Opposing Effects of Transmembrane and Soluble Fas Ligand Expression on Inflammation and Tumor Cell Survival

doi:10.1084/jem.191.7.1209

Published online 3 April 2000.

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© The Rockefeller University Press, 0022-1007/2000/4/1209/ $5.00
The Journal of Experimental Medicine, Volume 191, Number 7, April 3, 2000 1209-1220

Original Article

Opposing Effects of Transmembrane and Soluble Fas Ligand Expression on Inflammation and Tumor Cell Survival

Andreas M. Hohlbaum^a, Signa Moe^a, and Ann Marshak-Rothstein^a
^a Department of Microbiology, Boston University School of Medicine, Boston, Massachusetts 02118

Correspondence to: Ann Marshak-Rothstein, Department of Microbiology, Boston University School of Medicine, 80 E. Concord St., Boston, MA 02118-2394. Tel:617-638-4299 Fax:617-638-4286 E-mail:amrothst{at}bu.edu.

Fas ligand (FasL) has been shown to mediate both apoptotic andinflammatory reactions. To rigorously assess the physiologicalrole of different forms of the FasL molecule with regard tothese two distinct processes, we isolated stably transfectedlymphoma cell lines that expressed either murine wild-type FasL,membrane-only FasL, or functionally distinct forms of solubleFasL. First, the ability of these lines to induce an inflammatoryresponse was assessed in vivo by injecting the transfectantsintraperitoneally and measuring subsequent neutrophil extravasationinto the peritoneal cavity. Second, lines were assessed by injectingthe transfectants subcutaneously and monitoring their growthas solid tumors. Our study clearly demonstrated that the extentof inflammation induced by the transfectants directly correlatedwith their relative cytotoxic activities. A neutrophil responsecould only be elicited in mice with intact Fas death domainsalthough Fas expression by the neutrophils was not essential.Lymphoma cells expressing the soluble FasL form correspondingto the natural cleavage product could not trigger apoptosisand did not induce a neutrophil response. In contrast to theother FasL transfectants, these cells survived as tumor transplants.However, expression of soluble FasL was not benign, but actuallysuppressed the inflammatory response and protected other transfectantsfrom the effector mechanisms elicted by membrane-bound FasL.

Key Words: Fas ligand, apoptosis, neutrophil, chemotaxis, lymphoma

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