Successive transposition explosions in Drosophila melanogaster and reverse transpositions of mobile dispersed genetic elements

Transposition outbursts occur in the destabilized Drosophila melanogaster strain ct^MR2 carrying a mutation in the locus cut induced by an insertion of mdg4. While the distribution of mobile genetic elements remained unchanged in the great majority of germ cells, in a few cells numerous transpositions had occurred involving mdg (copia-like), fold-back and P-elements. We used in situ hybridization to analyze the distribution of five families of mdg elements in the X-chromosome during several consequent mutational changes in D. melanogaster. Each of them was accompanied by many changes in mdg localization, all of which occurred in one and the same cell. Thus, we could observe the series consisting of up to five successive transposition explosions leading to an almost complete change in the distribution of the mdg elements tested. We also found that in the course of successive transposition explosions, mdg elements often inserted into those sub-sections of the X-chromosome where they had previously been located. This phenomenon, designated as reverse directed transposition, was studied in more detail on insertion into the locus yellow. The rate of reverse transposition of the same mdg element to the corresponding locus was 10–100 times as high as that of primary insertion. In some cases, `the transposon shuttle' into and out of the locus was observed. The existence of `transposition memory' partially explains the specificity of mdg localization in closely related strains as well as the co-ordinated behaviour of different mdg elements in independent transposition explosions. The evolutionary significance of transposition explosions and directed reverse transposition (transposon shuttle) is discussed.     

Transposition bursts in analysis of repeated mutations in unstable strains of Drosophila melanogaster

The phenomenon of transposition memory was earlier demonstrated for the cut locus and mdg4. This work has been aimed at finding out, in what way the transposition memory can be realized. An unstable stock cmMR17ctMRpN17 was analysed which had high frequency of double cm+ct+ reversions and cmMRctMRpN repeated mutations. A series of five such transpositions could be followed. The ctMRpN17 mutation is a result of insertion at the cut locus mdg4 with the jockey element inserted within it. As seen from in situ hybridization analysis, transitions to the normal phenotype correlate, as a rule, with the excision of mdg4 and the jockey from the cut locus. Analysis of distribution of mdg1, mdg2, mdg3 and jockey on the X-chromosome of unstable revertants and repeated mutants indicated that not only transpositions of mdg4 and jockey, but also those of all mobile elements tested occur. So, we propose that the transposition memory in our genetic system is manifested in the process of transposition bursts.     

Interaction of mobile elements P and mdg3 in Drosophila melanogaster: genetic aspects

It was found earlier that two unstable sn mutants isolated from natural populations are connected with insertion of mobile element mdg3 into the 7D1-2 region where singed gene (1-21.0) is localised. From two original sn mutants, a series of unstable sn alleles, both mutant and normal for phenotype, was extracted. Then we studied, how they change the mutation rate in germinal and somatic cells of different hybrids with pi 2 stock having P cytotype and active P elements in the chromosomes. Addition of P chromosomes, independently of the background of cytoplasm, proved to reduce the sn instability. The level of sn mutability was decreased with increasing the dose of P chromosomes. It is suggested that mutation events are caused by transposition of mdg3 and that both mdg3 and P elements compete for the same cellular factor, capable of activation of transposition process.     

Fluorescence in situ hybridization analysis of hobo, mdg1 and Dm412 transposable elements reveals genomic instability following the Drosophila melanogaster genome sequencing

The genome of Drosophila melanogaster strain y cn bw sp has been sequenced and the transposable elements insertion sites have been determined. We hybridized fluorescence-labeled probes directed to the hobo transposon, Dm412 and mdg1 retrotransposons to polytene chromosomes and compared the observed sites to those published in the annotated genome sequence. We observed an almost twofold increase in the number of hobo hybridization sites (46 found as compared to 24 annotated sites). There was no evidence that the hobo transposition rate is slowing over the 10-year period. The patterns of Dm412 and mdg1 sites have changed less dramatically since the time of genome sequencing. Three novel Dm412 hybridization sites were detected while 4 out of 30 annotated sites were missing. Only one additional mdg1 site was found, while 1 out of 29 annotated sites has been lost.     

Transposition of a bacterial insertion sequence in chloroplasts

Bacterial transposable elements (IS elements, transposons) represent an important determinant of genome structure and dynamics, and are a major force driving genome evolution. Here, we have tested whether bacterial insertion sequences (IS elements) can transpose in a prokaryotic compartment of the plant cell, the plastid (chloroplast). Using plastid transformation, we have integrated different versions of the Escherichia coli IS element IS 150 into the plastid genome of tobacco ( Nicotiana tabacum ) plants. We show that IS 150 is faithfully mobilized inside the chloroplast, and that enormous quantities of transposition intermediates accumulate. As synthesis of the IS 150 transposase is dependent upon programmed ribosomal frame shifting, our data indicate that this process also occurs in chloroplasts. Interestingly, all insertion events detected affect a single site in the plastid genome, suggesting that the integration of IS 150 is highly sequence dependent. In contrast, the initiation of the transposition process was found to be independent of the sequence context. Finally, our data also demonstrate that plastids lack the capacity to repair double-strand breaks in their genomes by non-homologous end joining, a finding that has important implications for genome stability, and which may explain the peculiar immunity of the plastid to invading promiscuous DNA sequences of nuclear and mitochondrial origin.     

Malignant cell transformation and oncogenes

In genome of all transforming retroviruses special genes (oncogenes) have been identified which play a key role in malignant conversion of the cells, infected with these viruses. The homologues of these genes (protooncogenes) are persist in all normal cells. During transformation protooncogenes can be activated as a result of one of following processes: insertion of promotor-like elements, mutations, translocations, amplifications or rearrangements. Using transfection technique the transforming genes were isolated from different human tumors. The activation of one of the cellular oncogenes may switch on the other genes and malignant cell transformation may be characterized as a multifactor and multistage process.     

The influence of transposable elements on animal colouration

Transposable elements (TEs) are mobile genetic sequences present within host genomes. TEs can contribute to the evolution of host traits, since transposition is mutagenic and TEs often contain host regulatory and protein coding sequences. We review cases where TEs influence animal colouration, reporting major patterns and outstanding questions. TE-induced colouration phenotypes typically arise via introduction of novel regulatory sequences and splice sites, affecting pigment cell development or pigment synthesis. We discuss if particular TE types may be more frequently involved in the evolution of colour variation in animals, given that examples involving long terminal repeat (LTR) elements appear to dominate. Currently, examples of TE-induced colouration phenotypes in animals mainly concern model and domesticated insect and mammal species. However, several influential recent examples, coupled with increases in genome sequencing, suggest cases reported from wild species will increase considerably.     

The first steps of transposable elements invasion: parasitic strategy vs. genetic drift

Transposable elements are often considered as selfish DNA sequences able to invade the genome of their host species. Their evolutive dynamics are complex, due to the interaction between their intrinsic amplification capacity, selection at the host level, transposition regulation, and genetic drift. Here, we propose modeling the first steps of TE invasion, i.e., just after a horizontal transfer, when a single copy is present in the genome of one individual. If the element has a constant transposition rate, it will disappear in most cases: the elements with low-transposition rate are frequently lost through genetic drift, while those with high-transposition rate may amplify, leading to the sterility of their host. Elements whose transposition rate is regulated are able to successfully invade the populations, thanks to an initial transposition burst followed by a strong limitation of their activity. Self-regulation or hybrid dysgenesis may thus represent some genome-invasion parasitic strategies.     

New regulatory regions of Drosophila 412 retrotransposable element generated by recombination

There are no doubts that transposable elements (TEs) have greatly influenced genomes evolution. They have, however, evolved in different ways throughout mammals, plants, and invertebrates. In mammals they have been shown to be widely present but with low transposition activity; in plants they are responsible for large increases in genome size. In Drosophila, despite their low amount, transposition seems to be higher. Therefore, to understand how these elements have evolved in different genomes and how host genomes have proposed to go around them, are major questions on genome evolution. We analyzed sequences of the retrotransposable elements 412 in natural populations of the Drosophila simulans and D. melanogaster species that greatly differ in their amount of TEs. We identified new subfamilies of this element that were the result of mutation or insertion-deletion process, but also of interfamily recombinations. These new elements were well conserved in the D. simulans natural populations. The new regulatory regions produced by recombination could give rise to new elements able to overcome host control of transposition and, thus, become potential genome invaders.     

Evidence for horizontal transfer of the LTR retrotransposon mdg3, which lacks an env gene

Horizontal (interspecific) transfer is regarded as a possible strategy for the propagation of transposable elements through evolutionary time. To date, however, conclusive evidence that transposable elements are capable of horizontal transfer from one species to another has been limited to class II or DNA-type elements. We tested the possibility of such transfer for several Drosophila melanogaster LTR retrotransposons of the gypsy group in an experiment in which D. melanogaster and D. virilis somatic cell lines were used as donor and recipient cells, respectively. This approach was chosen in light of the high levels of LTR retrotransposon amplification and expression observed in cultured D. melanogaster cells. In the course of the experiment, parallel analysis for mdg1, mdg3, 17.6, 297, 412 and B104/roo retrotransposons was performed to detect their presence in the genome of recipient cells. Only the mdg3 retrotransposon, which lacks an env gene, was found to be transmitted into recipient cells. This model, based on the use of cultured cells, is a promising system for further investigating the mechanisms of LTR retrotransposon transfer.     

Extrachromosomal DNA forms of copia-like transposable elements, F elements and middle repetitive DNA sequences in Drosophila melanogaster. Variation in cultured cells and embryos

Drosophila melanogaster embryos and cells in culture were screened for the presence of unintegrated covalently closed circular DNA forms that hybridize to copia-like transposable elements, the F element and uncharacterized dispersed middle repetitive DNA elements. Our results indicate that the majority of copia-like elements (including copia, 297, 412, mdg1, mdg3 and gypsy), the F elements, and 9 of 12 middle repetitive DNA elements are present as free DNA forms in cultured cells and embryos. An 18 base-pair inverted repeat has been reported to flank the long direct repeat of mdg3, implying that mdg3 is not an orthodox copia-like element; however, we have sequenced two independently isolated mdg3 clones and shown that the inverted repeat is not part of the element. The relative abundance with which free DNA forms are found varies between the cultured cells used, and between cultured cells and embryos. This variation, which can be up to 20-fold for some elements, does not correlate well with either the amount of element-specific poly(A)+ RNA present per cell or the number of element-specific sequences integrated in the genome.     

植物中的反转录转座子及其应用

反转录转座子是植物中最不稳定的遗传元件之一,它们对基因组的大小、结构、功能和进化都有重要作用。本文综述了近年来对植物反转录转座子类型和结构、在基因组中表达、调控、转座活动、进化等方面的研究进展,讨论了它们在遗传研究中的应用前景。 Abstract:Retrotransposons are one of the most unstable genetic elements in the plant kingdom,they have the potential to dramatically affect gene function and host genome structure.The current status of their types and structure,expression regulation,transposition,and evolution are reviewed.Their potential as genetic tools are also discussed.     

Integration of R plasmid Rts1 to the gal region of the Escherichia coli chromosome.

An R plasmid Rts1 was integrated into the gal region of the chromosome of Escherichia coli XA-7012 (galE) strain by the directed transposition technique. The integration of the Rts1 genome was confirmed mainly by conjugation studies and also by transduction experiments using phage P1. As a result, it was found that the integrated genome contained genes responsible for kanamycin resistance, conjugal transferability, and for autonomous replication. As reported previously, Rts1 is temperature sensitive in replication and inhibits the growth of the host at nonpermissive temperature. However, although a plasmid derived from the integrated Rts1 genome still demonstrates temperature sensitivity upon transfer and high level of kanamycin resistance, this plasmid no longer displays temperature sensitivity in replication and the inhibitory effect on the host. These results indicate that the temperature sensitivity of replication of Rts1 and its inhibitory effect on the host cell are due to the presence of a gene or gene cluster on the Rts1 genome and that the gene(s) is clearly discriminated from the one responsible for the temperature sensitivity of transfer.     

Mutator转座子及MULE在植物基因与基因组进化中的作用

Mutator（Mu）转座子是植物中已发现的转座最活跃的转座子,其高的转座频率及趋向于单拷贝功能基因转座的特性,使该转座子成为玉米功能基因克隆的主要方法.Mu转座子的同源类似因子广泛存在于被子植物基因组中,而且同一基因组中往往具有多种变异类型.它不仅具有其他DNA转座子在基因和基因组进化中的普遍作用,而且具有能够承载基因组内功能基因和基因片段的载体功能,这种载体Mu转座子（Pack-MuLEs）能够在基因组内移动众多的基因片段,从而对基因和基因组进化产生作用.Mu转座子的同源序列发生在水稻与狗尾草之间的水平转移提供了高等植物核基因水平转移的首个例证.对Mu转座子的了解促进了我们对动态基因组概念的认识.文章对Mutator转座子的发现、转座特征、基因标签应用等的研究进展进行了综述,对Mu转座子家族的同源序列进行了分类,讨论了该转座子在基因组进化中的作用,分析了应加强研究的问题.     

Genomic regulation of transposable elements in Drosophila

Transposable elements are a major source of genetic change, including the creation of novel genes, the alteration of gene expression in development, and the genesis of major genomic rearrangements. They are ubiquitous among contemporary organisms and probably as old as life itself. The long coexistence of transposable elements in the genome would be expected to be accompanied by host-element coevolution. Indeed, the important role of host factors in the regulation of transposable elements has been illuminated by recent studies of several systems in Drosophila. These include host factors that regulate the P element, a host mutation that renders the genome permissive for gypsy mobilization and infection, and newly induced mutations that affect the expression of transposon insertion mutations. The finding of a type of hybrid dysgenesis in D. virilis, in which multiple unrelated transposable elements are mobilized simultaneously, may also be relevant to host-factor regulation of transposition.     

Alternative Transposition Generates New Chimeric Genes and Segmental Duplications at the Maize p1 Locus

The maize Ac/Ds transposon family was the first transposable element system identified and characterized by Barbara McClintock. Ac/Ds transposons belong to the hAT family of class II DNA transposons. We and others have shown that Ac/Ds elements can undergo a process of alternative transposition in which the Ac/Ds transposase acts on the termini of two separate, nearby transposons. Because these termini are present in different elements, alternative transposition can generate a variety of genome alterations such as inversions, duplications, deletions, and translocations. Moreover, Ac/Ds elements transpose preferentially into genic regions, suggesting that structural changes arising from alternative transposition may potentially generate chimeric genes at the rearrangement breakpoints. Here we identified and characterized 11 independent cases of gene fusion induced by Ac alternative transposition. In each case, a functional chimeric gene was created by fusion of two linked, paralogous genes; moreover, each event was associated with duplication of the ∼70-kb segment located between the two paralogs. An extant gene in the maize B73 genome that contains an internal duplication apparently generated by an alternative transposition event was also identified. Our study demonstrates that alternative transposition-induced duplications may be a source for spontaneous creation of diverse genome structures and novel genes in maize.