The results presented in this thesis provide new information on the role of the p53.S389A point mutation in chemical-induced tumorigenesis. After DNA damage, p53 protein levels increase due to... Show moreThe results presented in this thesis provide new information on the role of the p53.S389A point mutation in chemical-induced tumorigenesis. After DNA damage, p53 protein levels increase due to several post-translational activation processes. Phosphorylation of p53.S389 seems to be partly required for optimal induction of these p53 protein levels. Next, target genes are either induced or repressed, and phosphorylation of p53.S389 seems essential for an optimal p53-related transcriptional response both endogenously (especially repressed genes) as well as after the induction of DNA damage. Than as a read-out system for the activation of different genes, several cellular responses (apoptosis, cell cycle arrest etc.) can be observed, which again seems partly dependent on p53.S389 phosphorylation. When these processes are adversely affected due to inadequate functioning of p53, like is the case in p53.S389A mutant mice, this might lead to increased risks of developing tumors. Indeed, two chronic carcinogenicity experiments revealed an increased sensitivity of the p53.S389A mutant mice for tumor development upon exposure to DNA damaging agents. In conclusion, knowledge about the in vivo relationship between DNA damage induction, regulation of p53 activity (in terms of cell cycle control and/or apoptosis), DNA repair (NER) and the development of cancer was obtained. Show less
All organisms are composed of cells and the cell's nucleus contains DNA. The induction of DNA damage is a threat to organisms. Signalling of DNA damage and subsequent repair is of substantial... Show moreAll organisms are composed of cells and the cell's nucleus contains DNA. The induction of DNA damage is a threat to organisms. Signalling of DNA damage and subsequent repair is of substantial importance. Double-strand breaks (DSBs) in DNA can be induced by ionising radiation and DNA damaging agents but also arise as intermediates in several cellular processes (e.g. meiosis). DSBs are among the most genotoxic DNA lesions and their accurate repair is crucial. Genetic instability resulting from unrepaired DSBs can lead to cell death and, in a multicellular organism, to cancer. There are two major DSB repair pathways: homologous recombination (HR) and non-homologous endjoining (NHEJ). By NHEJ, broken DNA is sealed together, irrespective of sequence homology, in a not necessarily error-free way. HR, in which a homologous DNA molecule is needed as a template, accurately repairs DSBs. In this thesis we mainly focus on recombinational repair proteins of the RAD52 epistasis group and involved in HR. We analyse the biochemical properties of two Rad52 homologs in S. pombe, Rad22A and Rad22B. We examine combined mutations in RAD52 and RAD54 homologs in S. pombe and mice. We investigate the importance of sumolyation of recombinational repair proteins. We also introduce mice deficient in Sycp1, important for coordination during meiosis and the formation of crossovers Show less