The early phase of a bacterial insertion sequence infection

Bacterial insertion sequences are the simplest form of autonomous mobile DNA. It is unknown whether they need to have beneficial effects to infect and persist in bacterial populations, or whether horizontal gene transfer suffices for their persistence. We address this question by using branching process models to investigate the critical, early phase of an insertion sequence infection. We find that the probability of a successful infection is low and depends linearly on the difference between the rate of horizontal gene transfer and the fitness cost of the insertion sequences. Our models show that the median time to extinction of an insertion sequence that dies out is very short, while the median time for a successful infection to reach a modest population size is very long. We conclude that horizontal gene transfer is strong enough to allow the persistence of insertion sequences, although infection is an erratic and slow process.     

Estimating the fitness effect of an insertion sequence

Since its discovery, mobile DNA has fascinated researchers. In particular, many researchers have debated why insertion sequences persist in prokaryote genomes and populations. While some authors think that insertion sequences persist only because of occasional beneficial effects they have on their hosts, others argue that horizontal gene transfer is strong enough to overcome their generally detrimental effects. In this study, we model the long-term fate of a prokaryote cell population, of which a small proportion of cells has been infected with one insertion sequence per cell. Based on our model and the distribution of IS5, an insertion sequence for which sufficient data is available in 525 fully sequenced proteobacterial genomes, we show that the fitness cost of insertion sequences is so small that they are effectively neutral or only slightly detrimental. We also show that an insertion sequence infection can persist and reach the empirically observed distribution if the rate of horizontal gene transfer is at least as large as the fitness cost, and that this rate is well within the rates of horizontal gene transfer observed in nature. In addition, we show that the time needed to reach the observed prevalence of IS5 is unrealistically long for the fitness cost and horizontal gene transfer rate that we computed. Occasional beneficial effects may thus have played an important role in the fast spreading of insertion sequences like IS5.     

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.     

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.     

Distribution of the ermG gene among bacterial isolates from porcine intestinal contents

The ermG gene was first found in the soil bacterium Bacillus sphaericus. More recently, it was found in several human intestinal Bacteroides species. We report here the first finding of ermG genes in gram-positive bacteria isolated from porcine feces and from under-barn manure pits used to store porcine wastes. The porcine ermG sequences were identical to the sequence of the B. sphaericus ermG gene except that six of the seven ermG-containing strains contained an insertion sequence element insertion in the C-terminal end of the gene. The porcine ermG genes were found in three different gram-positive genera, an indication that it is possible that the gene is being spread by horizontal gene transfer. A segment of a Bacteroides conjugative transposon that carries an ermG gene cross-hybridized with DNA from six of the seven porcine isolates, but the restriction patterns in the porcine strains were different from that of the Bacteroides conjugative transposon.     

Inferring horizontal transfers in the presence of rearrangements by the minimum evolution criterion

MOTIVATION: The evolution of viruses is very rapid and in addition to local point mutations (insertion, deletion, substitution) it also includes frequent recombinations, genome rearrangements and horizontal transfer of genetic materials (HGTS). Evolutionary analysis of viral sequences is therefore a complicated matter for two main reasons: First, due to HGTs and recombinations, the right model of evolution is a network and not a tree. Second, due to genome rearrangements, an alignment of the input sequences is not guaranteed. These facts encourage developing methods for inferring phylogenetic networks that do not require aligned sequences as input. RESULTS: In this work, we present the first computational approach which deals with both genome rearrangements and horizontal gene transfers and does not require a multiple alignment as input. We formalize a new set of computational problems which involve analyzing such complex models of evolution. We investigate their computational complexity, and devise algorithms for solving them. Moreover, we demonstrate the viability of our methods on several synthetic datasets as well as four biological datasets. AVAILABILITY: The code is available from the authors upon request.     

The conservation of DNA sequences over very long periods of evolutionary time. Evidence against intergeneric chromosomal transfer as an explanation for the presence of Escherichia coli tuf gene sequences in taxonomically-unrelated prokaryotes

In the present study we tried to determine whether the presence of DNA sequences homologous to the Escherichia coli tuf gene (encodes peptide chain elongation factor Tu) in many taxonomically-unrelated prokaryotes is due to selective pressure for these sequences or due to the transfer of chromosomal material subsequent to the divergence of the genera from their progenitors. We found that the degree of sequence homology to the DNA immediately adjacent to the E. coli tuf A gene is either nonexistent or much less than that found for the tuf gene. Furthermore, the tuf-homologous sequences present in one prokaryote were found to be in large part the same as or a subset of those present in others. That is, various prokaryotes share a common subset of tuf-homologous sequences. These findings suggest that strong selective pressure and not recent intergeneric chromosomal transfer is responsible for the ubiquitous presence of certain tuf-homologous sequences. Because the genetic code is degenerate, DNA sequence need not be conserved to conserve protein sequence. Therefore, if the only function of these sequences is to encode protein, their persistence must mean that in some instances codon sequence is selected for.     

The molecular evolution of catalatic hydroperoxidases: evidence for multiple lateral transfer of genes between prokaryota and from bacteria into eukaryota

The past decade has produced an increasing number of reports on horizontal gene transfer between prokaryotic organisms. Only recently, with the flood of available whole genome sequence data and a renewed intensity of the debate about the universal tree of life, a very few reports on lateral gene transfer (LGT) from prokaryotes into the Eukaryota have been published. We have investigated and report here on the molecular evolution of the gene families that encode catalatic hydroperoxidases. We have found that this process included not only frequent horizontal gene transfer among prokaryotes but also several lateral gene transfer events between bacteria and fungi and between bacteria and the protistan ancestor of the alga/plant lineage.     

CRISPR Interference Can Prevent Natural Transformation and Virulence Acquisition during In Vivo Bacterial Infection

Pathogenic bacterial strains emerge largely due to transfer of virulence and antimicrobial resistance genes between bacteria, a process known as horizontal gene transfer (HGT). Clustered, regularly interspaced, short palindromic repeat (CRISPR) loci of bacteria and archaea encode a sequence-specific defense mechanism against bacteriophages and constitute a programmable barrier to HGT. However, the impact of CRISPRs on the emergence of virulence is unknown. We programmed the human pathogen Streptococcus pneumoniae with CRISPR sequences that target capsule genes, an essential pneumococcal virulence factor, and show that CRISPR interference can prevent transformation of nonencapsulated, avirulent pneumococci into capsulated, virulent strains during infection in mice. Further, at low frequencies bacteria can lose CRISPR function, acquire capsule genes, and mount?a successful infection. These results demonstrate that CRISPR interference can prevent the emergence of virulence in?vivo and that strong selective pressure for virulence or antibiotic resistance can lead to CRISPR loss in bacterial pathogens.     

Polymerase chain reaction of genes flanked by short noncontiguous sequence motifs

Short DNA sequence motifs have been demonstrated to interact with DNA binding proteins and regulate flanking genes. The short nature and the lack of continuity of many of these DNA binding sites make it difficult to develop an approach to characterize genes that have the same flanking sequences. We tested various oligonucleotide combinations using an immunoglobulin variable region gene family as a model amplification system. One successful amplification strategy used an oligonucleotide containing two known noncontiguous short sequences connected by random insertion of all four bases to maintain the appropriate spacing. A second approach used an oligonucleotide having a single short homologous sequence with the addition of all four bases randomly placed at the 5' end to increase the extent of homology. Both strategies will permit the priming of members of a specific gene family, with the two short sequences bridged by all four bases randomly added being more efficient in the amplification process.     

Evolution and Horizontal Transfer of dUTPase-Encoding Genes in Viruses and Their Hosts

dUTPase is a ubiquitous and essential enzyme responsible for regulating cellular levels of dUTP. The dut gene exists as single, tandemly duplicated, and tandemly triplicated copies. Crystallized single-copy dUTPases have been shown to assemble as homotrimers. dUTPase is encoded as an auxiliary gene in a number of virus genomes. The origin of viral dut genes has remained unresolved since their initial discovery. A comprehensive analysis of dUTPase amino acid sequence relationships was performed to explore the evolutionary dynamics of dut in viruses and their hosts. Our data set, comprised of 24 host and 51 viral sequences, includes representative sequences from available eukaryotes, archaea, eubacteria cells, and viruses, including herpesviruses. These amino acid sequences were aligned by using a hidden Markov model approach developed to align divergent data. Known secondary structures from single-copy crystals were mapped onto the aligned duplicate and triplicate sequences. We show how duplicated dUTPases might fold into a monomer, and we hypothesize that triplicated dUTPases also assemble as monomers. Phylogenetic analysis revealed at least five viral dUTPase sequence lineages in well-supported monophyletic clusters with eukaryotic, eubacterial, and archaeal hosts. We have identified all five as strong examples of horizontal transfer as well as additional potential transfer of dut genes among eubacteria, between eubacteria and viruses, and between retroviruses. The evidence for horizontal transfers is particularly interesting since eukaryotic dut genes have introns, while DNA virus dut genes do not. This implies that an intermediary retroid agent facilitated the horizontal transfer process between host mRNA and DNA viruses.     

Distribution of the ermG Gene among Bacterial Isolates from Porcine Intestinal Contents

The ermG gene was first found in the soil bacterium Bacillus sphaericus. More recently, it was found in several human intestinal Bacteroides species. We report here the first finding of ermG genes in gram-positive bacteria isolated from porcine feces and from under-barn manure pits used to store porcine wastes. The porcine ermG sequences were identical to the sequence of the B. sphaericus ermG gene except that six of the seven ermG-containing strains contained an insertion sequence element insertion in the C-terminal end of the gene. The porcine ermG genes were found in three different gram-positive genera, an indication that it is possible that the gene is being spread by horizontal gene transfer. A segment of a Bacteroides conjugative transposon that carries an ermG gene cross-hybridized with DNA from six of the seven porcine isolates, but the restriction patterns in the porcine strains were different from that of the Bacteroides conjugative transposon.     

Gene conversion as a mechanism for divergence of a chloroplast tRNA gene inserted in the mitochondrial genome of Brassica oleracea.

We have characterized a 1.7 kb sequence, containing a tRNA Leu2 gene shared by the ct and mt genomes of Brassica oleracea. The two sequences are completely homologous except in two short regions where two distinct gene conversion events have occurred between two sets of direct repeats leading to the insertion of 5 bp in the T loop of the mt copy of the ct gene. This is the first evidence that gene conversion represents the initial evolutionary step in inactivation of transferred ct genes in the mt genome. We also indicate that organelle DNA transfer by organelle fusion is an ongoing process which could be useful in genetic engineering.     

Microbial horizontal gene transfer and the DNA release from transgenic crop plants

Intraspecific and interspecific horizontal gene transfers among prokaryotes by mechanisms like conjugation, transduction and transformation are part of their life style. Experimental data and nucleotide sequence analyses show that these processes appear to occur in any prokaryotic habitat and have shaped microbial genomes throughout evolution over hundreds of million years. Here we summarize studies with a focus on the possibility of the transfer of free recombinant DNA released from transgenic plants to microorganisms by transformation. A list of 87 species capable of natural transformation is presented. We discuss monitoring techniques which allowed detection of the spread of intact DNA from plants during their growth, in the process of decay and by pollen dispersal including novel biomonitoring assays for measuring the transforming potential of DNA in the environment. Also, studies on the persistence of free DNA in soil habitats and the potential of bacteria to take up DNA in soil are summarized. On the other hand, the various barriers evolved in prokaryotes which suppress interspecific gene transfer and recombination will be addressed along with studies aiming to estimate the chance of a gene transfer from plant to microbe. The results suggest that, although such transfers could be possible in principle, each of the many steps involved from the release of intact DNA from a plant cell to integration into a prokaryotic genome has such a low probability that a successful transfer event be extremely rare. Further, interspecies transfer of chromosomal DNA is mostly negative for the recipient, and, if not, in the absence of a selective advantage the transformant will be lost. It is stressed that the nucleotide sequences introduced into transgenic plants are much less likely to be captured from the transgenic plants than directly from those organisms (often bacteria or viruses) from which they were originally derived.     

Toxic introns and parasitic intein in Coxiella burnetii: legacies of a promiscuous past

The genome of the obligate intracellular pathogen Coxiella burnetii contains a large number of selfish genetic elements, including two group I introns (Cbu.L1917 and Cbu.L1951) and an intervening sequence that interrupts the 23S rRNA gene, an intein (Cbu.DnaB) within dnaB and 29 insertion sequences. Here, we describe the ability of the intron-encoded RNAs (ribozymes) to retard bacterial growth rate (toxicity) and examine the functionality and phylogenetic history of Cbu.DnaB. When expressed in Escherichia coli, both introns repressed growth, with Cbu.L1917 being more inhibitory. Both ribozymes were found to associate with ribosomes of Coxiella and E. coli. In addition, ribozymes significantly reduced in vitro luciferase translation, again with Cbu.L1917 being more inhibitory. We analyzed the relative quantities of ribozymes and genomes throughout a 14-day growth cycle of C. burnetii and found that they were inversely correlated, suggesting that the ribozymes have a negative effect on Coxiella's growth. We determined possible sites for ribozyme associations with 23S rRNA that could explain the observed toxicities. Further research is needed to determine whether the introns are being positively selected because they promote bacterial persistence or whether they were fixed in the population due to genetic drift. The intein, Cbu.DnaB, is able to self-splice, leaving the host protein intact and presumably functional. Similar inteins have been found in two extremophilic bacteria (Alkalilimnicola ehrlichei and Halorhodospira halophila) that are distantly related to Coxiella, making it difficult to determine whether the intein was acquired by horizontal gene transfer or was vertically inherited from a common ancestor.     

Genetic exchange in the environment

Summary Reports made over the past few years leave little doubt that horizontal gene transfer among bacteria can and does occur in the environment. The significance of these events in the dissemination of recombinant molecules is not clear and more research is required to fully appreciate the impact of genetic exchange on their stability and survival. Based on the available data it is fair to say that horizontal gene transfer may play as important a role in transmission of recombinant sequences as does the survival and persistence of genetically engineered microorganisms.     

Identification and characterization of a bacteria-like sequence in the genome of some Silene species

The aim of this work was to characterize a nucleotide sequence MK14 that originated from a plasmid library obtained via degenerate oligonucleotide primed polymerase chain reaction (DOP-PCR) amplification of laser microdissected Y-chromosomes of Silene latifolia. This sequence showed significant similarity to parts of two adjoining genes from bacterial representatives of the genus Ralstonia. MK14 sequence contains a part of a conserved domain, and phylogenetic analysis based on this region confirmed its relationship to Ralstonia-derived sequences. Genomic Southern blot analysis proved the presence of this fragment in the genome of S. latifolia. We hypothesize that this insertion is of bacterial origin, and was probably gained via horizontal gene transfer. Moreover, MK14 insertion is shared by some closely related Silene species, suggesting an ancient spontaneous transformation by an ancestor of bacteria from the genus Ralstonia.     

基因水平转移的评判方法和转移方式研究进展

基因水平转移是不同物种之间或细胞器间基因的交流。基因水平转移现象在原核生物中普遍存在, 在真核生物中近年来也发现了众多例证, 说明水平转移是生物界的普遍现象。文章着重对基因水平转移的概念、评判基因水平转移的标准, 水平转移的特点和转移方式, 以及基因水平转移对基因组进化的作用等方面的研究进展进行了综述。在已有的基因水平转移研究中进化树分析法、碱基组成分析法、选择压力分析法、内含子分析法、特殊序列分析法和核苷酸组成偏向性分析法等几种是常用的方法; 转座序列是生物中最易于发生水平转移的基因类型;原核生物基因水平转移的主要方式有转化、接合和转导, 真核生物中水平转移发生方式尚不清楚。基因水平转移在基因、基因组和生物进化中有着其独特的作用。     

The population biology of bacterial plasmids: a hidden Markov model approach

Horizontal plasmid transfer plays a key role in bacterial adaptation. In harsh environments, bacterial populations adapt by sampling genetic material from a horizontal gene pool through self-transmissible plasmids, and that allows persistence of these mobile genetic elements. In the absence of selection for plasmid-encoded traits it is not well understood if and how plasmids persist in bacterial communities. Here we present three models of the dynamics of plasmid persistence in the absence of selection. The models consider plasmid loss (segregation), plasmid cost, conjugative plasmid transfer, and observation error. Also, we present a stochastic model in which the relative fitness of the plasmid-free cells was modeled as a random variable affected by an environmental process using a hidden Markov model (HMM). Extensive simulations showed that the estimates from the proposed model are nearly unbiased. Likelihood-ratio tests showed that the dynamics of plasmid persistence are strongly dependent on the host type. Accounting for stochasticity was necessary to explain four of seven time-series data sets, thus confirming that plasmid persistence needs to be understood as a stochastic process. This work can be viewed as a conceptual starting point under which new plasmid persistence hypotheses can be tested.