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Removal of apoptotic cells by macrophages or resident semi-professional phagocytes is a prominent principle with important implications for the pathophysiology of chronic inflammatory diseases, viral infections, or cancer. To characterize mechanisms which may determine the fate of apoptotic cells, I investigated chemokine expression in apoptotic promonocytic U-937 cells or PBMC. Exposure of U-937 cells to the anti-cancer drug etoposide (VP-16), an inducer of apoptosis in these cells, was associated with increased expression of the chemokines IL-8 and macrophage inflammatory protein 1alpha (MIP-1alpha). Upregulation of IL-8 mRNA expression by VP-16 was observed as early as 4 h after onset of treatment and was still detectable after 19h of exposure. A serine protease inhibitor prevented both VP-16-induced apoptosis and release of IL-8, whereas inhibition of p38 MAP-kinases reduced IL-8 secretion only. Moreover, I observed that incubation with 2-chlorodeoxyadenosine (CdA) upregulated release of IL-8 from adherent PBMC in parallel to induction of apoptosis. In these cells a modest but significant induction of TNF-alpha release by CdA was also detected. In addition, CdA augmented release of IL-8 from whole blood cultures. By facilitating adequate recruitment of phagocytes to sites of cell death, stress-induced upregulation of chemokines associated with apoptosis may contribute to mechanisms aiming at efficient removal of apoptotic cells.
During the past several years, ceramide has emerged as an important second messenger triggering cell responses including proliferation, differentiation, growth arrest and apoptosis. This thesis has focused on the regulation of neutral ceramidase which critically determines, in concert with ceramide generating sphingomyelinases, the intracellular ceramide levels. In the first part it is reported that besides a rapid and transient increase in neutral sphingomyelinase activity a second delayed peak of activation occurs after hours of IL-1beta treatment. This second phase of activation is first detectable after 2 h of treatment, and steadily increases over the next two hours reaching maximal values after 4 h. In parallel, a pronounced increase in neutral ceramidase activity is observed, which accounts for a constant or even decreased level of ceramide after long-term IL-1beta treatment, despite continuous sphingomyelinase activation. The increase in neutral ceramidase activity is due to expressional up-regulation, as detected by an increase in mRNA level and enhanced de novo protein synthesis. The increase of neutral ceramidase protein levels and activity can be blocked dosedependently by the p38- mitogen-activated protein kinase (p38-MAPK) inhibitor, SB 202190, whereas the classical MAPK pathway inhibitor U0126, and the PKC inhibitor Ro 31-8220 were ineffective. Moreover, co-treatment of cells for 24 h with IL-1~ and SB 202190 leads to an increase in ceramide formation. Interestingly, IL-1beta-stimulated neutral ceramidase activation is not reduced in mesangial cells isolated from mice deficient in MAPK-activated protein kinase 2 (MAPKAPK-2), which is one possible downstream substrate of the p38-MAPK, thus suggesting that the p38-MAPK-mediated induction of neutral ceramidase occurs independently of MAPKAPK-2. The results suggest a biphasic regulation of sphingomyelin hydrolysis in cytokine-treated mesangial cells with a delayed de novo synthesis of neutral ceramidase counteracting sphingomyelinase activity and apoptosis. Neutral ceramidase may thus represent a novel cytoprotective enzyme for mesangial cells exposed to inflammatory stress conditions. In a second part, the effect of NO on neutral ceramidase was studied. Ceramide levels are strongly increased in a delayed fashion by stimulation of renal mesangial cells with NO. This effect is due to a dual action of NO, comprising an activation of sphingomyelinases and an inhibition of ceramidase activity. The inhibition of neutral ceramidase activity correlates with the decrease of neutral ceramidase protein. A complete loss of neutral ceramidase protein is obtained after 24h of NO stimUlation. Moreover, the NO-induced degradation is reversed by the protein kinase C (PKC) activator, 12-0-tetradecanoylphorbol-13-acetate (TPA) , but also by the physiological PKC activators platelet-derived growth factor-BB (PDGF-BB), angiotensin II and ATP, resulting in a normalisation of neutral ceramidase protein as well as activity. In vivo phosphorylation studies using 32Pj-labelled mesangial cells, reveal that TPA, PDGF-BB, angiotensin II and ATP trigger an increased phosphorylation of the neutral ceramidase, which is blocked by the broad-spectrum PKC inhibitor Ro-31 8220, but not by CGP 41251, which has a preferential action on Ca2+-dependent PKC isoforms, thus suggesting the involvement of a Ca2+-independent PKC isoenzyme. In vitro phosphorylation assays using recombinant PKC isoenzymes and neutral ceramidase immunoprecipitated from unstimulated mesangial cells, show that particularly the PKC-alpha isoform, and to a lesser extent the PKC-a isoform, are efficient in directly phosphorylating neutral ceramidase. The data show that NO is able to induce degradation of neutral ceramidase thereby promoting accumulation of ceramide in the cell. This effect is reversed by PKC activation, most probably by the PKC-delta isoenzyme, which may directly phosphorylate and thereby, prevent neutral ceramidase degradation. In the third chapter it is demonstrated that the NO-triggered degradation of neutral ceramidase involves activation of the ubiquitin/proteasome complex. The specific proteasome inhibitor, lactacystin, completely reverses the NO-induced degradation of ceramidase protein and neutral ceramidase activity. As a consequence, the cellular amount of ceramide, which drastically increases by NO stimulation, is reduced in the presence of lactacystin. Furthermore, ubiquitinated neutral ceramidase accumulates after NO stimulation. The data clearly show that the ubiquitin/proteasome complex is an important determinant of neutral ceramidase activity and thereby regulates the availability of ceramide. In a last part, the cellular localisation of neutral ceramidase was investigated using green fluorescent protein (GFP) as fusion protein to examine cellular distribution and translocation of neutral ceramidase. Unstimulated HEK 293 cells reveal after transient transfection experiments that neutral ceramidase is preferentially localized in the cytoplasm. PKC activation led to an accumulation of neutral ceramidase at the nuclear membrane. In summary, this work demonstrates that the neutral ceramidase is a fine regulated protein that plays a critical role in regulating intracellular ceramide levels and thereby the cell's fate to undergo apoptosis or survive. Regulation of neutral ceramidase can be achieved on all levels, i.e. on the mRNA level, the protein level or posttranslationally by phosphorylation and subcellular translocation. Future work will reveal whether neutral ceramidase can serve as a therapeutic target in the development of novel antiinflammatory and anti-tumour drugs.