Prkar1a is an osteosarcoma tumor suppressor that defines a molecular subclass in mice
Sam D. Molyneux, … , Lawrence S. Kirschner, Rama Khokha
Sam D. Molyneux, … , Lawrence S. Kirschner, Rama Khokha
Published August 9, 2010
Citation Information: J Clin Invest. 2010;120(9):3310-3325. https://doi.org/10.1172/JCI42391.
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Research Article Oncology

Prkar1a is an osteosarcoma tumor suppressor that defines a molecular subclass in mice

Abstract

Some cancers have been stratified into subclasses based on their unique involvement of specific signaling pathways. The mapping of human cancer genomes is revealing a vast number of somatic alterations; however, the identification of clinically relevant molecular tumor subclasses and their respective driver genes presents challenges. This information is key to developing more targeted and personalized cancer therapies. Here, we generate a new mouse model of genomically unstable osteosarcoma (OSA) that phenocopies the human disease. Integrative oncogenomics pinpointed cAMP-dependent protein kinase type I, α regulatory subunit (Prkar1a) gene deletions at 11qE1 as a recurrent genetic trait for a molecularly distinct subclass of mouse OSA featuring RANKL overexpression. Using mouse genetics, we established that Prkar1a is a bone tumor suppressor gene capable of directing subclass development and driving RANKL overexpression during OSA tumorigenesis. Finally, we uncovered evidence for a PRKAR1A-low subset of human OSA with distinct clinical behavior. Thus, tumor subclasses develop in mice and can potentially provide information toward the molecular stratification of human cancers.

Authors

Sam D. Molyneux, Marco A. Di Grappa, Alexander G. Beristain, Trevor D. McKee, Daniel H. Wai, Jana Paderova, Meenakshi Kashyap, Pingzhao Hu, Tamara Maiuri, Swami R. Narala, Vuk Stambolic, Jeremy Squire, Josef Penninger, Otto Sanchez, Timothy J. Triche, Geoffrey A. Wood, Lawrence S. Kirschner, Rama Khokha

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Figure 1

Generation of a transgenic mouse model of OSA.

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Generation of a transgenic mouse model of OSA. (A) The OG2-TAg transgene...
(A) The OG2-TAg transgene construct used to generate 3 MOTO founders and FISH mapping of the OG2-TAg construct to chromosome 12qA-B1 in the MOTO-1 line (red indicates the transgene probe; green indicates the control chromosome 12qF2 probe). In the schematic for the transgene construct, “pA” represents a polyadenylation sequence. (B) qPCR measurement of SV40 TAg RNA in the tissues of the MOTO-1 mouse (11 weeks old) normalized to 18S; data are represented as mean ± SEM. (C) TAg immunostaining shows osteoblast specificity in (top) MOTO-1 rib and (bottom) MOTO-2 femur tumors. Scale bars: 50 μm. (D) Kaplan-Meier plot of age to morbidity for MOTO-1 (n = 97) and MOTO-2 mice (n = 91). (E) Frequency of OSAs in the human skeleton (adapted with permission from refs. 64 and 65) and the percentage of MOTO-1 (black) and MOTO-2 (red) mice that have at least 1 lesion in the indicated bone. (F) Whole-body x-ray images of a 20-week-old MOTO-2 mouse show multiple calcified radiodense tumors in humeri, scapulae, radius/ulna, ribs, femurs, and tibia (arrows). Images on the right show tumors from humerus and both femurs at higher magnification. (G) CT images of 18-week-old mice with bone tumors (arrows) show various levels of calcification and bone destruction. A poorly calcified femur tumor (left panel, arrow) and multiple calcified femur and tibia tumors (right panel, arrows) are shown. The small abdominal radiodensities represent intestinal food.