Lymphocytes support oval cell-dependent liver regeneration.

In case of hepatic damage, the liver uses a unique regeneration mechanism through proliferation of hepatocytes. If this process is inhibited, bipotent oval stem cells proliferate and differentiate to hepatocytes and bile ducts, thus restoring liver mass. Although oval cell accumulation in the liver is often associated with inflammatory processes, the role of lymphocytes in oval cell-mediated hepatic regeneration is poorly understood. We treated wild-type and immunodeficient mice with an oval cell-inducing diet: in the absence of T cells (CD3epsilon(-/-) and Rag2(-/-)) there were fewer oval cells, whereas in alymphoid mice (Rag2(-/-)gamma(c)(-/-)) a strongly reduced oval cell response and higher mortality, due to liver failure, was observed. Adoptive transfer of T cells into alymphoid mice protected them from liver failure, but was insufficient to restore the oval cell response. Treatment of Rag2(-/-) mice with an NK cell-depleting Ab resulted in a significantly diminished oval cell response. These genetic experiments point to a major role for NK and T cells in oval cell expansion. In wild-type mice, oval cell proliferation is accompanied by an intrahepatic inflammatory response, characterized by the recruitment of Kupffer, NK, NKT, and T cells. Under these conditions, lymphocytes produce T(H)1 proinflammatory cytokines (IFN-gamma and TNF-alpha) that are mitogenic for oval cells. Our data suggest that T and NK lymphocytes stimulate oval cell expansion by local cytokine secretion. This beneficial cross-talk between the immune system and liver stem cells operates under noninfectious conditions and could promote tissue regeneration following acute liver damage.

Gamma c cytokines condition the progressive differentiation of CD4+ T cells.

After their initial antigen encounter in the secondary lymphoid organs, activated T cells must receive additional signals in the peripheral tissues to fully differentiate. Here, we provide evidence that gamma(c) cytokines are critical during this process. Using the Marilyn (Ml) T cell antigen receptor (TCR) transgenic model, we show that male skin grafts are tolerated in the absence of gamma(c), but that Ml CD4(+) T cells proliferate normally in response to antigen, traffic to the graft site and recruit an inflammatory response [including natural killer (NK) cells, neutrophils, and macrophages] that is independent of T cell gamma(c) expression. Whereas wild-type T cells demonstrate a progressive differentiation phenotype from the spleen to the tissues, skin-infiltrating effector T cells (CD44(hi)CD62L(lo)) from gamma(c)(-) mice were phenotypically abnormal with reduced ICOS, NKG2D, granzyme B, and IFN-gamma expression. These defects could be mapped to deficiencies in IL-2 and, surprisingly, IL-15. These results define a late checkpoint in T cell differentiation in the tissues where gamma(c) cytokines, including IL-15, authenticate CD4(+) T cell effector functions.

gamma(c) cytokines provide multiple homeostatic signals to naive CD4(+) T cells.

Cytokines signaling through receptors sharing the common gamma chain (gamma(c)), including IL-2, IL-4, IL-7, IL-9, IL-15 and IL-21, are critical for the generation and peripheral homeostasis of B, T and NK cells. To identify unique or redundant roles for gamma(c) cytokines in naive CD4(+) T cells, we compared monoclonal populations of CD4(+) T cells from TCR-Tg mice that were gamma(c) (+), gamma(c) (-), CD127(-/-) or CD122(-/-). We found that gamma(c) (-) naive CD4(+) T cells failed to accumulate in the peripheral lymphoid organs and the few remaining cells were characterized by small size, decreased expression of MHC class I and enhanced apoptosis. By over-expressing human Bcl-2, peripheral naive CD4(+) T cells that lack gamma(c) could be rescued. Bcl-2(+) gamma(c) (-) CD4(+) T cells demonstrated enhanced survival characteristics in vivo and in vitro, and could proliferate normally in vitro in response to antigen. Nevertheless, Bcl-2(+) gamma(c) (-) CD4(+) T cells remained small in size, and this phenotype was not corrected by enforced expression of an activated protein kinase B. We conclude that gamma(c) cytokines (primarily but not exclusively IL-7) provide Bcl-2-dependent as well as Bcl-2-independent signals to maintain the phenotype and homeostasis of the peripheral naive CD4(+) T cell pool.

The JNK/AP-1 pathway upregulates expression of the recycling endosome rab11a gene in B cells transformed by Theileria.

Lymphocyte transformation induced by Theileria parasites involves constitutive activation of c-Jun N-terminal kinase (JNK) and the AP-1 transcription factor. We found that JNK/AP-1 activation is associated with elevated levels of Rab11 protein in Theileria-transformed B cells. We show that AP-1 regulates rab11a promoter activity in B cells and that the induction of c-Jun activity in mouse fibroblasts also leads to increased transcription of the endogenous rab11a gene, consistent with it being an AP-1 target. Pharmacological inhibition of the JNK pathway reduced Rab11 protein levels and endosome recycling of transferrin receptor (TfR) and siRNA knockdown of JNK1 and Rab11A levels also reduced TfR surface expression. We propose a model, where activation of the JNK/AP-1 pathway during cell transformation might assure that the regulation of recycling endosomes is co-ordinated with cell-cycle progression. This might be achieved via the simultaneous upregulation of the cell cycle machinery (e.g. cyclin D1) and the recycling endosome regulators (e.g. Rab11A).