Dissecting the Role of Aneuploidy in Solid Tumors

The maintenance of a normal complement of the genome is a requirement for the success of multicellular organisms. Aneuploidy refers to the presence of an abnormal (lower or higher than euploid) number of chromosomes or chromosome arms. Although detrimental at the organismal level, aneuploidy is extremely frequent (~90%) in human tumors (Beroukhim et al., 2010). Despite the fact that aneuploidy is so frequent in cancer, little is known about whether and how aneuploidy contributes to tumorigenesis and how aneuploidy could be targeted for cancer therapy. What are the causes and consequences of aneuploidy in cancer? How does aneuploidy affect patients’ response to therapy, especially immunotherapy? How does aneuploidy impact the transcriptome, proteome and metabolism of cancer cells? These are among the main questions the Davoli Lab is interested in. For example, we conducted a combined analysis of point mutation and copy number data in primary human tumor samples and demonstrated that the distribution of cancer driver genes can predict the frequency of whole chromosome or chromosome arm aneuploidy across cancers (Davoli et al., 2013; Sack, Davoli et al. 2018). This suggests that the recurrent patterns of aneuploidy in cancer act as driver events during tumorigenesis. Furthermore, through an analysis of genomics and transcriptomic data from primary human tumors, we recently identified a negative association between the level of cancer aneuploidy and the extent of tumor immune infiltrate, especially of cytotoxic T cells  (Davoli et al., 2017). Our ongoing research interest is to determine whether and how cancer aneuploidy regulates different aspects of cancer development and therapy response utilizing a combination of experimental and computational approaches. Lab website: www.davolilab.com.