The evolution of insertion sequences within enteric bacteria

Ancient Darwinian replicators nested within eubacterial genomes

Integrative mobile genetic elements (MGEs), such as transposons and insertion sequences, propagate within bacterial genomes, but persistence times in individual lineages are short. For long-term survival, MGEs must continuously invade new hosts by horizontal transfer. Theoretically, MGEs that persist for millions of years in single lineages, and are thus subject to vertical inheritance, should not exist. Here we draw attention to an exception - a class of MGE termed REPIN. REPINs are non-autonomous MGEs whose duplication depends on non-jumping RAYT transposases. Comparisons of REPINs and typical MGEs show that replication rates of REPINs are orders of magnitude lower, REPIN population size fluctuations correlate with changes in available genome space, REPIN conservation depends on RAYT function, and REPIN diversity accumulates within host lineages. These data lead to the hypothesis that REPINs form enduring, beneficial associations with eubacterial chromosomes. Given replicative nesting, our hypothesis predicts conflicts arising from the diverging effects of selection acting simultaneously on REPINs and host genomes. Evidence in support comes from patterns of REPIN abundance and diversity in two distantly related bacterial species. Together this bolsters the conclusion that REPINs are the genetic counterpart of mutualistic endosymbiotic bacteria.

Differential degeneration of the ACTAGT sequence among Salmonella: a reflection of distinct nucleotide amelioration patterns during bacterial divergence

When bacteria diverge, they need to adapt to the new environments, such as new hosts or different tissues of the same host, by accumulating beneficial genomic variations, but a general scenario is unknown due to the lack of appropriate methods. Here we profiled the ACTAGT sequence and its degenerated forms (i.e., hexa-nucleotide sequences with one of the six nucleotides different from ACTAGT) in Salmonella to estimate the nucleotide amelioration processes of bacterial genomes. ACTAGT was mostly located in coding sequences but was also found in several intergenic regions, with its degenerated forms widely scattered throughout the bacterial genomes. We speculated that the distribution of ACTAGT and its degenerated forms might be lineage-specific as a consequence of different selection pressures imposed on ACTAGT at different genomic locations (in genes or intergenic regions) among different Salmonella lineages. To validate this speculation, we modelled the secondary structures of the ACTAGT-containing sequences conserved across Salmonella and many other enteric bacteria. Compared to ACTAGT at conserved regions, the degenerated forms were distributed throughout the bacterial genomes, with the degeneration patterns being highly similar among bacteria of the same phylogenetic lineage but radically different across different lineages. This finding demonstrates biased amelioration under distinct selection pressures among the bacteria and provides insights into genomic evolution during bacterial divergence.

Elucidation of insertion elements carried on plasmids and in vitro construction of shuttle vectors from the toxic cyanobacterium Planktothrix

Several gene clusters that are responsible for toxin synthesis in bloom-forming cyanobacteria have been found to be associated with transposable elements (TEs). In particular, insertion sequence (IS) elements were shown to play a role in the inactivation or recombination of the genes responsible for cyanotoxin synthesis. Plasmids have been considered important vectors of IS element distribution to the host. In this study, we aimed to elucidate the IS elements propagated on the plasmids and the chromosome of the toxic cyanobacterium Planktothrix agardhii NIVA-CYA126/8 by means of high-throughput sequencing. In total, five plasmids (pPA5.5, pPA14, pPA50, pPA79, and pPA115, of 5, 6, 50, 79, and 120 kbp, respectively) were elucidated, and two plasmids (pPA5.5, pPA115) were found to propagate full IS element copies. Large stretches of shared DNA information between plasmids were constituted of TEs. Two plasmids (pPA5.5, pPA14) were used as candidates to engineer shuttle vectors (named pPA5.5SV and pPA14SV, respectively) in vitro by PCR amplification and the subsequent transposition of the Tn5 cat transposon containing the R6Kγ origin of replication of Escherichia coli. While pPA5.5SV was found to be fully segregated, pPA14SV consistently co-occurred with its wild-type plasmid even under the highest selective pressure. Interestingly, the Tn5 cat transposon became transferred by homologous recombination into another plasmid, pPA50. The availability of shuttle vectors is considered to be of relevance in investigating genome plasticity as a consequence of homologous recombination events. Combining the potential of high-throughput sequencing and in vitro production of shuttle vectors makes it simple to produce species-specific shuttle vectors for many cultivable prokaryotes.

Rapid quantification of sequence repeats to resolve the size, structure and contents of bacterial genomes

BACKGROUND

The numerous classes of repeats often impede the assembly of genome sequences from the short reads provided by new sequencing technologies. We demonstrate a simple and rapid means to ascertain the repeat structure and total size of a bacterial or archaeal genome without the need for assembly by directly analyzing the abundances of distinct k-mers among reads.

RESULTS

The sensitivity of this procedure to resolve variation within a bacterial species is demonstrated: genome sizes and repeat structure of five environmental strains of E. coli from short Illumina reads were estimated by this method, and total genome sizes corresponded well with those obtained for the same strains by pulsed-field gel electrophoresis. In addition, this approach was applied to read-sets for completed genomes and shown to be accurate over a wide range of microbial genome sizes.

CONCLUSIONS

Application of these procedures, based solely on k-mer abundances in short read data sets, allows aspects of genome structure to be resolved that are not apparent from conventional short read assemblies. This knowledge of the repetitive content of genomes provides insights into genome evolution and diversity.

A new subgroup of the IS3 family and properties of its representative member ISPpy1

Recently, we described a novel insertion element, ISPpy1, isolated from a permafrost strain of Psychrobacter maritimus. In this work, we demonstrated that ISPpy1 is a member of a novel subgroup of the IS3 family of insertion sequences (ISs) that was not identified and characterized previously. IS elements of this subgroup termed the ISPpy1 subgroup are broadly distributed among different taxa of Eubacteria, including Geobacteraceae, Chlorobiaceae, Desulfobacteraceae, Methylobacteriaceae, Nitrosomonadaceae and Cyanobacteria. While displaying characteristic features of the IS3-family elements, ISPpy1 subgroup elements exhibit some unusual features. In particular, most of them have longer terminal repeats with unconventional ends and frameshifting box with an atypical organization, and, unlike many other IS3-family elements, do not exhibit any distinct IS specificity. We studied the transposition and mutagenic properties of a representative member of this subgroup, ISPpy1 and showed that in contrast to the original P. maritimus host, in a heterologous host, Escherichia coli K-12, it is able to translocate with extremely high efficiency into the chromosome, either by itself or as a part of a composite transposon containing two ISPpy1 copies. The majority of transposants carry multiple chromosomal copies (up to 12) of ISPpy1. It was discovered that ISPpy1 is characterized by a marked mutagenic activity in E. coli: its chromosomal insertions generate various types of mutations, including auxotrophic, pleiotropic and rifampicin-resistance mutations. The distribution of IS elements of the novel subgroup among different bacteria, their role in the formation of composite transposons and the horizontal transfer of genes are examined and discussed.

Selection-driven extinction dynamics for group II introns in Enterobacteriales

Transposable elements (TEs) are one of the major driving forces of genome evolution, raising the question of the long-term dynamics underlying their evolutionary success. Some TEs were proposed to evolve under a pattern of periodic extinctions-recolonizations, in which elements recurrently invade and quickly proliferate within their host genomes, then start to disappear until total extinction. Depending on the model, TE extinction is assumed to be driven by purifying selection against colonized host genomes (Sel-DE model) or by saturation of host genomes (Sat-DE model). Bacterial group II introns are suspected to follow an extinction-recolonization model of evolution, but whether they follow Sel-DE or Sat-DE dynamics is not known. Our analysis of almost 200 group II intron copies from 90 sequenced Enterobacteriales genomes confirms their extinction-recolonization dynamics: patchy element distributions among genera and even among strains within genera, acquisition of new group II introns through plasmids or other mobile genetic elements, and evidence for recent proliferations in some genomes. Distributions of recent and past proliferations and of their respective homing sites further provide strong support for the Sel-DE model, suggesting that group II introns are deleterious to their hosts. Overall, our observations emphasize the critical impact of host properties on TE dynamics.

Factors behind junk DNA in bacteria

Although bacterial genomes have been traditionally viewed as being very compact, with relatively low amounts of repetitive and non-coding DNA, this view has dramatically changed in recent years. The increase of available complete bacterial genomes has revealed that many species present abundant repetitive DNA (i.e., insertion sequences, prophages or paralogous genes) and that many of these sequences are not functional but can have evolutionary consequences as concerns the adaptation to specialized host-related ecological niches. Comparative genomics analyses with close relatives that live in non-specialized environments reveal the nature and fate of this bacterial junk DNA. In addition, the number of insertion sequences and pseudogenes, as well as the size of the intergenic regions, can be used as markers of the evolutionary stage of a genome.

OASIS: an automated program for global investigation of bacterial and archaeal insertion sequences

Insertion sequences (ISs) are simple transposable elements present in most bacterial and archaeal genomes and play an important role in genomic evolution. The recent expansion of sequenced genomes offers the opportunity to study ISs comprehensively, but this requires efficient and accurate tools for IS annotation. We have developed an open-source program called OASIS, or Optimized Annotation System for Insertion Sequences, which automatically annotates ISs within sequenced genomes. OASIS annotations of 1737 bacterial and archaeal genomes offered an unprecedented opportunity to examine IS evolution. At a broad scale, we found that most IS families are quite widespread; however, they are not present randomly across taxa. This may indicate differential loss, barriers to exchange and/or insufficient time to equilibrate across clades. The number of ISs increases with genome length, but there is both tremendous variation and no increase in IS density for genomes >2 Mb. At the finer scale of recently diverged genomes, the proportion of shared IS content falls sharply, suggesting loss and/or emergence of barriers to successful cross-infection occurs rapidly. Surprisingly, even after controlling for 16S rRNA sequence divergence, the same ISs were more likely to be shared between genomes labeled as the same species rather than as different species.

Short- and long-term evolutionary dynamics of bacterial insertion sequences: insights from Wolbachia endosymbionts

Transposable elements (TE) are one of the major driving forces of genome evolution, raising the question of the long-term dynamics underlying their evolutionary success. Long-term TE evolution can readily be reconstructed in eukaryotes, thanks to many degraded copies constituting genomic fossil records of past TE proliferations. By contrast, bacterial genomes usually experience high sequence turnover and short TE retention times, thereby obscuring ancient TE evolutionary patterns. We found that Wolbachia bacterial genomes contain 52–171 insertion sequence (IS) TEs. IS account for 11% of Wolbachia wRi, which is one of the highest IS genomic coverage reported in prokaryotes to date. We show that many IS groups are currently expanding in various Wolbachia genomes and that IS horizontal transfers are frequent among strains, which can explain the apparent synchronicity of these IS proliferations. Remarkably, >70% of Wolbachia IS are nonfunctional. They constitute an unusual bacterial IS genomic fossil record providing direct empirical evidence for a long-term IS evolutionary dynamics following successive periods of intense transpositional activity. Our results show that comprehensive IS annotations have the potential to provide new insights into prokaryote TE evolution and, more generally, prokaryote genome evolution. Indeed, the identification of an important IS genomic fossil record in Wolbachia demonstrates that IS elements are not always of recent origin, contrary to the conventional view of TE evolution in prokaryote genomes. Our results also raise the question whether the abundance of IS fossils is specific to Wolbachia or it may be a general, albeit overlooked, feature of prokaryote genomes.

Do phages efficiently shuttle transposable elements among prokaryotes?

The distribution, dynamics, and evolution of insertion sequences (IS), the most frequent class of prokaryotic transposable elements, are conditioned by their ability to horizontally transfer between cells. IS horizontal transfer (HT) requires shuttling by other mobile genetic elements. It is widely assumed in the literature that these vectors are phages and plasmids. By examining the relative abundance of IS in 454 plasmid and 446 phage genomes, we found that IS are very frequent in plasmids but, surprisingly, very rare in phages. Our results indicate that IS rarity in phages reflects very strong and efficient postinsertional purifying selection, mainly caused by a higher density of deleterious insertion sites in phages compared to plasmids. As they do not tolerate IS insertions, we conclude that phages may be rather poor vectors of IS HT in prokaryotes, in sharp contrast with the conventional view.

The distribution of a phage-related insertion sequence element in the cyanobacterium, Microcystis aeruginosa

The cyanophage Ma-LMM01, specifically-infecting Microcystis aeruginosa, has an insertion sequence (IS) element that we named IS607-cp showing high nucleotide similarity to a counterpart in the genome of the cyanobacterium Cyanothece sp. We tested 21 strains of M. aeruginosa for the presence of IS607-cp using PCR and detected the element in strains NIES90, NIES112, NIES604, and RM6. Thermal asymmetric interlaced PCR (TAIL-PCR) revealed each of these strains has multiple copies of IS607-cp. Some of the ISs were classified into three types based on their inserted positions; IS607-cp-1 is common in strains NIES90, NIES112 and NIES604, whereas IS607-cp-2 and IS607-cp-3 are specific to strains NIES90 and RM6, respectively. This multiplicity may reflect the replicative transposition of IS607-cp. The sequence of IS607-cp in Ma-LMM01 showed robust affinity to those found in M. aeruginosa and Cyanothece spp. in a phylogenetic tree inferred from counterparts of various bacteria. This suggests the transfer of IS607-cp between the cyanobacterium and its cyanophage. We discuss the potential role of Ma-LMM01-related phages as donors of IS elements that may mediate the transfer of IS607-cp; and thereby partially contribute to the genome plasticity of M. aeruginosa.

Insertion sequence content reflects genome plasticity in strains of the root nodule actinobacterium Frankia

Background

Genome analysis of three Frankia sp. strains has revealed a high number of transposable elements in two of the strains. Twelve out of the 20 major families of bacterial Insertion Sequence (IS) elements are represented in the 148 annotated transposases of Frankia strain HFPCcI3 (CcI3) comprising 3% of its total coding sequences (CDS). EAN1pec (EAN) has 183 transposase ORFs from 13 IS families comprising 2.2% of its CDS. Strain ACN14a (ACN) differs significantly from the other strains with only 33 transposase ORFs (0.5% of the total CDS) from 9 IS families.

Results

Insertion sequences in the Frankia genomes were analyzed using BLAST searches, PHYML phylogenies and the IRF (Inverted Repeat Finder) algorithms. To identify putative or decaying IS elements, a PSI-TBLASTN search was performed on all three genomes, identifying 36%, 39% and 12% additional putative transposase ORFs than originally annotated in strains CcI3, EAN and ACN, respectively. The distribution of transposase ORFs in each strain was then analysed using a sliding window, revealing significant clustering of elements in regions of the EAN and CcI3 genomes. Lastly the three genomes were aligned with the MAUVE multiple genome alignment tool, revealing several Large Chromosome Rearrangement (LCR) events; many of which correlate to transposase clusters.

Conclusion

Analysis of transposase ORFs in Frankia sp. revealed low inter-strain diversity of transposases, suggesting that the majority of transposase proliferation occurred without recent horizontal transfer of novel mobile elements from outside the genus. Exceptions to this include representatives from the IS3 family in strain EAN and seven IS4 transposases in all three strains that have a lower G+C content, suggesting recent horizontal transfer. The clustering of transposase ORFs near LCRs revealed a tendency for IS elements to be associated with regions of chromosome instability in the three strains. The results of this study suggest that IS elements may help drive chromosome differences in different Frankia sp. strains as they have adapted to a variety of hosts and environments.

Experimental evolution of an essential Bacillus gene in an E. coli host

The acquisition of foreign genes by HGT potentially greatly speeds up adaptation by allowing faster evolution of beneficial traits. The evolutionary integration of novel genes into host gene expression and physiology is critical for adaptation by HGT, but remains largely unknown. We are exploring the evolutionary consequences of gene acquisition in populations of Escherichia coli in real time. A plasmid bearing the genes necessary for sucrose catabolism was constructed and introduced into a single E. coli genotype. Wild-type E. coli is generally incapable of utilizing sucrose, but E. coli transformants were able to grow on sucrose as a sole carbon and energy source, albeit poorly. Twelve replicate populations were initiated and propagated in sucrose minimal media for 300 generations. Over this time, we observed large fitness improvements in the selected environment. These results demonstrate the potential for HGT to substantially increase microbial niche breadth.

Distant horizontal gene transfer is rare for multiple families of prokaryotic insertion sequences

Horizontal gene transfer in prokaryotes is rampant on short and intermediate evolutionary time scales. It poses a fundamental problem to our ability to reconstruct the evolutionary tree of life. Is it also frequent over long evolutionary distances? To address this question, we analyzed the evolution of 2,091 insertion sequences from all 20 major families in 438 completely sequenced prokaryotic genomes. Specifically, we mapped insertion sequence occurrence on a 16S rDNA tree of the genomes we analyzed, and we also constructed phylogenetic trees of the insertion sequence transposase coding sequences. We found only 30 cases of likely horizontal transfer among distantly related prokaryotic clades. Most of these horizontal transfer events are ancient. Only seven events are recent. Almost all of these transfer events occur between pairs of human pathogens or commensals. If true also for other, non-mobile DNA, the rarity of distant horizontal transfer increases the odds of reliable phylogenetic inference from sequence data.

Characterization of a new variant of IS257 that has displaced the capsule genes within bovine isolates of Staphylococcus aureus

Many bovine Staphylococcus aureus isolates from Argentina are nontypeable (NT), i.e., they do not produce serotype 5 or 8 capsular polysaccharides (CPs). Some of these NT strains have a deletion of the cap5(8) gene cluster mediated by a variant of IS257, now designated IScap. IScap showed 93% amino acid identity to S. aureus ORF49 but only 85% identity to IS431 from S. aureus N315 and 88% identity to an IS257-like element from bovine strain RF122. Thirty-six (53%) of 68 bovine isolates, drawn from a previously described S. aureus strain collection, carried some variant of IS257, including IScap. Of these 36 IS+ isolates, 6 were CP5+, 1 was CP8+, and 29 were NT. Forty-four of the 68 isolates were NT, and 24 of these 44 NT isolates (55%) exhibited IScap-mediated deletion of the cap5(8) gene cluster. IScap was not found among 20 human NT S. aureus isolates bearing the cap5HIJK genes, which suggests that IScap-mediated deletion of the capsule locus is restricted to bovine strains of S. aureus. We were unable to identify a precursor strain in which IScap flanked the cap5(8) capsule locus, nor were we able to select for deletion of the cap5(8) locus in vitro. Our results support the hypothesis that deletion of the cap5 locus occurred in the distant past and that the relative abundance of these NT strains may be a result of their ability to persist in subclinical mastitis infection in cows.

A survey of bacterial insertion sequences using IScan

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

Causes of insertion sequences abundance in prokaryotic genomes

Insertion sequences (ISs) are the smallest and most frequent transposable elements in prokaryotes where they play an important evolutionary role by promoting gene inactivation and genome plasticity. Their genomic abundance varies by several orders of magnitude for reasons largely unknown and widely speculated. The current availability of hundreds of genomes renders testable many of these hypotheses, notably that IS abundance correlates positively with the frequency of horizontal gene transfer (HGT), genome size, pathogenicity, nonobligatory ecological associations, and human association. We thus reannotated ISs in 262 prokaryotic genomes and tested these hypotheses showing that when using appropriate controls, there is no empirical basis for IS family specificity, pathogenicity, or human association to influence IS abundance or density. HGT seems necessary for the presence of ISs, but cannot alone explain the absence of ISs in more than 20% of the organisms, some of which showing high rates of HGT. Gene transfer is also not a significant determinant of the abundance of IS elements in genomes, suggesting that IS abundance is controlled at the level of transposition and ensuing natural selection and not at the level of infection. Prokaryotes engaging in obligatory associations have fewer ISs when controlled for genome size, but this may be caused by some being sexually isolated. Surprisingly, genome size is the only significant predictor of IS numbers and density. Alone, it explains over 40% of the variance of IS abundance. Because we find that genome size and IS abundance correlate negatively with minimal doubling times, we conclude that selection for rapid replication cannot account for the few ISs found in small genomes. Instead, we show evidence that IS numbers are controlled by the frequency of highly deleterious insertion targets. Indeed, IS abundance increases quickly with genome size, which is the exact inverse trend found for the density of genes under strong selection such as essential genes. Hence, for ISs, the bigger the genome the better.

Positive selection on transposase genes of insertion sequences in the Crocosphaera watsonii genome

Insertion sequences (ISs) are mobile elements that are commonly found in bacterial genomes. Here, the structural and functional diversity of these mobile elements in the genome of the cyanobacterium Crocosphaera watsonii WH8501 is analyzed. The number, distribution, and diversity of nucleotide and amino acid stretches with similarity to the transposase gene of this IS family suggested that this genome harbors many functional as well as truncated IS fragments. The selection pressure acting on full-length transposase open reading frames of these ISs suggested (i) the occurrence of positive selection and (ii) the presence of one or more positively selected codons. These results were obtained using three data sets of transposase genes from the same IS family that were collected based on the level of amino acid similarity, the presence of an inverted repeat, and the number of sequences in the data sets. Neither recombination nor ribosomal frameshifting, which may interfere with the selection analyses, appeared to be important forces in the transposase gene family. Some positively selected codons were located in a conserved domain, suggesting that these residues are functionally important. The finding that this type of selection acts on IS-carried genes is intriguing, because although ISs have been associated with the adaptation of the bacterial host to new environments, this has typically been attributed to transposition or transformation, thus involving different genomic locations. Intragenic adaptation of IS-carried genes identified here may constitute a novel mechanism associated with bacterial diversification and adaptation.

Periodic Extinctions of Transposable Elements in Bacterial Lineages: Evidence from Intragenomic Variation in Multiple Genomes

Most previous work on the evolution of mobile DNA was limited by incomplete sequence information. Whole genome sequences allow us to overcome this limitation. I study the nucleotide diversity of prominent members of five insertion sequence families whose transposition activity is encoded by a single transposase gene. Eighteen among 376 completely sequenced bacterial genomes and plasmids carry between 3 and 20 copies of a given insertion sequence. I show that these copies generally show very low DNA divergence. Specifically, more than 68% of the transposase genes are identical within a genome. The average number of amino acid replacement substitutions at amino acid replacement sites is Ka = 0.013, that at silent sites is Ks = 0.1. This low intragenomic diversity stands in stark contrast to a much higher divergence of the same insertion sequences among distantly related genomes. Gene conversion among protein-coding genes is unlikely to account for this lack of diversity. The relation between transposition frequencies and silent substitution rates suggests that most insertion sequences in a typical genome are evolutionarily young and have been recently acquired. They may undergo periodic extinction in bacterial lineages. By implication, they are detrimental to their host in the long run. This is also suggested by the highly skewed and patchy distribution of insertion sequences among genomes. In sum, one can think of insertion sequences as slow-acting infectious diseases of cell lineages.

Sequence organization and insertion specificity of the novel chimeric ISHp609 transposable element of Helicobacter pylori

Here we describe ISHp609 of Helicobacter pylori, a new member of the IS605 mobile element family that is novel and contains two genes whose functions are unknown, jhp960 and jhp961, in addition to homologs of two other H. pylori insertion sequence (IS) element genes, orfA, which encodes a putative serine recombinase-transposase, and orfB, whose homologs in other species are also often annotated as genes that encode transposases. The complete four-gene element was found in 10 to 40% of strains obtained from Africa, India, Europe, and the Americas but in only 1% of East Asian strains. Sequence comparison of 10 representative ISHp609 elements revealed higher levels of DNA sequence matches (99%) than those seen in normal chromosomal genes (88 to 98%) or in other IS elements (95 to 97% for IS605, IS606, and IS607) from the same H. pylori populations. Sequence analysis suggested that ISHp609 can insert at many genomic sites with its left end preferentially next to TAT, with no target specificity for its right end, and without duplicating or deleting target sequences. A deleted form of ISHp609, containing just jhp960 and jhp961 and 37 bp of orfA, found in reference strain J99, was at the same chromosomal site in 15 to 40% of the strains from many geographic regions but again in only 1% of the East Asian strains. The abundance and sequence homogeneity of ISHp609 and of this nonmobile remnant suggested a recent bottleneck and then rapid spread in H. pylori populations, possibly selected by the contributions of the elements to bacterial fitness.

Evolutionary dynamics of insertion sequences in Helicobacter pylori

Prokaryotic insertion sequence (IS) elements behave like parasites in terms of their ability to invade and proliferate in microbial gene pools and like symbionts when they coevolve with their bacterial hosts. Here we investigated the evolutionary history of IS605 and IS607 of Helicobacter pylori, a genetically diverse gastric pathogen. These elements contain unrelated transposase genes (orfA) and also a homolog of the Salmonella virulence gene gipA (orfB). A total of 488 East Asian, Indian, Peruvian, and Spanish isolates were screened, and 18 and 14% of them harbored IS605 and IS607, respectively. IS605 nucleotide sequence analysis (n = 42) revealed geographic subdivisions similar to those of H. pylori; the geographic subdivision was blurred, however, due in part to homologous recombination, as indicated by split decomposition and homoplasy tests (homoplasy ratio, 0.56). In contrast, the IS607 populations (n = 44) showed strong geographic subdivisions with less homologous recombination (homoplasy ratio, 0.2). Diversifying selection (ratio of nonsynonymous change to synonymous change, >>1) was evident in approximately 15% of the IS605 orfA codons analyzed but not in the IS607 orfA codons. Diversifying selection was also evident in approximately 2% of the IS605 orfB and approximately 10% of the IS607 orfB codons analyzed. We suggest that the evolution of these elements reflects selection for optimal transposition activity in the case of IS605 orfA and for interactions between the OrfB proteins and other cellular constituents that potentially contribute to bacterial fitness. Taken together, similarities in IS elements and H. pylori population genetic structures and evidence of adaptive evolution in IS elements suggest that there is coevolution between these elements and their bacterial hosts.

Evolutionary genomics of ecological specialization

We used a combination of genomic techniques to monitor chromosomal evolution across hundreds of generations as Escherichia coli adapted to growth-limiting concentrations of either lactulose, methyl-galactoside, or a 72:28 mixture of the two. DNA microarrays identified 8 unique duplications and 16 unique deletions among 42 evolvants from 23 chemostat experiments. Each mutation was confirmed by sequencing PCR-amplified flanking genomic DNA and, except for one deletion, an insertion sequence was found at the break point. vPCR of insertion sequences identified these same mutations and 16 additional insertions (all confirmed by sequencing). The pattern of genomic evolution is highly reproducible. Statistical analyses show that duplications at lac and mutations in mgl are adaptations specific to lactulose and to methyl-galactoside, respectively. Adaptation to mixed sugars is characterized by similar mutations, but lac duplications and mgl mutations usually arise in different backgrounds, producing ecological specialists for each sugar. This suggests that an antagonistic pleiotropic tradeoff between duplications at lac and mutations in mgl retards the evolution of generalists. Other mutations that repeatedly appear in replicate experiments are adaptations to the chemostat environment and are not specific to one or the other sugar.

Molecular characterization of imipenem-resistant, cfiA-positive Bacteroides fragilis isolates from the USA, Hungary and Kuwait

Fifteen Bacteroides fragilis isolates from the USA, Hungary and Kuwait were examined for carbapenem resistance, for carbapenemase activity and, with the use of various PCR-based methods and nucleotide sequencing, for cfiA genes and activating insertion sequence (IS) elements. All the B. fragilis isolates were cfiA-positive, 10 of the cfiA genes being upregulated by IS elements that are already known. Of these 10, one was of a novel type (designated IS943) and two further ones (IS614B and IS614C) were suspected hybrids of IS612, IS614 and IS942. There were five cfiA-positive imipenem-resistant B. fragilis isolates with elevated imipenem MICs (minimal inhibitory concentration) that harboured no IS insertion upstream of the cfiA gene, but produced carbapenemase; these isolates might possess a novel activation mechanism. On the basis of the available phenotypic and genotypic evidence, the present data suggest that there are at least two cfiA activation mechanisms among B. fragilis isolates.

Interactions among strategies associated with bacterial infection: pathogenicity, epidemicity, and antibiotic resistance

Infections have been the major cause of disease throughout the history of human populations. With the introduction of antibiotics, it was thought that this problem should disappear. However, bacteria have been able to evolve to become antibiotic resistant. Nowadays, a proficient pathogen must be virulent, epidemic, and resistant to antibiotics. Analysis of the interplay among these features of bacterial populations is needed to predict the future of infectious diseases. In this regard, we have reviewed the genetic linkage of antibiotic resistance and bacterial virulence in the same genetic determinants as well as the cross talk between antibiotic resistance and virulence regulatory circuits with the aim of understanding the effect of acquisition of resistance on bacterial virulence. We also discuss the possibility that antibiotic resistance and bacterial virulence might prevail as linked phenotypes in the future. The novel situation brought about by the worldwide use of antibiotics is undoubtedly changing bacterial populations. These changes might alter the properties of not only bacterial pathogens, but also the normal host microbiota. The evolutionary consequences of the release of antibiotics into the environment are largely unknown, but most probably restoration of the microbiota from the preantibiotic era is beyond our current abilities.

Detection and activity of insertion sequences in environmental strains of Burkholderia

The presence of two insertion sequences, IS406 and IS407, was tested by polymerase chain reaction (PCR) amplification in 25 strains representing 15 Burkholderia species and the close relative Ralstonia pickettii. A total of 50% of the 25 strains contained at least one of the two insertion sequences (ISs) and a statistically significant correlation was found between the occurrences of IS406 and IS407. Moreover, PCR-RFLP studies of the amplified fragments showed that IS406 is largely conserved among all the strains tested, whereas IS407 is rather polymorphic. Transposition activity was studied in Burkholderia vietnamiensis TVV75, using the pGBG1 target plasmid. This entrapping plasmid permitted the isolation and characterization of three active IS, able to activate the plasmid-borne tetA gene after transposition. Sequencing permitted the identification of these mobile genetic elements as isoforms of IS402, IS407 and IS1416. PCR amplification products provided IS probes, which were used to determine the copy-numbers of IS402, IS407 and IS1416 in the genome of B. vietnamiensis TVV75, by Southern blotting. Copy numbers are 12, 3 and 11 respectively. To our knowledge, this is the first description of active insertion sequences in B. vietnamiensis.

Where are the pseudogenes in bacterial genomes?

Most bacterial genomes have very few pseudogenes; notable exceptions include the genomes of the intracellular parasites Rickettsia prowazekii and Mycobacterium leprae. As DNA can be introduced into microbial genomes in many ways, the compact nature of these genomes suggests that the rate of DNA influx is balanced by the rate of DNA deletion. We propose that the influx of dangerous genetic elements such as transposons and bacteriophages selects for the maintenance of relatively high deletion rates in most bacteria; the sheltered lifestyle of intracellular parasites removes this threat, leading to reduced deletion rates and larger pseudogene loads.

Detection and distribution of insertion sequence 1 (IS1)-containing bacteria in the freshwater environment(1)

The distribution of insertion sequence 1 (IS1)-containing bacteria was investigated in Windermere (Cumbria, UK), a freshwater body impacted by treated sewage discharge and run-off from the surrounding catchment. Culturable IS1-containing bacteria were recovered from the water column at three depths in Windermere North Basin (WNB) and South Basin (WSB), and from sediment at both sites (at the sediment surface in WSB and to a depth of 12-13 cm in WNB). Polymerase chain reaction amplification of IS1 and the Escherichia coli/Shigella sp. specific gene uidA, from community DNA from shallow sediments, extended the detection limit beyond that of culture at both sites. This detection was extended further into deep sediment extracted from WNB as IS1 and uidA were detected in sub-samples to a depth of 4.7 and 2.3 m, respectively. Analysis of a representative subset of 90 IS1-carrying isolates recovered from water and sediment at both sites demonstrated 21 heterogeneous IS1 profiles with estimated copy numbers ranging from 1 to 16. Identification of the host bacteria showed that the element was confined mainly to Enterobacter spp. However, this study showed IS1 to be present in Citrobacter freundii for the first time. Plasmids were carried by 75.3% of enterobacterial isolates and four plasmids (2.6%) carried IS1. DNA sequence analysis of five IS1 clones demonstrated that IS1 isoforms from this study were similar (>89% nucleotide identity) to known IS1 isoforms. Two isoforms of IS1 from a single Enterobacter cloacae isolate differed by 6.7% at the nucleotide level suggesting that they had been acquired independently.

Analysis of the beta-glucoside utilization (bgl) genes of Shigella sonnei: evolutionary implications for their maintenance in a cryptic state

The pattern of expression of the genes involved in the utilization of aryl beta-glucosides such as arbutin and salicin is different in the genus Shigella compared to Escherichia coli. The results presented here indicate that the homologue of the cryptic bgl operon of E. coli is conserved in Shigella sonnei and is the primary system involved in beta-glucoside utilization in the organism. The organization of the bgl genes in S. sonnei is similar to that of E. coli; however there are three major differences in terms of their pattern of expression. (i) The bglB gene, encoding phospho-beta-glucosidase B, is insertionally inactivated in S. sonnei. As a result, mutational activation of the silent bgl promoter confers an Arbutin-positive (Arb(+)) phenotype to the cells in a single step; however, acquiring a Salicin-positive (Sal(+)) phenotype requires the reversion or suppression of the bglB mutation in addition. (ii) Unlike in E. coli, a majority of the activating mutations (conferring the Arb(+) phenotype) map within the unlinked hns locus, whereas activation of the E. coli bgl operon under the same conditions is predominantly due to insertions within the bglR locus. (iii) Although the bgl promoter is silent in the wild-type strain of S. sonnei (as in the case of E. coli), transcriptional and functional analyses indicated a higher basal level of transcription of the downstream genes. This was correlated with a 1 bp deletion within the putative Rho-independent terminator present in the leader sequence preceding the homologue of the bglG gene. The possible evolutionary implications of these differences for the maintenance of the genes in the cryptic state are discussed.

Evidence for recent invasion of the medaka fish genome by the Tol2 transposable element

Tol2 is a transposable element of the terminal-inverted-repeat class, residing in the genome of the medaka fish Oryzias latipes. The genus Oryzias contains more than 10 species for which phylogenetic relationships have previously been estimated. To infer the history of Tol2 in this genus we performed genomic Southern blots and PCR analyses of 10 of the species. It was revealed that Tol2 occurs in 2 of the 10 species (O. curvinotus and O. latipes) and that the length and the restriction map structure of Tol2 are identical in the two cases. Further, sequencing analysis revealed an extremely low level of divergence compared with that in a nuclear gene. These results suggest recent incorporation of Tol2 into one or both of the two species, implying horizontal transfer of Tol2 from one species to the other or into them both from a common source.

Characterization of a recurrent clonal type of Escherichia coli O157:H7 causing major outbreaks of infection in Scotland

A particular recurrent clonal type of Escherichia coli O157 has been isolated from multiple clinical, veterinary, food, and environmental sources throughout Scotland since 1989. Significant genotypic variation was detected among isolates from distinct outbreaks, with the presence or absence of single fragments being sufficient to delineate outbreak groups within the clonal type.

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.

Analysis of the gene cluster encoding toluene/o-xylene monooxygenase from Pseudomonas stutzeri OX1

The toluene/o-xylene monooxygenase cloned from Pseudomonas stutzeri OX1 displays a very broad range of substrates and a very peculiar regioselectivity, because it is able to hydroxylate more than one position on the aromatic ring of several hydrocarbons and phenols. The nucleotide sequence of the gene cluster coding for this enzymatic system has been determined. The sequence analysis revealed the presence of six open reading frames (ORFs) homologous to other genes clustered in operons coding for multicomponent monooxygenases found in benzene- and toluene-degradative pathways cloned from Pseudomonas strains. Significant similarities were also found with multicomponent monooxygenase systems for phenol, methane, alkene, and dimethyl sulfide cloned from different bacterial strains. The knockout of each ORF and complementation with the wild-type allele indicated that all six ORFs are essential for the full activity of the toluene/o-xylene monooxygenase in Escherichia coli. This analysis also shows that despite its activity on both hydrocarbons and phenols, toluene/ o-xylene monooxygenase belongs to a toluene multicomponent monooxygenase subfamily rather than to the monooxygenases active on phenols.

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.

Recent horizontal transmission of plasmids between natural populations of Escherichia coli and Salmonella enterica

Seventy-one natural isolates obtained from a Salmonella reference collection were examined for the presence of plasmids closely related to the Escherichia coli F plasmid. The collection consists of several serovars of the S. enterica Typhimurium complex, subspecies I, to which 99% of pathogenic salmonellae belong. Molecular genetic techniques of DNA hybridization, along with PCR and DNA sequencing, were used to examine the occurrence, distribution, and genetic diversity of F-like plasmids among Salmonella strains. The F plasmid genes examined were finO, traD, traY, and repA, which map at dispersed positions on the F plasmid of E. coli. Comparative sequence analysis of each of the four genes in Salmonella plasmids showed them to be homologous (in some cases, virtually identical) to those found in F plasmids of E. coli natural isolates. Furthermore, the frequency of F-like plasmids in Salmonella strains was approximately the same as that observed in the E. coli Reference Collection. However, in Salmonella, the distribution was confined predominately to the serovars Typhimurium and Muenchen. The unexpected finding of a shared pool of F-like plasmids between S. enterica and E. coli demonstrates the significant role of conjugation in the histories of these important bacterial species.

Characterization of a mosaic ISS1 element and evidence for the recent horizontal transfer of two different types of ISS1 between Streptococcus thermophilus and Lactococcus lactis

A 12-kb region of the Streptococcus thermophilus CNRZ368 chromosome was found to contain two copies of IS981 (one complete and one truncated) and three copies of ISS1 (two complete, ISS1SA and ISS1SC, and one truncated, delta ISS1SB). Comparison of the nucleotide sequences of these ISS1 elements with those of previously identified iso-ISS1 elements from Lactococcus lactis and the Enterococcus genus indicated that the ISS1 group is divided into three distinct subgroups which we have named alpha, beta and gamma. Nucleotide sequences of elements belonging to the same subgroup share more than 97% identity whereas sequences of elements from different groups share only 75-85% identity. Sequence analysis of ISS1SA and delta ISS1SB showed that they are members of the alpha group. We found that ISS1SC from S. themophilus CNRZ368, an ISS1 from L. lactis IL964 and IS946 from L. lactis TEK1 resulted from recombinations between alpha and beta elements. In addition, ISS1W from L. lactis Wg2 resulted from a recombination event between a gamma element and an ISS1 belonging to an unidentified subgroup. ISS1 sequences belonging to the alpha and beta subgroups were found in both S. thermophilus and L. lactis and gamma sequences were found in both the Enterococcus genus and L. lactis. The quasi-identity of some ISS1 elements in S. thermophilus and L. lactis and the distribution of alpha and beta elements suggest that horizontal transfer of ISS1 elements recently took place from L. lactis to S. thermophilus, two lactic acid bacteria used in the manufacture of cheeses. Since the presence of IS981 in S. thermophilus CNRZ368 also probably resulted from a horizontal transfer from L. lactis [Guédon et al. (1995) Mol. Microbiol. 16, 69-78], the 12-kb region bearing IS981 and ISS1 elements could be due to the integration of a lactococcal DNA fragment into the chromosome.

The cobalamin (coenzyme B12) biosynthetic genes of Escherichia coli

The enteric bacterium Escherichia coli synthesizes cobalamin (coenzyme B12) only when provided with the complex intermediate cobinamide. Three cobalamin biosynthetic genes have been cloned from Escherichia coli K-12, and their nucleotide sequences have been determined. The three genes form an operon (cob) under the control of several promoters and are induced by cobinamide, a precursor of cobalamin. The cob operon of E. coli comprises the cobU gene, encoding the bifunctional cobinamide kinase-guanylyltransferase; the cobS gene, encoding cobalamin synthetase; and the cobT gene, encoding dimethylbenzimidazole phosphoribosyltransferase. The physiological roles of these sequences were verified by the isolation of Tn10 insertion mutations in the cobS and cobT genes. All genes were named after their Salmonella typhimurium homologs and are located at the corresponding positions on the E. coli genetic map. Although the nucleotide sequences of the Salmonella cob genes and the E. coli cob genes are homologous, they are too divergent to have been derived from an operon present in their most recent common ancestor. On the basis of comparisons of G+C content, codon usage bias, dinucleotide frequencies, and patterns of synonymous and nonsynonymous substitutions, we conclude that the cob operon was introduced into the Salmonella genome from an exogenous source. The cob operon of E. coli may be related to cobalamin synthetic genes now found among non-Salmonella enteric bacteria.

Correlation of Rhs elements with Escherichia coli population structure

The Rhs family of composite genetic elements was assessed for variation among independent Escherichia coli strains of the ECOR reference collection. The location and content of the RhsA-B-C-F subfamily correlates highly with the clonal structure of the ECOR collection. This correlation exists at several levels: the presence of Rhs core homology in the strain, the location of the Rhs elements present, and the identity of the Rhs core-extensions associated with each element. A provocative finding was that an identical 1518-bp segment, covering core-extension-b1 and its associated downstream open reading frame, is present in two distinct clonal groups, but in association with different Rhs elements. The sequence identity of this segment when contrasted with the divergence of other chromosomal segments suggests that shuffling of Rhs core extensions has been a relatively recent variation. Nevertheless the copies of core-extension-b1 were placed within the respective Rhs elements before the emergence of the clonal groups. In the course of this analysis, two new Rhs elements absent from E. coli K-12 were discovered: RhsF, a fourth member of the RhsA-B-C-F subfamily, and RhsG, the prototype of a third Rhs subfamily.

Sequence and distribution of IS1312: evidence for horizontal DNA transfer from Rhizobium meliloti to Agrobacterium tumefaciens

Two novel insertion sequences, IS1312 and IS1313, were found in pTiBo542, the Ti plasmid of Agrobacterium tumefaciens strains Bo542 and A281. Nucleotide sequencing and Southern hybridization revealed that IS1312 and IS1313 are homologous to Rhizobium meliloti ISRm1 and ISRm2, respectively. IS1312, ISRm1, and another Agrobacterium insertion sequence, IS426, belong to the same IS3 family of insertion sequences; however, IS1312 is more closely related to the Rhizobium ISRm1 than it is to the Agrobacterium IS426. The distribution patterns of these insertion elements and their sequence similarities suggest that IS1312 and IS1313 were horizontally transferred from R. meliloti to A. tumefaciens.

IS1222: analysis and distribution of a new insertion sequence in Enterobacter agglomerans 339

With a length of 1221 bp and 44-bp inverted repeats with ten mismatches, IS1222 was identified as an endogenous insertion sequence in Enterobacter agglomerans 339. In this host strain, four copies were located, three on the nif plasmid pEA9 and one at the chromosome. Sequence analysis showed two consecutive open reading frames, orfA and orfB, encoding putative polypeptides of 87 and 276 amino acids. In-between both reading frames, a potential frameshift window of the homonucleotide type was postulated, followed by a pseudoknot structure and a ribosome-binding site. Based on significant homology at the sequence level and similarity of the features discussed, IS1222 was placed among the group of IS3 elements with IS407, IS476 and ISR1 being the most closely related IS. Hybridization experiments suggest that the distribution of IS1222 is limited to a group of related bacterial strains among Enterobacteriaceae.

Characterization and distribution of insertion sequence IS1239 in Streptococcus pyogenes

The human pathogenic bacterium Streptococcus pyogenes causes pharyngitis, acute rheumatic fever, glomerulonephritis and toxic-shock-like syndrome. The bacterium synthesizes several extracellular products, including the recently described streptococcal superantigen SSA, a molecule that shares considerable homology with several Staphylococcus aureus enterotoxins. While studying allelic variation at the ssa locus, six isolates expressing serotypes M4, M23, M33, M41, M43, and provisional type PT4854, were identified that had PCR products about 40-bp larger than expected, and one isolate (M15) had an amplified fragment that was more than 1-kb larger than expected. All six isolates have a 34-bp insert located 103 bp 5' of the ssa start codon. The larger product is a result of a 1110-bp insertion at the analogous location. The complementary strand of this insert has a 981-bp open reading frame that potentially encodes a 326-amino-acid polypeptide with substantial homology to the Escherichia coli IS30 transposase. Results of Southern blot analysis showed that at least twelve copies of the sequence are present in the serotype M15 S. pyogenes isolate. This element, designated IS1239, is the first simple insertion sequence described in group-A streptococci. Results of PCR screening showed that 26 of 78 (33%) S. pyogenes isolates expressing distinct M protein serotypes contained sequences with homology to IS1239, which means that the element is widely distributed in the species.

Isolation of Insertion Sequence IS RLd TAL1145-1 from a Rhizobium sp. ( Leucaena diversifolia ) and Distribution of Homologous Sequences Identifying Cross-Inoculation Group Relationships

Insertion sequence (IS) element IS RLd TAL1145-1 from Rhizobium sp. ( Leucaena diversifolia ) strain TAL 1145 was entrapped in the sacB gene of the positive selection vector pUCD800 by insertional inactivation. A hybridization probe prepared from the whole 2.5-kb element was used to determine the distribution of homologous sequences in a diverse collection of 135 Rhizobium and Bradyrhizobium strains. The IS probe hybridized strongly to Southern blots of genomic DNAs from 10 rhizobial strains that nodulate both Phaseolus vulgaris (beans) and Leucaena leucocephala (leguminous trees), 1 Rhizobium sp. that nodulates Leucaena spp., 9 R. meliloti (alfalfa) strains, 4 Rhizobium spp. that nodulate Sophora chrysophylla (leguminous trees), and 1 nonnodulating bacterium associated with the nodules of Pithecellobium dulce from the Leucaena cross-inoculation group, producing distinguishing IS patterns for each strain. Hybridization analysis revealed that IS RLd TAL1145-1 was strongly homologous with and closely related to a previously isolated element, IS Rm USDA1024-1 from R. meliloti , while restriction enzyme analysis found structural similarities and differences between the two IS homologs. Two internal segments of these IS elements were used to construct hybridization probes of 1.2 kb and 380 bp that delineate a structural similarity and a difference, respectively, of the two IS homologs. The internal segment probes were used to analyze the structures of homologous IS elements in other strains. Five types of structural variation in homolog IS elements were found. The predominate IS structural type naturally occurring in a strain can reasonably identify the strain's cross-inoculation group relationships. Three IS structural types were found in Rhizobium species that nodulate beans and Leucaena species, one of which included the designated type IIB strain of R. tropici (CIAT 899). Weak homology to the whole IS probe, but not with the internal segments, was found with two Bradyrhizobium japonicum strains. The taxonomic and ecological implications of the distribution of IS RLd TAL1145-1 are discussed.

Clonal divergence in Escherichia coli as a result of recombination, not mutation

Nucleotide sequence analysis was performed on 12 natural isolates of Escherichia coli in four loci located in close proximity on the chromosome. A comparison of gene genealogies indicated that three recombination events have occurred in a subset of the strains (ECOR group A) in the time since their divergence from a common ancestor, while during the same time, no mutational divergence has occurred. The common ancestor of this subset existed no more than 2400 years ago, and recombination was shown to occur at a rate of 5.0 x 10(-9) changes per nucleotide per generation--50-fold higher than the mutation rate. Thus, recombination has been the dominant force driving the clonal divergence of the ECOR group A strains and must be considered a significant factor in structuring E. coli populations.

Identification of IS1206, a Corynebacterium glutamicum IS3-related insertion sequence and phylogenetic analysis

Integration of plasmid pCGL320 into a Corynebacterium glutamicum ATCC21086 derivative led to tandem amplification of the inserted plasmid (Labarre et al., 1993). One amplification event was associated with integration of an insertion sequence that we have named IS1206. Hybridizing sequences were only found in C. glutamicum strains and at various copy numbers. IS1206 is 1290 bp long, carries 32 bp imperfect inverted repeats and generates a 3 bp duplication of the target DNA upon insertion. IS1206 presents the features characteristic of the IS3 family and part of the DNA sequence centering on the putative transposase region (orfB) is similar to those of IS3 and some other related elements. Phylogenetic analysis of orfB deduced protein sequences from IS1206 and IS3-related elements contradicts the phylogeny of the species, suggesting that evolution of these elements might be complex. Horizontal transfer could be invoked but other alternatives like ancestral polymorphism or/and different rates of evolution could also be involved.

The mariner transposable element in the Drosophilidae family

The distribution of the mariner transposable element among Drosophilidae species was investigated using three different techniques, i.e. squash blots, Southern blots and PCR amplification, using two sets of primers (one corresponding to the Inverted Terminal Repeats and the other to two conserved regions of the putative transposase). Our results and those of others show that the distribution of mariner is not uniform and does not follow the phylogeny of the host species. An analysis of geographical distribution, based on endemic species, shows that mariner is mainly present in Asia and Africa. At least two hypotheses may be proposed to explain the specific and geographical distributions of this element. Firstly, they may be the results of several horizontal transmissions between Drosophila species and/or between Drosophila species and one or several donor species outside the Drosophilidae family. Secondly, these particular distributions may correspond to the evolution of the mariner element from an ancestral copy which was present in the ancestor of the Drosophilidae family.