Promoter mutations affecting divergent transcription in the Tn10 tetracycline resistance determinant

Role of AcrAB-TolC multidrug efflux pump in drug-resistance acquisition by plasmid transfer

Drug-resistance dissemination by horizontal gene transfer remains poorly understood at the cellular scale. Using live-cell microscopy, we reveal the dynamics of resistance acquisition by transfer of the Escherichia coli fertility factor-conjugation plasmid encoding the tetracycline-efflux pump TetA. The entry of the single-stranded DNA plasmid into the recipient cell is rapidly followed by complementary-strand synthesis, plasmid-gene expression, and production of TetA. In the presence of translation-inhibiting antibiotics, resistance acquisition depends on the AcrAB-TolC multidrug efflux pump, because it reduces tetracycline concentrations in the cell. Protein synthesis can thus persist and TetA expression can be initiated immediately after plasmid acquisition. AcrAB-TolC efflux activity can also preserve resistance acquisition by plasmid transfer in the presence of antibiotics with other modes of action.

Relation between tetR and tetA expression in tetracycline resistant Escherichia coli

BACKGROUND

Tetracyclines are among the most used antibiotics in livestock worldwide. Resistance is widely disseminated in Escherichia coli, where it is generally mediated by tetracycline efflux pumps, such as TetA. Expression of tetracycline efflux pumps is tightly controlled by the repressor TetR, which has been shown to be tetracycline-responsive at sub-MIC tetracycline concentrations. The objective of this study was to investigate the effects of increasing tetracycline concentrations on the growth of TetA-producing E. coli, and to determine how expression of tetA and tetR related to each other in different growth phases in the presence of tetracycline.

RESULTS

A tetracycline resistant E. coli strain containing tetA and tetR on the chromosome was constructed and cultured in the presence of increasing concentrations of tetracycline. Expression of tetR and tetA was measured at four time points in different growth phases by quantitative real-time PCR. The TetA-producing E. coli exhibited prolonged lag phase with increasing concentrations of tetracycline, while expression of tetA and tetR increased and decreased, respectively, with increasing tetracycline concentration. The levels of tetA and tetR mRNA varied depending on growth phase, resulting in a gradual decrease of the tetA/tetR ratio from approximately 4 in the lag phase to approximately 2 in the stationary phase.

CONCLUSION

This study shows that the expression of tetR and tetA is tetracycline concentration- and growth phase-dependent, contributing to improved understanding of the relationships between E. coli growth, tetracycline exposure and expression of tetracycline resistance.

Potential of Tetracycline Resistance Proteins To Evolve Tigecycline Resistance

Tigecycline is a glycylcycline antibiotic active against multidrug-resistant bacterial pathogens. The objectives of our study were to examine the potential of the Tet(A), Tet(K), Tet(M), and Tet(X) tetracycline resistance proteins to acquire mutations causing tigecycline resistance and to determine how this affects resistance to earlier classes of tetracyclines. Mutations in all four tet genes caused a significant increase in the tigecycline MIC in Escherichia coli, and strains expressing mutant Tet(A) and Tet(X) variants reached clinically relevant MICs (2 mg/liter and 3 mg/liter, respectively). Mutations predominantly accumulated in transmembrane domains of the efflux pumps, most likely increasing the accommodation of tigecycline as a substrate. All selected Tet(M) mutants contained at least one mutation in the functionally most important loop III of domain IV. Deletion of leucine 505 of this loop led to the highest increase of the tigecycline MIC (0.5 mg/liter) among Tet(M) mutants. It also caused collateral sensitivity to earlier classes of tetracyclines. A majority of the Tet(X) mutants showed increased activity against all three classes of tetracylines. All tested Tet proteins have the potential to acquire mutations leading to increased MICs of tigecycline. As tet genes are widely found in pathogenic bacteria and spread easily by horizontal gene transfer, resistance development by alteration of existing Tet proteins might compromise the future medical use of tigecycline. We predict that Tet(X) might become the most problematic future Tet determinant, since its weak intrinsic tigecycline activity can be mutationally improved to reach clinically relevant levels without collateral loss in activity to other tetracyclines.

Stochastic simulations of the tetracycline operon

Background

The tetracycline operon is a self-regulated system. It is found naturally in bacteria where it confers resistance to antibiotic tetracycline. Because of the performance of the molecular elements of the tetracycline operon, these elements are widely used as parts of synthetic gene networks where the protein production can be efficiently turned on and off in response to the presence or the absence of tetracycline. In this paper, we investigate the dynamics of the tetracycline operon. To this end, we develop a mathematical model guided by experimental findings. Our model consists of biochemical reactions that capture the biomolecular interactions of this intriguing system. Having in mind that small biological systems are subjects to stochasticity, we use a stochastic algorithm to simulate the tetracycline operon behavior. A sensitivity analysis of two critical parameters embodied this system is also performed providing a useful understanding of the function of this system.

Results

Simulations generate a timeline of biomolecular events that confer resistance to bacteria against tetracycline. We monitor the amounts of intracellular TetR2 and TetA proteins, the two important regulatory and resistance molecules, as a function of intrecellular tetracycline. We find that lack of one of the promoters of the tetracycline operon has no influence on the total behavior of this system inferring that this promoter is not essential for Escherichia coli. Sensitivity analysis with respect to the binding strength of tetracycline to repressor and of repressor to operators suggests that these two parameters play a predominant role in the behavior of the system. The results of the simulations agree well with experimental observations such as tight repression, fast gene expression, induction with tetracycline, and small intracellular TetR2 amounts.

Conclusions

Computer simulations of the tetracycline operon afford augmented insight into the interplay between its molecular components. They provide useful explanations of how the components and their interactions have evolved to best serve bacteria carrying this operon. Therefore, simulations may assist in designing novel gene network architectures consisting of tetracycline operon components.

A dual-signal regulatory circuit activates transcription of a set of divergent operons in Salmonella typhimurium

We present a molecular mechanism for signal transduction that activates transcription of the SlyA regulon in Salmonella typhimurium. We demonstrate that SlyA mediates transcriptional activation in response to guanosine tetraphosphate, ppGpp, according to the following observations: (i) in vivo transcription of SlyA-dependent genes is repressed when ppGpp is absent; this transcription can be restored by overproducing SlyA; (ii) in vivo dimerization and binding of SlyA to the target promoter are facilitated in the presence of ppGpp; and (iii) in vitro SlyA binding to the target promoter is enhanced when ppGpp is supplemented. Thus, ppGpp must be the cytoplasmic component that stimulates SlyA regulatory function by interacting directly with this regulator in Salmonella. This signaling domain, integrated by the PhoP/PhoQ 2-component system that activates slyA transcription by sensing Mg(2+), forms feedforward loops that regulate chromosomal loci identified through a motif search over the S. typhimurium genome. Many such loci are divergent operons, each formed by 2 neighboring genes in which transcription of these 2 loci proceeds in opposite directions. Both genes, however, are controlled by PhoP and SlyA through a single shared PhoP box and SlyA box present in their intergenic regions. A substitution in either box sequence causes a simultaneous cessation of transcription of a divergent operon, pagD-pagC, equivalent to the phenotype in a phoP or slyA mutant. We also identified several chromosomal loci that possess pagC-type genes without the cognate pagD-type genes. Therefore, our results provide a molecular basis for the understanding of SlyA-dependent phenotypes associated with Salmonella virulence.

lambda-Red genetic engineering in Salmonella enterica serovar Typhimurium

The use of the recombination system from bacteriophage lambda, lambda-Red, allows for PCR-generated fragments to be targeted to specific chromosomal locations in sequenced genomes. A minimal region of homology of 30 to 50 bases flanking the fragment to be inserted is all that is required for targeted mutagenesis. Procedures for creating specific insertions, deletions, and site-directed changes are described.

The presence of thetetgene from cloning vectors impairsSalmonellasurvival in macrophages

Cloning, mutagenesis and complementation of virulence factors are key steps to understand the mechanisms of bacterial pathogenesis and cloning vectors are routinely utilized for these processes. We have investigated the effect of the presence of commonly used cloning vectors on the survival of the intracellular bacterial pathogen Salmonella during macrophage infection. We demonstrate that the presence of the pSC101 derived tetracycline resistance gene on plasmids causes a lower survival rate of Salmonella in macrophages. The decrease in survival caused by the presence of the tet gene was not due to a higher susceptibility to gentamicin, a growth defect, or to increased sensitivity to acid. Higher susceptibility to hydrogen peroxide was observed in vitro for strain containing plasmid with the tet gene when the strains were grown at high densities but not when they were grown at low densities. Our findings demonstrate that the use of the tet gene for mutation or complementation can have deleterious effects and should thus be carefully considered.

The effects of DNA supercoiling on the expression of operons of the ilv regulon of Escherichia coli suggest a physiological rationale for divergently transcribed operons

Transcriptional activities of closely spaced divergent promoters are affected by the accumulation of local negative superhelicity in the region between transcribing RNA polymerase molecules (transcriptional coupling). The effect of this transcription-induced DNA supercoiling on these promoters depends on their intrinsic properties. As the global superhelical density of the chromosome is controlled by the energy charge of the cell, which is affected by environmental stresses and transitions from one growth state to another, the transcriptional coupling that occurs between divergently transcribed promoters is likely to serve a physiological purpose. Here, we suggest that transcriptional coupling between the divergent promoters of the ilvYC operon of Escherichia coli serves to co-ordinate the expression of this operon with other operons of the ilv regulon during metabolic adjustments associated with growth state transitions. As DNA supercoiling-dependent transcriptional coupling between the promoters of other divergently transcribed operons is investigated, additional global gene regulatory mechanisms and physiological roles are sure to emerge.

A Tn10 derivative (T-POP) for isolation of insertions with conditional (tetracycline-dependent) phenotypes

A new Tn10-based transposon has been constructed and used to isolate insertion mutations with tetracycline-conditional phenotypes. Classes of mutants include conditional lethal mutations, conditional auxotrophs, and conditional mutants of the eut (ethanolamine utilization) operon. The described mutations were made with a new derivative of Tn10dTet that we have called Tn10d(T-POP). Others have noted that transposon Tn10dTet directs weak tetracycline-inducible transcripts out of both ends of the element into adjacent sequences. We have increased this level of outward transcription from Tn10dTet by selecting deletion mutations within the element that presumably remove transcription-termination signals. Insertion of the Tn10d(T-POP) element within an operon disrupts the target gene and makes expression of distal genes dependent on induction of outward transcription by tetracycline. Insertion mutations made with Tn10d(T-POP) can cause tetracycline-correctable conditional phenotypes based on expression of distal genes.

Epistatic effects of promoter and repressor functions of the Tn10 tetracycline-resistance operon of 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.

Sequence of a class E tetracycline resistance gene from Escherichia coli and comparison of related tetracycline efflux proteins

We determined the nucleotide sequence of the class E tetA gene on plasmid pSL1456 from Escherichia coli SLH1456A. The deduced amino acid sequence of the class E TetA protein shows 50 to 56% identity with the sequences of five related TetA proteins (classes A through D and G). Hydrophobicity profiles identify 12 putative transmembrane segments with similar boundaries in all six TetA sequences. The N-terminal alpha domain of the six sequences is more highly conserved than the C-terminal beta domain; the central hydrophilic loop connecting the alpha and beta domains is the least conserved region. Amino acid residues that have been shown to be important for class B (Tn10) TetA function are conserved in all six TetA sequences. Unlike the class B tetA gene, the class D and E tetA genes do not exhibit a negative gene dosage effect when present on multicopy plasmids derived from pACYC177.

The Tn10-encoded tetR mRNA has heterogeneous 5' ends in vivo and in vitro

The 5' ends of the Tn10-encoded mRNAs have been analyzed by quantitative primer extensions of the in vivo synthesized RNA and in vitro run-off transcription. The gene is transcribed by a tandem promoter system consisting of PR1 and PR2. While PR1 contributes about 25% of the total PR activity in vitro, more than 95% of the in vivo-produced transcripts originate from PR2. Transcription from PR2 shows extensive heterogeneity at the 5' ends of the mRNAs in vitro and most likely also in vivo. A deletional and oligodeoxyribonucleotide-directed mutational analysis of the PR2 transcript reveals that length heterogeneity results from reiterative copying of a run of five A's at the transcription start point. In vivo transcription leads to longer reiteration products than in vitro transcription.

Hierarchies of base pair preferences in the P22 ant promoter

Oligonucleotide-directed mutagenesis was used to complete a collection of mutations in the -35 and -10 hexamers of the ant promoter of Salmonella phage P22. The effects of all 36 single-base-pair substitutions on promoter strength in vivo were measured in strains carrying the mutant promoters fused to an ant-lacZ gene on a single-copy prophage. The results of these assays show that certain consensus base pairs are more important than others; in general, the least-critical positions are among the most poorly conserved. Some mutations within the hexamers have smaller effects on promoter strength than certain mutations outside the hexamers in this and other promoters. Several different patterns of base pair preferences are observed. These hierarchies of base pair preferences correlate well (but not perfectly) with the hierarchies defined by the frequency distribution of base pairs at each position among wild-type promoters. The hierarchies observed in the ant promoter also agree well with most of the available information on base pair preferences in other promoters.

Quantitative analysis of Tn10 Tet repressor binding to a complete set of tet operator mutants

A saturating oligonucleotide-directed mutagenesis of both tet operators in the tet regulatory sequence was performed yielding mutants with four identical base pair exchanges at equivalent positions in the four tet operator half sides. The mutants were cloned between bipolar lacZ and galK indicator genes on a multicopy plasmid allowing the quantitative analysis of their effects in vivo. In the absence of Tet repressor the mutations lead to considerably different expression levels of both genes. They are discussed with respect to the promoter consensus sequences. In particular, the -10 region of the in vivo active tetPR2 promoter is unambiguously defined by these results. In the presence of Tet repressor most of the mutants exhibit a lower affinity for that protein as determined quantitatively by their reduced expression levels. In general, tet operator recognition is most strongly affected by alterations of base pairs near the center of the palindromic sequence. The most important position is the third base pair, followed by base pairs two, four, five and six, the latter showing similar effects as base pair one. At each position, the four possible base pairs show different affinities for Tet repressor. They are discussed according to their exposure of H-bond donors and -acceptors in the major and minor grooves of the B-DNA. The results are in agreement with major groove contacts at positions two, three and five. At position four a low potential correlation of efficiencies with the H-bonding in the minor groove is found, while mutations at position six seem to influence repressor binding by other mechanisms.

Identification and analysis of transcriptional regulatory signals for the kil and kor loci of Streptomyces plasmid pIJ101

Four regulated promoters that direct the transcription of genes (i.e., korA, tra, kilB, and korB) involved in the transfer of the Streptomyces plasmid pIJ101 were isolated following the in vitro fusion of plasmid DNA fragments to a promoterless gene encoding the S. lividans extracellular enzyme beta-galactosidase. Introduction of pIJ101 into cells carrying each of these promoter-lac fusions resulted in decreased lac expression. The sites of initiation of transcription by the promoter sequences were identified by primer extension experiments, and the DNA sequences specifically required for promoter activity and regulation by pIJ101-encoded functions were determined by deletion analysis. The data obtained indicate that the korB locus encodes a repressor that regulates its own transcription, as well as transcription of the kilB promoter; korA and tra are transcribed from overlapping divergent promoters that are coregulated by the korA gene product. Common DNA sequence domains within coregulated promoters allowed the identification of putative binding sites for each of the kor gene products.

Mutations in the Tn10 tet repressor that interfere with induction. Location of the tetracycline-binding domain

Tetracycline induces transcription of the Tn10 tetracycline resistance gene (tetA) by binding to the tet repressor, thereby reducing the repressor's affinity for two operator sites that overlap the tet promoters. We characterized mutations in the tet repressor (tetRs mutations) that interfere with induction of tetA expression. The mutations were isolated on multicopy Tn10 tet plasmids by selecting for resistance to the inducer 5a,6-anhydrotetracycline. Under these conditions, maximal induction of tetA expression inhibits the growth of Escherichia coli K-12. DNA sequence analysis of 25 spontaneous tetRs mutations identified amino acid changes at 13 different positions clustered near the middle of the 207 amino acid residue sequence of tet repressor. This region (residues 64 to 107) is distinct from the bihelical DNA-binding motif of tet repressor (residues 26 to 47). The capacity of tetRs repressors to bind tet operator DNA and to respond to inducer was examined in vivo in tetA-lacZ fusion strains. In three cases, the capacity of tetRs repressors to bind tetracycline was examined in vitro using cell extracts enriched in repressor. Mutations 64Y (His64----Tyr) and 82H (Asn82----His) reduce the repressor's affinity for tetracycline more than 1000-fold and more than 100-fold, respectively, suggesting that His64 and Asn82 may be part of the inducer-binding site or directly involved in maintaining its conformation. Mutation 103I (Thr103----Ile) reduces the repressor's affinity for tetracycline less than tenfold, yet it interferes with induction to a greater extent than either 64Y or 82H, suggesting that 103I may also reduce the repressor's capacity to undergo a conformational change required for induction. The properties of tetRs mutants suggest that the region of amino acid residues 64 to 107 is involved in inducer binding and in signalling between the inducer-binding and operator-binding domains of the repressor.

Bacillus subtilis rRNA promoters are growth rate regulated in Escherichia coli

rRNA promoters from the rrnB locus of Bacillus subtilis and from the rrnB locus of Escherichia coli were fused to the gene for chloramphenicol acetyltransferase (CAT). The level of expression of CAT in E. coli showed growth rate dependence when the CAT gene was linked to either E. coli or B. subtilis tandem promoters. The downstream promoter of the tandem Bacillus pair showed growth rate regulation, while the upstream promoter did not, whereas for the E. coli tandem promoters, only the upstream promoter was growth rate regulated.

Metalloregulatory DNA-binding protein encoded by the merR gene: isolation and characterization

The MerR protein mediates the induction of the mercury resistance phenotype in bacteria; it has been isolated in order to study the effects of metal-ion induced changes in the metabolism of prokaryotic cells at the molecular level. After DNA sequences responsible for negative autoregulation were removed, the 16-kilodalton protein was overproduced and purified to more than 90 percent homogeneity by a salt extraction procedure that yields about 5 milligrams of protein per gram of cells. Complementation data, amino terminal analysis, gel filtration, and deoxyribonuclease I protection studies demonstrate that the purified merR gene product is a dimer under nondenaturing conditions and that it binds specifically to DNA, in the presence and absence of mercury, at a palindromic site which is directly between the -10 and -35 regions of the structural genes and adjacent to its own promoter. These initial results indicate that MerR is a DNA-binding metalloregulatory protein that plays a central role in this heavy metal responsive system and they delineate an operator site in the mer operon.

Dominant negative mutations in the Tn10 tet repressor: evidence for use of the conserved helix-turn-helix motif in DNA binding

The Tn10 tet repressor regulates transcription of the tetracycline-resistance determinant in transposon Tn10. Previous DNA sequencing studies identified a region of tet repressor (amino acids 26-47) that is homologous to the helix-turn-helix regions of lambda Cro, lambda repressor, and catabolite gene activator protein that are implicated in sequence-specific DNA binding. Here we report the isolation of dominant tetR mutations that result in tet repressors deficient in tet operator binding but that retain some capacity to form dimers with, and thereby inactivate, wild-type repressor monomers. The mutations were isolated by transforming a tetR+ tetA-lacZ fusion strain with hydroxylamine-mutagenized tetR plasmid DNA and then screening for increased lacZ expression. DNA sequence analysis of 35 independent isolates identified seven different mutations, five of which are in the region of helix-turn-helix sequence homology. In vitro binding studies indicate that the mutations in this region of tet repressor reduce the affinity of tet repressor for tet operator DNA by at least a factor of 1000 but have no significant effect on the affinity of tet repressor for tetracycline. These results provide strong support for the proposal that tet repressor utilizes the conserved helix-turn-helix structural motif in binding to tet operator DNA.