In vitro and in vivo protection of stellate cells from apoptosis by leptin.

Hepatic fibrogenesis is reduced in the absence of leptin. We hypothesized that leptin protects hepatic stellate cells (HSCs) from apoptosis and tested this in in vitro and in vivo systems. (i) Fas ligand (fas-L)-mediated apoptosis was induced in vitro in activated HSCs in the absence and presence of leptin. (ii) HSC apoptosis was also induced by UV irradiation in the absence and presence of leptin. (iii) Fas-L-mediated apoptosis was induced in vitro in HSCs from db/db mice in the absence and presence of leptin. (iv) Liver fibrosis was induced in wt and db/db mice. (v) Liver fibrosis was induced in wild-type mice with TAA, and mice received additional leptin or a control solution. HSC apoptosis was assessed by TUNEL staining. Western blot for alpha-SMA was used to determine differences in HSC activation. Results were as follows. (i) Fas-L induced significant apoptosis of HSC, and preincubation with leptin reduced this approximately threefold. (ii) Leptin provided no protection from UV-induced apoptosis. (iii) HSCs from db/db mice were not protected by leptin against fas-L-induced apoptosis. (iv) TAA-induced fibrosis was significantly less in db/db mice compared to wild type. (v) Wild-type mice receiving leptin had less apoptosis and more alpha-SMA than controls. We conclude that leptin protects HSC from in vitro and in vivo apoptosis. The antiapoptotic effect of leptin requires the long form of the leptin receptor and interacts with the apoptotic pathway proximal to mitochondrial activation.

Kupffer cells required for high affinity peptide-induced deletion, not retention, of activated CD8+ T cells by mouse liver.

The immune response to foreign antigens in the liver is often suboptimal and this is clinically relevant in chronic persistence of hepatotropic viruses. In chronic infection with the hepatitis C virus, activated CD8+ T cells specific for viral epitopes are present in the peripheral blood and the liver, yet viral clearance is unusual. To define the fate of activated CD8+ entering the liver, we developed a mouse model of portal vein injection of activated CD8+ T cells in vivo. Activated CD8+ T cells are retained very efficiently by the liver and undergo an approximately 8-fold expansion in the first 48 hours. This expansion is followed by apoptosis and a decline in numbers of the retained cells over the next 4 days. The presence of high affinity (HA) antigen does not affect the initial retention by the liver but greatly limits the expansion in the first 48 hours by increasing apoptosis of the retained cells. In the absence of Kupffer cells, the initial retention and expansion are unchanged, but HA antigen does not limit the expansion of the liver CD8+ T cell pool. In conclusion, these data identify a previously unknown phase of CD8+ T cell expansion after entering the liver, demonstrate that HA antigen limits the hepatic CD8+ T cell pool by inducing apoptosis, and that this effect requires Kupffer cells. Interfering with antigen presentation by Kupffer cells may be a strategy to limit HA antigen-induced deletion of activated CD8+ T cells entering the liver.