Drosophila Cyclin G Is a Regulator of the Notch Signalling Pathway during Wing Development.

Notch signalling regulates a multitude of differentiation processes during Drosophila development. For example, Notch activity is required for proper wing vein differentiation which is hampered in mutants of either the receptor Notch, the ligand Delta or the antagonist Hairless. Moreover, the Notch pathway is involved in several aspects of Drosophila oogenesis as well. We have identified Drosophila Cyclin G (CycG) as a molecular interaction partner of Hairless, the major antagonist in the Notch signalling pathway, in vitro and in vivo. Loss of CycG was shown before to cause female sterility and to disturb the architecture of the egg shell. Nevertheless, Notch dependent processes during oogenesis appeared largely unaffected in cycG mutant egg chambers. Loss of CycG modified the dominant wing phenotypes of Notch, Delta and Hairless mutants. Whereas the Notch loss of function phenotype was ameliorated by a loss of CycG, the phenotypes of either Notch gain of function or of Delta or Hairless loss of function were enhanced. In contrast, loss of CycG had only a minor effect on the wing vein phenotype of mutants affecting the EGFR signalling pathway emphasizing the specificity of the interaction of CycG and Notch pathway members.

Dorso-ventral axis formation of the Drosophila oocyte requires Cyclin G.

In general, cyclins control the cell cycle. Not so the atypical cyclins, which are required for diverse cellular functions such as for genome stability or for the regulation of transcription and translation. The atypical Cyclin G (CycG) gene of Drosophila has been involved in the epigenetic regulation of abdominal segmentation, cell proliferation and growth, based on overexpression and RNAi studies, but detailed analyses were hampered by the lack of a cycG mutant. For further investigations, we subjected the cycG locus to a detailed molecular analysis. Moreover, we studied a cycG null mutant that we recently established. The mutant flies are homozygous viable, however, the mutant females are sterile and produce ventralized eggs. Here we show that this egg phenotype is primarily a consequence of a defective Epidermal Growth Factor Receptor (EGFR) signalling pathway. By using different read outs, we demonstrate that cycG loss is tantamount to lowered EGFR signalling. Inferred from epistasis experiments, we conclude that CycG promotes the Grk signal in the oocyte. Abnormal accumulation but regular secretion of the Grk protein suggests defects of Grk translation in cycG mutants rather than transcriptional regulation. Accordingly, protein accumulation of Vasa, which acts as an oocyte specific translational regulator of Grk in the oocyte is abnormal. We propose a role of cycG in processes that regulate translation of Grk and hence, influence EGFR-mediated patterning processes during oogenesis.

Cyclin G is involved in meiotic recombination repair in Drosophila melanogaster.

Cyclin G (CycG) belongs to the atypical cyclins, which have diverse cellular functions. The two mammalian CycG genes, CycG1 and CycG2, regulate the cell cycle in response to cell stress. Detailed analyses of the role of the single Drosophila cycG gene have been hampered by the lack of a mutant. We generated a null mutant in the Drosophila cycG gene that is female sterile and produces ventralised eggs. This phenotype is typical of the downregulation of epidermal growth factor receptor (EGFR) signalling during oogenesis. Ventralised eggs are also observed in mutants (for example, mutants of the spindle class) that are defective in meiotic DNA double-strand break repair. Double-strand breaks (DSBs) induce a meiotic checkpoint by activating Mei-41 kinase (the Drosophila ATR homologue), thereby indirectly causing dorsoventral patterning defects. We provide evidence for the role of CycG in meiotic checkpoint control. The increased incidence of DSBs in cycG mutant germaria may reflect inefficient DSB repair. Therefore, the downregulation of Mei-W68 (an endonuclease that induces meiotic DSBs), Mei-41, or Drosophila melanogaster Chk2 (a downstream kinase that initiates the meiotic checkpoint) rescues the cycG mutant eggshell phenotype. In vivo, CycG associates with Rad9 and BRCA2. These two proteins are components of the 9-1-1 complex, which is involved in sensing DSBs and in activating meiotic checkpoint control. Therefore, we propose that CycG has a role in an early step of meiotic recombination repair, thereby affecting EGFR-mediated patterning processes during oogenesis.