Pharmacological targeting of the protein synthesis mTOR/4E-BP1 pathway in cancer-associated fibroblasts abrogates pancreatic tumourchemoresistance

International audiencePancreatic ductal adenocarcinoma (PDAC) is extremely stroma-rich. Cancer-associated fibroblasts (CAFs) secrete proteins that activate survival and promote chemoresistance of cancer cells. Our results demonstrate that CAF secretome-triggered chemoresistance is abolished upon inhibition of the protein synthesis mTOR/4E-BP1 regulatory pathway which we found highly activated in primary cultures of -SMA-positive CAFs, isolated from human PDAC resections. CAFs selectively express the sst1 somatostatin receptor. The SOM230 analogue (Pasireotide) activates the sst1 receptor and inhibits the mTOR/4E-BP1 pathway and the resultant synthesis of secreted proteins including IL-6. Consequently, tumour growth and chemoresistance in nude mice xenografted with pancreatic cancer cells and CAFs, or with pieces of resected human PDACs, are reduced when chemotherapy (gemcitabine) is combined with SOM230 treatment. While gemcitabine alone has marginal effects, SOM230 is permissive to gemcitabine-induced cancer cell apoptosis and acts as an antifibrotic agent. We propose that selective inhibition of CAF protein synthesis with sst1-directed pharmacological compounds represents an anti-stromal-targeted therapy with promising chemosensitization potential

Toward a Full Characterization of the Human 20S Proteasome Subunits and Their Isoforms by a Combination of Proteomic Approaches

International audienceThe 20S proteasome is a multicatalytic protein complex, present in all eukaryotic cells, that plays a major role in intracellular protein degradation. In mammalian cells, this symmetrical cylindrical complex is composed of two copies each of seven different alpha and beta subunits arranged into four stacked rings (alpha(7)beta(7)beta(7)alpha(7)). Separation by two-dimensional (2D) gel electrophoresis of the human erythrocytes 20S proteasome subunits and mass spectrometry (MS) identification of all the observed spots reveal the presence of multiple isoforms for most of the subunits. These isoforms could correspond to protein variants and/or posttranslational modifications that may influence the 20S proteasome proteolytic activity. Their characterization is therefore important to establish the rules governing structure/activity relationships of the human 20S proteasome. This chapter describes the use of a combination of proteomic approaches to characterize the human 20S proteasome subunit isoforms separated by 2D gel electrophoresis. A "top-down" strategy was developed to determine by electrospray MS the molecular mass of the intact protein after its passive elution from the gel. Comparison of the experimental molecular mass to the theoretical one can reveal the presence of possible modifications. "Bottom-up" proteomic approaches are then performed and, after protein digestion, tandem MS analyses of the modified peptides allow the characterization and location of the modification. These methods are discussed for the study of the human erythrocytes 20S proteasome subunit isoforms

Comparison of label-free quantification methods for the determination of protein complexes subunits stoichiometry

Protein complexes are the main molecular machines that support all major cellular pathways and their in-depth characterization are essential to understand their functions. Determining the stoichiometry of the different subunits of a protein complex still remains challenging. Recently, many label-free quantitative proteomic approaches have been developed to study the composition of protein complexes. It is therefore of great interest to evaluate these different methods in a stoichiometry oriented objective. Here we compare the ability of four absolute quantitative label-free methods currently used in proteomic studies to determine the stoichiometry of a well-characterized protein complex, the 26S proteasome

Analysis of the processing of seven human tumor antigens by intermediate proteasomes.

We recently described two proteasome subtypes that are intermediate between the standard proteasome and the immunoproteasome. They contain only one (β5i) or two (β1i and β5i) of the three inducible catalytic subunits of the immunoproteasome. They are present in tumor cells and abundant in normal human tissues. We described two tumor antigenic peptides that are uniquely produced by these intermediate proteasomes. In this work, we studied the production by intermediate proteasomes of tumor antigenic peptides known to be produced exclusively by the immunoproteasome (MAGE-A3(114-122), MAGE-C2(42-50), MAGE-C2(336-344)) or the standard proteasome (Melan-A(26-35), tyrosinase(369-377), gp100(209-217)). We observed that intermediate proteasomes efficiently produced the former peptides, but not the latter. Two peptides from the first group were equally produced by both intermediate proteasomes, whereas MAGE-C2(336-344) was only produced by intermediate proteasome β1i-β5i. Those results explain the recognition of tumor cells devoid of immunoproteasome by CTL recognizing peptides not produced by the standard proteasome. We also describe a third antigenic peptide that is produced exclusively by an intermediate proteasome: peptide MAGE-C2(191-200) is produced only by intermediate proteasome β1i-β5i. Analyzing in vitro digests, we observed that the lack of production by a given proteasome usually results from destruction of the antigenic peptide by internal cleavage. Interestingly, we observed that the immunoproteasome and the intermediate proteasomes fail to cleave between hydrophobic residues, despite a higher chymotrypsin-like activity measured on fluorogenic substrates. Altogether, our results indicate that the repertoire of peptides produced by intermediate proteasomes largely matches the repertoire produced by the immunoproteasome, but also contains additional peptides