Pattern of invasion in human pancreatic cancer organoids is associated with loss of SMAD4 and clinical outcome

Wenjie Huang; Bernat Navarro-Serer; Yea Ji Jeong; Peter Chianchiano; Limin Xia; Claudio Luchini; Nicola Veronese; Cameron Dowiak; Tammy Ng; Maria A. Trujillo; Bo Huang; Michael J. Pfluger; Anne M. Macgregor-Das; Gemma Lionheart; Danielle Jones; Kohei Fujikura; Kim Vy Nguyen-Ngoc; Neil M. Neumann; Vincent P. Groot; Alina Hasanain; A. Floortje van Oosten; Sandra E. Fischer; Steven Gallinger; Aatur D. Singhi; Amer H. Zureikat; Randall E. Brand; Matthias M. Gaida; Stefan Heinrich; Richard A. Burkhart; Jin He; Christopher L. Wolfgang; Michael G. Goggins; Elizabeth D. Thompson; Nicholas J. Roberts; Andrew J. Ewald; Laura D. Wood

doi:10.1158/0008-5472.CAN-19-1523

Pattern of invasion in human pancreatic cancer organoids is associated with loss of SMAD4 and clinical outcome

Wenjie Huang, Bernat Navarro-Serer, Yea Ji Jeong, Peter Chianchiano, Limin Xia, Claudio Luchini, Nicola Veronese, Cameron Dowiak, Tammy Ng, Maria A. Trujillo, Bo Huang, Michael J. Pfluger, Anne M. Macgregor-Das, Gemma Lionheart, Danielle Jones, Kohei Fujikura, Kim Vy Nguyen-Ngoc, Neil M. Neumann, Vincent P. Groot, Alina HasanainA. Floortje van Oosten, Sandra E. Fischer, Steven Gallinger, Aatur D. Singhi, Amer H. Zureikat, Randall E. Brand, Matthias M. Gaida, Stefan Heinrich, Richard A. Burkhart, Jin He, Christopher L. Wolfgang, Michael G. Goggins, Elizabeth D. Thompson, Nicholas J. Roberts, Andrew J. Ewald, Laura D. Wood

School of Medicine

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

Pancreatic ductal adenocarcinoma (PDAC) is an aggressive malignancy characterized by extensive local invasion and systemic spread. In this study, we employed a three-dimensional organoid model of human pancreatic cancer to characterize the molecular alterations critical for invasion. Time-lapse microscopy was used to observe invasion in organoids from 25 surgically resected human PDAC samples in collagen I. Subsequent lentiviral modification and small-molecule inhibitors were used to investigate the molecular programs underlying invasion in PDAC organoids. When cultured in collagen I, PDAC organoids exhibited two distinct, morphologically defined invasive phenotypes, mesenchymal and collective. Each individual PDAC gave rise to organoids with a predominant phenotype, and PDAC that generated organoids with predominantly mesenchymal invasion showed a worse prognosis. Collective invasion predominated in organoids from cancers with somatic mutations in the driver gene SMAD4 (or its signaling partner TGFBR2). Reexpression of SMAD4 abrogated the collective invasion phenotype in SMAD4-mutant PDAC organoids, indicating that SMAD4 loss is required for collective invasion in PDAC organoids. Surprisingly, invasion in passaged SMAD4-mutant PDAC organoids required exogenous TGFb, suggesting that invasion in SMAD4-mutant organoids is mediated through noncanonical TGFb signaling. The Rho-like GTPases RAC1 and CDC42 acted as potential mediators of TGFb-stimulated invasion in SMAD4-mutant PDAC organoids, as inhibition of these GTPases suppressed collective invasion in our model. These data suggest that PDAC utilizes different invasion programs depending on SMAD4 status, with collective invasion uniquely present in PDAC with SMAD4 loss.

Original language	English (US)
Pages (from-to)	2804-2817
Number of pages	14
Journal	Cancer Research
Volume	80
Issue number	13
DOIs	https://doi.org/10.1158/0008-5472.CAN-19-1523
State	Published - Jul 1 2020

ASJC Scopus subject areas

Oncology
Cancer Research

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10.1158/0008-5472.CAN-19-1523

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Huang, W., Navarro-Serer, B., Jeong, Y. J., Chianchiano, P., Xia, L., Luchini, C., Veronese, N., Dowiak, C., Ng, T., Trujillo, M. A., Huang, B., Pfluger, M. J., Macgregor-Das, A. M., Lionheart, G., Jones, D., Fujikura, K., Nguyen-Ngoc, K. V., Neumann, N. M., Groot, V. P., ... Wood, L. D. (2020). Pattern of invasion in human pancreatic cancer organoids is associated with loss of SMAD4 and clinical outcome. Cancer Research, 80(13), 2804-2817. https://doi.org/10.1158/0008-5472.CAN-19-1523

Huang, W, Navarro-Serer, B, Jeong, YJ, Chianchiano, P, Xia, L, Luchini, C, Veronese, N, Dowiak, C, Ng, T, Trujillo, MA, Huang, B, Pfluger, MJ, Macgregor-Das, AM, Lionheart, G, Jones, D, Fujikura, K, Nguyen-Ngoc, KV, Neumann, NM, Groot, VP, Hasanain, A, Floortje van Oosten, A, Fischer, SE, Gallinger, S, Singhi, AD, Zureikat, AH, Brand, RE, Gaida, MM, Heinrich, S, Burkhart, RA , He, J, Wolfgang, CL, Goggins, MG , Thompson, ED , Roberts, NJ , Ewald, AJ & Wood, LD 2020, 'Pattern of invasion in human pancreatic cancer organoids is associated with loss of SMAD4 and clinical outcome', Cancer Research, vol. 80, no. 13, pp. 2804-2817. https://doi.org/10.1158/0008-5472.CAN-19-1523

@article{dd0a4ece18724355afd4586c7a32542b,

title = "Pattern of invasion in human pancreatic cancer organoids is associated with loss of SMAD4 and clinical outcome",

abstract = "Pancreatic ductal adenocarcinoma (PDAC) is an aggressive malignancy characterized by extensive local invasion and systemic spread. In this study, we employed a three-dimensional organoid model of human pancreatic cancer to characterize the molecular alterations critical for invasion. Time-lapse microscopy was used to observe invasion in organoids from 25 surgically resected human PDAC samples in collagen I. Subsequent lentiviral modification and small-molecule inhibitors were used to investigate the molecular programs underlying invasion in PDAC organoids. When cultured in collagen I, PDAC organoids exhibited two distinct, morphologically defined invasive phenotypes, mesenchymal and collective. Each individual PDAC gave rise to organoids with a predominant phenotype, and PDAC that generated organoids with predominantly mesenchymal invasion showed a worse prognosis. Collective invasion predominated in organoids from cancers with somatic mutations in the driver gene SMAD4 (or its signaling partner TGFBR2). Reexpression of SMAD4 abrogated the collective invasion phenotype in SMAD4-mutant PDAC organoids, indicating that SMAD4 loss is required for collective invasion in PDAC organoids. Surprisingly, invasion in passaged SMAD4-mutant PDAC organoids required exogenous TGFb, suggesting that invasion in SMAD4-mutant organoids is mediated through noncanonical TGFb signaling. The Rho-like GTPases RAC1 and CDC42 acted as potential mediators of TGFb-stimulated invasion in SMAD4-mutant PDAC organoids, as inhibition of these GTPases suppressed collective invasion in our model. These data suggest that PDAC utilizes different invasion programs depending on SMAD4 status, with collective invasion uniquely present in PDAC with SMAD4 loss.",

author = "Wenjie Huang and Bernat Navarro-Serer and Jeong, {Yea Ji} and Peter Chianchiano and Limin Xia and Claudio Luchini and Nicola Veronese and Cameron Dowiak and Tammy Ng and Trujillo, {Maria A.} and Bo Huang and Pfluger, {Michael J.} and Macgregor-Das, {Anne M.} and Gemma Lionheart and Danielle Jones and Kohei Fujikura and Nguyen-Ngoc, {Kim Vy} and Neumann, {Neil M.} and Groot, {Vincent P.} and Alina Hasanain and {Floortje van Oosten}, A. and Fischer, {Sandra E.} and Steven Gallinger and Singhi, {Aatur D.} and Zureikat, {Amer H.} and Brand, {Randall E.} and Gaida, {Matthias M.} and Stefan Heinrich and Burkhart, {Richard A.} and Jin He and Wolfgang, {Christopher L.} and Goggins, {Michael G.} and Thompson, {Elizabeth D.} and Roberts, {Nicholas J.} and Ewald, {Andrew J.} and Wood, {Laura D.}",

note = "Funding Information: The authors acknowledge the following sources of financial support: American Cancer Society RSG-18-143-01-CSM (L.D. Wood); NIH/NCI P50 CA62924 (L.D. Wood); NIH/NIDDK K08 DK107781 (L.D. Wood); NIH/NCI U01CA217846 (A.J. Ewald); NIH/NCI U54 CA2101732 (A.J. Ewald); Sol Goldman Pancreatic Cancer Research Center (L.D. Wood); Buffone Family Gastrointestinal Cancer Research Fund (L.D. Wood); Carol S. and Robert M. Long Pancreatic Cancer Research Fund (L.D. Wood); Kaya Tuncer Career Development Award in Gastrointestinal Cancer Prevention (L.D. Wood); AGA-Bernard Lee Schwartz Foundation Research Scholar Award in Pancreatic Cancer (L.D. Wood); Sidney Kimmel Foundation for Cancer Research Kimmel Scholar Award (L.D. Wood); AACR-Incyte Corporation Career Development Award for Pancreatic Cancer Research, Grant Number 16-20-46-WOOD (L.D. Wood); Joseph C Monastra Foundation (L.D. Wood); The Gerald O Mann Charitable Foundation (L.D. Wood); Susan Wojcicki and Denis Troper; Ontario Institute for Cancer Research (PanCuRx Translational Research Initiative) through funding provided by the Government of Ontario (S. Fischer); Wallace McCain Centre for Pancreatic Cancer supported by the Princess Margaret Cancer Foundation (S. Fischer); Terry Fox Research Institute (S. Fischer); Canadian Cancer Society Research Institute (S. Fischer); Pancreatic Cancer Canada Foundation (S. Fischer). Publisher Copyright: {\textcopyright} 2020 American Association for Cancer Research.",

year = "2020",

month = jul,

day = "1",

doi = "10.1158/0008-5472.CAN-19-1523",

language = "English (US)",

volume = "80",

pages = "2804--2817",

journal = "Cancer Research",

issn = "0008-5472",

publisher = "American Association for Cancer Research Inc.",

number = "13",

}

TY - JOUR

T1 - Pattern of invasion in human pancreatic cancer organoids is associated with loss of SMAD4 and clinical outcome

AU - Huang, Wenjie

AU - Navarro-Serer, Bernat

AU - Jeong, Yea Ji

AU - Chianchiano, Peter

AU - Xia, Limin

AU - Luchini, Claudio

AU - Veronese, Nicola

AU - Dowiak, Cameron

AU - Ng, Tammy

AU - Trujillo, Maria A.

AU - Huang, Bo

AU - Pfluger, Michael J.

AU - Macgregor-Das, Anne M.

AU - Lionheart, Gemma

AU - Jones, Danielle

AU - Fujikura, Kohei

AU - Nguyen-Ngoc, Kim Vy

AU - Neumann, Neil M.

AU - Groot, Vincent P.

AU - Hasanain, Alina

AU - Floortje van Oosten, A.

AU - Fischer, Sandra E.

AU - Gallinger, Steven

AU - Singhi, Aatur D.

AU - Zureikat, Amer H.

AU - Brand, Randall E.

AU - Gaida, Matthias M.

AU - Heinrich, Stefan

AU - Burkhart, Richard A.

AU - He, Jin

AU - Wolfgang, Christopher L.

AU - Goggins, Michael G.

AU - Thompson, Elizabeth D.

AU - Roberts, Nicholas J.

AU - Ewald, Andrew J.

AU - Wood, Laura D.

N1 - Funding Information: The authors acknowledge the following sources of financial support: American Cancer Society RSG-18-143-01-CSM (L.D. Wood); NIH/NCI P50 CA62924 (L.D. Wood); NIH/NIDDK K08 DK107781 (L.D. Wood); NIH/NCI U01CA217846 (A.J. Ewald); NIH/NCI U54 CA2101732 (A.J. Ewald); Sol Goldman Pancreatic Cancer Research Center (L.D. Wood); Buffone Family Gastrointestinal Cancer Research Fund (L.D. Wood); Carol S. and Robert M. Long Pancreatic Cancer Research Fund (L.D. Wood); Kaya Tuncer Career Development Award in Gastrointestinal Cancer Prevention (L.D. Wood); AGA-Bernard Lee Schwartz Foundation Research Scholar Award in Pancreatic Cancer (L.D. Wood); Sidney Kimmel Foundation for Cancer Research Kimmel Scholar Award (L.D. Wood); AACR-Incyte Corporation Career Development Award for Pancreatic Cancer Research, Grant Number 16-20-46-WOOD (L.D. Wood); Joseph C Monastra Foundation (L.D. Wood); The Gerald O Mann Charitable Foundation (L.D. Wood); Susan Wojcicki and Denis Troper; Ontario Institute for Cancer Research (PanCuRx Translational Research Initiative) through funding provided by the Government of Ontario (S. Fischer); Wallace McCain Centre for Pancreatic Cancer supported by the Princess Margaret Cancer Foundation (S. Fischer); Terry Fox Research Institute (S. Fischer); Canadian Cancer Society Research Institute (S. Fischer); Pancreatic Cancer Canada Foundation (S. Fischer). Publisher Copyright: © 2020 American Association for Cancer Research.

PY - 2020/7/1

Y1 - 2020/7/1

N2 - Pancreatic ductal adenocarcinoma (PDAC) is an aggressive malignancy characterized by extensive local invasion and systemic spread. In this study, we employed a three-dimensional organoid model of human pancreatic cancer to characterize the molecular alterations critical for invasion. Time-lapse microscopy was used to observe invasion in organoids from 25 surgically resected human PDAC samples in collagen I. Subsequent lentiviral modification and small-molecule inhibitors were used to investigate the molecular programs underlying invasion in PDAC organoids. When cultured in collagen I, PDAC organoids exhibited two distinct, morphologically defined invasive phenotypes, mesenchymal and collective. Each individual PDAC gave rise to organoids with a predominant phenotype, and PDAC that generated organoids with predominantly mesenchymal invasion showed a worse prognosis. Collective invasion predominated in organoids from cancers with somatic mutations in the driver gene SMAD4 (or its signaling partner TGFBR2). Reexpression of SMAD4 abrogated the collective invasion phenotype in SMAD4-mutant PDAC organoids, indicating that SMAD4 loss is required for collective invasion in PDAC organoids. Surprisingly, invasion in passaged SMAD4-mutant PDAC organoids required exogenous TGFb, suggesting that invasion in SMAD4-mutant organoids is mediated through noncanonical TGFb signaling. The Rho-like GTPases RAC1 and CDC42 acted as potential mediators of TGFb-stimulated invasion in SMAD4-mutant PDAC organoids, as inhibition of these GTPases suppressed collective invasion in our model. These data suggest that PDAC utilizes different invasion programs depending on SMAD4 status, with collective invasion uniquely present in PDAC with SMAD4 loss.

AB - Pancreatic ductal adenocarcinoma (PDAC) is an aggressive malignancy characterized by extensive local invasion and systemic spread. In this study, we employed a three-dimensional organoid model of human pancreatic cancer to characterize the molecular alterations critical for invasion. Time-lapse microscopy was used to observe invasion in organoids from 25 surgically resected human PDAC samples in collagen I. Subsequent lentiviral modification and small-molecule inhibitors were used to investigate the molecular programs underlying invasion in PDAC organoids. When cultured in collagen I, PDAC organoids exhibited two distinct, morphologically defined invasive phenotypes, mesenchymal and collective. Each individual PDAC gave rise to organoids with a predominant phenotype, and PDAC that generated organoids with predominantly mesenchymal invasion showed a worse prognosis. Collective invasion predominated in organoids from cancers with somatic mutations in the driver gene SMAD4 (or its signaling partner TGFBR2). Reexpression of SMAD4 abrogated the collective invasion phenotype in SMAD4-mutant PDAC organoids, indicating that SMAD4 loss is required for collective invasion in PDAC organoids. Surprisingly, invasion in passaged SMAD4-mutant PDAC organoids required exogenous TGFb, suggesting that invasion in SMAD4-mutant organoids is mediated through noncanonical TGFb signaling. The Rho-like GTPases RAC1 and CDC42 acted as potential mediators of TGFb-stimulated invasion in SMAD4-mutant PDAC organoids, as inhibition of these GTPases suppressed collective invasion in our model. These data suggest that PDAC utilizes different invasion programs depending on SMAD4 status, with collective invasion uniquely present in PDAC with SMAD4 loss.

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U2 - 10.1158/0008-5472.CAN-19-1523

DO - 10.1158/0008-5472.CAN-19-1523

M3 - Article

C2 - 32376602

AN - SCOPUS:85087647326

SN - 0008-5472

VL - 80

SP - 2804

EP - 2817

JO - Cancer Research

JF - Cancer Research

IS - 13

ER -

Pattern of invasion in human pancreatic cancer organoids is associated with loss of SMAD4 and clinical outcome

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