Trypanosoma brucei transferrin receptor: Functional replacement of the GPI anchor with a transmembrane domain

Theft of Host Transferrin Receptor-1 by Toxoplasma gondii is required for infection

Nutrient acquisition by apicomplexan parasites is essential to drive their intracellular replication, yet the mechanisms that underpin essential nutrient acquisition are not defined. Using the apicomplexan model Toxoplasma gondii , we show that host cell proteins including the transferrin receptor 1, transferrin, ferritin heavy and light chains, and clathrin light chain are robustly taken up by tachyzoites. Tachyzoite acquisition of host cell protein was not related to host cell type or parasite virulence phenotypes. Bradyzoites possessed little capacity to acquire host cell proteins consistent with the cyst wall representing a barrier to host cell protein cargo. Increased trafficking of host cell transferrin receptor 1 and transferrin to endolysosomes boosted tachyzoite acquisition of host proteins and growth rate. Theft of host transferrin 1 and transferrin did not significantly affect iron levels in the tachyzoite. This study provides insight into essential functions associated with parasite theft of host iron sequestration and storage proteins.

The Leishmania donovani Ortholog of the Glycosylphosphatidylinositol Anchor Biosynthesis Cofactor PBN1 Is Essential for Host Infection

Visceral leishmaniasis is a deadly infectious disease caused by Leishmania donovani, a kinetoplastid parasite for which no licensed vaccine is available. To identify potential vaccine candidates, we systematically identified genes encoding putative cell surface and secreted proteins essential for parasite viability and host infection. We identified a protein encoded by LdBPK_061160 which, when ablated, resulted in a remarkable increase in parasite adhesion to tissue culture flasks. Here, we show that this phenotype is caused by the loss of glycosylphosphatidylinositol (GPI)-anchored surface molecules and that LdBPK_061160 encodes a noncatalytic component of the L. donovani GPI-mannosyltransferase I (GPI-MT I) complex. GPI-anchored surface molecules were rescued in the LdBPK_061160 mutant by the ectopic expression of both human genes PIG-X and PIG-M, but neither gene could complement the phenotype alone. From further sequence comparisons, we conclude that LdBPK_061160 is the functional orthologue of yeast PBN1 and mammalian PIG-X, which encode the noncatalytic subunits of their respective GPI-MT I complexes, and we assign LdBPK_061160 as LdPBN1. The LdPBN1 mutants could not establish a visceral infection in mice, a phenotype that was rescued by constitutive expression of LdPBN1. Although mice infected with the null mutant did not develop an infection, exposure to these parasites provided significant protection against subsequent infection with a virulent strain. In summary, we have identified the orthologue of the PBN1/PIG-X noncatalytic subunit of GPI-MT I in trypanosomatids, shown that it is essential for infection in a murine model of visceral leishmaniasis, and demonstrated that the LdPBN1 mutant shows promise for the development of an attenuated live vaccine.