Embryonal rhabdomyosarcoma (ERMS) is a devastating malignancy of muscle that is diagnosed in hundreds of children and adults annually in the United States. Survival rates are less than 30% in patients with unresectable, metastatic, or relapsed RMS, with continued tumor growth and metastasis being initiated by a subset of cells called tumor propagating cells (TPCs). Yet, to date, targeted approaches to kill TPCs or to differentiate them into non-proliferative, differentiated ERMS cell types have not been developed. The long- term goal of our work is to uncover therapeutically relevant pathways that curb ERMS growth by killing or differentiating the TPCs. The overall objective of this application is to determine the extent to which the NOTCH1 pathway regulates self-renewal within TPCs and metastasis of ERMS. Our central hypothesis is that NOTCH1 pathway activation supports ERMS growth by specifically inducing self-renewal while also elevating the proclivity for metastasis. Our preliminary data indicate a prominent role for NOTCH1 in regulating TPC self- renewal in both zebrafish and human ERMS. Importantly, NOTCH1 pathway inactivation also led to a dramatic tumor shrinkage of human ERMS xenografts, while NOTCH1 pathway activation induced metastatic progression in our zebrafish tumor model. The rationale underlying our research is that the NOTCH1 pathway is active in 60% of human ERMS, is linked with a poor outcome, and is required for continued tumor growth in vivo, suggesting that targeting this pathway would benefit a large fraction of high-risk patients.
Aim 1 will dynamically visualize the effects of NOTCH1 pathway activation on ERMS self-renewal and metastasis in a fluorescent-transgenic zebrafish model that accurately recapitulates the molecular and histopathogenesis of the human disease. These experiments are designed to establish that NOTCH1 increases self-renewal and elevates metastatic progression.
Aim 2 will elucidate the molecular mechanisms regulated by intracellular NOTCH1 (ICN1) in human ERMS, by testing whether the ICN1/SNAIL1 axis enhances human ERMS self- renewal by suppressing terminal differentiation through MEF2C and whether ICN1 is stabilized intracellularly by loss of FBXW7, a ubiquitin-ligase known to degrade intracellular NOTCH1 and which is mutationally inactivated in a subset of human ERMS.
Aim 3 will assess NOTCH1 antibody inhibitors for their preclinical efficacy in patient derived xenografts of human ERMS. Our work will uncover the molecular pathways by which ICN1 drives ERMS growth, self-renewal and metastasis. Such insights will provide new biomarkers for assessing drug effects on TPCs and will likely identify novel drug targets beyond NOTCH1 for the treatment of ERMS. Our work is predicted to have a large positive translational impact, as it will directly address the feasibility and likely benefit of using new NOTCH1 blocking antibody to treat human ERMS. These findings will be relevant to applying these same antibody therapies to a wide range of NOTCH1-dependent human tumors.

Public Health Relevance

The NOTCH1 pathway is active in a majority of human rhabdomyosarcoma and has potent roles in elevating self-renewal, growth, and likely metastasis in the embryonal RMS subtype (ERMS). Here, we will uncover the molecular mechanisms by which the NOTCH1 pathway regulates ERMS growth. We will also directly assess the therapeutic benefit of NOTCH1 inhibitory antibodies in preclinical patient-derived xenograft models of ERMS.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
2R01CA154923-06A1
Application #
9237548
Study Section
Cancer Molecular Pathobiology Study Section (CAMP)
Program Officer
Espey, Michael G
Project Start
2011-03-01
Project End
2022-02-28
Budget Start
2017-03-01
Budget End
2018-02-28
Support Year
6
Fiscal Year
2017
Total Cost
Indirect Cost
Name
Massachusetts General Hospital
Department
Type
DUNS #
073130411
City
Boston
State
MA
Country
United States
Zip Code
02114
Ignatius, Myron S; Hayes, Madeline N; Moore, Finola E et al. (2018) tp53 deficiency causes a wide tumor spectrum and increases embryonal rhabdomyosarcoma metastasis in zebrafish. Elife 7:
Hayes, Madeline N; McCarthy, Karin; Jin, Alexander et al. (2018) Vangl2/RhoA Signaling Pathway Regulates Stem Cell Self-Renewal Programs and Growth in Rhabdomyosarcoma. Cell Stem Cell 22:414-427.e6
Ignatius, Myron S; Hayes, Madeline N; Lobbardi, Riadh et al. (2017) The NOTCH1/SNAIL1/MEF2C Pathway Regulates Growth and Self-Renewal in Embryonal Rhabdomyosarcoma. Cell Rep 19:2304-2318
Berberoglu, Michael A; Gallagher, Thomas L; Morrow, Zachary T et al. (2017) Satellite-like cells contribute to pax7-dependent skeletal muscle repair in adult zebrafish. Dev Biol 424:162-180
Moore, John C; Tang, Qin; Yordán, Nora Torres et al. (2016) Single-cell imaging of normal and malignant cell engraftment into optically clear prkdc-null SCID zebrafish. J Exp Med 213:2575-2589
Tang, Qin; Moore, John C; Ignatius, Myron S et al. (2016) Imaging tumour cell heterogeneity following cell transplantation into optically clear immune-deficient zebrafish. Nat Commun 7:10358
Ignatius, Myron S; Hayes, Madeline; Langenau, David M (2016) In Vivo Imaging of Cancer in Zebrafish. Adv Exp Med Biol 916:219-37
Moore, John C; Langenau, David M (2016) Allograft Cancer Cell Transplantation in Zebrafish. Adv Exp Med Biol 916:265-87
Moore, John C; Mulligan, Timothy S; Torres Yordán, Nora et al. (2016) T cell immune deficiency in zap70 mutant zebrafish. Mol Cell Biol :
Langenau, David M; Sweet-Cordero, Alejandro; Wechsler-Reya, Robert et al. (2015) Preclinical Models Provide Scientific Justification and Translational Relevance for Moving Novel Therapeutics into Clinical Trials for Pediatric Cancer. Cancer Res 75:5176-5186

Showing the most recent 10 out of 25 publications