BS a novel LINE-like element in Drosophila melanogaster

MITE infestation accommodated by genome editing in the germline genome of the ciliate Blepharisma

During their development following sexual conjugation, ciliates excise numerous internal eliminated sequences (IESs) from a copy of the germline genome to produce the functional somatic genome. Most IESs are thought to have originated from transposons, but the presumed homology is often obscured by sequence decay. To obtain more representative perspectives on the nature of IESs and ciliate genome editing, we assembled 40,000 IESs of Blepharisma stoltei, a species belonging to a lineage (Heterotrichea) that diverged early from those of the intensively studied model ciliate species. About a quarter of IESs were short (<115 bp), largely nonrepetitive, and with a pronounced ~10 bp periodicity in length; the remainder were longer (up to 7 kbp) and nonperiodic and contained abundant interspersed repeats. Contrary to the expectation from current models, the assembled Blepharisma germline genome encodes few transposases. Instead, its most abundant repeat (8,000 copies) is a Miniature Inverted-repeat Transposable Element (MITE), apparently a deletion derivative of a germline-limited Pogo-family transposon. We hypothesize that MITEs are an important source of IESs whose proliferation is eventually self-limiting and that rather than defending the germline genomes against mobile elements, transposase domestication actually facilitates the accumulation of junk DNA.

Helena and BS: Two Travellers between the Genera Drosophila and Zaprionus

The frequency of horizontal transfers of transposable elements (HTTs) varies among the types of elements according to the transposition mode and the geographical and temporal overlap of the species involved in the transfer. The drosophilid species of the genus Zaprionus and those of the melanogaster, obscura, repleta, and virilis groups of the genus Drosophila investigated in this study shared space and time at some point in their evolutionary history. This is particularly true of the subgenus Zaprionus and the melanogaster subgroup, which overlapped both geographically and temporally in Tropical Africa during their period of origin and diversification. Here, we tested the hypothesis that this overlap may have facilitated the transfer of retrotransposons without long terminal repeats (non-LTRs) between these species. We estimated the HTT frequency of the non-LTRs BS and Helena at the genome-wide scale by using a phylogenetic framework and a vertical and horizontal inheritance consistence analysis (VHICA). An excessively low synonymous divergence among distantly related species and incongruities between the transposable element and species phylogenies allowed us to propose at least four relatively recent HTT events of Helena and BS involving ancestors of the subgroup melanogaster and ancestors of the subgenus Zaprionus during their concomitant diversification in Tropical Africa, along with older possible events between species of the subgenera Drosophila and Sophophora. This study provides the first evidence for HTT of non-LTRs retrotransposons between Drosophila and Zaprionus, including an in-depth reconstruction of the time frame and geography of these events.

The rhizome of life: what about metazoa?

The increase in huge number of genomic sequences in recent years has contributed to various genetic events such as horizontal gene transfer (HGT), gene duplication and hybridization of species. Among them HGT has played an important role in the genome evolution and was believed to occur only in Bacterial and Archaeal genomes. As a result, genomes were found to be chimeric and the evolution of life was represented in different forms such as forests, networks and species evolution was described more like a rhizome, rather than a tree. However, in the last few years, HGT has also been evidenced in other group such as metazoa (for example in root-knot nematodes, bdelloid rotifers and mammals). In addition to HGT, other genetic events such as transfer by retrotransposons and hybridization between more closely related lineages are also well established. Therefore, in the light of such genetic events, whether the evolution of metazoa exists in the form of a tree, network or rhizome is highly questionable and needs to be determined. In the current review, we will focus on the role of HGT, retrotransposons and hybridization in the metazoan evolution.

Unique structural characteristics and evolution of a cluster of venom phospholipase A2 isozyme genes of Protobothrops flavoviridis snake

Protobothrops flavoviridis (Crotalinae) venom gland phospholipase A(2) (PLA(2)) isozyme genes have evolved in an accelerated manner to acquire diverse physiological activities in their products. For elucidation of the multiplication mechanism of PLA(2) genes, a 25,026 bp genome segment harboring five PLA(2) isozyme genes was obtained from Amami-Oshima P. flavoviridis liver and sequenced. The gene PfPLA 2 encoded [Lys(49)]PLA(2) called BPII, the gene PfPLA 4 neurotoxic [Asp(49)]PLA(2) called PLA-N, the gene PfPLA 5 basic [Asp(49)]PLA(2) called PLA-B, and PfPLA 1(psi) and PfPLA 3(psi) were the inactivated genes. The 5' truncated reverse transcriptase (RT) elements, whose intact forms constitute long interspersed nuclear elements (LINEs), were found in close proximity to the 3' end of PLA(2) genes and named PLA(2) gene-coupled RT fragments (PcRTFs). The facts that PcRTFs have the stem-loop and repetitive sequence in the 3' untranslated region (UTR) which is characteristic of CR1 LINEs suggest that PcRTFs are the debris of P. flavoviridis ancestral CR1 LINEs, denoted as PfCR1s. Since the associated pairs of PLA(2) genes and PcRTFs are arranged in tandem in the 25,026 bp segment, it is thought that an ancestral PLA(2) gene-PfCR1 unit (PfPLA-PfCR1) which was produced by retrotransposition of PfCR1 by itself to the 3' end of PLA(2) gene duplicated several times to form a multimer of PfPLA-PfCR1, a cluster of PLA(2) genes, in the period after Crotalinae and Viperinae snakes branched off. Recombinational hot spot of a 37bp segment, named Scomb, was found in the region 548 bp upstream from the TATA box of PLA(2) genes. Thus, it could be assumed that multiplication of PfPLA-PfCR1 occurred by unequal crossing over of the segment, -Scomb-PfPLA-PfCR1-Scomb-. The PfCR1 moieties were afterward disrupted in the 5' portion to PcRTFs. The detection of two types of PcRTFs different in length which were produced by elimination of two definitive sequences in PfCR1 moiety possibly by gene conversion clearly supports such process but not multiplication of the PLA(2) gene-PcRTF unit.

The evolutionary dynamics of the Helena retrotransposon revealed by sequenced Drosophila genomes

BACKGROUND

Several studies have shown that genomes contain a mixture of transposable elements, some of which are still active and others ancient relics that have degenerated. This is true for the non-LTR retrotransposon Helena, of which only degenerate sequences have been shown to be present in some species (Drosophila melanogaster), whereas putatively active sequences are present in others (D. simulans). Combining experimental and population analyses with the sequence analysis of the 12 Drosophila genomes, we have investigated the evolution of Helena, and propose a possible scenario for the evolution of this element.

RESULTS

We show that six species of Drosophila have the Helena transposable element at different stages of its evolution. The copy number is highly variable among these species, but most of them are truncated at the 5' ends and also harbor several internal deletions and insertions suggesting that they are inactive in all species, except in D. mojavensis in which quantitative RT-PCR experiments have identified a putative active copy.

CONCLUSION

Our data suggest that Helena was present in the common ancestor of the Drosophila genus, which has been vertically transmitted to the derived lineages, but that it has been lost in some of them. The wide variation in copy number and sequence degeneration in the different species suggest that the evolutionary dynamics of Helena depends on the genomic environment of the host species.

Mitch a rapidly evolving component of the Ndc80 kinetochore complex required for correct chromosome segregation in Drosophila

We identified an essential kinetochore protein, Mitch, from a genetic screen in D. melanogaster. Mitch localizes to the kinetochore, and its targeting is independent of microtubules (MTs) and several other known kinetochore components. Animals carrying mutations in mitch die as late third-instar larvae; mitotic neuroblasts in larval brains exhibit high levels of aneuploidy. Analysis of fixed D. melanogaster brains and mitch RNAi in cultured cells, as well as video recordings of cultured mitch mutant neuroblasts, reveal that chromosome alignment in mitch mutants is compromised during spindle formation, with many chromosomes displaying persistent mono-orientation. These misalignments lead to aneuploidy during anaphase. Mutations in mitch also disrupt chromosome behavior during both meiotic divisions in spermatocytes: the entire chromosome complement often moves to only one spindle pole. Mutant mitotic cells exhibit contradictory behavior with respect to the spindle assembly checkpoint (SAC). Anaphase onset is delayed in untreated cells, probably because incorrect kinetochore attachment maintains the SAC. However, mutant brain cells and mitch RNAi cells treated with MT poisons prematurely disjoin their chromatids, and exit mitosis. These data suggest that Mitch participates in SAC signaling that responds specifically to disruptions in spindle microtubule dynamics. The mitch gene corresponds to the transcriptional unit CG7242, and encodes a protein that is a possible ortholog of the Spc24 or Spc25 subunit of the Ndc80 kinetochore complex. Despite the crucial role of Mitch in cell division, the mitch gene has evolved very rapidly among species in the genus Drosophila.

APE-type non-LTR retrotransposons: determinants involved in target site recognition

Non-long terminal repeat (Non-LTR) retrotransposons represent a diverse and widely distributed group of transposable elements and an almost ubiquitous component of eukaryotic genomes that has a major impact on evolution. Their copy number can range from a few to several million and they often make up a significant fraction of the genomes. The members of the dominating subtype of non-LTR retrotransposons code for an endonuclease with homology to apurinic/apyrimidinic endonucleases (APE), and are thus termed APE-type non-LTR retrotransposons. In the last decade both the number of identified non-LTR retrotransposons and our knowledge of biology and evolution of APE-type non-LTR retrotransposons has increased tremendously.

A search for reverse transcriptase-coding sequences reveals new non-LTR retrotransposons in the genome of Drosophila melanogaster

BACKGROUND

Non-long terminal repeat (non-LTR) retrotransposons are eukaryotic mobile genetic elements that transpose by reverse transcription of an RNA intermediate. We have performed a systematic search for sequences matching the characteristic reverse transcriptase domain of non-LTR retrotransposons in the sequenced regions of the Drosophila melanogaster genome.

RESULTS

In addition to previously characterized BS, Doc, F, G, I and Jockey elements, we have identified new non-LTR retrotransposons: Waldo, You and JuanDm. Waldo elements are related to mosquito RTI elements. You to the Drosophila I factor, and JuanDm to mosquito Juan-A and Juan-C. Interestingly, all JuanDm elements are highly homogeneous in sequence, suggesting that they are recent components of the Drosophila genome.

CONCLUSIONS

The genome of D. melanogaster contains at least ten families of non-site-specific non-LTR retrotransposons representing three distinct clades. Many of these families contain potentially active members. Fine evolutionary analyses must await the more accurate sequences that are expected in the next future.

SCO-spondin is evolutionarily conserved in the central nervous system of the chordate phylum

Bovine SCO-spondin was shown to be a brain-secreted glycoprotein specifically expressed in the subcommissural organ, an ependymal differentiation located in the roof of the Sylvian aqueduct. Also, SCO-spondin makes part of Reissner's fiber, a phylogenetically and ontogenetically conserved structure present in the central canal of the spinal cord of chordates. This secretion is a large multidomain protein probably involved in axonal growth and/or guidance. As Reissner's fiber is highly conserved in the chordate central nervous system, we sought genes orthologous to the bovine SCO-spondin gene by Southern blot analysis in several members of the chordate phylum: urochordates, cephalochordates, cyclostomes, and lower and higher vertebrates, including humans. In addition, conserved glycoproteins present in the subcommissural organ and Reissner's fiber were revealed by immunohistochemistry using antibodies raised against bovine Reissner's fiber. Variation in the sites of Reissner's fiber production according to chordate subphylum, presence of this structure in the spinal cord, and conservation of the SCO-spondin gene are discussed in the context of chordate central nervous system development. These results indicate that SCO-spondin is an ancient ependymal secretion, making part of Reissner's fiber, that may have had an important function during the evolution of the central nervous system in chordates, including that of the spinal cord.

Invertebrate retroviruses: ZAM a new candidate in D.melanogaster

ZAM, a new retroelement of Drosophila melanogaster, was identified as a mutational insertion at the white locus. It displays all the structural features of a vertebrate retrovirus. Its three open reading frames encode predicted products resembling the products of the gag, pol and env genes of retroviruses. Its transcription gives rise to an 8.6 kb full-length RNA and a 1.7 kb spliced message for the env gene. The latter encodes an envelope protein that is typical of elements having an extracellular phase of the life cycle. The identification of a ZAM envelope retrogene provides evidence that ZAM is mobilized through a reverse trancriptional process in the germ line of flies. We report that ZAM is distributed differently among D.melanogaster strains. Two stocks out of >15 tested display a ZAM high copy number, with numerous copies distributed on chromosomal arms. This high copy number is associated with a high transcriptional rate of ZAM. The existence of these two categories of strains offers a new genetic system in which the properties of a potential invertebrate retrovirus can be tested.

Multiple downstream promoter modules regulate the transcription of the Drosophila melanogaster I, Doc and F elements

The basal promoters of three Drosophila long interspersed nuclear elements (LINEs), the I factor and the F and Doc elements, have the same architecture. In each, transcription is directed by an initiator which is faithfully and efficiently recognized only when flanked 3' by a DNA segment approximately 20 bp in length called the B region. The B regions of the three promoters are interchangeable and have a complex structure, comprising three functionally distinct elements: de1, de2 and de3. While de2 is relatively conserved, fitting the consensus RGACGTGY, de1 and de3 vary among the three promoters. At different levels, each downstream element is able to ensure accurate recognition of the initiator. The de2 domain stimulates transcription of the F, I and Doc promoters to the same extent. In contrast, the I de1 domain stimulates transcription much more efficiently than the corresponding domains of the F and Doc elements. The finding that de2 is selectively required in order to detect full activity of enhancer sequences found in the F element suggests that de1 and de2 interact with different proteins. The B regions can be replaced by and synergize with a TATA element, can functionally substitute for downstream promoter sequences in the Drosophila hsp70 gene, and significantly activate the mouse terminal deoxynucleotidyl transferase initiator. Our data suggest that the B regions stimulate transcription by providing sites of interaction for the TFIID complex. Sequences homologous to the del to de3 array are found downstream from the transcription start site(s) both in TATA-less and TATA-containing promoters.