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Characterization of N-terminal Myc Ubiquitylation and the Novel Oncogene CUL7

Myc is an oncogene that is commonly deregulated in human cancers. Mechanistic studies reveal that Myc is a transcription factor that interacts with a protein partner called Max. Heterodimerization and the formation of the Myc:Max complex enables Myc:Max to bind to the E-box and subsequently regulate the activation and repression of Myc target genes. Since regulation of its target genes are essential for Myc to drive transformation, the Myc and Max interaction has been targeted in mouse model studies to determine whether the oncogenic activity of Myc can be inhibited. Surprisingly, these studies reveal that targeting Myc is not only possible but a powerful way to suppress tumour growth. Since a better understanding of how Myc carries out its biological functions makes the possibility of targeting Myc a reality, it is essential to investigate and study the mechanisms of how Myc promotes tumourigenesis.
In the first part of this thesis, we investigate the idea that the N-terminal end of Myc may be post-translationally modified and this modification may dictate Myc activities. Indeed we report here that the N-terminal end of Myc can be ubiquitylated as well as acetylated, and that the loss of these modifications results in a decrease in Myc activities. Furthermore, we characterize Mdm2 as a potential E3 ubiquitin ligase that may ubiquitylate the N-terminal end of Myc.
In the second part of this thesis, we investigate CUL7 as a novel oncogene that may inhibit Myc-potentiated apoptosis and cooperate with Myc in transformation. Indeed, CUL7 is a novel p53 interacting protein that inhibits Myc potentiated apoptosis through the inhibition of p53. We have also characterized CUL7 to be overexpressed in primary human lung cancers, and a higher level of CUL7 expression associates with short-term survival of lung cancer patients.
Through the better understanding of the enzymes that post-translationally modify the N-terminal end of Myc and proteins, such as CUL7, that can cooperate with Myc to drive tumourigenesis, we may begin to devise ways to target and control deregulated Myc in cancer cells.

Identiferoai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/35715
Date18 July 2013
CreatorsKim, Sam Sulgi
ContributorsPenn, Linda Z.
Source SetsUniversity of Toronto
Languageen_ca
Detected LanguageEnglish
TypeThesis

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