Zinc Sensing Receptor Signaling, Mediated by GPR39, Reduces Butyrate-Induced Cell Death in HT29 Colonocytes via Upregulation of Clusterin

Zinc enhances epithelial proliferation, protects the digestive epithelial layer and has profound antiulcerative and antidiarrheal roles in the colon. Despite the clinical significance of this ion, the mechanisms linking zinc to these cellular processes are poorly understood. We have previously identified an extracellular Zn2+ sensing G-protein coupled receptor (ZnR) that activates Ca2+ signaling in colonocytes, but its molecular identity as well as its effects on colonocytes' survival remained elusive. Here, we show that Zn2+, by activation of the ZnR, protects HT29 colonocytes from butyrate induced cell death. Silencing of the G-protein coupled receptor GPR39 expression abolished ZnR-dependent Ca2+ release and Zn2+-dependent survival of butyrate-treated colonocytes. Importantly, GPR39 also mediated ZnR-dependent upregulation of Na+/H+ exchange activity as this activity was found in native colon tissue but not in tissue obtained from GPR39 knock-out mice. Although ZnR-dependent upregulation of Na+/H+ exchange reduced the cellular acid load induced by butyrate, it did not rescue HT29 cells from butyrate induced cell death. ZnR/GPR39 activation however, increased the expression of the anti-apoptotic protein clusterin in butyrate-treated cells. Furthermore, silencing of clusterin abolished the Zn2+-dependent survival of HT29 cells. Altogether, our results demonstrate that extracellular Zn2+, acting through ZnR, regulates intracellular pH and clusterin expression thereby enhancing survival of HT29 colonocytes. Moreover, we identify GPR39 as the molecular moiety of ZnR in HT29 and native colonocytes

Extracellular pressure stimulates tumor cell adhesion in vitro by paxillin activation

Metastasizing colon cancer cells bind target tissues primarily via integrins. Extracellular pressure or shear stress stimulates integrin-mediated adhesion to matrix proteins or endothelial cells by activating the focal adhesion proteins FAK and Src. Because this effect is blocked by cytoskeletal perturbation and paxillin may link the cytoskeleton to the focal adhesion complex, we evaluated the role of paxillin in pressureinduced malignant colonocyte adhesion. We studied SW620 colon cancer cells and confirmed key results in Caco-2 colon cancer cells, primary human colon cancer cells, and a murine colonic adenocarcinoma. We evaluated adhesion to collagen at ambient and 15 mmHg increased pressure after 30 minutes, and paxillin, FAK, and Src phosphorylation in suspended cells prior to adhesion. Some cells were treated with siRNA to paxillin or FAK, or the Src inhibitor PP2. We also compared pressure-induced signals in suspended cells with adhesion-induced signals after adhesion to collagen. Pressure stimulated adhesion and paxillin phosphorylation in SW620 and Caco-2 cells and human primary colon cancer cells. Pressure also increased paxillin phosphorylation in murine carcinoma cells. SiRNA to paxillin decreased SW620 and Caco-2 paxillin without altering basal levels of phosphorylated paxillin. Paxillin reduction decreased basal adhesion to collagen, and inhibited pressure-stimulated adhesion, as well as paxillin, FAK397, FAK576, and Src476 phosphorylation. Neither PP2 nor siRNA to FAK inhibited induction of paxillin phosphorylation by pressure. In contrast, adhesion stimulated FAK, Src, and paxillin phosphorylation regardless of paxillin reduction. In summary, pressure induced paxillin phosphorylation in colon cancer cells. Paxillin reduction inhibited basal adhesion and blocked the pressure-mediated increase in adhesion, as well as pressure-induced FAK and Src signals, while adhesion-induced signals were preserved. Paxillin may be an upstream mediator of pressure-stimulated adhesion, important in metastasis