A 120-kDa Alkaline Peptidase from Trypanosoma cruzi Is Involved in the Generation of a Novel Ca2+-signaling Factor for Mammalian Cells (*)

Trypomastigotes, the infective stages of the intracellular parasite Trypanosoma cruzi, induce rapid and repetitive cytosolic free Ca2+ transients in fibroblasts. Buffering or depletion of intracellular free Ca2+ inhibits cell entry by trypomastigotes, indicating a role for this signaling event in invasion. We show here that the majority of the Ca2+-signaling activity is associated with the soluble fraction of parasites disrupted by sonication. Distinct cell types from different species are responsive to this soluble factor, and intracellular free Ca2+ transients occur rapidly and reach concentrations comparable to responses induced by thrombin and bombesin. The Ca2+-signaling activity does not bind concanavalin A and is strongly inhibited by a specific subset of protease inhibitors. The only detectable protease in the fractions with Ca2+-signaling activity is an unusual alkaline peptidase of 120 kDa, to which no function had been previously assigned. The activity of the protease and cell invasion by trypomastigotes are blocked by the same specific inhibitors that impair Ca2+-signaling, suggesting that the enzyme is required for generating the response leading to infection. We demonstrate that the 120-kDa peptidase is not sufficient for triggering Ca2+-signaling, possibly being involved in the processing of precursors present only in infective trypomastigotes. These findings indicate a biological function for a previously identified unusual protozoan protease and provide the first example of a proteolytically generated parasite factor with characteristics of a mammalian hormone.

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