Control of G2/M transition by Drosophila Fos.

The transcription factors of the Fos family have long been associated with the control of cell proliferation, although the molecular and cellular mechanisms that mediate this function are poorly understood. We investigated the contributions of Fos to the cell cycle and cell growth control using Drosophila imaginal discs as a genetically accessible system. The RNA interference-mediated inhibition of Fos in proliferating cells of the wing and eye discs resulted in a specific defect in the G2-to-M-phase transition, while cell growth remained unimpaired, resulting in a marked reduction in organ size. Consistent with the conclusion that Fos is required for mitosis, we identified cyclin B as a direct transcriptional target of Fos in Drosophila melanogaster, with Fos binding to a region upstream of the cyclin B gene in vivo and cyclin B mRNA being specifically reduced under Fos loss-of-function conditions.

DREF is required for efficient growth and cell cycle progression in Drosophila imaginal discs.

Based on overexpression studies and target gene analyses, the transcription factor DNA replication-related element factor (DREF) has been proposed to regulate growth and replication in Drosophila melanogaster. Here we present loss-of-function experiments to analyze the contribution of DREF to these processes. RNA interference-mediated extinction of DREF function in vivo demonstrates a requirement for the protein for normal progression through the cell cycle and consequently for growth of imaginal discs and the derived adult organs. We show that DREF regulates the expression of genes that are required for the transition of imaginal disc cells through S phase. In conditions of suppressed apoptosis, DREF activation can cause overgrowth of developing organs. These data establish DREF as a global regulator of transcriptional programs that mediate cell proliferation and organ growth during animal development.

Physiological effects of manipulating the level of insulin-degrading enzyme in insulin-producing cells of Drosophila.

Insulin-degrading enzyme (IDE) degrades insulin and other peptides, including the Aß peptide of Alzheimer's disease. However, the mechanism by which IDE acts on its substrates in vivo is unclear, and its role in pathogenesis of type 2 diabetes and Alzheimer's disease is controversial. Here, we show that in Drosophila knocking down IDE in insulin-producing cells (IPCs) of the brain results in increased body weight and fecundity, decreased circulating sugar levels, and reduced lifespan. Moreover, knocking down and over-expressing IDE in IPCs have opposite physiological effects. As mis-regulated insulin signaling in peripheral tissues is known to cause similar phenotypes, our data suggest a role for Drosophila IDE in determining the level of insulin-like peptides made by IPCs that systemically activate insulin signaling.

Foxo and Fos regulate the decision between cell death and survival in response to UV irradiation.

Cells damaged by environmental insults have to be repaired or eliminated to ensure tissue homeostasis in metazoans. Recent studies suggest that the balance between cell survival signals and pro-apoptotic stimuli controls the decision between cell repair and death. How these competing signals are integrated and interpreted to achieve accurate control over cell fate in vivo is incompletely understood. Here, we show that the Forkhead Box O transcription factor Foxo and the AP-1 transcription factor DFos are required downstream of Jun-N-terminal kinase signaling for the apoptotic response to UV-induced DNA damage in the developing Drosophila retina. Both transcription factors regulate the pro-apoptotic gene hid. Our results indicate that UV-induced apoptosis is repressed by receptor tyrosine kinase-mediated inactivation of Foxo. These data suggest that integrating stress and survival signals through Foxo drives the decision between cell death and repair of damaged cells in vivo.

Inorganic mercury attenuates CD95-mediated apoptosis by interfering with formation of the death inducing signaling complex.

Inorganic mercury (Hg2+) modulates several lymphocyte signaling pathways and has been implicated as an environmental factor linked to autoimmune disease. From the standpoint that autoimmune diseases represent disorders of cell accumulation, in which dysregulated apoptosis may be one mechanism leading to the accumulation of autoreactive lymphocytes, we have been investigating the influences of Hg2+ on CD95-mediated apoptosis. We demonstrate here that low and noncytotoxic concentrations of Hg2+ impair CD95 agonist-induced apoptosis in representative Type-I and Type-II T cell lines. Hg2+ treatment blocks the CD95 agonist-induced activation of initiator and effector caspases as well as the association between CD95 and the signaling adaptor, FADD. CD95 multimerization does not appear to be affected by Hg2+. Thus, the Hg2+ sensitive step within the CD95 death pathway is localized to the level of the death inducing signaling complex (DISC). Disruption of proper DISC formation may be a biochemical mechanism whereby Hg2+ contributes to autoimmune disease.