Maintenance of transposable element copy number in natural populations of Drosophila melanogaster and D. simulans

To investigate the main forces controlling the containment of transposable elements (TE) in natural populations, we analyzed the copia, mdg1, and 412 elements in various populations of Drosophila melanogaster and D. simulans. A lower proportion of insertion sites on the X chromosome in comparison with the autosomes suggests that selection against the detrimental effects of TE insertions is the major force containing TE copies in populations of Drosophila. This selection effect hypothesis is strengthened by the absence of the negative correlation between recombination rate and TE copy number along the chromosomes, which was expected under the alternative ectopic exchange model (selection against the deleterious rearrangements promoted by recombination between TE insertions). A cline in 412 copy number in relation to latitude was observed among the natural populations of D. simulans, with very high numbers existing in some local populations (around 60 copies in a sample from Canberra, Australia). An apparent absence of selection effects in this Canberra sample and a value of transposition rate equal to 1–2 × 10^-3 whatever the population and its copy number agree with the idea of recent but temporarily drastic TE movements in local populations. The high values of transposition rate in D. simulans clearly disfavor the hypothesis that the low amount of transposable elements in this species could result from a low transposition rate. This revised version was published online in August 2006 with corrections to the Cover Date.     

A temperature cline in copy number for 412 but not roo/B104 retrotransposons in populations of Drosophila simulans.

The copy number of the retrotransposable element 412 of Drosophila simulans from populations collected worldwide shows a negative correlation with minimum temperature. No association was detected for the roo/B104 element. The possibility that selective pressures might regulate the 412 copy number in these natural populations is supported by detection of selection against the detrimental effects of 412 insertions (estimated by the proportion of insertions on the X chromosome in comparison with the autosomes) but not roo/B104. These data reveal different spatial patterns for two element families, and strongly suggest that some factors in the environment, such as temperature, may interfere with the control of retrotransposition, thus affecting important aspects of genomic evolution.     

Geographical variation in insertion site number of retrotransposon 412 inDrosophila simulans

The insertion site number of the retrotransposable element 412 was analyzed in natural populations ofDrosophila simulans of worldwide origin by in situ hybridization. We observe a gradient in copy number ranging from as high as 23 in Europe to 1–10 in South Africa, while populations in Madagascar and the Indian Islands, which are the cradle ofD. simulans, have only 3–7 copies. We find very different copy numbers in some local populations of Australia and the Pacific Islands (with around 60 copies in 1 sample and only 5 in another), suggesting spontaneous transposition bursts in local populations. Such bursts occurring now and then in local natural populations followed by fly migration could lead to the progressive invasion of the entire species by the transposable element mobilized, explaining the gradient in 412 copy number between northern and southern hemispheres.     

Accumulation of transposable elements in laboratory lines of Drosophila melanogaster

It is recognized that a stable number of transposable element (TE) copies per genome is maintained in natural populations of D. melanogaster as a result of the dynamic equilibrium between transposition to new sites and natural selection eliminating copies. The force of natural selection opposing TE multiplication is partly relaxed in inbred laboratory lines of flies. The average rate of TE transposition is from 2.6 × 10 ^-4 to 5.0 ×10 ^-4 per copy per generation, and the average rate of excision is at least two orders of magnitude lower; therefore inbred lines accumulate increasing numbers of copies with time. Correlations between the rate of transposition and TE copy number have been determined for copia, Doc, roo, and 412 and found to be either zero or positive. Because the rate of transposition is not a decreasing function of TE copy number, TE accumulation in inbred lines is self-accelerating. Transpositions cause a substantial fraction of mutations in D. melanogaster, therefore the mutation rate should increase with time in laboratory lines of this species. Inferences about the properties of spontaneous mutations from studies of mutation accumulation in laboratory lines should be reevaluated, because they are based on the assumption of a constant mutation rate. This revised version was published online in August 2006 with corrections to the Cover Date.     

Rates of movement of transposable elements on the second chromosome of Drosophila melanogaster

The rates of movement of 11 families of transposable elements of Drosophila melanogaster were studied by means of in situ hybridization of probes to polytene chromosomes of larvae from a long-term mutation accumulation experiment. Replicate mutation-accumulation lines carrying second chromosomes derived from a single common ancestral chromosome were maintained by backcrosses of single males heterozygous for a balancer chromosome and a wild-type chromosome, and were scored after 116 generations. Twenty-seven transpositions and 1 excision were detected using homozygous viable and fertile second chromosomes, for a total of 235,056 potential sources of transposition events and a potential 252,880 excision events. The overall transposition rate per element per generation was 1.15 x 10(-4) and the excision rate was 3.95 x 10(-6). The single excision (of a roo element) was due to recombination between the element's long terminal repeats. A survey of the five most active elements among nine homozygous lethal lines revealed no significant difference in the estimates of transposition and excision rates from those from viable lines. The excess of transposition over excision events is in agreement with the results of other in situ hybridization experiments, and supports the conclusion that replicative increase in transposable element copy number is opposed by selection. These conclusions are compared with those from other studies, and with the conclusions from population surveys of element frequencies.     

Prolongation of MGE 412 transposition induction after gamma-irradiation in an isogenic line of Drosophila melanogaster]]

The dose dependence of the rate of gamma-induced transpositions and consequent dynamics of the MGE 412 pattern after gamma-irradiation were investigated in isogenic line 49 in generations F1, F12, F140, and F170. It was shown that the results on dose dependence of transpositions was very similar with the corresponding results of the classic works by Timofeeff-Ressovsky et al. (1935). It is suggested that the transcribed copies of retrotransposon 412 "cure" gamma-radiation-induced double-strand DNA breaks. The phenomenon of prolongation of MGE transposition induction during early generations after treatment was shown. In this period (F1-F12), the maximum transposition rate (lambda approximately equal to 2 x 10(-2) events per MGE copy, per haploid genome, per generation) and the maximum number of heterozygous MGE copies were achieved. In the late generations (F140 and F170), the reduced induction level (lambda approximately 10(-3) was established. In the population of effective size Ne = 2000 individuals, this corresponds to the state when lambda > 1/4Ne, i.e., when the transposition flow prevails over the MGE copy loss by genetic drift. These data together with some indirect evidence argue for the hypothesis that the spontaneous transposition rate is proportional to the average number of heterozygous MGE copies per diploid genome.     

Polymorphism in structure of the retrotransposable element 412 in Drosophila simulans and D. melanogaster populations.

The structure of the 412 retrotransposable element was investigated in various natural populations of D. melanogaster and D. simulans by a restriction enzyme analysis. We show that although the canonical structure of the 412 element was the same in both species, a high structural polymorphism existed with various rearranged elements. A 412 family was thus composed of heterogeneous copies of different sizes, with a large proportion of full-size copies. D. simulans had more rearranged copies than D. melanogaster, with some specific copies, such as a 5.6-kb BsrBI fragment, present in all populations of D. simulans. Full-size and rearranged copies were detected in both the euchromatin and the heterochromatin, with many rearranged copies in D. simulans, suggesting a recent mobilization of the 412 element in this species.     

Studies on the transposition rates of mobile genetic elements in a natural population of Drosophila melanogaster

In an isolated population of Drosophila melanogaster on Ishigaki Island the chromosomal distribution of several retrotransposons, including copia, 412, 297, 17.6, I, and jockey elements, was examined by in situ hybridization. In this population the cosmopolitan inversion, In(2L)t, is known to exist in high frequency. One major haplotype concerning the occupied sites of the transposable elements was identified in the In(2L)t-carrying chromosomes. This haplotype is suggested to be the ancestral one. The age of the inversion in this local population was estimated to be 1,400 generations. The transposition rates of these elements were estimated based on the age of the inversion and the number of the elements lost and gained. The excision rates were in the range from 9.13 x 10(-5) to 2.25 x 10(-4) per site per generation. They were similar each other in the copia-like elements as well as in the LINE-like elements. The rate was higher in the copia-like elements than in the LINE-like elements. Insertions occurred in the range from 6.79 x 10(-4) to 9.05 x 10(-4) per element per generation. It is herein shown that both insertions and excisions occurred at a significantly higher rate in this population than in the laboratory.      

Can transposable element copy number distribution parameters be estimated from natural populations of Drosophila melanogaster?

The copy frequency distribution of a transposable element family in a Drosophila melanogaster natural population is generally characterised by the values of the Charlesworths' model parameters α and β (Charlesworth & Charlesworth, 1983). The estimation of these parameters is made using the observed distribution of the occupied sites in a population sample. Several results have been interpreted as due either to the influence of stochastic factors or to deterministic factors (transposition, excision, selection…). The accuracy of this method was tested by estimations performed on samples from simulated populations. The results show that with the sample size usually used for natural population studies, the confidence intervals are too large to reasonably deduce either the element copy number distribution or the values of transposition and excision rate and selective coefficients.     

The fate of transposable elements in asexual populations

Sexual reproduction and recombination are important for maintaining a stable copy number of transposable elements (TEs). In sexual populations, elements can be contained by purifying selection against host carriers with higher element copy numbers; however, in the absence of sex and recombination, asexual populations could be driven to extinction by an unchecked proliferation of TEs. Here we provide a theoretical framework for analyzing TE dynamics under asexual reproduction. Analytic results show that, in an infinite asexual population, an equilibrium in copy number is achieved if no element excision is possible, but that all TEs are eliminated if there is some excision. In a finite population, computer simulations demonstrate that small populations are driven to extinction by a Muller's ratchet-like process of element accumulation, but that large populations can be cured of vertically transmitted TEs, even with excision rates well below transposition rates. These results may have important consequences for newly arisen asexual lineages and may account for the lack of deleterious retrotransposons in the putatively ancient asexual bdelloid rotifers.     

Variability of localization of retrotransposon copia ant its effect on adaptation in inbred strains of Drosophila melanogaster with the different rate of transposition

Three sublines of an inbred laboratory line of Drosophila melanogaster with the initial copia transposition rate 2 x 10(-2), 2 x 10(-3), and 5 x 10(-4) per copy per generation were reared for several dozen generations under conditions of low effective population size (by full-sib crosses or in a small mass culture of 10 females x 10 males). All six lines were tested for the transposition rate, location pattern, and copy number of copia in euchromatic genome regions and for fitness inferred from the intraspecific competition index. The copia transposition rate remained constant in both versions of the lines with an initially lower rate and decreased by an order of magnitude in both versions of the line with an initially higher rate. New copia insertions behaved as selectively neutral and were accumulated in the genome. Each new copy decreased fitness by less than 1% on average. Some of the existing unfixed insertions remained segregating after long-term inbreeding and were assumed to provide a selective advantage to heterozygotes.     

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.     

Frequency and pattern of transposition of the maize transposable element Ds in transgenic rice plants

Two kinds of T-DNA constructs, I-RS/dAc-I-RS and Hm(R)Ds, carrying a non-autonomous transposable element of Ac of maize were introduced into rice plants by Agrobacterium-mediated gene transfer. Six transgenic rice plants identified as containing a single copy of the element were crossed with two transgenic rice plants carrying a gene for Ac transposase under the control of the cauliflower mosaic virus 35S promoter. In F2 progenies, excision of the element was detected by PCR analysis and re-integration of the element was investigated by Southern blot analysis. The frequency of the excision of the element was found to vary from 0 to 70% depending on the crossing combination. The frequency of the number of individual transposition events out of the total number of F2 plants with germinal excision was 44% in one crossing combination and 38% in the other. In the most efficient case, 10 plants with independent transposition were obtained out of the 49 F2 plants tested. Linkage analysis of the empty donor site and the transposed Ds-insertion site in F3 plants demonstrated that one of five Ds-insertion sites was not linked to the empty donor site. The transgenic rice obtained in this study can be used for functional genomics of rice.     

Dynamic equilibrium between insertion and excision of P elements in highly inbred lines from an M′ strain of Drosophila melanogaster

Six highly inbred lines of Drosophila melanogaster extracted from an M strain (in the P/M system of hybrid dysgenesis) were studied for the evolution of the number and chromosomal location of complete and defective P elements through generations 52–200. These lines possessed full-sized P elements but differed in their cytotype (M or P). Three lines with P cytotype and full-sized P elements at site 1A had a constant P copy number over generations with low rates of insertion and excision. Three lines with M cytotype and at least one full-sized P element accumulated P copies over the generations and reached a plateau near generation 196, at which rates of transposition and excision were equal to 1.2 × 10^–3 to 3 × 10^–3 events per element per generation. At that time these three lines still presented an M cytotype, produced transposase, and were able to regulate P copy number. The similarity at equilibrium between insertion and excision rates was exactly what was expected from theoretical models for a self-regulated element. The large number of generations necessary to attain the equilibrium in copy number indicates, however, that caution may be de rigueur when testing theoretical models of copy-number containment based on transposition and excision-rate comparison.     

Distribution of the retrotransposable element 412 in Drosophila species

Copy numbers of sequences homologous to the Drosophila melanogaster retrotransposable element 412, their distribution between the chromosome arms and the chromocenter, and whether they contain full- size copies were analyzed for 55 species of the Drosophila genus. Element 412 insertion sites were detected on the chromosome arms of D. melanogaster, Drosophila simulans, and a few species of the obscura group, but the chromocenter was labeled in almost all species. The presence of element 412 sequences in the majority of species shows that this element has a long evolutionary history in Drosophilidae, although it may have recently invaded the chromosomes in some species, such as D. simulans. Differences in copy number between species may be due to population size or specific endogenous or environmental factors and may follow the worldwide invasion of the species. Putative full-length copies were detected in the chromocenters of some species with no copies on the chromosome arms, suggesting that the chromocenter may be a shelter for such copies and not only for deleted ones.      

Effects of gene dosage and sequence modification on the frequency and timing of transposition of the maize element Activator (Ac) in tobacco

The effect of Ac copy number on the frequency and timing of germinal transposition in tobacco was investigated using the streptomycin phosphotransferase gene (SPT) as an excision marker. The activity of one and two copies of the element was compared by selecting heterozygous and homozygous progeny of transformants carrying single SPT::Ac inserts. It was observed that increasing gene copy not only increases the transposition frequency, but also occasionally alters the timing of transposition such that earlier events are obtained. The result is that some homozygous plants generate multiple streptomycin resistant progeny carrying the same transposed Ac (trAc) element. We have also investigated the effect of modification of the sequence in the region around 82 bp downstream of the polyadenylation site and 177 bp from the 3 end of the element on germinal excision frequencies. Alteration of three bases to create a BglII site at this location caused a minor decrease in germinal excision events, but insertion of four bases to create a Cla I site caused a 10-fold decrease in the transposition activity of the Ac element.     

Rates of movement and distribution of transposable elements in Drosophila melanogaster: in situ hybridization vs Southern blotting data.

Genomic copy numbers and the rates of movement of nine families of transposable elements (TEs) of Drosophila melanogaster were estimated in two sets of mutation accumulation lines: Beltsville and Madrid. Southern blotting was used to screen a large number of samples from both genetic backgrounds for TEs. The Madrid lines were also screened by in situ hybridization of TEs to polytene chromosomes, in order to obtain more detailed information about the behaviour of TEs in the euchromatin. Southern blotting data provided evidence of insertions and excision events in both genetic backgrounds, occurring at rates of approximately 10(-5) and 10(-6) per element copy per generation, respectively. In contrast, in situ data from the Madrid background presented a completely different picture, with no evidence for excisions, and a significantly higher rate of transposition (1.01 x 10(-4)). Direct comparison of the two data sets suggests that the Southern blotting technique had serious deficiencies: (i) it underestimated element abundance; (ii) it revealed less than 30% of the new insertions detected by in situ hybridization; and (iii) changes in the size of restriction fragments from any source were spuriously identified as simultaneous insertion-excision events. Our in situ data are consistent with previous studies, and suggest that selection is the main force controlling element spread by transposition.