Murine Liver Organoids as a Genetically Flexible System to Study Liver Cancer In Vivo and In Vitro

Anna Saborowski; Katharina Wolff; Steffi Spielberg; Benedikt Beer; Björn Hartleben; Zulrahman Erlangga; Diana Becker; Lukas E Dow; Silke Marhenke; Norman Woller; Kristian Unger; Peter Schirmacher; Michael P Manns; Jens U Marquardt; Arndt Vogel; Michael Saborowski

doi:10.1002/hep4.1312

Murine Liver Organoids as a Genetically Flexible System to Study Liver Cancer In Vivo and In Vitro

Standard

Murine Liver Organoids as a Genetically Flexible System to Study Liver Cancer In Vivo and In Vitro. / Saborowski, Anna; Wolff, Katharina; Spielberg, Steffi; Beer, Benedikt; Hartleben, Björn; Erlangga, Zulrahman; Becker, Diana; Dow, Lukas E; Marhenke, Silke; Woller, Norman; Unger, Kristian; Schirmacher, Peter; Manns, Michael P; Marquardt, Jens U; Vogel, Arndt; Saborowski, Michael.

In: HEPATOL COMMUN, Vol. 3, No. 3, 03.2019, p. 423-436.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Saborowski, A, Wolff, K, Spielberg, S, Beer, B, Hartleben, B, Erlangga, Z, Becker, D, Dow, LE, Marhenke, S, Woller, N, Unger, K, Schirmacher, P, Manns, MP, Marquardt, JU, Vogel, A & Saborowski, M 2019, 'Murine Liver Organoids as a Genetically Flexible System to Study Liver Cancer In Vivo and In Vitro', HEPATOL COMMUN, vol. 3, no. 3, pp. 423-436. https://doi.org/10.1002/hep4.1312

APA

Saborowski, A., Wolff, K., Spielberg, S., Beer, B., Hartleben, B., Erlangga, Z., Becker, D., Dow, L. E., Marhenke, S., Woller, N., Unger, K., Schirmacher, P., Manns, M. P., Marquardt, J. U., Vogel, A., & Saborowski, M. (2019). Murine Liver Organoids as a Genetically Flexible System to Study Liver Cancer In Vivo and In Vitro. HEPATOL COMMUN, 3(3), 423-436. https://doi.org/10.1002/hep4.1312

Vancouver

Saborowski A, Wolff K, Spielberg S, Beer B, Hartleben B, Erlangga Z et al. Murine Liver Organoids as a Genetically Flexible System to Study Liver Cancer In Vivo and In Vitro. HEPATOL COMMUN. 2019 Mar;3(3):423-436. https://doi.org/10.1002/hep4.1312

Bibtex

@article{99f81fb7597041d88fcd1bdcd048d69f,

title = "Murine Liver Organoids as a Genetically Flexible System to Study Liver Cancer In Vivo and In Vitro",

abstract = "The rising incidence of cholangiocarcinoma (CCA) coupled with a low 5-year survival rate that remains below 10% delineates the urgent need for more effective treatment strategies. Although several recent studies provided detailed information on the genetic landscape of this fatal malignancy, versatile model systems to functionally dissect the immediate clinical relevance of the identified genetic alterations are still missing. To enhance our understanding of CCA pathophysiology and facilitate rapid functional annotation of putative CCA driver and tumor maintenance genes, we developed a tractable murine CCA model by combining the cyclization recombination (Cre)-lox system, RNA interference, and clustered regularly interspaced short palindromic repeats/CRISPR associated protein 9 (CRISPR/Cas9) technology with liver organoids, followed by subsequent transplantation into immunocompetent, syngeneic mice. Histologically, resulting tumors displayed cytokeratin 19-positive ductal structures surrounded by a desmoplastic stroma-hallmark features of human CCAs. Despite their initial biliary phenotype in vitro, organoids retained the plasticity to induce a broader differentiation spectrum of primary liver cancers following transplantation into recipient mice, depending on their genetic context. Thus, the organoid system combines the advantage of using nontransformed, premalignant cells to recapitulate liver tumorigenesis as a multistep process, with the advantage of a reproducible and expandable cell culture system that abrogates the need for recurrent isolations of primary cells. Conclusion: Genetically modified liver organoids are able to transform into histologically accurate CCAs. Depending on the oncogenic context, they are also able to give rise to liver cancers that show features of hepatocellular carcinomas. The model can be used to functionally explore candidate cancer genes of primary liver cancers in immunocompetent animals and evaluate novel treatment regimens.",

author = "Anna Saborowski and Katharina Wolff and Steffi Spielberg and Benedikt Beer and Bj{\"o}rn Hartleben and Zulrahman Erlangga and Diana Becker and Dow, {Lukas E} and Silke Marhenke and Norman Woller and Kristian Unger and Peter Schirmacher and Manns, {Michael P} and Marquardt, {Jens U} and Arndt Vogel and Michael Saborowski",

year = "2019",

month = mar,

doi = "10.1002/hep4.1312",

language = "English",

volume = "3",

pages = "423--436",

journal = "HEPATOL COMMUN",

issn = "2471-254X",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "3",

}

RIS

TY - JOUR

T1 - Murine Liver Organoids as a Genetically Flexible System to Study Liver Cancer In Vivo and In Vitro

AU - Saborowski, Anna

AU - Wolff, Katharina

AU - Spielberg, Steffi

AU - Beer, Benedikt

AU - Hartleben, Björn

AU - Erlangga, Zulrahman

AU - Becker, Diana

AU - Dow, Lukas E

AU - Marhenke, Silke

AU - Woller, Norman

AU - Unger, Kristian

AU - Schirmacher, Peter

AU - Manns, Michael P

AU - Marquardt, Jens U

AU - Vogel, Arndt

AU - Saborowski, Michael

PY - 2019/3

Y1 - 2019/3

N2 - The rising incidence of cholangiocarcinoma (CCA) coupled with a low 5-year survival rate that remains below 10% delineates the urgent need for more effective treatment strategies. Although several recent studies provided detailed information on the genetic landscape of this fatal malignancy, versatile model systems to functionally dissect the immediate clinical relevance of the identified genetic alterations are still missing. To enhance our understanding of CCA pathophysiology and facilitate rapid functional annotation of putative CCA driver and tumor maintenance genes, we developed a tractable murine CCA model by combining the cyclization recombination (Cre)-lox system, RNA interference, and clustered regularly interspaced short palindromic repeats/CRISPR associated protein 9 (CRISPR/Cas9) technology with liver organoids, followed by subsequent transplantation into immunocompetent, syngeneic mice. Histologically, resulting tumors displayed cytokeratin 19-positive ductal structures surrounded by a desmoplastic stroma-hallmark features of human CCAs. Despite their initial biliary phenotype in vitro, organoids retained the plasticity to induce a broader differentiation spectrum of primary liver cancers following transplantation into recipient mice, depending on their genetic context. Thus, the organoid system combines the advantage of using nontransformed, premalignant cells to recapitulate liver tumorigenesis as a multistep process, with the advantage of a reproducible and expandable cell culture system that abrogates the need for recurrent isolations of primary cells. Conclusion: Genetically modified liver organoids are able to transform into histologically accurate CCAs. Depending on the oncogenic context, they are also able to give rise to liver cancers that show features of hepatocellular carcinomas. The model can be used to functionally explore candidate cancer genes of primary liver cancers in immunocompetent animals and evaluate novel treatment regimens.

AB - The rising incidence of cholangiocarcinoma (CCA) coupled with a low 5-year survival rate that remains below 10% delineates the urgent need for more effective treatment strategies. Although several recent studies provided detailed information on the genetic landscape of this fatal malignancy, versatile model systems to functionally dissect the immediate clinical relevance of the identified genetic alterations are still missing. To enhance our understanding of CCA pathophysiology and facilitate rapid functional annotation of putative CCA driver and tumor maintenance genes, we developed a tractable murine CCA model by combining the cyclization recombination (Cre)-lox system, RNA interference, and clustered regularly interspaced short palindromic repeats/CRISPR associated protein 9 (CRISPR/Cas9) technology with liver organoids, followed by subsequent transplantation into immunocompetent, syngeneic mice. Histologically, resulting tumors displayed cytokeratin 19-positive ductal structures surrounded by a desmoplastic stroma-hallmark features of human CCAs. Despite their initial biliary phenotype in vitro, organoids retained the plasticity to induce a broader differentiation spectrum of primary liver cancers following transplantation into recipient mice, depending on their genetic context. Thus, the organoid system combines the advantage of using nontransformed, premalignant cells to recapitulate liver tumorigenesis as a multistep process, with the advantage of a reproducible and expandable cell culture system that abrogates the need for recurrent isolations of primary cells. Conclusion: Genetically modified liver organoids are able to transform into histologically accurate CCAs. Depending on the oncogenic context, they are also able to give rise to liver cancers that show features of hepatocellular carcinomas. The model can be used to functionally explore candidate cancer genes of primary liver cancers in immunocompetent animals and evaluate novel treatment regimens.

U2 - 10.1002/hep4.1312

DO - 10.1002/hep4.1312

M3 - SCORING: Journal article

C2 - 30859153

VL - 3

SP - 423

EP - 436

JO - HEPATOL COMMUN

JF - HEPATOL COMMUN

SN - 2471-254X

IS - 3

ER -