Abstract
Eight to 10 million people in 21 endemic countries are infected with Trypanosoma cruzi. However, only 30% of those infected develop symptoms of Chagas’ disease, a chronic, neglected tropical disease worldwide. Similar to other pathogens, T. cruzi has evolved to resist the host immune response. Studies, performed 80 years ago in the Soviet Union, proposed that T. cruzi infects tumor cells with similar capacity to that displayed for target tissues such as cardiac, aortic, or digestive. An antagonistic relationship between T. cruzi infection and cancer development was also proposed, but the molecular mechanisms involved have remained largely unknown. Probably, a variety of T. cruzi molecules is involved. This review focuses on how T. cruzi calreticulin (TcCRT), exteriorized from the endoplasmic reticulum, targets the first classical complement component C1 and negatively regulates the classical complement activation cascade, promoting parasite infectivity. We propose that this C1-dependent TcCRT-mediated virulence is critical to explain, at least an important part, of the parasite capacity to inhibit tumor development. We will discuss how TcCRT, by directly interacting with venous and arterial endothelial cells, inhibits angiogenesis and tumor growth. Thus, these TcCRT functions not only illustrate T. cruzi interactions with the host immune defensive strategies, but also illustrate a possible co-evolutionary adaptation to privilege a prolonged interaction with its host.
Highlights
Trypanosoma cruzi cell infection is preceded by a variety of molecular interactions [1]
We have recently proposed that the T. cruzi calreticulin (TcCRT)/C1q/human CRT (HuCRT) interaction is very important in an ex vivo model of infection of human placenta [84], indicating a possible mechanism to explain the congenital transmission
We propose that, during T. cruzi infection, Native TcCRT (nTcCRT) mediates key alterations in the tumor cell microenvironment leading to an adaptive immune response, with significant antitumor effects
Summary
Trypanosoma cruzi (the protozoan agent of Chagas’ disease) cell infection is preceded by a variety of molecular interactions [1]. Of relevance is the generation of a synapsis involving parasite endoplasmic reticulum (ER)-resident T. cruzi calreticulin (TcCRT) that, after translocation, interacts with complement component C1. The complement system, an important arm of innate and adaptive immune responses, is inhibited and parasite infectivity increased. A unifying molecular basis for these apparently unrelated phenomena is proposed . These molecular interactions do provide benefits for both the host and the parasite. Microbial agents have developed different mechanisms to resist the host immune response.
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