A genetic screen has been developed in Drosophila for identifying host-repair genes responsible for processing DNA lesions formed during mobilization of P transposable elements. Application of that approach to repair deficient mutants has revealed that the mei-41 and mus302 genes are necessary for recovery of P-bearing chromosomes undergoing transposition. Both of these genes are required for normal postreplication repair. Mutants deficient in excision repair, on the other hand, have no detected effect on the repair of transposition- induced lesions. These observations suggest that P element-induced lesions are repaired by a postreplication pathway of DNA repair. The data further support recent studies implicating double-strand DNA breaks as intermediates in P transposition, because the mei-41 gene has been genetically and cytologically associated with the repair of interrupted chromosomes. Analysis of this system has also revealed a striking stimulation of site-specific gene conversion and recombination by P transposition. This result strongly suggests that postreplication repair in this model eukaryote operates through a conversion/recombination mechanism. Our results also support a recently developed model for a conversion-like mechanism of P transposition (Engels et al., 1990). Involvement of the mei-41 and mus302 genes in the repair of P element-induced double-strand breaks and postreplication repair points to a commonality in the mechanisms of these processes.
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A single genetically marked P element can be efficiently mobilized to insertionally mutagenize the Drosophila genome. We have investigated how the structure of the starting element and its location along the X chromosome influenced the rate and location of mutations recovered. The structure of two P[rosy+] elements strongly affected mobilization by the autonomous "Jumpstarter-1" element. Their average transposition rates differed more than 12-fold, while their initial chromosomal location had a smaller effect. The lethal and sterile mutations induced by mobilizing a P[rosy+] element from position 1F were compared with those identified previously using a P[neoR] element at position 9C. With one possible exception, insertion hotspots for one element were frequently also targets of the other transposon. These experiments suggested that the genomic location of a P element does not usually influence its target sites on nonhomologous chromosomes. During the course of these experiments, Y- linked insertions expressing rosy+ were recovered, suggesting that marked P elements can sometimes insert and function at heterochromatic sites.
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We have designed a system for targeted gene expression that allows the selective activation of any cloned gene in a wide variety of tissue- and cell-specific patterns. The gene encoding the yeast transcriptional activator GAL4 is inserted randomly into the Drosophila genome to drive GAL4 expression from one of a diverse array of genomic enhancers. It is then possible to introduce a gene containing GAL4 binding sites within its promoter, to activate it in those cells where GAL4 is expressed, and to observe the effect of this directed misexpression on development. We have used GAL4- directed transcription to expand the domain of embryonic expression of the homeobox protein even-skipped. We show that even-skipped represses wingless and transforms cells that would normally secrete naked cuticle into denticle secreting cells. The GAL4 system can thus be used to study regulatory interactions during embryonic development. In adults, targeted expression can be used to generate dominant phenotypes for use in genetic screens. We have directed expression of an activated form of the Dras2 protein, resulting in dominant eye and wing defects that can be used in screens to identify other members of the Dras2 signal transduction pathway.
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Nucleotide sequence comparisons were used to investigate the evolution of P transposable elements and the possibility that horizontal transfer has played a role in their occurrence in natural populations of Drosophila and other Diptera. The phylogeny of P elements was examined using published sequences from eight dipteran taxa and a new, partial sequence from Scaptomyza elmoi. The results from a number of different analyses are highly consistent and reveal a P-element phylogeny that contradicts the phylogeny of the species. At least three instances of horizontal transfer are necessary to explain this incongruence, but other explanations cannot be ruled out at this time.
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The gap-repair model proposes that P elements move via a conservative, "cut-and-paste" mechanism followed by double-strand gap repair, using either the sister chromatid or homolog as the repair template. We have tested this model by examining meiotic perturbations of an X-linked ry+ transposon during the meiotic cycle of males, employing the mei-S332 mutation, which induces high frequency equational nondisjunction. This system permits the capture of both sister-X chromatids in a single patroclinous daughter. In the presence of P-transposase, transpositions within the immediate proximity of the original site are quite frequent. These are readily detectable among the patroclinous daughters, thereby allowing the combined analysis of the transposed element, the donor site and the putative sister-strand template. Molecular analysis of 22 meiotic transposition events provide results that support the gap-repair model of P element transposition. Prior to this investigation, it was not known whether transposition events were exclusively or predominantly premeiotic. The results of our genetic analysis revealed that P elements mobilize at relatively high frequencies during meiosis. We estimated that approximately 4% of the dysgenic male gametes have transposon perturbations of meiotic origin; the proportion of gametes containing lesions of premeiotic origin was estimated at 32%.
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Several studies have suggested that P elements have rapidly spread through natural populations of Drosophila melanogaster within the last four decades. This observation, together with the observation that P elements are absent in the other species of the melanogaster subgroup, has lead to the suggestion that P elements may have entered the D. melanogaster genome by horizontal transmission from some more distantly related species. In an effort to identify the potential donor in the horizontal transfer event, we have undertaken an extensive survey of the genus Drosophila using Southern blot analysis. The results showed that P-homologous sequences are essentially confined to the subgenus Sophophora. The strongest P hybridization occurs in species from the closely related willistoni group. A wild-derived strain of D. willistoni was subsequently selected for a more comprehensive molecular examination. As part of the analysis, a complete P element was cloned and sequenced from this line. Its nucleotide sequence was found to be identical to the D. melanogaster canonical P, with the exception of a single base substitution at position 32. When the cloned element was injected into D. melanogaster embryos, it was able to both promote transposition of a coinjected marked transposon and induce singed-weak mutability, thus demonstrating its ability to function as an autonomous element. The results of this study suggest that D. willistoni may have served as the donor species in the horizontal transfer of P elements to D. melanogaster.
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The objective of this thesis work was to examine P element excision transposition in Drosophila melanogaster. This was done by characterizing dysgenesis-induced mutations of P element insertion alleles at two loci with a combination of genetic and molecular biology tools.
One result to arise from this work was that sites with integrated P elements can frequently be the sites of additional P element insertions. It was concluded integrated P elements not only influenced the sites of nearby insertions, but their presence actually increased the rate of insertions into the region. While it was not clear what the basis for these effects were, it was strongly suggested P element-induced chromatin changes may have been involved. The data were also interpreted as suggesting P elements made a significant number of short range transpositions. However, much more work is needed on this question before a strong conclusion can be made.
A second result was the quality and quantity of excisions were quite different for alleles with a single P element and alleles with two closely inserted P elements. When only a single element was present, excisions were invariably imprecise, leaving some portion of the element at the site. The total excision rate for alleles with a single P element were in the range of one to a few percent, while precise excision rates were less than a fraction of a percent. Conversely, excisions from alleles with two P elements inserted into the same target site were almost entirely precise, and occurred at rates as high as 50%.
However, all alleles with closely inserted elements did not behave similarly. While alleles with two P elements inserted into the same target site were highly mutable, undergoing precise excisions at high rates, this was only true of some of the alleles where the two elements were not inserted into the same target site. The basis for the difference was concluded to be related to the sequences flanking the two elements and potentially the distance between the elements. The results suggested similar target site duplications flanking two nearby elements were essential for high mutation and precise excision rates.
The data on excisions of solo elements was uninformative in terms of distinguishing amongst the various models of P element excision. However, in combination with preliminary data from an experiment designed to measure precise excision rates, it was postulated excisions of single elements resulted from a precise excision of the element followed by annealing or template-dependent repair and then annealing of the broken ends.
The data on "precise excisions" from alleles with two elements separated by more than 8 bp confirmed predictions made based on one of the models by Roiha, Rubin and O'Hare (1988) to explain the behavior of the prototype double insertion allele, snw. The loss of sequences between separated P elements led to the conclusion that "precise excisions" from closely inserted elements resulted from transposase-dependent pairing of the terminal repeats and potentially flanking DNA, followed by an exchange event or replication fork slippage in the region. Consequently, it was concluded the mechanism responsible for losses of single P elements was distinct for the losses of one of two closely inserted P elements.
The results and materials that arose from the work in this thesis have explored previously unrecognized facets of P element biology. These data could form the basis for additional experiments to study how P elements interact with each other and with host genomes in order to better understand their evolutionary impact on the organisms in which they are found.
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When mutation or recombination events occur premeiotically, the distribution of exceptional individuals among the offspring will be "clustered" as opposed to binomial. Even though the exact nature of the clustering is usually unknown, unbiased methods for measuring mutation rate and determining the precision of these measurements are given to replaced a biased method now frequently used. When clustering is pronounced, the unweighted average mutation rate is found to be a more efficient estimator than the usual average weighted by family size. Methods of statistical inference and optimal experimental design in the absence of specific knowledge of the mechanism of clustering are also discussed.
The recommended estimators for the variance are:
where pw is the frequency estimate (total number of mutants / total scored); ni is the number of individuals scored in group i; mi is the number of mutants in group i; n and m are the sums of ni and mi over all groups scored.
Equation (5) is best in situations where the mutation rate (pw) is close to 0 or 1, and equation (A6) is more accurate when pw is closer to 1/2.
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Hybrid dysgenesis is a syndrome of germ-line aberrations including, e.g., sterility and mutation, found in certain interstrain hybrids of Drosophila melanogaster. Previous studies of sterility have shown that elements responsible for dysgenesis may reside on all major chromosomes, but that their dysgenesis-causing ability is controlled by an unknown extrachromosomal factor. Dysgenic hybrids also give rise to unstable visible mutations thought to be DNA insertions at certain sensitive loci. One such unstable allele at the singed bristle locus, designated snw, was found to mutate at extraordinary rates exceeding 50%. This instability was shown to be under the same extrachromosomal control as hybrid dysgenesis itself. That is, the mutability of snw was reversibly suppressed when placed in the background cytotype known to prevent sterility and other characteristics of hybrid dysgenesis. These results suggest that snw may represent an insertion at the singed locus of a hypothetical gene responsible for hybrid dysgenesis.
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No Abstract Available: This is a longish review -- about 37,000 words -- on all aspects of the biology of P elements covering reports up to 1987.
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The P family of transposable genetic elements is thought to be a recent addition to the Drosophila melanogaster genome. New evidence suggests that the elements came from another Drosophila species, possibly carried by parasitic mites. The transposition mechanism of P elements involves DNA gap repair which may have facilitated their rapid spread through D. melanogaster worldwide. These results provide new insight into the process of a transposon's invasion into a new species and the potential risk of extinction such an invasion might entail.
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Nonautonomous P elements normally excise and transpose only when a source of transposase is supplied, and only in the germline. The germline specificity depends on one of the introns of the transposase gene which is not spliced in somatic cells. To study the effects of somatic P activity, a modified P element (2-3) lacking this intron was used as a source of transposase. Nonautonomous P elements from a strain called Birmingham, when mobilized in somatic cells by
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P transposable elements in Drosophila melanogaster can undergo precise loss at a rate exceeding 13% per generation. The process is similar to gene conversion in its requirement for a homolog that is wild type at the insertion site, and in its reduced frequency when pairing between the homologs is inhibited. However, it differs from classical gene conversion by its high frequency, its requirement for P transposase, its unidirectionality, and its occurrence in somatic and pre-meiotic cells. The results suggest a model of P element transposition in which jumps occur by a "cut-and-paste" mechanism, but are followed by double-strand gap repair to restore the P element at the donor site. The results also suggest a technique for site-directed mutagenesis in Drosophila.
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High levels of female and male sterility were observed among the hybrids from one of the two reciprocal crosses between a wild strain of D. melanogaster known as pi2 and laboratory strains. The sterility, which is part of a common syndrome called hybrid dysgenesis, was found to be associated with the rudimentary condition of one or both of the ovaries or testes. All other tissues, including those of the reproductive system were normal, as were longevity and mating behavior. The morphological details of the sterility closely mimic the agametic condition occurring when germ cells are destroyed by irradiation or by the maternal-effect mutation, grandchildless. We suggest that sterility in hybrid dysgenesis is also caused by failure in the early development of germ cells. There is a thermo-sensitive period beginning at approximately the time of initiation of mitosis among primordial germ cells a few hours before the egg hatches and ending during the early larval stages. Our results suggest that hybrid dysgenesis, which also includes male recombination, mutation and other traits, may be limited to the germ line, and that each of the primordial germ cells develops, or fails to develop, independently of the others. This hypothesis is consistent with the observed frequencies of unilateral and bilateral sterility, with the shape of the thermosensitivity curves and with the fact that males are less often sterile than females. The features of this intraspecific hybrid sterility are found to resemble those seen in some interspecific Drosophila hybrids, especially those from the cross D. melanogaster X D. simulans.
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A syndrome of germline abnormalities in Drosophila melanogaster called hybrid dysgenesis is thought to be caused by transposable genetic elements known as P factors. Several lines of evidence presented here show that the chromosomal positions of at least some P factors can be identified as points of frequent chromosome breakage (hotspots). Starting with a strain (pi 2) in which four hotspots had been identified on the X chromosome, we found individual hotspots vanished when their part of the chromosome was replaced by the homologous part from a strain known to lack P factors. All hotspots in the non-substituted parts of the chromosome remained functional, indicating that they can act autonomously. We also observed a new breakage site coinciding with the appearance of an unstable mutation at the singed bristle locus (snw). This mutation was dysgenesis- induced, and previous genetic evidence suggested that it was caused by the insertion of a P factor at that locus. We also present preliminary evidence for rapid scrambling of the positions of hotspots under certain conditions, and we describe a new procedure for efficiently determining the positions of hotspots on a given chromosome.
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We studied a collection of 746 chromosome rearrangements all induced by the activity of members of the P family of transposable elements in Drosophila melanogaster. The chromosomes ranged from simple inversions to complex rearrangements. The distribution of complex rearrangement classes was of the kind expected if each rearrangement came about from a single multibreak event followed by random rejoining of chromosome segments, as opposed to a series of two-break events. Most breakpoints occurred at or very near (within a few hundred nucleotide pairs) the sites of preexisting P elements, but these elements were often lost during the rearrangement event. There were also a few cases of apparent gain of P elements. In cases in which both breakpoints of an inversion retained P elements, that inversion was capable of reverting at high frequencies to the original sequence or something close to it. This reversion occurred with sufficient precision to restore the function of a gene, heldup- b, which had been mutated by the breakpoint. However, some of the reversions had acquired irregularities at the former breakpoints that were detectable either by standard cytology or by molecular methods. The revertants themselves retained the ability to undergo further rearrangements depending on the presence of P elements. We interpret these results to rule out the simplest hypotheses of rearrangement formation that involve cointegrate structures or homologous recombination. The data provide a general picture of the rearrangement process and its possible relationship to transposition.
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P element-induced chromosome breakage on the X chromosome of Drosophila melanogaster was repaired six times more frequently when a homologous template was located anywhere on the X rather than on an autosome. Cis-trans comparisons confirmed that recombinational repair was more frequent when the interacting sequences were physically connected. These results suggest that the search for homology between the broken ends and a matching template sequence occurs preferentially in the cis configuration. This cis advantage operates over more than 15 megabases of DNA.
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Transposable elements of the P family in Drosophila are thought to transpose by a cut-and-paste process that leaves a double-strand gap. The repair of such gaps resulted in the transfer of up to several kilobase pairs of information from a homologous template sequence to the site of P element excision by a process similar to gene conversion. The template was an in vitro-modified sequence which was tested at a variety of genomic positions. Characterization of 123 conversion tracts provided a detailed description of their length and distribution. Most events were continuous conversion tracts that overlapped the P insertion site without concomitant conversion of the template. The average conversion tract was 1379 base pairs, and the distribution of tract lengths fit a simple model of gap enlargement. The conversion events occurred at sufficiently high frequencies to form the basis of an efficient means of directed gene replacement.
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We describe here a family of P elements that we refer to as Type I repressors. These elements are identified by their repressor functions and their lack of any deletion within the first two-thirds of the cannonical P sequence. Elements belonging to this repressor class were isolated from P strains and were made in vitro. We found that Type I repressor elements could strongly repress both a cytotype-dependent allele and P element mobility in somatic and germline tissues. These effects were very dependent on genomic position. Moreover, we observed that an element's ability to repress in one assay positively correlated with its ability to repress in either of the other two assays. The Type I family of repressor elements includes both autonomous P elements and those lacking exon 3 of the P element. Fine structure deletion mapping showed that the minimal 3´ boundary of a functional Type I element lies between nucleotide position 1950 and 1956. None of 12 elements examined with more extreme deletions extending into exon 2 made repressor. We conclude that the Type I repressors form a structurally distinct group that does not include more extensively deleted repressors such as the KP element described previously.
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The transposase source
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It has previously been shown that the combination of two deleted P elements in trans, one containing the left functional end and the second element the right functional end, can lead to high levels of male recombination. This finding strongly suggests that P element ends from different chromosomes can become associated, followed by 'pseudo-excision',. We show that the structure formed from this excision event can be resolved in two ways: (1) the excised P element ends continue to function as a single unit (Hybrid Element) and insert at a nearby site in the chromosome or into the element itself (Hybrid Element Insertion - HEI), (2) free ends which may or may not contain P element ends repair and re-join (Hybrid Excision and Repair - HER). Both types of resolution can lead to recombination, and this paper concentrates on the HEI class. One type of HEI event predicts the exact reverse complementary duplication of an 8bp target site, and we have confirmed the existence of such a structure in a number of recombinant chromosomes. There is also a high tendency for insertion events to occur within a few bases of the original 8bp target site, including six apparent cases of insertion into the exact site. The results suggest that where insertion occurs close to an element, it is preferentially near the functional end of the element rather than the non-functional end.
(Accompanying papers by Preston & Engels, Preston, Sved & Engels)
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The genome of Drosophila bifasciata harbours two distinct subfamilies of P-homologous sequences, designated M-type and O-type elements based on similarities to P element sequences from other species. Both subfamilies have some general features in common: they are of similar length (M-type: 2935 bp, O-type: 2986 bp), are flanked by direct repeats of 8 bp (the presumptive target sequence), contain terminal inverted repeats, and have a coding region consisting of four exons. The splice sites are at homologous positions and the exons have the coding capacity for proteins of 753 amino acids (M-type) and 757 amino acids (O-type). It seems likely that both types of element represent functional transposons. The nucleotide divergence of the two P element subfamilies is high (31%). The main structural difference is observed in the terminal inverted repeats. Whereas the termini of M-type elements consists of 31 bp inverted repeats, the inverted repeats of the O-type elements are interrupted by non- complementary stretches of DNA, 12 bp at the 5' end and 14 bp at the 3' end. This peculiarity is shared by all members of the O-type subfamily. Comparison with other P element sequences indicates incongruities between the phylogenies of the species and the P transposons. M-type and O-type elements apparently have no common origin in the D. bifasciata lineage. The M-type sequence seems to be most closely related to the P element from Scaptomyza pallida and thus could be considered as a more recent invader of the D. bifasciata gene pool. The origin of the O-type elements cannot be unequivocally deduced from the present data.(ABSTRACT TRUNCATED AT 250 WORDS)
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A transient in vivo P element excision assay was used to test the regulatory properties of putative repressor-encoding plasmids in Drosophila melanogaster embryos. The somatic expression of an unmodified transposase transcription unit under the control of a heat shock gene promoter (phs pi) effectively repressed P excision in a dose-dependent manner at very low concentrations relative to somatically active transposase (encoded by the hs pi
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We studied the process by which whd, a P element insertion allele of the Drosophila white locus, is replaced by its homolog in the presence of transposase. These events are interpreted as the result of double-strand gap repair following excision of the P transposon in whd. As templates for this repair we used a series of alleles derived from whd through P element mobility. One group of them, referred to collectively as whd-F, carried fragments of the P element that had lost some of the sequences needed in cis for mobility. The other group, whd-D, had lost all of the P insert and carried a deletion of some of the flanking DNA from white. The average replacement frequency was 43% for whd-F alleles and 7% for the whd-D alleles. Some of the former were converted at frequencies exceeding 50%. Our data suggest that the high conversion frequencies for the whd-F templates can be attributed at least in part to an elevated efficiency of repair of unexpanded gaps, possibly due to the closer match between whd-F sequences and the unexpanded gap endpoints. In addition, we found that the gene substitutions were almost exclusively in the direction of whd being replaced by the whd-F or whd-D allele rather than the reverse. The template alleles were usually unaltered in the process. This asymmetry implies that the conversion process is unidirectional and that the P fragments are not good substrates for P element transposase. Our results help elucidate a highly efficient double-strand gap repair mechanism in Drosophila that can also be used for gene replacement procedures involving insertions and deletions. They also help explain the rapid spread of P elements in populations.
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Vectors derived from the Drosophila P element transposon are widely used to make transgenic Drosophila. Insertion of most P-element- derived vectors is nonrandom, but they exhibit a broad specificity of target sites. During experiments to identify cis-acting regulatory elements of the Drosophila segmentation gene engrailed, we identified a fragment of engrailed DNA that, when included within a P-element vector, strikingly alters the specificity of target sites. P-element vectors that contain this fragment of engrailed regulatory DNA insert at a high frequency near genes expressed in stripes.
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Mobility of P transposable elements in Drosophila melanogaster depends on the 87-kDa transposase protein encoded by the P element. Transposase recognizes a 10-base-pair DNA sequence that overlaps an A + T-rich region essential for transcription from the P-element promoter. We report here that transposase represses transcription from the P-element promoter in vitro. This transcriptional repression is blocked by prior formation of an RNA polymerase II transcription complex on the template DNA. Binding of transposase on the P-element promoter is blocked by prior binding of either the Drosophila RNA polymerase II complex or the yeast transcription factor TFIID. These data suggest that transposase represses transcription by preventing assembly of an RNA polymerase II complex at the P-element promoter.
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We have developed an in vitro reaction system for Drosophila P element transposition. Transposition products were recovered by selection in E. coli, and contained simple P element insertions flanked by 8 bp target site duplications as observed in vivo. Transposition required Mg+2 and partially purified P element transposase. Unlike other DNA rearrangement reactions, P element transposition in vitro used GTP as a cofactor; deoxyGTP, dideoxyGTP, or the nonhydrolyzable GTP analogs GMP-PNP or GMP-PCP were also used. Transposon DNA molecules cleaved at the P element termini were able to transpose, but those lacking 3'-hydroxyl groups were inactive. These biochemical data are consistent with genetic data suggesting that P element transposition occurs via a "cut-and-paste" mechanism.
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P element induced gene conversion has been previously used to modify the white gene of Drosophila in a directed fashion. The applicability of this approach of gene targeting in Drosophila, however, has not been analyzed quantitatively for other genes. We took advantage of the P-induced forked allele, fhd, which was used as a target , and we constructed a vector containing a modified forked fragment for converting fhd. Conversion frequencies were analyzed for this locus as well as for an alternative white allele, weh812. Combination of both P induced mutant genes allowed the simultaneous analysis of conversion frequencies under identical genetic, developmental and environmental conditions. This paper demonstrates that gene conversion through P-induced gap repair can be applied with similar success-rates at the forked locus as at the white gene. The average conversion frequencies at forked were 0.29% and at white 0.16%. These frequencies indicate that in vivo gene targeting in Drosophila should be applicable for other genes in this species at managable rates. A different experiment revealed evidence that may indicate that a protein (Su(Hw)), which imparts control on chromatin-condensation, may interfere with the gap repair process.
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The transposition of P elements in Drosophila melanogaster is regulated by products encoded by the P elements themselves. The molecular mechanisms of this regulation are complex and still unclear. We have assayed in vivo the effects of P regulatory products on the P promoter itself by using P-lacZ fusion genes. We have found that all the P-lacZ insertions are repressed in a P background. This repression occurs in all the tissues observed and at all the developmental stages. The amount of transcripts specific for P-lacZ is substantially reduced in a P background. These results suggest that P trans-acting products can exert a direct repression on the P promoter transcription.
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The transposition of P elements in Drosophila melanogaster is regulated by products encoded by the P elements themselves. The P cytotype, which represses transposition and associated phenomena, exhibits both a maternal effect and maternal inheritance. The genetic and molecular mechanisms of this regulation are complex and not yet fully understood. In a previous study, using P-lacZ fusion genes, we have shown that P element regulatory products were able to inhibit the activity of the P promoter in somatic tissues. However, the repression observed did not exhibit the maternal effect characteristic of the P cytotype. With a similar approach, we have assayed in vivo the effect of P element regulatory products in the germline. We show that the P cytotype is able to repress the P promoter in the germline as well as in the soma. Furthermore, this repression exhibits a maternal effect restricted to the germline. On the basis of these new observations, we propose a model for the mechanism of P cytotype repression and its maternal inheritance.
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Transposable elements may be potential tools for the dispersal of engineered DNA through target insect populations. The utility of this hypothesis is predicted on the ability of transposable elements carrying a large DNA insert to rapidly disperse through a population. In addition, the inserted DNA must be replicated with a high degree of fidelity during this dispersal. We have monitored the ability of a transposable element with an inserted gene to spread through experimental populations and tested whether the passenger gene retains its ability to encode an active protein. Several Drosophila melanogaster laboratory populations were initiated with female flies that were null for alcohol dehydrogenase activity and contained no P elements. Most of the females were mated to males of the same strain; however, 1 or 10% of the females were mated to males from a strain that had previously been transformed with a helper P element and a P element/Adh gene construct. The dispersal of P elements to new genomes was monitored at each generation by randomly selecting females and performing DNA hybridization assays on dissected ovarian tissue. In addition, each female was tested for alcohol dehydrogenase activity using a simple histochemical assay. We find that, despite an approximate threefold increase in size, the P element constructs containing a functioning gene are still capable of rapid dispersal through the experimental populations. We also show that many of the inserted Adh genes still encode an active product.
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P element transposition in Drosophila is controlled by the cytotype regulatory state: in P cytotype, transposition is repressed, whereas in M cytotype, transposition can occur. P cytotype is determined by a combination of maternally inherited factors and chromosomal P elements in the zygote. Transformant strains containing single elements that encoded the 66-kD P element protein zygotically repressed transposition, but did not display the maternal repression characteristic of P cytotype. Upon mobilization to new genomic positions, some of these repressor elements showed significant maternal repression of transposition in genetic assays, involving a true maternal effect. Thus, the genomic position of repressor elements can determine the maternal vs. zygotic inheritance of P cytotype. Immunoblotting experiments indicate that this genomic position effect does not operate solely by controlling the expression level of the 66-kD repressor protein during oogenesis. Likewise, P element derivatives containing the hsp26 maternal regulator sequence expressed high levels of the 66-kD protein during oogenesis, but showed no detectable maternal repression. These data suggest that the location of a repressor element in the genome may determine maternal inheritance of P cytotype by a mechanism involving more than the overall level of expression of the 66-kD protein in the ovary.
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We used P transposable element mobilization to study the repair of double-strand DNA breaks in Drosophila melanogaster premeiotic germ cells. The distribution of conversion tracts was found to be largely unaffected by changes in the length of sequence homology between the broken ends and the template, suggesting that only a short match is required. However, the frequency of repair was highly sensitive to single-base mismatches within the homologous region, ranging from 19% reversion when there were no mismatches to 5% when 15 mismatches were present over a 3455 base-pair span.
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P element-induced gap repair was used to copy nonhomologous DNA into the Drosophila white locus. We found that nearly 8000 base pairs of nonhomologous sequence could be copied in from an ectopic template at essentially the same rate as a single base substitution at the same location. An in vitro-constructed deletion was also copied into white at high frequencies. This procedure can be applied to the study of gene expression in Drosophila, especially for genes too large to be manipulated in other ways. We also observed several types of more complex events in which the copied template sequences were rearranged such that the breakpoints occurred at direct duplications. Most of these can be explained by a model of double strand break repair in which each terminus of the break invades a template independently and serves as a primer for DNA synthesis from it, yielding two overlapping single-stranded sequences. These single strands then pair, and synthesis is completed by each using the other as template. This synthesis-dependent strand annealing (SDSA) model is discussed as a possible general mechanism in complex organisms.
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The frequency of P element excision and the structure of the resulting excision products were determined in three drosophilid species. Drosophila melanogaster, D. virilis, and Chymomyza procnemis. A transient P element mobility assay was conducted in the cells of developing insect embryos, but unlike previous assays, this mobility assay permitted the recovery of excision products from plasmids regardless of whether the excision event was precise or imprecise. Both quantitative and qualitative differences between the products of excision in the various species studied were observed. The frequency with which P element excision products were recovered from D. melanogaster was 10-fold greater than from D. virilis and C. procnemis; however, the proportion of all excision events resulting in the reversion of a P-induced mutant phenotype was the same. Virtually all excision products recovered, including those resulting in a reversion of the mutant phenotype, did not result in the exact restoration of the original target sequence. Sequence analysis suggested that duplex cleavage at the 3' and 5' termini of the P element, or their subsequent modification, occurred asymmetrically and interdependently. P element-encoded transposase was not absolutely required for P element excision.
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We have isolated and characterized several members of the P transposable element family from a Drosophila melanogaster P strain. Large 2.9 kb elements are present as multiple highly conserved copies together with smaller (0.5-1.6 kb), heterogeneous elements. The complete DNA sequences of the 2.9 kb element and four small elements (previously isolated from hybrid-dysgenesis-induced mutations of the white locus) have been determined. Each small element appears to have arisen from the 2.9 kb element by a different internal deletion. P elements have 31 bp perfect inverse terminal repeats and upon insertion duplicate an 8 bp sequence found only once at the site of insertion. Three of the insertions into the white locus occurred at the same nucleotide, indicating a high degree of local site specificity for insertion. The basis of this specificity has been investigated by DNA sequence analysis of the sites where 18 P elements are found. A revertant of one of the white locus mutants has been found to result from precise excision of the P element, restoring the wild-type DNA sequence.
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We observed unusual kinds of rearrangements within tandemly clustered 5S genes internal to a P element in dysgenic context. Rearranged P transposons, initially containing eight 5S genes, were found to display discrete numbers of 5S genes, from 4 up to 17 units. Precise deletions and amplifications occurred at a high rate (40%), at both original and new insertion sites. These events can be explained by a "cut and paste" transposition model. Possible links between rearrangements due to dysgenic-like processes and concerted evolution are discussed.
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Several P homologous sequences have been cloned and sequenced from Drosophila subobscura. These sequences are located at the 85DE region of the O chromosome and at least three of them are organized in tandem. We have identified four copies which exhibit strong similarity between them. All of the isolated elements are truncated at the 5' and 3' ends. They have lost the inverted terminal repeats and exon 3, but maintain exons 0, 1 and 2. They are transcribed producing a polyadenylated RNA. The structure of these transcripts suggests that they are able to encode a 66 kd repressor-like protein, but not a functional transposase. We ask about the biological role of a potential repressor protein in this species.
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We have cloned two DNA elements (Lu-P1 and Lu-P2) from the Australian sheep blowfly Lucilia cuprina that are similar to the transposable P element of Drosophila melanogaster in both structure and sequence but have diverged from it and from each other considerably. Hybridization studies indicate that a third related element probably exists in another, as yet unsequenced, clone. Neither Lu-P1 nor Lu-P2 appears to be active in terms of mobility, and it is not known whether any transposition-competent copies of other related elements occur in the genome of the blowfly. However, the isolation of any P-like sequences from a species outside of the family Drosophilidae allows comparisons to be made of more widely divergent P-related elements than has been possible previously. We are unaware of any report of the presence of multiple P-like family members within a single species. The discovery of Lu-P1 and Lu-P2 in the blowfly fuels the possibility that similar elements may be widespread in insects, and perhaps in other orders of animals.
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The invasion of the Drosophila melanogaster genome by members of the P family of transposable elements was monitored by in situ hybridization to polytene chromosomes. Populations consisted of inbred lines starting with a single element. There were several cases of very rapid proliferation of element copy numbers, going from a single copy to more than twenty in the span of a few generations. These episodes, which occurred during periods of intense inbreeding and usually led to extinction of the stock, were preceded by 6-20 generations during which the copy number remained at one. In other cases, the founding P element was lost before any proliferation could occur, and in still others the stock gradually developed the "P cytotype" in which P element mobility is suppressed. Finally, there was one transposase-producing P element that appeared to be stable or nearly so. Possible explanations for this behavior and implications for natural populations are discussed.
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A P element insertion flanked by 13 RFLP marker sites was used to examine male recombination and gene conversion at an autosomal site. The great majority of crossovers on chromosome arm 2R occurred within the 4-kb region containing the P element and RFLP sites. Of the 128 recombinants analyzed, approximately two-thirds carried duplications or deletions flanking the P element. These rearrangements are described in more detail in the accompanying report. In a parallel experiment, we examined 91 gene conversion tracts resulting from excision of the same autosomal P element. We found the average tract length was 1463 bp, which is essentially the same as found previously at the white locus. The distribution of conversion tract endpoints was indistinguishable from the distribution of crossover points among the non rearranged male recombinants. Most recombination events can be explained by the "hybrid element insertion" model, but, for those lacking a duplication or deletion, a second step involving double strand gap repair must be postulated to explain the distribution of crossover points.
(Accompanying papers by Gray, Tanaka & Sved, and Preston, Sved & Engels)
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We studied P element-induced recombination in germline mitotic cells by examining the structure of the recombinant chromosomes. We found that most recombinants retain a mobile P element at the site of the recombination, usually with either a deletion or a duplication immediately adjacent to the P end at which the crossover occurred. The sizes of these deletions and duplications ranged from a few base pairs to well over 100 kb. These structures fit the "hybrid element insertion" (HEI) model of male recombination in which the two P element copies on sister chromatids combine to form a "hybrid element" whose termini insert into a nearby position on the homolog. The data suggest that P-induced recombination can be used as an efficient means of generating flanking deletions in the vicinity of existing P elements. These deletions are easily screened using distant flanking markers, and they can be chosen to extend in a given direction depending on which reciprocal recombinant type is selected. Furthermore, the retention of a mobile P element allows one to extend the deletion or generate additional variability at the site by subsequent rounds of recombination.
(Accompanying papers by Gray, Tanaka & Sved, and Preston & Engels)
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Individual P elements that were genetically isolated from wild-type strains were tested for their abilities to repress two aspects of hybrid dysgenesis: gonadal dysgenesis and mutability of a double-P element-insertion allele of the singed locus (snw). These elements were also characterized by Southern blotting, polymerase chain reaction amplification and DNA sequencing. Three of the elements were 1.1-kb KP elements, one was a 1.2-kb element called D50, and one was a 0.5-kb element called SP. These three types of elements could encode polypeptides of 207, 204, and 14 amino acids, respectively. Gonadal dysgenesis was repressed by two of the KP elements (denoted KP(1) and KP(6)) and by SP, but not by the third KP element (KP(D)), nor by D50. Repression of gonadal dysgenesis was mediated by a maternal effect, or by a combination of zygotic and maternal effects generated by the P elements themselves. The mutability of snw was repressed by the KP(1) and KP(6) elements, by D50 and by SP, but not by KP(D); however, the SP element repressed snw mutability only when the transposase came from complete P elements and the D50 element repressed it only when the transposase came from the modified P element known as
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The ability to repress P-element-induced gonadal dysgenesis was studied in 14 wild-type strains of D. melanogaster derived from populations in the central and eastern United States. Females from each of these strains had a high ability to repress gonadal dysgenesis in their daughters. Reciprocal hybrids produced by crossing each of the wild-type strains with an M strain demonstrated that repression ability was determined by a complex mixture of chromosomal and cytoplasmic factors. Cytoplasmic transmission of repression ability was observed in all 14 strains and chromosomal transmission was observed in 12 of them. Genomic Southern blots indicated that four of the strains possessed a particular type of P element, called KP, which has been proposed to account for the chromosomal transmission of repression ability. However, in this study several of the strains that lacked KP elements exhibited as much chromosomal transmission of repression ability as the strains that had KP elements, suggesting that other kinds of P elements may be involved.
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The mariner transposable element is a small member of the short inverted terminal repeat class thought to transpose through a DNA intermediate. Originally described in Drosophila mauritiana, it is now known in several species of the family Drosophilidae, and in a moth Hyalophora cecropia. Here I use primers designed to represent regions of amino-acid conservation between the putative transposase genes of the D. mauritiana and H. cecropia elements to amplify equivalent regions of presumed mariner elements from ten other insects representing six additional orders, including the malaria- vector mosquito, Anopheles gambiae. Sequences of multiple clones from each species reveal a diverse array of mariner elements, with multiple subfamilies in the genomes of some insects, indicating both vertical inheritance and horizontal transfers. An intact open reading frame in at least one clone from each species suggests each may carry functional transposable elements. Therefore the mariner element is an excellent candidate for development of genetic transformation systems for non-drosophilid insects, and possibly other arthropods.
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Activity of the P family of transposable elements in Drosophila melanogaster is regulated primarily by a cellular condition known as P cytotype. It has been hypothesized that P cytotype depends on a P element-encoded repressor of transposition and excision. We provide evidence in support of this idea by showing that two modified P elements, each with lesions affecting the fourth transposase exon, mimic most of the P cytotype effects. These elements were identified by means of two sensitive assays capable of detecting repression by a single P element. One assay makes use of cytotype-dependent gene expression of certain P element insertion mutations at the singed bristle locus. The other measures suppression of transposase activity from the unusually stable genomic P element,
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A single P element insert in Drosophila melanogaster, called P[ry+
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Two P elements, inserted at the cytological site 1A on an X chromosome from an Drosophila melanogaster natural population (Lerik, USSR), were isolated by genetic methods to determine if they are sufficient to cause the P cytotype, the cellular condition that regulates the P family of transposable element. The resulting "Lerik P(1A)" line (abbreviated "Lk-P(1A)") carries only one P element in situ hybridization site but genomic Southern analysis indicates that this site contains two, probably full length, P copies separated by at least one EcoRI cleavage site. Because the Lk-P(1A) line shows some transposase activity, at least one of these two P elements is autonomous. The Lk-P(1A) line fully represses germline P element activity as judged by the GD sterility and snw hypermutability assays; this result shows that the P cytotype can be elicited by only two P element copies. However, the Lk-P(1A) line does not fully repress
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In Drosophila melanogaster, transposition of the P element is under the control of a cellular state known as cytotype. The P cytotype represses P transposition whereas the M cytotype is permissive for transposition. In the long-term, the P cytotype is determined by chromosomal P elements but over a small number of generations it is maternally inherited. In order to analyse the nature of this maternal inheritance, we tested whether a maternal component can be transmitted without chromosomal P elements. We used a stable determinant of P cytotype, linked to the presence of two P elements at the tip of the X chromosome (1A site) in a genome devoid of other P elements. We measured P repression capacity using two different assays: gonadal dysgenic sterility (GD) and P-lacZ transgene repression. We show that zygotes derived from a P cytotype female (heterozygous for P (1A)/balancer devoid of P copies) and which inherit no chromosomal P elements from the mother, have, however, maternally received a P-type extra-chromosomal component: this component is insufficient to specify the P cytotype if the zygote formed does not carry chromosomal P elements but can promote P cytotype determination if regulatory P elements have been introduced paternally. We refer to this strictly extra-chromosomally inherited state as the "pre-P cytotype". In addition, we show that a zygote that has the pre-P cytotype but which has not inherited any chromosomal P elements, does not transmit the pre-P cytotype to the following generation. The nature of the molecular determinants of the pre-P cytotype is discussed.
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We have constructed six new P-element-based Drosophila melanogaster transformation vectors that specifically allow for the high-level accumulation of any RNA of interest in the developing egg and pre- blastoderm embryo. Such specificity results, in part, from the inclusion in the vectors of an enhancer active exclusively in nurse cells, the principal providers of RNA to the egg and early embryo. The nurse cell enhancer was derived from the hsp26 heat-shock (HS) gene, but its activity was neither dependent on nor sensitive to HS. In addition to the nurse cell enhancer, two of the vectors contain sequences from the K10 gene that promote the early transfer of RNAs from nurse cells into the oocyte; RNAs that contain the K10 sequence are transferred into the oocyte during the early to middle stages of oogenesis (i.e., during stages 2-9), while RNAs that lack such sequences are stored in nurse cells until stage 11. All of the vectors contain a tsp and a multiple cloning site (MCS) immediately downstream from the hsp26 nurse cell enhancer. In three of the vectors, the MCS is preceded by an ATG start codon. A wild-type copy of the white gene is included in all of the vectors as a selectable marker for transformation. The specificity of the vectors was demonstrated by the analysis of the expression patterns of lacZ derivatives.
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Several results suggest that P elements have recently invaded natural populations of Drosophila melanogaster after a horizontal transfer from another species. The donor species is thought to come from the willistoni group, which contains P elements very homologous to those of D. melanogaster. However, more divergent P elements are present in many other Drosophilidae species. We have analyzed such elements from Scaptomyza pallida, a species phylogenetically distant to D. melanogaster. We report here the isolation of two coding P elements from S. pallida (PS2 and PS18) that are 4% divergent from one another. At least one of these elements (PS18) is active since it is able to transpose in D. melanogaster and to mobilize a D. melanogaster defective P element, even though its nucleotide sequence is 24% divergent from the canonical P element of D. melanogaster. To our knowledge, a P element that is active and strongly divergent from the D. melanogaster P element has not been reported previously. Sequence comparison between the complete P elements of D. melanogaster and S. pallida reveals that the structural characteristics are maintained: PS2 and PS18 contain terminal inverted repeats and internal repeats very similar to those of the D. melanogaster P element. In addition, the noncoding regions cis necessary for the transposition are more conserved than the coding sequences. Two domains found in the D. melanogaster P transposase (helix-turn-helix and leucine zipper) are well conserved in the putative proteins encoded by PS2 and PS18. This study provides insights into which parts of P elements are functionally important and correlates with functional studies of the P element in D. melanogaster.
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The vestigial gene (vg+) is required for normal wing development and is expressed in a spatially distinct pattern in imaginal discs. We have exploited a general property of P element alleles to target an enhancer trap to the 5' region of the gene. By replacing the P element resident at this site in vg21 with a P element carrying a lacZ reporter gene, the vglacZ1 allele was selected on the basis of its increased mutant phenotype. In contrast to vg+ expression, which occurs primarily in the presumptive wing margin and hinge, beta- galactosidase expression in vglacZ1 wing discs is localized to the dorsal wing surface and displays homologous haltere expression. The targeting of P element enhancer traps could be readily extended to other genes with low rates of primary P element insertion.
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P element transposons in Drosophila melanogaster are capable of mobilizing incomplete P elements elsewhere in the genome, and of inducing recombination. This recombination is usually only of the order of 1% or less. We show that two P elements, located at exactly homologous sites, induce levels of recombination of 20% or higher. The recombination appears to be exact, as determined by the lack of phenotypic effects in recombinant products and the lack of size changes detectable by Southern hybridization. Female recombination is increased, but to a lesser extent than male recombination. Somatic recombination levels are also elevated. Alternative explanations for the high recombination levels are given in terms of the consequences of repair of an excision site and in terms of recombination as part of the replicative transposition process.
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The P element insertion
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We have previously established a transgenic Drosophila line with a highly transposable P element insertion. Using this strain we analyzed transposition and excision of the P element at the molecular level. We examined sequences flanking the new insertion sites and those of the remnants after excision. Our results on mobilization of the P element demonstrate that target-site duplication at the original insertion site does not play a role in forward excision and transposition. After P element excision an 8 bp target-site duplication and part of the 31 bp terminal inverted repeat (5-18 bp) remained in all the strains examined. Moreover, in 11 out of 28 strains, extra sequences were found between the two remaining inverted repeats. The double-strand gap repair model does not explain the origin of these extra sequences. The mechanism creating them may be similar to the hairpin model proposed for the transposon Tam in Antirrhinum majus.
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Two different schemes were used to demonstrate that Drosophila P elements preferentially transpose into genomic regions close to their starting sites. A starting element with weak rosy+ marker gene expression was mobilized from its location in the subtelomeric region of the 1,300-kb Dp1187 minichromosome. Among progeny lines with altered rosy+ expression, a much higher than expected frequency contained new insertions on Dp1187. Terminal deficiencies were also recovered frequently. In a second screen, a rosy(+)-marked element causing a lethal mutation of the cactus gene was mobilized in male and female germlines, and viable revertant chromosomes were recovered that still contained a rosy+ gene due to an intrachromosomal transposition. New transpositions recovered using both methods were mapped between 0 and 128 kb from the starting site. Our results suggested that some mechanism elevates the frequency 43-67-fold with which a P element inserts near its starting site. Local transposition is likely to be useful for enhancing the rate of insertional mutation within predetermined regions of the genome.
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P element transposition in Drosophila melanogaster is regulated by germline-specific splicing of the P element ORF2-ORF3 intron. This regulation has been shown to depend on a cis-acting sequence located in the exon 12-31 bases from the 5' splice site. Mutations within this sequence disrupt the regulation and result in splicing of the ORF2-ORF3 intron in all tissues, indicating that the sequence is required to inhibit splicing of this intron in the soma. We now show that a trans-acting factor in a human (HeLa) cell extract can inhibit splicing of the intron, suggesting that this regulatory mechanism is conserved from flies to humans.
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In hybrid dysgenesis, sterility can occur in both males and females. At 27.5 degrees, however, we found that P element-induced germline death was restricted to females. This sex-specific gonadal dysgenesis (GD) is complete by the first larval instar stage. As such, GD at 27.5 degrees reveals the sexually dimorphic character of the embryonic germline. The only other known dimorphic trait of the embryonic germline is the requirement for ovo. ovo is required for germline development in females only and has been implicated in germline sex determination. Dominant mutations of ovo partially suppressed female GD. Although embryonic germ cells are undifferentiated and morphologically indistinguishable between males and females, the functional dimorphism seen in ovo requirement and GD at 27.5 degrees indicates that sexual identity in Drosophila germ cells is established in embryogenesis.
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The vestigial (vg) locus of Drosophila melanogaster is involved in wing margin development. In the absence of a vg+ gene, extensive cell death occurs in third instar imaginal discs which results in a complete loss of adult wing margin structures. P-element tagging was used to obtain a molecular clone of the vg locus, which led to the molecular characterization of approximately 46 kb of DNA from the region. Deficiency analysis and molecular mapping identified sequences, spanning approximately 20 kb of DNA within the larger region, which are necessary for vg function. The molecular map was oriented with respect to a pre-existing genetic fine structure map of the locus. The centromere distal limits of the locus were defined by deficiency analyses while the proximal end has not yet been conclusively established. However, three transcripts, that are apparently unrelated to vg, provide circumstantial evidence for the proximal limits of the vg locus. The nature of the molecular lesions for several extant recessive or lethal vg alleles was determined, and these were placed on the vg molecular map. The characterization of the lesions associated with two dominant vg alleles and one complex vg allele imply interesting regulatory mechanisms for this locus. As well, a revertant of a 412 insertion mutant allele was shown to have resulted from a further insertion of a roo element into the 412 element.
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We have constructed a series of strains to facilitate the generation and analysis of clones of genetically distinct cells in developing and adult tissues of Drosophila. Each of these strains carries an FRT element, the target for the yeast FLP recombinase, near the base of a major chromosome arm, as well as a gratuitous cell-autonomous marker. Novel markers that carry epitope tags and that are localized to either the cell nucleus or cell membrane have been generated. As a demonstration of how these strains can be used to study a particular gene, we have analyzed the developmental role of the Drosophila EGF receptor homolog. Moreover, we have shown that these strains can be utilized to identify new mutations in mosaic animals in an efficient and unbiased way, thereby providing an unprecedented opportunity to perform systematic genetic screens for mutations affecting many biological processes.
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