Ian A. Boussy

The evolutionary genetics of thehobo transposable element in theDrosophila melanogaster complex

Hobo elements are a family of transposable elements found inDrosophila melanogaster and its three sibling species:D. simulans, D. mauritiana andD. sechellia. Studies inD. melanogaster have shown thathobo may be mobilized, and that the genetic effects of such mobilizations included the general features of hybrid dysgenesis: mutations, chromosomal rearrangements and gonadal dysgenis in F1 individuals. At the evolutionary level somehobo-hybridizing sequences have also been found in the other members of themelanogaster subgroup and in many members of the relatedmontium subgroup. Surveys of older collected strains ofD. melanogaster suggest that completehobo elements were absent prior to 50 years ago and that they have recently been introduced into this species by horizontal transfer. In this paper we review our findings and those of others, in order to precisely describe the geographical distribution and the evolutionary history ofhobo in theD. melanogaster complex. Studies of the DNA sequences reveal a different level of divergence between the groupD. melanogaster, D. simulans andD. mauritiana and the fourth speciesD. sechellia. The hypothesis of multiple transfers in the recent past into theD. melanogaster complex from a common outside source is discussed.

Origin and decay of the P element-associated latitudinal cline in Australian Drosophila melanogaster

The latitudinal cline in P transposable element-associated characteristics in eastern Australian populations of Drosophila melanogaster has changed between 1986 and 1991–1994. New collections were made in 1991–1994 from localities along the eastern coast of Australia. P element-associated properties of 256 isofemale lines from 43 localities were evaluated using gonadal dysgenesis and/or singed-weak hypermutability assays. The overall results indicate that both P activity and P susceptibility have declined, with all populations showing a tendency towards a state with little P activity potential but with P repressor function (neutral or ‘Q’). P repressor function is strong in all populations except some of the most southerly. P activity potential peaks at about 27° SLat, and drops off to the south (as in 1983–1986 collections) and to the north (in contrast to 1983–1986 collections); thus the cline is no longer a simple P-to-Q-to-M pattern from north to south, but is now Q-P-Q-M. A mtDNA RFLP that putatively distinguishes North American and European populations varies in frequency among the populations but the frequency does not vary clinally with latitude, ruling out massive introductions from North America and Europe as causing the cline.

Stimulation of IFN-γ, TNF-α, and TNF-β secretion in IL-2-activated T cells: Costimulatory roles for LFA-1, LFA-2, CD44, and CD45 molecules

Lymphokine-activated killer (LAK) cells are peripheral blood lymphocytes (PBLs) that possess the ability to kill target cells in a non-major histocompatibility complex (MHC)-restricted manner. Both NK and T cells can be stimulated with interleukin-2 (IL-2) to become LAK cells. We previously reported that the interaction of LAK cells with tumor cells also induces the secretion of interferon-gamma (IFN-gamma). The NK subset of LAK (LAK-NK) cells is stimulated by tumor cells to secrete IFN-gamma in a non-MHC-restricted manner while the T cell subset of LAK (LAK-T) cells is stimulated to secrete IFN-gamma upon cross-linking of the T cell receptor (TCR)-CD3 complex. We here report that LAK-T cells stimulated with anti-CD3 mAbs and tumor cells secrete two additional cytokines, tumor necrosis factor-alpha (TNF-alpha) and TNF-beta/lymphotoxin (TNF-beta). In addition, we demonstrate that at least four other structurally unrelated molecules, in addition to the TCR-CD3 complex, on LAK-T cells participate in the stimulation of IFN-gamma, TNF-alpha, and TNF-beta production. These molecules are the lymphocyte function associated antigen-1 (LFA-1), lymphocyte function associated antigen-2 (LFA-2), CD44, and CD45. LFA-1 is an integrin, LFA-2 is a member of the immunoglobulin supergene family, CD44 is homologous to the cartilage link proteins, and CD45 is a tyrosine phosphatase. Ligands to three of these molecules have been identified; ICAM-1, LFA-3, and hyaluronic acid binding to LFA-1, LFA-2, and CD44, respectively. LFA-1, LFA-2, and CD44 are reported to function both as adhesion molecules and as costimulators in resting T cells. Our data suggest that these three molecules enhance IFN-gamma, TNF-alpha, and TNF-beta production by augmenting LAK-T cell to tumor cell adhesion and also by functioning as costimulators.

Genomic P elements and P-M characteristics of eastern Australian populations of Drosophila melanogaster

As part of our effort to monitor changes in the clinal pattern of P element-associated traits in eastern Australian Drosophila melanogaster, we investigated the genomic P elements of 293 isofemale lines collected in the period 1991–1994 from 45 localities. P elements were present in many copies in all genomes examined, with full-size P and KP element size classes accounting for the large majority. SR elements were not present in at least 92% of the lines tested. South of about 26° south Latitude (°SLat), the ratio of KP to full-size P elements (KP/P ratio) increased, correlating weakly with the P-M phenotypes of the populations, from moderately P populations (26–29°SLat) to M populations (37–38°SLat) North of 26°SLat, in weak P populations, the KP/P ratio was higher than between 26 and 29°Slat. The KP/P ratio appears to be higher in the northern populations than it was when previous studies were done. Overall, a high KP/P ratio among lines correlated roughly with a lack of P activity, but it also correlated with reduced repressor function. In a sample of 30 lines, a maternal effect of repressor function did not show a pattern with latitude, nor with KP/P ratio, nor with presence or absence of P activity.

A Locus in Drosophila sechellia Affecting Tolerance of a Host Plant Toxin

Many insects feed on only one or a few types of host. These host specialists often evolve a preference for chemical cues emanating from their host and develop mechanisms for circumventing their host’s defenses. Adaptations like these are central to evolutionary biology, yet our understanding of their genetics remains incomplete. Drosophila sechellia, an emerging model for the genetics of host specialization, is an island endemic that has adapted to chemical toxins present in the fruit of its host plant, Morinda citrifolia. Its sibling species, D. simulans, and many other Drosophila species do not tolerate these toxins and avoid the fruit. Earlier work found a region with a strong effect on tolerance to the major toxin, octanoic acid, on chromosome arm 3R. Using a novel assay, we narrowed this region to a small span near the centromere containing 18 genes, including three odorant binding proteins. It has been hypothesized that the evolution of host specialization is facilitated by genetic linkage between alleles contributing to host preference and alleles contributing to host usage, such as tolerance to secondary compounds. We tested this hypothesis by measuring the effect of this tolerance locus on host preference behavior. Our data were inconsistent with the linkage hypothesis, as flies bearing this tolerance region showed no increase in preference for media containing M. citrifolia toxins, which D. sechellia prefers. Thus, in contrast to some models for host preference, preference and tolerance are not tightly linked at this locus nor is increased tolerance per se sufficient to change preference. Our data are consistent with the previously proposed model that the evolution of D. sechellia as a M. citrifolia specialist occurred through a stepwise loss of aversion and gain of tolerance to M. citrifolia’s toxins.

Incompatibility and competitive exclusion of genomic segments between sibling Drosophila species.

The extent and nature of genetic incompatibilities between incipient races and sibling species is of fundamental importance to our view of speciation. However, with the exception of hybrid inviability and sterility factors, little is known about the extent of other, more subtle genetic incompatibilities between incipient species. Here we experimentally demonstrate the prevalence of such genetic incompatibilities between two young allopatric sibling species, Drosophila simulans and D. sechellia. Our experiments took advantage of 12 introgression lines that carried random introgressed D. sechellia segments in different parts of the D. simulans genome. First, we found that these introgression lines did not show any measurable sterility or inviability effects. To study if these sechellia introgressions in a simulans background contained other fitness consequences, we competed and genetically tracked the marked alleles within each introgression against the wild-type alleles for 20 generations. Strikingly, all marked D. sechellia introgression alleles rapidly decreased in frequency in only 6 to 7 generations. We then developed computer simulations to model our competition results. These simulations indicated that selection against D. sechellia introgression alleles was high (average s = 0.43) and that the marker alleles and the incompatible alleles did not separate in 78% of the introgressions. The latter result likely implies that most introgressions contain multiple genetic incompatibilities. Thus, this study reveals that, even at early stages of speciation, many parts of the genome diverge to a point where introducing foreign elements has detrimental fitness consequences, but which cannot be seen using standard sterility and inviability assays.

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).

The occurrence of the transposable elementpogo inDrosophila melanogaster

We examined the genomic occurrence of the transposable elementpogo in over 120 strains ofDrosophila melanogaster, from around the world and from different eras. All had multiple copies of a 2.1 kilobase (kb)pogo element, and multiple copies of several size classes between 1.0 and 1.8 kb. There were differences between strains in intensities or presences of deletion-derivative size classes, suggesting current or recent mobility in the species. We were unable to find anypogo-hybridization in eight other species in the genus, in three subgenera, or in the relatedScaptomyza pallida. Thepogo element may be a ‘middle-aged’ element in the genome ofD. melanogaster, having entered the species since its divergence from its sibling species, but long before theP andhobo elements.

The transposable element hobo in Drosophila melanogaster and related species

The hobo transposable element of Drosophila melanogaster is a member of the same structural class as the much-studied P element (Finnegan, 1989), and hobo has proven to have properties similar to those of the P element. It was shown by Streck and coworkers that many strains of D. melanogaster have many hobo elements in their genomes (‘H’, for ‘hobo-bearing’, strains), but that some completely lack hobos (‘E’, for ‘empty’, strains) (Streck, MacGaffey & Beckendorf, 1986); this is obviously analogous to the P and ‘true M’ strains in the P element system (see below). Soon thereafter it was independently shown by two groups that hobo was often mobile, and that its mobility could be triggered by crosses between strains differing in their hobo complements (Yannopoulos et al., 1987; Blackman et al., 1987). The genetic effects of such mobilization included mutations, chromosomal rearrangements and non-development of gonads in Fl individuals. The name ‘hybrid dysgenesis’ was borrowed from the P and I element systems by both groups to describe the suite of effects produced by the hobo system (Yannopoulos et al., 1987; Blackman et al., 1987). The hobo element thus seemed to offer a system very similar to the P element system and thus valuable for comparison to it.