Center of Excellence In Genomic Medicine Research | Researches | Radiation-enhanced lung cancer progression in a transgenic mouse model of lung cancer is predictive of outcomes in human lung and breast cancer

Center of Excellence In Genomic Medicine Research

Document Details

Document Type	:	Article In Journal
Document Title	:	Radiation-enhanced lung cancer progression in a transgenic mouse model of lung cancer is predictive of outcomes in human lung and breast cancer Radiation-enhanced lung cancer progression in a transgenic mouse model of lung cancer is predictive of outcomes in human lung and breast cancer
Document Language	:	English
Abstract	:	Carcinogenesis is an adaptive process between nascent tumor cells and their microenvironment, including the modification of inflammatory responses from antitumorigenic to protumorigenic. Radiation exposure can stimulate inflammatory responses that inhibit or promote carcinogenesis. The purpose of this study is to determine the impact of radiation exposure on lung cancer progression in vivo and assess the relevance of this knowledge to human carcinogenesis. EXPERIMENTAL DESIGN: K-ras(LA1) mice were irradiated with various doses and dose regimens and then monitored until death. Microarray analyses were performed using Illumina BeadChips on whole lung tissue 70 days after irradiation with a fractionated or acute dose of radiation and compared with age-matched unirradiated controls. Unique group classifiers were derived by comparative genomic analysis of three experimental cohorts. Survival analyses were performed using principal component analysis and k-means clustering on three lung adenocarcinoma, three breast adenocarcinoma, and two lung squamous carcinoma annotated microarray datasets. RESULTS: Radiation exposure accelerates lung cancer progression in the K-ras(LA1) lung cancer mouse model with dose fractionation being more permissive for cancer progression. A nonrandom inflammatory signature associated with this progression was elicited from whole lung tissue containing only benign lesions and predicts human lung and breast cancer patient survival across multiple datasets. Immunohistochemical analyses suggest that tumor cells drive predictive signature. CONCLUSIONS: These results demonstrate that radiation exposure can cooperate with benign lesions in a transgenic model of cancer by affecting inflammatory pathways, and that clinically relevant similarities exist between human lung and breast carcinogenesis.
ISSN	:	1078-0432
Journal Name	:	Clinical Cancer Research
Volume	:	20
Issue Number	:	6
Publishing Year	:	1435 AH 2014 AD
Article Type	:	Article
Added Date	:	Wednesday, March 9, 2016

Researchers

Researcher Name (Arabic)	Researcher Name (English)	Researcher Type	Dr Grade	Email
Oliver Delgado	Delgado, Oliver	Investigator
Kimberly G Batten	Batten, Kimberly G	Researcher
James A Richardson	Richardson, James A	Researcher
Xian-Jin Xie	Xie, Xian-Jin	Researcher
Adi F Gazdar	Gazdar, Adi F	Researcher
Aadil A Kaisani	Kaisani, Aadil A	Researcher
Luc Girard	Girard, Luc	Researcher
Carmen Behrens	Behrens, Carmen	Researcher
Milind Suraokar	Suraokar, Milind	Researcher
Gail Fasciani	Fasciani, Gail	Researcher
Jerry W Shay	Shay, Jerry W	Researcher

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