Use of surface-enhanced laser desorption ionization-time-of-flight to identify heat shock protein 70 isoforms in closely related species of the virilis group of Drosophila

The 70-kDa heat shock protein (Hsp) family in all Drosophila species includes 2 environmentally inducible family members, Hsp70 and Hsp68. Two-dimensional gel electrophoresis revealed an unusual pattern of heat shock-inducible proteins in the species of the virilis group. Trypsin fingerprinting and microsequencing of tryptic peptides using ProteinChip Array technology identified the major isoelectric variants of Hsp70 family, including Hsp68 isoforms that differ in both molecular mass and isoelectric point from those in Drosophila melanogaster. The peculiar electrophoretic mobility is consistent with the deduced amino acid sequence of corresponding hsp genes from the species of the virilis group.

Reverse transcriptase and endonuclease activities encoded by Penelope-like retroelements

Penelope-like elements are a class of retroelement that have now been identified in >50 species belonging to at least 10 animal phyla. The Penelope element isolated from Drosophila virilis is the only transpositionally active representative of this class isolated so far. The single ORF of Penelope and its relatives contains regions homologous to a reverse transcriptase of atypical structure and to the GIY-YIG, or Uri, an endonuclease (EN) domain not previously found in retroelements. We have expressed the single ORF of Penelope in a baculovirus expression system and have shown that it encodes a polyprotein with reverse transcriptase activity that requires divalent cations (Mn2+ and Mg2+). We have also expressed and purified the EN domain in Escherichia coli and have demonstrated that it has EN activity in vitro. Mutations in the conserved residues of the EN catalytic module abolish its nicking activity, whereas the DNA-binding properties of the mutant proteins remain unaffected. Only one strand of the target sequence is cleaved, and there is a certain degree of cleavage specificity. We propose that the Penelope EN cleaves the target DNA during transposition, generating a primer for reverse transcription. Our results show that an active Uri EN has been adopted by a retrotransposon.

Evolution and arrangement of the hsp70 gene cluster in two closely related species of the virilis group of Drosophila

To investigate the genetic basis of differing thermotolerance in the closely related species Drosophila virilis and Drosophila lummei, which replace one another along a latitudinal cline, we characterized the hsp70 gene cluster in multiple strains of both species. In both species, all hsp70 copies cluster in a single chromosomal locus, 29C1, and each cluster includes two hsp70 genes arranged as an inverted pair, the ancestral condition. The total number of hsp70 copies is maximally seven in the more thermotolerant D. virilis and five in the less tolerant D. lummei, with some strains of each species exhibiting lower copy numbers. Thus, maximum hsp70 copy number corresponds to hsp70 mRNA and Hsp70 protein levels reported previously and the size of heat-induced puffs at 29C1. The nucleotide sequence and spacing of the hsp70 copies are consistent with tandem duplication of the hsp70 genes in a common ancestor of D. virilis and D. lummei followed by loss of hsp70 genes in D. lummei. These and other data for hsp70 in Drosophila suggest that evolutionary adaptation has repeatedly modified hsp70 copy number by several different genetic mechanisms.

[Determination of the endonuclease activity encoded by retrotransposon]

Mobile element Penelope is mobilized in the course of hybrid dysgenesis in D. virilis. This element is also responsible for the activation of other unrelated families of TE occurring in the progeny of dysgenic crosses. Penelope elements have extremely variable structure and combine some properties of LINEs and LTR-containing elements. Penelope-like elements (PLEs) have been recently described in various organisms including fish species, rotifers and amoebae. Computer analysis enabled to predict the presence of reverse transcriptase domain in Penelope-encoded polyprotein as well as UvrC type endonuclease at the C-end of the element. It is noteworthy that none of the previously described retroelements was shown to contain such a nuclease. Multiple alignments revealed five conservative catalytic motifs and all conservative residues present in GIY-YIG endonuclease family within Penelope-encoded protein. Herein we have demonstrated that Penelope element isolated from D. virilis encodes functionally active endonuclease exhibiting some sequence-specificity to the sequence previously demonstrated to serve as Penelope genomic insertion site.

Xenografts of embryonic nerve tissue from Drosophila neuromutants stimulate development of neural homografts in rat brain and block glial scar formation

The influence of xenografts of Drosophila melanogaster embryonic nerve cells on the development of embryonic neurohomografts in the adult rat brain has been investigated. Embryonic nerve cells, marked with bacterial galactosidase gene (lacZ) from D. melanogaster strain with a mutation in the Delta locus, were transplanted into adult rat brain. Drosophila cells were easily identifiable in brain histological sections by X-gal staining. Xenografts survived for at least 2-3 weeks in the recipient brain after the operation to be subsequently attacked by macrophages. Importantly, no glial scar was formed around the xenograft. The addition of Drosophila embryonic nerve cells to a homograft of rat embryonic neural tissue facilitated the survival and development of this homograft by blocking the glial scar formation, stimulating vascularization of the graft area and differentiation of the implanted embryonic nerve cells.

Retroelements containing introns in diverse invertebrate taxa

We report that two structurally similar transposable elements containing reverse transcriptase (RT), Penelope in Drosophila virilis and Athena in bdelloid rotifers, have proliferated as copies containing introns. The ability of Penelope-like elements (PLEs) to retain introns, their separate phylogenetic placement and their peculiar structural features make them a novel class of eukaryotic retroelements.

[The unusual mobile element Penelope and its behavior in distant Drosophila species]

The retroelement Penelope isolated from Drosophila virilis has a very unusual structure and codes for reverse transcriptase and an endonuclease belonging to the UvrC type. As shown previously, Penelope is a key element in induction of the hybrid dysgenesis syndrome described in D. virilis, which also involves mobilization of several unrelated mobile element families. Here we report a successful introduction of Penelope into the D. melanogaster genome by P element-mediated transformation. In the new host genome, Penelope is actively transcribed producing major transcript which coincides with that detected in dysgenic hybrids of D. virilis. In situ hybridization on D. melanogaster polytene chromosomes and Southern blotting revealed multiple transpositions of Penelope in the transformed D. melanogaster strains. We determined the structure of six Penelope copies inserted into D. melanogaster chromosomes. Some transformed D. melanogaster strains showed dysgenesis effects similar to those observed in hybrids from D. virilis dysgenic crosses.

Penelope retroelements from Drosophila virilis are active after transformation of Drosophila melanogaster

The Penelope family of retroelements was first described in species of the Drosophila virilis group. Intact elements encode a reverse transcriptase and an endonuclease of the UvrC type, which may play a role in Penelope integration. Penelope is a key element in the induction of D. virilis hybrid dysgenesis, which involves the mobilization of several unrelated families of transposable elements. We here report the successful introduction of Penelope into the germ line of Drosophila melanogaster by P element-mediated transformation with three different constructs. Penelope is actively transcribed in the D. melanogaster genome only in lines transformed with a construct containing a full-length Penelope clone. The transcript is identical to that detected in D. virilis dysgenic hybrids. Most newly transposed Penelope elements have a very complex organization. Significant proliferation of Penelope copy number occurred in some lines during the 24-month period after transformation. The absence of copy number increase with two other constructs suggests that the 5' andor 3' UTRs of Penelope are required for successful transposition in D. melanogaster. No insect retroelement has previously been reported to be actively transcribed and to increase in copy number after interspecific transformation.

[Evolution of the response to heat shock in genus Drosophila]

Thermotolerance was studied in a wide spectrum of Drosophila species and strains originating from different climatic zones and considerably differing from one another in the ambient temperature of their habitats. The species that lived in hot climate have a higher thermotolerance. Most species of the virilis group exhibited positive correlation between the HSP70 accumulation after heat exposure and thermotolerance; however, this correlation was absent in some species and strains. For example, the D. melanogaster Oregon R strain, which had the highest sensitivity to heat shock (HS) among all strains and species studied, displayed the maximum level of HSP70 proteins after HS. The patterns of induction of various heat shock protein (HSP) families after heat exposure in a wide spectrum of Drosophila species were compared. The results obtained suggest that the HSP40 and low-molecular-weight HSPs (lmwHSPs) play a significant role in thermotolerance and adaptation to hot climate. Polymorphism in hsp70 gene clusters of Drosophila and variation in the numbers of gene copies and hsp70 isoforms in group virilis were found. The evolutionary role of the variation in the number of hsp70 gene copies observed in the strains and species of genus Drosophila is discussed.

[Analysis of heat shock proteins and thermotolerance in a thermoresistant strain of Drosophila melanogaster]

Here we studied the response to heat shock in a desert D. melanogaster strain TT capable of living and propagating at 32 degrees C and the standard Oregon R strain. The TT strain proved to be more resistant to extreme temperatures. On the other hand, the observed high thermotolerance of the strain was not accompanied by a higher level of HSP70 synthesis. Conversely, reliably smaller amounts of HSP70 were synthesized in the TT strain as compared to Oregon R under all shock temperatures except the critical one (39.5 degrees C). Differences in both the structure of HSP70 genes and the pattern of all heat shock proteins have been observed between the studied strains. The role of the heat shock system in the adaptation to hyperthermia is discussed.

[Structure and evolutionary role of the Penelope mobile element in Drosophila species of the virilis group]

The mobile element Penelope is activated and mobilizes several other transposons in dysgenic crosses in Drosophila virilis. Its structure proved to be complex and to vary greatly in all examined species of the virilis group. Phylogenetic analysis of the reverse transcriptase (RT) domain assigned Penelope to a new branch, rather than to any known family, of LTR-lacking retroelements. Amino acid sequence analysis showed that the C-terminal domain of the Penelope polyprotein is an active endonuclease, which is related to intron-encoded endonucleases and to bacterial repair endonuclease UrvC, and may act as an integras. Retroelements coding for a putative endonuclease that differs from typical integrase have thus far not been known. The N-terminal domain of the Penelope polyprotein was shown to contain a protease with significant homology to HIV-1 protease. Phylogenetic analysis divided the Penelope copies from several virilis species into two subfamilies, one including virtually identical full-length copies, and the other comprising highly divergent defective copies. The results suggest both vertical and horizontal transfer of the element. Possibly, Penelope invasion recurred during evolution and contributed to genome rearrangement in the virilis species. Chromosome aberrations detected in D. virilis, which is now being invaded by Penelope, is direct evidence for this assumption.

[The sbr gene product in Drosophila melanogaster and its orthologs in yeast (Mex67p) and human (TAP)]

A DNA sequence from the 9F region of Drosophila melanogaster polytene chromosomes was cloned. Sequencing the cloned region and its comparison with the known sequences of the D. melanogaster genome showed that the cloned DNA part contains gene sbr and adjacent sequences. The literature data on the structure and functions of genes TAP in humans and Mex67 in yeast are discussed. These genes are orthologous to the sbr gene of Drosophila and control mRNA export from the nucleus to the cytoplasm. The literature evidence is consistent with the recessive expression of mutation l(1)ts403 (sbr10) upon heat treatment that is manifested as impaired HSP synthesis at the posttranscriptional level. However, it fails to explain the semidominant effect of the mutation manifested in high frequency of meiotic sex-chromosome nondisjunction in heat-treated females. A comparison of amino-acid sequences corresponding to the products of the three orthologous genes, TAP, Mex67, and sbr, showed that the sbr gene product of Drosophila is more similar to the human TAP factor than to the Mex67 factor in yeast.

The structure and evolution of Penelope in the virilis species group of Drosophila: an ancient lineage of retroelements

The Penelope element is the key element responsible for mobilization of other transposable elements in the course of hybrid dysgenesis in Drosophila virilis. Penelope has an unusually complex, highly variable organization in all studied species of the virlis group. Thc BRIDGE1 element from the fish Fugu rubripes is homologous to Penelope, and database searches detected additional homologous sequences among Expressed Sequence Tags from the flatworm Schistosoma mansonii and the nematode Ancylostoma caninum. Phylogenetic analysis shows that the reverse transcriptase of the Penelope group does not belong to any of the characterized major retroelement lineages, but apparently represents a novel branch of non-LTR retroelements. Sequence profile analysis results in the prediction that the C-terminal domain of the Penelope polyprotein is an active endonuclease related to intron-encoded endonucleases and the bacterial repair endonuclease UvrC, which could function as an integrase. No retroelements containing a predicted endonuclease of this family have been described previously. Phylogenetic analysis of Penelope copies isolated from several species of the virilis group reveals two subfamilies of Penelope elements, one of which includes full-length copies whose nucleotide sequences are almost identical, whereas the other one consists of highly diverged defective copies. Phylogenetic analysis of Penelope suggests both vertical transmission of the element and probable horizontal transfers. These findings support the notion that Penelope invasions occurred repeatedly in the evolution of the virilis group.

[Effect of the foreign gene GDNF on development of homo- and xenografts in the rat brain]

A transgenic line of Drosophila melanogaster was selected which carried the following genes: Delta, lacZ (for bacterial galactosidase), and human GDNF (for glial cell line-derived neurotrophic factor). Drosophila neuroectodermal embryonic cells were transplanted with the embryonic neurohomografts into the occipital brain region of an adult rat. Xenografts were found to block scar formation at the graft-host tissue boundary, stimulated homograft development (so that it was twice as large as the control homograft transplanted alone with no xenograft added), and noticeably improved vascularization of the homograft area.

Mobile elements and chromosomal evolution in the virilis group of Drosophila

Species of the virilis group of Drosophila differ by multiple inversions and chromosome fusions that probably accompanied, or led to, speciation. Drosophila virilis has the primitive karyotype for the group, and natural populations are exceptional in having no chromosomal polymorphisms. We report that the genomic locations of Penelope and Ulysses transposons are nonrandomly distributed in 12 strains of D. virilis. Furthermore, Penelope and Ulysses insertion sites in D. virilis show a statistically significant association with the breakpoints of inversions found in other species of the virilis group. Sixteen newly induced chromosomal rearrangements were isolated from the progeny of D. virilis hybrid dysgenic crosses, including 12 inversions, 2 translocations, and 2 deletions. Penelope and Ulysses were associated with the breakpoints of over half of these new rearrangements. Many rearrangement breakpoints also coincide with the chromosomal locations of Penelope and Ulysses insertions in the parental strains and with breakpoints of inversions previously established for other species of the group. Analysis of homologous sequences from D. virilis and Drosophila lummei indicated that Penelope insertion sites were closely, but not identically, located at the nucleotide sequence level. Overall, these results indicate that Penelope and Ulysses insert in a limited number of genomic locations and are consistent with the possibility that these elements play an important role in the evolution of the virilis species group.

How valuable are model organisms for transposable element studies?

Model organisms have proved to be highly informative for many types of genetic studies involving 'conventional' genes. The results have often been successfully generalized to other closely related organisms and also, perhaps surprisingly frequently, to more distantly related organisms. Because of the wealth of previous knowledge and their availability and convenience, model organisms were often the species of choice for many of the earlier studies of transposable elements. The question arises whether the results of genetic studies of transposable elements in model organisms can be extrapolated in the same ways as those of conventional genes? A number of observations suggest that special care needs to be taken in generalizing the results from model organisms to other species. A hallmark of many transposable elements is their ability to amplify rapidly in species genomes. Rapid spread of a newly invaded element throughout a species range has also been demonstrated. The types and genomic copy numbers of transposable elements have been shown to differ greatly between some closely related species. Horizontal transfer of transposable elements appears to be more frequent than for nonmobile genes. Furthermore, the population structure of some model organisms has been subject to drastic recent changes that may have some bearing on their transposable element genomic complements. In order to initiate discussion of this question, several case studies of transposable elements in well-studied Drosophila species are presented.

Thermotolerant desert lizards characteristically differ in terms of heat-shock system regulation

We compare the properties and activation of heat-shock transcription factor (HSF1) and the synthesis of a major family of heat-shock proteins (HSP70) in lizard species inhabiting ecological niches with strikingly different thermal parameters. Under normal non-heat-shock conditions, all desert-dwelling lizard species studied so far differ from a northern, non-desert species (Lacerta vivipara) in the electrophoretic mobility and content of proteins constitutively bound to the regulatory heat-shock elements in the heat-shock gene promoter. Under these conditions, levels of activated HSF1 and of both HSP70 mRNA and protein are higher in the desert species than in the non-desert species. Upon heat shock, HSF1 aggregates in all species studied, although in desert species HSF1 subsequently disaggregates more rapidly. Cells of the northern species have a lower thermal threshold for HSP expression than those of the desert species, which correlates with the relatively low constitutive level of HSPs and high basal content of HSF1 in their cells.

Distribution and evolution of mobile elements in the virilis species group of Drosophila

The distributions of Penelope and Ulysses, two transposable elements that can induce hybrid dysgenesis, were studied in several species groups of Drosophila. No significant hybridization to Penelope and Ulysses probes was detected by Southern blot analyses of species outside the virilis group. In contrast, both element families have had a long residence in all species of the virilis species group, as indicated by their strong presence in the heterochromatic chromocenter. Except for D. kanekoi, D. lummei, and some strains of D. virilis, species of the group carry full-sized, and at least potentially functional, copies of both element families. Consistent with the occurrence of recent transposition, Penelope and Ulysses elements are located at different chromosomal sites in different geographical strains of the same species. A total of 79 Penelope and 47 Ulysses euchromatic insertion sites were localized to chromosomal subsections in species of the virilis group. Highly significant deviations from independence of the distributions of Penelope and Ulysses and previously established inversion breakpoints were documented, suggesting that these transposable elements may have played an important role in genomic reorganization and evolution of the virilis species group, which is especially rich in karyotypic variation.

Gypsy group retrotransposon Tv1 from Drosophila virilis

We have determined the nucleotide sequence of the 6868 bp full-size retrotransposon termed 'Tv1'. Tv1 was isolated from the DNA fraction of extracellular virus-like particles of Drosophila virilis culture cells. Tv1 has the typical structure for a gypsy-group retrotransposon. The Tv1 element was found to be flanked by 453 bp long terminal direct repeats identical to each other. The central part of the element contains three long open reading frames which resemble the gag, pol and env genes of retroviruses. ORF2 includes conservative motifs of protease, reverse transcriptase, RNase H and integrase in the order characteristic for the gypsy-group retrotransposons. Although most copies of Tv1 are located in pericentromeric heterochromatin, the amplification of this family demonstrated in the cell culture and site polymorphism observed in different Drosophila strains suggest functional activity of the Tv1 element.

[Genetic structure of mobile elements of the "Penelope" family in closely related Drosophila species]

Genomic libraries were obtained from species belonging to the "virilis" group of Drosophila. Several copies of Penelope elements were isolated from these libraries by using a D. virilis Penelope clone as a probe. The elements were sequenced, and their structure was determined. The geographical distribution of this family of mobile elements in closely related species of the group was studied in detail. Cytological localization of the elements was also carried out. The high variability observed between different copies of Penelope is probably due to recombination between individual copies. The role of these elements in the evolution of closely related species is discussed.