Epistatic effects of promoter and repressor functions of the Tn10 tetracycline-resistance operon on the fitness of Escherichia coli

We have been studying the effects of expression of plasmid-borne, Tn10-encoded, tetracycline resistance on the fitness of Escherichia coli K12. We previously demonstrated large reductions in fitness resulting from induced or constitutive expression of the resistance protein; however, any residual expression by the repressed operon was so slight that possession of an inducible resistance function imposed essentially no burden in the absence of antibiotic. Here, we demonstrate two distinct disadvantages for inducible genotypes relative to isogenic constitutive constructs. During the transition from antibiotic-free to antibiotic-containing media, the inducible genotype experiences a longer lag phase prior to growth. In the sustained presence of antibiotic, full induction of the resistance function in the inducible genotype is prevented by the continued action of its repressor. However, these disadvantages may be reduced by increasing the strength of the promoter for the resistance gene in the inducible genotype. Simultaneous consideration of the mode of gene regulation (i.e. constitutive or inducible) and the strength of the resistance-gene promoter (i.e. maximum level of expression) indicates an adaptive landscape with very strong epistasis and, perhaps, multiple fitness peaks.     

Construction of an E. coli strain overproducing the Tn10-encoded TET repressor and its use for large scale purification.

Overproduction of the repressor protein from the Tn10-encoded tetracycline resistance operon is achieved by placement of the respective gene under control of bacteriophage lambda promoter PL in a vector-host system. All cloning steps have to be carried out under repressed conditions to assure survival of the cell. The cI 857 mutation is used to control expression of the tetR gene in large scale fermentation. After induction, the overproducing Escherichia coli strain continues to grow for 2.5 generations before growth terminates. In the expression phase, active TET repressor comprises up to 13% of the total soluble protein. A procedure is described to purify the TET repressor protein to homogeneity on a large scale. Starting from a 10 litre culture, approximately 250 mg of homogeneous, active TET repressor are obtained. The amino acid sequence of the N and C termini are in agreement with the gene start and stop determined from the nucleotide sequence of the Tn10 tetR gene.     

Constitutive expression of tetracycline resistance mediated by a Tn10-like element in Haemophilus parainfluenzae results from a mutation in the repressor gene.

The Tn10-like constitutively expressed tetracycline resistance determinant from a Haemophilus parainfluenzae strain was cloned in Escherichia coli. Toxicity resulting from expression on multicopy plasmids necessitated its being cloned on a low-copy plasmid vector or in cells containing the Tn10-encoded repressor. Constitutive expression of tetracycline resistance was found to result from the synthesis of a truncated inactive repressor molecule. Instead of the 23-kilodalton repressor found in other Tn10-containing strains, this determinant encoded a 14.5-kilodalton molecule. The DNA sequence of the 700-base-pair region spanning the repressor gene and promoter-operator regions of the Haemophilus determinant was identical to that of the same region of Tn10, except for the absence of a single T X A base pair in the repressor gene. This deletion leads to premature termination of the protein. Antisera to the repressor suggested that the repressor was also absent in a second independently isolated H. parainfluenzae strain bearing a Tn10-like constitutive tetracycline resistance determinant.     

MexAB-OprM hyperexpression in NalC-type multidrug-resistant Pseudomonas aeruginosa: identification and characterization of the nalC gene encoding a repressor of PA3720-PA3719

MexAB-OprM is a multidrug efflux system that contributes to intrinsic and acquired multidrug resistance in Pseudomonas aeruginosa, the latter as a result of mutational hyperexpression of the mexAB-oprM operon. While efflux gene hyperexpression typically results from mutations in the linked mexR repressor gene, it also occurs independently of mexR mutations in so-called nalC mutants that demonstrate more modest mexAB-oprM expression and, thus, more modest multidrug resistance than do mexR strains. Using a transposon insertion mutagenesis approach, nalC mutant strains were selected and the disrupted gene, PA3721, identified. Amplification and sequencing of this gene from previously isolated spontaneous nalC mutants revealed the presence of mutations in all instances and as such, PA3721 has been renamed nalC. PA3721 (nalC) encodes a probable repressor of the TetR/AcrR family and occurs upstream of an apparent two-gene operon, PA3720-PA3719, whose expression was negatively regulated by PA3721. Thus, PA3720-PA3719 was hyperexpressed in transposon insertion and spontaneous nalC mutants. The loss of PA3719 but not of PA3720 expression in a spontaneous nalC mutant reduced MexAB-OprM expression to wild-type levels and compromised multidrug resistance, an indication that hyperexpression of PA3719 only was necessary for the nalC phenotype. Introduction of PA3719 into wild-type P. aeruginosa on a multicopy plasmid was, in fact, sufficient to promote elevated MexAB-OprM expression and multidrug resistance characteristic of a nalC strain. Thus, the nalC (PA3721) mutation serves only to enhance PA3720-PA3719 expression, with expression of PA3719 (encodes a 53 amino acid protein of predicted pI 10.4) directly or indirectly impacting MexAB-OprM expression. Intriguingly, nalC strains produce markedly elevated levels of stable MexR protein suggesting that PA3720-PA3719 hyperexpression somehow modulates MexR repressor activity. The deduced products of PA3720-PA3719 show no homology to sequences presently in the GenBank databases, however, and as such provide no clues as to how this might occur.     

Cloning of chemically synthesized lactose operators.

Recombinant DNA molecules, constructed from the ColE1-Mk5 hybrid plasmid PMB9 and a chemically synthesized wild-type lactose operator segment, have been used to transform Escherichia coli. Up to 10% of the transformants (selected for the tetracycline-resistance property of PMB9) are partially constitutive for the lactose operon enzyme beta-galactosidase. In vitro studies demonstrate that these partially constitutive transformants contain plasmid DNA molecules which carry one or more lactose operators, and which will bind purified lactose repressor. Preliminary results with some modified operator sequences are also presented.     

Evolution of transposable elements: an IS10 insertion increases fitness in Escherichia coli

Strains of Escherichia coli carrying Tn10, a transposon consisting of two IS10 insertion sequences flanking a segment encoding for a tetracycline-resistance determinant, gain a competitive advantage in chemostat cultures. All Tn10-bearing strains that increase in frequency during competition have a new IS10 insertion that is found in the same location in the genome of those strains. We mapped, by a gradient of transmission, the position of the new IS10 insertion. We examined 11 isolates whose IS10 insertion was deleted by recombinational crossing- over, and in all cases the competitive fitness of the isolates was decreased. These results show that the IS10-generated insertion increases fitness in chemostat cultures. We named the insertion fit::IS10 and suggest that transposable elements may speed the rate of evolution by promoting nonhomologous recombination between preexisting variations within a genome and thereby generating adaptive variation.      

Sequence homology between the tetracycline-resistance determinants of Tn10 and pBR322

The Tn10 tetracycline resistance gene, tetA, encodes a tetracycline-inducible protein with an apparent Mr of 36 X 10(3). We have determined the nucleotide sequence of the Tn10 tetA gene. The extent of the tetA gene was determined by analysis of amino-terminal and carboxy-terminal deletion mutants. We conclude that a single Tn10 gene, the tetA gene, is sufficient to confer tetracycline resistance. The predicted Mr of the tetA protein is 43.2 X 10(3). The sequence homology between the Tn10 tetA gene and the pBR322 tetracycline resistance determinant (49% nucleotide homology, 44% amino acid homology) indicates that these phenotypically distinct tetracycline-resistance determinants must have evolved from a common ancestral sequence. The markedly hydrophobic character of the predicted amino acid sequences of the Tn10 tetA and pBR322 tet-coded proteins suggests that a substantial portion of these proteins may be embedded within the cytoplasmic membrane.     

The gene yjfQ encodes the repressor of the yjfR-X regulon (ula), which is involved in L-ascorbate metabolism in Escherichia coli

Mutations in yjfQ allowed us to identify this gene as the regulator of the operon yjfS-X (ula operon), reported to be involved in L-ascorbate metabolism. Inactivation of this gene renders constitutive the expression of the ula operon, indicating that YjfQ acts as a repressor. We also demonstrate that this repressor regulates the nearby yjfR gene, which in this way constitutes a regulon with the ula operon.