KRASG12D and TP53R167H Cooperate to Induce Pancreatic Ductal Adenocarcinoma in Sus scrofa Pigs

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作者
Daniel R. Principe
Nana Haahr Overgaard
Alex J. Park
Andrew M. Diaz
Carolina Torres
Ronald McKinney
Matthew J. Dorman
Karla Castellanos
Regina Schwind
David W. Dawson
Ajay Rana
Ajay Maker
Hidayatullah G. Munshi
Lauretta A. Rund
Paul J. Grippo
Lawrence B. Schook
机构
[1] Medical Scientist Training Program,Department of Immunology and Vaccinology
[2] University of Illinois College of Medicine,Department of Medicine
[3] National Veterinary Institute,Department of Pathology and Laboratory Medicine
[4] Technical University of Denmark Copenhagen,Department of Surgery
[5] University of Illinois Department of Animal Sciences,Department of Medicine
[6] University of Illinois at Chicago,Institute for Genomic Biology
[7] Department of Radiology,undefined
[8] University of Illinois at Chicago,undefined
[9] Jonsson Comprehensive Cancer Center,undefined
[10] David Geffen School of Medicine at UCLA,undefined
[11] University of Illinois at Chicago,undefined
[12] Northwestern University,undefined
[13] University of Illinois,undefined
来源
Scientific Reports | / 8卷
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摘要
Although survival has improved in recent years, the prognosis of patients with advanced pancreatic ductal adenocarcinoma (PDAC) remains poor. Despite substantial differences in anatomy, physiology, genetics, and metabolism, the overwhelming majority of preclinical testing relies on transgenic mice. Hence, while mice have allowed for tremendous advances in cancer biology, they have been a poor predictor of drug performance/toxicity in the clinic. Given the greater similarity of sus scrofa pigs to humans, we engineered transgenic sus scrofa expressing a LSL-KRASG12D-TP53R167H cassette. By applying Adeno-Cre to pancreatic duct cells in vitro, cells self-immortalized and established tumors in immunocompromised mice. When Adeno-Cre was administered to the main pancreatic duct in vivo, pigs developed extensive PDAC at the injection site hallmarked by excessive proliferation and desmoplastic stroma. This serves as the first large animal model of pancreatic carcinogenesis, and may allow for insight into new avenues of translational research not before possible in rodents.
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