Electron microscope heteroduplex studies of sequence relations among bacterial plasmids: identification and mapping of the insertion sequences IS1 and IS2 in F and R plasmids.

Heteroduplex experiments between the plasmid R6 and one strand of the deoxyribonucleic acid (DNA) of a lambda phage carrying the insertion sequence IS1 show that IS1 occurs on R6 at the two previously mapped junctions of resistance transfer factor (RTF) DNA with R-determinant DNA. From previous heteroduplex experiments, it then follows that IS1 occurs at the same junctions in R6-5, R100-1, and R1 plasmids. Heteroduplex experiments with the DNA from a lambda phage carrying the insertion sequence IS2 show that one copy of IS2 occurs in R6, R6-5, and R100-1 (but not R1) at a point within the RTF with coordinates 67.5 TO 68.9 kilobase units (kb). In an accompanying paper, Ptashne and Cohen (1975) show that the insertion sequence IS3 occurs on R6 and R6-5. R100-25, a traC mutant, differs from its parent R100-1 only in that it contains an additional copy of IS1 inserted within the tra gene region of 82.1 kb. R100-31, atraX, TC-s mutant of R100-1, is deleted in R100-1 sequences starting at one of the IS3 termini (46.9 kb) and extending with RTF to 61.0 kb. Heteroduplex studies of F plasmids with the DNA of a lambda phage bearing insertion sequence IS2 show that the sequence of F with coordinates 16.3-17.6F is IS2. The occurrence of IS1 at the two junctions of R-determinant DNA and RTF DNA in R plasmids provides a structural basis to explain the mechanism of the previously observed formation of molecules containing one RTF unit and several tandem copies of the R-determinant unit, when R plasmids in Proteus mirabilis are grown in the presence of antibiotics, and the segregation of an R plasmid into an RTF unit and an R-determinant unit. In general, correlation of our results with previous studies shows that insertion sequences play a role in a variety of F- and R-related intra- and intermolecular recombination phenomena.     

Occurrence of insertion sequence (IS) regions on plasmid deoxyribonucleic acid as direct and inverted nucleotide sequence duplications.

Insertion sequence (IS) regions have been identified previously as a cause of strongly polar mutations in Escherichia coli and several bacteriophages. The present experiments indicate that genetically characterized IS regions occur on bacterial plasmid deoxyribonucleic acid (DNA) as both direct and inverted DNA sequence duplications. The DNA insertion which has been shown previously (Sharp et al., 1973) to control expression of tetracycline resistance in the R6-5 plasmid, and which occurs as directly and inversely repeated DNA sequences adjacent to the region believed to contain the tetracycline resistance gene, has been identified as IS3. A second genetically characterized insertion sequence (IS1) has been identified as a direct DNA duplication occurring at both junctions of the resistance transfer factor and R-determinant components of R6-5 and related plasmids. A model is presented for the reversible dissociation of resistance transfer factor and R-determinant components of co-integrate R plasmids at the sites of DNA sequence homology provided by the repeated IS regions.     

Heteroduplex electron microscopy of phage Mu mutants containing IS1 insertions and chloramphenicol resistance transposons.

We have examined by electron microscopy the DNA heteroduplexes of six bacteriophage Mu mutants, Mu X cam, generated by the insertion of the Tn9 transposon for chloramphenicol resistance. Tn9 was found to be 2.8 +/- 0.2 kilobases (kb) in length and to consist of a cam determinant flanked by two IS1 sequences arranged in a direct order. In two of the six Mu X cam mutants, the Tn9 insertion was at a fixed location, 3.9 kb from the left, or c, end. In the other four mutants, the position of the insertion varied, even though the lysogenic cultures induced were grown from single colonies. The insertion was located at either 3.3 kb, 3.9 kb, or, less frequently, at 4.4 kb from the left end of the DNA. Furthermore, at low frequencies, the insertions were found to be in an orientation opposite to what predominated in the preparation. Thus, Tn9 in the Mu X cam mutants examined could appear to undergo rapid rearrangements during Mu growth or over a few generations of cell growth. One of the Tn9 insertion sites was apparently the same as that for a 0.8 kb insertion found in a Mu X mutant. This latter insertion was identified as an IS1 sequence. The DNA molecules from all the Mu X cam mutant phage particles were found to be missing the bacterial DNA at the S (right) end, along with a variable amount of the adjoining Mu DNA in the beta region. This observation supports the headful packaging model for Mu DNA.     

Sequence arrangements of the Escherichia coli chromosome and of putative insertion sequences, as revealed by electron microscopic heteroduplex studies.

Total Escherichia coli DNA from strain DK445 (which is CSH50 F^?, R^?, deletion lac and pro, lysogenized with lambda cIts857 Sam7 lac5: :Mu cI⁺) was denatured, reannealed, and observed by electron microscopy. The single-strand DNA lengths ranged from about 50 to 150 kilobases (kb). In some molecules a short duplex region with a single-stranded fork at each end was observed. The duplex lengths were 0.75 kb, 1.30 kb, 5.22 kb, 5.62 kb, which correspond to those of IS1; of IS2, IS3, or IS4; of the ribosomal RNA genes; and of the γδ sequence, respectively. Duplexes of 1.0 kb and 0.5 kb were also found. Most of the duplexes of 0.5, 0.75, 1.0 and 1.3 kb were observed as intramolecular stem-loop structures and were therefore interpreted to be sequence duplications in inverted order on the same DNA strand. The most frequent separations of the putative inverted insertion sequences were around 22 and 27.5 ± 1.5 kb. About 14% of the E. coli chromosome is estimated to be involved in the sequence arrangements that give rise to stem-loop structures upon denaturation and reannealing. The copy numbers of the putative insertion sequences and other elements that form the “stems” of the stem-loop structures are also estimated.     

Insertion sequence-based cassette PCR: cultivation-independent isolation of γ-hexachlorocyclohexane-degrading genes from soil DNA

gamma-Hexachlorocyclohexane (gamma-HCH) is a highly chlorinated pesticide that has caused serious environmental problems. Based on the frequently observed association of insertion sequence IS6100 with lin genes for gamma-HCH degradation in several gamma-HCH-degrading bacterial strains isolated to date, DNA fragments flanked by two copies of IS6100 were amplified by nested polymerase chain reaction (PCR) technique using a DNA sample extracted from soil contaminated with HCH. Four distinct DNA fragments with sizes of 6.6, 2.6, 1.6, and 1.3 kb were obtained, three of which carried lin genes: the 6.6-kb fragment carried linD and linE as well as linR; the 2.6-kb fragment showed a truncated form of linF; and the 1.6-kb fragment carried linB. Our approach, named as insertion sequence (IS)-based cassette PCR, was successful in the isolation of the lin genes from HCH-contaminated soil without cultivation of host cells and is applicable for the culture-independent isolation of other functional genes bordered by other IS elements.     

Transposition of IS10 from the host Escherichia coli genome to a plasmid may lead to cloning artefacts

During recloning of Nicotiana tabacum L. repetitive sequence R8.3 in Escherichia coli, a modified clone that differed from the original by the insertion of an IS10 sequence was unintentionally produced. The insert was flanked by a 9-bp direct repeat derived from the R8.3 sequence, the 9-bp duplication of acceptor DNA in the site of insertion being a characteristic of IS10 transposition events. A database search using the FASTA program showed IS10 and other prokaryotic IS elements inserted into numerous eukaryotic clones. Unexpectedly, the IS10, which is not a natural component of the E. coli genome, appeared to be by far the most frequent contaminant of DNA databases among several IS sequences tested. In the GenEMBL database, the IS10 query sequence yielded positive scores with more than 500 eukaryotic clones. Insertions of shortened IS10 sequences having only one intact terminal inverted repeat were commonly found. Most full-length IS10 insertions (32 out of 40 analyzed) were flanked by 9-bp direct repeats having the consensus 5'-NPuCNN-NGPyN-3' with a strong preference for 5'-TGCTNA-GNN-3'. One insertion was flanked by an inverted repeat of more than 400 bp in length. PCR amplification and Southern analysis revealed the presence of IS10 sequences in E. coli strains commonly used for DNA cloning, including some reported to be Tn10-free. No IS10-specific PCR product was obtained with N. tabacum or human DNA. Our data suggest that transposition of IS10 elements may accompany cloning steps, particularly into large BAC vectors. This might lead to the relatively frequent contamination of DNA databases by this bacterial sequence. It is estimated that one in approximately every thousand eukaryotic clone in the databases is contaminated by IS-derived sequences. We recommend checking submitted sequences for the presence of IS10 and other IS elements. In addition, DNA databases should be corrected by removing contaminating IS sequences.     

Further mapping of IS2 and IS3 in the lac-purE region of the Escherichia coli K-12 genome: structure of the F-prime ORF203.

The sequence organization of the F-prime ORF203 was determined by heteroduplex analysis. This large, type II F-prime (Scaife, 1967) contains lac, proC, and purE genes derived from the W1485 subline of Escherichia coli K-12. The IS3 and IS2 elements previously found in the lac-proC-purE region derived from the 58-161 subline (Hu et al., 1975) are also present in the same locations in the bacterial deoxyribonucleic acid (DNA) from the W1485 subline. Recombination between the IS2 region of F and an IS2 element located between lac and proC on the bacterial DNA apparently led to the formation of the perental Hfr, OR21. IS2 is thus directly repeated, with one copy of each element appearing at each of the two junctions between F and the bacterial sequences on ORF203. The F plasmid is found together with ORF203 in the plasmid DNA, and this probably forms from ORF203 by recombination between the directly repeated IS2 elements. ORF203 appears to have been excised from the Hfr chromosome by recombination between the IS3 sequence alpha3beta3 located counterclockwise of lac and the directly repeated IS3 sequence alpha4beta4 located clockwise of purE.     

Isolation and analysis of IS6120, a new insertion sequence from Mycobacterium smegmatis

Insertion sequence IS6120 from Mycobacterium smegmatis was identified by its ability to transpose into different sites in the lambda repressor gene, cl857, carried on an Escherichia coli/mycobacteria shuttle plasmid. IS6120 is a novel 1.5 kb insertion sequence, which has 24-bp imperfect terminal inverted repeats and generates 9-bp duplications of the target DNA following insertion. IS6120 is present in at least three copies in M. smegmatis but was not found in other species, including Mycobacterium tuberculosis. Nucleotide sequence analysis revealed that IS6120 contains two open reading frames, one of which encodes a putative transposase with similarities to those found in IS256 from Staphylococcus aureus, IST2 from Thiobacillus ferrooxidans, and ISRm3 from Rhizobium meliloti. The fact that IS6120 does not recognize a consensus target sequence for insertion and has no homologous sequences in the other strains studied makes IS6120 useful for transposon mutagenesis in mycobacteria.     

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.     

Deoxyribonucleic Acid Sequence Homologies Among Bacterial Insertion Sequence Elements and Genomes of Various Organisms

Plasmid and phage deoxyribonucleic acid (DNA) harboring bacterial insertion sequence (IS) elements IS1, IS2, and IS5 were characterized and used as probes to detect homologous sequences in various procaryotic and eucaryotic genomes. The hybridization method used permits the detection of sequences partially homologous to the elements. Hybridization of the IS-containing probes to each other revealed a region of limited homology between IS1 and IS2. Homologous sequences were then detected by computer analysis of the published IS1 and IS2 nucleotide sequences. The homologous sequence contains a tandemly repeated tetranucleotide sequence which resembles the repeated sequence at the hot spot for spontaneous mutations in the lacI gene (P. J. Farabaugh, U. Schmeissner, M. Hofer, and J. Miller, J. Mol. Biol. 126:847-863, 1978). Homology between the IS elements and various genomes was determined by hybridizing labeled DNA containing IS1, IS2, and IS5 sequences to Southern blots of chromosomal DNA cleaved with restriction endonucleases. IS1 and IS5 appear limited to the enteric bacteria, whereas IS2 sequences can also be detected in Pseudomonas putida, Pseudomonas aeruginosa, and Serratia marcescens. Bacteria which appear not to possess extrachromosomal elements, e.g., Caulobacter crescentus, did not show homology with any insertion sequences tested. In addition, sequences homologous to IS1, IS2, or IS5 were not detected in Saccharomyces cerevisiae, Dictyostelium discoideum, or calf thymus DNA.     

Host processing of branched DNA intermediates is involved in targeted transposition of IS911

A simplified system using bacterial insertion sequence IS911 has been developed to investigate targeted insertion next to DNA sequences resembling IS ends. We show here that these IR-targeted events occur by an unusual mechanism. In the circular IS911 transposition intermediate the two IRs are abutted to form an IR/IR junction. IR-targeted insertion involves transfer of a single end of the junction to the target IR to generate a branched DNA structure. The single-end transfer (SET) intermediate, but not the final insertion product, can be detected in an in vitro reaction. SET intermediates must be processed by the bacterial host to obtain the final insertion products. Sequence analysis of these IR-targeted insertion products and of those obtained in vivo revealed high levels of DNA sequence conversion in which mutations from one IR were transferred to another. These sequence changes cannot be explained by the classic transposition pathway. A model is presented in which the four-way Holliday-like junction created by SET is processed by host-mediated branch migration, resolution, repair and replication. This pathway resembles those described for processing other branched DNA structures such as stalled replication forks.     

Sequence analysis and distribution of an IS3-like insertion element isolated from Salmonella enteritidis

The nucleotide sequence of a 3 kb region immediately upstream of the sef operon of Salmonella enteritidis was determined. A 1230 base pair insertion sequence which shared sequence identity (>75%) with members of the IS3 family was revealed. This element, designated IS1230, had almost identical (90% identity) terminal inverted repeats to Escherichia coli IS3 but unlike other IS3-like sequences lacked the two characteristic open reading frames which encode the putative transposase. S. enteritidis possessed only one copy of this insertion sequence although Southern hybridisation analysis of restriction digests of genomic DNA revealed another fragment located in a region different from the sef operon which hybridised weakly which suggested the presence of an IS1230 homologue. The distribution of IS1230 and IS1230-like elements was shown to be widespread amongst salmonellas and the patterns of restriction fragments which hybridised differed significantly between Salmonella serotypes and it is suggested that IS1230 has potential for development as a differential diagnostic tool.     

Characterization of an insertion sequence (IS891) of novel structure from the cyanobacterium Anabaena sp. strain M-131.

When recombinant plasmids that were transferred to the cyanobacterium Anabaena sp. strain M-131 were transferred back to Escherichia coli, some of the transformants contained inserts. One of the insertion sequences (ISs) was characterized by sequencing. This 1,351-base-pair IS contained an open reading frame that was capable of encoding a peptide of 310 amino acids and had terminal sequences with distinctive structures, but it lacked terminal inverted repeats and did not duplicate target DNA upon insertion. The element bore no significant sequence homology to any sequence stored in the GenBank data base. Restriction analysis of the genomes of Anabaena sp. strain M-131 and Anabaena sp. strain PCC 7120 showed those strains to be closely related. Sequences homologous to the IS element were also present in the DNA of Anabaena strain PCC 7120, but the copy numbers and chromosomal locations of such sequences differed in the two strains. The largest visualized plasmid was 425 kilobases (kb) in M-131 and 410 kb in PCC 7120; at least the former plasmid contained multiple copies of the element, as did a 115-kb plasmid in M-131.     

A survey of bacterial insertion sequences using IScan

Bacterial insertion sequences (ISs) are the simplest kinds of bacterial mobile DNA. Evolutionary studies need consistent IS annotation across many different genomes. We have developed an open-source software package, IScan, to identify bacterial ISs and their sequence elements—inverted and target direct repeats—in multiple genomes using multiple flexible search parameters. We applied IScan to 438 completely sequenced bacterial genomes and 20 IS families. The resulting data show that ISs within a genome are extremely similar, with a mean synonymous divergence of K_s = 0.033. Our analysis substantially extends previously available information, and suggests that most ISs have entered bacterial genomes recently. By implication, their population persistence may depend on horizontal transfer. We also used IScan's ability to analyze the statistical significance of sequence similarity among many IS inverted repeats. Although the inverted repeats of insertion sequences are evolutionarily highly flexible parts of ISs, we show that this ability can be used to enrich a dataset for ISs that are likely to be functional. Applied to the thousands of genomes that will soon be available, IScan could be used for many purposes, such as mapping the evolutionary history and horizontal transfer patterns of different ISs.     

Comparative analysis of 18 sex pheromone plasmids fromEnterococcus faecalis: detection of a new insertion element on pPD1 and implications for the evolution of this plasmid family

A new IS element, IS1062, related to the enterococcal IS elements IS6770 and IS1252, was detected in the 3′-terminus of the surface exclusion gene,sep1, of sex pheromone plasmid pPD1 inEnterococcus faecalis. pPD1-bearing cells lack the surface exclusion function, probably as a consequence of this insertion. Analysis of pAD1 and pPD1 sequences (7.5 kb and 2.7 kb, respectively) downstream of their aggregation substance genes revealed no similarity in these DNA regions. Detailed DNA/DNA hybridization studies using DNA probes specific for various pAD1-encoded genes needed for plasmid transfer indicated that the sex pheromone plasmids have evolved by repeated recombination and insertion of diverse transposable elements which presumably account for recent acquisition of antibiotic resistances.     

Isolation and characterization of IS elements repeated in the bacterial chromosome

Shigella sonnei contains repetitive sequences, including an insertion element IS1, which can be isolated as double-stranded DNA fragments by DNA denaturation and renaturation and by treatment with S1 nuclease. In this paper, we describe a method of cloning the IS1 fragments prepared by the S1 nuclease digestion technique into phage M13mp8 RFI DNA. Several clones contained IS1, usually with a few additional bases. We isolated and characterized five other repetitive sequences using this method. One sequence, 1264 base-pairs in length, had terminal inverted repeats and contained two open reading frames. This sequence, called IS600, showed about 44% sequence homology with IS3 and was repeated more than 20 times in the Sh. sonnei chromosome. Another sequence (named IS629, 1310 base-pairs in length), which was repeated six times, was found also to be related to IS3 and thus IS600. Two other sequences (named IS630 and IS640, 1159 and 1092 base-pairs in length, respectively), which were repeated approximately ten times, had characteristic terminal inverted repeats and contained a large open reading frame coding for a protein. The inverted repeat sequences of IS630 were similar to the sequence at one end of IS200, a Salmonella-specific IS element. The fifth sequence, repeated ten times in Sh. sonnei, had about 98% sequence homology with a portion of IS2. The method described here can be applied to the isolation of IS or iso-IS elements present in any other bacterial chromosome.     

A new insertion sequence, IS231M, in an autoagglutinable isolate of Bacillus thuringiensis

An insertion sequence was isolated from an autoagglutinable strain of Bacillus thuringiensis. Analysis of its DNA sequence revealed high homology to the IS231 family. The name IS231M is proposed for this new insertion sequence. IS231M is 1652 bp long and is delimited by two imperfect 20-bp inverted repeat sequences with two mismatches, which are flanked by two perfect 11-bp direct repeats (DRs). The region upstream of the open reading frame, presumed to be able to form a stable hairpin structure, is particularly well conserved in IS231M. Based on primary nucleotide sequences, IS231M is most homologous to IS231F and IS231G and most distant from IS231V and IS231W. However, as opposed to the single transposase A ORF found in IS231A, -B, -C, -D, -F, and -G, IS231M has two overlapping open reading frames, ORF1 and ORF2, that could code for polypeptides of 334 and 143 amino acids, respectively. Whether IS231M is a functional transposable element remains to be determined.     

IS911 partial transposition products and their processing by the Escherichia coli RecG helicase

Insertion of bacterial insertion sequence IS911 can often be directed to sequences resembling its ends. We have investigated this type of transposition and shown that it can occur via cleavage of a single end and its targeted transfer next to another end. The single end transfer (SET) events generate branched DNA molecules that contain a nicked Holliday junction and can be considered as partial transposition products. Our results indicate that these can be processed by the Escherichia coli host independently of IS911-encoded proteins. Such resolution depends on the presence of homologous DNA regions neighbouring the cross-over point in the SET molecule. Processing is often accompanied by sequence conversion between donor and target sequences, suggesting that branch migration is involved. We show that resolution is greatly reduced in a recG host. Thus, the branched DNA-specific helicase, RecG, involved in processing of potentially lethal DNA structures such as stalled replication forks, also intervenes in the resolution of partial IS911 transposition products.     

Insertion-sequence-dependent rearrangements of Pseudomonas cepacia plasmid pTGL1.

Pseudomonas cepacia 249 (ATCC 17616) harbors a 170-kilobase (kb) plasmid designated pTGL1. We identified three insertion sequences, IS405, IS408, and IS411, on this plasmid. Various prototrophic and auxotrophic derivatives in our collection contained variants of pTGL1 formed by accretion and deletion of other elements. Plasmid pTGL6, the variant in one prototroph, evolved from pTGL1 by the addition of three copies of IS401 (1.3 kb) and one of IS402 (1 kb), to generate pTGL5, and recombination between two of the copies of IS401 on pTGL5 to form pTGL6. The latter event entailed loss of one copy of IS401 and an additional 5.4 kb of plasmid DNA. Derivatives of the broad-host-range plasmid pRP1 carrying the above insertion sequences and recombinant plasmids carrying fragments of plasmids pTGL6 and pTGL5 were used as probes to ascertain the extent of reiteration of the various elements in the P. cepacia genome. The data indicate a high frequency of genomic rearrangements which presumably contributes to the extraordinary adaptability of this bacterium.