Screening and Validation of Molecular Targeted Radiosensitizers

Henning Willers; Xiao Pan; Nathalie Borgeaud; Irina Korovina; Lydia Koi; Regina Egan; Patricia Greninger; Aliza Rosenkranz; Jong Kung; Andrew S. Liss; Leslie A. Parsels; Meredith A. Morgan; Theodore S. Lawrence; Steven H. Lin; Theodore S. Hong; Beow Y. Yeap; Lori J. Wirth; Aaron N. Hata; Christopher J. Ott; Cyril H. Benes; Michael Baumann; Mechthild Krause

doi:10.1016/j.ijrobp.2021.07.1694

Screening and Validation of Molecular Targeted Radiosensitizers

Henning Willers, Xiao Pan, Nathalie Borgeaud, Irina Korovina, Lydia Koi, Regina Egan, Patricia Greninger, Aliza Rosenkranz, Jong Kung, Andrew S. Liss, Leslie A. Parsels, Meredith A. Morgan, Theodore S. Lawrence, Steven H. Lin, Theodore S. Hong, Beow Y. Yeap, Lori J. Wirth, Aaron N. Hata, Christopher J. Ott, Cyril H. BenesMichael Baumann, Mechthild Krause

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

8 Scopus citations

Abstract

The development of molecular targeted drugs with radiation and chemotherapy is critically important for improving the outcomes of patients with hard-to-treat, potentially curable cancers. However, too many preclinical studies have not translated into successful radiation oncology trials. Major contributing factors to this insufficiency include poor reproducibility of preclinical data, inadequate preclinical modeling of intertumoral genomic heterogeneity that influences treatment sensitivity in the clinic, and a reliance on tumor growth delay instead of local control (TCD50) endpoints. There exists an urgent need to overcome these barriers to facilitate successful clinical translation of targeted radiosensitizers. To this end, we have used 3-dimensional (3D) cell culture assays to better model tumor behavior in vivo. Examples of successful prediction of in vivo effects with these 3D assays include radiosensitization of head and neck cancers by inhibiting epidermal growth factor receptor or focal adhesion kinase signaling, and radioresistance associated with oncogenic mutation of KRAS. To address the issue of tumor heterogeneity, we leveraged institutional resources that allow high-throughput 3D screening of radiation combinations with small-molecule inhibitors across genomically characterized cell lines from lung, head and neck, and pancreatic cancers. This high-throughput screen is expected to uncover genomic biomarkers that will inform the successful clinical translation of targeted agents from the National Cancer Institute Cancer Therapy Evaluation Program portfolio and other sources. Screening “hits” need to be subjected to refinement studies that include clonogenic assays, addition of disease-specific chemotherapeutics, target/biomarker validation, and integration of patient-derived tumor models. The chemoradiosensitizing activities of the most promising drugs should be confirmed in TCD50 assays in xenograft models with or without relevant biomarker and using clinically relevant radiation fractionation. We predict that appropriately validated and biomarker-directed targeted therapies will have a higher likelihood than past efforts of being successfully incorporated into the standard management of hard-to-treat tumors.

Original language	English (US)
Pages (from-to)	e63-e74
Journal	International Journal of Radiation Oncology Biology Physics
Volume	111
Issue number	5
DOIs	https://doi.org/10.1016/j.ijrobp.2021.07.1694
State	Published - Dec 1 2021

ASJC Scopus subject areas

Radiation
Oncology
Radiology Nuclear Medicine and imaging
Cancer Research

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10.1016/j.ijrobp.2021.07.1694

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Willers, H., Pan, X., Borgeaud, N., Korovina, I., Koi, L., Egan, R., Greninger, P., Rosenkranz, A., Kung, J., Liss, A. S., Parsels, L. A., Morgan, M. A., Lawrence, T. S., Lin, S. H., Hong, T. S., Yeap, B. Y., Wirth, L. J., Hata, A. N., Ott, C. J., ... Krause, M. (2021). Screening and Validation of Molecular Targeted Radiosensitizers. International Journal of Radiation Oncology Biology Physics, 111(5), e63-e74. https://doi.org/10.1016/j.ijrobp.2021.07.1694

Willers, H, Pan, X, Borgeaud, N, Korovina, I, Koi, L, Egan, R, Greninger, P, Rosenkranz, A, Kung, J, Liss, AS, Parsels, LA, Morgan, MA, Lawrence, TS, Lin, SH, Hong, TS, Yeap, BY, Wirth, LJ, Hata, AN, Ott, CJ, Benes, CH, Baumann, M & Krause, M 2021, 'Screening and Validation of Molecular Targeted Radiosensitizers', International Journal of Radiation Oncology Biology Physics, vol. 111, no. 5, pp. e63-e74. https://doi.org/10.1016/j.ijrobp.2021.07.1694

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title = "Screening and Validation of Molecular Targeted Radiosensitizers",

abstract = "The development of molecular targeted drugs with radiation and chemotherapy is critically important for improving the outcomes of patients with hard-to-treat, potentially curable cancers. However, too many preclinical studies have not translated into successful radiation oncology trials. Major contributing factors to this insufficiency include poor reproducibility of preclinical data, inadequate preclinical modeling of intertumoral genomic heterogeneity that influences treatment sensitivity in the clinic, and a reliance on tumor growth delay instead of local control (TCD50) endpoints. There exists an urgent need to overcome these barriers to facilitate successful clinical translation of targeted radiosensitizers. To this end, we have used 3-dimensional (3D) cell culture assays to better model tumor behavior in vivo. Examples of successful prediction of in vivo effects with these 3D assays include radiosensitization of head and neck cancers by inhibiting epidermal growth factor receptor or focal adhesion kinase signaling, and radioresistance associated with oncogenic mutation of KRAS. To address the issue of tumor heterogeneity, we leveraged institutional resources that allow high-throughput 3D screening of radiation combinations with small-molecule inhibitors across genomically characterized cell lines from lung, head and neck, and pancreatic cancers. This high-throughput screen is expected to uncover genomic biomarkers that will inform the successful clinical translation of targeted agents from the National Cancer Institute Cancer Therapy Evaluation Program portfolio and other sources. Screening “hits” need to be subjected to refinement studies that include clonogenic assays, addition of disease-specific chemotherapeutics, target/biomarker validation, and integration of patient-derived tumor models. The chemoradiosensitizing activities of the most promising drugs should be confirmed in TCD50 assays in xenograft models with or without relevant biomarker and using clinically relevant radiation fractionation. We predict that appropriately validated and biomarker-directed targeted therapies will have a higher likelihood than past efforts of being successfully incorporated into the standard management of hard-to-treat tumors.",

author = "Henning Willers and Xiao Pan and Nathalie Borgeaud and Irina Korovina and Lydia Koi and Regina Egan and Patricia Greninger and Aliza Rosenkranz and Jong Kung and Liss, {Andrew S.} and Parsels, {Leslie A.} and Morgan, {Meredith A.} and Lawrence, {Theodore S.} and Lin, {Steven H.} and Hong, {Theodore S.} and Yeap, {Beow Y.} and Wirth, {Lori J.} and Hata, {Aaron N.} and Ott, {Christopher J.} and Benes, {Cyril H.} and Michael Baumann and Mechthild Krause",

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AU - Willers, Henning

AU - Pan, Xiao

AU - Borgeaud, Nathalie

AU - Korovina, Irina

AU - Koi, Lydia

AU - Egan, Regina

AU - Greninger, Patricia

AU - Rosenkranz, Aliza

AU - Kung, Jong

AU - Liss, Andrew S.

AU - Parsels, Leslie A.

AU - Morgan, Meredith A.

AU - Lawrence, Theodore S.

AU - Lin, Steven H.

AU - Hong, Theodore S.

AU - Yeap, Beow Y.

AU - Wirth, Lori J.

AU - Hata, Aaron N.

AU - Ott, Christopher J.

AU - Benes, Cyril H.

AU - Baumann, Michael

AU - Krause, Mechthild

PY - 2021/12/1

Y1 - 2021/12/1

N2 - The development of molecular targeted drugs with radiation and chemotherapy is critically important for improving the outcomes of patients with hard-to-treat, potentially curable cancers. However, too many preclinical studies have not translated into successful radiation oncology trials. Major contributing factors to this insufficiency include poor reproducibility of preclinical data, inadequate preclinical modeling of intertumoral genomic heterogeneity that influences treatment sensitivity in the clinic, and a reliance on tumor growth delay instead of local control (TCD50) endpoints. There exists an urgent need to overcome these barriers to facilitate successful clinical translation of targeted radiosensitizers. To this end, we have used 3-dimensional (3D) cell culture assays to better model tumor behavior in vivo. Examples of successful prediction of in vivo effects with these 3D assays include radiosensitization of head and neck cancers by inhibiting epidermal growth factor receptor or focal adhesion kinase signaling, and radioresistance associated with oncogenic mutation of KRAS. To address the issue of tumor heterogeneity, we leveraged institutional resources that allow high-throughput 3D screening of radiation combinations with small-molecule inhibitors across genomically characterized cell lines from lung, head and neck, and pancreatic cancers. This high-throughput screen is expected to uncover genomic biomarkers that will inform the successful clinical translation of targeted agents from the National Cancer Institute Cancer Therapy Evaluation Program portfolio and other sources. Screening “hits” need to be subjected to refinement studies that include clonogenic assays, addition of disease-specific chemotherapeutics, target/biomarker validation, and integration of patient-derived tumor models. The chemoradiosensitizing activities of the most promising drugs should be confirmed in TCD50 assays in xenograft models with or without relevant biomarker and using clinically relevant radiation fractionation. We predict that appropriately validated and biomarker-directed targeted therapies will have a higher likelihood than past efforts of being successfully incorporated into the standard management of hard-to-treat tumors.

AB - The development of molecular targeted drugs with radiation and chemotherapy is critically important for improving the outcomes of patients with hard-to-treat, potentially curable cancers. However, too many preclinical studies have not translated into successful radiation oncology trials. Major contributing factors to this insufficiency include poor reproducibility of preclinical data, inadequate preclinical modeling of intertumoral genomic heterogeneity that influences treatment sensitivity in the clinic, and a reliance on tumor growth delay instead of local control (TCD50) endpoints. There exists an urgent need to overcome these barriers to facilitate successful clinical translation of targeted radiosensitizers. To this end, we have used 3-dimensional (3D) cell culture assays to better model tumor behavior in vivo. Examples of successful prediction of in vivo effects with these 3D assays include radiosensitization of head and neck cancers by inhibiting epidermal growth factor receptor or focal adhesion kinase signaling, and radioresistance associated with oncogenic mutation of KRAS. To address the issue of tumor heterogeneity, we leveraged institutional resources that allow high-throughput 3D screening of radiation combinations with small-molecule inhibitors across genomically characterized cell lines from lung, head and neck, and pancreatic cancers. This high-throughput screen is expected to uncover genomic biomarkers that will inform the successful clinical translation of targeted agents from the National Cancer Institute Cancer Therapy Evaluation Program portfolio and other sources. Screening “hits” need to be subjected to refinement studies that include clonogenic assays, addition of disease-specific chemotherapeutics, target/biomarker validation, and integration of patient-derived tumor models. The chemoradiosensitizing activities of the most promising drugs should be confirmed in TCD50 assays in xenograft models with or without relevant biomarker and using clinically relevant radiation fractionation. We predict that appropriately validated and biomarker-directed targeted therapies will have a higher likelihood than past efforts of being successfully incorporated into the standard management of hard-to-treat tumors.

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Screening and Validation of Molecular Targeted Radiosensitizers

Abstract

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