Rearrangements of genetic material in Escherichia coli as observed on the bacteriophage P1 plasmid

Everyman's Guide to Bacterial Insertion Sequences

The number and diversity of known prokaryotic insertion sequences (IS) have increased enormously since their discovery in the late 1960s. At present the sequences of more than 4000 different IS have been deposited in the specialized ISfinder database. Over time it has become increasingly apparent that they are important actors in the evolution of their host genomes and are involved in sequestering, transmitting, mutating and activating genes, and in the rearrangement of both plasmids and chromosomes. This review presents an overview of our current understanding of these transposable elements (TE), their organization and their transposition mechanism as well as their distribution and genomic impact. In spite of their diversity, they share only a very limited number of transposition mechanisms which we outline here. Prokaryotic IS are but one example of a variety of diverse TE which are being revealed due to the advent of extensive genome sequencing projects. A major conclusion from sequence comparisons of various TE is that frontiers between the different types are becoming less clear. We detail these receding frontiers between different IS-related TE. Several, more specialized chapters in this volume include additional detailed information concerning a number of these.

In a second section of the review, we provide a detailed description of the expanding variety of IS, which we have divided into families for convenience. Our perception of these families continues to evolve and families emerge regularly as more IS are identified. This section is designed as an aid and a source of information for consultation by interested specialist readers.

Lack of hotspot targets: a constraint for IS30 transposition in Salmonella

IS30 is an insertion element common in E. coli strains but rare or absent in Salmonella. Transfer of the IS30-flanked transposon Tn2700 to Salmonella typhimurium was assayed using standard delivery procedures of bacterial genetics (conjugation and transduction). Tn2700 'hops' were rare and required transposase overproduction, suggesting the existence of host constraints for IS30 activity. Sequencing of three Tn2700 insertions in the genome of S. typhimurium revealed that the transposon had been inserted into sites with a low homology to the IS30 consensus target, suggesting that inefficient Tn2700 transposition to the Salmonella genome might be caused by a lack of hotspot targets. This view was confirmed by the introduction of an IS30 'hot target sequence', whose sole presence permitted Tn2700 transposition without transposase overproduction. Detection of IS30-induced DNA rearrangements in S. typhimurium provided further evidence that the element undergoes similar activities in E. coli and S. typhimurium. Thus, hotspot absence may be the main (if not the only) limitation for IS30 activity in the latter species. If these observations faithfully reproduce the scenario of natural populations, establishment of IS30 in the Salmonella genome may have been prevented by a lack of DNA sequences closely related to the unusually long (24 bp) IS30 consensus target.

Relation of the slow growth phenotype to neoplastic transformation: possible significance for human cancer

Deletions are widely distributed over the genome in the most frequently occurring human cancers and are the most abundant genetic lesion found there. Deletions are highly correlated with the slow growth phenotype of mutated animal and human cells and result in chromosomal transposition when the retained ends are joined. Transpositions are only a minor source of mutation in rapidly multiplying bacteria but are a major cause of mutations in stationary bacteria. The NIH 3T3 line of mouse cells undergoes neoplastic transformation during prolonged incubation in a stationary state and expresses the slow growth phenotype on serial subculture at low density, suggesting a relation between transformation and chromosomal deletions. To further explore the relation between neoplastic transformation and the slow growth phenotype as a surrogate for deletions, two sublines of the NIH 3T3 cells with differing competence for transformation were serially subcultured in the stationary state at confluence and tested at each subculture for transformation and growth rate. Cell death in a fraction of the population and a heritable slowdown in proliferation of most of the survivors became increasingly pronounced with successive rounds of confluence. The reduction in growth rate was not proportional to the degree of transformation of the cultures, but all of the transformed cultures were slow growers at low density. All of the discrete colonies from cloning transformed cultures developed at a lower initial rate than control colonies under optimal conditions for growth, but they continued to grow at later stages, forming multilayered colonies under conditions that inhibited the further growth of the control colonies. The results suggest that prolonged incubation of NIH 3T3 cells in the stationary state results in growth-impairing deletions over a wide range of sites in the genome, but more restricted subsets of such lesions are responsible for neoplastic transformation. These findings provide dynamic, functional support in culture for the histopathological evidence that the quiescent state of cells associated with atrophy and fibrosis plays a significant role in the origin of some cancers in experimental animals and human beings.

The cellular ecology of progressive neoplastic transformation: a clonal analysis

A comparison was made of the competence for neoplastic transformation in three different sublines of NIH 3T3 cells and multiple clonal derivatives of each. Over 90% of the neoplastic foci produced by an uncloned transformed (t-SA') subline on a confluent background of nontransformed cells were of the dense, multilayered type, but about half of the t-SA' clones produced only light foci in assays without background. This asymmetry apparently arose from the failure of the light focus formers to register on a background of nontransformed cells. Comparison was made of the capacity for confluence-mediated transformation between uncloned parental cultures and their clonal derivatives by using two nontransformed sublines, one of which was highly sensitive and the other relatively refractory to confluence-mediated transformation. Transformation was more frequent in the clones than in the uncloned parental cultures for both sublines. This was dramatically so in the refractory subline, where the uncloned culture showed no overt sign of transformation in serially repeated assays but increasing numbers of its clones exhibited progressive transformation. The reason for the greater susceptibility of the pure clones is apparently the suppression of transformation among the diverse membership that makes up the uncloned parental culture. Progressive selection toward increasing degrees of transformation in confluent cultures plays a major role in the development of dense focus formers, but direct induction by the constraint of confluence may contribute by heritably damaging cells. In view of our finding of increased susceptibility to transformation in clonal versus uncloned populations, expansion of some clones at the expense of others during the aging process would contribute to the marked increase of cancer with age.

Accessory genes in the darA operon of bacteriophage P1 affect antirestriction function, generalized transduction, head morphogenesis, and host cell lysis

Bacteriophage P1 mutants with the 8.86-kb region between the invertible C-segment and the residential IS1 element deleted from their genome are still able to grow vegetatively and to lysogenize stably, but they show several phenotypic changes. These include the formation of minute plaques due to delayed cell lysis, the abundant production of small-headed particles, a lack of specific internal head proteins, sensitivity to type I host restriction systems, and altered properties to mediate generalized transduction. In the wild-type P1 genome, the accessory genes encoding the functions responsible for these characters are localized in the darA operon that is transcribed late during phage production. We determined the relevant DNA sequence that is located between the C-segment and the IS1 element and contains the cin gene for C-inversion and the accessory genes in the darA operon. The darA operon carries eight open reading frames that could encode polypeptides containing >100 amino acids. Genetic studies indicate that some of these open reading frames, in particular those residing in the 5' part of the darA operon, are responsible for the phenotypic traits identified. The study may contribute to a better comprehension of phage morphogenesis, of the mobilization of host DNA into phage particles mediating generalized transduction, of the defense against type I restriction systems, and of the control of host lysis.

Insertion sequences

Insertion sequences (ISs) constitute an important component of most bacterial genomes. Over 500 individual ISs have been described in the literature to date, and many more are being discovered in the ongoing prokaryotic and eukaryotic genome-sequencing projects. The last 10 years have also seen some striking advances in our understanding of the transposition process itself. Not least of these has been the development of various in vitro transposition systems for both prokaryotic and eukaryotic elements and, for several of these, a detailed understanding of the transposition process at the chemical level. This review presents a general overview of the organization and function of insertion sequences of eubacterial, archaebacterial, and eukaryotic origins with particular emphasis on bacterial elements and on different aspects of the transposition mechanism. It also attempts to provide a framework for classification of these elements by assigning them to various families or groups. A total of 443 members of the collection have been grouped in 17 families based on combinations of the following criteria: (i) similarities in genetic organization (arrangement of open reading frames); (ii) marked identities or similarities in the enzymes which mediate the transposition reactions, the recombinases/transposases (Tpases); (iii) similar features of their ends (terminal IRs); and (iv) fate of the nucleotide sequence of their target sites (generation of a direct target duplication of determined length). A brief description of the mechanism(s) involved in the mobility of individual ISs in each family and of the structure-function relationships of the individual Tpases is included where available.

Conserved structure of IS200 elements in Salmonella

Sequence analysis of three IS200 elements (two from Salmonella typhimurium, one from Salmonella abortusovis) reveals a highly conserved structure, with a length of 707-708 bp and absence of terminal repeats. IS200 contains an open-reading-frame (ORF) which potentially encodes a peptide of 151 amino acids, with a putative ribosome-binding-site properly placed upstream of the ORF. A potential RNA stem-loop structure that might occlude the ribosome-binding-site of the ORF is also found. Another conserved trait is a potential RNA hairpin which resembles a Rho-independent transcription terminator, located near one end of IS200. The junctions between IS200 and host DNA sequences are A+T-rich. Upon insertion, IS200 duplicates 1-2 bp of host DNA sequences. The observation that IS200 elements characterized as 'hops' are roughly identical to those residing in the Salmonella genome suggests that IS200 transposition is unlikely to generate inactive copies. If such is the case and many or all IS200 elements are active, the extremely low frequency of IS200 transposition may reflect the normal behavior of the element.

Regulation of bacteriophage Mu transposition

Bacteriophage Mu is a transposon and a temperate phage which has become a paradigm for the study of the molecular mechanism of transposition. As a prophage, Mu has also been used to study some aspects of the influence of the host cell growth phase on the regulation of transposition. Through the years several host proteins have been identified which play a key role in the replication of the Mu genome by successive rounds of replicative transposition as well as in the maintenance of the repressed prophage state. In this review we have attempted to summarize all these findings with the purpose of emphasizing the benefit the virus and the host cell can gain from those phage-host interactions.

Adaptive mutation: the uses of adversity

When populations of microorganisms are subjected to certain nonlethal selections, useful mutants arise among the nongrowing cells whereas useless mutants do not. This phenomenon, known as adaptive, directed, or selection-induced mutation, challenges the long-held belief that mutations only arise at random and without regard for utility. In recent years a growing number of studies have examined adaptive mutation in both bacteria and yeast. Although conflicts and controversies remain, the weight of the evidence indicates that adaptive mutation cannot be explained by trivial artifacts and that nondividing cells accumulate mutations in the absence of genomic replication. Because this process tends to produce only useful mutations, the cells appear to have a mechanism for preventing useless genetic changes from occurring or for eliminating them after they occur. The model that most readily explains the evidence is that cells under stress produce genetic variants continuously and at random, but these variants are immortalized as mutations only if they allow the cell to grow.

Elements in microbial evolution

Spontaneous mutation, selection, and isolation are key elements in biological evolution. Molecular genetic approaches reveal a multitude of different mechanisms by which spontaneous mutants arise. Many of these mechanisms depend on enzymes, which often do not act fully at random on the DNA, although a large number of sites of action can be observed. Of particular interest in this respect are DNA rearrangement processes, e.g., by transposition and by site-specific recombination systems. The development of gene functions has thus to be seen as the result of both DNA rearrangement processes and sequence alterations brought about by nucleotide substitutions and small local deletions, insertions, and duplications. Prokaryotic microorganisms are particularly appropriate for studying the effects of spontaneous mutation and thus microbial evolution, as they have haploid genomes, so that genetic alterations become rapidly apparent phenotypically. In addition, bacteria and their viruses and plasmids have relatively small genomes and short generation times, which also facilitate research on evolutionary processes. Besides the strategy of development of gene functions in the vertical transmission of genomes from generation to generation, the acquisition of short DNA segments from other organisms appears to be an important strategy in microbial evolution. In this process of horizontal evolution natural vector DNA molecules are often involved. Because of acquisition barriers, the acquisition strategy works best for relatively small DNA segments, hence at the level of domains, single genes, or at most operons. Among the many enzymes and functional systems involved in vertical and horizontal microbial evolution, some may serve primarily for essential life functions in each individual and only secondarily contribute to evolution.(ABSTRACT TRUNCATED AT 250 WORDS)

Detection of free cytoplasmic circles of transposon Tn9 multimers in Escherichia coli

Extrachromosomal circular DNA molecules consisting of IS1-cat repeats, (IS1-cat)n, were isolated from an E. coli strain harboring nearly 30 copies of tandemly amplified transposon Tn9 located on the chromosome. The DNA 'circles' were characterized by restriction analysis followed by Southern blotting and electron microscopic examination. Their size varied from approximately 5.5 kb to 53 kb.

Plasmid analysis and restriction fragment length polymorphisms of chromosomal DNA allow a distinction between Borrelia burgdorferi strains

We examined the relationships of the genomes of five strains of Borrelia burgdorferi isolated from ticks, two from North America, including the type strain B31, and three from Switzerland. We determined restriction fragment length polymorphisms by using eight cloned DNA fragments as hybridization probes to genomic Southern blots. Two divergent patterns were observed, represented by B31 and one Swiss strain on the one hand and the two other Swiss strains on the other. The second American strain resembled B31. One of the DNA probes allowed distinction between the closely related strains within a group. The close resemblance of one Swiss strain to the North American strains suggests the possibility of their European origin. All five strains carried a circular plasmid of about 29 kb, and three contained an additional species of about 9 kb, both of which exhibited homology between the strains. The profiles of linear plasmids revealing species of 5.1 kb to 58 kb reflected the polymorphisms of chromosomal DNAs. Linear plasmids of similar size shared DNA sequence homology. Some of the smaller plasmids tended to become lost during cultivation.

Characterization of mutations of the bacteriophage P1 mod gene encoding the recognition subunit of the EcoP1 restriction and modification system

This study characterized several mutations of the bacteriophage P1 mod gene. This gene codes for the subunit of the EcoP1 restriction enzyme that is responsible for DNA sequence recognition and for modification methylation. We cloned the mutant mod genes into expression vectors and purified the mutant proteins to near homogeneity. Two of the mutant mod genes studied were the c2 clear-plaque mutants described by Scott (Virology 41:66-71, 1970). These mutant proteins can recognize EcoP1 sites in DNA and direct restriction but are unable to modify DNA. Methylation assays as well as S-adenosylmethionine (SAM) binding studies showed that the c2 mutants are methylation deficient because they do not bind SAM, and we conclude that the mutations destroy the SAM-binding site. Both of the c2 mutations lie within a region of the EcoP1 mod gene that is not conserved when compared with the mod gene of the related EcoP15 system. EcoP15 and EcoP1 recognize different DNA sequences, and we believe that this region of the protein may code for the DNA-binding site of the enzyme. The other mutants characterized were made by site-directed mutagenesis at codon 240. Evidence is presented that one of them, Ser-240----Pro, simultaneously lost the capacity to bind SAM and may also have changed its DNA sequence specificity.

Absence of insertions among spontaneous mutants of Salmonella typhimurium

While insertion sequences (IS) in Escherichia coli transpose frequently to generate spontaneous insertion mutants, such mutations are rare in Salmonella typhimurium: the only documented insertion mutation is a hisD mutation caused by the Salmonella-specific IS element IS200. To obtain more examples of IS200 insertion mutations and to seek additional types of IS elements in Salmonella, we selected and characterized 422 independent, spontaneous His- mutants and some 2100 additional mutants that are not necessarily independent. None of the mutants showed the absolute polar effect characteristic of insertion mutations or the reversion properties characteristic of insertions (low spontaneous reversion frequency and no reversion induction by chemical mutagens). A few mutants, showing a high spontaneous reversion frequency, were screened physically. No insertion mutations were found. Thus insertion mutations appear to be rare in S. typhimurium, in strong contrast to E. coli and despite the possession in Salmonella of at least one type of insertion element (IS200). These results suggest that in Salmonella transposition of the endogenous elements has been controlled. The transposition ability of the elements may have been reduced or favored target sites removed from the host genome.

A selection cartridge for rapid detection and analysis of spontaneous mutations including insertions of transposable elements in Enterobacteriaceae

We present a method that allows positive selection and rapid analysis of mutations in Enterobacteriaceae. Mutations are detected in a 2630 bp selection cartridge inserted in two different bacterial multicopy plasmid vectors. Spontaneous mutations in Escherichia coli, Enterobacter cloacae and Citrobacter freundii include insertions, deletions and point mutations. The small size of the target sequence facilitates rapid analysis of DNA rearrangements by cleavage with restriction enzymes and of any type of mutation by DNA sequence analysis. While in E. coli insertions of the mobile elements IS1, IS2 and IS5 were readily found, insertions of putative new transposable elements were detected in Enterobacter cloacae. The selection cartridge can thus serve as a tool for studying the spectrum of insertion mutations in Enterobacteriaceae and probably other Gram-negative bacteria, and the dependency of this spectrum on physiological and environmental factors and the host's genetic background can be investigated.

Alleviation of type I restriction in adenine methylase (dam) mutants of Escherichia coli

The host-controlled EcoK-restriction of unmodified phage lambda.O is alleviated in dam mutants of Escherichia coli by 100- to 300-fold. In addition, the EcoK modification activity is substantially decreased in dam- strains. We show that type I restriction (EcoB, EcoD and EcoK) is detectably alleviated in dam mutants. However, no relief of EcoRI restriction (Type II) occurs in dam- strains and only a slight effect of dam mutation on EcoP1 restriction (Type III) is observed. We interpret the alleviation of the type I restriction in dam- strains to be a consequence of induction of the function which interferes with type I restriction systems.

Widespread occurrence of the restriction endonuclease YenI, an isoschizomer of PstI, in Yersinia enterocolitica serotype O8

The cold-active restriction endonuclease YenI, an isoschizomer of PstI, was found in 12 of 14 Yersinia enterocolitica serotype O8 strains of different origins, but not in other serotypes of Y. enterocolitica, Yersinia pseudotuberculosis, or Yersinia pestis. In spite of the limited number of strains tested, the result suggests that the detection of YenI endonuclease or the gene might result in more rapid determination of the prominently pathogenic serotype of Y. enterocolitica.

Transposable element IS1 intrinsically generates target duplications of variable length

Target duplication during transposition is one of the characteristics of mobile genetic elements. IS1, a resident insertion element of Escherichia coli K-12, was known to generate a 9-base-pair target duplication, while an IS1 variant, characterized by a nucleotide substitution in one of its terminal inverted repeats, was reported to duplicate 8 base pairs of its target during cointegration. We have constructed a series of transposons flanked by copies of either the normal or the variant IS1. The analysis of their transposition products revealed that transposons with normal termini as well as those with variant termini can intrinsically generate either 9- or 8-base-pair target duplications. We also observed that a normal IS1 from the host chromosome generated an 8-base-pair repeat. The possible relevance of the observation for the understanding of transposition processes and models to explain the variable length of target duplications are discussed.

IS30, a new insertion sequence of Escherichia coli K12

Three independent spontaneous mutations of prophage P1 affecting the ability of the phage to reproduce vegetatively are due to the insertion of a mobile genetic element, called IS30. The same sequence is also carried in the R plasmid NR 1-Basel, but not in the parental plasmid NR 1. Southern hybridisation study indicates that the Escherichia coli K 12 chromosome carries several copies of IS30 as a normal resident. IS30 is 1.2 kb long and contains unique restriction cleavage sites for BglII, ClaI, HindIII, NciI and HincII, and it is cleaved twice by the enzymes HpaII and TaqI. The ends of IS30 are formed by 26 bp long inverted repeats with 3 bases mismatched. Upon transposition IS30 generates a duplication of only 2 bp of the target. The following observations suggest a pronounced specificity in target selection by IS30. In transposition to the phage P1 genome a single integration site was used three times independently, and in both orientations. A short region of sequence homology has been identified between the P1 and NR 1-Basel insertion sites. IS30 has mediated cointegration as well as deletion. The entire IS30 sequences were duplicated in the cointegrates between a pBR322 derivative containing IS30 and the genome of phage P1-15, and several loci on the P1-15 genome served as fusion sites, some of which were used more than once.

Characterization of generalized transducing phage phi w39 heteroimmune to phage P1 in Escherichia coli W39

Generalized transducing phage similar to phage P1 in Escherichia coli was isolated from E. coli W39, an antigenic test strain of the O121 group. This phage, designated phi w39, was reciprocally heteroimmune to phages P1 and P7, but nonreciprocally heteroimmune to phage D6. Transduction experiments using various R plasmids with different molecular weights suggested that phage phi w39 could transduce at least 65 megadaltons DNA. As in the case of P1 prophage, phi w39 prophage existed as a plasmid belonging to incompatibility group Y and carried a dnaB-like function. The molecular weight of phi w39 plasmid was nearly the same as that of plasmid, i.e., 58.6 megadaltons. Despite the pronounced structural and functional similarity of phages phi w39 and P1, restriction cleavage patterns of their genomes differed considerably.

Circularized copies of amplifiable resistance genes from Haemophilus influenzae plasmids

Tandem repeat amplification of resistance determinants in Haemophilus influenzae plasmids is associated with the occurrence of separate circular DNA molecules. They were demonstrated to represent mono- and multimeric forms of the amplifiable segments of the plasmids which comprise the respective resistance transposons and an additional region designated as an amplification sequence. The latter region mediates the recombinational events involved in amplification. The DNA circles apparently lack the ability to replicate autonomously but most probably provide an effective means for the translocation of resistance genes from one plasmid to another.

Resistance to fusidic acid in Escherichia coli mediated by the type I variant of chloramphenicol acetyltransferase. A plasmid-encoded mechanism involving antibiotic binding

Plasmid-encoded fusidic acid resistance in Escherichia coli is mediated by a common variant of chloramphenicol acetyltransferase (EC 2.3.1.28), an enzyme which is an effector of chloramphenicol resistance. Resistance to chloramphenicol is a consequence of acetylation of the antibiotic catalysed by the enzyme and the failure of the 3-acetoxy product to bind to bacterial ribosomes. Cell-free coupled transcription and translation studies are in agreement with genetic studies which indicated that the entire structural gene for the type I chloramphenicol acetyltransferase is necessary for the fusidic acid resistance phenotype. The mechanism of resistance does not involve covalent modification of the antibiotic. The other naturally occurring enterobacterial chloramphenicol acetyltransferase variants (types II and III) do not cause fusidic acid resistance. Steady-state kinetic studies with the type I enzyme have shown that the binding of fusidic acid is competitive with respect to chloramphenicol. The inhibition of polypeptide chain elongation in vitro which is observed in the presence of fusidic acid is relieved by addition of purified chloramphenicol acetyltransferase, and equilibrium dialysis experiments with [3H]fusidate and the type I enzyme have defined the stoichiometry and apparent affinity of fusidate for the type I enzyme. Further binding studies with fusidate analogues, including bile salts, have shown some of the structural constraints on the steroidal skeleton of the ligand which are necessary for binding to the enzyme. Determinations of antibiotic resistance levels and estimates of intracellular chloramphenicol acetyltransferase concentrations in vivo support the data from experiments in vitro to give a coherent mechanism for fusidic acid resistance based on reversible binding of the antibiotic to the enzyme.

Genome fusion mediated by the site specific DNA inversion system of bacteriophage P1

The genome of bacteriophage P1 contains a segment which is invertible by site specific recombination between sequences near the outside ends of the inverted repeats which flank it. Immediately adjacent to this C segment is the coding sequence for cin, the enzyme catalyzing inversion. We show that multicopy plasmids carrying cin and the sequences at which it acts (cix) can form dimers in the absence of the host recA function. Further, such plasmids can be cotransduced with P1 markers at high frequency from recA lysogens, indicating cointegration with the P1 genome. It is thus demonstrated that a system whose primary role is the inversion of a specific DNA segment can also mediate intermolecular recombination.

Inverted duplication in the genome of the temperate Streptomyces phage SH3

The DNA of the temperate Streptomyces phage SH3 contains 100 base-pair long inverted repeats separated by a 940 base-pair long segment of DNA as revealed by electronmicroscopic analysis of snapback structures formed after rapid intrastrand reannealing of denatured DNA. The inverted repeat structure was found preferentially at map unit 22 of the circular physical map, in rare cases also in other positions, suggesting a movable character of this genetic element.

Influence of phage T3 and T7 gene functions on a type III(EcoP1) DNA restriction-modification system in vivo

The ocr+ gene function (gp 0.3) of bacteriophages T3 and T7 not only counteracts type I (EcoB, EcoK) but also type III restriction endonucleases (EcoP1). Despite the presence of recognition sites, phage DNA as well as simultaneously introduced plasmid DNA are protected by ocr+ expression against both the endonucleolytic and the methylating activities of the EcoP1 enzyme. Nevertheless, the EcoP1 protein causes the exclusion of T3 and T7 in P1-lysogenic cells, apparently by exerting a repressor-like effect on phage gene expression. T3 which induces an S-adenosylmethionine hydrolase is less susceptible to the repressor effect of the SAM-stimulated EcoP1 enzyme. The abundance of EcoP1 recognition sites in the T7 genome is explained by their near identity with the T7 DNA primase recognition site.

A site-specific, conservative recombination system carried by bacteriophage P1. Mapping the recombinase gene cin and the cross-over sites cix for the inversion of the C segment

The bacteriophage P1 genome carries an invertible C segment consisting of 3-kb unique sequences flanked by 0.6-kb inverted repeats. With insertion and deletion mutants of P1 derivatives the site-specific recombinase gene cin for C inversion) has been mapped adjacent to the C segment and the cix sites (for C inversion cross-over) have been located at the outside ends of the inverted repeats. Inversion of the C segment functions as a biological switch and controls expression of the gene(s) responsible for phage infectivity carried on the C segment. The cin gene product can promote recombination between a 'quasi- cix ' site on plasmid pBR322 and a cix site on P1 DNA. The junctions formed on the resulting co-integrate can also serve as cix sites. This observation implies a potential evolutionary process to bring genes under the control of a biological switch acting by DNA inversion.

Dissection of the r-determinant of the plasmid R100.1: the sequence at the extremities of Tn21

We have sequenced the extremities of the transposon Tn21, isolated from the r-determinant of the multiple antibiotic resistance plasmid R100.1, and show that it is a member of the Tn3 family of elements.

Cointegrates between bacteriophage P1 DNA and plasmid pBR322 derivatives suggest molecular mechanisms for P1-mediated transduction of small plasmids

We characterized cointegrates formed in an Escherichia coli rec+ strain between bacteriophage P1 genomes and small plasmids related to pBR322. The partners were, on the one hand, either phage P1 DNA, which carries one copy of IS1, or phage P1-15 DNA, a derivative which lacks the IS1, and, on the other hand, plasmids containing either a split IS1 or no. In the presence of IS1 sequences on both partners, cointegrates were usually formed by reciprocal recombination between SI1 sequences. Cointegrates between P1 and a plasmid carrying no IS1 sequence were formed by transpositional cointegration mediated by IS1 of P1. Cointegrates between P1-15 and small plasmid containing a split IS1 were formed by one of three ways: (a) acquisition of an IS1 by P1-15 followed by reciprocal recombination between IS1 sequences, (b) transpositional cointegration mediated by the split IS1 element, Tn2657, or (c) involvement of the invertible segment carried on P1-15 DNA. Most cointegrates segregated into the small plasmids and phage P1 derivatives. A comparison of the phenomenon studied and of their frequencies allowed us to conclude that cointegrate formation is a molecular mechanism involved in the transduction of plasmids smaller than those packageable into P1 virions, although it does not seem to be the only process used.

The plasmid cloning vector pBR325 contains a 482 base-pair-long inverted duplication

The plasmid pBR325 is a cloning vector constructed in vitro by addition of the chloramphenicol resistance (Cmr) gene of an IS1-flanked transposon to pBR322 (Bolivar, 1978). It is a 5 995 bp plasmid carrying no sequence originating from IS1. DNA-sequence data suggest that its Cmr segment was derived from a Cm transposon longer than Tn9. The plasmid pBR325 carries between the Cmr and Tcr genes a 482 bp sequence which duplicates, in the opposite orientation, a section pf pBR322 located at the end of the tcr gene. The same structure was found in pBR328, a deletion derivative of pBR325 (Soberon et al., 1980). The possible implications of this inverted duplication on cloning experiments are discussed.

Tn2001, a transposon encoding chloramphenicol resistance in Pseudomonas aeruginosa

We isolated a new transposon, Tn2001, from the group P-2 plasmid Rms159-1 in Pseudomonas aeruginosa. Tn2001-encoded chloramphenicol resistance did not result from the formation of chloramphenicol acetyltransferase. Tn2001 was transposable between temperate phages and conjugative and nonconjugative plasmids belonging to various incompatibility groups, including P-1, P-3, P-4, P-5, P-7, and P-8 in P. aeruginosa. Transposition occurred independently of the general recombination ability of the Pseudomonas host, and its frequency varied between 10(-1) and 10(-8), depending upon the donor and recipient replicons. Tn2001 transposition also occurred in a recombination-deficient strain of Escherichia coli. Agarose gel electrophoresis and electron microscopic observations revealed that Tn2001 could transpose to different sites in the RP4 replicon and that the transposed deoxyribonucleic acid fragment was 2.1 kilobases long.

Distribution of the insertion sequence IS1 in gram-negative bacteria

Translocation of DNA segments is a recombinational event seen in both eukaryotic and prokaryotic chromosomes, and it is thought to be involved in controlling gene expression and in the evolution of chromosomes. In bacteria, insertion (IS) and transposable (Tn) elements not only translocate their own DNA, but also promote the rearrangement of both bacterial chromosomes and the plasmic genomes carrying them. The insertion element IS1 is one such element which is 768 base pairs long. IS1 is involved in the generation of deletion mutations and in the fusion of two different plasmid genomes. It can also promote the translocation of DNA segments flanked by two copies of IS1 to give rise to transposable elements responsible for antibiotic resistance and enterotoxin production. We report here the distribution of the IS1 sequence in various bacterial DNAs, particularly in the family Enterobacteriaceae. Comparison of the results with the phylogenetic relationship of these bacteria suggests that IS1 was transferred from one bacterium to another after their divergence and in some bacteria the copy number of IS1 increased by translocation. The increase in the number of copies of IS1 in bacteria may increase the probability of the genetic rearrangement responsible for the generation of resistance and enterotoxin plasmids, the existence of which is a serious problem in medical microbiology.

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.

The origin of human cancers

The limited evidence available suggests that most human cancers are not caused by conventional mutagens but are more likely to be the result of genetic transpositions. Although the molecular biology of transposition is starting to be understood, the external factors that influence its frequency have not yet been studied in any detail.

Isolation of an IS1 flanked kanamycin resistance transposon from R1drd19

We have isolated and identified an IS1-flanked transposon from the plasmid R1drd19. This transposon specifies resistance to kanamycin and is 10.4 kg long. It exhibits a frequency of transposition two orders of magnitude lower than that of the smaller, IS1-flanked transposon Tn9. We have named it Tn2350.

Electron microscopic observation of new transposable elements inserted into P22 phage genome from R plasmids

By using phage P22spl, a deletion mutant of phage P22, the structures of two new transposons on P22 genomes were studied by the electron microscopic heteroduplex method. One of these was the Cm (chloramphenicol) transposon derived from an R plasmid, NR1, and the other the Km (kanamycin) transposon frin obr502. the heteroduplex between P22 phage DNAs with and without the Cm transposon revealed that the Cm transposon was similar in structure to the Tn9 element, a well-known Cm transposon derived from the R plasmid pMS14. On the other hand, the Km transposon of pNR502 was quite different in structure from other Km transposons reported previously. This transposon consists of a 6.8 kilobase (kb) segment of DNA, in which a short inverted repeat is contained. The heteroduplex experiments showed that a 4.5 kb segment of DNA was deleted from the P22 genome in the P22spl genome. Because of a shorter unit length of the genome, phage P22spl is considered to be useful of assaying various kinds of transposable elements.

Genetic evidence for absence of transposition functions from the internal part of Tn981 a relative of Tn9

Inverse transposition of the DNA of pBR322 was found to be mediated by the small transposon Tn981 a relative of Tn9 flanked by direct repeats of IS1. Since the resulting structure IS1::pBR322::IS1 (Tn983) is transposed in a second step in the absence of Tn981, it is concluded that all the functions necessary for transposition of IS1 flanked transposons are coded for by IS1 itself or the E. coli chromosome, respectively.

Does the insertion element IS1 transpose preferentially into A+T-rich DNA segments?

IS1-mediated insertion and deletion formation occur preferentially into A+T-rich regions of DNA of bacteriophate P1 and of the r-determinant of the R plasmid NR1. The significance of this correlation is discussed in view of other published data.

Nucleotide sequence analysis of the chloramphenicol resistance transposon Tn9

The transposable genetic element Tn9 consists of two direct repeats of the insertion sequence IS1 flanking a region of 1,102 base pairs which determines chloramphenicol resistance. Transposition of Tn9 leads to the duplication of a 9-base pair sequence which preexists at the site of insertion. One copy of this sequence is found at each end of the inserted element. The chloramphenicol resistance determined by Tn9, and by various other R plasmids, is due to the synthesis of the enzyme chloramphenicol acetyl transferase (CAT). This enzyme catalyses the formation of acetylated derivatives of chloramphenicol which are inactive as inhibitors of protein synthesis. By using the chain termination technique of DNA sequencing, we have now determined the nucleotide sequence of the 1,102 base pair region between the directly repeated IS1 sequence in the bacterial transposon Tn9 (encoding chloramphenicol resistance). The amino acid sequence of CAT predicted from the nucleotide sequence is identical to that determined by Shaw and coworkers. An analysis of the sequence suggests that the internal 1,102 base pair region is not directly involved in transposition.

Some properties of the chloramphenicol resistance transposon Tn9

We have isolated variants of the plasmid RTF which have received the transposon Tn9 from bacteriophage P1Cm. We have shown by the formation of heteroduplex molecules between one RTF:Tn9 derivative and R100.1 that Tn9 is homologous to the r-determinant region of R100.1 which carries the determinants for chloramphenicol resistance. This suggests that Tn9 was derived from an r-det like structure by deletion, possibly mediated by one of the flanking IS1 elements. In spite of the similarity in structure between Tn9 and r-det however, we have demonstrated two distinct differences in the behavior of these two elements: 1) Tn9 but not r-det, is able to amplify, by a recA dependent mechanism, when cells harboring RTF::Tn9 are grown in the presence of chloramphenicol, and 2) Tn9, unlike r-det, does not form extrachromosomal circular molecules when RTF::Tn9 is tegrated into the bacterial chromosome.

Amplification of chloramphenicol resistance transposons carried by phage P1Cm in Escherichia coli

We have characterized a number of P1Cm phages which contain the resistance genes to chloramphenicol and fusidic acid as IS1-flanked Cm transposons. Restriction cleavage and electron microscopic analysis showed that these Cm transposons were carried as monomers (M) or tandem dimers (D). Lysogens of P1Cm (D) are more resistant to chloramphenicol than those of its P1Cm (M) presumably as a result of an increased gene dosage. Amplification of the Cm transposons to tandem multimers was frequently observed in P1Cm (D) lysogens grown in the presence of high concentrations of chloramphenicol or fusidic acid and was also detected in P1Cm (M) lysogens. The degree of amplification varied in different clones which suggests that cells containing spontaneously amplified Cm transposons were selected by high doses of the antibiotics. The dimeric as well as the amplified Cm transposons carried in P1Cm lysogens grown in the absence of chloramphenicol displayed considerable stability. Mechanisms for the amplification of the IS1-flanked transposons are discussed.