Detection of c‐fos expression in benign and malignant musculoskeletal lesions

Weisstein, Jason S.; Majeska, Robert J.; Klein, Michael J.; Einhorn, Thomas A.

doi:10.1016/s0736-0266(00)90020-2

Cited by 22 publications

(13 citation statements)

References 35 publications

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“…5c), which is specifically activated through the ERK1/2 molecular pathway and is strongly implicated in regulating c-fos gene expression. Targeting c-fos expression may be a promising strategy for treating many different human cancers, such as sarcomas [34,35], breast cancer [36] and epitheloid adenocarcinoma [37]; therefore, indirect Elk1 inhibition by MT477 may represent a critical finding of our study.…”

Section: Discussionmentioning

confidence: 99%

A novel quinoline, MT477: suppresses cell signaling through Ras molecular pathway, inhibits PKC activity, and demonstrates in vivo anti-tumor activity against human carcinoma cell lines

et al. 2007

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MT477 is a novel thiopyrano[2,3-c]quinoline that has been identified using molecular topology screening as a potential anticancer drug with a high activity against protein kinase C (PKC) isoforms. The objective of the present study was to determine the mechanism of action of MT477 and its activity against human cancer cell lines. MT477 interfered with PKC activity as well as phosphorylation of Ras and ERK1/2 in H226 human lung carcinoma cells. It also induced poly-caspase-dependent apoptosis. MT477 had a dose-dependent (0.006 to 0.2 mM) inhibitory effect on cellular proliferation of H226, MCF-7, U87, LNCaP, A431 and A549 cancer cell lines as determined by in vitro proliferation assays. Two murine xenograft models of human A431 and H226 lung carcinoma were used to evaluate tumor response to intraperitoneal administration of MT477 (33 microg/kg, 100 microg/kg, and 1 mg/kg). Tumor growth was inhibited by 24.5% in A431 and 43.67% in H226 xenografts following MT477 treatment, compared to vehicle controls (p < 0.05). In conclusion, our empirical findings are consistent with molecular modeling of MT477's activity against PKC. We also found, however, that its mechanism of action occurs through suppressing Ras signaling, indicating that its effects on apoptosis and tumor growth in vivo may be mediated by Ras as well as PKC. We propose, therefore, that MT477 warrants further development as an anticancer drug.

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Section: Discussionmentioning

confidence: 99%

A novel quinoline, MT477: suppresses cell signaling through Ras molecular pathway, inhibits PKC activity, and demonstrates in vivo anti-tumor activity against human carcinoma cell lines

et al. 2007

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“…Loss of p53, but not Rb alone, was sufficient to promote tumorigenesis, whereas the loss of both exhibited strong synergy. Other alterations in human OSA include high expression of MYC, MET, and FOS (23,24); transgenic FOS expression in mice results in bone sarcomas, some of which are osteogenic (25,26). Overall, the prevalence of widespread copy number alterations (CNAs) in OSA point to the existence of many unidentified OSA genes.…”

Section: Introductionmentioning

confidence: 99%

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

Molyneux

Grappa²,

Beristain³

et al. 2010

J. Clin. Invest.

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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.

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“…Other genes such as C-FOS (77, 78) , TWIST (79) , p14ARF (80) , p16INK4a (81) , PRKAR1A (71), and p21CIP (82) have also been implicated in OS pathogenesis based on studies of human OS samples. Their mutation appears to complement the defects in the P53 and RB pathways, and their involvement in osteosarcomagenesis is also demonstrated from genetically engineered mouse models.…”

Section: Genetically Engineered Mouse Modelsmentioning

confidence: 99%

Animal Models in Osteosarcoma

2014

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Osteosarcoma (OS) is the most common non-hematologic primary tumor of bone in children and adults. High-dose cytotoxic chemotherapy and surgical resection have improved prognosis, with long-term survival for non-metastatic disease approaching 70%. However, most OS tumors are high grade and tend to rapidly develop pulmonary metastases. Despite clinical advances, patients with metastatic disease or relapse have a poor prognosis. Toward a better understanding of the molecular pathogenesis of human OS, several genetically modified OS mouse models have been developed and will be reviewed here. However, better animal models that more accurately recapitulate the natural progression of the disease are needed for the development of improved prognostic and diagnostic markers as well as targeted therapies for both primary and metastatic OS.

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Detection of c‐fos expression in benign and malignant musculoskeletal lesions

Cited by 22 publications

References 35 publications

A novel quinoline, MT477: suppresses cell signaling through Ras molecular pathway, inhibits PKC activity, and demonstrates in vivo anti-tumor activity against human carcinoma cell lines

A novel quinoline, MT477: suppresses cell signaling through Ras molecular pathway, inhibits PKC activity, and demonstrates in vivo anti-tumor activity against human carcinoma cell lines

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

Animal Models in Osteosarcoma

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