TY - GEN
T1 - The role of Fas/FasL in the metastatic potential of osteosarcoma and targeting this pathway for the treatment of osteosarcoma lung metastases
AU - Gordon, Nancy
AU - Kleinerman, Eugenie S.
N1 - Funding Information:
We are very grateful to Joyce Furlough for her clerical assistance. This work was supported in part by NCI grant CA42992 (ESK) and NIH Core grant CA16672.
PY - 2009
Y1 - 2009
N2 - Pulmonary metastases remain the main cause of death in patients with Osteosarcoma (OS). In order to identify new targets for treatment, our laboratory has focused on understanding the biological properties of the tumor microenvironment that contribute to or interfere with metastasis. Dysfunction of the Fas/FasL signaling pathway has been implicated in tumor development, and progression. Here we describe the status of Fas expression in murine nonmetastatic K7 and metastatic K7M2 cells and human nonmetastatic SAOS and LM2 and metastatic LM6 OS cells. We demonstrated that Fas expression correlates inversely with metastatic potential. Pulmonary metastases from patients were uniformly Fas- supporting the importance of Fas expression to the metastatic potential. Since FasL is constitutively expressed in the lung, our data suggests that Fas+ tumor cells undergo apoptosis and are cleared from the lung. By contrast, Fas- tumor cells evade this host defense mechanism and form lung metastases. We confirmed these findings by blocking the Fas pathway using Fas Associated Death Domain Dominant-Negative (FDN). Fas + cells transfected with FDN were not sensitive to FasL, showed delayed clearance and formed lung metastases. Fas+ cells were also able to form lung metastases in FasL-deficient mice. Using our mouse model systems, we demonstrated that aerosol treatment with liposomal 9-Nitrocamptothecin and Gemcitabine (chemotherapeutic agents known to upregulate Fas expression) increased Fas expression and induced tumor regression in wild type mice. Lung metastases in FasL deficient mice did not respond to the treatment. We conclude that Fas is an early defense mechanism responsible for clearing invading Fas+ tumor cells from the lung. Fas- cells or cells with a nonfunctional Fas pathway evade this defense mechanism and form lung metastases. Therapy that induces Fas expression may therefore be effective in patients with established OS lung metastases. Aerosol delivery of these agents is an ideal way to target treatment to the lung.
AB - Pulmonary metastases remain the main cause of death in patients with Osteosarcoma (OS). In order to identify new targets for treatment, our laboratory has focused on understanding the biological properties of the tumor microenvironment that contribute to or interfere with metastasis. Dysfunction of the Fas/FasL signaling pathway has been implicated in tumor development, and progression. Here we describe the status of Fas expression in murine nonmetastatic K7 and metastatic K7M2 cells and human nonmetastatic SAOS and LM2 and metastatic LM6 OS cells. We demonstrated that Fas expression correlates inversely with metastatic potential. Pulmonary metastases from patients were uniformly Fas- supporting the importance of Fas expression to the metastatic potential. Since FasL is constitutively expressed in the lung, our data suggests that Fas+ tumor cells undergo apoptosis and are cleared from the lung. By contrast, Fas- tumor cells evade this host defense mechanism and form lung metastases. We confirmed these findings by blocking the Fas pathway using Fas Associated Death Domain Dominant-Negative (FDN). Fas + cells transfected with FDN were not sensitive to FasL, showed delayed clearance and formed lung metastases. Fas+ cells were also able to form lung metastases in FasL-deficient mice. Using our mouse model systems, we demonstrated that aerosol treatment with liposomal 9-Nitrocamptothecin and Gemcitabine (chemotherapeutic agents known to upregulate Fas expression) increased Fas expression and induced tumor regression in wild type mice. Lung metastases in FasL deficient mice did not respond to the treatment. We conclude that Fas is an early defense mechanism responsible for clearing invading Fas+ tumor cells from the lung. Fas- cells or cells with a nonfunctional Fas pathway evade this defense mechanism and form lung metastases. Therapy that induces Fas expression may therefore be effective in patients with established OS lung metastases. Aerosol delivery of these agents is an ideal way to target treatment to the lung.
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U2 - 10.1007/978-1-4419-0284-9_29
DO - 10.1007/978-1-4419-0284-9_29
M3 - Conference contribution
C2 - 20213411
AN - SCOPUS:77953672971
SN - 9781441902832
T3 - Cancer Treatment and Research
SP - 497
EP - 508
BT - Pediatric and Adolescent Osteosarcoma
A2 - Jaffe, Norman
A2 - Bruland, Oyvind
A2 - Bielack, Stefan
ER -