Caitlin Bourque

Transparent adult zebrafish as a tool for in vivo transplantation analysis.

The zebrafish is a useful model for understanding normal and cancer stem cells, but analysis has been limited to embryogenesis due to the opacity of the adult fish. To address this, we have created a transparent adult zebrafish in which we transplanted either hematopoietic stem/progenitor cells or tumor cells. In a hematopoiesis radiation recovery assay, transplantation of GFP-labeled marrow cells allowed for striking in vivo visual assessment of engraftment from 2 hr-5 weeks posttransplant. Using FACS analysis, both transparent and wild-type fish had equal engraftment, but this could only be visualized in the transparent recipient. In a tumor engraftment model, transplantation of RAS-melanoma cells allowed for visualization of tumor engraftment, proliferation, and distant metastases in as little as 5 days, which is not seen in wild-type recipients until 3 to 4 weeks. This transparent adult zebrafish serves as the ideal combination of both sensitivity and resolution for in vivo stem cell analyses.

The histone methyltransferase SETDB1 is recurrently amplified in melanoma and accelerates its onset

The most common mutation in melanoma, BRAF(V600E), activates the BRAF serine/threonine kinase and causes excessive MAPK pathway activity1,2. BRAF(V600E)mutations are also present in benign melanocytic nevi3, highlighting the importance of additional genetic alterations in the genesis of malignant tumors. Such changes include recurrent copy number variations that result in the amplification of oncogenes4,5. For certain amplifications, the large number of genes in the interval has precluded an understanding of cooperating oncogenic events. Here, we have used a zebrafish melanoma model to test genes in a recurrently amplified region on chromosome 1 for the ability to cooperate with BRAF(V600E) and accelerate melanoma. SETDB1, an enzyme that methylates histone H3 on lysine 9 (H3K9), was found to significantly accelerate melanoma formation in the zebrafish. Chromatin immunoprecipitation coupled with massively parallel DNA sequencing (ChIP-Seq) and gene expression analyses revealed target genes, including Hox genes, that are transcriptionally dysregulated in response to elevated SETDB1. Our studies establish SETDB1 as an oncogene in melanoma and underscore the role of chromatin factors in regulating tumorigenesis.

APC mutant zebrafish uncover a changing temporal requirement for wnt signaling in liver development.

Developmental signaling pathways hold the keys to unlocking the promise of adult tissue regeneration, and to inhibiting carcinogenesis. Patients with mutations in the Adenomatous Polyposis Coli (APC) gene are at increased risk of developing hepatoblastoma, an embryonal form of liver cancer, suggesting that Wnt affects hepatic progenitor cells. To elucidate the role of APC loss and enhanced Wnt activity in liver development, we examined APC mutant and wnt inducible transgenic zebrafish. APC(+/-) embryos developed enlarged livers through biased induction of hepatic gene programs and increased proliferation. Conversely, APC(-/-) embryos formed no livers. Blastula transplantations determined that the effects of APC loss were cell autonomous. Induction of wnt modulators confirmed biphasic consequences of wnt activation: endodermal pattern formation and gene expression required suppression of wnt signaling in early somitogenesis; later, increased wnt activity altered endodermal fate by enhancing liver growth at the expense of pancreas formation; these effects persisted into the larval stage. In adult APC(+/-) zebrafish, increased wnt activity significantly accelerated liver regeneration after partial hepatectomy. Similarly, liver regeneration was significantly enhanced in APC(Min/+) mice, indicating the conserved effect of Wnt pathway activation in liver regeneration across vertebrate species. These studies reveal an important and time-dependent role for wnt signaling during liver development and regeneration.

Co-injection strategies to modify radiation sensitivity and tumor initiation in transgenic Zebrafish

The zebrafish has emerged as a powerful genetic model of cancer, but has been limited by the use of stable transgenic approaches to induce disease. Here, a co-injection strategy is described that capitalizes on both the numbers of embryos that can be microinjected and the ability of transgenes to segregate together and exert synergistic effects in forming tumors. Using this mosaic transgenic approach, gene pathways involved in tumor initiation and radiation sensitivity have been identified.

Imaging tumour cell heterogeneity following cell transplantation into optically clear immune-deficient zebrafish

Cancers contain a wide diversity of cell types that are defined by differentiation states, genetic mutations and altered epigenetic programmes that impart functional diversity to individual cells. Elevated tumour cell heterogeneity is linked with progression, therapy resistance and relapse. Yet, imaging of tumour cell heterogeneity and the hallmarks of cancer has been a technical and biological challenge. Here we develop optically clear immune-compromised rag2E450fs (casper) zebrafish for optimized cell transplantation and direct visualization of fluorescently labelled cancer cells at single-cell resolution. Tumour engraftment permits dynamic imaging of neovascularization, niche partitioning of tumour-propagating cells in embryonal rhabdomyosarcoma, emergence of clonal dominance in T-cell acute lymphoblastic leukaemia and tumour evolution resulting in elevated growth and metastasis in BRAFV600E-driven melanoma. Cell transplantation approaches using optically clear immune-compromised zebrafish provide unique opportunities to uncover biology underlying cancer and to dynamically visualize cancer processes at single-cell resolution in vivo.

RSK1 activation promotes invasion in nodular melanoma

Materials and methods Expression of 141 signaling proteins was evaluated by protein pathway array in 3 Radial Growth Phase (RGP)/ SSM and 3 Vertical Growth Phase (VGP)/NM cell lines. The impact of p90-ribosomal-S6-kinase (RSK1) and its inhibition on proliferation, migration and invasion was assessed in SSM and NM cell lines, and confirmed using NM cells treated with a RSK inhibitor (BI-D1870) in microarray profiling studies. The effect of constitutive RSK1 activation in vivo was further studied using a zebrafish model.

Hooked on zebrafish: insights into development and cancer of endocrine tissues

Zebrafish is emerging as a unique model organism for studying cancer genetics and biology. For several decades zebrafish have been used to study vertebrate development, where they have made important contributions to understanding the specification and differentiation programs in many tissues. Recently, zebrafish studies have led to important insights into thyroid development, and have been used to model endocrine cancer. Zebrafish possess a unique set of attributes that make them amenable to forward and reverse genetic approaches. Zebrafish embryos develop rapidly and can be used to study specific cell lineages or the effects of chemicals on pathways or tissue development. In this review, we highlight the structure and function of endocrine organs in zebrafish and outline the major achievements in modeling cancer. Our goal is to familiarize readers with the zebrafish as a genetic model system and propose opportunities for endocrine cancer research in zebrafish.

KIT Suppresses BRAFV600E-Mutant Melanoma by Attenuating Oncogenic RAS/MAPK Signaling

The receptor tyrosine kinase KIT promotes survival and migration of melanocytes during development, and excessive KIT activity hyperactivates the RAS/MAPK pathway and can drive formation of melanomas, most notably of rare melanomas that occur on volar and mucosal surfaces of the skin. The much larger fraction of melanomas that occur on sun-exposed skin is driven primarily by BRAF- or NRAS-activating mutations, but these melanomas exhibit a surprising loss of KIT expression, which raises the question of whether loss of KIT in these tumors facilitates tumorigenesis. To address this question, we introduced a kit(lf) mutation into a strain of Tg(mitfa:BRAFV600E); p53(lf) melanoma-prone zebrafish. Melanoma onset was accelerated in kit(lf); Tg(mitfa:BRAFV600E); p53(lf) fish. Tumors from kit(lf) animals were more invasive and had higher RAS/MAPK pathway activation. KIT knockdown also increased RAS/MAPK pathway activation in a BRAFV600E-mutant human melanoma cell line. We found that pathway stimulation upstream of BRAFV600E could paradoxically reduce signaling downstream of BRAFV600E, and wild-type BRAF was necessary for this effect, suggesting that its activation can dampen oncogenic BRAFV600E signaling. In vivo, expression of wild-type BRAF delayed melanoma onset, but only in a kit-dependent manner. Together, these results suggest that KIT can activate signaling through wild-type RAF proteins, thus interfering with oncogenic BRAFV600E-driven melanoma formation. Cancer Res; 77(21); 5820-30. ©2017 AACR.

Abstract 5020: Genetic and epigenetic analysis of tumors in a zebrafish model of melanoma

Proceedings: AACR 103rd Annual Meeting 2012‐‐ Mar 31‐Apr 4, 2012; Chicago, IL The activating BRAF kinase mutation V600E occurs in ∼60% of human nevi and melanomas. A transgenic strain of zebrafish expressing BRAF-V600E under the control of the mitfa promoter on a p53 mutant background develops melanomas with 100% penetrance. Previously, we showed that a transposon-based vector, MiniCoopR, allows us to program melanocytes to express a candidate gene in a specialized zebrafish strain Tg(mitfa:BRAFV600E); mitfa-/-; p53-/-. This strain lacks melanocytes, but the lineage can be rescued by MiniCoopR injection at the 1-cell stage. This genetic system allows us to create cohorts of transgenic animals that express candidate genes and assay the effects on tumor development. Previous work identified two histone methyltransferases (HMTs), SETDB1 and SUV39H1, which cooperate with BRAF-V600E to accelerate the onset and severity of melanoma development. A number of HMTs display alterations in expression level or copy number in human cancers compared to normal tissues, and we tested a panel of methyltransferases using the MiniCoopR system. We hypothesize that HMTs promote tumorigenesis by altering the epigenetic program of melanocytes. In order to explore the effects on melanocyte specification and differentiation, we overexpressed and depleted candidate HMTs in zebrafish embryos and performed in situ hybridization for lineage-specific markers, such as crestin, sox10, mitfa, dct, and tyr. HMTs that exert specific developmental phenotypes were further characterized by performing chromatin immunoprecipitation (ChIP). Our goal is to correlate the processes affected in the developing embryo with the epigenetic program to elucidate the mechanism by which HMTs influence tumorigenesis. Additionally, we are developing a strain of zebrafish Tg(mitfa:BRAFV600E); mitfa-/-; alb-/-; p53-/-; Tg(mitfa:GFP) in which melanocytes rescued with MiniCoopR express GFP. These rescued melanocytes can be programmed to express candidate HMTs and allow us to visualize melanocyte and melanoma development in vivo. The work presented here will help correlate cancer phenotypes with specific chromatin-modifying enzymes that may be the basis for new drug development and biomarker discovery. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 5020. doi:1538-7445.AM2012-5020

Multiplexing of ChIP-Seq Samples in an Optimized Experimental Condition Has Minimal Impact on Peak Detection

Multiplexing samples in sequencing experiments is a common approach to maximize information yield while minimizing cost. In most cases the number of samples that are multiplexed is determined by financial consideration or experimental convenience, with limited understanding on the effects on the experimental results. Here we set to examine the impact of multiplexing ChIP-seq experiments on the ability to identify a specific epigenetic modification. We performed peak detection analyses to determine the effects of multiplexing. These include false discovery rates, size, position and statistical significance of peak detection, and changes in gene annotation. We found that, for histone marker H3K4me3, one can multiplex up to 8 samples (7 IP + 1 input) at ~21 million single-end reads each and still detect over 90% of all peaks found when using a full lane for sample (~181 million reads). Furthermore, there are no variations introduced by indexing or lane batch effects and importantly there is no significant reduction in the number of genes with neighboring H3K4me3 peaks. We conclude that, for a well characterized antibody and, therefore, model IP condition, multiplexing 8 samples per lane is sufficient to capture most of the biological signal.