Reconstitution of galectin-3 alters glutathione content and potentiates TRAIL-induced cytotoxicity by dephosphorylation of Akt.

We investigated the role of galectin-3 in tumor necrosis factor-related apoptosis-inducing ligand (TRAIL)-induced apoptotic death in human breast carcinoma BT549 cells. We observed that parental galectin-3 null BT549 cells (BT549(par)) as well as control vector transfected (BT549(neo)) cells were resistant to TRAIL, while galectin-3 cDNA-transfected BT549 cells (BT549(gal-3)) were sensitive to TRAIL. Data from flow cytometry and immunoblotting analyses reveal that reconstitution of galectin-3 promoted cell death and PARP cleavage as well as caspase (-8, -9, and -3) activation during TRAIL treatment. However, unlike TRAIL treatment, galectin-3 transfectants were resistant to UV-B-induced PARP cleavage. Data from cDNA array analysis show that galectin-3 did not significantly enhance or reduce any apoptosis-related gene expression. Moreover, although galectin-3 restored pre-mRNA splicing activity and resulted in elevation of FLIPs protein, experiments with FLIPs cDNA-transfected cells show that overexpression of FLIPs did not sensitize cells to TRAIL. Interestingly, BT549(gal-3) cells demonstrated a approximately 2-fold increase in total glutathione content as well as a approximately 5-fold increase in GSSG content in comparison to BT549(par) and BT549(neo) cells, suggesting that galectin-3 overexpression may alter intraceullular oxidation/reduction reactions affecting the metabolism of glutathione and other thiols. In addition, galectin-3 overexpression inactivated Akt by dephosphorylation. Finally, overexpression of constitutively activated Akt protected BT549(gal-3) cells from TRAIL-induced cytotoxicity. Taken together, our data suggest that galectin-3-enhanced TRAIL-induced cytotoxicity is mediated through dephosphorylation of Akt, possibly through a redox-dependent process.

Differential regulation of maturation and apoptosis of human monocyte-derived dendritic cells mediated by MHC class II.

Antigen-driven interaction of dendritic cells (DC) with CD4(+) T(h) cells results in the exchange of bidirectional activating signals. Cross-linking of TCR by MHC class II-bound antigen activates T(h) cells, resulting in their up-regulation of CD40 ligand. Here we show that MHC class II molecules, in addition to their passive role in DC-T(h) cell interaction, can also actively induce DC maturation. Cross-linking of MHC class II molecules on human monocyte-derived DC results in the up-regulation of the surface expression of CD83, CD80, CD86, CD54, CD1a and CD40 molecules, the typical DC maturation-associated markers. It also promotes a rapid homotypic aggregation of DC paralleled by the up-regulation of such adhesion molecules as VLA-4, tissue transglutaminase, CD54 and CD11c. The impact of MHC class II cross-linking upon DC was context dependent. The outcome of MHC class II signaling depends on the maturation status of DC. While the cross-linking of MHC class II on immature DC promoted their maturation, the dominant effect upon the DC that were previously matured was the induction of DC apoptosis. Our current observations indicate that, in addition to the previously reported negative impact of MHC class II-mediated signaling on DC function, it also promotes DC maturation, participating in the enhancement of DC stimulatory function. Importantly, MHC class II-induced DC maturation and apoptosis are mediated by different signaling pathways, sensitive to different sets of inhibitors. This opens the possibility of differential regulation of each of these events in immunotherapy.