Norepinephrine induces anoikis resistance in high-grade serous ovarian cancer precursor cells
Hunter D. Reavis, … , Laura M. Sanchez, Ronny Drapkin
Hunter D. Reavis, … , Laura M. Sanchez, Ronny Drapkin
Published January 25, 2024
Citation Information: JCI Insight. 2024;9(5):e170961. https://doi.org/10.1172/jci.insight.170961.
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Research Article Cell biology Oncology

Norepinephrine induces anoikis resistance in high-grade serous ovarian cancer precursor cells

Abstract

High-grade serous carcinoma (HGSC) is the most lethal gynecological malignancy in the United States. Late diagnosis and the emergence of chemoresistance have prompted studies into how the tumor microenvironment, and more recently tumor innervation, may be leveraged for HGSC prevention and interception. In addition to stess-induced sources, concentrations of the sympathetic neurotransmitter norepinephrine (NE) in the ovary increase during ovulation and after menopause. Importantly, NE exacerbates advanced HGSC progression. However, little is known about the role of NE in early disease pathogenesis. Here, we investigated the role of NE in instigating anchorage independence and micrometastasis of preneoplastic lesions from the fallopian tube epithelium (FTE) to the ovary, an essential step in HGSC onset. We found that in the presence of NE, FTE cell lines were able to survive in ultra-low-attachment (ULA) culture in a β-adrenergic receptor–dependent (β-AR–dependent) manner. Importantly, spheroid formation and cell viability conferred by treatment with physiological sources of NE were abrogated using the β-AR blocker propranolol. We have also identified that NE-mediated anoikis resistance may be attributable to downregulation of colony-stimulating factor 2. These findings provide mechanistic insight and identify targets that may be regulated by ovary-derived NE in early HGSC.

Authors

Hunter D. Reavis, Stefan M. Gysler, Grace B. McKenney, Matthew Knarr, Hannah J. Lusk, Priyanka Rawat, Hannah S. Rendulich, Marilyn A. Mitchell, Dara S. Berger, Jamie S. Moon, Suyeon Ryu, Monica Mainigi, Marcin P. Iwanicki, Dave S. Hoon, Laura M. Sanchez, Ronny Drapkin

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Figure 5

NE activates ADRβ-dependent transcriptional changes.

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NE activates ADRβ-dependent transcriptional changes. (A) Experimental de...
(A) Experimental design for bulk RNA sequencing of FT237 and FT246 cells grown under ULA conditions for 4 and 24 hours, with or without 10 μM NE and/or 10 μM propranolol. (B) Volcano plots of differentially expressed transcripts upregulated (magenta) and downregulated (cyan) upon NE treatment relative to vehicle-treated cells at 24 hours. CSF2, colony-stimulating factor 2. (C) Volcano plots of differentially expressed transcripts upregulated (magenta) and downregulated (cyan) upon propranolol and NE treatment relative to NE treatment alone at 24 hours. (D) Heatmap of common transcripts between FT237 and FT246 cells whose NE-induced expression levels are abrogated upon cotreatment with propranolol at 24 hours; all transcript values are normalized to untreated 2D control cells. N, norepinephrine; NP, norepinephrine + propranolol; P, propranolol. (E) Ingenuity Pathway Analysis results for disease-related pathways enriched in NE-treated cells at the 24-hour time point.