Identification of proteins modified by phosphorylation after treatment of Schistosoma mansoni with human TNF-alpha

Schistosomiasis remains one of the parasitic diseases with the highest incidence worldwide. Schistosoma mansoni, the only species found in Brazil, has a complex life cycle which includes six life stages and two hosts, one of them being humans. Our group has identified a gene that encodes a TNF-alpha receptor-like in S. mansoni (SmTNFR) and described the in vitro effect of human TNF-alpha cytokine on large-scale gene expression of the parasite. The signaling pathways by which TNF-alpha acts upon the parasite remain unknown. In humans, when TNF-alpha binds to the receptor isoform that is most similar to SmTNFR it initiates a phosphorylation cascade that activates a signaling pathway leading to the activation of transcription factors. Our hypothesis is that this cytokine could act in the parasite through a phosphorylation cascade that activates transcription factors resulting in the change of gene expression observed in our previous work. The aim of this work was to verify if there were proteins that showed increased phosphorylation upon the in vitro treatment of worms with human TNF-alpha, identifying them, to try and elucidate the signaling pathway by which the cytokine acts in S. mansoni. In order to identify which proteins are significantly differentially phosphorylated upon exposure of S. mansoni to the human cytokine, we incubated male adult worms for 15 min in culture with human TNF-alpha (20 ng / ml), or with vehicle only, in controls, and we extracted total proteins from the parasites. We used the phosphoproteomics approach of bidimensional gel electrophoresis followed by phospho-specific staining of gels using Pro-Q Diamond dye (Invitrogen). To identify which proteins were phosphorylated or had their phosphorylation changed due to the treatment, we quantified the spots (determined the spots volumes) from Pro-Q stained gels using Image Master 2D Platinum software (GE). A total protein staining of the gels was performed using Coomassie Brilliant Blue (CBB) in order to localize all protein spots in the gel. We excised from CBB stained gels the protein spots that showed statistically significant changes in phosphorylation (n= 3 replicates; p-value<0.05, t-test), based on the relative volumes of their spot images with respect to the total volume of spots in the gel, with samples from treated compared to control parasites, and subsequently the proteins in these samples were identified by mass spectrometry. We have analyzed three biological replicates and observed 45 spots that were differentially phosphorylated; 42 of them had their phosphorylation increased and 3 had their phosphorylation decreased upon a 15-min-treatment of male adult worms with the cytokine. Among the spots identified by mass spectrometry, we found proteins related to metabolic process, cell signaling, and cytoskeleton and muscle contraction. Although the experimental approach adopted for this study was not sensitive enough to conclude which canonical signal transduction pathway is activated by human TNF-alpha in S. mansoni, this kind of study confirmed the increase in phosphorylation of target proteins induced by human TNF-alpha, opening new paths for further investigation in order to characterize the role of the proteins identified as altered by this specific signaling, which will lead to a better understanding of the importance of this cytokine in the biology of S. mansoni and in host-parasite interaction. (AU)