Vege and Mar: two novel hAT MITE families from Drosophila willistoni

Two novel families of miniature inverted repeat transposable elements (MITEs), Vege and Mar, are described from Drosophila willistoni. Based on their structures, both element families are hypothesized to belong to the hAT superfamily of transposable elements. Both elements have perfect, inverted terminal repeats and 8-bp target site duplications and were found to have inserted within fixed copies of nonautonomous P elements. Vege is present in all studied D. willistoni populations and appears to have a relatively low copy number. Mar was identified in only a single D. willistoni population, and its copy number is presently unknown. Although MITEs occupy relatively large proportions of the genomes of a broad range of organisms, this may be their first unambiguous identification in any species of the genus Drosophila.     

Transposase concentration controls transposition activity: Myth or reality?

Deciphering the mechanisms underlying the regulation of DNA transposons might be central to understanding their function and dynamics in genomes. From results obtained under artificial experimental conditions, it has been proposed that some DNA transposons self-regulate their activity via overproduction inhibition (OPI), a mechanism by which transposition activity is down-regulated when the transposase is overconcentrated in cells. However, numerous studies have given contradictory results depending on the experimental conditions. Moreover, we do not know in which cellular compartment this phenomenon takes place, or whether transposases assemble to form dense foci when they are highly expressed in cells.     

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.     

Unraveling the evolutionary scenario of the hobo element in populations of Drosophila melanogaster and D. simulans in South America using the TPE repeats as markers

Transposable elements (TEs) are nucleotide sequences found in most studied genomes. These elements are highly diversified and have a large variation in nucleotide structure and mechanisms of transposition. hobo is a member of class II, belonging to hAT superfamily, described inDrosophila melanogaster, and it presents in its Open Reading Frame, a repetitive region encoding the amino acids threonine-proline-glutamic acid (TPE), which shows variability in the number of repeats in some regions of the world. Due to this variability some evolutionary scenarios of the hobo element are discussed, such as the scenario of the invasion of hobo element in populations ofD. melanogaster. In the present study, we investigated 22 DNA sequences of D. melanogaster and seven sequences ofD. simulans, both from South America, to check the number of repetitions of TPE, in order to clarify the evolutionary scenario of thehobo element in these populations. Our results showed a monomorphism in populations of both species in South America, with only three TPE repeats. Hence, we discuss and propose an evolutionary scenario of the invasion of the hobo element in populations of D. melanogaster and D. simulans.     

A hAT-related family of interspersed repetitive elements in genomes of western Palaearctic water frogs

A family of interspersed repetitive elements, RlBamHI, with sequence similarity to the transposase of hAT DNA transposons, occurs in genomes of eight western Palaearctic water frog taxa and the brown frog Rana dalmatina , but was not detected in Xenopus laevis or Salamandra salamandra . RlBamHI elements are not tandemly arrayed, are dispersed across all chromosomes although not uniformly distributed, and based on dot-blot hybridizations may constitute as much as approximately 10% of the genomes of Rana lessonae , Rana ridibunda , and Rana perezi , but only approximately 1% of that of Rana saharica . Eleven nucleotide sequences of a 572 bp fragment from the nine taxa are very similar (pairwise differences 0.4–8.1% for nucleotides, 0.6–18.2% for amino acids), and all share a single open reading frame across the whole RlBamHI fragment. The reading frame is maintained despite several indels, most of which are multiples of 3 bp, but a pair of which in one species alters and, after 13 codons, restores the reading frame. It is possible that the reading frame is selectively maintained, suggesting recent or even present transposition capacity. The amino acid sequences encoded by RlBamHI elements, but not the nucleotide sequences themselves, reveal the similarity of RlBamHI to members of the widespread hAT superfamily of DNA transposons. Amino acid sequence comparisons permitted no convincing phylogenetic placement of RlBamHI among 32 representative hAT transposons across organisms, probably reflecting both the genetic divergence of RlBamHI elements and the paucity of aligned residues available for analysis. Among DNA transposons, a genomic fraction of 10% is extraordinarily high. Phylogenetic analyses of Rana RlBamHI sequences match poorly with independent genetic and molecular phylogenies; the elements compared probably are not orthologous, which renders their sequences inadequate for reconstructing organismal phylogenetic histories.