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

Enhanced immune responses to viral epitopes by combining macrophage-inducible expression with multimeric display on a Salmonella vector

In this study, the immunogenicity of chimeric 987P fimbriae on a Salmonella vaccine strain was improved by optimizing fimbrial expression. The constitutive tetA promoter and the in vivo activated nirB and pagC promoters were evaluated for their use to express two epitopes of the transmissible gastroenteritis virus (TGEV) spike protein carried by fimbriae which were displayed on a Salmonella vaccine strain. Constructs with the pagC promoter were shown to drive increased expression of chimeric 987P fimbriae in macrophages as well as in Mg(2+)-poor media, mimicking a major environmental signal found in Salmonella-containing endocytic vacuoles of macrophages. Mice immunized orally with a Salmonella vaccine strain which expressed chimeric fimbriae from the pagC promoter elicited significantly higher mucosal and systemic immune responses to both the 987P fimbriae and the TGEV epitopes than mice immunized with the same strain hosting a tetA or nirB promoter-driven expression plasmid. Moreover, only the Salmonella vaccine strains harboring a plasmid with the pagC promoter, with or without an additional tetA promoter in tandem, elicited neutralizing antibodies to TGEV. This indicated that the pagC promoter can be used successfully to improve epitope-display by chimeric fimbriae on Salmonella vaccine strains for the induction of a desired immune response.

Butyrolactone autoregulator receptor protein (BarA) as a transcriptional regulator in Streptomyces virginiae

BarA of Streptomyces virginiae is a specific receptor protein for virginiae butanolides (VBs), a member of the butyrolactone autoregulators of Streptomyces species. Sequencing around the barA gene revealed two novel open reading frames: one upstream, barX, encoding a homolog of AfsA of Streptomyces griseus and another downstream, barB. Northern (RNA) blot analysis for S. virginiae demonstrated that the addition of VB during cultivation switched on the expression of barB. An in vivo expression system in Streptomyces lividans with the use of the xylE reporter gene indicated that BarA in conjunction with VB controlled the barB promoter. Furthermore, the DNA binding ability of BarA was demonstrated in vitro for the first time by means of surface plasmon resonance and a gel-shift assay. Complex formation with VB in vitro resulted in the dissociation of BarA from DNA, thus suggesting that the VB receptor, BarA, is a transcriptional regulator and that the VB signal is transduced to the next step in the signal transduction pathway by modification of the DNA binding ability of BarA.

Mutations in the tetA(B) gene that cause a change in substrate specificity of the tetracycline efflux pump

The tetA(B) gene from transposon Tn10 fails to mediate resistance to the novel tetracycline analog 9-(dimethylglycylamido)minocycline (DMG-Mino) (P. E. Sum, V. J. Lee, R. T. Testa, J. J. Hlavka, G. A. Ellestad, J. D. Bloom, Y. Gluzman, and F. P. Tally, J. Med. Chem. 37:184-188, 1994; R. T. Testa, P. Petersen, N. V. Jacobus, P. E. Sum, V. J. Lee, and F. P. Tally, Antimicrob. Agents Chemother. 37:2270-2277, 1993). Mutations in either of two codons of tetA(B) that resulted in increased resistance to DMG-Mino also caused diminished resistance to tetracycline, identifying amino acid residues critical for the recognition of tetracycline.

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.

Nucleotide sequence of class D tetracycline resistance genes from Salmonella ordonez

Plasmid pIP173, isolated from Salmonella ordonez strain BM2000, confers resistance to tetracycline and a number of other antibiotics. We determined the nucleotide sequence of the pIP173 tetR repressor and tetA resistance genes. The pIP173 tetR gene is essentially identical to the class D tetR gene from plasmid RA1. The pIP173 tet genes are flanked by directly repeated copies of the insertion sequence IS26. Interestingly, the 3' end of the tetR gene, encoding the C-terminal 16 amino acids of the TetR protein, extends into the flanking IS26 sequence. The relationships between the class A, B, C, and D TetA sequences parallel the relationships between the corresponding TetR sequences; class D is more closely related to class B than to either class A or C. Overall, the four TetA sequences show 38% identity and 57% similarity.

Genetic analysis of the tetA(C) gene on plasmid pBR322

The TetA(C) protein, encoded by the tetA(C) gene of plasmid pBR322, is a member of a family of membrane-bound proteins that mediate energy-dependent efflux of tetracycline from the bacterial cell. The tetA(C) gene was mutagenized with hydroxylamine, and missense mutations causing the loss of tetracycline resistance were identified at 30 distinct codons. Mutations that encoded substitutions within putative membrane-spanning alpha-helical regions were scattered throughout the gene. In contrast, mutations outside the alpha-helical regions were clustered in two cytoplasmic loops, between helices 2 and 3 and helices 10 and 11, suggesting that these regions play a critical role in the recognition of tetracycline and/or energy transduction. All of the missense mutations encoded a protein that retained the ability to rescue an Escherichia coli strain defective in potassium uptake, suggesting that the loss of tetracycline resistance was not due to an unstable TetA(C) protein or to the failure of the protein to be inserted in the membrane. We postulate that the mutations encode residues that are critical for the active efflux of tetracycline, except for mutations that result in the introduction of charged residues within hydrophobic regions of the TetA(C) protein.

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.

Computer simulations and experimental studies of gel mobility patterns for weak and strong non-cooperative protein binding to two targets on the same DNA: application to binding of tet repressor variants to multiple and single tet operator sites

A series of computer simulations of gel patterns assuming non-cooperative binding of a protein to two targets on the same DNA fragment was performed and applied to interprete gel mobility shift experiments of Tet repressor-tet operator binding. While a high binding affinity leads to the expected distribution of free DNA, DNA bound by one repressor dimer and DNA bound by two repressor dimers, a lower affinity or an increased electrophoresis time results in the loss of the band corresponding to the singly occupied complex. The doubly occupied complex remains stable under these conditions. This phenomenon is typical for protein binding to DNA fragments with two identical sites. It results from statistical disproportionation of the singly occupied complex in the gel. The lack of the singly occupied complex is commonly taken to indicate cooperative binding, however, our analysis shows clearly, that cooperativity is not needed to interprete these results. Tet repressor proteins and small DNA fragments with two tet operator sites have been prepared from four classes of tetracycline resistance determinants. The results of gel mobility shift analyses of various complexes of these compounds confirm the predictions. Furthermore, calculated gel patterns assuming different gel mobilities of the two singly occupied complexes show discrete bands only if the electrophoresis time is shorter than the inverse of the microscopic dissociation rate constant. Simulations assuming increasing dissociation rates predict that the two bands first merge into one, which then disappears. This behavior was verified by gel mobility analyses of Tet repressor-tet operator titrations at increased salt concentrations as well as by direct footprinting of the complexes in the gel. It is concluded that comparison of the intensities of the single and the double occupation bands allow a rough estimation of the dissociation rate constant. On this basis the sixteen possible Tet repressor-tet operator combinations can be ordered with decreasing binding affinities by a simple gel shift experiment. The implications of these results for gel mobility analyses of other protein-DNA complexes are discussed.

Interdomain hybrid Tet proteins confer tetracycline resistance only when they are derived from closely related members of the tet gene family

Inner membrane Tet proteins encoded by tet genes in gram-negative bacteria mediate resistance to tetracycline (Tcr) by directing its export. Total sequences for class A, B, and C tet genes demonstrate that their products have a common ancestor, with Tet(A) and Tet(C) being more closely related (78% identical) than either is to Tet(B) (45% identical). The N- and C-terminal halves of Tet(B) and Tet(C) appear to comprise separate domains, and trans-complementation observed between tetracycline sensitive mutants in either domain of Tet(B) suggests separate but interactive functions for these domains. In this present study, interdomain hybrid genes were constructed to express hybrid tet products whose N- and C-terminal halves were derived from different family members [Tet(A/C), Tet(B/C), and Tet(C/B)]. Tet(A/C) specified a level of Tcr comparable to wild-type Tet(C) and 60% that of Tet(A), indicating that domains from these closely related tet products can function in cis. Although neither Tet(B/C) nor Tet(C/B) hybrids conferred significant Tcr, cells producing both of these types of hybrid proteins expressed substantial Tcr, indicating that productive interactions can occur in trans between Tet(B/C) and Tet(C/B). Taken together, these results suggest that highly specific interactions between the N- and C-terminal domains are necessary for Tcr and do not occur in individual hybrids derived from the more distant relatives, Tet(B) and Tet(C). This requirement for specific interactions suggests that N- and C-terminal domains have coevolved in each member of the Tet family.

Identification and nucleotide sequence of the class E tet regulatory elements and operator and inducer binding of the encoded purified Tet repressor

The regulatory region and repressor (tetRE) gene from the class E tetracycline resistance determinant previously isolated from Enterobacteriaceae have been identified and completely sequenced. The regulatory region is located between the resistance gene and the tetR gene which have opposite polarity. The tetR gene encodes a protein consisting of 211 amino acids with a calculated molecular weight of 23.6 kDa. Cloning of the tetR gene under transcriptional control of the lambda PL promoter leads to overexpression of a polypeptide with an apparent molecular weight of 26 kDa. The purified protein binds sequence specifically to DNA fragments containing putative tet operators. This property is lost in the presence of tetracycline. The relationship of the tetRE sequence to four known tetracycline resistance determinants is discussed.

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.

Tn10-encoded tet repressor can regulate an operator-containing plant promoter

The Tn10-encoded tet repressor-operator system was used to regulate transcription from the cauliflower mosaic virus (CaMV) 35S promoter. Expression was monitored in a transient assay system by using electric field-mediated gene transfer ("electroporation") into tobacco protoplasts. The tet repressor, being expressed in the plant cells under the control of eukaryotic transcription signals, blocks transcription of a CaMV 35S promoter chloramphenicol acetyltransferase (cat) fusion gene when the two tet operators flank the "TATA" box. In the presence of the inducer tetracycline, expression is restored to full activity. Location of the operators 21 base pairs downstream of the transcription start site does not significantly affect transcription in the presence of the repressor. These experiments show that a prokaryotic regulatory protein can function in plant cells. The tet repressor-operator complex may be useful for specifically inducing transferred genes at different stages of plant development.

Topoisomerase I mutants: the gene on pBR322 that encodes resistance to tetracycline affects plasmid DNA supercoiling

Plasmid pBR322 DNA isolated from topoisomerase I mutants of Escherichia coli and Salmonella typhimurium exhibits a distinctive supercoiling distribution characterized by an extremely heterogeneous distribution of linking numbers that contains highly negatively supercoiled topoisomers. Analysis of the supercoiling distributions of deletion and insertion derivatives of pBR322 shows that the presence of the gene on pBR322 encoding resistance to tetracycline is responsible for the unusual supercoiling distribution. Both an intact promoter and a portion of the remainder of the gene, but not the gene product, are required. However, no particular section of the gene outside the promoter appears to be necessary; only the size of the section remaining appears to be important. These observations suggest that transcription of this gene may be responsible for its effect on DNA supercoiling.

Regions associated with the stable maintenance of plasmid pSC101 and its tetracycline resistance

Two regions tentatively called unsA and unsR were identified on pSC101. One, unsA, corresponds to less than 650 bp of the N-terminal in the tetracycline resistance structural gene and seems to inhibit stable maintenance of pSC101. The other, unsR, is defined within the 1 kb XhoI-EcoRI region located upstream of the tetracycline resistance structural gene and is a regulatory gene clearly distinct from tetR (Unger et al. 1984); it serves as a suppressor of the unsA function.

Expression, purification and operator binding of the transposon Tn1721-encoded Tet repressor

The regulation of expression of the Tn1721-encoded tetracycline-resistance determinant is described at the molecular level. The transcriptional control element consists of overlapping divergent promoters, which are negatively regulated by two operators with nearly identical sequence. The mRNA for the regulatory gene tetR is translated without a ribosome-binding site. This result is confirmed by S1 nuclease mapping and RNA sequencing of the tetR mRNA. The start nucleotide for transcription of this mRNA is the adenosine residue of the sequence 5'-AUG. Determination of the N-terminal amino acid sequence of the purified Tet repressor proves that this AUG is the initiation codon for translation. The Tet repressor protein is further used to map the two tet operators by DNase I footprinting. Tight contacts of the protein to the N-7 positions of two guanosine residues in each operator are determined from methylation protection experiments with dimethylsulfate. The differential regulation and positive control of transcription of the tetR gene that is possible with this arrangement of promoters and operators is discussed.

Acinetobacter calcoaceticus encoded mutarotase: nucleotide sequence analysis of the gene and characterization of its secretion in Escherichia coli

The nucleotide sequence of the mutarotase gene from Acinetobacter calcoaceticus has been determined. It reveals an open reading frame of 381 amino acids. The codon usage of A. calcoaceticus for this gene is similar to E. coli except for the amino acids Leu, Ala, Glu, and Arg where major differences exist. This did not interfere drastically with high level expression in E. coli. The regulatory sequences for the initiation of translation are similar to the ones described for E. coli. The N-terminal 20 amino acids, which are not found in the mature enzyme, show homology to signal sequences of exported proteins. In A. calcoaceticus and E. coli mutarotase is specifically secreted into the periplasmic space. Processing of the signal sequence occurs at identical sites in both organisms. The mature mutarotase consists of 361 amino acids and has a calculated molecular weight of 38457 Da. Expression of mutarotase at a high level in a recombinant E. coli destabilizes the outer membrane. This results in coordinated leakage of mutarotase and beta-lactamase into the culture broth.

Promoter-probe vectors for the analysis of divergently arranged promoters

A series of plasmid-based promoter-probe vectors has been constructed which are particularly useful for the analysis of divergent control regions. Each vector contains a pair of divergently oriented indicator genes whose expression can be monitored over a wide range by simple assay methods. These genes are separated by different polylinkers. Specifically, the beta-galactosidase gene (lacZ) was employed in combination with either the galactokinase gene (galK) or the alkaline phosphatase gene (phoA). In all cases translational stop codons are present in all three reading frames upstream from the initiation codon. The vectors permit direct detection of promoters--independent of insert orientation--on indicator plates after transformation. Using this vector system, we further characterized the divergent tet control regions of transposon Tn10 and plasmid pBR322.

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.