Testimoni Puerarin

July 26, 2017

ity prompted us to ask whether a potential mechanistic basis for this lethal phenotype was via induction of an apoptotic response in these flies. We recently reported a microarray 910232-84-7 biological activity analysis comparing global changes in gene expression in response to ubiquitous induction of Tip60E431Q in the fly. While this study reported misregulation of genes linked to diverse neuronal functions, the identity of genes that function in specific neuronal P53 pathway Parkinson disease Wnt signaling pathway doi:10.1371/journal.pone.0041776.t003 processes was not explored. To address this and to examine the causative mechanism that mediates the Tip60/APP induced lethal phenotype, we wanted to further analyze our previously published microarray gene expression data with specific focus on genes that are known to function in apoptosis related pathways. Towards this end, we performed pathway analysis by first identifying canonical Tip60 Mediates APP Induced Cell Death in the CNS apoptotic pathways and their respective genes from online databases like Gene Ontology and the PANTHER classification system. The dTip60E431Q microarray data set was then examined to see if genes linked to such apoptotic pathways were misregulated in response to loss of Tip60’s HAT activity. Our analysis identified 53 such PubMed ID:http://www.ncbi.nlm.nih.gov/pubmed/22205030 unique genes that are involved in 17 different apoptotic pathways to be misregulated in the dTip60E431Q data set. Intriguingly, the identified pathways included those that are associated with Alzheimer’s, Parkinson’s and Huntington’s diseases, all neurodegenerative disorders in which massive neuronal death due to apoptosis is a common characteristic. Importantly, the p53 mediated pathway and Wnt signaling pathway were among the most highly represented pathways, consistent with previous reports implicating Tip60 in a p53 mediated apoptotic response. To validate our microarray results, we carried out quantitative RT-PCR analysis of nine genes that encoded protein products with known functions involved in inducing an apoptotic response and were representative of a particular pathway. Of the genes that were upregulated in response to Tip60 HAT loss was Calpain, a calcium dependent enzyme that mediates proteolytic cleavage of proteins like APP and tau. Abnormal activation of Calpain has also been reported to initiate degradation of proteins essential for neuronal survival. Among the other confirmed targets that were upregulated were genes with established roles in the induction of the p53 mediated apoptotic pathway such as TRAF4 and CG9418. The wingless protein and Frizzled, a transmembrane protein that functions as Wg receptor were two confirmed upregulated targets critical in the Wnt signaling pathway involved in regulating apoptosis. Also upregulated in the microarray data was ALiX, a calcium dependent ubiquitously expressed protein involved in neuronal cell death. Consistent with this finding, upregulation of endogenous ALiX has also been reported to correlate with cell death in vivo. Myc proteins are essential regulators of cellular growth and proliferation during normal development. Recently, the ability of overexpressed Myc to induce cell-autonomous apoptosis has been shown to be evolutionarily conserved in Drosophila Myc. Interestingly, we too found Myc to be upregulated in response to loss of Tip60 HAT activity. Our identification of these target genes that are affected by loss of Tip60 HAT activity further support an as yet unidentified putative role for Tip60 in t