Accumulation of Transposable Elements in the Heterochromatin and on the Y Chromosome of Drosophila simulans and Drosophila melanogaster

The elements of the transposon families G, copia, mdg 1, 412, and gypsy that are located in the heterochromatin and on the Y chromosome have been identified by the Southern blotting technique in Drosophila simulans and D. melanogaster populations. Within species, the abundance of such elements differs between transposon families. Between species, the abundance in the heterochromatin and on the Y chromosome of the elements of the same family can differ greatly suggesting that differences within a species are unrelated to structural features of elements. By shedding some new light on the mechanism of accumulation of transposable elements in the heterochromatin, these data appear relevant to the understanding of the long-term interaction between transposable elements and the host genome. Received: 8 August 1997 / Accepted: 11 December 1997     

Intragenomic distribution and stability of transposable elements in euchromatin and heterochromatin of drosophila melanogaster: non-LTR retrotransposon

The intragenomic location of the elements of the I, G, jockey, F, and Doc transposon families has been studied by the Southern blot analysis, in 12 laboratory Drosophila melanogaster stocks. Elements located in euchromatin, heterochromatin, and on the Y chromosome are identified, and their stability has been assessed by comparing the autoradiographs detected in different stocks and analysis of individual flies. Evidence is shown suggesting that preferential location in euchromatin or heterochromatin and the distribution within heterochromatin are distinctive of transposon families. Elements located in heterochromatin can be unstable. These results are discussed in the context of the relationship between transposable elements and the host genome. Received: 21 August 1996 / Accepted: 24 March 1997     

Phylogenetic Analysis of Mos1-Like Transposable Elements in the Drosophilidae

We have performed a phylogenetic analysis of 59 mariner elements in 14 Drosophilidae species that are related to the active Drosophila mauritiana Mos1 element. This includes 38 previously described sequences and 21 new sequences amplified by PCR from 10 species. Most of the elements detected are nonfunctional due to several frameshifts and deletions. They have been subdivided into four groups according to specific signatures in the nucleotidic and amino acid sequences. The mean nucleotide diversity is 4.8 ± 0.1% and reflects mainly the divergence of inactive elements over different periods. Although this probably gives rise to occasional homoplasies between distantly related taxa, the elements of each species remain grouped together. Horizontal transfer, reported previously between D. mauritiana and Zaprionus tuberculatus, can be extended to Z. verruca, while the Mos1-like element of Z. indianus belongs to another group. Interpretation of the phylogeny leads to a comparison of the influence of common ancestral sequences and putative horizontal transfers. Received: 31 May 1999 / Accepted: 28 June 1999     

Molecular Evolution of P Transposable Elements in the Genus Drosophila. II. The obscura Species Group

A phylogenetic analysis of P transposable elements in the Drosophila obscura species group is described. Multiple P sequences from each of 10 species were obtained using PCR primers that flank a conserved region of exon 2 of the transposase gene. In general, the P element phylogeny is congruent with the species phylogeny, indicating that the dominant mode of transmission has been vertical, from generation to generation. One manifestation of this is the distinction of P elements from the Old World obscura and subobscura subgroups from those of the New World affinis subgroup. However, the overall distribution of elements within the obscura species group is not congruent with the phylogenetic relationships of the species themselves. There are at least four distinct subfamilies of P elements, which differ in sequence from each other by as much as 34%, and some individual species carry sequences belonging to different subfamilies. P sequences from D. bifasciata are particularly interesting. These sequences belong to two subfamilies and both are distinct from all other P elements identified in this survey. Several mechanisms are postulated to be involved in determining phylogenetic relationships among P elements in the obscura group. In addition to vertical transmission, these include retention of ancestral polymorphisms and horizontal transfer by an unknown mating-independent mechanism.     

Codon Usage by Transposable Elements and Their Host Genes in Five Species

We compared the codon usage of sequences of transposable elements (TEs) with that of host genes from the species Drosophila melanogaster, Arabidopsis thaliana, Caenorhabditis elegans, Saccharomyces cerevisiae, and Homo sapiens. Factorial correspondence analysis showed that, regardless of the base composition of the genome, the TEs differed from the genes of their host species by their AT-richness. In all species, the percentage of A + T on the third codon position of the TEs was higher than that on the first codon position and lower than that in the noncoding DNA of the genomes. This indicates that the codon choice is not simply the outcome of mutational bias but is also subject to selection constraints. A tendency toward higher A + T on the third position than on the first position was also found in the host genes of A. thaliana, C. elegans, and S. cerevisiae but not in those of D. melanogaster and H. sapiens. This strongly suggests that the AT choice is a host-independent characteristic common to all TEs. The codon usage of TEs generally appeared to be different from the mean of the host genes. In the AT-rich genomes of Arabidopsis thaliana, Caenorhabditis elegans, and Saccharomyces cerevisiae, the codon usage bias of TEs was similar to that of weakly expressed genes. In the GC-rich genome of D. melanogaster, however, the bias in codon usage of the TEs clearly differed from that of weakly expressed genes. These findings suggest that selection acts on TEs and that TEs may display specific behavior within the host genomes. Received: 2 May 2001 / Accepted: 29 October 2001     

Tirant: A New Retrotransposon-Like Element in Drosophila melanogaster

In this paper we report a new retrotransposon-like element of Drosophila melanogaster called Tirant. This sequence is moderately repeated in the genome of this species and it has been found to be widely dispersed throughout its distribution area. From Southern blot and in situ analyses, this sequence appears to be mobile in D. melanogaster, since its chromosome location and the hybridization patterns vary among the different strains analyzed. In this way, partial sequencing of Tirant ends suggests that it is a retrotransposon, since it is flanked by two LTRs. The presence of sequences homologous to Tirant has been also investigated in 28 species of the genus Drosophila by means of Southern analyses. These sequences were only detected in species from melanogaster and obscura groups. These data suggest that ancestral sequences of Tirant appeared after the Sophophora radiation and before the divergence of those groups. Received: 1 January 1995 / Accepted: 20 August 1995     

Amplification and Phylogenetic Relationships of a Subfamily of blood, a Retrotransposable Element of Drosophila

To get a better understanding of the effect of interelement selection on the variation of long terminal repeat retrotransposon families, we have investigated the evolutionary history of blood in the Drosophila melanogaster species complex. We carried out a PCR approach to amplify the 5′ untranslated region from blood in the four species of the complex. This procedure revealed two main classes of size variants. Phylogenetic analyses of nucleotide sequences from these variants and blood elements from the Drosophila Genome Projects database show that elements are grouped according to their size, so that they probably correspond to two subfamilies. These two subfamilies arose prior to the split of the complex, and several facts indicate that the expansion of one of them is leading to the competitive exclusion of the other, at least from the euchromatic regions of the genome. Received: 17 August 2000 / Accepted: 20 November 2000     

Absence of Protein Polymorphism in the Ras Genes of Drosophila melanogaster

Sequence analysis of 27 alleles of each of the three Ras-related genes in Drosophila melanogaster indicates that they all have low levels of polymorphism but may experience slightly different evolutionary pressures. No amino acid replacement substitutions were indicated in any of the sequences, or in the sibling species D. simulans and D. mauritiana. The Dras1 gene, which is the major ras homologue in Drosophila, has less within-species variation in D. melanogaster relative to the amount of divergence from the sibling species than does Dras2, although the contrast was not significant by the HKA test. Dras2 appears to be maintaining two classes of haplotype in D. melanogaster, one of which is closer to the alleles observed in the sibling species, suggesting that this is not likely to be a pseudogene despite the absence of a mutant phenotype. Although differences in level of expression may affect the function of the genes, it is concluded that genetic variation in the Ras signal transduction pathways cannot be attributed to catalytic variation in the Ras proteins. Received: 5 November 1998 / Accepted: 26 March 1999     

Potentially active copies of the gypsy retroelement are confined to the y chromosome of some strains of drosophila melanogaster possibly as the result of the female-specific effect of the flamenco gene

Gypsy is an endogenous retrovirus present in the genome of Drosophila melanogaster. This element is mobilized only in the progeny of females which contain active gypsy elements and which are homozygous for permissive alleles of a host gene called flamenco (flam). Some data strongly suggest that gypsy elements bearing a diagnostic HindIII site in the central region of the retrovirus body represent a subfamily that appears to be much more active than elements devoid of this site. We have taken advantage of this structural difference to assess by the Southern blotting technique the genomic distribution of active gypsy elements. In some of the laboratory Drosophila stocks tested, active gypsy elements were found to be restricted to the Y chromosome. Further analyses of 14 strains tested for the permissive vs. restrictive status of their flamenco alleles suggest that the presence of permissive alleles of flam in a stock tends to be associated with the confinement of active gypsy elements to the Y chromosome. This might be the result of the female-specific effect of flamenco on gypsy activity. Received: 13 June 1997 / Accepted: 27 August 1997     

The Behavior of a Daphnia pulex Transposable Element in Cyclically and Obligately Parthenogenetic Populations

Using Southern blot analysis, we have characterized restriction fragment patterns of a transposable element, Pokey, in obligately and cyclically parthenogenetic populations of the cladoceran crustacean Daphnia pulex. We show that the element is most likely active in cyclically parthenogenetic populations but is, for the most part, inactive in obligate parthenogens. This result is consistent with theory suggesting that transposable element dynamics are likely to change with a change in reproductive mode. Such changes could have important consequences for the long-term evolutionary potential of obligate parthenogens and may also be informative with regard to the underlying mechanisms that regulate transposable element frequencies in sexual organisms. Received: 29 August 2000 / Accepted: 1 March 2001     

Transposable elements and the penetrance of quantitative characters in Drosophila melanogaster

We wanted to determine whether there is a correlation between the quantitative character, the penetrance of the loss of humeral bristles in scute lines, and the distribution of transposable genetic elements in their genomes. We derived 18 isogenic lines with penetrance ranging between 2.8% and 92.0% from six mutant lines. The localization of the transposable elements (TEs) P, mdg1, Dm412, copia, gypsy and B104 was determined in all isogenic derivatives by in situ hybridization. The total number of the TE sites over all lines was 180. A comparison of the distribution of the TEs in the isogenic lines revealed the location of sites typical of lines with similar penetrance, no matter which parental line was involved. The results obtained suggest that such typical sites appear to tag the genome regions where the polygenes affecting the character in question are most likely to be found.     

Histone H1 Genes and Histone Gene Clusters in the Genus Drosophila

Whereas the genomes of many organisms contain several nonallelic types of linker histone genes, one single histone H1 type is known in Drosophila melanogaster that occurs in about 100 copies per genome. Amplification of H1 gene sequences from genomic DNA of wild type strains of D. melanogaster from Oregon, Australia, and central Africa yielded numerous clones that all exhibited restriction patterns identical to each other and to those of the known H1 gene sequence. Nucleotide sequences encoding the evolutionarily variable domains of H1 were determined in two gene copies of strain Niamey from central Africa and were found to be identical to the known H1 sequence. Most likely therefore, the translated sequences of D. melanogaster H1 genes do not exhibit intragenomic or intergenomic variations. In contrast, three different histone H1 genes were isolated from D. virilis and found to encode proteins that differ remarkably from each other and from the H1 of D. melanogaster and D. hydei. About 40 copies of H1 genes are organized in the D. virilis genome with copies of core histone genes in gene quintets that were found to be located in band 25F of chromosome 2. Another type of histone gene cluster is present in about 15 copies per genome and contains a variable intergenic sequence instead of an H1 gene. The H1 heterogeneity in D. virilis may have arisen from higher recombination rates than occur near the H1 locus in D. melanogaster and might provide a basis for formation of different chromatin subtypes. Received: 2 March 2000 / Accepted: 1 June 2000     

Codon Usage Bias and tRNA Abundance in Drosophila

Codon usage bias of 1,117 Drosophila melanogaster genes, as well as fewer D. pseudoobscura and D. virilis genes, was examined from the perspective of relative abundance of isoaccepting tRNAs and their changes during development. We found that each amino acid contributes about equally and highly significantly to overall codon usage bias, with the exception of Asp which had very low contribution to overall bias. Asp was also the only amino acid that did not show a clear preference for one of its synonymous codons. Synonymous codon usage in Drosophila was consistent with ``optimal' codons deduced from the isoaccepting tRNA availability. Interestingly, amino acids whose major isoaccepting tRNAs change during development did not show as strong bias as those with developmentally unchanged tRNA pools. Asp is the only amino acid for which the major isoaccepting tRNAs change between larval and adult stages. We conclude that synonymous codon usage in Drosophila is well explained by tRNA availability and is probably influenced by developmental changes in relative abundance. Received: 5 December 1996 / Accepted: 14 June 1997     

Mutational mechanisms,phylogeny, and evolution of a repetitive region within a clock gene ofDrosophila melanogaster

The D. melanogaster clock gene period (per) is an internally repetitive gene encoding a tandem array of Thr-Gly codons that are highly polymorphic in length in European natural populations. The two major length variants, (Thr-Gly)₂₀ and (Thr-Gly)₁₇, show a highly significant latitudinal cline. In this study we present the complete sequence of the Thr-Gly region of 91 individuals from 6 natural populations of D. melanogaster, 5 from Europe and 1 from North Africa. We further characterized these 91 individuals for polymorphic sites in two other regions, one upstream and one downstream of the Thr-Gly repeat. We used the haplotypic combinations of Thr-Gly allele with flanking markers in an attempt to identify the mechanisms involved in the evolution of the D. melanogaster Thr-Gly region and to infer the phylogenetic relationship existing among the Thr-Gly alleles. We observe evidence for both intra- and interallelic mutational mechanisms, including replication slippage, unequal crossing-over, and gene conversion. Received: 22 August 1995 / Accepted: 17 October 1995     

Analysis of Orthologous Retrovirus-Like Elements in the White-Footed Mouse,Peromyscus leucopus

Three loci in the genome of the white-footed mouse, Peromyscus leucopus, were examined for the presence or absence of orthologous copies of the retrovirus-like element mys using polymerase chain reaction. We examined these loci in 28 mice collected throughout the P. leucopus species range. Mys insertions were present in only one of the individuals examined at the mys-1 and mys-7 loci. Conversely, the mys-6 element was found in several individuals, but the presence of this element was limited to northern latitudes. Because the long terminal repeats (LTRs) of a given element are expected to be identical at the time of retrotransposition into the genome, and to accumulate changes over evolutionary time, within-element LTR sequence comparisons can be used to estimate the relative age of insertions. Within-element LTR differences are greater in mys-6 than in mys-1 or mys-7. The LTRs from orthologous mys-6 elements of six mice were sequenced. The alignment revealed 13 of the 22 differences between the right and left LTRs that were shared by all orthologous mys-6 sites, suggesting that relative to its time of insertion into the genome, mys-6 has only recently spread across the northern part of the species range. Received: 23 January 1996 / Accepted: 24 April 1996     

The Comparative Genomics of Polyglutamine Repeats: Extreme Difference in the Codon Organization of Repeat-Encoding Regions Between Mammals and Drosophila

Polyglutamine repeats within proteins are common in eukaryotes and are associated with neurological diseases in humans. Many are encoded by tandem repeats of the codon CAG that are likely to mutate primarily by replication slippage. However, a recent study in the yeast Saccharomyces cerevisiae has indicated that many others are encoded by mixtures of CAG and CAA which are less likely to undergo slippage. Here we attempt to estimate the proportions of polyglutamine repeats encoded by slippage-prone structures in species currently the subject of genome sequencing projects. We find a general excess over random expectation of polyglutamine repeats encoded by tandem repeats of codons. We nevertheless find many repeats encoded by nontandem codon structures. Mammals and Drosophila display extreme opposite patterns. Drosophila contains many proteins with polyglutamine tracts but these are generally encoded by interrupted structures. These structures may have been selected to be resistant to slippage. In contrast, mammals (humans and mice) have a high proportion of proteins in which repeats are encoded by tandem codon structures. In humans, these include most of the triplet expansion disease genes. Received: 17 August 2000 / Accepted: 20 November 2000     

Selection and Methionine Accumulation in the Fat Body Protein 2 Gene (FBP2), a Duplicate of the Drosophila Alcohol Dehydrogenase (ADH) Gene

The Drosophila fat body protein 2 gene (Fbp2) is an ancient duplication of the alcohol dehydrogenase gene (Adh) which encodes a protein that differs substantially from ADH in its methionine content. In D. melanogaster, there is one methionine in ADH, while there are 51 (20% of all amino acids) in FBP2. Methionine is involved in 46% of amino acid replacements when Fbp2 DNA sequences are compared between D. melanogaster and D. pseudoobscura. Methionine accumulation does not affect conserved residues of the ADH-ADH^r-FBP2 multigene family. The multigene family has evolved by replacement of mildly hydrophobic amino acids by methionine with no apparent reversion. Its short-term evolution was compared between two Drosophila species, while its long-term evolution was compared between two genera belonging respectively to acalyptrate and calyptrate Diptera, Drosophila and Sarcophaga. The pattern of nucleotide substitution was consistent with an independent accumulation of methionines at the Fbp2 locus in each lineage. Under a steady-state model, the rate of methionine accumulation was constant in the lineage leading to Drosophila, and was twice as fast as that in the calyptrate lineage. Substitution rates were consistent with a slight positive selective advantage for each methionine change in about one-half of amino acid sites in Drosophila. This shows that selection can potentially account for a large proportion of amino acid replacements in the molecular evolution of proteins. Received: 12 December 1994 / Accepted: 15 April 1996     

Characterization of a Novel Class of Interspersed LTR Elements in Primate Genomes: Structure, Genomic Distribution, and Evolution

Retrovirus-like sequences and their solitary (solo) long terminal repeats (LTRs) are common repetitive elements in eukaryotic genomes. We reported previously that the tandemly arrayed genes encoding U2 snRNA (the RNU2 locus) in humans and apes contain a solo LTR (U2-LTR) which was presumably generated by homologous recombination between the two LTRs of an ancestral provirus that is retained in the orthologous baboon RNU2 locus. We have now sequenced the orthologous U2-LTRs in human, chimpanzee, gorilla, orangutan, and baboon and examined numerous homologs of the U2-LTR that are dispersed throughout the human genome. Although these U2-LTR homologs have been collectively referred to as LTR13 in the literature, they do not display sequence similarity to any known retroviral LTRs; however, the structure of LTR13 closely resembles that of other retroviral LTRs with a putative promoter, polyadenylation signal, and a tandemly repeated 53-bp enhancer-like element. Genomic blotting indicates that LTR13 is primate-specific; based on sequence analysis, we estimate there are about 2,500 LTR13 elements in the human genome. Comparison of the primate U2-LTR sequences suggests that the homologous recombination event that gave rise to the solo U2-LTR occurred soon after insertion of the ancestral provirus into the ancestral U2 tandem array. Phylogenetic analysis of the LTR13 family confirms that it is diverse, but the orthologous U2-LTRs form a coherent group in which chimpanzee is closest to the humans; orangutan is a clear outgroup of human, chimpanzee, and gorilla; and baboon is a distant relative of human, chimpanzee, gorilla, and orangutan. We compare the LTR13 family with other known LTRs and consider whether these LTRs might play a role in concerted evolution of the primate RNU2 locus. Received: 29 September 1997 / Accepted: 16 January 1998