Transposition of IS1-lambdaBIO-IS1 from a bacteriophage lambda derivative carrying the IS1-cat-IS1 transposon (Tn9)

A composite transposon 3' to the cow fetal globin gene binds a sequence specific factor

Two unusual sequence organizations were found within the beta-globin locus of the cow. Each was a composite, consisting of closely linked Alu-type repeats with a short stretch of genomic non-repetitive sequence, called a lagan, sandwiched between. One lagan was found 3' to the fetal globin gene, while the second lay between the adult globin gene and a globin pseudogene. Southern blot analysis indicated that both lagans appeared twice within the cow haploid genome, with the second copies lying outside the cow beta-globin locus. One of these non-globin locus homologues was cloned and subjected to sequence analysis. Comparison of the DNA sequence data showed that the lagan-Alu composite was transposed as a unit. The lagan 3' to the cow fetal globin gene contains the recognition site for a sequence specific DNA binding factor. This factor was present in extracts from fetal, but not from adult cow tissues.

Fusions of the Escherichia coli gyrA and gyrB control regions to the galactokinase gene are inducible by coumermycin treatment

We have previously shown that the genes encoding the two subunits of Escherichia coli DNA gyrase are regulated in a manner which is dependent on DNA conformation. When the DNA encoding the gyrA and gyrB genes is relaxed, both genes are expressed at a high level; in negatively supercoiled DNA they are expressed at a low level. In this paper we describe fusions of both the gyrA and gyrB 5' sequences to the E. coli galactokinase gene. In such fusions we found that galactokinase can be induced by treating the cells with coumermycin A1, an inhibitor of DNA gyrase. Our results suggest that the regulation occurs at the transcriptional level and that only a small region of DNA is necessary for coumermycin-induced gene expression.

DNA inversion mediated by the r-determinant of plasmid NR1: evidence for the intramolecular replicative transposition of a 23 kb IS1-flanked transposon?

The r-determinant (r-det) of the R plasmid NR1-Basel is a 23 kb, IS1-flanked transposon, called Tn2671, which has been shown to transpose to the genome of bacteriophage P7. Among the derivatives of phage P7::r-det we found one which carried two copies of the r-det as inverted repeats and which also contained the P7 genome segment between them in inverted orientation. Its generation is best explained by assuming that the entire 23 kb Tn2671 transposon has undergone intramolecular replicative transposition.

Evidence for replicative transposition of Tn5 and Tn9

Two basic types of models, conservative and replicative, have been proposed to account for the mechanism of transposition in bacteria. A method was developed to test these models by positive selection of various transposon-promoted events as galactose-resistant colonies from plasmid-containing cells. The results show that recA plays an important role in the transposition of Tn5 and Tn9 in Escherichia coli. All Tn5-promoted events (cointegrates, deletions and transpositions) are suppressed in recA-, and restored in recA+. In the case of Tn9, however, only transpositions (but not cointegrates or deletions) are diminished in recA-. Therefore, the recA function is required for cointegrate formation by Tn5, and for cointegrate resolution by Tn9. Both Tn5 and Tn9 cointegrates segregate transpositions (which can be seen as sectors on indicator plates) in recA+ hosts. In recA-, the unresolved Tn9 cointegrates undergo a second round of cointegrate formation to excise plasmids bearing galactose-resistant deletions. In growing cultures, the proportion of cointegrates declines steadily while transpositions increase so that, in late stages, cultures are rich in transpositions and contain few cointegrates. This explains the failure of previous workers to identify cointegrates as essential intermediates in transposition. Hence, with the exception of the recA requirement, the mechanism of transposition of these composite transposons is not very different from simple transposons like Tn3. It is concluded that transposition of Tn5 and Tn9 is normally a replicative process.

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.

Cointegrate formation mediated by Tn9. II. Activity of IS1 is modulated by external DNA sequences

We have studied the effect on the transposition activity of IS1 of the position and orientation of the element in the donor replicon. Previous studies have shown that the IS1s in the compound transposon Tn9 have different activities in forming plasmid cointegrates. In this study, designed to investigate the sources of this differential activity, we have cloned Tn9 (together with 132 base-pairs of flanking DNA) into several sites in pBR322 and created various derivatives of these plasmids to be used as donor molecules in plasmid fusion experiments. These pBR322-Tn9 plasmids were allowed to form cointegrates with a conjugative, F-derived plasmid, and a large collection of independently formed cointegrates was isolated. The relative activities of the two IS1 elements of Tn9 were estimated by examining the structures of the cointegrates for the frequency of usage of each of the IS1s in cointegrate formation. The results suggest that IS1 activity is modulated by the transcription activity of adjacent DNA sequences in the donor plasmids. Transcription directed into an IS1 inhibits its activity. Confirmatory evidence for this hypothesis is provided by the observation that deletion of adjacent promoters of transcription relieves the inhibitory effect on IS1 activity.

Detection of chemicals that stimulate Tn9 transposition in Escherichia coli K12

A spot test has been developed for detecting substances that enhance the transposition of Tn9 in Escherichia coli. Phage lambda::Tn9-infected cells were plated on chloramphenicol media and a drop of the test substance was placed at the center of the plate. Following incubation, chloramphenicol-resistant colonies appeared due to the transposition of Tn9 to the bacterial chromosome. By comparing the test plate and a control plate with respect to the number and distribution of colonies, the effect of the test compound can be evaluated. Out of over 100 compounds tested, acetate, two detergents (Brij 58 and Nonidet P40) and dimethylsulfoxide were found to enhance transposition 3-20 fold. Acetate was also found to enhance the transposition of Tn5 and Tn10. The stimulating effect of Brij 58 was lost when palmitic acid was added with the Brij 58. The nature of these substances, which we refer to as "transposagens", suggests an involvement of lipid or membrane in the transposition process.

Insertion of IS2 creates a novel ampC promoter in Escherichia coli

A class of ampC beta-lactamase-hyperproducing mutants of Escherichia coli were shown to have the insertion element IS2 inserted into the ampC promoter. The insertion of IS2 in orientation II created a novel promoter in which the -35 region and the 17 bp long spacing sequence between the two consensus sequences are present in IS2 DNA, whereas the -10 region from the original ampC promoter is retained. In vitro transcription revealed that the transcription initiation site in the ampC::IS2 mutants was identical with that of ampC wild-type promoter. The novel promoter exhibited a 20-fold increase in promoter strength relative to the original ampC promoter, presumably due to the increase in the spacing sequence from 16 to 17 bp. The evolution of transposable elements and of control elements such as promoters are discussed on the basis of the findings described herein.

Chloramphenicol acetyltransferase: enzymology and molecular biology

Naturally occurring chloramphenicol resistance in bacteria is normally due to the presence of the antibiotic inactivating enzyme chloramphenicol acetyltransferase (CAT) which catalyzes the acetyl-S-CoA-dependent acetylation of chloramphenicol at the 3-hydroxyl group. The product 3-acetoxy chloramphenicol does not bind to bacterial ribosomes and is not an inhibitor of peptidyltransferase. The synthesis of CAT is constitutive in E. coli and other Gram-negative bacteria which harbor plasmids bearing the structural gene for the enzyme, whereas Gram-positive bacteria such as staphylococci and streptococci synthesize CAT only in the presence of chloramphenicol and related compounds, especially those with the same stereochemistry of the parent compound and which lack antibiotic activity and a site of acetylation (3-deoxychloramphenicol). Studies of the primary structures of CAT variants suggest a marked degree of heterogeneity but conservation of amino acid sequence at and near the putative active site. All CAT variants are tetramers composed in each case of identical polypeptide subunits consisting of approximately 220 amino acids. The catalytic mechanism does not appear to involve an acyl-enzyme intermediate although one or more cysteine residues are protected from thiol reeagents by substrates. A highly reactive histidine residue has been implicated in the catalytic mechanism.

Factors determining frequency of plasmid cointegration mediated by insertion sequence IS1

We demonstrate that mutants with deletions at either end of the insertion sequence IS1 lose the ability to mediate cointegration of two plasmids, whereas mutants with deletions or an insertion within IS1 can mediate cointegration at a reduced frequency. These results, together with the nucleotide sequence analysis of the IS1 mutants, indicate that the two ends of IS1 (insL and insR) and two genes (insA and insB) that are encoded by IS1 are required for cointegration. Using a plasmid carrying two copies of IS1, we found that the individual IS1s mediate cointegration at different characteristic frequencies, and that each of two parts of plasmid DNA segments flanked by the two IS1s is a transposon, mediating plasmid cointegration at a unique frequency. When one IS1 was replaced with a mutant IS1, the remaining wild-type IS1 complemented the cointegration ability of the mutant IS1 as well as a resulting mutant transposon that was then flanked by a wild-type IS1 and a mutant IS1. The efficiency of this complementation reflected the characteristic ability of an individual IS1 present on the plasmid to promote cointegration. The results suggest that the IS1-encoded proteins are produced in different amounts, depending on the location of IS1 in the plasmid, and that these amounts determine the efficiency of complementation of the cointegration ability of a mutant IS1 as well as a mutant transposon. However, the location of an individual IS1 itself can also determine the frequency of cointegration in the presence of a given amount of the IS1 proteins. On the basis of the observation that the cointegration ability of a mutant IS1 is less efficiently complemented than is the ability of a mutant transposon, we also suggest that the IS1-encoded proteins can function in trans, but act preferentially on the IS1 or transposon sequence from which they are produced in promoting cointegration.

Mapping of IS1 elements flanking the argF gene region on the Escherichia coli K-12 chromosome

Two directly-repeated IS1 elements have been mapped on the Escherichia coli K-12 chromosome at positions 23.2 kb and 34.5 kb counterclockwise of the IS3 element alpha3beta3 by using F-prime plasmids (including the F lac- proAB+ plasmid F128) that carry different portions of the bacterial chromosome in the purE to proA region. Mapping was accomplished in part by construction of EcoRI, BamHI, and BglII restriction enzyme cleavage maps. Electron microscope heteroduplex and hybridization studies indicate that the chromosomal region flanked by these IS1 elements is completely homologous to the IS1-argF-IS1 region (Tn2901) on the P1argF5 transducing phage (York and Stodolsky, 1981), which suggests that the argF gene region in the usual E. coli K-12 strains has a transposon-like structure.

Characterization of P1argF derivatives from Escherichia coli K12 transduction. I. IS1 elements flank the argF gene segment

Specialized transducing derivatives of the temperate bacteriophage P1 (P1std) are selected by transduction into recipients with deletions in the corresponding genes (Stodolsky 1973). When Escherichia coli K12 strains are used as donors in such transduction experiments, P1argF derivatives can be selected. The argF gene is unique to these strains (Glansdorff et al. 1967). Under these experimental conditions P1argF are formed with frequencies 10,000 times greater than other P1std. The majority of the P1argF derivatives that have been analyzed are indistinguishable by cleavage analyses. One such derivative, P1argF5 has been characterized in detail. Heteroduplex analysis against P1, P7, and P1CmO identified an 11 kb insertion of DNA precisely at the naturally occurring IS1 locus of P1. Cleavage analysis with EcoRI, BamHI and PstI confirmed this finding. To further define the argF insertion, a P1Cm13argF derivative was constructed having the IS1 sequences of Cm13 and argF in opposite orientation. Intrastrand annealing of P1Cm13argF5 DNA established that the argF segment is flanked by directly repeated IS1 sequences. The IS1-argF-IS1 segment is designated Tn2901. The assignment of the map position of the argF gene within the 11 kb insert of P1argF5 is discussed. The evolutionary significance of this finding and a model for P1argF formation is also presented.

Terminal repeats of the Drosophila transposable element copia: nucleotide sequence and genomic organization

We have determined the nucleotide sequence of the terminal regions of two members of the copia sequence family of D. melanogaster. The first 276 bp at one end of a copia element are repeated in direct orientation at its other end. The direct repeats on a single copia element are identical to each other, but they differ by two nucleotide substitutions between the two elements which were examined; this suggests that during transposition only one direct repeat of the parent element is used as a template for both direct repeats of the transposed element. Each direct repeat itself contain a 17 bp imperfectly matched inveted terminal repetition. The ends of copia show significant sequence homology both to the yeast Ty1 element and to the integrated provirus of avian spleen necrosis virus, two other eucaryotic elements known to insert at many different chromosomal locations. Analysis of the genomic organization of the direct repeat sequence demonstrates that it seldom, if ever, occurs unlinked to an entire copia element.