysis of the leuC and leuD genes suggested that cysteine residues for iron-sulfur binding and other amino acid residues involved in isomerase activity, which have been inferred from analysis of a related protein, aconitase, were highly conserved.

Cloning of Phanerochaete chrysosporium leu2 by complementation of bacterial auxotrophs and transformation of fungal auxotrophs

A Phanerochaete chrysosporium cDNA library was constructed in an expression vector that allows expression in both Escherichia coli and Saccharomyces cerevisiae. This expression vector, lambda YES, contains the lacZ promoter for expression in E. coli and the GAL1 promoter for expression in yeast. A number of genes were cloned by complementation of bacterial amino acid auxotrophs. The cDNA encoding the beta-isopropylmalate dehydrogenase from P. chrysosporium was characterized further. The genomic clone (gleu2) was subsequently isolated and was used successfully as a selectable marker to transform P. chrysosporium auxotrophs for LEU2. Protoplasts for transformation were prepared with readily obtained conidiospores rather than with basidiospores, which were used in previous P. chrysosporium transformation procedures. The method described here allows other genes to be isolated from P. chrysosporium for use as selectable markers.

Production of heteropolymeric polyhydroxyalkanoate in Escherichia coli from a single carbon source

Poly[beta-hydroxybutyrate-co-beta-hydroxyvalerate] co-polymer, PHBV, is a polyhydroxyalkanoate (PHA) that has greater utility as a biodegradable thermoplastic polyester than poly-beta-hydroxybutyrate, PHB. In order to produce PHBV, a system of pathways is required to produce both hydroxybutyrate (HB) and hydroxyvalerate (HV) monomers from the sources of carbon. A working model for conversion of glucose to PHBV via acetyl- and propionyl-coenzyme A was constructed by expressing the PHA biosynthesis genes from Alcaligenes eutrophus in Escherichia coli strain K-12 under novel growth conditions. When 1 mM valine was added to 1% glucose medium, growth ceased and up to 2.5% of the incorporated monomers were HV; up to 4% were HV when 1 mM threonine was added as well. Threonine dehydratase (TD) converts threonine to alpha-ketobutyrate; TD is required for HV to be incorporated into PHA unless its transaminated reaction product, alpha-aminobutyrate, is added to the medium. Intracellular alpha-ketobutyrate accumulates when valine is added to the medium because valine, which cannot be metabolized to HV by E. coli strain K-12, stimulates TD and inhibits acetolactate synthase. In turn, alpha-ketobutyrate is converted to propionyl-CoA by the E. coli pyruvate dehydrogenase complex. This constitutes a defined system of pathways for synthesis of a heteropolymeric PHA from a single carbon source, which in the future could be transferred to other organisms including plants.

In vivo growth characteristics of leucine and methionine auxotrophic mutants of Mycobacterium bovis BCG generated by transposon mutagenesis

Insertional mutagenesis in Mycobacterium bovis BCG, a member of the slow-growing M. tuberculosis complex, was accomplished with transposons engineered from the Mycobacterium smegmatis insertion element IS1096. Transposons were created by placing a kanamycin resistance gene in several different positions in IS1096, and the resulting transposons were electroporated into BCG on nonreplicating plasmids. These analyses demonstrated that only one of the two open reading frames was necessary for transposition. A library of insertions was generated. Southern analysis of 23 kanamycin-resistant clones revealed that the transposons had inserted directly, with no evidence of cointegrate formation, into different restriction fragments in each clone. Sequence analysis of nine of the clones revealed junctional direct 8-bp repeats with only a slight similarity in target sites. These results suggest that IS1096-derived transposons transposed into the BCG genome in a relatively random fashion. Three auxotrophs, two for leucine and one for methionine, were isolated from the library of transposon insertions in BCG. They were characterized by sequencing and found to be homologous to the leuD gene of Escherichia coli and a sulfate-binding protein of cyanobacteria, respectively. When inoculated intravenously into C57BL/6 mice, the leucine auxotrophs, in contrast to the parent BCG strain or the methionine auxotroph, showed an inability to grow in vivo and were cleared within 7 weeks from the lungs and spleen.

Molecular cloning of the leuB gene from Bacteroides fragilis by functional complementation in Escherichia coli

Clones containing the Bacteroides fragilis leuB-complementing gene were isolated by screening of a B. fragilis genomic library constructed in Escherichia coli. One recombinant clone, designated pOT865, with the smallest DNA insert (4.5 kb) could complement three independent leuB mutations in E. coli and the leuB-complementing determinant in pOT865 was localized to a region of 1.5-kb DNA. The results of Southern blot analysis suggested that a single copy of the cloned gene was present in the B. fragilis genome. The cloned fragment appeared to contain a sequence that could function as promoter in E. coli and direct the synthesis of a 42-kDa protein. These results suggest that the cloned segment contains the structural gene for beta-isopropylmalate dehydrogenase (leuB).

Hydrophobic interaction at the subunit interface contributes to the thermostability of 3-isopropylmalate dehydrogenase from an extreme thermophile, Thermus thermophilus

We cloned and sequenced the leuB gene encoding 3-isopropylmalate dehydrogenase from Escherichia coli K-12 (JM103). Errors (33 residues) were found and corrected in the sequence previously reported for the leuB gene of Thermus thermophilus. The three-dimensional structure of the thermophile enzyme and the amino acid sequence comparison suggested that a part of the high stability of the T. thermophilus enzyme is conferred by increased hydrophobic interaction at the subunit-subunit interface. Two residues at the interface of the T. thermophilus enzyme, Leu246 and Val249, are substituted with less hydrophobic residues, Glu and Met, respectively, in the E. coli enzyme, whereas other residues in this region are highly conserved. The mutated T. thermophilus enzyme [L246E, V249M]IPMDH had reduced stability to heat. Two residues of the E. coli dehydrogenase, Glu256 and Met259, were replaced with the corresponding residues from the thermophile sequence. The resulted mutant enzyme was more resistant to heat than the wild-type enzyme.

Leucine synthesis in Corynebacterium glutamicum: enzyme activities, structure of leuA, and effect of leuA inactivation on lysine synthesis

Enzymes and genes of the isopropylmalate pathway leading to leucine in Corynebacterium glutamicum were studied, and assays were performed to unravel their connection to lysine oversynthesis. The first enzyme of the pathway is inhibited by leucine (Ki = 0.4 mM), and all three enzyme activities of the isopropylmalate pathway are reduced upon addition of this amino acid to the growth medium. Three different DNA fragments were cloned, each resulting in an oversynthesis of one of the three enzymes. The leuA complementing fragment encoding the isopropylmalate synthase was sequenced. The leuA gene is 1,848 bp in size, encoding a polypeptide with an M(r) of 68,187. Upstream of leuA there is extensive hyphenated dyad symmetry and a putative leader peptide, which are features characteristic of attenuation control. In addition to leuA, the sequenced fragment contains an open reading frame with high coding probability whose disruption did not result in a detectable phenotype. Furthermore, the sequence revealed that this open reading frame separates leuA from lysC, which encodes the aspartate kinase initiating the synthesis of all amino acids of the aspartate family. The leuA gene was inactivated in three lysine-secreting strains by insertional mutagenesis. Fermentations were performed, and a roughly 50% higher lysine yield was obtained when appropriate leucine concentrations limiting for growth of the constructed strains were used.

Functions of the gene products of Escherichia coli

A list of currently identified gene products of Escherichia coli is given, together with a bibliography that provides pointers to the literature on each gene product. A scheme to categorize cellular functions is used to classify the gene products of E. coli so far identified. A count shows that the numbers of genes concerned with small-molecule metabolism are on the same order as the numbers concerned with macromolecule biosynthesis and degradation. One large category is the category of tRNAs and their synthetases. Another is the category of transport elements. The categories of cell structure and cellular processes other than metabolism are smaller. Other subjects discussed are the occurrence in the E. coli genome of redundant pairs and groups of genes of identical or closely similar function, as well as variation in the degree of density of genetic information in different parts of the genome.

Branched-chain-amino-acid biosynthesis in plants: molecular cloning and characterization of the gene encoding acetohydroxy acid isomeroreductase (ketol-acid reductoisomerase) from Arabidopsis thaliana (thale cress)

Towards the goal of gaining a better understanding of the molecular mechanisms controlling branched-chain-amino-acid biosynthesis in plants, we have isolated, sequenced and characterized a gene encoding acetohydroxy acid isomero-reductase (ketol-acid reductoisomerase) from Arabidopsis thaliana (thale cress). Comparison between the acetohydroxy acid isomeroreductase cDNA and the genomic sequence has allowed us to determine the exon structure of the coding region. The isolated acetohydroxy acid isomeroreductase gene is distributed over approx. 4.5 kbp and contains nine introns (79-347 bp). The transcriptional start site was found to be 52 bp upstream of the translational initiation site. Southern-blot analysis of A. thaliana genomic DNA shows that the acetohydroxy acid isomeroreductase is encoded by a single-copy gene.

The nucleotide sequence of genes involved in the leucine biosynthetic pathway of Clostridium pasteurianum

A 2.2 kb SphI/ClaI fragment of the Clostridium pasteurianum chromosome has previously been cloned and shown to complement leuB401 and leuC171 mutations in Escherichia coli. The nucleotide sequence of this fragment has been determined (2327 bp) and carries three open reading frames. The products of translation of these reading frames display significant homologies with the alpha-isopropylmalate isomerase subunit (leuD) gene of Salmonella typhimurium, the beta-isopropylmalate dehydrogenase (leuB) genes of several organisms, and the dihydroxyacid dehydrase (ilvD) gene of E. coli.

Branched-chain amino acid biosynthesis genes in Lactococcus lactis subsp. lactis

The genes for biosynthesis of the branched-chain amino acids leucine, isoleucine, and valine in Lactococcus lactis subsp. lactis NCDO2118 were characterized by cloning, complementation in Escherichia coli and Bacillus subtilis, and nucleotide sequence analysis. Nine structural genes are clustered on a 12-kb DNA fragment in the order leuABCD ilvDBNCA. Upstream of these genes, the nucleotide sequence suggests the existence of regulation by transcriptional attenuation. Between the leuD and ilvD genes is an unexpected gene, encoding a protein which belongs to the ATP-binding cassette protein superfamily.

Genetic approaches to cell biology and metabolism of spirochetes

Genetic analysis and methodology have only comparatively recently been applied to the study of spirochetes. Although genetic transfer procedures for spirochetes are not widely available, there are several examples of progress in genetic analysis of spirochetes by other approaches. Some examples of these approaches are the following. 1) Genes for synthetic pathways in Treponema and Leptospira have been cloned by complementation of Escherichia coli serving as plasmid hosts. 2) The OspA protein of Borrelia burgdorferi has been overexpressed in E. coli without the signal peptide; the recombinant product has been suitable for circular dichroism as well as other biochemical analyses. 3) The heat shock proteins of B. burgdorferi are homologous to heat shock proteins of E. coli. 4) Enzyme activity profiles of B. burgdorferi and other spirochetes show strain heterogeneity and also indicate which biosynthetic and enzymatic activities are conserved within different spirochetes. 5) The gene organization of rRNA genes have revealed differences between spirochetes and other types of bacteria.

Cloning of Campylobacter jejuni genes required for leucine biosynthesis, and construction of leu-negative mutant of C. jejuni by shuttle transposon mutagenesis

Campylobacter jejuni is a Gram-negative pathogen responsible for diarrhoeal diseases in humans. To date, very little is known about the genetic organization and molecular biology of this microorganism. The cosmid vector pHC79 was used to construct a genomic library from the total genomic DNA of C. jejuni strain C31 in Escherichia coli and recombinant cosmids capable of complementing the auxotrophic defect in leucine biosynthesis of E. coli HB101 were identified. Three of 400 clones tested were found to be capable of complementing the nutritional defect of E. coli HB101 as well as those of independent leuB mutants of E. coli strains. These results indicated that the cloned genes responsible for leucine complementation encoded an enzyme analogous to the beta-isopropylmalate dehydrogenase specified by the leuB gene in E. coli strains. The sizes of the recombinant cosmids which became stabilized in E. coli cells ranged from 12.9 to 15.4 kb compared to the expected, originally packaged, 45- to 50-kb molecules, attesting to major rearrangements occurring in this background. The recombinant plasmid pILL547 was shown to carry genes that were analogous to the leuB gene and also to the leuC and leuD genes of E. coli. The gene required for leuB complementation was subcloned on a 1.6-kb restriction fragment and was mapped more precisely by insertional mutagenesis using as transposon a newly constructed (MiniTn3-Km) element engineered to mutagenize Campylobacter genes. The leuB gene of C. jejuni was shown to be expressed from its own promoter in E. coli cells. In E. coli minicells, the cloned insert encoded a polypeptide with an apparent molecular weight of 40 kDa. A leucine auxotrophic mutant of C. jejuni strain C31 was constructed in vitro by allelic exchange, replacing the original copy of the leucine gene by an allele mutated by the insertion of the kanamycin transposable element.

A functional leuABCD operon is required for leucine synthesis by the tyrosine-repressible transaminase in Escherichia coli K-12

In Escherichia coli K-12, two enzymes, encoded by ilvE and tyrB, catalyze the amination of 2-ketoisocaproate (2-KIC) to form leucine. Although leucine-requiring derivatives of an ilvE strain that are unable to grow on 2-KIC were expected to have mutations only in tyrB, mapping studies showed that one such mutation was tightly linked to the leu operon (at 1.5 min), not to tyrB (at 92 min). Chromosomal fragments cloned because they complemented this mutation were found to complement leu mutations, and vice versa, but none of these fragments complemented a tyrB mutation. The Tn5 insertion and flanking host DNA from this anomalous mutant was cloned in vivo, using Mu dII4042, and an in vivo procedure was developed to isolate deletion derivatives of Tn5-containing plasmids. These deletion plasmids were used to determine the DNA sequences flanking the transposon. The data showed that Tn5 was inserted between bp 122 and 132 in the leu leader. In addition, other ilvE leu double mutants were found to be unable to grow on 2-KIC in place of leucine. The accumulation of 2-ketoisovalerate in ilvE leu double mutants was shown to interfere with 2-KIC amination by the tyrB-encoded transaminase and also by the aspC- and avtA-encoded transaminases (which are able to catalyze this reaction in vivo when the corresponding genes are present on multicopy plasmids).

Molecular cloning and characterization of supQ/newD, a gene substitution system for the leuD gene of Salmonella typhimurium

The isopropylmalate isomerase of Salmonella typhimurium and Escherichia coli is a complex of the leuC and leuD gene products. The supQ/new D gene substitution system in S. typhimurium restores leucine prototrophy to leuD mutants of S. typhimurium. Previous genetic evidence supports a model that indicates the replacement of the missing LeuD polypeptide by the newD gene product. This model proposed that this gene substitution is possible when a mutation at the supQ locus (near newD) liberates unaltered newD polypeptide from its normal complex with the supQ protein product. In this study, recombinant plasmids carrying newD, supQ, or both were transformed into E. coli and S. typhimurium strains deleted for the leuD and supQ genes to test the supQ/newD gene substitution model for suppression of leucine auxotrophy. It was determined that the newD gene encodes a 22-kilodalton polypeptide which can restore leucine prototrophy to leuD deletion strains and that a functional supQ gene prevents this suppression. It was also determined that the supQ and newD genes are separated by a gene encoding a 50-kilodalton protein, pB. While there is extensive DNA sequence homology between the leucine operons of S. typhimurium and E. coli, DNA hybridization experiments did not indicate substantial homology between the newD and leuD genes. These data, taken together with previously obtained genetic data, eliminate the possibility that supQ and newD are recently translocated segments of the leucine operon.

Expression of leucine genes from an extremely thermophilic bacterium in Escherichia coli

The organisation of the leucine genes in Thermus thermophilus HB8 was analysed by examining the ability of recombinant DNAs to complement Escherichia coli mutations. The arrangement of the genes is different from that in the mesophilic bacteria E. coli and Salmonella typhimurium. The promoter responsible for the expression of the leuB, leuC and leuD genes of Thermus HB8 in E. coli was identified. The sequence of Thermus DNA containing this promoter revealed structural similarities to the promoter and attenuator regions of the E. coli leucine operon.

Allele-specific complementation of an Escherichia coli leuB mutation by a Lactobacillus bulgaricus tRNA gene

A Lactobacillus bulgaricus gene encoding a serine tRNA with the anticodon CGA was isolated from a L. bulgaricus clone bank and characterized. This gene is expressed and active in Escherichia coli. The wild-type form of the gene allele specifically complements the E. coli leuB6 mutation. This process depends on gene copy number; high copy number restores leucine prototrophy, while low copy number does not. We suggest that restoration of activity of the mutant leuB6 allele occurs by missense suppression. The L. bulgaricus tRNA(CGASer) when overproduced in E. coli is misacylated at a low frequency, leading to the insertion of an amino acid other than serine in response to the presumed mutant codon UCG in the leuB6 gene. Nucleotide (nt) sequences flanking the tRNA coding region are present in the L. bulgaricus tRNA gene, closely resembling E. coli promoter and terminator elements. A noteworthy feature of this tRNA gene is the extreme length (22 nt) of its extra arm. The 3'-terminal CCA of the tRNA is not encoded in this tRNA gene and thus must be added posttranscriptionally.

Characterization of the 3' end of the leucine operon of Salmonella typhimurium

The nucleotide sequence of the leuD gene of Salmonella typhimurium and of the downstream flanking region are presented. S1 mapping experiments identified 3' endpoints of leu mRNA 140 and 285 nucleotides downstream of the UAA stop codon of leuD mRNA. Experiments employing pulse-labeled RNA suggest that these endpoints result from transcription termination rather than RNA processing. Our results indicate that the organization of the 3' non-translated region of the leu operon from S. typhimurium resembles that of the trp operon of Escherichia coli. Further, our results suggest that the leu operon of S. typhimurium does not contain structural genes other than those identified by genetic experiments, i.e. leu, A,B,C and D.

Insertion of bacteriophage SP beta into the citF gene of Bacillus subtilis and specialized transduction of the ilvBC-leu genes

We isolated a strain of Bacillus subtilis in which the SP beta c2 prophage is inserted into the citF (succinate dehydrogenase) gene. Defective specialized transducing particles for the ilvBC-leu genes were isolated from phage-induced lysates of this lysogen. We isolated a group of phages that differ in the amount of genetic material they carry from this region. Also, we incorporated mutant ilv and leu alleles into the genomes of several transducing phages. Our phage collection enables us to identify the cistron of new ilv and leu mutations by complementation analysis. In this process we discovered a fourth leu cistron, leuD. Characterization of the phages confirmed the published gene order: ilvB-ilvC-leuA-leuC-leuB; leuD lies to the right of leuB.

Wild-type isopropylmalate isomerase in Salmonella typhimurium is composed of two different subunits

The isopropylmalate isomerase in Salmonella typhimurium is the second enzyme specific for leucine biosynthesis. It is a complex enzyme composed of two subunits which are coded for by two genes of the leucine operon, leuC and leuD. The two polypeptides have been shown to copurify through successive ammonium sulfate fractionations and have been identified on sodium dodecyl sulfate-polyacrylamide gels as having molecular weights of 51,000 (leuC gene product) and 23,500 (leuD gene product). They have also been shown to be fairly stable, since in vitro complementation of cell-free extracts of leuC and leuD mutant strains was demonstrated, with only a 40% loss of activity 16 h after preparation of the extracts. The native isopropylmalate isomerase was shown to have a Km for its substrate alpha-isopropylmalate of 3 x 10(-4)M.

Cloning of an EcoRI-generated fragment of the leucine operon of Salmonella typhimurium

Recombinant plasmids carrying part of the leucine operon of Salmonella typhimurium were isolated following transformation of an Escherichia coli leucine auxotroph to prototrophy with a ligated mixture of EcoRI-treated Salmonella DNA and plasmid pSC101 DNA. Plasmids pCV11 and pCV13, containing a 3.4-10(6) dalton DNA fragment ligated to the vector, had the leu operon oriented in opposite directions. The orientation of the leu operon relative to plasmid genes was determined. The 3.4-10(6) dalton fragment was ligated in to the EcoRI site of plasmid pMB9 yielding plasmids pCV12 (orientation as in pCV11) and pCV14 (orientation as in pCV13). The results of enzyme assays and complementation tests indicated that these plasmids carry functional leuA, leuB, and leuC genes but not a functional leuD gene. Furthermore, the following results indicated that they have a functional leu control region and promoter. Expression of plasmid leu genes was markedly enhanced under conditions of leucine limitation whereas introduction of a leu promoter mutation into the operon oriented in either direction with respect to plasmid genes had a strong negative effect upon leu operon expression. Transcriptional readthrough from plasmid promoters, if it occurs at all, must be small in comparison with transcription initiated at the leu promoter. RNA was isolated from leucine auxotrophs grown under conditions of repression and derepression and from prototrophic strains derepressed for the leucine operon as a result of mutations in leuO, leuS, and flrB. The rate of synthesis of leu mRNA, measured by hybridization to plasmid pCV12 DNA, was proportional in each case to leu enzyme levels.

Salmonella typhimurium newD and Escherichia coli leuC genes code for a functional isopropylmalate isomerase in Salmonella typhimurium-Escherichia coli hybrids

The supQ newD gene substitution system in Salmonella typhimurium restores leucine prototrophy to leuD mutants by providing the newD gene product which is capable of replacing the missing leuD polypeptide in the isopropylmalate isomerase, a complex of the leuC and leuD gene product. Mutations in the supQ gene are required to make the newD protein available. An Escherichia coli F' factor was constructed which carried supQ- newD+ from S. typhimurium on a P22-specialized transducing genome. This F' pro lac (P22dsupQ394newD) episome was transferred into S. typhimurium strains containing th leuD798-ara deletion; the resulting merodiploid strains had a Leu+ phenotype, indicating that supQ- newD+ is dominant over supQ+ newD+, and eliminating the possibility that the supQ gene codes for a repressor of the newD gene. Furthermore, transfer of the F' pro lac (P22dsupQ39newD) into E. coli leuD deletion strains restored leucine prototrophy, showing that the S. typhimurium newD gene can complment the E. coli leuC gene. Growth rates of the S. typhimurium-E coli hybrid strains indicated that the mutant isopropylmalate isomerase in these strains does not induce a leucine limitation, as it does in S. typhimurium leuD supQ mutants. In vitro activity of the mutant isopropylmalate isomerase was demonstrated; the Km values for alpha-isopropylmalate of both the S. typhimurium leuC-newD isomerase and the S. typhimurium-E. coli hybrid isomerase were as much as 100 times higher than the Km values for alpha-isopropylmalate of the wild-type enzyme, which was 3 x 10(-4) M. Mutagenesis of E. coli leuD deletion strains failed to restore leucine prototrophy, indicating that E. coli does not have genes analogous to the S. typhimurium supQ newD genes, of that, if present, activation of a newD is a rare event or is lethal to the cell.

Transformation of yeast by a replicating hybrid plasmid

Chimaeric plasmids have been constructed containing a yeast plasmid and fragments of yeast nuclear DNA linked to pMB9, a derivative of the ColEl plasmid from E. coli. Two plasmids were isolated which complement leuB mutations in E. coli. These plasmids have been used to develop a method for transforming a leu2 strain of S. cerevisiae to Leu+ with high frequency. The yeast transformants contained multiple plasmid copies which were recovered by transformation in E. coli. The yeast plasmid sequence recombined intramolecularly during propagation in yeast.

Relationship between messenger ribonucleic acid and enzyme levels specified by the leucine operon of Escherichia coli K-12

The levels of leucine-forming enzymes in Escherichia coli K-12 varied over a several thousand-fold range, depending upon conditions of growth. The highest levels were achieved by growing auxotrophs in a chemostat under conditions of leucine limitation. Under such conditions, enzyme levels were increased 45- to 90-fold relative to cells grown in minimal medium containing leucine (the latter values arbitrarily called 1). Leucine operon-specific messenger ribonucleic acid levels were elevated to about the same extent as enzyme levels in cells grown in a chemostat. Growth in media of greater complexity resulted in progressively lower levels of leucine-forming enzymes, reaching a value of less than 0.02 for growth in a medium containing tryptone broth and yeast extract. The levels of leucine operon-specified enzymes and messenger ribonucleic acid were also measured in strains containing about 25 copies of plasmid pCV1(ColE1-leu) per chromosome. For such strains grown in minimal medium, enzyme levels were proportional to the number of plasmids per cell. Furthermore, they followed the same trends as those described above upon derepression in a chemostat or upon repression following growth in rich media. Leucine messenger ribonucleic acid, measured both by pulse-labeling and hybridization-competition experiments, was roughly proportional to enzyme levels over this entire range. For a plasmid-containing strain grown in a chemostat under conditions of leucine limitation (about 100 plasmids per chromosome), about 27% of pulse-labeled ribonucleic acid was coded for by genes in or adjacent to the leucine operon, and 10% of the total protein was beta-isopropylmalate dehydrogenase.

Functional expression of cloned yeast DNA in Escherichia coli

A collection of hybrid circular DNAs was constructed in vitro using the poly(dA-dT) "connector" method: each hybrid circle contained one molecule of poly(dT)-tailed DNA of plasmid ColE1 (made linear by digestion with EcoRI endonuclease) annealed to a poly(dA)-tailed fragment of yeast (Saccharomyces cerevisiae) DNA, produced originally by shearing total yeast DNA to an average size of 8 X 10(6) daltons. This DNA preparation was used to transform E. coli cells, selecting colicin-E1-resistant clones that contain hybrid ColE1-yeast DNA plasmids. Sufficient numbers of transformant clones were obtained to ensure that the hybrid plasmid population was representative of the entire yeast genome. Various hybrid ColE1-yeast DNA plasmids capable of complementing E. coli auxotrophic mutations were selected from this population. Plasmid pYeleu 10 complements several different point or deletion mutations in the E. coli or S. typhimurium leuB gene (beta-isopropylmalate dehydrogenase); plasmids pYeleu11, pYeleu12, and pYeleu17 are specific suppressors of the leuB6 mutation in E. coli C600. Plasmid pYehis2 complements a deletion in the E. coli hisB gene (imidazole glycerol phosphate dehydratase). Complementation of bacterial mutations by yeast DNA segments does not appear to be a rare phenomenon.

Leucine biosynthesis in the blue-green bacterium Anacystis nidulans

Leucine-requiring auxotrophs of the unicellular blue-green bacterium Anacystis nidulans have been isolated. Extracts of these mutants were deficient in alpha-isopropylmalate synthetase (EC 4.1.3.12). In wild-type cells, this enzyme was subject to feedback inhibition by leucine. However, formation of the enzymes of leucine biosynthesis was little affected by exogenous leucine in either wild-type or mutant strains. Cultures of the latter subjected to extreme leucine deprivation showed no change in specific activity of beta-isopropylmalate isomerase (EC 4.2.1.33) and at most a 50% increase in the specific activity of beta-isopropylmalate dehydrogenase (EC 1.1.1.85). These results are compared with others bearing on the evolution of the control of amino acid biosynthesis in blue-green bacteria.

Evolution of a new gene substituting for the leuD gene of Salmonella typhimurium: origin and nature of supQ and newD mutations

The second specific enzyme in the biosynthesis of leucine, alpha-isopropylmalate isomerase, is coded for by two genes, leuC and leuD. Leucine auxotrophs carrying mutations in the leuD gene (including deletions of the entire leuD gene) revert to leucine prototrophy by secondary mutations at the locus supQ, which is located in the proline region of the chromosome. The mechanism of the supQ function is explained by the following model. The supQ gene and an additional gene, newD, code for two different subunits of a multimeric enzyme, whose normal function is yet to be determined. The newD gene protein is able, without genetic alterations, to form an active complex with the leuC protein, thus replacing the nonfunctional or missing leuD protein and restoring leucine prototrophy. The newD protein has, however, a higher affinity for the supQ protein than for the leuC protein; therefore, mutations in the supQ gene are needed to make sufficient amounts of the newD protein available. The following gene order has been established: gpt-proB-proA-ataA-supQ-newD. Different supQ mutations have been identified, i.e., insertion in the supQ gene, point mutations, and deletions of various extent. Some deletions remove the P22 phage attachment site ataA. Other supQ deletions are simultaneously Pro(-), because they extend into the proA or proA and proB genes; some extend even further, i.e., into the gpt gene (guanine phosphoribosyl transferase). Mutations in the newD gene caused renewed leucine auxotrophy in leuD supQ mutant strains. One newD mutation causes a temperature-sensitive Leu(+) phenotype. Alternate models for the supQ-newD interactions are discussed.

Gene order and co-transduction in the leu-ara-fol-pyrA region of the Salmonella typhimurium linkage map

The gene order and orientation in the leu-pyrA region of the Salmonella typhimurium linkage map was established by phage P22-mediated transductions. The gene order, in counterclockwise orientation, is leuO-leuA-leuB-leuC-leuD-ara-fol-pyrA. The fol locus is co-transducible with either the ara and leu loci or the pyrA locus, whereas no co-transduction for the ara and pyrA loci can be found.

Genetic analysis of the leucine region in Escherichia coli B-r: gene-enzyme assignments

Genetic mapping by transduction and conjugation using F(-) and F' strains carrying either point mutations in the l-arabinose or leucine regions or ara-leu fusion-deletion mutations has resulted in a detailed genetic map of the arabinose-leucine region of Escherichia coli B/r. These studies have identified four genes in the leucine region having the same order as found in Salmonella typhimurium: ara... leuDCBA.