Promoter mutations affecting divergent transcription in the Tn10 tetracycline resistance determinant

The tetracycline resistance determinant in transposon Tn10 consists of two genes, the tetA resistance gene and the tetR repressor gene, that are transcribed from divergent overlapping promoters. We determined the levels of pulse-labeled tet messenger RNA in Escherichia coli strains with the Tn10 tet genes on a multicopy plasmid. Addition of the inducer 5a,6-anhydrotetracycline results in a 270- to 430-fold increase in tetA mRNA and a 35- to 65-fold increase in tetR mRNA. As judged by the relative molar amounts of tetA and tetR mRNA synthesized under maximally inducing conditions, the tetA promoter (tetPA) is 7 to 11 times more active than the two tetR promoters (tetPR1 and tetPR2) combined. We characterized ten mutations in tetPA, including nine single-base-pair substitutions and a 30-base-pair deletion. All of the single-base-pair changes reduce the agreement with the consensus sequence for promoters recognized by E. coli RNA polymerase. Mutations in highly conserved nucleotides result in a 200- to 600-fold reduction in tetPA activity in vivo. Unexpectedly, tetPA mutations reduce by two- to fourfold the combined activity in vivo of tetPR1 and tetPR2, in spite of their locations outside the -35 and -10 regions of tetPR1 and tetPR2. For two tetPA mutations, the negative effect on tetPR activity was also demonstrated in tetR- tetPR-lacZ operon fusion strains, thus eliminating the possibility that it is due to variations in either plasmid copy-number or induction efficiency. The pleiotropic effects of tetPA mutations are discussed in terms of the expectation that the overlapping tet promoters compete for RNA polymerase.     

Mutations in multicopy Tn10 tet plasmids that confer resistance to inhibitory effects of inducers of tet gene expression.

Escherichia coli K-12 strains that carry the Tn10 tetracycline resistance determinant (tet) on multicopy plasmids are hypersensitive to 5a,6-anhydrotetracycline and heated chlortetracycline, two tetracycline derivatives that are relatively more effective as inducers of tet gene expression than as inhibitors of bacterial growth. Twenty spontaneous mutations that confer resistance to anhydrotetracycline (Atr) and resistance to heated chlortetracycline (Ctr) were isolated and characterized. All of these Atr mutations are located in the Tn10 tet region; the majority (18 of 20) have no effect on tetR repressor function. Atr mutations can increase, reduce, or eliminate the phenotypic expression of plasmid tetracycline resistance (Tcr). IS insertions that result in an Atr Tcs phenotype are clustered in a 150-base-pair promoter-proximal region of the tetA resistance gene. Some Atr mutations reduce expression of the tetA gene by altering either the tetR repressor or the tetA promoter. In addition, it appears that E. coli cannot tolerate constitutive expression of the wild-type tetA gene from a multicopy plasmid containing a tetR deletion. These observations support the proposal that high level expression of the 36-kilodalton tetA gene product inhibits the growth of E. coli. We speculate that this inhibition is related to the interaction of the tetA gene product with the cytoplasmic membrane.     

Plasmid vectors based on Tn10 DNA: gene expression regulated by tetracycline

The regulatory region of the tetracycline resistance determinant from transposon Tn10 has been used to construct plasmid vectors for gene expression regulated by tetracycline. Plasmids pRS tetBam-8 and pRS tetBam-16 include the tet regulatory region, the segment coding for the first four amino acids of the tetracycline resistance protein (tetA protein), and a linker region with SalI, HpaII, and BamHI restriction sites for gene fusions. Plasmid pTB-1, a derivative of pRS tetBam-8 and of the beta-galactosidase gene-containing plasmid pMC1403, constitutively expresses a tetA fragment-beta-galactosidase fusion protein. If a multicopy runaway replication plasmid, pMOBglII-16 that includes a 2.7-kb BglII DNA fragment from Tnl10 that provides tetR protein is present along with pTB-1, the expression of beta-galactosidase is reduced eightfold. Tetracycline acts as an inducer of the system and restores the level of beta-galactosidase activity measured in transformants containing pTB-1 alone. Plasmid mutants unable to produce active tetR protein are ineffective in reducing expression. Escherichia coli carrying plasmids that express both tetA protein and tetR protein show an increase in the tetracycline resistance level after incubation with the drug. The observations are consistent with the previously proposed mechanism of regulation of tetracycline resistance in Tn10.     

Multicopy Tn10 tet plasmids confer sensitivity to induction of tet gene expression.

We inserted the Tn10 tetracycline resistance determinant (tet) into the multicopy plasmid pACYC177, and we examined the phenotype of Escherichia coli K-12 strains harboring these plasmids. In agreement with others, we find that Tn10 tet exhibits a negative gene dosage effect. Strains carrying multicopy Tn10 tet plasmids are 4- to 12-fold less resistant to tetracycline than are strains with a single copy of Tn10 in the bacterial chromosome. In addition, we find that multicopy tet strains are 30- to 100-fold less resistant to the tetracycline derivative 5a,6-anhydrotetracycline than are single-copy tet strains. Multicopy tet strains are, in fact, 10- to 25-fold more sensitive to anhydrotetracycline than are strains that lack tet altogether. The hypersensitivity of multi-copy strains to anhydrotetracycline is correlated with the effectiveness of anhydrotetracycline as an inducer of tet gene expression, rather than its effectiveness as an inhibitor of protein synthesis. Anhydrotetracycline is 50- to 100-fold more effective than tetracycline as an inducer of tetracycline resistance and as an inducer of beta-galactosidase in strains that harbor tet-lac gene fusions. In contrast, anhydrotetracycline appears to be two- to fourfold less effective than tetracycline as an inhibitor of protein synthesis. Both anhydrotetracycline and tetracycline induce synthesis of tet polypeptides in minicells harboring multicopy tet plasmids. Differences between E. coli K-12 backgrounds influence the tetracycline and anhydrotetracycline sensitivity of multicopy strains; ZnCl2 enhances the tetracycline and anhydrotetracycline sensitivity of these strains two- to threefold. We propose that the overexpression of one or more Tn10 tet gene products inhibits the growth of multicopy tet strains and accounts for their relative sensitivity to inducers of tet gene expression.     

Nucleotide sequence of the gene, protein purification and characterization of the pSC101-encoded tetracycline resistance-gene-repressor

The nucleotide sequence of the pSC101-encoded tetracycline repressor gene (tetR) was confirmed. The deduced amino acid sequence is compared to that of other repressor proteins. To overproduce the repressor protein, tetR was placed under the control of bacteriophage lambda promoter pL. Tet repressor protein was purified to homogeneity and shown to bind specifically to two tet operators and also to tetracycline (Tc). The inducer function of Tc is demonstrated by the loss of the specific binding between the tet operator DNA and the Tet repressor-Tc complex.     

Tetracycline-dependent conditional gene knockout in Bacillus subtilis

Reversible tetracycline-dependent gene regulation allows induction of expression with the tetracycline repressor (TetR) or gene silencing with the newly developed reverse mutant revTetR. We report here the implementation of both approaches with full regulatory range in gram-positive bacteria as exemplified in Bacillus subtilis. A chromosomally located gene is controlled by one or two tet operators. The precise adjustment of regulatory windows is accomplished by adjusting tetR or revtetR expression via different promoters. The most efficient induction was 300-fold in the presence of 0.4 microM anhydrotetracycline obtained with a Pr-xylA-tetR fusion. Reversible 500-fold gene knockouts were obtained in B. subtilis after adjusting expression of revTetR by synthetically designed promoters. We anticipate that these tools will also be useful in many other gram-positive bacteria.     

A quantitative real-time PCR assay for the detection of tetR of Tn10 in Escherichia coli using SYBR Green and the Opticon

Bacteria of implant infections are extremely resistant to antibiotics. One reason for this antibiotic resistance are transposons; the well-known transposon Tn10, for example, mediates tetracycline resistance to Escherichia coli. Two genes of Tn10, tetA and tetR, are essential for the mechanism of resistance. These genes encode a drug-specific efflux protein and a tetracycline repressor protein, respectively. Tn10 is also widely used in molecular biology. For example, tTA, a recombinant derivate of tetR, has been utilised for a highly efficient gene regulation system in mammalian cells. We have examined E. coli isolates from implant infections for tetracycline resistance and for the presence of tetR. A real-time PCR assay was developed for detection of tetR with SybrGreen using the Opticon PCR machine of MJ Research. This method offers a quick, sensitive, efficient, and reliable approach to the detection and quantification of genes. Clinical isolates of E. coli were examined successfully for tetracycline resistance and for the presence of tetR. The real-time PCR is effective using a variety of templates including isolated E. coli DNA, pure colonies, or liquid culture sources. Using quantified standard DNA, this assay can accurately detect as few as 15 copies. Moreover, this assay has the ability to quantify the number of tetR genes in the presence of contaminating mammalian DNA. In conclusion, the tetR real-time PCR offers new methods for detection and quantification of tetracycline-resistant bacteria and tTA in transfected cell-lines or transgenic animals.     

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.     

Similarities between the regulatory sequences of the unrelated tetracycline genes of pBR322 and Tn10

The regulatory regions of the tetracycline genes present in pBR322 (pSC101) and in the transposon Tn10 are compared. They show a low degree of nucleotide sequence similarity but a high level of structure similarity. Furthermore, analyses of RNAs transcribed in the opposite direction of the pBR322 tet gene show that there are two mRNA initiation sites separated by 29 nucleotides. This suggests the existence of two promoters for the tet repressor gene in Tn10. These features reveal a strong resemblance of the mode of regulation between the tet operons of Tn10 and pSC101.     

Novel tetracycline resistance determinant isolated from an environmental strain of Serratia marcescens

Resistances to tetracycline and mercury were identified in an environmental strain of Serratia marcescens isolated from a stream highly contaminated with heavy metals. As a step toward addressing the mechanisms of coselection of heavy metal and antibiotic resistances, the tetracycline resistance determinant was cloned in Escherichia coli. Within the cloned 13-kb segment, the tetracycline resistance locus was localized by deletion analysis and transposon mutagenesis. DNA sequence analysis of an 8.0-kb region revealed a novel gene [tetA(41)] that was predicted to encode a tetracycline efflux pump. Phylogenetic analysis showed that the TetA(41) protein was most closely related to the Tet(39) efflux protein of Acinetobacter spp. yet had less than 80% amino acid identity with known tetracycline efflux pumps. Adjacent to the tetA(41) gene was a divergently transcribed gene [tetR(41)] predicted to encode a tetracycline-responsive repressor protein. The tetA(41)-tetR(41) intergenic region contained putative operators for TetR(41) binding. The tetA(41) and tetR(41) promoters were analyzed using lacZ fusions, which showed that the expression of both the tetA(41) and tetR(41) genes exhibited TetR(41)-dependent regulation by subinhibitory concentrations of tetracycline. The apparent lack of plasmids in this S. marcescens strain, as well as the presence of metabolic genes adjacent to the tetracycline resistance locus, suggested that the genes were located on the S. marcescens chromosome and may have been acquired by transduction. The cloned Tet 41 determinant did not confer mercury resistance to E. coli, confirming that Tet 41 is a tetracycline-specific efflux pump rather than a multidrug transporter.     

Complete nucleotide sequence of Tn1721: gene organization and a novel gene product with features of a chemotaxis protein.

The complete 11,139-nucleotide sequence of transposon Tn1721 has been determined. It contains three 38-bp inverted repeats, and (in this order) a new orfI, a resolution site (res), genes encoding resolvase (tnpR), transposase (tnpA), tetracycline-resistance (TcR) repressor (tetR), TcR (tetA) and a truncated transposase gene (tnpA'). The modulator origin of Tn1721 from at least three separate sources is supported by the distinctive codon usages of orfI, tnpR/tnpA and tetR/tetA, and by sequence similarities with Tn501 (tnpR/tnpA) and RP1 (tetR/tetA). The ORFI-encoded 56-kDa polypeptide exhibits features of a methyl-accepting chemotaxis protein (MCP) with a conserved signal domain and a potential transmembrane domain; this polypeptide cross-reacts with anti-MCP antiserum. Like chemotaxis genes, orfI is transcribed from a sigma 28-like promoter. The overexpressed orfI gene product interferes with MCP-dependent chemotaxis suggesting that it completes for soluble transducer protein(s) in the cell. The potential selective advantage of this novel transposon-borne gene is discussed.     

Overproduction and purification of the Tn10-specified inner membrane tetracycline resistance protein Tet using fusions to β-galactosidase

Tetracycline resistance in the Enterobacteriaceae is mediated by a number of genetically related, usually plasmid-borne, determinants which specify an efflux system involving an inner membrane protein, Tet. Attempts to overproduce the Tn10 (Class B)-encoded Tet in Escherichia coli by cloning the structural gene tet downstream of the lambda PL promoter under regulation by temperature-sensitive lambda repressor cI857 were unsuccessful; induction at 42 degrees C resulted in filamentous, non-viable cells containing little detectable overproduction of the protein. However, cells containing tet fused to lacZ were resistant to tetracycline at 30 degrees C and synthesized modest amounts of a large fusion protein when induced at 42 degrees C. Fusion of the N-terminal half or the first 38 amino acids of tet to lacZ did lead to increased production of fusion proteins. Fusions could be purified by size or by LacZ immunoaffinity or substrate-affinity chromatography. In the latter method, selected detergents were required to counteract nonspecific binding of Tet to the adsorbant. Amino acid sequencing of the N-terminus of Tet-LacZ fusion proteins indicated that most molecules were blocked at this terminus. The sequence of an unblocked subpopulation was consistent with that expected from the nucleotide sequence. A collagen peptide linker, genetically placed between tet and lacZ, allowed recovery of purified Tet protein after collagenase treatment of the purified fusion protein.