Multiple Allelism of the net Gene in Drosophila melanogaster and Drosophila simulans

Thenetgene mutations are known to cause abnormal pattern of veining in all wing regions except for the first posterior cells. In natural populations of Drosophila melanogaster, the net alleles were identified, which differ in phenotypic expression from standard mutations. The mutants net-extra-analis from a population Belokurikha-2000 have only a single additional vein in the third posterior cell. A line from Chernobyl-1986 population have another nontypical allele net ^Ch86 and shows a lower degree of abnormalities than that usually observed. About 10% of these flies have an additional vein fragment in the first posterior cell. In both males and females ofD. simulans population Tashkent -2001, which exhibit net ^ST91 mutation, a net of additional veins is formed as a specific additional fragment in the first posterior cell. The pattern of veining conferred by alleles net-extra-analis and net ^Ch86 is altered to a lesser extent; these alleles are dominant with respect to alleles net ^2-45 and net ^ST91, which cause more abnormalities. The heterozygotes for alleles net ^ST9 and net ^Ch86 and for Df(2) net ⁶² deletion have an additional fragment in the first posterior cell and show similarly strong deviations from normal wing vein pattern. The naturalnet alleles correspond, presumably, to different molecular gene defects involved into uncertain local interactions with numerous modifying factors and other genes that specify the wing vein pattern.     

Genetic analysis of the wing vein pattern of Drosophila

Summary Of the many mutations known to affect the wing vein pattern we have selected the most extreme in 29 genes for study. Their phenotype can be classified in two major classes: lack-of-veins and excess-of-veins, and in several internally coherent groups. The study of multiple mutant combinations, within groups and between groups, reveals several genetic operations at work in the generation of the vein pattern. The finding that some of these mutations also affect cell proliferation in characteristic ways has prompted a generative model of wing morphogenetic and pattern formation based on cell behaviour properties defined by the corresponding wild-type genes.     

Developmental Genetic Analysis of Contrabithorax Mutations in Drosophila Melanogaster

A developmental analysis of the Contrabithorax (Cbx) alleles offers the opportunity to examine the role of the Ultrabithorax (Ubx) gene in controlling haltere, as alternative to wing, morphogenesis in Drosophila. Several Cbx alleles are known with different spatial specificity in their wing toward haltere homeotic transformation. The molecular data on these mutations, however, does not readily explain differences among mutant phenotypes. In this work, we have analyzed the "apogenetic" mosaic spots of transformation in their adult phenotype, in mitotic recombination clones and in the spatial distribution of Ubx proteins in imaginal discs. The results suggest that the phenotypes emerge from early clonality in some Cbx alleles, and from cell-cell interactions leading to recruitment of cells to Ubx gene expression in others. We have found, in addition, mutual interactions between haltere and wing territories in pattern and dorsoventral symmetries, suggesting short distance influences, "accommodation," during cell proliferation of the anlage. These findings are considered in an attempt to explain allele specificity in molecular and developmental terms.     

Effect of genotypic environment on phenotypic manifestation of radius incompletus mutation in Drosophila melanogaster

Genetic analysis of marked regions of Drosophila chromosome 3 was performed in order to localize the "effective factors" of the polygene system that controls the expression of the limiting mutation in radius incompletus, the major-effect gene. The marked homozygous strain with genotype th st ri sr ca was crossed with the "selection" riSN strain. Contributions of the marked regions of chromosome 3 to the expression of the proximal and distal fragments of the wing radial vein were estimated. It was demonstrated that the th-st region of the marked strain contained a polygene determining a large positive contribution to the lengths of both fragments, whereas the st-ri region contained a polygene determining a large negative contribution to the length of the distal fragment compared to the riSN strain. Crossings were performed between strains that contained Mendelian mutations of the ri, ve, and vn major-effect genes of the wing vein patterns. Unexpectedly, a strong, non-additive effect of the interaction between these mutations was found. This effect was expressed as a complete disarrangement of the wing vein pattern. Each participant gene may be regarded as a large-effect polygene relative to the other genes.     

Localized cell death caused by mutations in a Drosophila gene coding for a transforming growth factor-beta homolog

Recessive mutations (dppdisk) in one region of the decapentaplegic (dpp) gene of Drosophila, which codes for a transforming growth factor-beta homolog, cause loss of distal parts from adult appendages. Different dppdisk alleles cause effects of different severity, the milder alleles removing distal parts and the more severe alleles removing progressively more proximal structures. In the wing disc derivatives, the most extreme dppdisk genotype removes the entire wing and leaves only a thorax fragment. We show that structures are lost in these mutants as a result of massive apoptotic cell death in the corresponding regions of the imaginal discs during the mid-third larval instar. The remaining disc fragments do not regenerate when cultured alone in the growth-permissive environment of the adult abdomen, but they can be made to regenerate by coculturing them with appropriate fragments of wild-type wing discs. This nonautonomous development is interpreted as showing that a product of dpp+, presumably the TGF-beta homolog, is secreted by the normal cells and can rescue the mutant cells in the mixed tissue.     

Genetic studies of mutations at two loci of Drosophila melanogaster which cause a wide variety of homeotic transformations

Summary The ash-1 locus is in the proximal region of the left arm of the third chromosome of Drosophila melanogaster and the ash-2 locus is in the distal region of the right arm of the third chromosome. Mutations at either locus can cause homeotic transformations of the antenna to leg, proboscis to leg and/or antenna, dorsal prothorax to wing, first and third leg to second leg, haltere to wing, and genitalia to leg and/or antenna. Mutations at the ash-1 locus cause, in addition, transformations of the posterior wing and second leg to anterior wing and second leg, respectively. A similar spectrum of transformations is caused by mutations at yet another third chromosome locus, trithorax. One extraordinary aspect of mutations at all three of these loci is that they cause such a wide variety of transformations. For mutations at both of the loci that we have studied the expression of the homeotic phenotype is both disc-autonomous (as shown by injecting mutant discs into metamorphosing larvae) and cell autonomous (as shown by somatic recombination analysis). The original mutations which identified these two loci, although lethal, manifest variable expressivity and incomplete penetrance of the homeotic phenotype suggesting that they are hypomorphic. The phenotype of double mutants which were synthesized by combining different pairs of those original mutations manifest for two of the four pairs a greater degree of expressivity and slightly more penetrance of the homeotic transformations. This mutual enhancement suggests that the products of both loci interact in the same process. A third double mutant expresses a discless phenotype.Additional alleles have been recovered at both the ash-1 and the ash-2 loci. Some of these alleles as homozygotes or transheterozygotes express the wide range of transformations revealed first by double mutants. One of the alleles at the ash-1 locus when homozygous and several transheterozygous pairs can cause either the homeotic transformation of discs or the absence of those discs. The fact that these two defects, absence of specific discs and homeotic transformations of those same discs can be caused by mutations within a single gene suggests that the activity of the product of this gene is essential for normal imaginal disc cell proliferation. Loss of that activity leads to the absence of discs, whereas, reduction of that activity leads to homeotic transformations.     

A screen to identify Drosophila genes required for integrin-mediated adhesion.

Drosophila integrins have essential adhesive roles during development, including adhesion between the two wing surfaces. Most position-specific integrin mutations cause lethality, and clones of homozygous mutant cells in the wing do not adhere to the apposing surface, causing blisters. We have used FLP-FRT induced mitotic recombination to generate clones of randomly induced mutations in the F1 generation and screened for mutations that cause wing blisters. This phenotype is highly selective, since only 14 lethal complementation groups were identified in screens of the five major chromosome arms. Of the loci identified, 3 are PS integrin genes, 2 are blistered and bloated, and the remaining 9 appear to be newly characterized loci. All 11 nonintegrin loci are required on both sides of the wing, in contrast to integrin alpha subunit genes. Mutations in 8 loci only disrupt adhesion in the wing, similar to integrin mutations, while mutations in the 3 other loci cause additional wing defects. Mutations in 4 loci, like the strongest integrin mutations, cause a "tail-up" embryonic lethal phenotype, and mutant alleles of 1 of these loci strongly enhance an integrin mutation. Thus several of these loci are good candidates for genes encoding cytoplasmic proteins required for integrin function.     

Change in the system of wing venation of Drosophila melanogaster under heat shock and selection

A change in the system of wing venation of Drosophila melanogaster appeared in response to heat shock and positive selection pressure directed to restoring the normal formation of wing radial vein, L2, that had been violated earlier by the recessive mutation of radius incompletes. Positive selection was effective, L2 having been formed correctly and completely to 35 generation. Besides, (+)-selection was accompanied by appearance of a small fragment of an additional vein at the wing tip. Selection directed to increase of size of this fragment resulted in the sufficient changes in the system of wing venation as a whole. It is suggested that, during evolution, transformation of wing venation of Drosophila was effected by the change of the way of prepattern realization, whereas the cells of wing plate continued to allow the formation of veins practically over a whole area.     

Dominant Enhancers of Egfr in Drosophila Melanogaster: Genetic Links between the Notch and Egfr Signaling Pathways

The Drosophila epidermal growth factor receptor (EGFR) is a key component of a complex signaling pathway that participates in multiple developmental processes. We have performed an F(1) screen for mutations that cause dominant enhancement of wing vein phenotypes associated with mutations in Egfr. With this screen, we have recovered mutations in Hairless (H), vein, groucho (gro), and three apparently novel loci. All of the E(Egfr)s we have identified show dominant interactions in transheterozygous combinations with each other and with alleles of N or Su(H), suggesting that they are involved in cross-talk between the N and EGFR signaling pathways. Further examination of the phenotypic interactions between Egfr, H, and gro revealed that reductions in Egfr activity enhanced both the bristle loss associated with H mutations, and the bristle hyperplasia and ocellar hypertrophy associated with gro mutations. Double mutant combinations of Egfr and gro hypomorphic alleles led to the formation of ectopic compound eyes in a dosage sensitive manner. Our findings suggest that these E(Egfr)s represent links between the Egfr and Notch signaling pathways, and that Egfr activity can either promote or suppress Notch signaling, depending on its developmental context.     

Changing spatial patterns of DNA replication in the developing wing of Drosophila

Using an antibody against bromodeoxyuridine we have analyzed the distribution of S-phase nuclei in the wing disc of Drosophila as the larval disc transforms into the adult wing during metamorphosis. On the basis of the timing of replication three cell populations can be distinguished: the cells of the presumptive wing margin, the precursor cells of the longitudinal veins, and those of the intervein regions. In each of these populations the cell cycle is first arrested and later resumes at a specific time, so that at each developmental time point a characteristic spatial pattern of S-phase nuclei is seen. An interpretation of these changing patterns in terms of vein formation, compartments, and neural development is offered.     

The relationship between the dominant Additional vein mutant in Drosophila melanogaster and engrailed.

Additional vein (Adv) is a dominant mutation that affects the first wing vein in Drosophila. It also manifests a recessive lethal phenotype and is associated with a large inversion. Using a combination of genetic and cytogenetic techniques, we show that Adv interacts with engrailed (en), likely because one of the inversion breakpoints interferes with en function. Genetic interaction studies reveal that Adv is lethal in trans with various lethal alleles of en and gives an engrailed-like wing phenotype with weak alleles of en. In situ hybridization to polytene chromosomes using en cDNA demonstrates that one of the inversion breakpoints lies within the en coding region. Although the cause of the wing phenotype is not determined herein, it likely is caused by the other inversion breakpoint interfering with a different function. The characterization of this mutation could expedite studies to understand what molecular events result in the Adv phenotype and thereby provide insight into the development of the first wing vein in Drosophila.     

Effects of deficiencies in the engrailed region of Drosophila melanogaster

The engrailed gene of Drosophila melanogaster is believed to be involved in control of determination and differentiation of posterior compartments. en1/en1 causes a partial transformation of the posterior compartment of wing and first leg to mirror-image anterior, which prompted the hypothesis that engrailed + is a "selector gene" required for the posterior pathway decision. The incomplete transformation was thought due to residual en+ activity in en1; a deletion of engrailed (en28) was constructed to determine if a complete transformation can occur. en28 is homozygous lethal and cell lethal. en28/en1 survives to adult stage, but causes a weaker transformation than en1/en1, indicating that en1 is not a simple hypomorph. A more distal deletion, en30, survives over en-lethal alleles. Both en30/en1 and en28/en30 survive to adult stage, but do not cause a stronger posterior to anterior transformation than en1/en1; thus this effect may be allele specific. New abnormalities included (1) transformation of the posterior wing blade to haltere, an effect dependent on the bx+ (but not pbx+) pseudoallele of the bithorax complex; (2) abnormal bristle pattern, tarsal fusion, and degenerate posterior claws of all legs. Although these abnormalities are posterior compartment specific, they are not expected of a "selector gene." Thus the function of engrailed may be more complex than originally believed.