Distinguishing commonly deleted genes as drivers or passengers of human cancers are key to delineating mechanisms of tumor initiation. The “Chaos3” mouse model of spontaneous breast cancer carries a missense mutation in a gene called Mcm4 (minichromosome maintenance 4), causing destabilization of the MCM2-7 replicative helicase, which in turn causes elevated genomic instability. Approximately 80% of female mice homozygous for this mutation in the C3HeB/FeJ strain background develop mammary tumors with an average latency of 12 months. Genomic analysis of these tumors revealed a recurrent subset of genes with copy number alterations such as Arid1a and Nf1. This project aims to: 1) test whether the genes Arid1a and Nf1 act as mammary tumor drivers in the Chaos3 breast cancer model; 2) understand the genome-wide effects of Arid1a loss in mammary tumorigenesis; 3) identifying potential therapeutic targets for Arid1a-deficient mammary tumors; and 4) unravel the mechanism by which destabilization of MCM2-7 replicative helicase leads to cancer onset. To achieve these aims, several experiments such as conditional mutagenesis, CUTandRUN, RNA-seq, and replication timing profiling were conducted to address my aims. Preliminary data indicates that heterozygous loss of Arid1ain Chaos3 mammary tumors produces a distinct transcriptional profile compared to mammary tumors without Arid1a deletion. Additionally, Chaos3 primary cells have markedly altered replication timing patterns in certain regions of the genome that might explain increased susceptibility to mutations. My experiments can validate new candidates like Arid1a as a driver of sporadic breast cancer in humans. In addition, these studies will not only lend insight into how key tumor suppressors are deleted in the Chaos3 model, but also potentially reveal features of genomic regions that are particularly susceptible to genetic or environmental perturbations to DNA replication. The Chaos3 sporadic breast cancer mouse model mimics sporadic human luminal breast cancer and can be used as a tool to better understand the biology and genetics of a common disease that plagues women worldwide.

Citation Format: Marquita Winters, John Schimenti. Identifying drivers of mammary tumorigenesis & elucidating the mechanisms of cancer initiation in DNA replication defective Chaos3 mice [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 4611.