Inferring the history of interchromosomal gene transposition in Drosophila using n-dimensional parsimony

Gene transposition puts a new gene copy in a novel genomic environment. Moreover, genes moving between the autosomes and the X chromosome experience change in several evolutionary parameters. Previous studies of gene transposition have not utilized the phylogenetic framework that becomes possible with the availability of whole genomes from multiple species. Here we used parsimonious reconstruction on the genomic distribution of gene families to analyze interchromosomal gene transposition in Drosophila. We identified 782 genes that have moved chromosomes within the phylogeny of 10 Drosophila species, including 87 gene families with multiple independent movements on different branches of the phylogeny. Using this large catalog of transposed genes, we detected accelerated sequence evolution in duplicated genes that transposed when compared to the parental copy at the original locus. We also observed a more refined picture of the biased movement of genes from the X chromosome to the autosomes. The bias of X-to-autosome movement was significantly stronger for RNA-based movements than for DNA-based movements, and among DNA-based movements there was an excess of genes moving onto the X chromosome as well. Genes involved in female-specific functions moved onto the X chromosome while genes with male-specific functions moved off the X. There was a significant overrepresentation of proteins involving chromosomal function among transposed genes, suggesting that genetic conflict between sexes and among chromosomes may be a driving force behind gene transposition in Drosophila.     

Duplicative and conservative transpositions of larval serum protein 1 genes in the genus Drosophila

Interspecific comparative molecular analyses of transposed genes and their flanking regions can help to elucidate the time, direction, and mechanism of gene transposition. In the Drosophila melanogaster genome, three Larval serum protein 1 (Lsp1) genes (alpha, beta and gamma) are present and each of them is located on a different chromosome, suggesting multiple transposition events. We have characterized the molecular organization of Lsp1 genes in D. buzzatii, a species of the Drosophila subgenus and in D. pseudoobscura, a species of the Sophophora subgenus. Our results show that only two Lsp1 genes (beta and gamma) exist in these two species. The same chromosomal localization and genomic organization, different from that of D. melanogaster, is found in both species for the Lsp1beta and Lsp1gamma genes. Overall, at least two duplicative and two conservative transpositions are necessary to explain the present chromosomal distribution of Lsp1 genes in the three Drosophila species. Clear evidence for implication of snRNA genes in the transposition of Lsp1beta in Drosophila has been found. We suggest that an ectopic exchange between highly similar snRNA sequences was responsible for the transposition of this gene. We have also identified the putative cis-acting regulatory regions of these genes, which seemingly transposed along with the coding sequences.     

Molecular evolution of Drosophila odorant receptor genes

A total of 752 odorant receptor (Or) genes, including pseudogenes, were identified in 11 Drosophila species and named after their orthologs in Drosophila melanogaster. The 813 Or genes, including 61 from D. melanogaster, were classified into 59 orthologous groups that are well supported by gene phylogeny. By reconciling with the gene family phylogeny, we estimated the number of gene duplication/loss events and intron gain/loss events in the species phylogeny. We found that these events are particularly frequent in Drosophila grimshawi, Drosophila willistoni, and obscura group. More than half of the duplicated genes stay as tandem arrays, whose size range from 2 to 8. These genes vary in sequence and some likely underwent positive selection, indicating that the gene duplication was important for flies to acquire new olfactory functions. We hypothesize that Or genes conferred the basic olfactory repertoire to ancestral flies before the speciation of the Drosophila and Sophophora subgenera about 40 Mya. This repertoire has been largely maintained in the current species, whereas lineage-specific gene duplication seems to have led to additional specialization in some species in response to specific ecological conditions.     

Evolution in the fast lane: rapidly evolving sex-related genes in Drosophila

A large portion of the annotated genes in Drosophila melanogaster show sex-biased expression, indicating that sex and reproduction-related genes (SRR genes) represent an appreciable component of the genome. Previous studies, in which subsets of genes were compared among few Drosophila species, have found that SRR genes exhibit unusual evolutionary patterns. Here, we have used the newly released genome sequences from 12 Drosophila species, coupled to a larger set of SRR genes, to comprehensively test the generality of these patterns. Among 2505 SRR genes examined, including ESTs with biased expression in reproductive tissues and genes characterized as involved in gametogenesis, we find that a relatively high proportion of SRR genes have experienced accelerated divergence throughout the genus Drosophila. Several testis-specific genes, male seminal fluid proteins (SFPs), and spermatogenesis genes show lineage-specific bursts of accelerated evolution and positive selection. SFP genes also show evidence of lineage-specific gene loss and/or gain. These results bring us closer to understanding the details of the evolutionary dynamics of SRR genes with respect to species divergence.     

Transposition of a chromosomal segment bounded by redundant rRNA genes into other rRNA genes in Escherichia coli.

We have constructed several mutants of Escherichia coli which have the chromosomal segment between the directly repeated rrnB and rrnE genes deleted from the normal position and transposed into another one of the seven redundant rRNA genes. We have examples where the transposition has been into rrnC, rrnD, rrnG, and rrnH. Included in the evidence for each of these transpositions was the finding that each transposition specifically affected a different one of the seven BamHI-PstI restriction nuclease fragments known to correspond to the seven rrn genes. The transposition mutants were generally healthy, but sensitive mixed-growth experiments revealed that most of them grew somewhat more slowly than the parental control in rich medium. The maximal detrimental effect was a 4 to 5% reduction in growth rate when the transposition of the rrnB-rrnE segment was into rrnG. We have found that a rrnF gene, reported by others to be linked to malA, does not exist in our standard strain, a derivative of Cavalli Hfr. Instead of rrnF, we identified a new rrn gene, rrnH, which mapped near min 5.     

Ac as a tool for the functional genomics of rice

To examine whether the maize autonomous transposable element Ac can be used for the functional analysis of the rice genome, we used Southern blot analysis to analyze the behaviour of Ac in 559 rice plants of four transgenic families through three successive generations. All families showed highly active transposition of Ac, and 103 plants (18.4%) contained newly transposed Ac insertions. In nine of the 12 independent transpositions analyzed, their germinal transmission was detected. Partial sequencing of 99 Ac-flanking sequences revealed that 21 clones exhibited significant similarities with protein-coding genes in databases and four of them matched rice cDNA sequences. These results indicate preferential Ac transposition into protein-coding rice genes. To examine the feasibility of PCR-based screening of gene knockouts in rice Ac plants, we prepared bulked genomic DNA from the leaves of approximately 6000 rice Ac plants and pooled the DNA according to a three-dimensional matrix. Of 14 randomly selected genes, two gene knockouts were identified, and one encoding a rice cytochrome P450 (CYP86) gene was shown to be stably inherited to the progeny. Together, these results suggest that Ac can be efficiently used for the functional analysis of the rice genome.     

Transposition of a plasmid deoxyribonucleic acid sequence that mediates ampicillin resistance: identity of laboratory-constructed plasmids and clinical isolates.

The structural gene for ampicillin resistance resides upon a 3.2 X 10(6)-dalton sequence of deoxyribonucleic acid, TnA that can be transposed from replicon to replicon in laboratory experiments. TnA was transposed from a large conjugative plasmid to a small nonconjugative plasmid, RSF1010. Several RSF1010::TnA plasmids isolated in these laboratory experiments have been shown to be identical to plasmids found in clinical isolates. These data provide direct support to the theory that transposition of drug resistance genes play a key role in the evolution of R plasmids.     

A cloned I-factor is fully functional in Drosophila melanogaster

Summary I-R hybrid dysgenesis in Drosophila melanogaster occurs in female progeny of crosses between reactive strain females and inducer strain males, and is controlled by transposable elements called I-factors. These are 5.3 kb elements that are structurally similar to mammalian LINE elements and other retroposons. We have tested the activity of an I-factor directly, by introducing it into the genome of a reactive strain, using P-element mediated transformation. It confers the complete inducer phenotype on the reactive strain, and can stimulate dysgenesis when transformed males are mated with reactive females. It has transposed in the transformed lines, and we have cloned one of the transposed copies. This is the first time that it has been possible to demonstrate that a particular retroposon is transposition proficient, and to compare donor and transposed elements. We propose a mechanism for I-factor transposition based on these results, and the coding capacity of these elements. We have been unable to detect either autonomous transposition of a complete I-factor from a plasmid injected into reactive strain embryos, or transposition of a marked I-factor when co-injected with a complete element.     

Genomic signatures of local adaptation in the Drosophila immune response

As environments and pathogen landscapes shift, host defenses must evolve to remain effective. Due to this selection pressure, among-species comparisons of genetic sequence data often find immune genes to be among the fastest evolving genes across the genome. The full extent and nature of these immune adaptations, however, remain largely unexplored. In a recent study, we analyzed patterns of selection within distinct components of the Drosophila melanogaster immune pathway. While we found evidence of positive selection within some immune processes, immune genes were not universally characterized by signatures of strong selection. On the contrary, we even found that some immune functions show greater than expected constraint. Overall these results highlight 2 major factors that appear to play an outsize role in determining a gene's evolutionary rate: the type of pathogen the gene targets and the gene's position within the immune network. These results join a growing body of literature that highlight the complexity of immune adaptation. Rather than there being uniformly strong selection across all immune genes, a combination of pathogen-specificity and host genetic constraints appear to play key roles in determining each immune gene's individual evolutionary trajectory.     

Evolutionary profiling of the U49 snoRNA gene

Small nucleolar RNAs (snoRNAs) are involved in precursor ribosomal RNA (pre-rRNA) processing and rRNA base modifications (2'-O-ribose methylation and pseudouridylation). Their genomic organization show great flexibility: some are individually or polycistronically transcribed, while others are encoded within introns of other genes. Here, we present an evolutionary analysis of the U49 gene in seven species. In all species analyzed, U49 contains the typical hallmarks of C and D box motifs, and a conserved 12-15 nt sequence complementary to rRNA that define them as homologs. In mouse, human, and Drosophila U49 is found encoded within introns of different genes, and in plants it is transcribed polycistronically from four different locations. In addition, U49 has two copies in two different introns of the RpL14 gene in Drosophila. The results indicate a substantial degree of duplication and translocation of the U49 gene in evolution. In light of its variable organization we discuss which of the two proposed mechanisms of rearrangement has acted upon the U49 snoRNA gene: chromosomal duplication or transposition through an RNA intermediate.     

The molecular analyses of an antimorphic mutation of Drosophila melanogaster, Scutoid

A dominant mutation of Drosophila melanogaster, Scutoid (Sco), acts as an antimorphic allele of the no-ocelli (noc) gene. In Sco the noc region has been transposed from 35B to 35D on chromosome arm 2L and the noc gene is now adjacent to snail (sna). Induced revertants of Sco are frequently mutant for sna or are aberrations broken very close to sna. A molecular analysis of the Sco chromosome has confirmed that noc is transposed and fused to the sna region. However, only part of the noc region is included within the transposition. The breakpoints of 19 chromosomally aberrant Sco revertants have been mapped at the molecular level. Fourteen of these breakpoints map to the noc region, spread over about 80 kb of DNA. The breakpoints of the remaining five are not within the DNA of the noc region and appear to map within sequences from the sna region. This has been shown directly for three of these, those associated with T(2;3)ScoR+13, In(2L)ScoR+24 and In(2L)ScoR+26. Thus mutation of either noc or sna, genes which are apparently unrelated in their wild-type functions, can revert the antimorphic phenotype of Sco.     

Evidence of adaptive evolution of accessory gland proteins in closely related species of the Drosophila repleta group

Accessory gland proteins (Acps) are part of the seminal fluid of Drosophila species. These proteins have important reproductive functions, being responsible for the proper functioning of several steps of the fertilization process. Acps also contribute indirectly for the reproductive success of males by modulating female behavior. Evidence that Acps participate in sperm competition and sexual conflict includes findings that, on average, Acps have fast evolutionary rates, suggestive of adaptive evolution. This is especially true in species of the Drosophila repleta group. Nevertheless, only in a few occasions have robust statistical tests been used to determine whether observed evolutionary rates are in fact due to positive selection on amino acid substitutions between related species. Here we apply maximum likelihood tests for positive selection on 14 Acps of the D. repleta group. To increase statistical robustness, we use at least 8 sequences, all belonging to species of the Drosophila mulleri complex, for each gene analyzed. We found significant evidence of adaptive evolution for 10 of the tested genes. Among these, the ones with a conserved protein domain had positively selected sites within the functional region of the sequence. We also detected one instance of lineage-specific adaptive evolution in a clade formed by 2 sister species.