Stromal architecture directs early dissemination in pancreatic ductal adenocarcinoma
Arja Ray, Mackenzie K. Callaway, Nelson J. Rodríguez-Merced, Alexandra L. Crampton, Marjorie Carlson, Kenneth B. Emme, Ethan A. Ensminger, Alexander A. Kinne, Jonathan H. Schrope, Haley R. Rasmussen, Hong Jiang, David G. DeNardo, David K. Wood, Paolo P. Provenzano
Arja Ray, Mackenzie K. Callaway, Nelson J. Rodríguez-Merced, Alexandra L. Crampton, Marjorie Carlson, Kenneth B. Emme, Ethan A. Ensminger, Alexander A. Kinne, Jonathan H. Schrope, Haley R. Rasmussen, Hong Jiang, David G. DeNardo, David K. Wood, Paolo P. Provenzano
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Research Article Cell biology Oncology

Stromal architecture directs early dissemination in pancreatic ductal adenocarcinoma

Abstract

Pancreatic ductal adenocarcinoma (PDA) is an extremely metastatic and lethal disease. Here, in both murine and human PDA, we demonstrate that extracellular matrix architecture regulates cell extrusion and subsequent invasion from intact ductal structures through tumor-associated collagen signatures (TACS). This results in early dissemination from histologically premalignant lesions and continual invasion from well-differentiated disease, and it suggests TACS as a biomarker to aid in the pathologic assessment of early disease. Furthermore, we show that pancreatitis results in invasion-conducive architectures, thus priming the stroma prior to malignant disease. Analysis in potentially novel microfluidic-derived microtissues and in vivo demonstrates decreased extrusion and invasion following focal adhesion kinase (FAK) inhibition, consistent with decreased metastasis. Thus, data suggest that targeting FAK or strategies to reengineer and normalize tumor microenvironments may have roles not only in very early disease, but also for limiting continued dissemination from unresectable disease. Likewise, it may be beneficial to employ stroma-targeting strategies to resolve precursor diseases such as pancreatitis in order to remove stromal architectures that increase risk for early dissemination.

Authors

Arja Ray, Mackenzie K. Callaway, Nelson J. Rodríguez-Merced, Alexandra L. Crampton, Marjorie Carlson, Kenneth B. Emme, Ethan A. Ensminger, Alexander A. Kinne, Jonathan H. Schrope, Haley R. Rasmussen, Hong Jiang, David G. DeNardo, David K. Wood, Paolo P. Provenzano

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Figure 4

FAK inhibition abrogates collagen fiber–guided PDA cell extrusion in vitro.

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FAK inhibition abrogates collagen fiber–guided PDA cell extrusion in vit...
(A) Schematic demonstrating our in vitro platform to mimic tumor cell extrusion from ductal structures into surrounding collagen. Matrigel droplets generated in a microfluidic device by orthogonal flow of Matrigel in an oil based medium, before coating them with primary KPCG or KPCT cells. Coated droplets are cultured individually in custom-fabricated microwells for several days before embedding in a collagen matrix. (B and C) Bright-field (B) and multiphoton excitation microscopy image (C) of a formed microtissue. (D and E) Maximum intensity projection (MIP) (D) and cross-sectional (E) MPE immunofluorescence micrographs show a typical droplet structure resembling the cross-section of a duct with basement membrane. (F) MPE/SHG imaging of a droplet embedded in collagen matrix. (GI) Control (G) and FAK inhibitor (H) treated conditions, showing significant invasion in the control group at say 1, which is completely abrogated by inhibition of FAK, as quantified by single-cell extrusion analysis in (I); n = 20–30 droplets per condition from n = 2 experiments. Data are mean ± SEM; ****P < 0.0001 by ordinary 2-way ANOVA and Sidak’s multiple-comparison test. Scale bars: 20 μm (BF) and 50 μm (G and H).