Transposable elements for efficient manipulation of a wide range of gram-negative bacteria: promoter probes and vectors for foreign genes

We describe here the construction and use of a series of modified transposons based on the insertion sequence IS1. Like their parent, omegon-Km [Fellay et al., Gene 76 (1989) 215-226], these elements permit efficient insertional mutagenesis of a variety of Gram-negative bacteria. The presence of a functional pBR322 origin of replication within the transposable element facilitates subsequent cloning of the mutated gene. The omegon-Km system was previously shown to function in Pseudomonas putida, Rhizobium leguminosarum and Paracoccus denitrificans. The results we present here demonstrate that its use can be extended to Xanthomonas campestris, a plant pathogen, and to the microaeroduric Zymomonas mobilis. Derivative transposons carrying unique restriction sites for ScaI, NdeI, XbaI and XhoI have been constructed, allowing the cloning and introduction of foreign genes. We have also constructed two derivatives which can be used to generate operon fusions upon insertion and are thus useful for isolating and characterising indigenous promoters. One carries a promoterless chloramphenicol acetyl-transferase (CAT)-encoding gene (cat) and the second, the entire promoterless Escherichia coli lac operon. We demonstrate the utility of the cat promoter probe in X. campestris to target conditional promoters inducible by high salt or subject to repression by glucose.     

Gene fusion vehicles for the analysis of gene expression in Rhizobium meliloti.

A set of plasmid cloning vehicles was developed to facilitate the construction of gene or operon fusions in Rhizobium meliloti. The vehicles also contain a broad-host-range replicon and could be introduced into bacteria either by transformation or by transduction, using bacteriophage P2. Insertion of foreign DNA into a unique restriction endonuclease cleavage site promotes the synthesis of either the Escherichia coli lactose operon or the kanamycin phosphotransferase gene from transposon Tn5. Expression of the lactose operon could be detected by observing the color of Rhizobium colonies on medium that contained a chromogenic indicator. We also determined the growth conditions that make it possible to select either for or against the expression of the E. coli lactose operon in R. meliloti. Recombinant plasmids were constructed by inserting MboI restriction fragments of R. meliloti DNA into one of the vehicles, pMK353 . Expression of beta-galactosidase by a number of these recombinants was measured in both R. meliloti and E. coli.     

Molecular cloning in yeast by in vivo homologous recombination of the yeast putative alpha1 subunit of the voltage-gated calcium channel

Saccharomyces cerevisiae has only one gene encoding a putative voltage-gated Ca2+ channel pore-forming subunit, CCH1, which is not possible to be cloned by conventional molecular cloning techniques using Escherichia coli. Here, we report the successful cloning of CCH1 in yeast by in vivo homologous recombination without using E. coli. Overexpression of the cloned CCH1 or MID1 alone, which encodes a putative stretch-activated Ca2+ channel component, does not increase Ca2+ uptake activity, but co-overexpression results in a 2- to 3-fold increase. Overexpression of CCH1 does not substantially complement the lethality and low Ca2+ uptake activity of a mid1 mutant and vice versa. These results indicate that co-overproduction of Cch1 and Mid1 is sufficient to increase Ca2+ uptake activity.     

Identification and characterization of an outer membrane protein, OmpX, in Escherichia coli that is homologous to a family of outer membrane proteins including Ail of Yersinia enterocolitica.

We previously reported that a region of the Escherichia coli chromosome at 18 min increased E sigma E activity when cloned in multicopy (J. Mecsas, P. E. Rouviere, J. W. Erickson, T. J. Donohue, and C. A. Gross, Genes Dev. 7:2618-2628, 1993). In the present report, we identify and characterize the gene responsible for the increase in E sigma E activity. This gene is in a monocistronic operon with two promoters and a rho-independent terminator. Sequence analysis of this gene indicated that it encodes an outer membrane protein which is 83% identical to OmpX in Enterobacter cloacae, leading us to name this gene ompX. There are four other proteins that are homologous to OmpX. Several of these proteins, Ail of Yersinia enterocolitica and Rck and PagC of Salmonella typhimurium, have properties that allow bacteria to adhere to mammalian cells, survive exposure to human serum, and/or survive within macrophages. We therefore characterized strains deleted for ompX for their growth phenotypes, E sigma E activity, serum resistance, and adherence to mammalian cells. No differences in growth rates, serum resistance, or adherence to mammalian cells were observed; however, E sigma E activity was dependent on expression of OmpX in certain strain backgrounds.     

Expression and characterization of ras mRNAs from Saccharomyces cerevisiae.

The cellular homologs of the Harvey and Kirsten murine sarcoma virus oncogenes comprise a multigene family, ras, that displays striking evolutionary conservation. We recently reported [DeFeo-Jones et al., Nature (London) 306:707-709, 1983] the cloning of two ras homologs from the yeast Saccharomyces cerevisiae. The nucleotide sequences of these genes predict polypeptides that show remarkable homology to p21, the mammalian ras gene product. We have also found proteins in yeast lysates with serological cross-reactivity to p21 (Papageorge et al., Mol. Cell. Biol. 4:23-29, 1984). In this work, we explored the relationship between the immunoprecipitated proteins and the yeast ras genes. We show that both ras genes are expressed in the wild-type cell. Furthermore, we demonstrate by in vitro translation of hybrid-selected RASsc1 mRNA and immunoprecipitation of the translation products that the cloned RASsc1 gene encodes the proteins immunoprecipitated from yeast lysates by anti-p21 monoclonal antibody. Finally, we used anti-p21 monoclonal antibodies to detect a guanine nucleotide binding activity in yeast lysates. The structural and biochemical homologies between ras gene products of S. cerevisiae and mammalian cells suggest that information obtained by genetic analysis of ras function in a lower eucaryote should be applicable to higher organisms as well.     

Expression of E. coli araBAD operon encoding enzymes for metabolizing L-arabinose in Saccharomyces cerevisiae

The Escherichia coli araBAD operon consists of three genes encoding three enzymes that convert L-arabinose to D-xylulose-5 phosphate. In this paper we report that the genes of the E. coli araBAD operon have been expressed in Saccharomyces cerevisiae using strong promoters from genes encoding S. cerevisiae glycolytic enzymes (pyruvate kinase, phosphoglucose isomerase, and phosphoglycerol kinase). The expression of these cloned genes in yeast was demonstrated by the presence of the active enzymes encoded by these cloned genes and by the presence of the corresponding mRNAs in the new host. The level of expression of L-ribulokinase (araB) and L-ribulose-5-phosphate 4-epimerase (araD) in S. cerevisiae was relatively high, with greater than 70% of the activity of the enzymes in wild type E. coli. On the other hand, the expression of L-arabinose isomerase (araA) reached only 10% of the activity of the same enzyme in wild type E. coli. Nevertheless, S. cerevisiae, bearing the cloned L-arabinose isomerase gene, converted L-arabinose to detectable levels of L-ribulose during fermentation. However, S. cerevisiae bearing all three genes (araA, araB, and araD) was not able to produce detectable amount of ethanol from L-arabinose. We speculate that factors such as pH, temperature, and competitive inhibition could reduce the activity of these enzymes to a lower level during fermentation compared to their activity measured in vitro. Thus, the ethanol produced from L-arabinose by recombinant yeast containing the expressed BAD genes is most likely totally consumed by the cell to maintain viability.     

pLR: A lentiviral backbone series to stable transduction of bicistronic genes and exchange of promoters

Gene transfer based on lentiviral vectors allow the integration of exogenous genes into the genome of a target cell, turning these vectors into one of the most used methods for stable transgene expression in mammalian cells, in vitro and in vivo. Currently, there are no lentivectors that allow the cloning of different genes to be regulated by different promoters. Also, there are none that permit the analysis of the expression through an IRES (internal ribosome entry site) - reporter gene system. In this work, we have generated a series of lentivectors containing: (1) a malleable structure to allow the cloning of different target genes in a multicloning site (mcs); (2) unique site to exchange promoters, and (3) IRES followed by one of two reporter genes: eGFP or DsRed. The series of the produced vectors were named pLR (for lentivirus and RSV promoter) and were fairly efficient with a strong fluorescence of the reporter genes in direct transfection and viral transduction experiments. This being said, the pLR series have been found to be powerful biotechnological tools for stable gene transfer and expression.     

Suppression of Escherichia coli alkB mutants by Saccharomyces cerevisiae genes.

The alkB gene is one of a group of alkylation-inducible genes in Escherichia coli, and its product protects cells from SN2-type alkylating agents such as methyl methanesulfonate (MMS). However, the precise biochemical function of the AlkB protein remains unknown. Here, we describe the cloning, sequencing, and characterization of three Saccharomyces cerevisiae genes (YFW1, YFW12, and YFW16) that functionally complement E. coli alkB mutant cells. DNA sequence analysis showed that none of the three gene products have any amino acid sequence homology with the AlkB protein. The YFW1 and YFW12 proteins are highly serine and threonine rich, and YFW1 contains a stretch of 28 hydrophobic residues, indicating that it may be a membrane protein. The YFW16 gene turned out to be allelic with the S. cerevisiae STE11 gene. STE11 is a protein kinase known to be involved in pheromone signal transduction in S. cerevisiae; however, the kinase activity is not required for MMS resistance because mutant STE11 proteins lacking kinase activity could still complement E. coli alkB mutants. Despite the fact that YFW1, YFW12, and YFW16/STE11 each confer substantial MMS resistance upon E. coli alkB cells, S. cerevisiae null mutants for each gene were not MMS sensitive. Whether these three genes provide alkylation resistance in E. coli via an alkB-like mechanism remains to be determined, but protection appears to be specific for AlkB-deficient E. coli because none of the genes protect other alkylation-sensitive E. coli strains from killing by MMS.     

Genetic complementation of the Saccharomyces cerevisiae leu2 gene by the Escherichia coli leuB gene.

The leucine operon of Escherichia coli was cloned on a plasmid possessing both E. coli and Saccharomyces cerevisiae replication origins. This plasmid, pEH25, transformed leuA, leuB, and leuD auxotrophs of E. coli to prototrophy; it also transformed leu2 auxotrophs of S. cerevisiae to prototrophy. beta-Isopropylmalate dehydrogenase was encoded by the leuB gene of E. coli and the leu2 gene of yeast. Verification that the leuB gene present on pEH26 was responsible for complementing yeast leu2 was obtained by isolating in E. coli several leuB mutations that resided on the plasmid. These mutant leuB- plasmids were no longer capable of complementing leu2 in S. cerevisiae. We conclude that S. cerevisiae is capable of transcribing at least a portion of the polycistronic leu operon of E. coli and can translate a functional protein from at least the second gene of this operon. The yeast Leu+ transformants obtained with pEH25, when cultured in minimal medium lacking leucine, grew with a doubling time three to four times longer than when cultured in medium supplemented with leucine.     

Cloning, nucleotide sequence, and expression of the Bacillus subtilis lon gene.

The lon gene of Escherichia coli encodes the ATP-dependent serine protease La and belongs to the family of sigma 32-dependent heat shock genes. In this paper, we report the cloning and characterization of the lon gene from the gram-positive bacterium Bacillus subtilis. The nucleotide sequence of the lon locus, which is localized upstream of the hemAXCDBL operon, was determined. The lon gene codes for an 87-kDa protein consisting of 774 amino acid residues. A comparison of the deduced amino acid sequence with previously described lon gene products from E. coli, Bacillus brevis, and Myxococcus xanthus revealed strong homologies among all known bacterial Lon proteins. Like the E. coli lon gene, the B. subtilis lon gene is induced by heat shock. Furthermore, the amount of lon-specific mRNA is increased after salt, ethanol, and oxidative stress as well as after treatment with puromycin. The potential promoter region does not show similarities to promoters recognized by sigma 32 of E. coli but contains sequences which resemble promoters recognized by the vegetative RNA polymerase E sigma A of B. subtilis. A second gene designated orfX is suggested to be transcribed together with lon and encodes a protein with 195 amino acid residues and a calculated molecular weight of 22,000.