Identification of proteins modified by S-nitrosylation and tyrosine nitration after adhesion of Trypanosoma cruzi to the extracellular matrix

Nitric oxide (NO) is a second messenger biosynthesized from L-Arginine and involved in cell signaling by different mechanisms: activation of cGMP production by guanilyl cyclase; regulation of enzymes by interaction with their metallic centers; or by S-nitrosylation of cysteine and nitration of tyrosine, posttranslational modifications capable of modulating the activity of several proteins. In this work, we sought to investigate whether the interaction between extracellular matrix (ECM) and Trypanosoma cruzi, the etiological agent of Chagas\' disease, was capable of modulating NO signaling in the parasite. Trypomastigotes incubated with ECM presented a decrease in NOS activity and NO production. Accordingly, a decrease in S-nitrosylation and tyrosine nitration of proteins from ECM-incubated parasites was also observed, as evidenced by indirect immunofluorescence and immunoblotting. In addition, S-nitrosylated and tyrosine nitrated proteins profiles were modified in ECM-incubated parasites, with an enhancement in protein denytrosylation and denitration. A decrease from 40 to 22 of S-nitrosylated proteins was detected after parasite adhesion to ECM, more evident in some protein groups (as for example 52.5% hypothetical proteins modified in the control group against 36.4% after adhesion). On the other hand, an increase of S-nitrosylation was detected in other groups of proteins, such as cytoskeleton proteins (from 2.5% of total S-nitrosylated proteins to 9.1% after adhesion). The same general pattern was observed in relation to tyrosine-nitrated proteins, with a decrease in the number of modified proteins from 48 to 20 after incubation with ECM, exemplified by those related to protein synthesis, with a contribution of 35.4% in the control group versus 5.0% after treatment with ECM. Despite this general denitration profile, some protein classes have an increase in nitration, such as metabolic proteins (from 18.8% to 35.0%), in addition to some specific targets, such as enolase. Taken together, the results suggest that NO signaling is modulated during adhesion of T. cruzi to components of the extracellular matrix, probably by the classical nitric oxide pathway and by NO-induced post translational modifications. (AU)