Multi-Omic Approaches Identify Metabolic and Autophagy Regulators Important in Ovarian Cancer Dissemination

High-grade serous ovarian cancers (HGSOCs) arise from exfoliation of transformed cells from the fallopian tube, indicating that survival in suspension, and potentially escape from anoikis, is required for dissemination. We report here the results of a multi-omic study to identify drivers of anoikis...

Descripción completa

Detalles Bibliográficos
Autores principales: Wheeler, Lindsay J., Watson, Zachary L., Qamar, Lubna, Yamamoto, Tomomi M., Sawyer, Brandon T., Sullivan, Kelly D., Khanal, Santosh, Joshi, Molishree, Ferchaud-Roucher, Veronique, Smith, Harry, Vanderlinden, Lauren A., Brubaker, Sky W., Caino, Cecilia M., Kim, Hyunmin, Espinosa, Joaquin M., Richer, Jennifer K., Bitler, Benjamin G.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Elsevier 2019
Materias:
Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6710300/
https://www.ncbi.nlm.nih.gov/pubmed/31437751
http://dx.doi.org/10.1016/j.isci.2019.07.049
_version_ 1783446320253501440
author Wheeler, Lindsay J.
Watson, Zachary L.
Qamar, Lubna
Yamamoto, Tomomi M.
Sawyer, Brandon T.
Sullivan, Kelly D.
Khanal, Santosh
Joshi, Molishree
Ferchaud-Roucher, Veronique
Smith, Harry
Vanderlinden, Lauren A.
Brubaker, Sky W.
Caino, Cecilia M.
Kim, Hyunmin
Espinosa, Joaquin M.
Richer, Jennifer K.
Bitler, Benjamin G.
author_facet Wheeler, Lindsay J.
Watson, Zachary L.
Qamar, Lubna
Yamamoto, Tomomi M.
Sawyer, Brandon T.
Sullivan, Kelly D.
Khanal, Santosh
Joshi, Molishree
Ferchaud-Roucher, Veronique
Smith, Harry
Vanderlinden, Lauren A.
Brubaker, Sky W.
Caino, Cecilia M.
Kim, Hyunmin
Espinosa, Joaquin M.
Richer, Jennifer K.
Bitler, Benjamin G.
author_sort Wheeler, Lindsay J.
collection PubMed
description High-grade serous ovarian cancers (HGSOCs) arise from exfoliation of transformed cells from the fallopian tube, indicating that survival in suspension, and potentially escape from anoikis, is required for dissemination. We report here the results of a multi-omic study to identify drivers of anoikis escape, including transcriptomic analysis, global non-targeted metabolomics, and a genome-wide CRISPR/Cas9 knockout (GeCKO) screen of HGSOC cells cultured in adherent and suspension settings. Our combined approach identified known pathways, including NOTCH signaling, as well as novel regulators of anoikis escape. Newly identified genes include effectors of fatty acid metabolism, ACADVL and ECHDC2, and an autophagy regulator, ULK1. Knockdown of these genes significantly inhibited suspension growth of HGSOC cells, and the metabolic profile confirmed the role of fatty acid metabolism in survival in suspension. Integration of our datasets identified an anoikis-escape gene signature that predicts overall survival in many carcinomas.
format Online
Article
Text
id pubmed-6710300
institution National Center for Biotechnology Information
language English
publishDate 2019
publisher Elsevier
record_format MEDLINE/PubMed
spelling pubmed-67103002019-08-28 Multi-Omic Approaches Identify Metabolic and Autophagy Regulators Important in Ovarian Cancer Dissemination Wheeler, Lindsay J. Watson, Zachary L. Qamar, Lubna Yamamoto, Tomomi M. Sawyer, Brandon T. Sullivan, Kelly D. Khanal, Santosh Joshi, Molishree Ferchaud-Roucher, Veronique Smith, Harry Vanderlinden, Lauren A. Brubaker, Sky W. Caino, Cecilia M. Kim, Hyunmin Espinosa, Joaquin M. Richer, Jennifer K. Bitler, Benjamin G. iScience Article High-grade serous ovarian cancers (HGSOCs) arise from exfoliation of transformed cells from the fallopian tube, indicating that survival in suspension, and potentially escape from anoikis, is required for dissemination. We report here the results of a multi-omic study to identify drivers of anoikis escape, including transcriptomic analysis, global non-targeted metabolomics, and a genome-wide CRISPR/Cas9 knockout (GeCKO) screen of HGSOC cells cultured in adherent and suspension settings. Our combined approach identified known pathways, including NOTCH signaling, as well as novel regulators of anoikis escape. Newly identified genes include effectors of fatty acid metabolism, ACADVL and ECHDC2, and an autophagy regulator, ULK1. Knockdown of these genes significantly inhibited suspension growth of HGSOC cells, and the metabolic profile confirmed the role of fatty acid metabolism in survival in suspension. Integration of our datasets identified an anoikis-escape gene signature that predicts overall survival in many carcinomas. Elsevier 2019-08-06 /pmc/articles/PMC6710300/ /pubmed/31437751 http://dx.doi.org/10.1016/j.isci.2019.07.049 Text en © 2019 The Author(s) http://creativecommons.org/licenses/by-nc-nd/4.0/ This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
spellingShingle Article
Wheeler, Lindsay J.
Watson, Zachary L.
Qamar, Lubna
Yamamoto, Tomomi M.
Sawyer, Brandon T.
Sullivan, Kelly D.
Khanal, Santosh
Joshi, Molishree
Ferchaud-Roucher, Veronique
Smith, Harry
Vanderlinden, Lauren A.
Brubaker, Sky W.
Caino, Cecilia M.
Kim, Hyunmin
Espinosa, Joaquin M.
Richer, Jennifer K.
Bitler, Benjamin G.
Multi-Omic Approaches Identify Metabolic and Autophagy Regulators Important in Ovarian Cancer Dissemination
title Multi-Omic Approaches Identify Metabolic and Autophagy Regulators Important in Ovarian Cancer Dissemination
title_full Multi-Omic Approaches Identify Metabolic and Autophagy Regulators Important in Ovarian Cancer Dissemination
title_fullStr Multi-Omic Approaches Identify Metabolic and Autophagy Regulators Important in Ovarian Cancer Dissemination
title_full_unstemmed Multi-Omic Approaches Identify Metabolic and Autophagy Regulators Important in Ovarian Cancer Dissemination
title_short Multi-Omic Approaches Identify Metabolic and Autophagy Regulators Important in Ovarian Cancer Dissemination
title_sort multi-omic approaches identify metabolic and autophagy regulators important in ovarian cancer dissemination
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6710300/
https://www.ncbi.nlm.nih.gov/pubmed/31437751
http://dx.doi.org/10.1016/j.isci.2019.07.049
work_keys_str_mv AT wheelerlindsayj multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT watsonzacharyl multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT qamarlubna multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT yamamototomomim multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT sawyerbrandont multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT sullivankellyd multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT khanalsantosh multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT joshimolishree multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT ferchaudroucherveronique multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT smithharry multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT vanderlindenlaurena multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT brubakerskyw multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT cainoceciliam multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT kimhyunmin multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT espinosajoaquinm multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT richerjenniferk multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination
AT bitlerbenjaming multiomicapproachesidentifymetabolicandautophagyregulatorsimportantinovariancancerdissemination

Ejemplares similares