Truncated products of the vestigial proliferation gene induce apoptosis.

The vestigial (vg) gene in D. melanogaster, whose mutant phenotype is characterized by wing atrophy, encodes a novel nuclear protein involved in cell proliferation. The original vg mutant (vgBG) displays massive apoptosis in the wing imaginal disc. Here we tested the hypothesis that the vg mutant phenotype could be due: (i) to lack of cell proliferation in null mutants due to the absence of the Vg product and, (ii) to apoptosis in vgBG and other mutants due to the presence of a major Vg truncated product. In agreement with our hypothesis no cell death was observed in null vg mutants, and the anticell death baculovirus P35 product is unable to rescue the mutant phenotype caused by absence of the Vg product. In addition, expression of the antiproliferative gene dacapo, the homolog of p21, induces a mutant wing phenotype without inducing cell death. In contrast the wing phenotype of the original vg mutant could be reproduced by the ectopic expression of the reaper cell death gene when expressed by vg regulatory sequences. In agreement with the hypothesis, the classic vg mutant spontaneously displays an increase in reaper expression in the wing disc and its phenotype can be partially rescued by the P35 product. Finally, we showed that ectopic expression of a truncated Vg product is able on its own to induce ectopic cell death and reaper expression. Our results shed new light on the function of the vg gene, in particular, they suggest that the normal and truncated products affect vg target genes in different ways.

Temperature regulates expression of the Drosophila vestigial gene only in mutant wing discs.

All Vestigial mutants in Drosophila melanogaster display a thermosensitive phenotype, with the exception of two which disrupt an intronic wing-specific enhancer element. Here we report a very unusual transcriptional regulation; temperature changes are associated with alterations in the level of vg expression only in the wing disc of thermosensitive mutant flies and not in the brain. No effect is observed in the wild-type strain. The tissue specificity of the temperature effect indicates an involvement of the intronic wing-specific enhancer element in determining the thermosensitivity of mutants.

Control of apterous by vestigial drives indirect flight muscle development in Drosophila.

Drosophila thoracic muscles are comprised of both direct flight muscles (DFMs) and indirect flight muscles (IFMs). The IFMs can be further subdivided into dorsolongitudinal muscles (DLMs) and dorsoventral muscles (DVMs). The correct patterning of each category of muscles requires the coordination of specific executive regulatory programs. DFM development requires key regulatory genes such as cut (ct) and apterous (ap), whereas IFM development requires vestigial (vg). Using a new vg(null) mutant, we report that a total absence of vg leads to DLM degeneration through an apoptotic process and to a total absence of DVMs in the adult. We show that vg and scalloped (sd), the only known VG transcriptional coactivator, are coexpressed during IFM development. Moreover, we observed an ectopic expression of ct and ap, two markers of DFM development, in developing IFMs of vg(null) pupae. In addition, in vg(null) adult flies, degenerating DLMs express twist (twi) ectopically. We provide evidence that ap ectopic expression can induce per se ectopic twi expression and muscle degeneration. All these data seem to indicate that, in the absence of vg, the IFM developmental program switches into the DFM developmental program. Moreover, we were able to rescue the muscle phenotype of vg(null) flies by using the activity of ap promoter to drive VG expression. Thus, vg appears to be a key regulatory gene of IFM development.