Evasion of the complement system by Leishmania through the uptake of C4bBP, a complement regulatory protein, and probably by the action of GP63 on C4b molecules deposited on parasite surface.

The complement system is a primary component of the vertebrate innate immune system, and its activity is harmful to microorganisms and parasites. To evade complement attack, some pathogens, such as viruses, bacteria, and protozoa, can interact with complement regulatory proteins from their hosts. Our research group has described the ability of Leishmania species to bind Factor H from human serum and use it as a tool to evade the complement system. However, there is no description of the interaction of Leishmania with other complement regulatory proteins, such as the C4b-binding protein (C4bBP), a negative regulator of classical and lectins complement system pathways. The results presented in this manuscript suggest that Leishmania infantum, L. amazonensis, and L. braziliensis recruit C4bBP from human serum. The uptake of C4bBP by L. infantum was studied in detail to improve our understanding of this inhibitory mechanism. When exposed to this complement regulator, parasites with inactivated GP63 bind to C4bBP and inactivate C4b deposited on their surface after serum exposure. This inactivation occurs by the action of Factor I, a complement system protease. In addition to the C4bBP-Factor I inactivation mechanism, the surface parasite protease GP63 can also inactivate soluble C4b molecules and probably that C4b molecules deposited on the parasites surface. This manuscript shows that Leishmania has two independent strategies to inactivate C4b molecules, preventing the progress of classical and lectins pathways. The identification of the C4bBP receptor on the Leishmania membrane may provide a new vaccine target to fight leishmaniasis.

Evasion of the complement system by Leishmania through the uptake of factor H, a complement regulatory protein.

Escaping the complement system is an important step in the establishment of infections. Some pathogens have acquired the ability to inactivate the complement system to ensure successful infection. This has been observed in parasites from the genus Leishmania, which inactivate C3b molecules deposited on their surface through the membrane protease GP63. In the present study, we describe a new mechanism that also acts through C3b inactivation. This mechanism involves the binding of the complement regulatory molecule factor H from serum. Factor H signals a plasma protease (factor I) to inactivate C3b molecules deposited on the surface of the parasites. According to our results, Leishmania infantum, L. amazonensis, and L. braziliensis recruit factor H from human serum. The absorption of factor H by L. infantum was studied in detail to better understand how it works. L. infantum binds factor H from human serum and factor H-like proteins from dog serum. When exposed to purified factor H, promastigotes bind this regulatory molecule and inactivate C3b in the presence of factor I. This indicates the existence of an as yet unidentified factor H-binding outer surface molecule functioning as a receptor. The two mechanisms (GP63 and factor H binding) work independently, as Leishmania promastigotes with inhibited GP63 can easily inactivate C3b molecules on the surface of the parasite. The identification of the factor H receptor could lead to the development of a vaccine target for leishmaniasis control, as blocking antibodies to factor H binding could impair the mechanism of C3b inactivation, making the parasite more susceptible to the complement system.

How Lutzomyia longipalpis deals with the complement system present in the ingested blood: The role of soluble inhibitors and the adsorption of factor H by midgut.

Complement inhibitors are present in all hematophagous arthropods. Lutzomyia longipalpis is an important vector of Leishmania infantum, the etiologic agent of visceral leishmaniasis in the Americas. Studies with this vector identified complement inhibitors and respective inhibitory mechanisms. Despite the studies conducted with L. longipalpis, there is a gap in the knowledge about what happens in vivo with the complement present in the blood ingested. The experiments reported here show that the soluble inhibitor present in the intestinal lumen can act on the classical pathway of the human complement system by inhibiting the cascade soon after the activation of the C4 component. This means that this inhibitor can inhibit both the classical and lectin pathways. In the absence of salivary or gut inhibitors, the intestinal epithelium can activate the alternative pathway. At the same time, it can activate the lectin and the classical pathways by binding of MBL as well as by an antibody-independent C1 deposition mechanism. Without the salivary and intestinal inhibitors, the sand fly midgut epithelium may be more susceptible to complement attack as indicated by the C9/C3 deposition ratio when compared with intestines after a blood feed on a human host. In L. longipalpis, most of the C3 molecules present inside the midgut after a blood meal are found in their native form (not activated C3) or are present as iC3b (its inactivated form). C3b inactivation to iC3b, on the intestinal surface, is probably performed by a mechanism involving the uptake of factor H by the intestinal epithelium. Factor H is a negative complement regulator present in the plasma. Collectively, these results indicate how the complement inhibitors are necessary for a successful hematophagy in a sand fly model.

Host modulation by a parasite: how Leishmania infantum modifies the intestinal environment of Lutzomyia longipalpis to favor its development.

Some reports have described the interference of Leishmania on sand flies physiology, and such behavior most likely evolved to favor the development and transmission of the parasite. Most of these studies showed that Leishmania could modulate the level of proteases in the midgut after an infective blood meal, and decreased proteolytic activity is indeed beneficial for the development of promastigotes in the gut of sand flies. In the present study, we performed a detailed investigation of the intestinal pH in Lutzomyia longipalpis females naturally infected with Leishmania infantum and investigated the production of trypsin by these insects using different approaches. Our results allowed us to propose a mechanism by which these parasites interfere with the physiology of L. longipalpis to decrease the production of proteolytic enzymes. According to our hypothesis L. infantum promastigotes indirectly interfere with the production of trypsin by modulating the mechanism that controls the intestinal pH via the action of a yet non-identified substance released by promastigote forms inside the midgut. This substance is not an acid, whose action would be restrict on to release H+ to the medium, but is a substance that is able to interfere with midgut physiology through a mechanism involving pH control. According to our hypothesis, as the pH decreases, the proteolytic enzymes efficiency is also reduced, leading to a decline in the supply of amino acids to the enterocytes: this decline reduces the stimulus for protease production because it is regulated by the supply of amino acids, thus leading to a delay in digestion.