Given the importance of cytokinesis in maintaining genomic integrity it is particularly intriguing to note that orthologues of Hif2p

July 31, 2017

e equivalent number of TUNEL positive cells in these brains compared to those expressing Tip60WT alone. Taken together, our results demonstrate that Tip60 and APP functionally interact to regulate neuronal apoptotic cell death in the Drosophila CNS and that this interaction is dependent upon the C-terminus of APP. Discussion In this study, we have generated a unique transgenic Drosophila model system suitable for investigating a functional link between Tip60 HAT activity and APP in neuronal development, in vivo. We demonstrate that Tip60 and APP functionally interact in both general and nervous system development in Drosophila, in vivo and that this interaction specifically mediates apoptotic neuronal cell death in the CNS, a process that when misregulated is linked to AD pathology. Remarkably, Tip60 appears to display a neuroprotective function in that Tip60 overexpression can rescue both loss of viability and neuronal apoptosis induction in a Drosophila AD model. While a number of in vitro studies supporting the transcription regulatory role of the Tip60/AICD complex in gene control have been reported, our work is the first to demonstrate a functional interaction between Tip60 HAT activity and APP in nervous system development in vivo. Here we show that misexpression PubMed ID:http://www.ncbi.nlm.nih.gov/pubmed/22205030 of Tip60 induces neuronal apoptotic cell death in the Drosophila CNS, and that this process is mediated via a functional interaction between Tip60 and the APP C-terminal domain. Since disruption of Tip60 HAT activity induced neuronal cell death, we examined whether there was specific misregulation of apoptosis linked genes due to loss of Tip60 HAT activity. Pathway analysis of our previously reported microarray data set of genome wide changes in gene expression induced in the fly in response to Tip60 HAT loss revealed genes functioning in 17 different apoptotic pathways to be enriched, many of which were associated with the p53 apoptotic pathway. Our findings are consistent with previous studies demonstrating a role for Tip60 as a p53 MedChemExpress SCD-inhibitor co-activator in p53 mediated apoptotic pathways. Recent studies have found Tip60 to be required for activation of proapoptotic genes through acetylation of p53 DNA binding domain. TRAF4, one Tip60 Mediates APP Induced Cell Death in the CNS son’s, Huntington’s and Alzheimer’s disease. These diseases are also characterized by neuronal cell death that increases over time and underlies an array of symptoms that depend on the function of the lost neuronal population. It has been proposed that in AD, in addition to the deposition of toxic b-amyloid plaques in the brain, neurodegeneration may also be caused via c-secretase cleavage of APP that generates AICD carboxy terminal fragments that are toxic to neurons. Accordingly, ectopic expression of AICD in rat pheocytoma cells and cortical neurons and H4 neuroglioma cells has been shown to induce apoptosis upon nuclear translocation. Consistent with these reports, we too observe induction of apoptosis when APP is expressed in the nervous system of Drosophila in vivo at physiological temperatures and that this phenotype is dependent upon the C-terminal domain of APP. Interestingly, APP C-terminal domain induced apoptosis has previously been reported to be mediated via Tip60 HAT activity in vitro, such that induction of apoptosis in neuroglioma cells transfected with APP C-terminal domain is enhanced by cotransfection of wild type Tip60 and decreased by a dominant negative version of Tip60 lacking HAT a