Transposon Tn10-like tetracycline resistance determinants in Haemophilus parainfluenzae.

Tetracycline resistance (Tcr) determinants from three different strains of Haemophilus parainfluenzae expressed 10-fold higher levels of resistance when mated into Escherichia coli. No plasmid was found in any of the E. coli recipients, even in matings in which a plasmid was identified in the donor Haemophilus sp. The Tcr determinant from Haemophilus sp. caused instability of resident plasmids in the recipient E. coli: all plasmids were lost within 30 generations in antibiotic-free media. However, by serial subculture in antibiotics, stable resident plasmids were obtained which carried the Tcr determinant from Haemophilus sp. and were transferable by conjugation and transformation among E. coli strains. All Haemophilus determinants hybridized with a probe for the Tcr determinant on Tn10, which bears inducible Tcr. However, Haemophilus determinants were constitutively resistant to tetracycline in the Haemophilus donors and in the E. coli recipients. This constitutive expression was recessive to wild-type Tn10 in the same cell, indicating that the constitutive phenotype resulted from the absence of an active repressor. Restrictive enzyme analysis of various E. coli plasmid derivatives bearing a Tcr determinant from Haemophilus sp. demonstrated that the inserted DNA was of similar size (8.95 to 9.35 kilobases), close to that of Tn10. Heteroduplex analysis and DNA:DNA hybridization confirmed that the Tcr determinant from Haemophilus sp. had greater than 90% homology with the Tn10 determinant, including the DNA sequence for the repressor.     

Identification of repressor binding sites controlling expression of tetracycline resistance encoded by Tn10

The regulatory region controlling the expression of tetracycline resistance and repressor genes contains two nearly identical regions of dyad symmetry. Deletions of this control region were isolated by digestion with S1 nuclease. The ability of these deletions to bind the tet repressor was determined by an in vivo repressor titration assay. The results indicate that repressor specifically binds both regions of dyad symmetry.     

Identification of the tetracycline resistance promoter and repressor in transposon Tn10.

The structural and regulatory functions encoding tetracycline resistance in transposon Tn10 lie within a 2,700-base pair region. Using recombinant plasmids with different deoxyribonucleic acid sequences adjacent to a HincII site in this region, we located the promoter controlling the expression of tetracycline resistance. These various sequences conferred altered levels of tetracycline resistance. Plasmids containing deletions of a 695-base pair HincII fragment were constitutive and showed the loss of a 23,000-dalton tetracycline-inducible polypeptide, thus identifying the repressor and the location of its gene.     

Characterization of Tn916S, a Tn916-like element containing the tetracycline resistance determinant tet(S)

We have characterized a transferable tetracycline resistance (Tcr) element from a Streptococcus intermedius isolate. The gene responsible for this resistance was identified by PCR and Southern hybridization as tet(S). Furthermore, the genetic support for this determinant was shown to be a conjugative transposon closely related to Tn916. This element has been designated Tn916S.     

Inversions and deletions of the Salmonella chromosome generated by the translocatable tetracycline resistance element Tn10

Spontaneous tetraoyoline-sensitive derivatives of a Tn10 insertion in the hisG gene of Salmonella typhimurium were isolated and subjected to genetic analysis. All 123 of the drug-sensitive derivatives characterized have undergone stable alterations in the Tn10 element itself; over half of the derivatives have also undergone major alterations of neighboring regions of the Salmonella chromosome. These chromosomal rearrangements are of two types: inversions and deletions. Any single inversion or deletion affects a contiguous stretch of chromosomal material extending from the site of the original Tn10 element either leftward or rightward.The genetic properties of deletion and inversion derivatives suggest that these chromosomal alterations are promoted by the Tn10 element itself. The role of translocatable elements in promoting chromosomal deletions is well documented; the ability of an element to promote inversions of chromosomal material has not previously been reported. Possible analogies between the 1400-base-pair inverted repetition at the end of Tn10 and the small insertion sequence IS1 predict particular structures for Tn10-promoted deletions. A structural explanation or model for Tn10-promoted inversions is presented. The observation that Tn10 promotes the formation of inversions suggests that such elements could play a previously unanticipated role in promoting chromosomal inversions during evolution of prokaryotic organisms. Generally applicable genetic methods for the identification and characterization of chromosomal inversions are described.     

Two complementation groups mediate tetracycline resistance determined by Tn10.

The structural and regulatory tetracycline resistance genes of transposon Tn10 are located on a 2,700-base pair HpaI fragment. We have used eight tetracycline-sensitive mutations in the 2,700-base pair fragment, cloned into two compatible plasmids, to demonstrate that two complementation groups are required for tetracycline resistance. By genetic recombination with plasmids containing the regulatory or structural regions for resistance, we have determined that both complementation groups reside within the structural region. The complementation groups, designated tetA and tetB, are proximal and distal, respectively, to the promoter for the tetracycline resistance structural region. The tetB mutations are in the portion of the structural region that is known to encode the 36,000-molecular-weight, inner-membrane TET protein. The levels of tetracycline resistance expressed during complementation suggest a complex interaction between the products of the tetA and tetB loci.     

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.     

Stoichiometry of metal-tetracycline/H+ antiport mediated by transposon Tn10-encoded tetracycline resistance protein in Escherichia coli.

The tetracycline resistance protein (TetA) endoded by transposon Tn10 mediates the efflux of divalent cation-tetracycline chelating complexes [Yamaguchi, A., Udagawa, T. and Sawai, T. (1990) J. Biol. Chem. 265, 4809-4813]. It was confirmed that protons were antiported with the complexes through an electrically-neutral process because the antiport consumed delta pH but not delta psi. The quantitative relationship between delta pH and delta pTC determined by a flow-dialysis method clearly indicated a 1:1 stoichiometry of the monocationic metal-tetracycline/H+ exchange.     

Intracistronic complementation of the tetracycline resistance membrane protein of Tn10.

The structural gene region for tetracycline resistance on Tn10 consists of two complementation groups, tetA and tetB (M. S. Curiale and S. B. Levy, J. Bacteriol. 151:209-215, 1982). Using a series of deletion mutants, we have determined that the tetA region is 450 to 600 base pairs long and that the tetB region, which is adjacent to tetA, is 600 to 750 base pairs long. Point mutations in either tetA or tetB affected the amount and size of the inducible inner-membrane Tet protein synthesized in Escherichia coli maxicells. Moreover, deletions in these regions led to the synthesis of an appropriately smaller Tet protein. A single tetracycline-inducible RNA of about 1,200 bases was detected that was homologous with the tetracycline resistance structural gene region. These results indicate that the tetA and tetB complementation regions represent two parts of a single gene encoding two domains of the tetracycline resistance protein Tet.     

Analysis of the reduction in expression of tetracycline resistance determined by transposon Tn10 in the multicopy state

The tet genes of transposon Tn10 have been mapped in a 2,200 bp DNA sequence by analysing deletion and Tn5 insertion mutations. When the tet genes were present on multi-copy plasmids the level of resistance expressed was about ten-fold lower than that determined by a single copy of Tn10 in the E. coli chromosome. The 36K tet protein known to be encoded by R100 in E. coli minicells was not detected when they harboured a multicopy tet plasmid. However, normal high levels of resistance were expressed when the tet genes were recombined into the host chromosome as part of a lambda lysogen, showing that the multicopy effect was phenotypic. Most of the Tn5 insertions and deletions in tet which caused Tc^s mutations also prevented expression of high level Tc^r from a chromosomal Tn10 element present in the same cell. Only those insertions in the promoter-proximal 90–130 bp of a 1,275 bp HindII fragment known to carry the gene encoding the 36K tet protein did not reduce the single copy Tn10 resistance level.A gene fusion system that results in the constitutive synthesis of -galactosidase from a tet promoter has been used to assay tet repressor activity. The basal (uninduced) -galactosidase level in cells carrying multicopy tet plasmids was 10–20 fold lower than those carrying a single copy. The tet:: Tn5 mutants defective in the trans-dominant multicopy effect still made normal amounts of tet repressor showing that repressor overproduction was not responsible for this effect. In addition a repressor-defective constitutive mutant did not exhibit a higher resistance level when located on a multicopy plasmid vector. We postulate that a regulatory mechanism recognises the amino-terminus of the tet structural gene product when attempts are being made to overproduce the protein and prevents further translation.     

Location of ribosome-binding sites on the tetracycline resistance transposon Tn10.

Eight ribosome-binding sites were located on the single-stranded Tn10 DNA loop which was formed after denaturation of lambda phage DNA containing the Tn10 transposon sequence. Ribosomes were bound only to the Tn10 loop contained on the R strand of lambda DNA but not to that on the L strand, suggesting that one of the two strands of Tn10 DNA is selectively transcribed. Six of the eight ribosome binding sites were located in one-half of the DNA loop. The maximum sizes of potential polypeptides were calculated for these genes to range between 9,500 and 84,000 daltons.     

Tetracycline resistance transposon Tn1721: recA-dependent gene amplification and expression of tetracycline resistance

The 7.1-megadalton transposon Tn1721 codes for inducible tetracycline resistance (Tcr). The transposable element consists of a "minor transposon" (3.6 megadaltons) encoding functions required for transposition and a "tet region" (3.5 megadaltons) encoding resistance. Multiple tandem repeats of the tet region can be generated by recA-dependent gene amplification. This feature of Tn1721 has been used to analyze the relationship between gene dosage and Tcr. Derivatives of plasmid R388:Tn1721 containing from one to nine copies of the tet region were isolated and separately transformed into recA host cells, where they are stably maintained. The results of the study of Tcr in these strains were as follows: (i) the uninduced, "basal" level of Tcr was linearly related to gene dosage between 4 and 36 copies of tet per chromosome equivalent; (ii) the underlying mechanism could not be attributed to reduced accumulation of the drug; and (iii) induction with tetracycline elicited a four- to fivefold reduction in drug accumulation, independent of the gene dosage.     

Overproduction of transposon Tn10-encoded tetracycline resistance protein results in cell death and loss of membrane potential.

High-level expression of the Tn10 tetracycline resistance protein TetA in Escherichia coli caused partial collapse of the membrane potential, arrest of growth, and killing of the cells. Since alpha-methylglucoside transport was not affected, the overproduced TetA protein may cause not destruction of membrane structure but rather unrestricted translocation of protons and/or ions across the membrane.     

The identification of a tetracycline resistance gene tet(M), on a Tn916-like transposon,in the Bacillus cereus group

In order to investigate whether resistance genes present in bacteria in manure could transfer to indigenous soil bacteria, resistant isolates belonging to the Bacillus cereus group (Bacillus cereus, Bacillus anthracis and Bacillus thuringiensis) were isolated from farm soil (72 isolates) and manure (12 isolates) samples. These isolates were screened for tetracycline resistance genes (tet(K), tet(L), tet(M), tet(O), tet(S) and tet(T)). Of 88 isolates examined, three (3.4%) isolates carried both tet(M) and tet(L) genes, while four (4.5%) isolates carried the tet(L) gene. Eighty-one (92.1%) isolates did not contain any of the tested genes. All tet(M) positive isolates carried transposon Tn916 and could transfer this mobile DNA element to other Gram-positive bacteria.     

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.     

Restriction enzyme cleavage map of Tn10, a transposon which encodes tetracycline resistance.

A cleavage map of a recombinant plasmid carrying Tn10 was constructed for 13 different restriction enzymes. The Tn10 region of this plasmid contains cleavage sites for BamHI, AvaI, BglI, BglII, EcoRI, XbaI, HincII, HindIII, and HpaI. Restriction enzymes PstI, SmaI, KpnI, XhoI, SalI, and PvuI do not cleave within the Tn10 element. This map confirms the previously reported structure of this transposon; it is composed of a unique sequence (approximately6,400 base pairs long), which in part codes for the tetracycline resistance functions and is bounded by inverted repeats (approximately 1,450 base pairs long).