Aspartyl Protease 5 Matures Dense Granule Proteins That Reside at the Host-Parasite Interface in Toxoplasma gondii

infects approximately 30% of the world's population, causing disease primarily during pregnancy and in individuals with weakened immune systems. secretes and exports effector proteins that modulate the host during infection, and several of these proteins are processed by the Golgi-associated as...

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Bibliographic Details
Published in:mBio 2018-10, Vol.9 (5)
Main Authors: Coffey, Michael J, Dagley, Laura F, Seizova, Simona, Kapp, Eugene A, Infusini, Giuseppe, Roos, David S, Boddey, Justin A, Webb, Andrew I, Tonkin, Christopher J
Format: Article
Language:English
Subjects:
Aspartic Acid Proteases - genetics
Aspartic Acid Proteases - metabolism
Cells, Cultured
effector
Fibroblasts - parasitology
Gene Deletion
Host-Microbe Biology
Humans
Intracellular Membranes - metabolism
Protein Processing, Post-Translational
proteomics
Protozoan Proteins - genetics
Protozoan Proteins - metabolism
Toxoplasma
Toxoplasma - enzymology
Toxoplasma - genetics
Toxoplasma - metabolism
Vacuoles - metabolism
Vacuoles - parasitology
virulence
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Summary:infects approximately 30% of the world's population, causing disease primarily during pregnancy and in individuals with weakened immune systems. secretes and exports effector proteins that modulate the host during infection, and several of these proteins are processed by the Golgi-associated aspartyl protease 5 (ASP5). Here, we identify ASP5 substrates by selectively enriching N-terminally derived peptides from wild-type and parasites. We reveal more than 2,000 unique N-terminal peptides, mapping to both natural N termini and protease cleavage sites. Several of these peptides mapped directly downstream of the characterized ASP5 cleavage site, arginine-arginine-leucine (RRL). We validate candidates as true ASP5 substrates, revealing they are not processed in parasites lacking ASP5 or in wild-type parasites following mutation of the motif from RRL to ARL. All identified ASP5 substrates are dense granule proteins, and interestingly, none appear to be exported, thus differing from the analogous system in related spp. Instead we show that the majority of substrates reside within the parasitophorous vacuole (PV), and its membrane (the PVM), including two kinases and one phosphatase. We show that genetic deletion of WNG2 leads to attenuation in a mouse model, suggesting that this putative kinase is a new virulence factor in Collectively, these data constitute the first in-depth analyses of ASP5 substrates and shed new light on the role of ASP5 as a maturase of dense granule proteins during the lytic cycle. is one of the most successful human parasites. Central to its success is the arsenal of virulence proteins introduced into the infected host cell. Several of these virulence proteins require direct maturation by the aspartyl protease ASP5, and all require ASP5 for translocation into the host cell, yet the true number of ASP5 substrates and complete repertoire of effectors is currently unknown. Here we selectively enrich N-terminally derived peptides using Terminal Amine Isotopic Labeling of Substrates (TAILS) and use quantitative proteomics to reveal novel ASP5 substrates. We identify, using two different enrichment techniques, new ASP5 substrates and their specific cleavage sites. ASP5 substrates include two kinases and one phosphatase that reside at the host-parasite interface, which are important for infection.
ISSN:2161-2129
2150-7511
DOI:10.1128/mBio.01796-18