Global mapping of transposon location

Transposable genetic elements are ubiquitous, yet their presence or absence at any given position within a genome can vary between individual cells, tissues, or strains. Transposable elements have profound impacts on host genomes by altering gene expression, assisting in genomic rearrangements, causing insertional mutations, and serving as sources of phenotypic variation. Characterizing a genome's full complement of transposons requires whole genome sequencing, precluding simple studies of the impact of transposition on interindividual variation. Here, we describe a global mapping approach for identifying transposon locations in any genome, using a combination of transposon-specific DNA extraction and microarray-based comparative hybridization analysis. We use this approach to map the repertoire of endogenous transposons in different laboratory strains of Saccharomyces cerevisiae and demonstrate that transposons are a source of extensive genomic variation. We also apply this method to mapping bacterial transposon insertion sites in a yeast genomic library. This unique whole genome view of transposon location will facilitate our exploration of transposon dynamics, as well as defining bases for individual differences and adaptive potential.     

Accumulation of Spock and Worf,two novel non-LTR retrotransposons,on the neo-Y chromosome of Drosophila miranda

Transposable elements constitute a major fraction of eukaryotic genomes. Here, I characterize two novel non-LTR retrotransposons, cloned from the neo-Y chromosome of Drosophila miranda. Worf is 4.1 kb in size and shows homology to the T1-2 non-LTR transposon characterized in Anopheles. Spock is 4.9 kb in size and shows similarity to the Doc element of D. melanogaster. Southern blot analysis of both elements yielded stronger signals for male DNA. In situ hybridization to polytene chromosomes revealed that both elements are accumulating on the neo-Y chromosome of D. miranda. PCR analysis was conducted to investigate the frequency of spock and worf and of the previously identified transposons, TRIM and TRAM, at individual chromosomal sites among 12 strains of D. miranda. Contrary to the observation that element frequencies are usually kept low at individual sites in Drosophila, the four transposons investigated are fixed at their genomic locations on the neo-Y chromosome. These results support the hypothesis that transposons accumulate in nonrecombining regions and may be one cause of the heteromorphism of sex chromosomes.     

Bombyx small RNAs: genomic defense system against transposons in the silkworm, Bombyx mori

Selfish genetic elements called transposons can insert themselves at new locations in host genomes to modify gene structure and alter gene expression. Expansion of transposons can occur when novel transposition events are transmitted to subsequent generations after germline hopping. Therefore, organisms seem likely to have evolved defense mechanisms to silence transposons in the germline. Recently, small RNAs interacting with Piwi proteins (piwi-interacting RNAs: piRNAs) have been demonstrated to be involved in genomic defense mechanism against transposons. Here, we show that piRNA-like small RNAs are present abundantly in the Bombyx ovary. We cloned 38,493 kinds of Bombyx small RNA from the ovary and performed functional characterization. Bombyx small RNAs showed a unimodal length distribution with a peak at 28nt and a strong bias for U at the 5' end. We found that 12,869 kinds of Bombyx small RNAs were associated with transposons or repetitive sequences. We classified them as repeat-associated small interfering RNAs (rasiRNAs), a subclass of piRNAs. Notably, antisense rasiRNAs have a strong bias toward U at 5' ends; in contrast, sense rasiRNAs have a strong bias toward A at nucleotide position 10, indicating that the piRNA amplification loop proposed in Drosophila is evolutionarily conserved in Bombyx. These results suggest that Bombyx small RNAs regulate transposon activity.     

DNA transposon-based gene vehicles - scenes from an evolutionary drive

DNA transposons are primitive genetic elements which have colonized living organisms from plants to bacteria and mammals. Through evolution such parasitic elements have shaped their host genomes by replicating and relocating between chromosomal loci in processes catalyzed by the transposase proteins encoded by the elements themselves. DNA transposable elements are constantly adapting to life in the genome, and self-suppressive regulation as well as defensive host mechanisms may assist in buffering ‘cut-and-paste’ DNA mobilization until accumulating mutations will eventually restrict events of transposition. With the reconstructed Sleeping Beauty DNA transposon as a powerful engine, a growing list of transposable elements with activity in human cells have moved into biomedical experimentation and preclinical therapy as versatile vehicles for delivery and genomic insertion of transgenes. In this review, we aim to link the mechanisms that drive transposon evolution with the realities and potential challenges we are facing when adapting DNA transposons for gene transfer. We argue that DNA transposon-derived vectors may carry inherent, and potentially limiting, traits of their mother elements. By understanding in detail the evolutionary journey of transposons, from host colonization to element multiplication and inactivation, we may better exploit the potential of distinct transposable elements. Hence, parallel efforts to investigate and develop distinct, but potent, transposon-based vector systems will benefit the broad applications of gene transfer. Insight and clever optimization have shaped new DNA transposon vectors, which recently debuted in the first DNA transposon-based clinical trial. Learning from an evolutionary drive may help us create gene vehicles that are safer, more efficient, and less prone for suppression and inactivation.     

The Drosophila gene disruption project: progress using transposons with distinctive site specificities

The Drosophila Gene Disruption Project (GDP) has created a public collection of mutant strains containing single transposon insertions associated with different genes. These strains often disrupt gene function directly, allow production of new alleles, and have many other applications for analyzing gene function. Here we describe the addition of ～7600 new strains, which were selected from >140,000 additional P or piggyBac element integrations and 12,500 newly generated insertions of the Minos transposon. These additions nearly double the size of the collection and increase the number of tagged genes to at least 9440, approximately two-thirds of all annotated protein-coding genes. We also compare the site specificity of the three major transposons used in the project. All three elements insert only rarely within many Polycomb-regulated regions, a property that may contribute to the origin of "transposon-free regions" (TFRs) in metazoan genomes. Within other genomic regions, Minos transposes essentially at random, whereas P or piggyBac elements display distinctive hotspots and coldspots. P elements, as previously shown, have a strong preference for promoters. In contrast, piggyBac site selectivity suggests that it has evolved to reduce deleterious and increase adaptive changes in host gene expression. The propensity of Minos to integrate broadly makes possible a hybrid finishing strategy for the project that will bring >95% of Drosophila genes under experimental control within their native genomic contexts.     

抑制基因组转座子活性的小RNAs在生育调节中的作用

小RNAs可以在转录和转录后水平沉默转座子, 最近发现的几类小RNAs(piRNAs、endo-siRNAs)均具有抑制转座子活性的作用, 其中, 果蝇piRNAs、小鼠piRNAs、小鼠endo-siRNAs及其相关蛋白主要在生殖系表达, 说明小RNAs作用途径在生殖系转座子沉默中扮演着重要角色。最新的研究揭示了小RNAs、转座子沉默、生殖生育调节之间的联系, 然而其具体作用机制尚未得到阐明。文章综述了小RNAs对基因组转座子活性的控制及其在生育调节中的作用。     

Minimization of the Escherichia coli genome using a Tn5-targeted Cre/loxP excision system

An increasing number of microbial genomes have been completely sequenced, and functional analyses of these genomic sequences are under way. To facilitate these analyses, we have developed a genome-engineering tool for determining essential genes and minimizing bacterial genomes. We made two large pools of independent transposon mutants in Escherichia coli using modified Tn5 transposons with two different selection markers and precisely mapped the chromosomal location of 800 of these transposons. By combining a mapped transposon mutation from each of the mutant pools into the same chromosome using phage P1 transduction and then excising the flanked genomic segment by Cre-mediated loxP recombination, we obtained E. coli strains in which large genomic fragments (59-117 kilobases) were deleted. Some of these individual deletions were then combined into a single "cumulative deletion strain" that lacked 287 open reading frames (313.1 kilobases) but that nevertheless exhibited normal growth under standard laboratory conditions.     

A genome-wide screen identifies 27 genes involved in transposon silencing in C. elegans

Transposon jumps are a major cause of genome instability. In the C. elegans strain Bristol N2, transposons are active in somatic cells, but they are silenced in the germline, presumably to protect the germline from mutations. Interestingly, the transposon-silencing mechanism shares factors with the RNAi machinery. To better understand the mechanism of transposon silencing, we performed a genome-wide RNAi screen for genes that, when silenced, cause transposition of Tc1 in the C. elegans germline. We identified 27 such genes, among which are mut-16, a mutator that was previously found but not identified at the molecular level, ppw-2, a member of the argonaute family, and several factors that indicate a role for chromatin structure in the regulation of transposition. Some of the newly identified genes are also required for cosuppression and therefore represent the shared components of the two pathways. Since most of the newly identified genes have clear homologs in other species, and since transposons are found from protozoa to human, it seems likely that they also protect other genomes against transposon activity in the germline.     

Wake up of transposable elements following Drosophila simulans worldwide colonization.

Transposable elements (TEs) make up around 10%-15% of the Drosophila melanogaster genome, but its sibling species Drosophila simulans carries only one third as many such repeat sequences. We do not, however, have an overall view of copy numbers of the various classes of TEs (long terminal repeat [LTR] retrotransposons, non-LTR retrotransposons, and transposons) in genomes of natural populations of both species. We analyzed 34 elements in individuals from various natural populations of these species. We show that D. melanogaster has higher average chromosomal insertion site numbers per genome than D. simulans for all TEs except five. The LTR retrotransposons gypsy, ZAM, and 1731 and the transposon bari-1 present similar low copy numbers in both species. The transposon hobo has a large number of insertion sites, with significantly more sites in D. simulans. High variation between populations in number of insertion sites of some elements of D. simulans suggests that these elements can invade the genome of the entire species starting from a local population. We propose that TEs in the D. simulans genome are being awakened and amplified as they had been a long time ago in D. melanogaster.     

Whole genome resequencing reveals natural target site preferences of transposable elements in Drosophila melanogaster

Transposable elements are mobile DNA sequences that integrate into host genomes using diverse mechanisms with varying degrees of target site specificity. While the target site preferences of some engineered transposable elements are well studied, the natural target preferences of most transposable elements are poorly characterized. Using population genomic resequencing data from 166 strains of Drosophila melanogaster, we identified over 8,000 new insertion sites not present in the reference genome sequence that we used to decode the natural target preferences of 22 families of transposable element in this species. We found that terminal inverted repeat transposon and long terminal repeat retrotransposon families present clade-specific target site duplications and target site sequence motifs. Additionally, we found that the sequence motifs at transposable element target sites are always palindromes that extend beyond the target site duplication. Our results demonstrate the utility of population genomics data for high-throughput inference of transposable element targeting preferences in the wild and establish general rules for terminal inverted repeat transposon and long terminal repeat retrotransposon target site selection in eukaryotic genomes.     

Tel-1 Transposon-like Elements of Tetrahymena Thermophila Are Associated with Micronuclear Genome Rearrangements

The micronuclear genome of Tetrahymena thermophila contains Tel-1 elements that structurally resemble transposons. Here we present molecular evidence that Tel-1 transposon-like elements are mobile. The arrangements of Tel-1 elements in the micronuclear genomes of several T. thermophila strains and cell lines were assayed by Southern blotting. The molecular evidence for Tel-1 transposition is most striking in strains that have undergone unusual laboratory-induced meioses. The genetic history of the strains exhibiting evidence of Tel-1 transposition is consistent with periods of genome restructuring in response to genomic ``shock' that B. McClintock has suggested could result in transposon activation.     

A systematic identification of Kolobok superfamily transposons in Trichomonas vaginalis and sequence analysis on related transposases

Transposons are sequence elements widely distributed among genomes of all three kingdoms of life, providing genomic changes and playing significant roles in genome evolution. Trichomonas vaginalis is an excellent model system for transposon study since its genome ( ～ 160 Mb) has been sequenced and is composed of ～65% transposons and other repetitive elements. In this study, we primarily report the identification of Kolobok-type transposons (termed tvBac) in T. vaginalis and the results of transposase sequence analysis. We categorized 24 novel subfamilies of the Kolobok element, including one autonomous subfamily and 23 non-autonomous subfamilies. We also identified a novel H2CH motif in tvBac transposases based on multiple sequence alignment. In addition, we supposed that tvBac and Mutator transposons may have evolved independently from a common ancestor according to our phylogenetic analysis. Our results provide basic information for the understanding of the function and evolution of tvBac transposons in particular and other related transposon families in general.     

Transposons in biotechnologically relevant strains of Aspergillus niger and Penicillium chrysogenum

In the past 15 years, many class I and class II transposons were identified in filamentous fungi. However, little is known about the influence of transposons during industrial strain development. The availability of the complete genome sequences of the industrially relevant fungi Aspergillus niger and Penicillium chrysogenum has enabled an analysis of transposons present in these two fungi. Here, a compilation of the transposon-like sequences identified is provided. We investigated a yet undescribed A. niger retrotransposon, ANiTa1, as well as two P. chrysogenum transposons (PeTra1 and PeTra2), which are the first P. chrysogenum transposons ever described, in more detail. Analysis of the genomic distribution of selected transposable elements in five strains of A. niger and seven strains of P. chrysogenum revealed the transposon distribution to be virtually identical. However, one element, Vader-previously published-from A. niger, showed strain-specific differences in transposon distribution, suggesting transposition activity during classical strain improvement programs.     

Somatic excision of the Mu1 transposable element of maize.

The Mu transposons of the Robertsons's Mutator transposable element system in maize are unusual in many respects, when compared to the other known plant transposon systems. The excision of these elements occurs late in somatic tissues and very rarely in the germ line. Unlike the other plant transposons, there is no experimental evidence directly linking Mu element excision and integration. We have analyzed the excision products generated by a Mu1 transposon inserted into the bronze 1 locus of maize. We find that the excision products or 'footprints' left by the Mu1 element resemble those of the other plant transposable elements, rather than those of the animal transposable element systems. We also find some novel types of footprints resembling recombinational events. We suggest that the Mu1 element can promote intrachromosomal crossovers and conversions near its site of insertion, and that this may be another mechanism by which transposons can accelerate the evolution of genomes.     

The rde-1 gene, RNA interference, and transposon silencing in C. elegans.

Double-stranded (ds) RNA can induce sequence-specific inhibition of gene function in several organisms. However, both the mechanism and the physiological role of the interference process remain mysterious. In order to study the interference process, we have selected C. elegans mutants resistant to dsRNA-mediated interference (RNAi). Two loci, rde-1 and rde-4, are defined by mutants strongly resistant to RNAi but with no obvious defects in growth or development. We show that rde-1 is a member of the piwi/sting/argonaute/zwille/eIF2C gene family conserved from plants to vertebrates. Interestingly, several, but not all, RNAi-deficient strains exhibit mobilization of the endogenous transposons. We discuss implications for the mechanism of RNAi and the possibility that one natural function of RNAi is transposon silencing.     

The <Emphasis Type="Italic">piggyBac</Emphasis> Transposon as a Tool in Genetic Engineering

Transposons are mobile genetic elements that are part of the genomic DNA of numerous organisms and belong to two classes. Unlike class I transposons, class II DNA transposons do not use the stage of RNA synthesis in their transition; they perform it by the cut-and-paste mechanism or with a replicative transposition. The integration of a DNA transposon in a new site results in the duplication of a target sequence on either side of a transposon, and its excision is, as a rule, associated with insertions and deletions. The piggyBac transposon isolated from the Trichoplusia ni moth differs from other mobile elements of its class. Due to its unique ability to leave no traces after excision from an insertion site and to perform successful transposition and transference of large DNA fragments, piggyBac is a convenient tool for the development of gene engineering approaches. The TTAA sequence serves as a target site for transposon integration: insertion in the AT-rich DNA regions is more frequent. The ability of piggyBac to be transferred to a new area independently of the cell apparatus and to restore a DNA site without error after excision lies in the mechanism of its transposition, which is discussed in detail in the present review. Along with other transposons and viruses, the piggyBac transposon is widely used in the transgenesis of various organisms; it also finds application in insertion mutagenesis and gene therapy.