Reduction in Surface Urokinase Receptor Forces Malignant Cells into a Protracted State of Dormancy

doi:10.1083/jcb.137.3.767

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© The Rockefeller University Press, 0021-9525/1997//767 $5.00
The Journal of Cell Biology, Volume 137, Number 3, , 1997 767-777

Article

Reduction in Surface Urokinase Receptor Forces Malignant Cells into a Protracted State of Dormancy

W. Yu, J. Kim, and L. Ossowski

The Rochelle Belfer Chemotherapy Foundation Laboratory, Department of Medicine, Division of Neoplastic Diseases, Mount Sinai School of Medicine, New York 10029

Considerable evidence links urokinase plasminogen activator(uPA) bound to its surface receptor (uPAR) with enhanced invasivenessof cancer cells. By blocking uPAR expression in human epidermoidcarcinoma cells (HEp3), we have now identified an additionaland novel in vivo function for this receptor by showing thatreceptor-deficient cells enter a state of dormancy reminiscentof that observed in human cancer metastasis. Its main characteristicis survival without signs of progressive growth. Five clonestransfected with a vector expressing uPAR antisense RNA under the β-actin promoter were isolated and shown to have uPAR (at the mRNA and protein levels) reduced by 50 to 80%;four clones, transfected with vector alone and having uPARlevels similar to those of parental cells, served as controls.In confirmation of our previous results, reduced uPAR alwayscoincided with a significantly reduced invasiveness. Each ofthe control clones produced rapidly growing, highly metastatictumors within 2 wk of inoculation on chorioallantoic membranes(CAMs) of chick embryos. In contrast, each of the clones withlow surface uPAR, whose proliferation rate in culture was indistinguishablefrom controls, remained dormant for up to 5 mo when inoculatedon CAMs. Thus, the reduction in uPAR altered the phenotypeof HEp3 tumor cells from tumorigenic to dormant. Although protracted,tumor dormancy was not permanent since in spite of maintaininglow uPAR levels, each of the in vivo–passaged antisenseclones eventually reemerged from dormancy to initiate progressive growth and to form metastases at a level of 20 to 90% of thatof fully malignant control. This observation suggested thatother factors, whose expression is dependent on cumulative andprolonged in vivo effects, can compensate for the lack of afull complement of surface uPAR required for the expressionof malignant properties. These "reemerged," uPAR-deficient cloneswere easily distinguishable from the vector-transfected controlsby the fact that after only 1 wk in culture, the invasion ofCAM by all five clones and tumorigenicity of four of the fiveclones were reduced back to the values observed before in vivomaintenance. In contrast, dissociated and in vitro–growncells of control tumors were fully invasive and produced large,metastatic tumors when reinoculated on CAMs. Quantitation ofthe percent of apoptotic and S-phase cells in vivo, in the control and uPAR-deficient, dormant clones, showed that themechanism responsible for the dormancy was a diminished proliferation.

1. Abbreviations used in this paper: CAM, chorioallantoic membrane; HEp3, human epidermoid carcinoma; IUdR and BUdR, iododeoxyuridineand bromodexoyuridine; uPA, urokinase plasminogen activator; uPAR, uPA receptor.

Address all correspondence to L. Ossowski, The Rochelle BelferChemotherapy Foundation Laboratory, Department of Medicine,Division of Neoplastic Diseases, Box 1178, Mount Sinai Schoolof Medicine, New York, NY 10029. Tel.: (212) 241-3194. Fax:(212) 996-5787.

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