Genetic Instability in Drosophila Melanogaster Mediated by Hobo Transposable Elements

Eight independent recessive lethal mutations that occurred on derivatives of an unstable X chromosome (Uc) in Drosophila melanogaster were analyzed by a combination of genetic and molecular techniques. Seven of the mutations were localized to complementation groups in polytene chromosome bands 6E; 7A. In situ hybridization and genomic Southern analysis established that hobo transposable elements were associated with all seven of the mutations. Six mutations involved deletions of DNA, some of which were large enough to be seen cytologically, and in each case, a hobo element was inserted at the junction of the deletion's breakpoints. A seventh mutation was associated with a small inversion between 6F and 7A-B and a hobo element was inserted at one of its breakpoints. One of the mutant chromosomes had an active hobo-mediated instability, manifested by the recurrent production of mutations of the carmine (cm) locus in bands 6E5-6. This instability persisted for many generations in several sublines of an inbred stock. Two levels of instability, high and basal, were distinguished. Sublines with high instability had two hobo elements in the 6E-F region and produced cm mutations by deleting the segment between the two hobos; a single hobo element remained at the junction of the deletion breakpoints. Sublines with low instability had only one hobo element in the 6E-F region, but they also produced deletion mutations of cm. Both types of sublines also acquired hobo-mediated inversions on the X chromosome. Collectively, these results suggest that interactions between hobo elements are responsible for the instability of Uc. It is proposed that interactions between widely separated elements produce gross rearrangements that restructure the chromosome and that interactions between nearby elements cause regional instabilities manifested by the recurrence of specific mutations. These regional instabilities may arise when a copy of hobo transposes a short distance, creating a pair of hobos that can interact to produce small rearrangements.     

Wanderings of Hobo: A Transposon in Drosophila Melanogaster and its Close Relatives

The transposon hobo is present in the genomes of Drosophila melanogaster and Drosophila simulans (and D. mauritiana and probably D. sechellia, based on Southern blots) as full-size elements and internally deleted copies. The full-size melanogaster, simulans and mauritiana hobo elements are 99.9% identical at the DNA sequence level, and internally deleted copies in these species essentially differ only in having deletions. In addition to these, hobo-related sequences are present and detectable with a hobo probe in all these species. Those in D. melanogaster are 86-94% identical to the canonical hobo, but with many indels. We have sequenced one that appears to be inserted in heterochromatin (GenBank Acc. No. AF520587). It is 87.6% identical to the canonical hobo, but quite fragmented by indels, with remnants of other transposons inserted in and near it, and clearly is defunct. Numerous similar elements are found in the sequenced D. melanogaster genome. It has recently been shown that some are fixed in the euchromatic genome, but it is probable that still more reside in heterochromatic regions not included in the D. melanogaster genome database. They are probably all relics of an earlier introduction of hobo into the ancestral species. There appear to have been a minimum of two introductions of hobo into the melanogaster subgroup, and more likely three, two ancient and one quite recent. The recent introduction of hobo was probably followed by transfers between the extant species (whether 'horizontally' or by infrequent interspecific hybridization).     

S Elements: A Family of Tc1-like Transposons in the Genome of Drosophila Melanogaster

The S elements form a diverse family of long-inverted-repeat transposons within the genome of Drosophila melanogaster. These elements vary in size and sequence, the longest consisting of 1736 bp with 234-bp inverted terminal repeats. The longest open reading frame in an intact S element could encode a 345-amino acid polypeptide. This polypeptide is homologous to the transposases of the mariner-Tc1 superfamily of transposable elements. S elements are ubiquitous in D. melanogaster populations and also appear to be present in the genomes of two sibling species; however, they seem to be absent from 17 other Drosophila species that were examined. Within D. melanogaster strains, there are, on average, 37.4 cytologically detectable S elements per diploid genome. These elements are scattered throughout the chromosomes, but several sites in both the euchromatin and β heterochromatin are consistently occupied. The discovery of an S-element-insertion mutation and a reversion of this mutation indicates that S elements are at least occasionally mobile in the D. melanogaster genome. These elements seem to insert at an AT dinucleotide within a short palindrome and apparently duplicate that dinucleotide upon insertion.     

The P-M and the 23.5 Mrf (Hobo) Systems of Hybrid Dysgenesis in Drosophila Melanogaster Are Independent of Each Other

Strains of Drosophila melanogaster bearing the male recombination factor 23.5 MRF induce hybrid dysgenesis in a way which is highly reminiscent of the P-M system, and, most probably, causally related to the activity of the transposable element hobo. We have investigated potential interactions between the two systems of hybrid dysgenesis by studying mixed lines derived from bidirectional crosses between 23.5 MRF and P strains, and analyzed their potentials to induce or suppress the occurrence of dysgenesis. All new lines possess the P induction abilities, as determined by two different procedures, and have also acquired a P cytotype. In contrast, some of them lost their ability to induce the non-P-M dysgenesis, as well as to suppress the action of 23.5 MRF. This loss of the 23.5 MRF induction abilities parallels the selective loss of full-length hobo elements from the genome of these lines, providing further substantiation to the notion that the 23.5 MRF activity is directly linked to this transposable element.     

Polygenic Mutation in Drosophila Melanogaster: Estimates from Response to Selection of Inbred Strains

Replicated divergent artificial selection for abdominal and sternopleural bristle number from a highly inbred strain of Drosophila melanogaster resulted in an average divergence after 125 generations of selection of 12.0 abdominal and 8.2 sternopleural bristles from the accumulation of new mutations affecting bristle number. Responses to selection were highly asymmetrical, with greater responses for low abdominal and high sternopleural bristle numbers. Estimates of V(M), the mutational variance arising per generation, based on the infinitesimal model and averaged over the responses to the first 25 generations of selection, were 4.32 X 10(-3) V(E) for abdominal bristle number and 3.66 X 10(-3) V(E) for sternopleural bristle number, where V(E) is the environmental variance. Based on 10 generations of divergent selection within lines from generation 93, V(M) for abdominal bristle number was 6.75 X 10(-3) V(E) and for sternopleural bristle number was 5.31 X 10(-3) V(E). However, estimates of V(M) using the entire 125 generations of response to selection were lower and generally did not fit the infinitesimal model largely because the observed decelerating responses were not compatible with the predicted increasing genetic variance over time. These decelerating responses, periods of response in the opposite direction to artificial selection, and rapid responses to reverse selection all suggest new mutations affecting bristle number on average have deleterious effects on fitness. Commonly observed periods of accelerated responses followed by long periods of stasis suggest a leptokurtic distribution of mutational effects for bristles.     

Interaction of the Stubble-Stubbloid Locus and the Broad-Complex of Drosophila Melanogaster

The 2B5 region on the X chromosome of Drosophila melanogaster forms an early ecdysone puff at the end of the third instar. The region is coextensive with a complex genetic locus, the Broad-Complex (BR-C). The BR-C is a regulatory gene that contains two major functional domains, the br domain and the l(1)2Bc domain. BR-C mutants prevent metamorphosis, including morphogenesis of imaginal discs; br mutants prevent elongation and eversion of appendages and l(1)2Bc mutants prevent fusion of the discs. The Stubble-stubbloid (Sb-sbd) locus at 89B9-10 is best known for the effects of its mutants on bristle structure. Mutants of the BR-C and the Sb-sbd locus interact to produce severe malformation of appendages. Viable heteroallelic and homoallelic combinations of Sb-sbd mutants, including loss-of-function mutants, affect the elongation of imaginal disc appendages. Thus, the Sb-sbd(+) product is essential for normal appendage elongation. Sb-sbd mutants, however, do not affect eversion or fusion of discs. Correspondingly, only BR-C mutants deficient in br function interact with Sb-sbd mutants. The interaction occurs in deficiency heterozygotes using single, wild-type doses of the BR-C, of the Sb-sbd locus, or of both loci. These last results are formally consistent with the possibility that the BR-C acts as a positive regulator of the Sb-sbd locus. The data do not exclude other possible nonregulatory interactions between the two loci, e.g., interactions between the products of both genes.     

Hobo Enhancer Trapping Mutagenesis in Drosophila Reveals an Insertion Specificity Different from P Elements

P element enhancer trapping has become an indispensable tool in the analysis of the Drosophila melanogaster genome. However, there is great variation in the mutability of loci by these elements such that some loci are relatively refractory to insertion. We have developed the hobo transposable element for use in enhancer trapping and we describe the results of a hobo enhancer trap screen. In addition, we present evidence that a hobo enhancer trap element has a pattern of insertion into the genome that is different from the distribution of P elements in the available database. Hence, hobo insertion may facilitate access to genes resistant to P element insertion.     

Deltex, a Locus Interacting with the Neurogenic Genes, Notch, Delta and Mastermind in Drosophila Melanogaster

The Notch locus of Drosophila melanogaster, which codes for a transmembrane protein sharing homology with the mammalian epidermal growth factor, is one of a small number of zygotically acting genes, the so called neurogenic loci, which are necessary for the correct segregation of neural from epidermal lineages during embryogenesis. In an attempt to identify genes whose products may interact with that of Notch, we designed a genetic screen aimed at identifying suppressors of certain Notch mutations which are known to affect the extracellular epidermal growth factor homologous domain of Notch. Mutations in two neurogenic loci were identified as suppressors: Delta, whose product was recently shown to interact with Notch and mastermind. In addition, a third, X-linked gene was shown capable of acting as a suppressor. We show that this gene is the deltex locus, characterize the phenotype of deltex mutations, and demonstrate both a maternal and zygotic action of the locus. All deltex alleles behave as recessive viables affecting wing, ocellar and eye morphology. There are allele specific interactions between deltex and various Notch alleles; for example, deltex mutants with a reduced dosage of wild-type Notch die as pupae. deltex also interacts with Delta and mastermind in a fashion that is formally analogous to its interaction with Notch. These results emphasize the special relationship between Notch, Delta and mastermind suggested by previous work and indicate that deltex is likely to play an important role in the same genetic circuitry within which these three neurogenic loci operate.     

A Genetic Analysis of Deltex and Its Interaction with the Notch Locus in Drosophila Melanogaster

During Drosophila development networks of genes control the developmental pathways that specify cell fates. The Notch gene is a well characterized member of some cell fate pathways, and several other genes belonging to these same pathways have been identified because they share a neurogenic null phenotype with Notch. However, it is unlikely that the neurogenic genes represent all of the genes in these pathways. The goal of this research was to use a genetic approach to identify and characterize one of the other genes that acts with Notch to specify cell fate. Mutant alleles of genes in the same pathway should have phenotypes similar to Notch alleles and should show phenotypic interactions with Notch alleles. With this approach we identified the deltex gene as a potential cell fate gene. An extensive phenotypic characterization of loss-of-function deltex phenotypes showed abnormalities (such as thick wing veins, double bristles and extra cone cells) that suggest that deltex is involved in cell fate decision processes. Phenotypic interactions between deltex and Notch as seen in double mutants showed that Notch and deltex do not code for duplicate functions and that the two genes function together in many different developing tissues. The results of these investigations lead to the conclusion that the deltex gene functions with the Notch gene in one or more developmental pathways to specify cell fate.