Evolution of a New Gene Substituting for the leuD Gene of Salmonella typhimurium: Characterization of supQ Mutations

Alpha-isopropylmalate isomerase, the second specific enzyme in the biosynthesis of leucine, is coded for by two genes, leuC and leuD. Leucine auxotrophs, harboring leuD mutations including a deletion of the entire leuD gene, revert to leucine prototrophy owing to mutations at a locus, supQ, substantially distant to the leucine operon. A large number of independently isolated supQ mutations were characterized. A significant increase in the spontaneous frequency of supQ mutations was found after mutagenesis with 2-aminopurine, N-methyl-N′-nitro-N-nitrosoguanidine, diethyl sulfate, and nitrous acid. The supQ function in most of these strains is temperature sensitive, resulting in more efficient suppression with decreasing temperature. At higher temperatures, the supQ limits the growth rate of leuD supQ mutant strains. All supQ mutations are co-transducible with proA and proB, with co-transduction frequencies ranging from 5.4 to 99.9% for different supQ mutations. Many supQ mutations were isolated, especially after nitrous acid mutagenesis, that had acquired a simultaneous proline requirement. The data support the idea of two genes, supQ and newD, whose protein products form a complex. The newD gene product, without any genetic alteration, is capable of substituting for the missing leuD protein. However, mutations in the supQ gene (point mutations or deletions) are necessary to make the newD protein available, which is normally tied up in a complex with the supQ protein.     

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.     

Introduction of genes for leucine biosynthesis from Clostridium pasteurianum into C. acetobutylicum by cointegrate conjugal transfer

Summary A Clostridium pasteurianum gene bank was constructed in Escherichia coli, using plasmid pAT153, and several chromosomal fragments found which complemented both leuB and leuC mutations in auxotrophic E. coli K12 strains. No fragments capable of complementing leuA or leuD mutations were identified. Conjugal transfer of the LeuB/leuC genes from Bacillus subtilis into two different Leu^- C. acetobutylicum auxotrophic strains was elicited by their incorporation into a large plasmid cointegrate composed of the conjugal plasmid pAM1 and a specially constructed gram-positive, replication-deficient plasmid, pMTL21 EC. Inheritance of the cointegrate plasmid restored one of the auxotrophic C. acetobutylicum strains to prototrophy. The second strain remained Leu^-.     

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

Summary 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.     

Biological assay of prokaryotic genes in mouse cells following DNA mediated transformation

Summary Genes coding for leucine biosynthesis in Bacillus subtilis were introduced into mouse LTK^- cells by co-transformation with thymidine kinase⁺ (tk) DNA. Genomic DNA from the tk⁺ transformants was used to transform competent cultures of different B. subtilis leucine auxotrophs. Each auxotroph was transformed to prototrophy at a similar frequency and the number of leucine gene sequences per transformant genome as deduced by the B. subtilis bioassay strongly correlated with the number estimated by hybridization methods. Tk^- subclones were obtained by plating the transformants in 5-bromodeoxyuridine. One subclone still contained the non-selected leucine gene sequences and could transform auxotrophs of B. subtilis. No deletions or rearrangements in the linkage relationships of the leucine genes occurred in the LTK^- cells that inhibited transformation of B. subtilis.     

Efficient Allelic Exchange and Transposon Mutagenesis in Mycobacterium avium by Specialized Transduction

Mycobacterium tuberculosis and Mycobacterium avium are pathogenic slow-growing mycobacteria that cause distinct human diseases. In contrast to recent advances in M. tuberculosis genetics and pathogenesis investigation, M. avium has remained genetically intractable and, consequently, its pathogenic strategies remain poorly understood. Here we report the successful development of efficient allelic exchange and transposon mutagenesis in an opaque clinical strain of M. avium by specialized transduction. Efforts to disrupt the leuD gene of M. avium by specialized transduction were successful but were complicated by inefficient isolation of recombinants secondary to high spontaneous antibiotic resistance. However, by using this leucine auxotroph as a genetic host and the Streptomyces coelicolor leuD gene as a selectable marker, we achieved efficient allelic exchange at the M. avium pcaA locus. A leuD-marked transposon delivered by specialized transduction mutagenized M. avium with efficiencies similar to M. tuberculosis. These results establish a system for random and directed mutagenesis of M. avium. In combination with the forthcoming M. avium genome sequence, these tools will allow the distinct physiologic and pathogenic properties of M. avium to be dissected in molecular detail.     

In-Frame and Unmarked Gene Deletions in Burkholderia cenocepacia via an Allelic Exchange System Compatible with Gateway Technology

Burkholderia cenocepacia is an emerging opportunistic pathogen causing life-threatening infections in immunocompromised individuals and in patients with cystic fibrosis, which are often difficult, if not impossible, to treat. Understanding the genetic basis of virulence in this emerging pathogen is important for the development of novel treatment regimes. Generation of deletion mutations in genes predicted to encode virulence determinants is fundamental to investigating the mechanisms of pathogenesis. However, there is a lack of appropriate selectable and counterselectable markers for use in B. cenocepacia, making its genetic manipulation problematic. Here we describe a Gateway-compatible allelic exchange system based on the counterselectable pheS gene and the I-SceI homing endonuclease. This system provides efficiency in cloning homology regions of target genes and allows the generation of precise and unmarked gene deletions in B. cenocepacia. As a proof of concept, we demonstrate its utility by deleting the Bcam1349 gene, encoding a cyclic di-GMP (c-di-GMP)-responsive regulator protein important for biofilm formation.     

The Green Monster Process for the Generation of Yeast Strains Carrying Multiple Gene Deletions

Phenotypes for a gene deletion are often revealed only when the mutation is tested in a particular genetic background or environmental condition^1,2. There are examples where many genes need to be deleted to unmask hidden gene functions^3,4. Despite the potential for important discoveries, genetic interactions involving three or more genes are largely unexplored. Exhaustive searches of multi-mutant interactions would be impractical due to the sheer number of possible combinations of deletions. However, studies of selected sets of genes, such as sets of paralogs with a greater a priori chance of sharing a common function, would be informative.In the yeast Saccharomyces cerevisiae, gene knockout is accomplished by replacing a gene with a selectable marker via homologous recombination. Because the number of markers is limited, methods have been developed for removing and reusing the same marker^5,6,7,8,9,10. However, sequentially engineering multiple mutations using these methods is time-consuming because the time required scales linearly with the number of deletions to be generated.Here we describe the Green Monster method for routinely engineering multiple deletions in yeast¹¹. In this method, a green fluorescent protein (GFP) reporter integrated into deletions is used to quantitatively label strains according to the number of deletions contained in each strain (Figure 1). Repeated rounds of assortment of GFP-marked deletions via yeast mating and meiosis coupled with flow-cytometric enrichment of strains carrying more of these deletions lead to the accumulation of deletions in strains (Figure 2). Performing multiple processes in parallel, with each process incorporating one or more deletions per round, reduces the time required for strain construction.The first step is to prepare haploid single-mutants termed ''ProMonsters,'' each of which carries a GFP reporter in a deleted locus and one of the ''toolkit'' loci—either Green Monster GMToolkit-a or GMToolkit-α at the can1Δ locus (Figure 3). Using strains from the yeast deletion collection¹², GFP-marked deletions can be conveniently generated by replacing the common KanMX4 cassette existing in these strains with a universal GFP-URA3 fragment. Each GMToolkit contains: either the a- or α-mating-type-specific haploid selection marker¹ and exactly one of the two markers that, when both GMToolkits are present, collectively allow for selection of diploids.The second step is to carry out the sexual cycling through which deletion loci can be combined within a single cell by the random assortment and/or meiotic recombination that accompanies each cycle of mating and sporulation.     

Role of the Outer Membrane Protein OprD2 in Carbapenem-Resistance Mechanisms of Pseudomonas aeruginosa

We investigated the relationship between the outer membrane protein OprD₂ and carbapenem-resistance in 141 clinical isolates of Pseudomonas aeruginosa collected between January and December 2013 from the First Affiliated Hospital of Anhui Medical University in China. Agar dilution methods were employed to determine the minimum inhibitory concentration of meropenem (MEM) and imipenem (IMP) for P. aeruginosa. The gene encoding OprD₂ was amplified from141 P. aeruginosa isolates and analyzed by PCR and DNA sequencing. Differences between the effects of IMP^R and IMP^S groups on the resistance of the P. aeruginosa were observed by SDS-poly acrylamide gel electrophoresis (SDS-PAGE). Three resistance types were classified in the 141 carbapenem-resistant P. aeruginosa (CRPA) isolates tested, namely IMP^RMEM^R (66.7%), IMP^RMEM^S (32.6%), and IMP^RMEM^S (0.7%). DNA sequencing revealed significant diverse gene mutations in the OprD₂-encoding gene in these strains. Thirty-four strains had large fragment deletions in the OprD₂gene, in 6 strains the gene contained fragment inserts, and in 96 resistant strains, the gene featured small fragment deletions or multi-site mutations. Only 4 metallo-β-lactamase strains and 1 imipenem-sensitive (meropenem-resistant) strain showed a normal OprD₂ gene. Using SDS-PAGE to detect the outer membrane protein in 16 CRPA isolates, it was found that 10 IMP^RMEM^R strains and 5 IMP^RMEM^S strains had lost the OprD₂ protein, while the IMP^SMEM^R strain contained a normal 46-kDa protein. In conclusion, mutation or loss of the OprD₂-encoding gene caused the loss of OprD₂, which further led to carbapenem-resistance of P. aeruginosa. Our findings provide insights into the mechanism of carbapenem resistance in P. aeruginosa.     

The NIaIV restriction and modification genes of Neisseria lactamica are flanked by leucine biosynthesis genes

The genes encoding the Neisseria lactamica restriction endonuclease IV (R.NIaIV) and its cognate DNA methyltransferase (M.NlaIV), both of which recognize the sequence GGNNCC, have been cloned in Escherichia coli and overexpressed using the T7 polymerase/promoter system. Analysis of a sequenced 3.58 kb fragment established the gene order, leuD-M.NlaIV-R.NlaIV-leuB. The predicted primary sequence of M.NlaIV (423 amino acids) shows the highest degree of identity to a pair of cytosine-specific methyltransferases, M.BanI (44.9%) and M.HgiCI (44.3%), which recognize the sequence GGYRCC (Y, pyrimidines; R, purines). In contrast, the R.NlaIV protein sequence (243 amino acids) is unique in the existing database, a situation that holds for most endonucleases. Flanking the NlaIV modification and restriction genes are homologues of the leuD and leuB genes of enteric bacteria, which code for enzymes in the leucine biosynthesis pathway. This gene context implies a possible new mode of gene regulation for the RM.NlaIV system, which would involve a mechanism similar to the recently discovered leucine/Lrp regulon in E. coli.     

Genomic Characterization of Phenylalanine Ammonia Lyase Gene in Buckwheat

Phenylalanine Ammonia Lyase (PAL) gene which plays a key role in bio-synthesis of medicinally important compounds, Rutin/quercetin was sequence characterized for its efficient genomics application. These compounds possessing anti-diabetic and anti-cancer properties and are predominantly produced by Fagopyrum spp. In the present study, PAL gene was sequenced from three Fagopyrum spp. (F. tataricum, F. esculentum and F. dibotrys) and showed the presence of three SNPs and four insertion/deletions at intra and inter specific level. Among them, the potential SNP (position 949^th bp G>C) with Parsimony Informative Site was selected and successfully utilised to individuate the zygosity/allelic variation of 16 F. tataricum varieties. Insertion mutations were identified in coding region, which resulted the change of a stretch of 39 amino acids on the putative protein. Our Study revealed that autogamous species (F. tataricum) has lower frequency of observed SNPs as compared to allogamous species (F. dibotrys and F. esculentum). The identified SNPs in F. tataricum didn’t result to amino acid change, while in other two species it caused both conservative and non-conservative variations. Consistent pattern of SNPs across the species revealed their phylogenetic importance. We found two groups of F. tataricum and one of them was closely related with F. dibotrys. Sequence characterization information of PAL gene reported in present investigation can be utilized in genetic improvement of buckwheat in reference to its medicinal value.     

Heterologous expression and characterization of bacterial 2-C-methyl-d-erythritol-4-phosphate pathway in Saccharomyces cerevisiae

Transfer of a biosynthetic pathway between evolutionary distant organisms can create a metabolic shunt capable of bypassing the native regulation of the host organism, hereby improving the production of secondary metabolite precursor molecules for important natural products. Here, we report the engineering of Escherichia coli genes encoding the 2-C-methyl-d-erythritol-4-phosphate (MEP) pathway into the genome of Saccharomyces cerevisiae and the characterization of intermediate metabolites synthesized by the MEP pathway in yeast. Our UPLC-MS analysis of the MEP pathway metabolites from engineered yeast showed that the pathway is active until the synthesis of 2-C-methyl-d-erythritol-2,4-cyclodiphosphate, but appears to lack functionality of the last two steps of the MEP pathway, catalyzed by the [4Fe–4S] iron sulfur cluster proteins encoded by ispG and ispH. In order to functionalize the last two steps of the MEP pathway, we co-expressed the genes for the E. coli iron sulfur cluster (ISC) assembly machinery. By deleting ERG13, thereby incapacitating the mevalonate pathway, in conjunction with labeling experiments with U–¹³C₆ glucose and growth experiments, we found that the ISC assembly machinery was unable to functionalize ispG and ispH. However, we have found that leuC and leuD, encoding the heterodimeric iron–sulfur cluster protein, isopropylmalate isomerase, can complement the S. cerevisiae leu1 auxotrophy. To our knowledge, this is the first time a bacterial iron–sulfur cluster protein has been functionally expressed in the cytosol of S. cerevisiae under aerobic conditions and shows that S. cerevisiae has the capability to functionally express at least some bacterial iron–sulfur cluster proteins in its cytosol.     

The Type II Secretion System of Legionella pneumophila Elaborates Two Aminopeptidases, as Well as a Metalloprotease That Contributes to Differential Infection among Protozoan Hosts

Legionella pneumophila, the agent of Legionnaires' disease, is an intracellular parasite of aquatic amoebae and human macrophages. A key factor for L. pneumophila in intracellular infection is its type II protein secretion system (Lsp). In order to more completely define Lsp output, we recently performed a proteomic analysis of culture supernatants. Based upon the predictions of that analysis, we found that L. pneumophila secretes two distinct aminopeptidase activities encoded by the genes lapA and lapB. Whereas lapA conferred activity against leucine, phenylalanine, and tyrosine aminopeptides, lapB was linked to the cleavage of lysine- and arginine-containing substrates. To assess the role of secreted aminopeptidases in intracellular infection, we examined the relative abilities of lapA and lapB mutants to infect human U937 cell macrophages as well as Hartmannella vermiformis and Acanthamoeba castellanii amoebae. Although these experiments identified a dispensable role for LapA and LapB, they uncovered a previously unrecognized role for the type II-dependent ProA (MspA) metalloprotease. Whereas proA mutants were not defective for macrophage or A. castellanii infection, they (but not their complemented derivatives) were impaired for growth upon coculture with H. vermiformis. Thus, ProA represents the first type II effector implicated in an intracellular infection event. Furthermore, proA represents an L. pneumophila gene that shows differential importance among protozoan infection models, suggesting that the legionellae might have evolved some of its factors to especially target certain of their protozoan hosts.     

Integration of mammalian, microbial and drosophila procedures for evaluating chemical mutagens.

cis-Platinum(II)diamminodichloride (PDD), an anti-tumor agent, induced auxotrophic mutations in Escherichia coli, some of which were reverted to prototrophy by exposure to PDD, 2-aminopurine (2-AP), and N-methyl-N′-nitro-N-nitroguanidine (NTG), but not ICR derivatives. Similarly, various 2-AP-, NTG-, and ultraviolet light-induced auxotrophs were reverted to prototrophy by PDD. Some PDD-induced auxotrophs carried nonsense mutations and others could be phenotypically suppressed by growth with streptomycin. Although these findings suggest that PDD promotes base substitutions, this mutagen may also cause base subtractions because (like NTG)it induced, at reduced frequency, reversion to prototrophy of certain ICR-induced auxotrophs. Isomeric trans-platinum(II)diamminodichloride, which lacks anti-tumor activity, was an ineffective mutagen. Near-optimal conditions for PDD-induced mutagenesis entailed prolonged cultivation with low levels of mutagen where the frequency of forward mutation to auxotrophy was 10⁻³ and that of a selected trp isolate to prototrophy was 10⁻².     

Gene Expression and Stability of mRNA Affected by DNA-Arrested Synthesis in Gene 59, 46, and 47 Mutants of Bacteriophage T4

The effect of bacteriophage T4 gene 59 mutations (DNA-arrested synthesis) on kinetics of DNA synthesis, gene expression, and stability of mRNA has been studied. When Escherichia coli B was infected by a T4 gene 59 mutant, DNA synthesis proceeded to increase linearly after initiation, but started to decrease at 8 min and was completely arrested at 12 min at 37°C. At various incubation temperatures (20 to 42°C), the initial rates and times of arrest of DNA synthesis were different, but the total amount of DNA synthesized was constant. This result supports the hypothesis that function of gene 59 is required for the conversion of 63S DNA molecules to other replicative intermediates (39). The abnormality in protein synthesis caused by gene 59 mutation is manifested by (i) a delayed shutoff in the expression of early proteins (gene 43, 46, 39, 52, 63, 42-45, and some unidentified proteins), (ii) a reduced rate of late gene expression (gene 34, 37, 18, 20, 23, wac, 24, 22, 38, and 19), and (iii) an absence of cleavage of certain late proteins (23, 24, IPIII and 22 to 23^*, 24^*, IPIII^*, and small fragments). It appears that there was no effect on the expression of gene 33, 55, and 32 by a mutation in gene 59. Results obtained from an addition of rifampin at the prereplicative cycle after infection indicated that mRNA from genes 43, rIIA, 46, 39, 52, and 63 are more stable in T4amC5 (gene 59) than in wild-type-infected cells. mRNA remained functional longer in mutant-infected cells, and this may explain the prolonged synthesis of certain early proteins. The gene expression of other DNA arrested mutants—those in genes 46 and 47—showed a pattern of abnormal protein synthesis similar to that found in gene 59 mutant-infected cells, except more late proteins are synthesized. The gene expression in terms of phage DNA structure is discussed.     

Cloning and Characterization of the Zymobacter palmae Pyruvate Decarboxylase Gene (pdc) and Comparison to Bacterial Homologues

Pyruvate decarboxylase (PDC) is the key enzyme in all homo-ethanol fermentations. Although widely distributed among plants, yeasts, and fungi, PDC is absent in animals and rare in bacteria (established for only three organisms). Genes encoding the three known bacterial pdc genes have been previously described and expressed as active recombinant proteins. The pdc gene from Zymomonas mobilis has been used to engineer ethanol-producing biocatalysts for use in industry. In this paper, we describe a new bacterial pdc gene from Zymobacter palmae. The pattern of codon usage for this gene appears quite similar to that for Escherichia coli genes. In E. coli recombinants, the Z. palmae PDC represented approximately 1/3 of the soluble protein. Biochemical and kinetic properties of the Z. palmae enzyme were compared to purified PDCs from three other bacteria. Of the four bacterial PDCs, the Z. palmae enzyme exhibited the highest specific activity (130 U mg of protein⁻¹) and the lowest K_m for pyruvate (0.24 mM). Differences in biochemical properties, thermal stability, and codon usage may offer unique advantages for the development of new biocatalysts for fuel ethanol production.     

Mutations Affecting the α Subunit of Bordetella pertussis RNA Polymerase Suppress Growth Inhibition Conferred by Short C-Terminal Deletions of the Response Regulator BvgA

The effects of short deletions of the C terminus of the BvgA response regulator protein of the BvgAS two-component system were examined in Bordetella pertussis. When present as a single copy in the chromosome, deletions removing as few as two amino acids conferred a completely Bvg⁻ phenotype. When provided in trans, on the broad-host-range plasmid pRK290, under the control of the native bvgAS promoter, deletions of two or three amino acids conferred a profound growth inhibition which was dependent on the integrity and activity of the wild-type chromosomal bvgAS locus. It is proposed that this phenotype was the result of an inappropriate interaction of the mutant BvgA protein with the RNA polymerase enzyme, specifically the α subunit. Mutant strains in which this growth inhibition was relieved were isolated and characterized. Although most of the suppressor mutations affected either the mutant plasmid copy or the wild-type chromosomal bvg locus, three mutations which affected the α subunit of B. pertussis RNA polymerase were also isolated. Two of these resulted in increased levels of the α subunit, and one caused a substitution of glycine for the aspartic acid residue at position 171, in the N-terminal domain. All three mutations also resulted in a differential phenotype in that expression of fha was essentially normal, but expression of ptx was greatly reduced.