Molecular mechanisms underlying Ca2+-mediated motility of human pancreatic duct cells.

We recently reported that transforming growth factor-ß (TGF-ß) induces an increase in cytosolic Ca(2+) ([Ca(2+)](cyt)) in pancreatic cancer cells, but the mechanisms by which TGF-ß mediates [Ca(2+)](cyt) homeostasis in these cells are currently unknown. Transient receptor potential (TRP) channels and Na(+)/Ca(2+) exchangers (NCX) are plasma membrane proteins that play prominent roles in controlling [Ca(2+)](cyt) homeostasis in normal mammalian cells, but little is known regarding their roles in the regulation of [Ca(2+)](cyt) in pancreatic cancer cells and pancreatic cancer development. Expression and function of NCX1 and TRPC1 proteins were characterized in BxPc3 pancreatic cancer cells. TGF-ß induced both intracellular Ca(2+) release and extracellular Ca(2+) entry in these cells; however, 2-aminoethoxydiphenyl borate [2-APB; a blocker for both inositol 1,4,5-trisphosphate (IP(3)) receptor and TRPC], LaCl(3) (a selective TRPC blocker), or KB-R7943 (a selective inhibitor for the Ca(2+) entry mode of NCX) markedly inhibited the TGF-ß-induced increase in [Ca(2+)](cyt). 2-APB or KB-R7943 treatment was able to dose-dependently reverse membrane translocation of PKCα induced by TGF-ß. Transfection with small interfering RNA (siRNA) against NCX1 almost completely abolished NCX1 expression in BxPc3 cells and also inhibited PKCα serine phosphorylation induced by TGF-ß. Knockdown of NCX1 or TRPC1 by specific siRNA transfection reversed TGF-ß-induced pancreatic cancer cell motility. Therefore, TGF-ß induces Ca(2+) entry likely via TRPC1 and NCX1 and raises [Ca(2+)](cyt) in pancreatic cancer cells, which is essential for PKCα activation and subsequent tumor cell invasion. Our data suggest that TRPC1 and NCX1 may be among the potential therapeutic targets for pancreatic cancer.

TGF-beta downregulates PTEN via activation of NF-kappaB in pancreatic cancer cells.

TGF-beta utilizes receptor-activated SMAD signaling to mediate growth suppression; however, non-SMAD signaling that modulates the TGF-beta response in epithelial cells become apparent when the SMAD signaling is abrogated, a common occurrence in pancreatic cancers. Here, we examined whether TGF-beta utilized NF-kappaB to downregulate PTEN, a gene that is rarely mutated in pancreatic cancers. SMAD4-null BxPc3 and CAPAN-1 pancreatic cancer cells were treated with TGF-beta (10 ng/ml) and lysed, and cellular proteins were analyzed by Western blots using p-IkappaB, p65, and PTEN antibodies. PTEN promoter and NF-kappaB activities were assessed by PTEN-luc and p-NF-luc constructs, respectively. Dominant negative p-IkappaB-alpha-M (NF-kappaB superrepressor) was used to block activation of NF-kappaB. Cell motility was assessed by Boyden chamber migration assay. TGF-beta induced IkappaB-alpha phosphorylation followed by NF-kappaB p65 subunit nuclear translocation and increased NF-kappaB activity. IkappaB-alpha-M blocked TGF-beta-induced NF-kappaB activity, reversed downregulated PTEN promoter activity and PTEN expression, and prevented augmentation of cell motility induced by TGF-beta. SMAD4 restoration, but not knockdown of SMAD2 and/or 3, reversed TGF-beta-induced NF-kappaB activity. Thus TGF-beta suppresses PTEN in pancreatic cancer cells through NF-kappaB activation and enhances cell motility and invasiveness in a SMAD4-independent manner that can be counteracted when TGF-beta-SMAD signaling is restored. The TGF-beta/NF-kappaB/PTEN cascade may be a critical pathway for pancreatic cancer cells to proliferate and metastasize.