Project description:Cancer is the second leading cause of death globally, and this is due primarily to metastatic dissemination to distal sites. Metastatic outgrowth requires that cancer cells delaminate from the primary tumor, intravasate, survive in circulation, extravasate, then migrate to and proliferate at a distal site. Recurrent genetic drivers of metastasis have remained elusive, suggesting that, unlike the initial steps of oncogenic transformation and primary tumor development, drivers of metastasis may be variable. Here, we develop a framework for interrogating pathways governing metastasis by applying CRISPR/Cas9-based forward genetic screening in a genetically defined tumor-organoid model of colorectal adenocarcinoma. We conduct in vitro screens for invasion and migration alongside orthotopic, in vivo screens for gain of metastatic potential in a syngeneic mouse model, identifying suppressors of metastasis both unique to the in vivo setting as well as common to both models. Specifically, we identify Ctnna1 and Bcl2l13 as bona fide metastasis suppressors acting through distinct mechanisms, with CTNNA1 loss promoting carcinoma cell invasion and migration through an atypical EMT-like mechanism, and BCL2L13 loss promoting cell survival after extracellular matrix detachment and non-cell-autonomous changes to macrophage polarization. Ultimately, this study provides a proof-of-principle that high-content forward genetic screening can be performed in tumor-organoid models in vivo and identifies novel regulators of colon cancer metastasis.

Project description:Cancer is the second leading cause of death globally, and this is due primarily to metastatic dissemination to distal sites. Metastatic outgrowth requires that cancer cells delaminate from the primary tumor, intravasate, survive in circulation, extravasate, then migrate to and proliferate at a distal site. Recurrent genetic drivers of metastasis have remained elusive, suggesting that, unlike the initial steps of oncogenic transformation and primary tumor development, drivers of metastasis may be variable. Here, we develop a framework for interrogating pathways governing metastasis by applying CRISPR/Cas9-based forward genetic screening in a genetically defined tumor-organoid model of colorectal adenocarcinoma. We conduct in vitro screens for invasion and migration alongside orthotopic, in vivo screens for gain of metastatic potential in a syngeneic mouse model, identifying suppressors of metastasis both unique to the in vivo setting as well as common to both models. Specifically, we identify Ctnna1 and Bcl2l13 as bona fide metastasis suppressors acting through distinct mechanisms, with CTNNA1 loss promoting carcinoma cell invasion and migration through an atypical EMT-like mechanism, and BCL2L13 loss promoting cell survival after extracellular matrix detachment and non-cell-autonomous changes to macrophage polarization. Ultimately, this study provides a proof-of-principle that high-content forward genetic screening can be performed in tumor-organoid models in vivo and identifies novel regulators of colon cancer metastasis.

Project description:Cancer is the second leading cause of death globally, and this is due primarily to metastatic dissemination to distal sites. Metastatic outgrowth requires that cancer cells delaminate from the primary tumor, intravasate, survive in circulation, extravasate, then migrate to and proliferate at a distal site. Recurrent genetic drivers of metastasis have remained elusive, suggesting that, unlike the initial steps of oncogenic transformation and primary tumor development, drivers of metastasis may be variable. Here, we develop a framework for interrogating pathways governing metastasis by applying CRISPR/Cas9-based forward genetic screening in a genetically defined tumor-organoid model of colorectal adenocarcinoma. We conduct in vitro screens for invasion and migration alongside orthotopic, in vivo screens for gain of metastatic potential in a syngeneic mouse model, identifying suppressors of metastasis both unique to the in vivo setting as well as common to both models. Specifically, we identify Ctnna1 and Bcl2l13 as bona fide metastasis suppressors acting through distinct mechanisms, with CTNNA1 loss promoting carcinoma cell invasion and migration through an atypical EMT-like mechanism, and BCL2L13 loss promoting cell survival after extracellular matrix detachment and non-cell-autonomous changes to macrophage polarization. Ultimately, this study provides a proof-of-principle that high-content forward genetic screening can be performed in tumor-organoid models in vivo and identifies novel regulators of colon cancer metastasis.

Project description:Most cancer deaths are due to metastatic dissemination to distant organs. Bone is the most frequently affected organ in metastatic prostate cancer and a major cause of prostate cancer deaths. Yet, our partial understanding of the molecular factors that drive bone metastasis has been a limiting factor for developing preventative and therapeutic strategies to improve patient survival and well-being. Although recent studies have uncovered molecular alterations that occur in prostate cancer metastasis, their functional relevance for bone metastasis is not well understood. Using genome-wide CRISPR activation and inhibition screens we have identified multiple drivers and suppressors of prostate cancer metastasis. Through functional validation, including innovative organ-on-a-chip invasion platform for studying bone tropism, our study identifies the transcriptional modulator, CITED2, as a novel driver of prostate cancer bone metastasis and uncovers multiple new potential molecular targets for bone metastatic disease.

Project description:Abstract: Accumulating experimental and clinical evidence suggest that the immune response to cancer is not exclusively anti-tumor. Indeed, the pro-tumor roles of the immune system - as suppliers of growth and pro-angiogenic factors or defenses against cytotoxic immune attacks, for example - have been long appreciated, but relatively few theoretical works have considered their effects. Inspired by the recently proposed "immune-mediated" theory of metastasis, we develop a mathematical model for tumor-immune interactions at two anatomically distant sites, which includes both anti- and pro-tumor immune effects, and the experimentally observed tumor-induced phenotypic plasticity of immune cells (tumor "education" of the immune cells). Upon confrontation of our model to experimental data, we use it to evaluate the implications of the immune-mediated theory of metastasis. We find that tumor education of immune cells may explain the relatively poor performance of immunotherapies, and that many metastatic phenomena, including metastatic blow-up, dormancy, and metastasis to sites of injury, can be explained by the immune-mediated theory of metastasis. Our results suggest that further work is warranted to fully elucidate the pro-tumor effects of the immune system in metastatic cancer.

Project description:Using a functional model of breast cancer heterogeneity, we previously showed that clonal sub-populations proficient at generating circulating tumour cells were not all equally capable of forming metastases at secondary sites1. A combination of differential expression and focused in vitro and in vivo RNAi screens revealed candidate drivers of metastasis that discriminated metastatic clones. Among these, Asparagine Synthetase (ASNS) expression in a patient’s primary tumour was most strongly correlated with later metastatic relapse. Here, we have shown that asparagine bioavailability strongly influences metastatic potential. Limiting asparagine by Asns knockdown, treatment with L-asparaginase, or dietary asparagine restriction reduced metastasis without impacting growth of the primary tumour, whereas increased dietary asparagine or enforced Asns expression promoted metastatic progression. Altering asparagine availability in vitro strongly influenced invasive potential, and this was correlated with an impact on proteins that promote the epithelial to mesenchymal transition. This provides at least one potential mechanism for how the bioavailability of a single amino acid could regulate metastatic progression.

Project description:To identify genes important for colorectal cancer (CRC) development and metastasis, we established a new metastatic mouse organoid model using Sleeping Beauty (SB) transposon mutagenesis. Intestinal organoids derived from mice carrying actively mobilizing SB transposons, an activating KrasG12D, and an inactivating ApcΔ716 allele, were transplanted to immunodeficient mice. Analysis of SB insertion sites in tumors identified numerous candidate cancer genes (CCGs) identified previously in intestinal SB screens performed in vivo, in addition to new CCGs, such as Atxn1. To provide functional validation, we knocked out Atxn1 in mouse tumor organoids carrying an activating KrasG12D, and an inactivating ApcΔ716 allele, and transplanted to mice. Tumor development was promoted when these gene were knocked out, demonstrating that these are potent tumor suppressors.

Project description:Metastasis is a complex multi-step process requiring the concerted action of many genes and is the primary cause of cancer deaths. Pathways that regulate metastasis enhancement and suppression both contribute to tumor dissemination process. In order to identify novel metastasis suppressors, we set up a forward genetic screen in a mouse model. We transduced a genome-wide RNAi library into the non-metastatic 168FARN breast cancer cell line, orthotopically transplanted the cells into mouse mammary fat pads, and then selected for cells that could metastasize to the lung and identified an RNAi for the KLF17 gene. Conversely, ectopic expression of KLF17 in highly metastatic 4T1 breast cancer cell line inhibited their ability to metastasize from the mammary fat pad to the lung. We showed that suppression of KLF17 expression promotes breast cancer cell invasion and epithelial-mesenchymal transition (EMT). We also showed that KLF17 functions by directly binding to the promoter of Id-1, a key metastasis regulator in breast cancer, to inhibit its transcription. Finally, we demonstrated that KLF17 expression is significantly down-regulated in primary human breast cancer samples and that the combined expression patterns of KLF17 and Id-1 can serve as a potential biomarker for lymph node metastasis in breast cancer.

Project description:<p>Breast Cancer Subject Participant ID 700064 (Source Sample names: 6888 and 206). We used massively parallel DNA sequencing technologies to screen entire genomes, in an unbiased manner, for genetic changes associated with tumor growth and metastasis. We describe the complete genome sequence analysis of four DNA samples from a 44-year old African-American patient with basal-like breast cancer: peripheral blood, the primary tumor, a brain metastasis that developed within a year of initial therapy, and a first-passage xenograft derived from the primary tumor. A total of 50 validated mutations were discovered within coding, RNA, or splice site sequences. Of these, 20 mutations were abundantly present in all three tumors, including mutations in <i>CSMD1</i> and <i>JAK2</i>. These two genes subsequently were found to be mutated in other breast tumors. The metastasis contained two <i>de novo</i> mutations not present in the primary tumor, and was significantly enriched for 20 shared mutations, suggesting that they may be involved in the metastatic process. The xenograft contained no unique coding, RNA, or splice site mutations and retained all primary tumor mutations, albeit at different frequencies. However, a significant increase in copy number alterations was observed in the xenograft as compared to the primary tumor. We validated 28 large deletions and six inversions, as well as seven translocations in at least one of the three tumor samples. Among them, a 26 kb deletion in <i>MECR</i> was solely identified, assembled, and validated in the brain metastasis and two overlapping large deletions on chromosome 5 encompassing <i>CTNNA1</i>, a potential tumor suppressor gene, were identified in all three tumors. The differential mutation frequencies and structural variation patterns between primary and metastatic tumors suggest that metastatic tumors may arise from minor subpopulations of cells within the primary. Namely, the metastatic and xenografting processes apparently select for cells harboring a distinct subset of the primary tumor mutation repertoire.</p>

Project description:Metastasis formation is the major cause for cancer-related deaths and the underlying mechanisms remain poorly understood. In this study we describe spontaneous metastasis xenograft mouse models of human neuroblastoma used for unbiased identification of metastasis-related proteins by applying an infrared laser (IR) for sampling primary tumor and metastatic tissues, followed by mass spectrometric proteome analysis. IR aerosol samples were obtained from ovarian and liver metastases, which were indicated by bioluminescence imaging (BLI), and matched subcutaneous primary tumors. Corresponding histology proved the human origin of metastatic lesions. Ovarian metastases were commonly larger than liver metastases indicating differential outgrowth capacities. Among ~1,700 proteins identified at each of the three sites, 89 proteins were differentially regulated in ovarian metastases while 290 proteins were regulated in liver metastases. There was an overlap of 26 and 10 proteins up- and down-regulated at both metastatic sites, respectively, most of which were so far not related to metastasis such as LYPLA2, ACTL8, EIF4B, LGALS7, GFAP, and ELAVL4. Moreover, we established in vitro sublines from primary tumor and metastases and demonstrate differences in cellular protrusions, migratory/invasive potential and glycosylation. Summarized, this work identified several novel putative drivers of metastasis formation that are tempting candidates for future functional studies.