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生命科學學院學術報告:Surprising roles of p53 and Mdm2 in regulating metabolism of cancer cells
2019-05-13

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浙江快乐彩咋玩的 www.umgdu.com   題目:    Surprising roles of p53 and Mdm2 in regulating metabolism of cancer cells

  報告人: Carol Prives教授

  時間:    2019年5月13日14:00

  地點:    教一樓201室

  報告人簡介: Carol Prives博士是美國哥倫比亞大學講座教授、美國科學院院士、美國藝術和科學學院院士、p53功能的奠基者,在Cell、Nature、Science 發表幾十篇論文。目前擔任Cell、eLife、 Genes & Development等刊物的編委。                                                                                             

     報告摘要:

  Despite decades of intense scrutiny we still do not fully understand how p53 functions as a tumor suppressor in its wild-type state, and as an oncogene when harboring cancer-related mutations. Further, we have yet to clarify the roles of Mdm2 and MdmX, most well understood as negative regulators of p53, in p53-independent activities. Work from our lab has revealed that p53 and Mdm2 can regulate metabolism in different ways. For example, in collaboration we discovered that while mutant p53 upregulates the mevalonate pathway by which cells synthesize cholesterol and key byproducts that play roles in cell growth, in complete opposition to this wild-type p53 can repress expression of the genes encoding the mevalonate pathway enzymes. In collaboration with the group of Scott Lowe it was shown that that p53 repression of the mevalonate pathway is required for prevention of hepatocellular carcinoma in mice.

  In separate studies, we found that Mdm2 and MdmX play one or more roles in maintaining growth and survival of some cancer cell lines. Interestingly, however, I collaboration with Brent Stockwell, we discovered that the same cells when induced to undergo  ferroptosis, which is an iron-dependent form of cell death caused by lipid peroxidation, actually require Mdm2 and MdmX for maximal response to inducers of ferroptosis. Insight into how Mdm2 and MdmX play such roles will be presented.

  Finally, our studies of mutant p53 that can form dimers but not tetramers has revealed an novel role for p53 in regulating glycolysis. Oligomerization-defective mutant forms of p53 display a distinct phenotype marked by enhanced glucose influx and antioxidant generation. Despite elevated antioxidant pools, dimeric mutant cells display increased basal ROS and significantly