The oral tolerance as a complex network phenomenon

The phenomenon of oral tolerance refers to a local and systemic state of tolerance, induced in the gut associated lymphoid tissues, after its exposure to innocuous antigens, such as food proteins. While recent findings shed light in the cellular and molecular basis of oral tolerance, the network of interactions between the components mediating oral tolerance has not been investigated yet. Our work brings a complex systems theory approach, aiming to identify the contribution of each element in an oral tolerance network. We also propose a model that allows dynamical plus topological quantifying which must encompass functional responses as the local host involved on the oral tolerance. To keep track of reality of our model, we test knockout (KO) of immunological components (i. e. silencing a vertex) and see how it diverges when the system is topologically health. The results from these simulated KO's are then compared to real molecular knock-outs. To infer from these processing we apply a new implementation of a random walk algorithm for directed graphs, which ultimately generate statistical quantities provided by the dynamical behaviour of the simulated KO's. It was observed that the a specifics KO caused the greatest impact on network standard flux. In a brief analysis, the results obtained correspond to biological data. Our model addresses both topological proprieties and dynamical relations. The construction of a qualitative dynamic model for oral tolerance could reflect empirical observations, through the standard flux results and relative error based on individual knockout.