If host is refractory, insistent parasite goes berserk: Trypanosomatid Blastocrithidia raabei in the dock bug Coreus marginatus.

Here we characterized the development of the trypanosomatid Blastocrithidia raabei in the dock bug Coreus marginatus using light and electron microscopy. This parasite has been previously reported to occur in the host hemolymph, which is rather typical for dixenous trypanosomatids transmitted to a plant or vertebrate with insect's saliva. In addition, C. marginatus has an unusual organization of the intestine, which makes it refractory to microbial infections: two impassable segments isolate the anterior midgut portion responsible for digestion and absorption from the posterior one containing symbiotic bacteria. Our results refuted the possibility of hemolymph infection, but revealed that the refractory nature of the host provokes very aggressive behavior of the parasite and makes its life cycle more complex, reminiscent of that in some dixenous trypanosomatids. In the pre-barrier midgut portion, the epimastigotes of B. raabei attach to the epithelium and multiply similarly to regular insect trypanosomatids. However, when facing the impassable constricted region, the parasites rampage and either fiercely break through the isolating segments or attack the intestinal epithelium in front of the barrier. The cells of the latter group pass to the basal lamina and accumulate there, causing degradation of the epitheliocytes and thus helping the epimastigotes of the former group to advance posteriorly. In the symbiont-containing post-barrier midgut segment, the parasites either attach to bacterial cells and produce cyst-like amastigotes (CLAs) or infect enterocytes. In the rectum, all epimastigotes attach either to the cuticular lining or to each other and form CLAs. We argue that in addition to the specialized life cycle B. raabei possesses functional cell enhancements important either for the successful passage through the intestinal barriers (enlarged rostrum and well-developed Golgi complex) or as food reserves (vacuoles in the posterior end).

Role of trypanosomatid's arginase in polyamine biosynthesis and pathogenesis.

L-Arginine is one of the precursor amino acids of polyamine biosynthesis in most living organisms including Leishmania parasites. L-Arginine is enzymatically hydrolyzed by arginase producing L-ornithine and urea. In Leishmania spp. and other trypanosomatids a single gene encoding arginase has been described. The product of this gene is compartmentalized in glycosomes and is the main source of L-ornithine for polyamine synthesis in these parasites. L-Ornithine is substrate of ornithine decarboxylase (ODC) - one of the key enzymes of polyamine biosynthesis and a validated target for therapeutic intervention - producing putrescine, which in turn is converted to spermidine by condensing with an aminopropyl group from decarboxylated S-adenosylmethionine. Unlike trypanosomatids, mammalian hosts have two arginases (arginase I and II), which have close structural and kinetic resemblances, but localize in different subcellular organelles, respond to different stimuli and have different immunological reactivity. Arginase I is a cytosolic enzyme, mostly expressed in the liver as a pivotal component of the urea cycle, providing in addition L-ornithine for polyamine synthesis. In contrast, arginase II localizes inside mitochondria and is metabolically involved in L-proline and L-glutamine biosynthesis. More striking is the role played by L-arginine as substrate for nitric oxide synthase (NOS2) in macrophages, the main route of clearance of many infectious agents including Leishmania and Trypanosoma cruzi. In infected macrophages L-arginine is catalysed by NOS2 or arginase, contributing to host defense or parasite killing, respectively. A balance between NOS2 and arginase activities is a crucial factor in the progression of the Leishmania infection inside macrophages. In response to T-helper type 2 (Th2) cytokines, resident macrophages induce arginase I inhibiting NO production from L-arginine, thereby promoting parasite proliferation. Conversely, the response to T-helper type 1 (Th1) cytokines is linked to NOS2 induction and parasite death. Moreover, induction of any of these enzymes is accompanied by suppression of the other. Specifically, arginase reduces NO synthesis by substrate depletion, and N(ω)-hydroxy-L-arginine, one of the intermediates of NOS2 catalysis, competitively inhibits arginase activity. In spite of abundant data concerning arginases in mammals as well their involvement in parasite killing, there are very few papers regarding the actual role of arginase in the parasite itself. This review is an update on the recent progress in research on leishmanial arginase including the role played by this enzyme in the establishment of infection in macrophages and the immune response of the host. A comparative study of arginases from other kinetoplatids is also discussed.