BACKGROUND and AIMS: It has been a challenge to identify liver tumor suppressors or oncogenes due to the genetic heterogeneity of these tumors. We performed a genome-wide screen to identify suppressors of liver tumor formation in mice, using CRISPR-mediated genome editing. METHODS: We performed a genome-wide CRISPR/Cas9-based knockout screen of P53-null mouse embryonic liver progenitor cells that overexpressed MYC. We infected p53-/-;Myc;Cas9 hepatocytes with the mGeCKOa lentiviral library of 67,000 single-guide RNAs (sgRNAs), targeting 20,611 mouse genes, and transplanted the transduced cells subcutaneously into nude mice. Within 1 month, all the mice that received the sgRNA library developed subcutaneous tumors. We performed high-throughput sequencing of tumor DNA and identified sgRNAs increased at least 8-fold compared to the initial cell pool. To validate the top 10 candidate tumor suppressors from this screen, we collected data from patients with hepatocellular carcinoma (HCC) using the Cancer Genome Atlas and COSMIC databases. We used CRISPR to inactivate candidate tumor suppressor genes in p53-/-;Myc;Cas9 cells and transplanted them subcutaneously into nude mice; tumor formation was monitored and tumors were analyzed by histology and immunohistochemistry. Mice with liver-specific disruption of p53 were given hydrodynamic tail-vein injections of plasmids encoding Myc and sgRNA/Cas9 designed to disrupt candidate tumor suppressors; growth of tumors and metastases was monitored. We compared gene expression profiles of liver cells with vs without tumor suppressor gene disrupted by sgRNA/Cas9. Genes found to be up-regulated after tumor suppressor loss were examined in liver cancer cell lines; their expression was knocked down using small hairpin RNAs, and tumor growth was examined in nude mice. Effects of the MEK inhibitors AZD6244, U0126, and trametinib, or the multi-kinase inhibitor sorafenib, were examined in human and mouse HCC cell lines. RESULTS: We identified 4 candidate liver tumor suppressor genes not previously associated with liver cancer (Nf1, Plxnb1, Flrt2, and B9d1). CRISPR-mediated knockout of Nf1, a negative regulator of RAS, accelerated liver tumor formation in mice. Loss of Nf1 or activation of RAS up-regulated the liver progenitor cell markers HMGA2 and SOX9. RAS pathway inhibitors suppressed the activation of the Hmga2 and Sox9 genes that resulted from loss of Nf1 or oncogenic activation of RAS. Knockdown of HMGA2 delayed formation of xenograft tumors from cells that expressed oncogenic RAS. In human HCCs, low levels of NF1 messenger RNA or high levels of HMGA2 messenger RNA were associated with shorter patient survival time. Liver cancer cells with inactivation of Plxnb1, Flrt2, and B9d1 formed more tumors in mice and had increased levels of mitogen-activated protein kinase phosphorylation. CONCLUSIONS: Using a CRISPR-based strategy, we identified Nf1, Plxnb1, Flrt2, and B9d1 as suppressors of liver tumor formation. We validated the observation that RAS signaling, via mitogen-activated protein kinase, contributes to formation of liver tumors in mice. We associated decreased levels of NF1 and increased levels of its downstream protein HMGA2 with survival times of patients with HCC. Strategies to inhibit or reduce HMGA2 might be developed to treat patients with liver cancer.

Our genome is constantly challenged by sources that cause DNA damage. To repair DNA damage and maintain genomic stability eukaryotes have evolved a complex network of pathways termed the DNA damage response (DDR). The DDR consists of signal transduction pathways that sense DNA damage and mediate tightly coordinated reactions to halt the cell cycle and repair DNA with a collection of different enzymes. In this manner, the DDR protects the genome by preventing the accumulation of mutations and DNA aberrations that promote cellular transformation and cancer development. Loss of function mutations in DDR genes and genomic instability occur frequently in many tumor types and underlie numerous cancer-prone hereditary syndromes such as Fanconi Anemia (FA). My thesis research applies candidate-based and unbiased experimental approaches to investigate the role of several tumor suppressor genes (TSGs) in the DDR. My dissertation will first describe a novel function for the breast and ovarian cancer tumor suppressor and FA-associated gene FANCJ in the DDR to ultraviolet (UV) irradiation. In response to UV irradiation FANCJ supports checkpoint induction, the arrest of DNA synthesis, and suppresses UV induced point mutations. Suggesting that FANCJ could suppress UV induced cancers, in sequenced melanomas from multiple databases I found somatic mutations in FANCJ previously associated with breast/ovarian cancer and FA syndrome. The second part of my dissertation will describe an RNA interference screen to identify genes modulating cellular sensitivity to the chemotherapeutic drug cisplatin. The hereditary breast/ovarian cancer tumor suppressor BRCA2 is essential for DNA repair, thus BRCA2 mutant ovarian cancer cells are initially sensitive to cisplatin chemotherapy that induces DNA damage. However, drug resistance develops and remains a major problem in the clinic. My screen identified the chromatin remodeling factor CHD4 as a potent modulator of cisplatin sensitivity and predictor of response to chemotherapy in BRCA2 mutant cancers. Taken together, my investigations highlight the important contribution of the DDR and the role they play in tumorigenesis and predicting therapeutic response.