Verotoxin-1-Induced ER Stress Triggers Apoptotic or Survival Pathways in Burkitt Lymphoma Cells.

Shiga toxins (Stxs) expressed by the enterohaemorrhagic Escherichia coli and enteric Shigella dysenteriae 1 pathogens are protein synthesis inhibitors. Stxs have been shown to induce apoptosis via the activation of extrinsic and intrinsic pathways in many cell types (epithelial, endothelial, and B cells) but the link between the protein synthesis inhibition and caspase activation is still unclear. Endoplasmic reticulum (ER) stress induced by the inhibition of protein synthesis may be this missing link. Here, we show that the treatment of Burkitt lymphoma (BL) cells with verotoxin-1 (VT-1 or Stx1) consistently induced the ER stress response by activation of IRE1 and ATF6-two ER stress sensors-followed by increased expression of the transcription factor C/REB homologous protein (CHOP). However, our data suggest that, although ER stress is systematically induced by VT-1 in BL cells, its role in cell death appears to be cell specific and can be the opposite: ER stress may enhance VT-1-induced apoptosis through CHOP or play a protective role through ER-phagy, depending on the cell line. Several engineered Stxs are currently under investigation as potential anti-cancer agents. Our results suggest that a better understanding of the signaling pathways induced by Stxs is needed before using them in the clinic.

The EcoRI-DNA complex as a model for investigating protein-DNA interactions by atomic force microscopy.

Atomic force microscopy (AFM) is a technique widely used to image protein-DNA complexes, and its application has now been extended to the measurements of protein-DNA binding constants and specificities. However, the spreading of the protein-DNA complexes on a flat substrate, generally mica, is required prior to AFM imaging. The influence of the surface on protein-DNA interactions is therefore an issue which needs to be addressed. For that purpose, the extensively studied EcoRI-DNA complex was investigated with the aim of providing quantitative information about the surface influence. The equilibrium binding constant of the complex was determined by AFM at both low and high ionic strengths and compared to electrophoretic mobility shift assay measurements (EMSA). In addition, the effect of the DNA length on dissociation of the protein from its specific site was analyzed. It turned out that the AFM measurements are similar to those obtained by EMSA at high ionic strengths. We then advance the idea that this effect is due to the high counterion concentration near the highly negatively charged mica surface. In addition, a dissociation of the complexes once they are adsorbed onto the surface was observed, which is weakly dependent on the ionic strength contrary to what occurs in solution. Finally, a two-step mechanism, which describes the adsorption of the EcoRI-DNA complexes on the surface, is proposed. This model could also be extended to other protein-DNA complexes.