Organization of the Tn6-related kanamycin resistance transposon Tn2680 carrying two copies of IS26 and an IS903 variant, IS903. B

IS26 and the IS26 family: versatile resistance gene movers and genome reorganizers

SUMMARYIn Gram-negative bacteria, the insertion sequence IS26 is highly active in disseminating antibiotic resistance genes. IS26 can recruit a gene or group of genes into the mobile gene pool and support their continued dissemination to new locations by creating pseudo-compound transposons (PCTs) that can be further mobilized by the insertion sequence (IS). IS26 can also enhance expression of adjacent potential resistance genes. IS26 encodes a DDE transposase but has unique properties. It forms cointegrates between two separate DNA molecules using two mechanisms. The well-known copy-in (replicative) route generates an additional IS copy and duplicates the target site. The recently discovered and more efficient and targeted conservative mechanism requires an IS in both participating molecules and does not generate any new sequence. The unit of movement for PCTs, known as a translocatable unit or TU, includes only one IS26. TU formed by homologous recombination between the bounding IS26s can be reincorporated via either cointegration route. However, the targeted conservative reaction is key to generation of arrays of overlapping PCTs seen in resistant pathogens. Using the copy-in route, IS26 can also act on a site in the same DNA molecule, either inverting adjacent DNA or generating an adjacent deletion plus a circular molecule carrying the DNA segment lost and an IS copy. If reincorporated, these circular molecules create a new PCT. IS26 is the best characterized IS in the IS26 family, which includes IS257/IS431, ISSau10, IS1216, IS1006, and IS1008 that are also implicated in spreading resistance genes in Gram-positive and Gram-negative pathogens.

Identification and Characterisation of pST1023 A Mosaic, Multidrug-Resistant and Mobilisable IncR Plasmid

We report the identification and characterisation of a mosaic, multidrug-resistant and mobilisable IncR plasmid (pST1023) detected in Salmonella ST1023, a monophasic variant 4,[5],12:i: strain of widespread pandemic lineage, reported as a Southern European clone. pST1023 contains exogenous DNA regions, principally gained from pSLT-derivatives and IncI1 plasmids. Acquisition from IncI1 included oriT and nikAB and these conferred the ability to be mobilisable in the presence of a helper plasmid, as we demonstrated with the conjugative plasmids pST1007-1D (IncFII) or pVC1035 (IncC). A sul3-associated class 1 integron, conferring resistance to aminoglycosides, chloramphenicol and trimethoprim-sulphonamides, was also embedded in the acquired IncI1 DNA segment. pST1023 also harboured an additional site-specific recombination system (rfsF/rsdB) and IS elements of the IS1, IS5 (IS903 group) and IS6 families. Four of the six IS26 elements present constituted two pseudo-compound-transposons, named PCT-sil and PCT-Tn10 (identified here for the first time). The study further highlighted the mosaic genetic architecture and the clinical importance of IncR plasmids. Moreover, it provides the first experimental data on the ability of IncR plasmids to be mobilised and their potential role in the horizontal spread of antimicrobial-resistant genes.

The IS6 family, a clinically important group of insertion sequences including IS26

The IS6 family of bacterial and archaeal insertion sequences, first identified in the early 1980s, has proved to be instrumental in the rearrangement and spread of multiple antibiotic resistance. Two IS, IS26 (found in many enterobacterial clinical isolates as components of both chromosome and plasmids) and IS257 (identified in the plasmids and chromosomes of gram-positive bacteria), have received particular attention for their clinical impact. Although few biochemical data are available concerning the transposition mechanism of these elements, genetic studies have provided some interesting observations suggesting that members of the family might transpose using an unexpected mechanism. In this review, we present an overview of the family, the distribution and phylogenetic relationships of its members, their impact on their host genomes and analyse available data concerning the particular transposition pathways they may use. We also provide a mechanistic model that explains the recent observations on one of the IS6 family transposition pathways: targeted cointegrate formation between replicons.

An analysis of the IS6/IS26 family of insertion sequences: is it a single family?

The relationships within a curated set of 112 insertion sequences (ISs) currently assigned to the IS6 family, here re-named the IS6/IS26 family, in the ISFinder database were examined. The encoded DDE transposases include a helix-helix-turn-helix (H-HTH) potential DNA binding domain N-terminal to the catalytic (DDE) domain, but 10 from Clostridia include one or two additional N-terminal domains. The transposase phylogeny clearly separated 75 derived from bacteria from 37 from archaea. The longer bacterial transposases also clustered separately. The 65 shorter bacterial transposases, including Tnp26 from IS26, formed six clades but share significant conservation in the H-HTH domain and in a short extension at the N-terminus, and several amino acids in the catalytic domain are completely or highly conserved. At the outer ends of these ISs, 14 bp were strongly conserved as terminal inverted repeats (TIRs) with the first two bases (GG) and the seventh base (G) present in all except one IS. The longer bacterial transposases are only distantly related to the short bacterial transposases, with only some amino acids conserved. The TIR consensus was longer and only one IS started with GG. The 37 archaeal transposases are only distantly related to either the short or the long bacterial transposases and different residues were conserved. Their TIRs are loosely related to the bacterial TIR consensus but are longer and many do not begin with GG. As they do not fit well with most bacterial ISs, the inclusion of the archaeal ISs and the longer bacterial ISs in the IS6/IS26 family is not appropriate.

Identification of a novel lineage of plasmids within phylogenetically diverse subclades of IncHI2-ST1 plasmids

IncHI2-ST1 plasmids play an important role in co-mobilizing genes conferring resistance to critically important antibiotics and heavy metals. Here we present the identification and analysis of IncHI2-ST1 plasmid pSPRC-Echo1, isolated from an Enterobacter hormaechei strain from a Sydney hospital, which predates other multi-drug resistant IncHI2-ST1 plasmids reported from Australia. Our time-resolved phylogeny analysis indicates pSPRC-Echo1 represents a new lineage of IncHI2-ST1 plasmids and show how their diversification relates to the era of antibiotics.

Mobile Genetic Elements Associated with Antimicrobial Resistance

Strains of bacteria resistant to antibiotics, particularly those that are multiresistant, are an increasing major health care problem around the world. It is now abundantly clear that both Gram-negative and Gram-positive bacteria are able to meet the evolutionary challenge of combating antimicrobial chemotherapy, often by acquiring preexisting resistance determinants from the bacterial gene pool. This is achieved through the concerted activities of mobile genetic elements able to move within or between DNA molecules, which include insertion sequences, transposons, and gene cassettes/integrons, and those that are able to transfer between bacterial cells, such as plasmids and integrative conjugative elements. Together these elements play a central role in facilitating horizontal genetic exchange and therefore promote the acquisition and spread of resistance genes. This review aims to outline the characteristics of the major types of mobile genetic elements involved in acquisition and spread of antibiotic resistance in both Gram-negative and Gram-positive bacteria, focusing on the so-called ESKAPEE group of organisms (Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, Enterobacter spp., and Escherichia coli), which have become the most problematic hospital pathogens.

Transposons: the agents of antibiotic resistance in bacteria

Transposons are a group of mobile genetic elements that are defined as a DNA sequence. Transposons can jump into different places of the genome; for this reason, they are called jumping genes. However, some transposons are always kept at the insertion site in the genome. Most transposons are inactivated and as a result, cannot move. Transposons are divided into two main groups: retrotransposons (class І) and DNA transposons (class ІІ). Retrotransposons are often found in eukaryotes. DNA transposons can be found in both eukaryotes and prokaryotes. The bacterial transposons belong to the DNA transposons and the Tn family, which are usually the carrier of additional genes for antibiotic resistance. Transposons can transfer from a plasmid to other plasmids or from a DNA chromosome to plasmid and vice versa that cause the transmission of antibiotic resistance genes in bacteria. The treatment of bacterial infectious diseases is difficult because of existing antibiotic resistance that part of this antibiotic resistance is caused by transposons. Bacterial infectious diseases are responsible for the increasing rise in world mortality rate. In this review, transposons and their roles have been studied in bacterial antibiotic resistance, in detail.

Complete nucleotide sequence of two multidrug-resistant IncR plasmids from Klebsiella pneumoniae

We report here the complete nucleotide sequence of two IncR replicons encoding multidrug resistance determinants, including β-lactam (blaDHA-1, blaSHV-12), aminoglycoside (aphA1, strA, strB), and fluoroquinolone (qnrB4, aac6'-1b-cr) resistance genes. The plasmids have backbones that are similar to each other, including the replication and stability systems, and contain a wide variety of transposable elements carrying known antibiotic resistance genes. This study confirms the increasing clinical importance of IncR replicons as resistance gene carriers.

Analysis of antibiotic resistance regions in Gram-negative bacteria

Antibiotic resistance in Gram-negative bacteria is often due to the acquisition of resistance genes from a shared pool. In multiresistant isolates these genes, together with associated mobile elements, may be found in complex conglomerations on plasmids or on the chromosome. Analysis of available sequences reveals that these multiresistance regions (MRR) are modular, mosaic structures composed of different combinations of components from a limited set arranged in a limited number of ways. Components common to different MRR provide targets for homologous recombination, allowing these regions to evolve by combinatorial evolution, but our understanding of this process is far from complete. Advances in technology are leading to increasing amounts of sequence data, but currently available automated annotation methods usually focus on identifying ORFs and predicting protein function by homology. In MRR, where the genes are often well characterized, the challenge is to identify precisely which genes are present and to define the boundaries of complete and fragmented mobile elements. This review aims to summarize the types of mobile elements involved in multiresistance in Gram-negative bacteria and their associations with particular resistance genes, to describe common components of MRR and to illustrate methods for detailed analysis of these regions.

Sequence of pNL194, a 79.3-kilobase IncN plasmid carrying the blaVIM-1 metallo-beta-lactamase gene in Klebsiella pneumoniae

The nucleotide sequence of pNL194, a VIM-1-encoding plasmid, is described in this study. pNL194 (79,307 bp) comprised an IncN-characteristic segment (38,940 bp) and a mosaic structure (40,367 bp) including bla(VIM-1), aacA7, aadA1, aadA2, dfrA1, dfrA12, aphA1, strA, strB, and sul1. Tn1000 or Tn5501 insertion within fipA probably facilitated recruitment of additional mobile elements carrying resistance genes.

Characterization of the highly variable region surrounding the blaCTX-M-9 gene in non-related Escherichia coli from Barcelona

OBJECTIVES

The dispersion of a clone, a plasmid or a mobile element carrying the bla(CTX-M-9) gene was evaluated in 30 Escherichia coli strains isolated in Barcelona between 1996 and 1999. The presence of the previously described orf513-bearing class 1 integron, In60, carrying the bla(CTX-M-9) gene, was also studied.

METHODS

The clonality was analysed by pulsed-field gel electrophoresis. Plasmid analysis was performed by S1 digestion and hybridization with the CTX-M-9 probe. PCR mapping using specific designed primers was used to study the presence of In60 and In60-like structures.

RESULTS

The clonality between the 30 strains was minor. The size of bla(CTX-M-9) carrying plasmids ranged between approximately 80 and 430 kb. One strain produced only a chromosome-encoded CTX-M-9 beta-lactamase. Thirty-six per cent of the strains showed differences with respect to the In60 structure due to an insertion or deletion events.

CONCLUSIONS

These findings suggest that the bla(CTX-M-9) gene may be carried by a mobile element that disperses it between plasmids. The fast dispersion of the CTX-M-9 enzyme could therefore be due to both diffusion of plasmids and mobile elements.

Complete nucleotide sequence of plasmid Rts1: implications for evolution of large plasmid genomes

Rts1, a large conjugative plasmid originally isolated from Proteus vulgaris, is a prototype for the IncT plasmids and exhibits pleiotropic thermosensitive phenotypes. Here we report the complete nucleotide sequence of Rts1. The genome is 217,182 bp in length and contains 300 potential open reading frames (ORFs). Among these, the products of 141 ORFs, including 9 previously identified genes, displayed significant sequence similarity to known proteins. The set of genes responsible for the conjugation function of Rts1 has been identified. A broad array of genes related to diverse processes of DNA metabolism were also identified. Of particular interest was the presence of tus-like genes that could be involved in replication termination. Inspection of the overall genome organization revealed that the Rts1 genome is composed of four large modules, providing an example of modular evolution of plasmid genomes.

Identification and characterization of the single-stranded DNA-binding protein of bacteriophage P1

The genome of bacteriophage P1 harbors a gene coding for a 162-amino-acid protein which shows 66% amino acid sequence identity to the Escherichia coli single-stranded DNA-binding protein (SSB). The expression of the P1 gene is tightly regulated by P1 immunity proteins. It is completely repressed during lysogenic growth and only weakly expressed during lytic growth, as assayed by an ssb-P1/lacZ fusion construct. When cloned on an intermediate-copy-number plasmid, the P1 gene is able to suppress the temperature-sensitive defect of an E. coli ssb mutant, indicating that the two proteins are functionally interchangeable. Many bacteriophages and conjugative plasmids do not rely on the SSB protein provided by their host organism but code for their own SSB proteins. However, the close relationship between SSB-P1 and the SSB protein of the P1 host, E. coli, raises questions about the functional significance of the phage protein.

Three functions of bacteriophage P1 involved in cell lysis

Amber and deletion mutants were used to assign functions in cell lysis to three late genes of bacteriophage P1. Two of these genes, lydA and lydB of the dar operon, are 330 and 444 bp in length, respectively, with the stop codon of lydA overlapping the start codon of lydB. The third, gene 17, is 558 bp in length and is located in an otherwise uncharacterized operon. A search with the predicted amino acid sequence of LydA for secondary motifs revealed a holin protein-like structure. Comparison of the deduced amino acid sequence of gene 17 with sequences of proteins in the SwissProt database revealed homologies with the proteins of the T4 lysozyme family. The sequence of lydB is novel and exhibited no known extended homology. To study the effect of gp17, LydA, and LydB in vivo, their genes were cloned in a single operon under the control of the inducible T7 promoter, resulting in plasmid pAW1440. A second plasmid, pAW1442, is identical to pAW1440 but has lydB deleted. Induction of the T7 promoter resulted in a rapid lysis of cells harboring pAW1442. In contrast, cells harboring pAW1440 revealed only a small decrease in optical density at 600 nm compared with cells harboring vector alone. The rapid lysis phenotype in the absence of active LydB suggests that this novel protein might be an antagonist of the holin LydA.

Presence of a P1 bacteriophage sequence in transforming plasmids of Pleurotus ostreatus

Replicative plasmids pP01 and pP02, recovered from Pleurotus ostreatus transformants, contain an insert of bacteriophage origin. These plasmids have been amplified by the polymerase chain reaction (PCR) and have been shown to represent a low-grade component in the initial preparation of the vector pAN7-1. The pP01 and pP02 plasmids share an insert (P01A) of virtual identity with a SmaI-BamHI genomic fragment of P 1 bacteriophage and retain remnants of a polylinker at the 5' end of this fragment. Such an insert undoubtedly represents an in vitro-generated event and did not arise, as suggested previously, by recombination of pAN7-1 with the P. ostreatus genome. The P. ostreatus transformants, however, do select for the minority pP0 plasmid, apparently recognizing the P01A insert as a heterologous or surrogate replicon.

A new dhfrVIII trimethoprim-resistance gene, flanked by IS26, whose product is remote from other dihydrofolate reductases in parsimony analysis

A new plasmid-borne gene, dhfrVIII, encoding high-level trimethoprim resistance (TpR) was found in an intestinal Escherichia coli. It seems to be a widely occurring mediator of TpR. Among 973 examined TpR E. coli, the new resistance gene was found in 13 (1.3%) isolates from Sweden, Finland and Nigeria. The new gene was sequenced and found to code for a dihydrofolate reductase (DHFR) of 169 amino acids (M(r) 19005). The dhfrVIII gene on the studied plasmid pLMO226 was observed to be flanked by IS26 elements. The dhfrVIII gene and a 3' unidentified open reading frame (ORF) seem to be borne on a compound transposon with IS26 at its ends, since the configuration of two IS26 flanking dhfrVIII and the unidentified ORF was conserved among the isolates that were probe-positive for the gene. Phylogeny parsimony analysis showed the dhfrVIII-encoded enzyme to be only remotely related to other known plasmid-mediated, drug-resistant DHFR. Only a few of the latter form well-supported monophyletic groups.

The transposon-like structure of IS26-tetracycline, and kanamycin resistance determinant derived from transferable R plasmid of fish pathogen, Pasteurella piscicida

Tetracycline (pp-tet), and kanamycin (pp-kan) resistance genes were cloned from a transferable R plasmid of fish pathogen Pasteurella piscicida, and complete nucleotide sequences were determined. The pp-tet was a class D Tet determinant constructed with the tetA resistance gene of 1,182 bp encoding a protein with a deduced molecular mass of 41 kDa and the tetR repressor gene of 654 bp encoding a product of 24 kDa. The pp-tet was highly homologous to the tet(D) of plasmid RA1 isolated from Aeromonas hydrophila with two nucleotide differences in the tetR, and of plasmid pIP173 from Salmonella ordonez with two nucleotide differences in the tetA. The pp-kan contained 813 bp encoding a 31 kDa protein of 271 amino acids, and was classified into type aph-Ic. It was identical to the aphA7 in the IAB operon of pBWH77, in which was originally found an isolate of Klebsiella pneumoniae, in its nucleotide sequences and hybrid promoter construction. The genes were connected by an insertion sequence IS26 of 820 bp, and were flanked by repeated copies in direct orientation at the 3' flanking region of the pp-tetA and in inverted orientation at the 3' flanking region of the pp-kan. The genetic elements are organized like a complex transposon by close linkage of the IS26 and the pp-tet and -kan.

Mutational analysis of the bacteriophage P1 late promoter sequence Ps

The bacteriophage P1 late promoter sequence Ps controls the expression of the genes in the tail-fibre operon. Transcription from Ps only occurs during the second half of the P1 vegetative growth cycle and is positively regulated by the product of the phage gene 10. In this study degenerate oligonucleotides were used as primers in site-directed mutagenesis reactions in order to construct a large set of point mutations within the late promoter sequence Ps. A total of 35 independent single point mutations was isolated and the mutants were tested for promoter activity. Mutations in the Escherichia coli-like -10 region and in a late operator sequence, containing a symmetric sequence centred around position -22, resulted in significant reductions in promoter strength. Most of these mutations alter base-pairs that are highly conserved among the known late promoter sequences of the P1 family. In addition, insertion mutants that change the spacing between the -10 and the late operator indicate that a special topological arrangement between the two boxes is crucial for late promoter function. These results suggest that the product of gene 10 binds specifically to a late operator in order to activate transcription from P1 late promoter sequences.

Bacteriophage P1 gene 10 is expressed from a promoter-operator sequence controlled by C1 and Bof proteins

Gene 10 of bacteriophage P1 encodes a regulatory function required for the activation of P1 late promoter sequences. In this report cis and trans regulatory functions involved in the transcriptional control of gene 10 are identified. Plasmid-borne fusions of gene 10 to the indicator gene lacZ were constructed to monitor expression from the gene 10 promoter. Production of gp10-LacZ fusion protein became measurable at about 15 min after prophage induction, whereas no expression was observed during lysogenic growth. The activity of an Escherichia coli-like promoter, Pr94, upstream of gene 10, was confirmed by mapping the initiation site of transcription in primer extension reactions. Two phage-encoded proteins cooperate in the trans regulation of transcription from Pr94: C1 repressor and Bof modulator. Both proteins are necessary for complete repression of gene 10 expression during lysogeny. Under conditions that did not ensure repression by C1 and Bof, the expression of gp10-LacZ fusion proteins from Pr94 interfered with transformation efficiency and cell viability. Results of in vitro DNA-binding studies confirmed that C1 binds specifically to an operator sequence, Op94, which overlaps the -35 region of Pr94. Although Bof alone does not bind to DNA, together with C1 it increases the efficiency of the repressor-operator interaction. These results are in line with the idea that gp10 plays the role of mediator between early and late gene transcription during lytic growth of bacteriophage P1.

Evolved neomycin phosphotransferase from an isolate of Klebsiella pneumoniae

A new aminoglycoside resistance gene (aphA1-IAB) confers high-level resistance to neomycin. The sequence of aphA1-IAB is closely related to aphA1 found in the transposons Tn4352, Tn903 and Tn602. For example, aphA1-IAB differs from aphA1-903 at five nucleotides that result in four amino acid replacements. The enzyme encoded by aphA1-IAB has a significantly higher turnover number with neomycin, kanamycin and G418 as substrates than does the aphA1-903 enzyme. A parsimonious phylogenetic tree suggests that aphA1-IAB evolved from an ancestral form that is closely related or identical to the aphA1 found in Tn903. The excess of replacement substitutions over silent substitutions in aphA1-IAB, as well as its convergence toward aphA3 from Staphylococcus aureus, is indicative of selective evolution. Our hypothesis to explain these results is that aphA1-IAB evolved under the selective pressure of neomycin use in relatively recent times.

Three short fragments of Rts1 DNA are responsible for the temperature-sensitive growth phenotype (Tsg) of host bacteria

Rts1 is a multiphenotype drug resistance factor, and one of its phenotypes is temperature-sensitive growth (Tsg) of host bacteria. A 3.65-kb fragment from Rts1 DNA was shown to cause the Tsg phenotype in host cells. This tsg fragment was split by a restriction enzyme, HincII, into four fragments. Two of these fragments were called HincII-S (short) and HincII-L (long), respectively. Each of these two fragments conferred the Tsg phenotype, indicating that, in fact, these two independent regions were responsible for the Tsg phenotype. The HincII-S 783-bp and HincII-L 1,479-bp fragments were sequenced. The region in the HincII-S fragment to which the Tsg phenotype was attributed was narrowed to a 146-bp (nucleotides 1 to 146) fragment by various restriction enzyme digestions. Further digestion of the 146-bp fragment with Bal 31 suggested that the 116-bp (nucleotides 9 to 124) fragment is the minimum sequence required for Tsg. On the other hand, in the HincII-L fragment, a fragment of 249 bp (nucleotides 1210 to 1458) and a fragment of 321 bp (nucleotides 1942 to 2262) contained separate temperature-sensitive growth activity. None of three tsg fragments contained open reading frames. The 249-bp fragment had very weak Tsg activity, while the 321-bp fragment had no Tsg activity. On the other hand, when these two fragments were together in the pUC19 vector, they exhibited very strong Tsg activity equivalent to that of the original 1,479-bp fragment. In addition, two of the 249-bp fragments gave similar, strong Tsg activity. The HincII-L 1,479-bp fragment contained an open reading frame for kanamycin resistance which was found between nucleotides 1423 and 2238. This kanamycin resistance gene sequence was different from that of the reported kanamycin resistance gene of Tn903 at 12 positions which were deduced to change seven amino acids.

Cloning of genes interrupted by Tn10 derivatives using antibiotic-resistance-carrying M13mp bacteriophages

We have developed a system for rapidly cloning chromosomal DNA that flanks the site of insertion of Tn10 derivatives. A central portion of the tetracycline-resistance gene (tet) from Tn10 was cloned into a recombinant M13mp vector that carries a cat marker. Infection of a strain that contains a Tn10 derivative (mini-tet) leads to homologous recombination between the chromosomal tet gene and the cloned segment on the bacteriophage. Correct M13 lysogens can be identified by the inactivation of the tet gene and the gain of the cat gene. Digestion, ligation and transformation of chromosomal DNA from an M13 lysogen produces phage which carry a portion of the Tn10 as well as adjoining chromosomal DNA. The phage can be sequenced directly and are very useful for probing libraries for the wild type gene. Recombinant M13 clones have also been developed for the cloning of sequences adjacent to a Tn10 derivative which confers kanamycin resistance (mini-kan).

Direct involvement of IS26 in an antibiotic resistance operon

The plasmid pBWH77, originally found in an isolate of Klebsiella pneumoniae, harbors a new antibiotic resistance operon containing two resistance genes transcribed from an IS26-hybrid promoter, as shown by nucleotide sequencing, mRNA mapping, and the effect of inserting a transcription terminator within the promoter-proximal gene. The nucleotide sequence of this region revealed that the operon (IAB) is made up of three sections that are closely related to previously described genetic elements. The -35 region of the promoter, together with the adjacent sequence, is identical to sequences of the IS26 element. One of the resistance genes, aphA7, which is located next to the hybrid promoter, confers assistance to neomycin and structurally related aminoglycosides. This aphA7 gene is highly homologous to aphA1 of Tn903, with five nucleotide differences. The second gene, blaS2A, encodes an evolved SHV-type beta-lactamase with a pI of 7.6 that confers resistance to the broad-spectrum cephalosporins cefotaxime and ceftizoxime. The deduced amino acid sequence of SHV-2A shows that amino acid 238 is a serine, a residue reported to confer resistance to cefotaxime. We discuss how the operon may have evolved by a combination of insertion sequence-mediated genetic rearrangements and acquisitive evolution. Using phylogenetic parsimony, we show that aphA7 in the IAB operon evolved from an ancestral form similar to aphA1 in Tn903 and that blaS2A evolved from an ancestral form similar to blaS1.

Bacteriophage P1 tail-fibre and dar operons are expressed from homologous phage-specific late promoter sequences

Two plasmid systems, containing the easily assayable galK and lacZ functions, were employed to study the regulation of the bacteriophage P1 tail-fibre and dar operons. Various P1 DNA fragments carrying either the 5' end of lydA (the 1st gene in the dar operon) or the tail-fibre gene 19 precede the promoterless coding region of galK or were fused, in-frame, to the lacZ gene. In the presence of an induced P1 prophage, GalK and LacZ activities were both detected after a 20 to 30 minute lag period, indicating that the dar and tail-fibre operons are expressed from positively regulated, late promoters. The corresponding DNA operons are expressed from positively regulated, late promoters. The corresponding DNA region of the closely related p15B plasmid exhibits comparable promoter properties. Deletion analysis mapped the promoter of a gene 19-lacZ fusion to a DNA region upstream from gene R, an open reading frame that precedes the coding frame of gene 19. The tail-fibre gene thus forms the second gene in a three gene operon (genes R, 19 (S) and U). Sequence comparison between this promoter region, upstream sequences of the lydA gene and the corresponding portions of the p15B genome allowed the identification of a highly conserved 38 base-pair sequence, which most likely represents a P1-specific late promoter. This was confirmed by 5' mapping of P1 mRNA. Transcription of both the tail-fibre and dar operons is initiated at sites five and six base-pairs, respectively, downstream from the first conserved nucleotide of this sequence. The conserved motif consists of a standard Escherichia coli -10 region followed by a nine base-pair palindromic sequence located centrally about position -22.

The Salmonella wien virulence plasmid pZM3 carries Tn1935, a multiresistance transposon containing a composite IS1936-kanamycin resistance element

Tn1935, a 23.5-kb transposon mediating resistance to ampicillin, kanamycin, mercury, spectinomycin, and sulfonamide was isolated from pZM3, an IncFIme virulence plasmid from Salmonella wien. Tn1935 possesses the entire sequence of Tn21 and contains two additional DNA segments of 0.95 and 2.7 kb carrying the ampicillin and kanamycin resistance genes, respectively. The latter is part of a composite element since it is flanked by two IS15-like insertion sequences (IS1936) in direct orientation. IS1936 is about 800 bp long and is closely related to IS15 delta, IS26, IS46, IS140, and IS176. Functional analysis of IS1936-mediated cointegrates shows that both insertion sequences are active and able to form cointegrates at the same frequency. Resolution of the cointegrates requires the presence of the host Rec system. The presence of the composite IS1936-element within Tn1935 supports the hypothesis that multidrug resistance transposons evolved by insertion of antibiotic determinants which are themselves transposable.

Nucleotide sequence of an Rts1 fragment causing temperature-dependent instability

Rts1 is a multiphenotypic drug resistance plasmid which is eliminated from host bacteria at 42 degrees C but not at 32 degrees C. This phenotype has been called temperature-dependent instability (Tdi). We determined the nucleotide sequence of the Rts1 DNA b' segment which causes this phenotype. Within this 786-base-pair segment, several open reading frames (ORFs) were found, including one which encodes a protein with a molecular weight of 16,000. A protein approximately corresponding to this protein is expressed in Escherichia coli minicells harboring plasmids containing the b' segment. In addition, we found the chi sequence at 112 bases proximal to this ORF. Temperature-dependent elimination due to this segment was not observed in the RecA strain of E. coli, but the RecB protein was not required for expression of this phenotype. We constructed various deletion derivatives and found that three portions, the region containing the chi (nucleotides 1 to 24), ORF (nucleotides 25 to 546), and tail (nucleotides 631 to 786) sequences are necessary for Tdi activity. Site-directed mutagenesis studies indicated that ORF I is required for Tdi expression.

Acquisition by a Campylobacter-like strain of aphA-1, a kanamycin resistance determinant from members of the family Enterobacteriaceae

A Campylobacter-like organism, BM2196, resistant to kanamycin and streptomycin-spectinomycin was isolated from the feces of a patient with acute enteritis. The kanamycin and streptomycin-spectinomycin resistances were not transferable to Camplylobacter sp. or to Escherichia coli, and no plasmid DNA was detected in this strain. The resistance genes were therefore tentatively assigned to a chromosomal locality. Analysis by the phosphocellulose paper-binding assay of extracts from BM2196 indicated that resistance to kanamycin and structurally related antibiotics was due to the synthesis of 3'-aminoglycoside phosphotransferase type I [APH(3')-I], an enzyme specific for gram-negative bacteria, and that resistance to streptomycin-spectinomycin was secondary to the presence of a 3",9-aminoglycoside adenylyltransferase. Homology between BM2196 and an APH(3')-I probe was detected by DNA-DNA hybridization. A 2.2-kilobase BM2196 DNA fragment conferring resistance to kanamycin was cloned in E. coli and was sequenced partially. The resistance gene appeared nearly identical to that of Tn903 from E. coli and was adjacent to IS15-delta, an insertion sequence widespread in gram-negative bacteria, thus indicating that Campylobacter species can act as a recipient for genes originating in members of the family Enterobacteriaceae.

Tn602: a naturally occurring relative of Tn903 with direct repeats

We report the characterization of Tn602, a transposon encoding resistance to kanamycin and related aminoglycosides present on the R-plasmid pGD10. Tn602 is highly homologous to the previously characterized Tn903, present on the R-plasmid R6, in that it consists of a gene for aminoglycoside-phosphotransferase-3'-I (homologous to that of Tn903) flanked by copies of an IS-element homologous to IS903. Tn602 differs from Tn903 in the following respects: the flanking IS-elements (IS602) are in direct rather than inverted orientation as in Tn903; the fusion points between the IS-elements and the central region are different from those in Tn903; and several sequence changes, detected by the loss and acquisition of restriction sites, show the two repeats of IS602 to be nonidentical and different from IS903, IS102, and IS903.B. These structural details suggest that Tn602 and Tn903 evolved separately from related modules.

Identification of the Rts 1 DNA fragment responsible for temperature sensitive growth of host cells harboring a drug resistant factor Rts 1

We have placed a kanamycin resistance SalI fragment (3.65 Kb) from the drug resistance factor Rts1 into pUC19 and pBR322. These chimeric plasmids containing the kanamycin resistance fragment from Rts1 cause temperature sensitive growth in E coli. The orientation of the kanamycin resistance fragment in the vector plasmids does not influence this phenotype.

A pathway for the evolution of the plasmid NTP16 involving the novel kanamycin resistance transposon Tn4352

The kanamycin resistance determinant of the drug resistance plasmid NTP16 has been characterized by DNA sequencing and has been shown to possess all of the structural features of a transposable element. It is made up of a 1040-bp central region encoding a protein identical to the aminoglycoside 3'-phosphotransferase of Tn903, flanked by direct repeats of an element identical to IS26. This novel transposon has been designated Tn4352. Analysis of the host sequences flanking the transposon reveal that they are derived from a Tn3-like element, and contain no 8 base pair target size duplications which are normally created by the insertion of IS26-like elements. Comparison to the Tn3 sequence shows that the flanking sequences are noncontiguous within Tn3, with the clear implication that NTP16 has evolved from a similar plasmid encoding only ampicillin resistance (presumably NTP1) by the insertion of Tn4352 into the Tn3-like element, followed by a substantial deletion. The sequence analysis suggests that the initial insertion was into the tnpR gene of the ampicillin transposon, followed by a deletion extending to a specific site within tnpA.

Tn1721 derivatives for transposon mutagenesis, restriction mapping and nucleotide sequence analysis

New derivatives of the tetracycline-resistance transposon Tn1721 that carry resistances to chloramphenicol, tetracycline, kanamycin and streptomycin are described. These elements are provided on various plasmid vehicles and as chromosomal insertions to extend the range of targets for Tn mutagenesis. Single EcoRI sites at the ends of these transposons proved most useful for physical mapping, for the generation of new EcoRI sites in cloning experiments, for end-labelling and for sequencing of DNA adjacent to an insertion.

Gene organization and target specificity of the prokaryotic mobile genetic element IS26

The 820-bp mobile genetic element IS26 loses its ability to promote transpositional cointegration (1) by short deletions near the middle of the element causing shifts in both reading frames ORFI (left to right) and ORFII (right to left) and (2) by deletions causing substitutions of the C-terminus of ORFI but not affecting ORFII. The 702-bp ORFI is thus likely to code for the IS26 transposase. An 82-bp long sequence from the left end of IS26 contains a promoter-like structure in front of the start of ORFI at coordinate 64. In appropriately constructed plasmids, this sequence promotes the expression of the galK structural gene. The observation provides additional evidence for the functional relevance of ORFI. Neither the presence nor the absence of an intact IS26 element on the same plasmid affects measurably the degree of the galK gene expression by the IS26 promoter. Sequence comparison of 14 independent integration sites of IS26 and its relatives reveals no striking rules for target selection by the element, and the distrubtion of integration sites of IS26 on small multicopy plasmids is nearly random and independent of the local AT-content.

An active variant of the prokaryotic transposable element IS903 carries an amber stop codon in the middle of an open reading frame

The prokaryotic mobile genetic element IS903.B is an active variant of IS903. It differs from IS903 and IS102 by 34 and 61 nucleotide substitutions, respectively. The large open reading frame (ORFI) which probably encodes the transposase is conserved in all three IS elements, whereas the smaller open reading frame (ORFII), which codes on the opposite DNA strand and entirely overlaps ORFI, contains an amber stop codon past the middle of ORFII in IS903.B. Experiments using Escherichia coli K12 strains permissive or non-permissive for amber mutations revealed no difference in the cointegration frequency mediated by IS903.B. Therefore, a possible peptide encoded by ORFII on the IS903-related element is unlikely to be necessary for transposition.