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

Interaction of bacteriophage P1 with an epiphytic Pantoea agglomerans strain-the role of the interplay between various mobilome elements

P1 is a model, temperate bacteriophage of the 94 kb genome. It can lysogenize representatives of the Enterobacterales order. In lysogens, it is maintained as a plasmid. We tested P1 interactions with the biocontrol P. agglomerans L15 strain to explore the utility of P1 in P. agglomerans genome engineering. A P1 derivative carrying the Tn9 (cmR) transposon could transfer a plasmid from Escherichia coli to the L15 cells. The L15 cells infected with this derivative formed chloramphenicol-resistant colonies. They could grow in a liquid medium with chloramphenicol after adaptation and did not contain prophage P1 but the chromosomally inserted cmR marker of P1 Tn9 (cat). The insertions were accompanied by various rearrangements upstream of the Tn9 cat gene promoter and the loss of IS1 (IS1L) from the corresponding region. Sequence analysis of the L15 strain genome revealed a chromosome and three plasmids of 0.58, 0.18, and 0.07 Mb. The largest and the smallest plasmid appeared to encode partition and replication incompatibility determinants similar to those of prophage P1, respectively. In the L15 derivatives cured of the largest plasmid, P1 with Tn9 could not replace the smallest plasmid even if selected. However, it could replace the smallest and the largest plasmid of L15 if its Tn9 IS1L sequence driving the Tn9 mobility was inactivated or if it was enriched with an immobile kanamycin resistance marker. Moreover, it could develop lytically in the L15 derivatives cured of both these plasmids. Clearly, under conditions of selection for P1, the mobility of the P1 selective marker determines whether or not the incoming P1 can outcompete the incompatible L15 resident plasmids. Our results demonstrate that P. agglomerans can serve as a host for bacteriophage P1 and can be engineered with the help of this phage. They also provide an example of how antibiotics can modify the outcome of horizontal gene transfer in natural environments. Numerous plasmids of Pantoea strains appear to contain determinants of replication or partition incompatibility with P1. Therefore, P1 with an immobile selective marker may be a tool of choice in curing these strains from the respective plasmids to facilitate their functional analysis.

Alterations in chromosomal genes nfsA, nfsB, and ribE are associated with nitrofurantoin resistance in Escherichia coli from the United Kingdom

Antimicrobial resistance in enteric or urinary Escherichia coli is a risk factor for invasive E. coli infections. Due to widespread trimethoprim resistance amongst urinary E. coli and increased bacteraemia incidence, a national recommendation to prescribe nitrofurantoin for uncomplicated urinary tract infection was made in 2014. Nitrofurantoin resistance is reported in <6% urinary E. coli isolates in the UK, however, mechanisms underpinning nitrofurantoin resistance in these isolates remain unknown. This study aimed to identify the genetic basis of nitrofurantoin resistance in urinary E. coli isolates collected from north west London and then elucidate resistance-associated genetic alterations in available UK E. coli genomes. As a result, an algorithm was developed to predict nitrofurantoin susceptibility. Deleterious mutations and gene-inactivating insertion sequences in chromosomal nitroreductase genes nfsA and/or nfsB were identified in genomes of nine confirmed nitrofurantoin-resistant urinary E. coli isolates and additional 11 E. coli isolates that were highlighted by the prediction algorithm and subsequently validated to be nitrofurantoin-resistant. Eight categories of allelic changes in nfsA , nfsB , and the associated gene ribE were detected in 12412 E. coli genomes from the UK. Evolutionary analysis of these three genes revealed homoplasic mutations and explained the previously reported order of stepwise mutations. The mobile gene complex oqxAB , which is associated with reduced nitrofurantoin susceptibility, was identified in only one of the 12412 genomes. In conclusion, mutations and insertion sequences in nfsA and nfsB were leading causes of nitrofurantoin resistance in UK E. coli . As nitrofurantoin exposure increases in human populations, the prevalence of nitrofurantoin resistance in carriage E. coli isolates and those from urinary and bloodstream infections should be monitored.

Isolation, characterization, genomic sequencing, and GFP-marked insertional mutagenesis of a high-performance nitrogen-fixing bacterium, Kosakonia radicincitans GXGL-4A and visualization of bacterial colonization on cucumber roots

A gram-negative bacterium GXGL-4A was originally isolated from maize roots. It displayed nitrogen-fixing (NF) ability under nitrogen-free culture condition, and had a significant promotion effect on cucumber growth in the pot inoculation test. The preliminary physiological and biochemical traits of GXGL-4A were characterized. Furthermore, a phylogenetic tree was constructed based on 16S ribosomal DNA (rDNA) sequences of genetically related species. To determine the taxonomic status of GXGL-4A and further utilize its nitrogen-fixing potential, genome sequence was obtained using PacBio RS II technology. The analyses of average nucleotide identity based on BLAST+ (ANIb) and correlation indexes of tetra-nucleotide signatures (Tetra) showed that the NF isolate GXGL-4A is closely related to the Kosakonia radicincitans type strain DSM 16656. Therefore, the isolate GXGL-4A was eventually classified into the species of Kosakonia radicincitans and designated K. radicincitans GXGL-4A. A high consistency in composition and gene arrangement of nitrogen-fixing gene cluster I (nif cluster I) was found between K. radicincitans GXGL-4A and other Kosakonia NF strains. The mutants tagged with green fluorescence protein (GFP) were obtained by transposon Tn5 mutagenesis, and then, the colonization of gfp-marked K. radicincitans GXGL-4A cells on cucumber seedling root were observed under fluorescence microscopy. The preferential sites of the labeled GXGL-4A cell population were the lateral root junctions, the differentiation zone, and the elongation zone. All these results should benefit for the deep exploration of nitrogen fixation mechanism of K. radicincitans GXGL-4A and will definitely facilitate the genetic modification process of this NF bacterium in sustainable agriculture.

Insertion sequence-caused large-scale rearrangements in the genome of Escherichia coli

A majority of large-scale bacterial genome rearrangements involve mobile genetic elements such as insertion sequence (IS) elements. Here we report novel insertions and excisions of IS elements and recombination between homologous IS elements identified in a large collection of Escherichia coli mutation accumulation lines by analysis of whole genome shotgun sequencing data. Based on 857 identified events (758 IS insertions, 98 recombinations and 1 excision), we estimate that the rate of IS insertion is 3.5 × 10(-4) insertions per genome per generation and the rate of IS homologous recombination is 4.5 × 10(-5) recombinations per genome per generation. These events are mostly contributed by the IS elements IS1, IS2, IS5 and IS186 Spatial analysis of new insertions suggest that transposition is biased to proximal insertions, and the length spectrum of IS-caused deletions is largely explained by local hopping. For any of the ISs studied there is no region of the circular genome that is favored or disfavored for new insertions but there are notable hotspots for deletions. Some elements have preferences for non-coding sequence or for the beginning and end of coding regions, largely explained by target site motifs. Interestingly, transposition and deletion rates remain constant across the wild-type and 12 mutant E. coli lines, each deficient in a distinct DNA repair pathway. Finally, we characterized the target sites of four IS families, confirming previous results and characterizing a highly specific pattern at IS186 target-sites, 5'-GGGG(N6/N7)CCCC-3'. We also detected 48 long deletions not involving IS elements.

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.

Bacteriophage recombineering in the lytic state using the lambda red recombinases

Bacteriophages, the historic model organisms facilitating the initiation of molecular biology, are still important candidates of numerous useful or promising biotechnological applications. Development of generally applicable, simple and rapid techniques for their genetic engineering is therefore a validated goal. In this article, we report the use of bacteriophage recombineering with electroporated DNA (BRED), for the first time in a coliphage. With the help of BRED, we removed a copy of mobile element IS1, shown to be active, from the genome of P1vir, a coliphage frequently used in genome engineering procedures. The engineered, IS-free coliphage, P1virdeltaIS, displayed normal plaque morphology, phage titre, burst size and capacity for generalized transduction. When performing head-to-head competition experiments, P1vir could not outperform P1virdeltaIS, further indicating that the specific copy of IS1 plays no direct role in lytic replication. Overall, P1virdeltaIS provides a genome engineering vehicle free of IS contamination, and BRED is likely to serve as a generally applicable tool for engineering bacteriophage genomes in a wide range of taxa.

The CO2-concentrating mechanism of Synechococcus WH5701 is composed of native and horizontally-acquired components

The cyanobacterial CO(2)-concentrating mechanism (CCM) is an effective adaptation that increases the carbon dioxide (CO(2)) concentration around the primary photosynthetic enzyme Ribulose-1,5-bisphosphate Carboxylase/Oxygenase (RuBisCO). α-Cyanobacteria (those containing Form1-A RuBisCO within cso-type α-carboxysomes) have a limited CCM composed of a small number of Ci-transporters whereas β-cyanobacteria (those species containing Form-1B RuBisCO within ccm-type β-carboxysomes) exhibit a more diverse CCM with a greater variety in Ci-transporter complement and regulation. In the coastal species Synechococcus sp. WH5701 (α-cyanobacteria), the minimal α-cyanobacterial CCM has been supplemented with β-cyanobacterial Ci transporters through the process of horizontal gene transfer (HGT). These transporters are transcriptionally regulated in response to external Ci-depletion however this change in transcript abundance is not correlated with a physiological induction. WH5701 exhibits identical physiological responses grown at 4% CO(2) (K (1/2) ≈ 31 μM Ci) and after induction with 0.04% CO(2) (K (1/2) ≈ 29 μM Ci). Insensitivity to external Ci concentration is an unusual characteristic of the WH5701 CCM which is a result of evolution by HGT. Our bioinformatic and physiological data support the hypothesis that WH5701 represents a clade of α-cyanobacterial species in transition from the marine/oligotrophic environment to a coastal/freshwater environment.

Transposon Mutagenesis of Azospirillum brasilense and Azospirillum lipoferum: Physical Analysis of Tn5 and Tn5-Mob Insertion Mutants

Tn5-induced insertion mutants were generated in Azospirillum brasilense Sp7 and A. lipoferum SpBr17 by mating with Escherichia coli strains carrying suicide plasmid vectors. The sources of Tn5 were the suicide plasmids pGS9 and pSUP2021. Kanamycin-resistant Azospirillum colonies appeared from crosses with E. coli at maximum frequencies of 10 per recipient cell. Transposon Tn5 also conferred streptomycin resistance on Azospirillum colonies as was observed earlier for Rhizobium sp. Eight Tn5-induced Km SmA. brasilense Sp7 mutants with reduced nitrogen-fixing capacity were isolated. The potential use of Tn5-Mob for labeling and mobilization of Azospirillum-indigenous plasmids was demonstrated by isolating Tn5-Mob insertions in the megaplasmids of A. brasilense Sp7.

ISEcp1B-mediated transposition of blaCTX-M in Escherichia coli

Several expanded-spectrum beta-lactamase bla(CTX-M) genes are associated with ISEcp1-like elements in Enterobacteriaceae. We found that ISEcp1B was able to mobilize the adjacent bla(CTX-M-19) gene by a transpositional mechanism in Escherichia coli by recognizing a variety of DNA sequences as right inverted repeats.

ISSa4-based differentiation of Streptococcus agalactiae strains and identification of multiple target sites for ISSa4 insertions

A collection of 113 epidemiologically unrelated Streptococcus agalactiae strains were studied (group B streptococcus; GBS): they belonged to different serotypes and were isolated from pregnant women in China and Russia. The insertion sequence ISSa4 was found in 21 of 113 strains (18,6%). All of the strains with ISSa4 belonged to serotypes II and II/c and were characterized by the presence of IS1381 and IS861 as well as the absence of IS1548 and GBSi1. All of the strains with ISSa4 possessed both bca and bac virulence genes coding for alpha and beta antigens, respectively. Among 21 ISSa4-positive strains, 13 different HindIII patterns (D1 to D13) hybridizing with an ISSa4 probe were found. One of them (D13) contained a single HindIII hybridization fragment 6.5 kb in size that was found to be specific for all ISSa4-positive GBS strains. Multiple target sites for insertions of ISSa4 were identified and included a putative pathogenicity island, "housekeeping" genes, and intergenic regions, as well as the genes for hypothetical proteins. No significant similarity was observed in the sequences of the target genes for ISSa4 insertions, in the relative location of the target genes on the chromosome, or the biological functions of the encoded proteins. The possible significance of ISSa4-based differentiation of the strains and the presence of possible "hot spots" for insertions of ISSa4 in GBS genome are discussed.

Genetic variation in the flanking regions of Shiga toxin 2 gene in Shiga toxin-producing Escherichia coli O157:H7 isolated in Japan

We found frequent IS1 integration nearby the stx(2) gene during in vitro mutagenesis of an stx(2) variant, stx(2vhd). To examine the possibility that such insertions have been contributing to generate new stx(2) variants, we screened 86 strains of Escherichia coli O157:H7 isolated in Japan for variations in the ca. 4-kb region flanking the stx(2) locus using PCR methods. Two major classes were identified based on the PCR amplicon size. DNA sequence analysis revealed that the stx(2) subtype of the two classes were stx(2) (referred to as stx(2-EDL933)) and stx(2vhd). IS1203v insertions were found in three stx(2vhd)-positive strains and two stx(2-EDL933)-positive strains, and no other insertions were found. These results suggest that the DNA sequences surrounding the stx(2) genes are preferably integrated by IS1203v in wild-type Shiga toxin-producing E. coli strains.

Transposition of IS1 circles

BACKGROUND

IS1, the smallest active transposable element in bacteria, encodes transposase. IS1 transposase promotes transposition as well as production of miniplasmids from a plasmid carrying IS1 by deletion of the region adjacent to IS1. The IS1 transposase also promotes production of IS1 circles consisting of the entire IS1 sequence and a sequence, 6-9 bp in length, as a spacer between terminal inverted repeats of IS1. The biological significance of the generation of IS1 circles is not known.

RESULTS

Plasmids carrying an IS1 circle with a spacer sequence 6-9 bp long transposed to target plasmids at a very high frequency when transposase was produced from a co-resident plasmid. The products were target plasmids with the donor plasmid inserted at the ends of IS1 in the IS1 circle. This insertion accompanied the removal of the spacer sequence and duplication of the sequence at the target site. IS1 circles with a much longer spacer sequence transposed less frequently. The SOS response was induced in cells harbouring a plasmid with an IS1 circle owing to transposase. IS1 circles could transpose in the strain deficient in H-NS, a nucleoid-associated DNA-binding protein known to be required for the transposition of IS1.

CONCLUSIONS

IS1 circles appear to act as intermediates for simple insertion into the target DNA via cleavage of the circles which induces the SOS response. H-NS may function in promoting the assembly of an active IS1 DNA-transposase complex at the terminal inverted repeats.

Oxygen-insensitive nitroreductases: analysis of the roles of nfsA and nfsB in development of resistance to 5-nitrofuran derivatives in Escherichia coli

Nitroheterocyclic and nitroaromatic compounds constitute an enormous range of chemicals whose potent biological activity has significant human health and environmental implications. The biological activity of nitro-substituted compounds is derived from reductive metabolism of the nitro moiety, a process catalyzed by a variety of nitroreductase activities. Resistance of bacteria to nitro-substituted compounds is believed to result primarily from mutations in genes encoding oxygen-insensitive nitroreductases. We have characterized the nfsA and nfsB genes of a large number of nitrofuran-resistant mutants of Escherichia coli and have correlated mutation with cell extract nitroreductase activity. Our studies demonstrate that first-step resistance to furazolidone or nitrofurazone results from an nfsA mutation, while the increased resistance associated with second-step mutants is a consequence of an nfsB mutation. Inferences made from mutation about the structure-function relationships of NfsA and NfsB are discussed, especially with regard to the identification of flavin mononucleotide binding sites. We show that expression of plasmid-carried nfsA and nfsB genes in resistant mutants restores sensitivity to nitrofurans. Among the 20 first-step and 53 second-step mutants isolated in this study, 65 and 49%, respectively, contained insertion sequence elements in nfsA and nfsB. IS1 integrated in both genes, while IS30 and IS186 were found only in nfsA and IS2 and IS5 were observed only in nfsB. Insertion hot spots for IS30 and IS186 are indicated in nfsA, and a hot spot for IS5 insertion is evident in nfsB. We discuss potential regional and sequence-specific determinants for insertion sequence element integration in nfsA and nfsB.

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.

Tn5/IS50 target recognition

This communication reports an analysis of Tn5/IS50 target site selection by using an extensive collection of Tn5 and IS50 insertions in two relatively small regions of DNA (less than 1 kb each). For both regions data were collected resulting from in vitro and in vivo transposition events. Since the data sets are consistent and transposase was the only protein present in vitro, this demonstrates that target selection is a property of only transposase. There appear to be two factors governing target selection. A target consensus sequence, which presumably reflects the target selection of individual pairs of Tn5/IS50 bound transposase protomers, was deduced by analyzing all insertion sites. The consensus Tn5/IS50 target site is A-GNTYWRANC-T. However, we observed that independent insertion sites tend to form groups of closely located insertions (clusters), and insertions very often were spaced in a 5-bp periodic fashion. This suggests that Tn5/IS50 target selection is facilitated by more than two transposase protomers binding to the DNA, and, thus, for a site to be a good target, the overlapping neighboring DNA should be a good target, too. Synthetic target sequences were designed and used to test and confirm this model.

Characterization of IS1515, a functional insertion sequence in Streptococcus pneumoniae

We describe the characterization of a new insertion sequence, IS1515, identified in the genome of Streptococcus pneumoniae I41R, an unencapsulated mutant isolated many years ago (R. Austrian, H. P. Bernheimer, E. E. B. Smith, and G. T. Mills, J. Exp. Med. 110:585-602, 1959). A copy of this element located in the cap1EI41R gene was sequenced. The 871-bp-long IS1515 element possesses 12-bp perfect inverted repeats and generates a 3-bp target duplication upon insertion. The IS encodes a protein of 271 amino acid residues similar to the putative transposases of other insertion sequences, namely IS1381 from S. pneumoniae, ISL2 from Lactobacillus helveticus, IS702 from the cyanobacterium Calothrix sp. strain PCC 7601, and IS112 from Streptomyces albus G. IS1515 appears to be present in the genome of most type 1 pneumococci in a maximum of 13 copies, although it has also been found in the chromosome of pneumococcal isolates belonging to other serotypes. We have found that the unencapsulated phenotype of strain 141R is the result of both the presence of an IS1515 copy and a frameshift mutation in the cap1EI41R gene. Precise excision of the IS was observed in the type 1 encapsulated transformants isolated in experiments designed to repair the frameshift. These results reveal that IS1515 behaves quite differently from other previously described pneumococcal insertion sequences. Several copies of IS1515 were also able to excise and move to another locations in the chromosome of S. pneumoniae. To our knowledge, this is the first report of a functional IS in pneumococcus.

Genetic analyses of the interactions of the IS1-encoded proteins with the left end of IS1 and its insertion hotspot

Insertion sequence IS1 specifies the InsA, delta InsA-B'-InsB and InsA-B'-InsB protein species. These three proteins have the identical alpha-helix-turn-alpha-helix motif that is likely to be responsible for DNA binding. In fact, InsA binds to the ends of IS1, and regulates gene expression and transposition of IS1. delta InsA-B'-InsB and/or InsA-B'-InsB has been thought to possess a transposase-like activity. Here, I examined the actions of these proteins in vivo on the promoter (pinsL) in the left end of IS1. InsA repressed pinsL-driven gene expression, both in cis and in trans. delta InsA-B'-InsB inhibited it efficiently only when pinsL was located near the construct where delta InsA-B'-InsB is expressed. Furthermore, it has been shown that the possible -10 sequence of pinsL is required for delta InsA-B'-InsB to act on, but the -35 sequence where InsA binds specifically, is not. InsA-B'-InsB appeared not to work on a nearby pinsL. The cis-action of delta InsA-B'-InsB is consistent with the previous observation that the IS1 transposase acts preferentially in cis. Interestingly, delta InsA-B'-InsB acted on a nearby P3 promoter in the IS1 insertion hotspot, and on another promoter outside the hotspot. delta InsA-B'-InsB may generally interact with the regions in or around promoters owing to their low DNA helix stability. Note that IS1 transposes preferentially into A + T-rich DNA segments, and that DNA is unwound from the -10 region of a promoter in transcription. The cis-preference of delta InsA-B'-InsB would result in an overall reduction of transposition of IS1 and its defective copy in a cell, allowing stable existence of the element in its bacterial host.

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.

The non-random pattern of insertion of IS2 into the hemB gene of Escherichia coli

The hemB gene of Escherichia coli has been identified as a hot spot for the insertion of the transposable element IS2. The insertional specificity of IS2 is still unclear. This study reports on the attempt to sequence a statistically significant number of insertions in hemB, in order to determine whether there might be a basis for future studies to determine a molecular basis of IS2 insertional specificity. The results indicate that IS2 inserts in a non-random manner into a 240 bp segment at the 5' end of the gene (region I). Twenty-one of 24 insertions occurred in region I. Three insertions have been identified in the two middle 250 bp segments of the 975 bp gene, and none in the 3' terminal segment. A seventeen bp sequence showing 88.2% identity with a segment of IS2, 221 bp from the 3' terminus has been identified in region I. Four instances of repeated insertion between the same pair of nucleotides have been observed at four different sites.

Insertion of a novel DNA sequence, 1S1186, upstream of the silent carbapenemase gene cfiA, promotes expression of carbapenem resistance in clinical isolates of Bacteroides fragilis

A small number of isolates of Bacteroides fragilis, an anaerobic pathogen of the human intestinal flora, carries a copy (or copies) of the carbapenemresistance gene, cfiA, which may be silent or expressed. We have studied the mechanism of activation of the frequently silent gene in in vitro-selected mutants and in clinical isolates. In both types of strains, activation was observed as the consequence of the insertion, at several possible sites, of a novel 1.3 kb insertion sequence, IS1186, immediately upstream of the carbapenemase gene. IS1186 has two open reading frames, on opposite strands, with coding capacities for a 41.2 kDa (ORF1) and a 22.5kDa (ORF2) protein. The 41.2kDa protein has homology with some proteins predicted from open reading frames of IS elements or DNA direct repeats of aerobic, but not anaerobic, Gram-negative bacteria. Upon insertion, transcription of cfiA was found to be driven from a promoter identified on the right end of IS1186. In one instance, insertion occurred into the putative ribosome-binding site of cfiA, leaving intact the tetranucleotide AGAA which is concluded to be a fully functional ribosome-binding site. Between 3 and 14 copies of IS1186 were detected per genome and the element was found, within the species B. fragilis, almost exclusively in the subgroup carrying the cifA gene.

TTAA serves as the target site for TFP3 lepidopteran transposon insertions in both nuclear polyhedrosis virus and Trichoplusia ni genomes

We have analysed TFP3 transposable elements from five independently isolated FP mutants of the Autographa californica nuclear polyhderosis virus (AcMNPV). We also analysed genomic copies of TFP3 elements amplified from the DNAs of the Trichoplusia ni cell line (TN-368) and T. ni larvae using the polymerase chain reaction (PCR). The sequences of all the newly isolated TFP3 elements closely resemble the previously described TFP3/1 element. Each of the transposons isolated from the virus mutants duplicated a TTAA tetranucleotide target site upon insertion into the viral genome. Four of these TFP3 elements transposed into three different 'TTAA' target sites within the 25 K gene (FP locus, map units 36-37 of AcMNPV). The fifth TFP3 element inserted at a 'TTAA' site within the AcMNPV Hin dIII-E fragment. One genomic TFP3 element, amplified from the TN-368 cell line DNA by an inverse PCR method, duplicated a 'TTAA' tetranucleotide target site that is present only once in the homologous larval DNA sequence. These data suggest that mobilization of TFP3 into both viral and cellular sites is identical in specificity and mechanism.

A simple and efficient system for the construction of phoA gene fusions in gram-negative bacteria

We have developed a two-plasmid system for generating gene fusions between phoA and cloned genes encoding envelope proteins. The vector plasmid carries a temperature-sensitive replication system and can be rescued at high temperature by insertion of an IS1-based transposon carrying the ori region of pBR322 and a phoA gene lacking transcription and translation initiation signals. The vector plasmid also carries the transfer origin of the conjugative plasmid, F, permitting transfer into a suitable recipient strain. We have used this system in the analysis of the bla gene cloned from pBR322.

Transposon mutagenesis of baculoviruses: analysis of Trichoplusia ni transposon IFP2 insertions within the FP-locus of nuclear polyhedrosis viruses

The transposable IFP2 element of Trichoplusia ni was originally isolated as a host DNA insertion in spontaneous FP mutants of Galleria mellonella or Autographa californica nuclear polyhedrosis viruses (NPVs). The termini of IFP2 insertions from five independently isolated FP mutants were sequenced. In all cases IFP2 is flanked by 13-bp terminal inverted repeats and has additional inverted repeats of 19 bp in length located asymmetrically with respect to the ends of the element. Insertion of IFP2 into the viral genome always generated a duplication of the tetranucleotide target site, TTAA. There was an apparent preference for insertion within a 12-bp A + T-rich imperfect palindromic sequence surrounding the target site. Sequence analysis of three independent IFP2 elements revealed an internal domain of 2.475 kb containing an RNA polymerase II promoter region and two large open reading frames. Primer extension analysis of IFP2-specific mRNA positioned the 5' terminus of the transcript. The element is present in DNA isolated from T. ni cell lines TN-368 and TN-5B1, but is not apparent in DNAs isolated from the TN-R2 cell line or our laboratory colony of T. ni larvae, suggesting IFP2 was recently introduced into the T. ni genome.

Rhizobium meliloti insertion element ISRm2 and its use for identification of the fixX gene

Two of the three plasmids of the wild-type Rhizobium meliloti 41 (pRme41a and pRme41c) carry a copy of ISRm2, a 2.7-kilobase-long transposable element. ISRm2 is terminated by 22-base-pair (bp) inverted repeat sequences, exhibiting some homology to the inverted repeats of elements generating 9-bp target sequence duplication. Transposition of ISRm2 results in a duplication of 8 bp in length, rather rare among transposable elements. DNA sequences homologous to an internal fragment of ISRm2 were found in several Rhizobium species. Transposition of ISRm2 into fixation and nodulation genes located on the symbiotic plasmid pRme41b was detected at a high frequency. Exact locations of two copies of ISRm2 which transposed into the nod-nif region on the megaplasmid were determined. In one case, integration into the protein-coding region of the hsnD gene that determines a host specificity function of nodulation occurred. In the other mutant, ISRm2 was localized upstream of nifA, where a short open reading frame coding for a new fix gene (fixX) was identified. The product of fixX is a ferredoxin carrying a characteristic cluster of cysteine residues. On the basis of the observation that the arrangement of the ISRm2 copies is identical in the free-living wild-type cells and in nitrogen-fixing nodules, we concluded that the involvement of ISRm2 transposition in the development of nitrogen-fixing symbiosis is unlikely.

Functional promoters created by the insertion of transposable element IS1

We have isolated several insertions of the transposable element IS1 into the proximal promoter (P3) of the beta-lactamase gene of plasmid pBR322, which do not abolish resistance to ampicillin. Using a transcription termination module (omega), we have shown that the gene can be expressed from hybrid promoters, created by the insertion of IS1. The terminal inverted repeats of IS1 carry sequences partially homologous to the "-35" consensus region. Splicing either of these sequences to the existing "-10" region of the beta-lactamase promoter by transposition of IS1 at the proper distance results in the formation of an active hybrid promoter. This interpretation was confirmed by transcription studies in vitro. Gene expression from the hybrid promoters was found to be less efficient than from P3. However, the orientation of IS1 that contributes a "-35" with the greater homology to the known "-35" consensus sequence is significantly more efficient than the other. In addition, we were able to assign a strong determinant of IS1 polarity to a 254 base-pair internal segment of IS1. An examination of the ends of many insertion sequences leads us to expect that the phenomenon described here may occur with several of these transposable elements, and may have an unexpected evolutionary significance.

Enhancement of bacterial gene expression by insertion elements or by mutation in a CAP-cAMP binding site

The regulatory region (bglR) of the cryptic bgl operon was characterized by DNA sequence analysis and transcription mapping. Bgl(-)-specific transcription was found to occur in both the wild-type Bgl- and mutant Bgl+ cells. However, the steady-state level of bgl RNA was much higher in the Bgl+ mutant than in the wild-type. Activation of the bgl operon by insertion sequence-mediated bglR mutations or point mutations in bglR is therefore the result of increased transcription. The ethylmethane sulfonate-induced point mutations in bglR are alterations in a single base in the cAMP binding protein (CAP) binding site, leading to a stronger binding of the CAP-cAMP complex. The IS1 and IS5-mediated bglR mutations analyzed show that the insertion sequences can activate the bgl operon by integration 78 to 125 base-pairs upstream from the transcription initiation site. The role of the insertion sequences in activation of the bgl operon is discussed.

Sequence relations among the IncY plasmid p15B, P1, and P7 prophages

Electron microscopic analysis of heteroduplex molecules between the 94-kb plasmid p15B and the 92-kb phage P1 genome revealed nine regions of nonhomology, eight substitutions, and two neighboring insertions. Overall, the homologous segments correspond to 83% of the P1 genome and 81% of p15B. Heteroduplex molecules between p15B and the 99-kb phage P7 genome showed nonhomology in eight of the same nine regions; in addition, two new nonhomologous segments are present and P7 carries a 5-kb insertion representing Tn902. The DNA homology between those two genomes amounts to 79% of P7 DNA and 83% of p15B. Plasmid p15B contains two stem-loop structures. One of them has no equivalent structure on P1 and P7 DNA. The other substitutes the invertible C segments of P1 and P7 and their flanking sequences including cin, the gene for the site-specific recombinase mediating inversion.

Denaturation maps of Bacillus licheniformis phages LP52 and theta DNAs

Employing electron microscopy (EM) of partially denatured DNAs of phages LP52 and theta, distinct denaturation maps were determined and correlated with published restriction and heteroduplex maps. The pattern of early melting regions is similar although the two phages share only 50% nucleotide sequence homology.

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.

Specificity of insertion of IS1

A systematic study of the specificity of insertion of the transposable element IS1 into small defined-sequence plasmids (pBR322 and derivatives) was conducted to determine the features of the DNA sequence that influence target site selection. We have physically mapped several collections of independent insertions of IS1 into these plasmids and have determined: (1) that about 80% of all insertions occur in the DNA segment (about 200 base-pairs) between the unique EcoRI site of pBR322 and the beginning of the beta-lactamase gene, one of the two regions of high A + T density in this plasmid; (2) that there is a strong orientation effect in this region (almost all IS1 insertions are in one orientation) that depends on both the pBR322 sequence and the environment of the transposon in the donor molecule; and (3) that the orientation effect does not depend on the strong transcription that is directed through this region in pBR322. Furthermore, we have found that insertion of a poly(dA X dT) segment into pBR322 creates an artificial hotspot for IS1 insertion, even though it is not as attractive for insertion as the above-mentioned major hotspot. Our observations suggest that an interplay between several properties of the target sequences and the sequence environment of the donor transposon is responsible for the observed specificity of position and orientation. One of the possibilities discussed here is that preferred "entry-sites", or "signal" sequences, for the transposition complex play a major role in determining the positions and orientations of IS1 insertions.

Recombination in recA cells between direct repeats of insertion element IS1

The IS1 sequences that flank the Tn9 chloramphenicol acetyltransferase gene as direct repeats recombine after transformation into an Escherichia coli recA strain. The recombination requires the lambda pL promoter on the plasmid. A plasmid that contains mutant IS1 elements does not recombine. These results indicate that this recombination requires an IS1-specific gene product. The recombinational activity of IS1 may resolve transient cointegrates formed during the transposition of IS1. I discuss a possible role for the lambda pL promoter.

In vitro insertional mutagenesis with a selectable DNA fragment

A new method for in vitro insertional mutagenesis of genes cloned in Escherichia coli is presented. This simple procedure combines the advantages of in vitro DNA linker mutagenesis with those of in vivo transposition mutagenesis. It makes use of the omega fragment, a 2.0-kb DNA segment consisting of an antibiotic resistance gene (the Smr/Spcr gene of the R100.1 plasmid) flanked by short inverted repeats carrying transcription and translation termination signals and synthetic polylinkers. The omega fragment is inserted into a linearized plasmid by in vitro ligation, and the recombinant DNA molecules are selected by their resistance to streptomycin and spectinomycin. The omega fragment terminates RNA and protein synthesis prematurely, thus allowing the definition and mapping of both transcription and translation units. Because of the symmetrical structure of omega, the same effect is obtained with insertions in either orientation. The antibiotic resistance gene can be subsequently excised from the mutated molecules, leaving behind its flanking restriction site(s).

Conduction of nonconjugative plasmids by F' lac is not necessarily associated with transposition of the gamma delta sequence

A nonconjugative kanamycin-resistant (Kmr) recombinant plasmid, pNR5311, transferred at a low frequency from an Hfr or F' lac Escherichia coli donor to an F- lac- recipient. Among the transconjugants, two types of Kmr plasmids were found: one was indistinguishable from pNR5311 (type A), and the other was a recombinant between pNR5311 and the gamma delta sequence (type B). When the F' lac strain was used as a donor, 5% of lactose-fermenting (Lac+) and 75% of lactose-nonfermenting (Lac-) transconjugants had type A plasmids. A kinetic study revealed that type A plasmids were transferred more readily in short mating periods than were type B plasmids. Involvement of Tn903, which is present in pNR5311, in transfer of type A plasmids was unlikely since there was no discernible change in the F' lac molecule coexisting with the type A plasmid in the transconjugant cells. The non-gamma delta-associated conduction of pNR5311 by F' lac did not require the recA+ function of the donor. Conduction of pBR322 by F' lac was also carried out, and two types of plasmids with and without gamma delta were found, as with pNR5311. These findings suggest that the transfer of nonconjugative plasmids is conducted by a novel pathway which is not associated with translocation of transposable elements into either plasmid.

DNA restriction--modification genes of phage P1 and plasmid p15B. Structure and in vitro transcription

The EcoP1 and EcoP15 DNA restriction-modification systems are coded by the related P1 prophage and p15B plasmid. We have examined the organization of the genes for these systems using P1 itself, "P1-P15" hybrid phages expressing the EcoP15 restriction specificity of p15B and cloned restriction fragments derived from these phage DNAs. The results of transposon mutagenesis, restriction cleavage analysis. DNA heteroduplex analysis and in vitro transcription mapping allow the following conclusions to be drawn concerning the structural genes. (1) All of the genetic information necessary to specify either system is contained within a contiguous DNA segment of 5 x 10(3) bases which encodes two genes. One of them, necessary for both restriction and modification, we call mod and the other, required only for restriction (together with mod), we call res. (2) The res gene is about 2.8 x 10(3) bases long and at the heteroduplex level is largely identical for P1 and P15: it shows a small region of partial nonhomology and some restriction cleavage site differences. The mod gene is about 2.2 x 10(3) bases long and contains a 1.2 x 10(3) base long region of non-homology between P1 and P15 toward the N-terminus of the gene. The rest of the gene at this level of analysis is identical for the two systems. (3) Each of the genes is transcribed in vitro from its own promoter. It is possible that the res gene is also transcribed by readthrough from the mod promoter.

Cointegrational transduction and mobilization of gentamicin resistance plasmid pWP14a is mediated by IS140

The structures of two R-plasmids pWP14a and pWP12a (Tra-, Ap, Gm; 21 kb) and of several cointegrates they form with bacteriophages P1Cm and P1-15 were analyzed. In each case, replicon fusion was mediated by the element IS140 (about 0.8 kb), one copy of which resides on both plasmids adjacent to the gentamicin resistance determinant (AAC(3)-III). pWP14a cointegrated preferentially into or near the invertible C-loop structure of the P1 genome. Cointegrational mobilization of pWP14a was observed also with several conjugative R-factors. The process of replicon fusion is independent of the host's rec+ functions. Sequences homologous to IS140 are constituents of many R-factors, including RA1, R40a, R124, R144, Rts1, N3, and pJR255. IS140 also shows homology to two other sequences, IS15 delta and Tn2680, but not to other, well studied transposable elements. The ampicillin resistance determinant of pWP14a is within a Tn3-like transposon, Tn3651.

DNA of the Streptomyces phage SH10: binding sites for Escherichia coli RNA polymerase and denaturation map

Escherichia coli RNA polymerase bound to Streptomyces phage SH10 DNA was visualized by electron microscopy. Six specific binding sites were observed at map units 53, 85, 93, 97, 98, and 99 on the physical map of the 48 kb long genome. Electron microscopy of partially denatured SH10 DNA revealed a characteristic melting pattern of A + T-rich regions around map units 1, 3, 48, 52, and 99. A comparison of the denaturation map with the RNA polymerase binding sites indicates that three binding sites are located in the most A + T-rich regions, two in other early melting regions and one in a segment of higher DNA helix stability.

A symmetrical six-base-pair target site sequence determines Tn10 insertion specificity

Transposon Tn10 inserts at many sites in the bacterial chromosome, but preferentially inserts at particular hotspots. We believe we have identified the target DNA signal responsible for this specificity. We have determined the DNA sequences of 11 Tn10 insertion sites and identified a particular 6 base pair (bp) symmetrical consensus sequence (GCTNAGC) common to those sites. The sequences at some sites differ from the consensus sequence but only in limited and well defined ways. The sequences at some sites differ from the consensus sequence than do sequences at other sites, and the consensus sequence and closely related sequences are generally absent from potential target regions where Tn10 is known not to insert. Other aspects of the target DNA can significantly influence the efficiency with which a particular target site sequence is used. The 6 bp consensus sequence is symmetrically located within the 9 bp target DNA sequence that is cleaved and duplicated during Tn10 insertion. This juxtaposition of recognition and cleavage sites plus the symmetry of the perfect consensus sequence suggest that the target DNA may be both recognized and cleaved by the symmetrically disposed subunits of a single protein, as suggested for type II restriction endonucleases. There is plausible homology between the consensus sequence and the very ends of Tn10, compatible with recognition of transposon ends and target DNA by the same protein. The sequences of actual insertion sites deviate from the perfect consensus sequence in a way which suggests that the 6 bp specificity determinant may be recognized through protein-DNA contacts along the major groove of the DNA double helix.

A fine structure map of spontaneous and induced mutations in the lambda repressor gene, including insertions of IS elements

Mutations at over 70 sites in the cI gene have been mapped by 4-factor crosses and assigned precise or approximate positions in the DNA sequence. 16 of 25 spontaneous mutations were insertions of IS1, IS3 or IS5 into AT-rich regions of cI. The 5-methylcytosine in the sequence Cm5CAGG is a hot spot for spontaneous cI amber mutations. Recombination frequencies between mutations were proportional to distance with the exception of amber mutations at 4 sites, including the host spot for spontaneous mutations. Mutations with a given phenotype are clustered on the genetic map. No missense mutations affecting repressor activity were found in the central one-third of cI, but 5 of 6 ind- mutations were located in this region. The amino-terminal third of the gene contains the sites of most trans-dominant cI- mutations, and of all ts mutations that result in repressors that are reversibly inactivated at high temperatures.

Integration specificity of an artificial kanamycin transposon constructed by the in vitro insertion of an internal Tn5 fragment into IS2

IS2 has been marked genetically by the in vitro insertion into its HindIII site of a 3.3 Kb HindIII fragment of Tn5 conferring resistance to kanamycin. The transposition of the IS2::Km, thus obtained, to lambda has been found and insertion sites were characterised. Each of ten independent IS2::Km insertions were found at the same site at 61.2% of the lambda map, always in the same orientation (orientation II relative to the xis gene). The integration sites of IS2::Km in five of the kanamycin-transducing phages were determined by DNA sequence analysis, and were found to be identical at the nucleotide level. Further transposition of IS2::Km from lambda to the bacterial chromosome was demonstrated.

On the molecular mechanisms of transposition

We present a model for transposition that allows a choice between cointegrate formation (replicon fusion) and direct transposition. We propose that initiation of the process occurs by invasion of the target DNA by a single-stranded end of the transposable element. This leads to nicking of one of the DNA strands of the target molecule and ligation of this strand to that of the invading transposon. Transposition then occurs in a processive way by replication of the element from the invading end into the target site in a looped rolling-circle mode similar to replication of phage phi X174 replicative form to viral strand. The choice between cointegrate formation and direct transposition occurs at the nick-ligation step, which terminates the process. We suggest that the choice is determined by the topology of the transposition enzymes and could be related to whether the element generates five- or nine-base-pair repeats in the target DNA on insertion.

The sequence of IS4

IS-elements are devoid of easily recognizable transacting functions and exert their visible effects in the position cis only (recent reviews Calos and Miller 1980; Starlinger 1980). It has been a matter of debate, whether these elements encode functions for their own transposition. In the case of the E. coli IS-elements this could not easily be determined by genetic methods, because most of these elements are present in several copies (Saedler and Heiss 1973; Deonier et al. 1979). In the case of the IS-elements flanking transposons, evidence has recently been brought forward that these carry the transposition specificity (Rothstein et al. 1980; Kleckner 1980; Grindley 1981). IS4 is present in one copy only in several E. coli K12 strains and should, therefore, be suitable for genetic and physiological studies (Chadwell et al. 1979). It has been cloned from several sites on the E. coli chromosome in pBR322 (Klaer and Starlinger 1980). Here we report the DNA sequence of IS4 which contains an open reading frame for 442 amino acids, and of the junctions of this element with surrounding DNA at three different sites in the E. coli chromosome.

Nucleotide sequence of acceptor site and termini of integrated avian endogenous provirus ev1: integration creates a 6 bp repeat of host DNA

The nucleotide sequences at the junctions between host cellular and integrated proviral DNA at the chicken endogenous retrovirus locus ev1 have been determined. These sequences have been compared with that of a DNA fragment presumed to contain the acceptor site for integration of the provirus at this locus. The results show that the integrated ev1 provirus contains a long terminal repeat (LTR) of 273 base pairs (bp). The left and right LTR are identical and contain sequences similar to proposed transcription control signals. In addition, there is a direct repeat of 6 bp of host DNA immediately flanking each provirus terminus. The nucleotide sequence of the fragment that contains the unoccupied acceptor site is identical to that which flanks the ev1 provirus, except that the 6 bp sequence occurs only once. We propose that the repeat was produced during integration by a mechanism similar to that of procaryotic and eucaryotic transposable genetic elements. This and other similarities in structure suggest a common evolution and mode of function for these movable genetic elements.