Transposon Display identifies individual transposable elements in high copy number lines

The dTph1 transposable element family of Petunia hybrida line W138 consists of between 100 and 200 members. A strategy that allows simultaneous detection of individual elements is described. Sequences flanking dTph1 elements are amplified by means of a ligation-mediated PCR. The resulting fragments are locus-specific and can be analysed by polyacrylamide gel electrophoresis. One of the applications of Transposon Display is the isolation of dTph1-tagged genes. Fragments that co-segregate with a mutant phenotype can be extracted from the gel and reamplified, providing access to tagged genes, as demonstrated in a reconstruction experiment. Data on the molecular identification of a phenotypic mutant, isolated in a random tagging experiment is also presented. Upon sequencing, the obtained candidate fragment was found to be identical to part of the previously identified Fbp1 gene.     

Population genetics models of transposable elements

The control of transposable element copy number is of considerable theoretical and empirical interest. Under simple models, copy numbers may increase without limit. Mechanisms that can prevent such an increase include those in which the effect of selection increases with copy number, those in which the rate of transposition decreases with copy number, and those where unlimited increase in copy number is prevented by the consequences of functional heterogeneity in the transposable element family. Finite population sizes may attenuate the power of natural selection to act on transposable element copy number in a number of ways that may be of particular importance in laboratory populations. First, a small host population size will create occasional periods in which the variance between individuals in copy number is diminished, and with it the power of natural selection, even when the expected variance is Poisson. Second, small population sizes will produce high-frequency transposable element sites, systematically reducing the variance in copy number. The consequences will be particularly profound when the selective damage of transposable elements follows from their heterozygosity, as when ectopic exchange limits copy number. This revised version was published online in August 2006 with corrections to the Cover Date.     

A transient transgenic RNAi strategy for rapid characterization of gene function during embryonic development

RNA interference (RNAi) is a powerful strategy for studying the phenotypic consequences of reduced gene expression levels in model systems. To develop a method for the rapid characterization of the developmental consequences of gene dysregulation, we tested the use of RNAi for "transient transgenic" knockdown of mRNA in mouse embryos. These methods included lentiviral infection as well as transposition using the Sleeping Beauty (SB) and PiggyBac (PB) transposable element systems. This approach can be useful for phenotypic validation of putative mutant loci, as we demonstrate by confirming that knockdown of Prdm16 phenocopies the ENU-induced cleft palate (CP) mutant, csp1. This strategy is attractive as an alternative to gene targeting in embryonic stem cells, as it is simple and yields phenotypic information in a matter of weeks. Of the three methodologies tested, the PB transposon system produced high numbers of transgenic embryos with the expected phenotype, demonstrating its utility as a screening method.     

Evolutionary forces generating sequence homogeneity and heterogeneity within retrotransposon families

Genome projects allow us to sample copies of a retrotransposon sequence family residing in a host genome. The variation in DNA sequence between these individual copies will reflect the evolutionary process that has spread the sequences through the genome. Here I review quantitatively the expected diversity of elements belonging to a transposable genetic element family. I use a simple neutral model for replicative mobile DNAs such as retrotransposons to predict the extent of sequence variability between members of a single family of transposable elements, both within and between species. The effects of horizontal transfer are also explored. I also consider the impact on these distributions of an increase in transposition rate arising from a mutational change in copy of the sequence. In addition, I consider the question of the interaction between retrotransposons and their hosts, and the causes of the abundance of transposable elements in the genomes that they occupy.     

Structural comparison of the integrative and conjugative elements R391, pMERPH, R997, and SXT

R391 and SXT are members of a group of eleven chromosome-borne conjugative elements found in the gamma-proteobacteria, whose members carry different antibiotic resistance traits. Recent genomic analysis of R391 and SXT revealed a highly conserved 'backbone' encoding integration/excision, conjugative transfer, and regulation functions, augmented by an array of phenotypic traits and transposable elements. In this study, PCR amplification and sequence analysis were employed to investigate the genomic structure of two further MGE of the R391 family, pMERPH (HgR) and R997 (ApR, SmR, SuR). R997 and pMERPH were found to be structurally related to R391 and SXT and share a number of virtually identical regions with them-including putative integration, conjugative transfer, and regulatory determinants-interrupted by variable DNA segments and transposable elements. The presence of a highly conserved backbone in the four elements strongly suggests their origin in a common ancestral element, which itself was a mosaic of sequences related to phages and plasmids. Subsequent genetic recombination and the acquisition of transposable elements resulted in the possession of variable phenotypic traits among the four MGE, and diversification into two distinct lineages, the first one including R391 and pMERPH, the second one containing SXT and R997.     

A Model for DNA Sequence Evolution within Transposable Element Families

A quantitative model is proposed for the expected degree of relationship between copies of a family of transposable elements in a finite population of hosts. Special cases of the model (in which the process of homogenization of element copies either is or is not limited by transposition rate) are presented and illustrated, using data on mobile sequences from different species. It is shown that transposition will be expected, in large populations, to result in only a rather distant relationship between transposable elements at different genomic sites. Possible inadequacies of the model are suggested and quantified.     

Insertion mutagenesis and study of transposable elements using a new unstable virescent seedling allele for isolation of haploid petunia lines

The new unstable virescent seedling ( vis* ) allele of a petunia mutant, that has green leaves but white cotyledons with green revertant spots, was used to identify spontaneously occurring haploid petunia lines with active transposable elements. Endogenous transposons were trapped into the single petunia nitrate reductase structural gene ( nia ) using chlorate selection on haploid protoplasts. In two mutant lines, the dTph1 -like transposable element dTph1–3 was inserted at almost the same position but in opposite orientations in the first exon of the nia gene. In a third mutant, a different transposable element was integrated into the fourth exon. This element, called dTph4 , is 787 bp long and has 13 bp terminal inverted repeats of which 12 bp are identical to those of dTph1 . Insertion of dTph1–3 and dTph4 results in an 8 bp duplication of the target site, as already described for dTph1 . In contrast to dTph1 -like elements, dTph4 is present at low copy number in the petunia genome. This can facilitate its use for gene tagging in petunia. The dTph1–3 and dTph4 elements excise frequently, as transposon footprints were found in most of the insertion mutants. The data demonstrate that haploid petunia is an excellent system for gene tagging and for the study of transposable elements.     

PCR detection of excision suggests mobility of the medaka fish Tol1 transposable element in the frog Xenopus laevis

Tol1 is a DNA-based transposable element identified in the medaka fish Oryzias latipes and a member of the hAT (hobo/Activator/Tam3) transposable element family. Its mobility has already been demonstrated in the human and mouse, in addition to its original host species. This element is thus expected to be useful in a wide range of vertebrates as a genomic manipulation tool. Herein, we show that the Tol1 element can undergo excision in the African clawed frog Xenopus laevis, a major model organism for vertebrate genetics and developmental biology. An indicator plasmid carrying a Tol1 element was injected into 2- or 4-cell-stage embryos together with either a helper plasmid coding for the full-length Tol1 transposase or a modified helper plasmid yielding a truncated protein, and recovered from tailbud-stage embryos. Deletion of the Tol1 region of the indicator plasmid was observed in the experiment with the full-length transposase, and not in the other case. The deletion was associated with various footprint sequences at breakpoints, as frequently observed with many DNA-based transposable elements. These results indicate that the Tol1 element was excised from the indicator plasmid by catalysis of the transposase, and suggest that the Tol1 element is mobile in this frog species.     

Characterization of Tpn1 family in the Japanese morning glory: En/Spm-related transposable elements capturing host genes

Some mutant phenotypes are known to be unstable somatically and germinally due to the insertion of transposable elements in the Japanese morning glory (Ipomoea nil). Several transposable elements that cause mutable phenotypes have recently been isolated. All of these elements show characteristic features of the En/Spm (Enhancer/Suppressor-mutator) or CACTA family. They carry common 28 bp terminal inverted repeats and subterminal repetitive regions and are known as the Tpn1 family. All of these elements are thought to be non-autonomous and mobilized by unidentified autonomous element(s). Using a probe corresponding to the subterminal region, we isolated many genomic Tpn clones, 120 of which were classified into 28 types based on their restriction maps. The copy number of the Tpn1 family was estimated to be between 500 and 1,000 copies per haploid genome. We then determined the complete sequences of 28 representative clones from each Tpn type. Most Tpn elements showed a high degree of similarity to plant genes in their internal sequences, suggesting that the Tpn1 family captured host gene sequences during the process of evolution. Detailed analyses of Tpn104 in comparison with an orthologous host gene InAP2B confirmed this assumption.     

Genome-wide comparison of cyanobacterial transposable elements, potential genetic diversity indicators

Transposable elements are widely distributed in archaea, bacteria and eukarya domains. Considerable discrepancies of transposable elements in eukaryotes have been reported, however, the studies focusing on the diversity of transposable element systems in prokaryotes were scarce. Understanding the transposable element system in cyanobacteria by the genome-wide analysis will greatly improve the knowledge of cyanobacterial diversity. In this study, the transposable elements of seventeen cyanobacterial genomes were analyzed. The abundance of insertion sequence (IS) elements differs significantly among the cyanobacterial genomes examined. In particular, water bloom forming Microcystis aeruginosa NIES843 was shown to have the highest abundance of IS elements reaching 10.85% of the genome. IS family is a widely acceptable IS classification unit, and IS subfamily, based on probe sequences, was firstly proposed as the basic classification unit for IS element system, therefore both IS family and IS subfamily were suggested as the two hierarchical units for evaluating the IS element system diversity. In total, 1980 predicted IS elements, within 21 IS families and 132 subfamilies, were identified in the examined cyanobacterial genomes. Families IS4, IS5, IS630 and IS200-605 are widely distributed, and therefore supposed to be the ancestral IS families. Analysis on the intactness of IS elements showed that the percentage of the intact IS differs largely among these cyanobacterial strains. Higher percentage of the intact IS detected in the two hot spring cyanobacterial strains implied that the intactness of IS elements may be related to the genomic stabilization of cyanobacteria inhabiting in the extreme environments. The frequencies between IS elements and miniature inverted-repeat transposable elements (MITEs) were shown to have a linear positive correlation. The transposable element system in cyanobacterial genomes is of hypervariability. With characterization of easy definition and stability, IS subfamily is considered as a reliable lower classification unit in IS element system. The abundance of intact IS, the composition of IS families and subfamilies, the sequence diversity of IS element nucleotide and transposase amino acid are informative and suitable as the indicators for studies on cyanobacterial diversity. Practically, the transposable system may provide us a new perspective to realize the diversity and evolution of populations of water bloom forming cyanobacterial species.     

New transposable elements identified as insertions in rice transposon Tnr1

Tnr1 (235 bp long) is a transposable element in rice. Polymerase chain reactions (PCRs) done with a primer(s) that hybridizes to terminal inverted repeat sequences (TIRs) of Tnr1 detected new Tnr1 members with one or two insertions in rice genomes. Six identified insertion sequences (Tnr4, Tnr5, Tnr11, Tnr12, Tnr13 and RIRE9) did not have extensive homology to known transposable elements, rather they had structural features characteristic of transposable elements. Tnr4 (1767 bp long) had imperfect 64-bp TIRs and appeared to generate duplication of a 9-bp sequence at the target site. However, the TIR sequences were not homologous to those of known transposable elements, indicative that Tnr4 is a new transposable element. Tnr5 (209 bp long) had imperfect 46-bp TIRs and appeared to generate duplication of sequence TTA like that of some elements of the Tourist family. Tnr11 (811 bp long) had 73-bp TIRs with significant homology to those of Tnr1 and Stowaway and appeared to generate duplication of sequence TA, indicative that Tnr11 is a transposable element of the Tnr1/Stowaway family. Tnr12 (2426 bp long) carried perfect 9-bp TIRs, which began with 5'-CACTA- -3' from both ends and appeared to generate duplication of a 3-bp target sequence, indicative that Tnr12 is a transposable element of the En/Spm family. Tnr13 (347 bp long) had 31-bp TIRs and appeared to generate duplication of an 8-bp target sequence. Two sequences, one the transposon-like element Crackle, had partial homology in the Tnr13 ends. All five insertions appear to be defective elements derived from autonomous ones encoding the transposase gene. All had characteristic tandem repeat sequences which may be recognized by transposase. The sixth insertion sequence, named RIRE9 (3852 bp long), which begins with 5'-TG- -3' and ends with 5'- -CA-3', appeared to generate duplication of a 5-bp target sequence. These and other structural features indicate that this insertion is a solo LTR (long terminal repeat) of a retrotransposon. The transposable elements described above could be identified as insertions into Tnr1, which do not deleteriously affect the growth of rice cells.     

Transposition without transposase: a spontaneous mutation in bacteria.

Transposition mutations are typically associated with the activities of transposable elements such as transposons and insertion sequences, whose mobility is dependent upon transposase enzymes that catalyze exchanges between element ends and target sites. We describe a single transposition event in which a block of donor sequence is inserted at a target site without the involvement of any known transposase or the ends of any known transposable element. We propose that this is a new type of spontaneous mutation which may be difficult to detect in standard mutant hunts but may be of evolutionary importance.     

Identification of active transposon dTok, a member of the hAT family, in rice

Recent completion of the sequencing of the rice genome has revealed that it contains >40% repetitive sequences, most of which are related to inactive transposable elements. During the molecular analysis of the floral organ number 1/multiple pistil 2 (fon1/mp2) mutant, we identified an active transposable element dTok0 that was inserted at the kinase domain of FON1, a homolog of CLAVATA1. Insertion of the element into FON1 generated an 8 bp duplication of its target sites, which is one of the major characteristics of the hAT family of transposons. The dTok0 element was actively transposed out of the FON1 gene, leaving 5-8 bp footprints. Reinsertion into a new location was observed at a low frequency. Analysis of the genome sequence showed that the rice cultivar 'Nipponbare' contains 25 copies of dTok elements; similar numbers were present in all the Oryza species examined. Because dTok0 does not encode a transposase, enzyme activity should be provided in trans. We identified a putative autonomous transposon, Tok1 that contains an intact open reading frame of the Ac-like transposase.     

Plant transposable elements generate the DNA sequence diversity needed in evolution

Two germinal and 16 somatic reversion events induced by the Enhancer (En) transposable element system at the wx-8::Spm-I8 allele of Zea mays were cloned and studied by sequence analysis. Excision of the Spm-I8 receptor element from the wx gene results in various mutant DNA sequences. This leads to altered gene products, some of which are still capable of restoring the wild-type phenotype. Possible 'foot-print' sequences that may have arisen by the excision of transposable elements were observed when intron sequences of the wild-type (wx+) and mutant (wx-m8) alleles of the wx gene were compared. The sequence divergence generated by visitation of a locus by plant transposable elements is discussed with respect to the molecular evolution of the new gene functions.     

Models of Repression of Transposition in P-M Hybrid Dysgenesis by P Cytotype and by Zygotically Encoded Repressor Proteins

By analytical theory and computer simulation the expected evolutionary dynamics of P transposable element spread in an infinite population are investigated. The analysis is based on the assumption that, unlike transposable elements which move via RNA intermediates, the harmful effects of P elements arise primarily in the act of transposition, and that this causes their evolutionary dynamics to be unusual. It is suggested that a situation of transposition-selection balance will be superceded by the buildup of a cytoplasmically inherited repression or by the elimination of active transposase-encoding elements from the chromosomes, a process which may be accompanied by the evolution of elements which encode proteins which repress transposition.     

Repeat-induced point mutation and the population structure of transposable elements in Microbotryum violaceum

Repeat-induced point mutation (RIP) is a genome defense in fungi that hypermutates repetitive DNA and is suggested to limit the accumulation of transposable elements. The genome of Microbotryum violaceum has a high density of transposable elements compared to other fungi, but there is also evidence of RIP activity. This is the first report of RIP in a basidiomycete and was obtained by sequencing multiple copies of the integrase gene of a copia-type transposable element and the helicase gene of a Helitron-type element. In M. violaceum, the targets for RIP mutations are the cytosine residues of TCG trinucleotide combinations. Although RIP is a linkage-dependent process that tends to increase the variation among repetitive sequences, a chromosome-specific substructuring was observed in the transposable element population. The observed chromosome-specific patterns are not consistent with RIP, but rather suggest an effect of gene conversion, which is also a linkage-dependent process but results in a homogenization of repeated sequences. Particular sequences were found more widely distributed within the genome than expected by chance and may reflect the recently active variants. Therefore, sequence variation of transposable elements in M. violaceum appears to be driven by selection for transposition ability in combination with the context-specific forces of the RIP and gene conversion.     

A new copia-like transposable element found in a Drosophila rDNA gene unit.

We have discovered a member of a new family of copia-like transposable elements inserted into the non-transcribed spacer between two ribosomal genes (rDNA). This family, which we call 3S18, consists of at least 15 elements which are scattered throughout the Drosophila melanogaster genome. The elements of this family are approximately 6.5 kb long and have 0.5 kb terminal direct repeats. All of the elements appear to have the same restriction sites. The element is mobile as the size pattern of homologous fragments varies among different strains. In situ hybridization results confirm the scattered location and transposable qualities of 3S18. The element is not transcribed into abundant RNA.