DNA sequence comparison of micropia transposable elements from Drosophila hydei and Drosophila melanogaster

Evolutionary history and classification of Micropia retroelements in Drosophilidae species

Transposable elements (TEs) have the main role in shaping the evolution of genomes and host species, contributing to the creation of new genes and promoting rearrangements frequently associated with new regulatory networks. Support for these hypotheses frequently results from studies with model species, and Drosophila provides a great model organism to the study of TEs. Micropia belongs to the Ty3/Gypsy group of long terminal repeats (LTR) retroelements and comprises one of the least studied Drosophila transposable elements. In this study, we assessed the evolutionary history of Micropia within Drosophilidae, while trying to assist in the classification of this TE. At first, we performed searches of Micropia presence in the genome of natural populations from several species. Then, based on searches within online genomic databases, we retrieved Micropia-like sequences from the genomes of distinct Drosophilidae species. We expanded the knowledge of Micropia distribution within Drosophila species. The Micropia retroelements we detected consist of an array of divergent sequences, which we subdivided into 20 subfamilies. Even so, a patchy distribution of Micropia sequences within the Drosophilidae phylogeny could be identified, with incongruences between the species phylogeny and the Micropia phylogeny. Comparing the pairwise synonymous distance (dS) values between Micropia and three host nuclear sequences, we found several cases of unexpectedly high levels of similarity between Micropia sequences in divergent species. All these findings provide a hypothesis to the evolution of Micropia within Drosophilidae, which include several events of vertical and horizontal transposon transmission, associated with ancestral polymorphisms and recurrent Micropia sequences diversification.

The LTR retrotransposon micropia in the cardini group of Drosophila (Diptera: Drosophilidae): a possible case of horizontal transfer

The presence of the micropia retroelement from the Ty1-copia family of LTR retroelements was investigated in three species of the Drosophila cardini group. Southern blot analysis suggested the existence of at least four micropia copies in the genomes of D. cardinoides, D. neocardini and D. polymorpha populations. The high sequence similarity between dhMiF2 and Dm11 clones (micropia retroelements isolated from D. hydei and D. melanogaster, respectively) with micropia sequences amplified from D. cardini group genome supports the hypothesis that this retroelement plays an active role in horizontal transfer events between D. hydei and the D. cardini group.

Integrase diversity and transcription of the maize retrotransposon Grande

Grande is an abundant gypsy-like retrotransposon present in the genera Zea and Tripsacum. Related retro transposon families can be found in sorghum, rice, and barley, but not in wheat or rye. We have amplified and sequenced several copies of part of the integrase domain derived from the Zea mays, Zea diploperennis, and Tripsacum dactyloides genomes. There are no significant differences in divergence or clustering between the integrase sequences of these species. The substitution rate for synonimous sites was found to be higher than those of non-synomymous sites; this indicates that Grande integrase has been under purifying selection for function. Grande is transcribed in leaves. The transcripts show sequence diversity similar to that of genomic sequences, but belong to restricted clades; this indicates that only some evolutionary branches of Grande have retained transcriptional competence.

Variability, Recombination, and Mosaic Evolution of the Barley BARE-1 Retrotransposon

BARE-1 is a highly abundant, copia-like, LTR (long terminal repeat) retrotransposon in the genus Hordeum. The LTRs provide the promoter, terminator, and polyadenylation signals necessary for the replicational life cycle of retrotransposons. We have examined the variability and evolution of BARE-1-like elements, focusing on the LTRs. Three groups were found, corresponding to each of the Hordeum genome types analyzed, which predate the divergence of these types. The most variable LTR regions are tandem repeats near the 3' end and the promoter. In barley (H. vulgare L.), two main classes of LTR promoters were defined, corresponding to BARE-1 and to a new class we call BARE-2. These can be considered as families within the group I BARE elements. Although less abundant in cultivated barley than is BARE-1, BARE-2 is transcriptionally active in leaves and calli. A sequenced BARE-2 has more than 99% similar LTRs and perfect terminal direct repeats (TDRs), indicating it is a recent insertion, but the coding region, especially gag, is disrupted by frameshifts and stop codons. BARE-2 appears to be a chimeric element resulting from retrotransposon recombination by strand switching during replication, with LTRs and 5'UTR more similar to BARE-1 and the rest more similar to Wis-2. We provide evidence as well for another form of recombination, where LTR-LTR recombination has generated tandem multimeric BARE-1 elements in which internal coding domains are interspersed with shared LTRs. The data indicate that recombination contributes to the complexity and plasticity of retroelement evolution in plant genomes.

Retroviral diversity and distribution in vertebrates

We used the PCR to screen for the presence of endogenous retroviruses within the genomes of 18 vertebrate orders across eight classes, concentrating on reptilian, amphibian, and piscine hosts. Thirty novel retroviral sequences were isolated and characterized by sequencing approximately 1 kb of their encoded protease and reverse transcriptase genes. Isolation of novel viruses from so many disparate hosts suggests that retroviruses are likely to be ubiquitous within all but the most basal vertebrate classes and, furthermore, gives a good indication of the overall retroviral diversity within vertebrates. Phylogenetic analysis demonstrated that viruses clustering with (but not necessarily closely related to) the spumaviruses and murine leukemia viruses are widespread and abundant in vertebrate genomes. In contrast, we were unable to identify any viruses from hosts outside of mammals and birds which grouped with the other five currently recognized retroviral genera: the lentiviruses, human T-cell leukemia-related viruses, avian leukemia virus-related retroviruses, type D retroviruses, and mammalian type B retroviruses. There was also some indication that viruses isolated from individual vertebrate classes tended to cluster together in phylogenetic reconstructions. This implies that the horizontal transmission of at least some retroviruses, between some vertebrate classes, occurs relatively infrequently. It is likely that many of the retroviral sequences described here are distinct enough from those of previously characterized viruses to represent novel retroviral genera.

Evolutionary conservation and molecular characteristics of repetitive sequences of Drosophila koepferae

Thirteen middle repetitive DNA clones obtained from the genome of Drosophila koepferae have been tested for their evolutionary conservation in the other seven species of the buzzatii and martensis clusters (repleta group). All but two of these clones exhibit qualitatively similar patterns of hybridization in the eight species. The average interspecific hybridization signal is 85 per cent of that found intraspecifically, ranging from 73 to 93 per cent. Partial sequencing of six of these clones has shown sequences related to the retrotransposon Gypsy, first characterized in D. melanogaster, as well as to the Anopheles gambiae LINE elements T1Ag and Q. A fragment of a hitherto unknown, short inverted repeat transposable element has also been found. The evolutionary conservation of repetitive D. koepferae sequences seems to be related to the high proportion of simple DNA and inactive mobile elements in the genome of this species.

Strukturdifferenzierungen in Y-chromosom von Drosophila hydei: the unique morphology of the Y chromosomal lampbrush loops Threads results from 'coaxial shells' formed by different satellite-specific subregions within megabase-sized transcripts

The results of pulsed-field gel electrophoresis (PFGE) analysis and two-colour transcript fluorescence in situ hybridization (FISH) for the three Threads-specific DNA satellites YLII, YLI and rally are in support of long-range clustering of these sequence families within the subterminal region on the long arm of the Y chromosome of Drosophila hydei. On the basis of the linear arrangement of at least four extended clusters of satellite-specific sequences, the loop morphology of wild-type and several mutant Threads can be explained by assumption of a single Threads-specific transcription unit comprising about 5.1 Mb of repetitive DNA located between the Pseudonucleolus and the Nucleolus organizer. Transcription is unidirectional from the Pseudonucleolus towards the terminally located Nucleolus organizer. Transcripts most likely start in front of or within the 3.2 Mb region of YLII-related sequences, pass through subsequent blocks of 1.2 and 0.3 Mb of YLI- and rally-related sequences, respectively, and cease within the region of a smaller block of YLI-related repeats. The megabase-sized transcripts remain physically linked to the DNA axis and their extended satellite-specific regions form coaxial clouds or shells around the central DNA axis. In this way each cluster of earlier-transcribed sequences generates a cloud or shell on top of the later-transcribed ones. According to this model of 'satellite-specific coaxial shells' the tube-like morphology and other peculiarities of the Y chromosomal lampbrush loops Threads can be explained as a result of satellite-specific RNA superstructures and/or formation of extended ribonucleoprotein (RNP) complexes between clusters of satellite-specific transcripts and specific proteins. On the basis of this model the specific morphology of several Threads mutants can be interpreted as the result of large interstitial or terminal deletions that alter the total length of the Threads-specific transcription unit without exerting other major effects on principal features of the transcription process along the Threads.

The distribution of the transposable element Bari-1 in the Drosophila melanogaster and Drosophila simulans genomes

The distribution of the transposable element Bari-1 in D. melanogaster and D. simulans was examined by Southern blot analysis and by in situ hybridization in a large number of strains of different geographical origins and established at different times. Bari-1 copies mostly homogeneous in size and physical map are detected in all strains tested. Both in D. melanogaster and in D. simulans a relatively high level of intraspecific insertion site polymorphism is detectable, suggesting that in both species Bari-1 is or has been actively transposing. The main difference between the two sibling species is the presence of a large tandem array of the element in a well-defined heterochromatic location of the D. melanogaster genome, whereas such a cluster is absent in D. simulans. The presence of Bari-1 elements with apparently identical physical maps in all D. melanogaster and D. simulans strains examined suggests that Bari-1 is not a recent introduction in the genome of the melanogaster complex. Structural analysis reveals unusual features that distinguish it from other inverted repeat transposons, whereas many aspects are similar to the widely distributed Tc1 element of C. elegans.

The elusive fertility genes of Drosophila: the ultimate haven for selfish genetic elements

The Y chromosomes of Drosophila are necessary for male fertility. They carry giant genes that have some unconventional properties besides controlling the motility of the spermatozoa. Classical genetic and molecular studies suggest that evolution has favoured the close association between these genes and repetitive DNA sequences with 'selfish' traits.

Degenerating gypsy retrotransposons in a male fertility gene on the Y chromosome of Drosophila hydei

During the evolution of the Y chromosome of Drosophila hydei, retrotransposons became incorporated into the lampbrush loop pairs formed by several of the male fertility genes on this chromosome. Although insertions of retrotransposons are involved in many spontaneous mutations, they do not affect the functions of these genes. We have sequenced gypsy elements that are expressed as constituents of male fertility gene Q in the lampbrush loop pair Nooses. We find that these gypsy elements are all truncated and specifically lost those sequences that may interfere with the continuity of lampbrush loop transcription. Only defective coding regions are found within the loop. Gypsy is not transcribed in loops of many other Drosophila species harboring the family. These results suggest that any contribution of gypsy to the function of male fertility gene Q does not depend on a conserved DNA sequence.

Structure, molecular evolution and maintenance of copy number of extended repeated structures in the X-heterochromatin of Drosophila melanogaster

The 60 kb repeats located in the distal heterochromatin of the X chromosome of Drosophila melanogaster were cloned in overlapping cosmids. These regions, designated as SCLRs, comprised the following types of repeated elements: Stellate genes, which are known to be involved in spermatogenesis; copia-like retrotransposons; LINE elements, including amplified Type I rDNA insertions; and rDNA fragments. The following steps in SCLR formation were hypothesized: insertion of mobile elements into the rDNA and Stellate gene clusters; internal tandem duplication events; recombination between the rDNA cluster and Stellate tandem repeat; and amplification of the whole SCLR structure. There are about nine SCLR copies per haploid genome, but there is approximately a twofold variation in copy number between fly stocks. The SCLR copy number differences between closely related stocks are suggested to be the result of unequal sister chromatid exchange (USCE). The restricted variation in SCLR copy number between unrelated stocks and the absence of chromosomes free of SCLRs suggests that natural selection is active in copy number maintenance.

The Drosophila micropia retrotransposon encodes a testis-specific antisense RNA complementary to reverse transcriptase

The micropia transposable element of Drosophila hydei is a long terminal repeat-containing retrotransposon present in both the autosomes and the Y chromosome. micropia expression gives rise to a complex set of sense and antisense RNAs transcribed primarily during spermatogenesis. The most abundant sense RNAs constitute an assortment of heterogeneous high-molecular-weight transcripts expressed as constituents of the Y-chromosomal lampbrush loops of primary spermatocytes. In addition, micropia encodes a full-length RNA that extends between the two long terminal repeats of the element. The major 1.0-kb antisense RNA characterized is complementary to the reverse transcriptase and RNase H coding regions of micropia. It is expressed from a testis-specific promoter during the primary spermatocyte stages and is detectable until spermatid elongation stages. Sequence comparison of this promoter with the 5' region of other testis-specific genes allows the conception of a conserved sequence that is responsible for this pattern of expression. A 284-bp fragment containing this sequence is able to drive testis-specific expression of the Escherichia coli lacZ gene in Drosophila melanogaster. This sequence is conserved in the micropia elements present in other Drosophila species that also encode an antisense RNA. The evolutionary conservation of micropia antisense RNA expression and the sequences responsible for its testis-specific transcription suggests a role for this antisense RNA in the control of germ line expression of the full-length transcript or transposon-encoded proteins.

The Drosophila micropia retrotransposon encodes a testis-specific antisense RNA complementary to reverse transcriptase

The micropia transposable element of Drosophila hydei is a long terminal repeat-containing retrotransposon present in both the autosomes and the Y chromosome. micropia expression gives rise to a complex set of sense and antisense RNAs transcribed primarily during spermatogenesis. The most abundant sense RNAs constitute an assortment of heterogeneous high-molecular-weight transcripts expressed as constituents of the Y-chromosomal lampbrush loops of primary spermatocytes. In addition, micropia encodes a full-length RNA that extends between the two long terminal repeats of the element. The major 1.0-kb antisense RNA characterized is complementary to the reverse transcriptase and RNase H coding regions of micropia. It is expressed from a testis-specific promoter during the primary spermatocyte stages and is detectable until spermatid elongation stages. Sequence comparison of this promoter with the 5' region of other testis-specific genes allows the conception of a conserved sequence that is responsible for this pattern of expression. A 284-bp fragment containing this sequence is able to drive testis-specific expression of the Escherichia coli lacZ gene in Drosophila melanogaster. This sequence is conserved in the micropia elements present in other Drosophila species that also encode an antisense RNA. The evolutionary conservation of micropia antisense RNA expression and the sequences responsible for its testis-specific transcription suggests a role for this antisense RNA in the control of germ line expression of the full-length transcript or transposon-encoded proteins.

Genome canalization: the coevolution of transposable and interspersed repetitive elements with single copy DNA

Transposable and interspersed repetitive elements (TIREs) are ubiquitous features of both prokaryotic and eukaryotic genomes. However, controversy has arisen as to whether these sequences represent useless 'selfish' DNA elements, with no cellular function, as opposed to useful genetic units. In this review, we selected two insect species, the Dipteran Drosophila and the Lepidopteran Bombyx mori (the silkmoth), in an attempt to resolve this debate. These two species were selected on the basis of the special interest that our laboratory has had over the years in Bombyx with its well known molecular and developmental biology, and the wealth of genetic data that exist for Drosophila. In addition, these two species represent contrasting repetitive element types and patterns of distribution. On one hand, Bombyx exhibits the short interspersion pattern in which Alu-like TIREs predominate while Drosophila possesses the long interspersion pattern in which retroviral-like TIREs are prevalent. In Bombyx, the main TIRE family is Bm-1 while the Drosophila group contains predominantly copia-like elements, non-LTR retroposons, bacterial-type retroposons and fold-back transposable elements sequences. Our analysis of the information revealed highly non-random patterns of both TIRE biology and evolution, more indicative of these sequences acting as genomic symbionts under cellular regulation rather than useless or selfish junk DNA. In addition, we extended our analysis of potential TIRE functionality to what is known from other eukaryotic systems. From this study, it became apparent that these DNA elements may have originated as innocuous or selfish sequences and then adopted functions. The mechanism for this conversion from non-functionality to specific roles is a process of coevolution between the repetitive element and other cellular DNA often times in close physical proximity. The resulting interdependence between repetitive elements and other cellular sequences restrict the number of evolutionarily successful mutational changes for a given function or cistron. This mutual limitation is what we call genome canalization. Well documented examples are discussed to support this hypothesis and a mechanistic model is presented for how such genomic canalization can occur. Also proposed are empirical studies which would support or invalidate aspects of this hypothesis.

Genetic and cytogenetic analysis of the "Th-Ps" region of the Y chromosome of Drosophila hydei: evidence for dual functions of the lampbrush loop-forming fertility genes?

Two competing hypotheses have been proposed for the function of the Y chromosomal fertility factors in Drosophila, which form giant lampbrush loops during the primary spermatocyte stage. The first hypothesis suggests a conventional coding function, the second proposes an unconventional gene function mediated through protein binding by nascent transcripts. Therefore, we studied the genetics and cytogenetics of the two Y chromosomal fertility genes A and C of Drosophila hydei (which form the lampbrush loops threads and pseudonucleolus) in order to test the validity of these different hypotheses. Both lampbrush loops bind specific proteins, which are recognized by different antisera. Absence of either of the lampbrush loops does not interfere with the synthesis of the antigens but completely prevents the binding of the particular antigen to other lampbrush loops. Absence of the loops also does not interfere with the postmeiotic presence and localization of the particular antigen. Deletion (or inactivation) of either of the lampbrush loops threads or pseudonucleolus causes sterility of the male flies as do other male-sterile alleles of both fertility genes, which do not affect the morphology of the lampbrush loops. The phenotypic effects of these mutations on sperm morphogenesis are identical for all various male-sterile alleles of each of the fertility genes A and C, regardless of whether a particular allele leaves the loop intact, modifies that loop, or deletes (or inactivates) the loop completely. Finally, the isolation of fertile Y chromosomal mutations which modify the morphology of the lampbrush loops demonstrates that it is possible to uncouple loop morphology and genetic function. These findings do not support the hypothesis that the binding of proteins to a lampbrush loop has a substantial impact on spermiogenesis.