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.     

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.     

Tn4400, a compound transposon isolated from Bacteroides fragilis, functions in Escherichia coli.

Transfer factor pBFTM10, isolated from the obligate anaerobic bacterium Bacteroides fragilis, carries a clindamycin resistance determinant which we have suggested is part of a transposable element. DNA homologous to this determinant is found in many Clnr Bacteroides isolates, either in the chromosome or on plasmids. We have now established that Ccr resides on a transposon, Tn4400. In addition to the Ccr determinant that functions under anaerobic conditions in B. fragilis, Tn4400 also carries a determinant for tetracycline resistance (Tcr) which only functions in Escherichia coli under aerobic conditions. The presence of Tn4400 on pBFTM10 does not confer tetracycline resistance on B. fragilis cells containing it. DNA from pBFTM10 was cloned in E. coli, with pDG5 as the cloning vector, to form pGAT500. Using a mobilization assay involving pGAT500 and an F factor derivative, pOX38, we determined that a 5.6-kilobase region of pBFTM10 DNA was capable of mediating replicon fusion and transposition. Most of the mobilization products resulted from inverse transposition reactions, while some were the result of true cointegrate formation. Analysis of the cointegrate molecules showed that three were formed by the action of one of the ends of Tn4400 (IS4400), and one was formed by the action of the whole element (Tn4400). The cointegrate molecule carrying intact copies of Tn4400 at the junction of the two plasmids could resolve to yield an unaltered donor plasmid (pGAT500) and a conjugal plasmid containing a copy of Tn4400 or a copy of one insertion sequence element (pOX38::Tn4400 or pOX38::IS4400). Thus, Tn4400 is a compound transposon containing active insertion sequence elements as directly repeated sequences at its ends.     

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.     

TetZ, a new tetracycline resistance determinant discovered in gram-positive bacteria, shows high homology to gram-negative regulated efflux systems

The complete nucleotide sequence of the tetracycline resistance plasmid pAG1 from the gram-positive soil bacterium Corynebacterium glutamicum 22243 (formerly Corynebacterium melassecola 22243) was determined. The R-plasmid has a size of 19,751 bp and contains at least 18 complete open reading frames. The resistance determinant of pAG1 revealed homology to gram-negative tetracycline efflux and repressor systems of Tet classes A through J. The highest levels of amino acid sequence similarity were observed to the transmembrane tetracycline efflux protein TetA(A) and to the tetracycline repressor TetR(A) of transposon Tn1721 with 64 and 56% similarity, respectively. This is the first time a repressor-regulated tet gene has been found in gram-positive bacteria. A new class of tetracycline resistance and repressor proteins, termed TetA(Z) and TetR(Z), is proposed.     

Introduction of transposon Tn916 DNA into Haemophilus influenzae and Haemophilus parainfluenzae.

Enterococcus (Streptococcus) faecalis transposon Tn916 was introduced into Haemophilus influenzae Rd and Haemophilus parainfluenzae by transformation and demonstrated to transpose efficiently. Haemophilus transformants resistant to tetracycline were observed at a frequency of approximately 3 x 10(2) to 5 x 10(3)/micrograms of either pAM120 (pGL101::Tn916) or pAM180 (pAM81::Tn916) plasmid DNAs, which are incapable of autonomous replication in this host. Restriction enzyme analysis and Southern blot hybridization revealed that (i) Tn916 integrates into many different sites in the H. influenzae and H. parainfluenzae genomes; (ii) only the 16.4-kilobase-pair Tn916 DNA integrates, and no vector DNA was detected; and (iii) the Tetr phenotype was stable in the absence of selective pressure. Second-generation Tn916 transformants occurred at the high frequency of chromosomal markers and retained their original chromosomal locations. Similar results were obtained with H. influenzae Rd BC200 rec-1 as the recipient strain, which suggests host rec functions are not required in Tn916 integrative transposition. Transposition with Tn916 is an important procedure for mutagenesis of Haemophilus species.     

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.     

Reduced expression of Tn 10-mediated tetracycline resistance in Escherichia coli containing more than one copy of the transposon

In Escherichia coli a single copy of Tn10 confers high-level resistance to tetracycline. Resistance itself results from expression of three distinct mechanisms which normally act together (Shales et al., 1980). In cells containing two copies of Tn10, the level of resistance to tetracycline was reduced. This was not due to overproduction of the repressor which controls the resistance genes, because strains diploid for an operator-constitutive allele of Tn10 also exhibited reduced expression of resistance. The negative gene dosage effect resulted from decreased expression of two mechanisms (1 and 2) consequent on enhanced expression of the third mechanism. The net result of increasing the copy number was a decrease in resistance because mechanism 3 was less efficient than mechanisms 1 and 2 in protecting the cell against tetracycline. The DNA sequence responsible for the reduced expression of resistance was contained in the internal BglII fragment of Tn10. This sequence, which is probably unique to Tn10, may encode the protein which mediates mechanism 3. Elevated levels of this protein probably cause decreased expression of mechanisms 1 and 2.     

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.     

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.     

Relationships among some R plasmids found in Haemophilus influenzae.

Tetracycline resistance in a strain of Haemophilus influenzae isolated in the United Kingdom was found to be determined by an apparently non-selftransmissible plasmid of 31 X 10(6) daltons (31 MDal), designated pUB701. Deoxyribonucleic acid hybridization studies indicated that pUB701 shares about 70% base sequence homology with the 30-MDal ampicillin resistance R plasmid RSF007 isolated in the United States from H. influenzae, and 64% sequence homology with the 38-MDal tetracycline and chloramphenicol resistance R plasmid pRI234, isolated in the Netherlands. Heteroduplex studies between RSF007 and pUB701 confirmed the fact that these plasmids were largely homologous, except that pUB701 contained the tetracycline resistance transposon TnD, whereas RSF007 contained the ampicillin resistance transposon TnA. A strain of H. parainfluenzae resistant to both chloramphenicol and tetracycline carried two species of plasmid deoxyribonucleic acid of 2.7 and 0.75 MDal. We were unable to prove that either resistance was plasmid-borne in this strain. Hybridization studies with a [3H]thymine-labeled tetracycline resistance enteric plasmid suggested that the tetracycline transposon was integrated into the chromosome of H. parainfluenzae UB2832. We conclude either that the strains we studied received R factors of the same incompatibility group bearing different resistance genes, or that different resistance genes were translocated to a commom resident plasmid of H. influenzae.     

Tn5 carries a streptomycin resistance determinant downstream from the kanamycin resistance gene

In Rhizobium meliloti, Tn5 conferred resistance not only to kanamycin but to streptomycin, as well, in Escherichia coli, however only to kanamycin. Using in vitro recombinant DNA techniques, it was shown that the streptomycin resistance determinant was located downstream from the kanamycin resistance gene in the unique central region of Tn5. Expression of various cloned fragments of Tn5 suggested that both kanamycin and streptomycin resistance genes were transcribed from the same promoter. E. coli mutants allowing the expression of streptomycin resistance from Tn5 were isolated. The differential expression of the streptomycin resistance gene provides a simple selection/counterselection criterion, using only streptomycin in transfer experiments of Tn5 between E. coli and R. meliloti.     

Identification and sequence of a tet(M) tetracycline resistance determinant homologue in clinical isolates of Escherichia coli

The presence of the tetracycline resistance determinant tet(M) in human clinical isolates of Escherichia coli is described for the first time in this report. The homologue was >99% identical to the tet(M) genes reported to occur in Lactobacillus plantarum, Neisseria meningitidis, and Streptococcus agalactiae, and 3% of the residues in its deduced amino acid sequence diverge from tet(M) of Staphylococcus aureus. Sequence analysis of the regions immediately flanking the gene revealed that sequences upstream of tet(M) in E. coli have homology to Tn916; however, a complete IS26 insertion element was present immediately upstream of the promoter element. Downstream from the termination codon is an insertion sequence that was homologous to the ISVs1 element reported to occur in a plasmid from Vibrio salmonicida that has been associated with another tetracycline resistance determinant, tet(E). Results of mating experiments demonstrated that the E. coli tet(M) gene was on a mobile element so that resistance to tetracycline and minocycline could be transferred to a susceptible strain by conjugation. Expression of the cloned tet(M) gene, under the control of its own promoter, provided tetracycline and minocycline resistance to the E. coli host.     

Haemophilus influenzae immunoglobulin A1 protease genes: cloning by plasmid integration-excision, comparative analyses, and localization of secretion determinants.

Many bacteria which establish infections after invasion at human mucosal surfaces produce enzymes which cleave immunoglobulin A (IgA), the primary immunoglobulin involved with protection at these sites. Bacterial species such as Haemophilus influenzae which produce IgA1 proteases secrete this enzyme into their environment. However, when the gene encoding this protein was isolated from H. influenzae serotype d and introduced into Escherichia coli, the activity was not secreted into the medium but was localized in the periplasmic space. In this study, the IgA1 protease gene (iga) from an H. influenzae serotype c strain was isolated and the gene from the serotype d strain was reisolated. The IgA1 proteases produced in E. coli from these genes were secreted into the growth medium. A sequence linked to the carboxyl terminus of the iga gene but not present in the original clone was shown to be necessary to achieve normal secretion. Tn5 mutagenesis of the additional carboxyl-terminal region was used to define a 75- to 100-kilodalton coding region required for complete secretion of IgA1 protease but nonessential for protease activity. The iga genes were isolated by a plasmid integration-excision procedure. In this method a derivative of plasmid pBR322 containing a portion of the protease gene and the kanamycin resistance determinant of Tn5 was introduced into H. influenzae by transformation. The kanamycin resistance gene was expressed in H. influenzae, but since pBR322 derivatives are unable to replicate in this organism, kanamycin-resistant transformants arose by integration of the plasmid into the Haemophilus chromosome by homologous recombination. The plasmid, together with the adjoining DNA encoding IgA1 protease, was then excised from the chromosome with DNA restriction enzymes, religated, and reintroduced into E. coli. Comparisons between the H. influenzae protease genes were initiated which are useful in locating functional domains of these enzymes.     

The inactivation of tet genes on a plasmid by the duplication of one inverted repeat of a transposon-like structure which itself mediates tetracycline resistance

Derivatives of a naturally occurring IncFII tetracycline resistance plasmid (pUB889) which are unable to confer resistance to tetracycline, and which were isolated from both partners of a married couple, have been examined. The tet genes are part of a transposon-like structure which is closely related to, but distinct from, Tn10. The lesions in the two plasmids examined are identical and involve the insertion of a nucleotide sequence of 0.9 × 10⁶ within the region encoding tetracycline resistance, expression of which is lost as a consequence. The extra DNA is homologous with the nucleotide sequence, a pair of which form the inverted repeats of the Tn10-like structure. We conclude that this nucleotide sequence comprises an IS element. The epidemiological implications arising from the origin of these plasmids are discussed.     

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.     

Nucleotide sequence analysis of the class G tetracycline resistance determinant from Vibrio anguillarum.

The nucleotide sequence of the class G tetracycline resistance determinant previously isolated from Vibrio anguillarum has been determined. Two open reading frames of divergent polarity were identified. A resistance gene (tet A) encodes a protein of 393 amino acid residues (deduced molecular mass of 40.9 kDa), and a repressor gene (tet R) encodes a protein consisting of 210 amino acids with a calculated molecular mass of 23.6 kDa. Based on the deduced amino acid sequences, the proteins of tet A(G) and tet R(G) are about 60% homologous with those of RP1/Tn1721 (class A) and pSC101/pBR322 (class C), and about 50% homologous with Tn10 (class B). The relationship of the tet (G) sequence to five known tetracycline resistance determinants (class A to E) is discussed.