Barbara Clough scite author profile

The guanylate binding protein (GBP) family of interferon‐inducible GTPases promotes antimicrobial immunity and cell death. During bacterial infection, multiple mouse Gbps, human GBP2, and GBP5 support the activation of caspase‐1‐containing inflammasome complexes or caspase‐4 which trigger pyroptosis. Whether GBPs regulate other forms of cell death is not known. The apicomplexan parasite Toxoplasma gondii causes macrophage death through unidentified mechanisms. Here we report that Toxoplasma‐induced death of human macrophages requires GBP1 and its ability to target Toxoplasma parasitophorous vacuoles through its GTPase activity and prenylation. Mechanistically, GBP1 promoted Toxoplasma detection by AIM2, which induced GSDMD‐independent, ASC‐, and caspase‐8‐dependent apoptosis. Identical molecular determinants targeted GBP1 to Salmonella‐containing vacuoles. GBP1 facilitated caspase‐4 recruitment to Salmonella leading to its enhanced activation and pyroptosis. Notably, GBP1 could be bypassed by the delivery of Toxoplasma DNA or bacterial LPS into the cytosol, pointing to its role in liberating microbial molecules. GBP1 thus acts as a gatekeeper of cell death pathways, which respond specifically to infecting microbes. Our findings expand the immune roles of human GBPs in regulating not only pyroptosis, but also apoptosis.

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K63-Linked Ubiquitination Targets Toxoplasma gondii for Endo-lysosomal Destruction in IFNγ-Stimulated Human Cells

Clough

et al. 2016

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Toxoplasma gondii is the most common protozoan parasitic infection in man. Gamma interferon (IFNγ) activates haematopoietic and non-haematopoietic cells to kill the parasite and mediate host resistance. IFNγ-driven host resistance pathways and parasitic virulence factors are well described in mice, but a detailed understanding of pathways that kill Toxoplasma in human cells is lacking. Here we show, that contrary to the widely held belief that the Toxoplasma vacuole is non-fusogenic, in an immune-stimulated environment, the vacuole of type II Toxoplasma in human cells is able to fuse with the host endo-lysosomal machinery leading to parasite death by acidification. Similar to murine cells, we find that type II, but not type I Toxoplasma vacuoles are targeted by K63-linked ubiquitin in an IFNγ-dependent manner in non-haematopoetic primary-like human endothelial cells. Host defence proteins p62 and NDP52 are subsequently recruited to the type II vacuole in distinct, overlapping microdomains with a loss of IFNγ-dependent restriction in p62 knocked down cells. Autophagy proteins Atg16L1, GABARAP and LC3B are recruited to <10% of parasite vacuoles and show no parasite strain preference, which is consistent with inhibition and enhancement of autophagy showing no effect on parasite replication. We demonstrate that this differs from HeLa human epithelial cells, where type II Toxoplasma are restricted by non-canonical autophagy leading to growth stunting that is independent of lysosomal acidification. In contrast to mouse cells, human vacuoles do not break. In HUVEC, the ubiquitinated vacuoles are targeted for destruction in acidified LAMP1-positive endo-lysosomal compartments. Consequently, parasite death can be prevented by inhibiting host ubiquitination and endosomal acidification. Thus, K63-linked ubiquitin recognition leading to vacuolar endo-lysosomal fusion and acidification is an important, novel virulence-driven Toxoplasma human host defence pathway.

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Cell Death of Gamma Interferon-Stimulated Human Fibroblasts upon Toxoplasma gondii Infection Induces Early Parasite Egress and Limits Parasite Replication

et al. 2013

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dThe intracellular protozoan parasite Toxoplasma gondii is a major food-borne illness and opportunistic infection for the immunosuppressed. Resistance to Toxoplasma is dependent on gamma interferon (IFN-␥) activation of both hematopoietic and nonhematopoietic cells. Although IFN-␥-induced innate immunity in nonhematopoietic cells has been extensively studied in mice, it remains unclear what resistance mechanisms are relied on in nonhematopoietic human cells. Here, we report an IFN-␥-induced mechanism of resistance to Toxoplasma in primary human foreskin fibroblasts (HFFs) that does not depend on the deprivation of tryptophan or iron. In addition, infection is still controlled in HFFs deficient in the p65 guanylate binding proteins GBP1 or GBP2 and the autophagic protein ATG5. Resistance is coincident with host cell death that is not dependent on the necroptosis mediator RIPK3 or caspases and is correlated with early egress of the parasite before replication. This IFN-␥-induced cell death and early egress limits replication in HFFs and could promote clearance of the parasite by immune cells.

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A Subtilisin-like Protein in Secretory Organelles of Plasmodium falciparum Merozoites

Blackman¹,

Fujioka

Stafford³

et al. 1998

Journal of Biological Chemistry

119

101

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In the vertebrate host, the malaria parasite invades and replicates asexually within circulating erythrocytes. Parasite proteolytic enzymes play an essential but poorly understood role in erythrocyte invasion. We have identified a Plasmodium falciparum gene, denoted pfsub-1, encoding a member of the subtilisin-like serine protease family (subtilases). The pfsub-1 gene is expressed in asexual blood stages of P. falciparum, and the primary gene product (PfSUB-1) undergoes post-translational processing during secretory transport in a manner consistent with its being converted to a mature, enzymatically active form, as documented for other subtilases. In the invasive merozoite, the putative mature protease (p47) is concentrated in dense granules, which are secretory organelles located toward the apical end of the merozoite. At some point following merozoite release and completion of erythrocyte invasion, p47 is secreted from the parasite in a truncated, soluble form. The subcellular location and timing of secretion of p47 suggest that it is likely to play a role in erythrocyte invasion. PfSUB-1 is a new potential target for antimalarial drug development.Plasmodium falciparum, the causative agent of the most severe form of human malaria, is an obligate intracellular apicomplexan parasite. The life cycle of the organism includes a number of specialized invasive (zoite) stages. In the vertebrate host, replication of the parasite in circulating erythrocytes is initiated when the cells are invaded by merozoites. The parasite replicates asexually within the infected erythrocyte to produce a number of progeny merozoites. Upon rupture of the host cell, these are released to invade fresh erythrocytes and perpetuate the blood stage cycle. Erythrocyte invasion by the malaria merozoite has been the subject of intensive study, since intervention strategies that prevent invasion would effectively block both replication of the parasite and the associated clinical disease.Electron microscopic studies have shown that erythrocyte invasion by the malaria merozoite takes place in a number of discrete stages. Initial reversible attachment of the parasite to the red cell surface is rapidly followed by reorientation, the formation of an irreversible junction between the apical prominence of the merozoite and the host cell surface, and finally entry of the parasite into the cell by a mechanism resembling a form of induced endocytosis (1-4). The process is facilitated by the controlled release of the contents of three types of secretory organelles, called rhoptries, micronemes, and dense granules, situated at or toward the apical domain of the merozoite (2, 5, 6). There is extensive evidence indicating an essential role for parasite-derived proteases in invasion. Invasion by P. falciparum merozoites is blocked in the presence of the serine protease inhibitor phenylmethylsulfonyl fluoride (PMSF) 1 (7), and invasion by merozoites of a number of Plasmodium species is prevented by chymostatin (8 -13). The inhibitory effect of chymostatin on inv...

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Barbara Clough

Validation of N-myristoyltransferase as an antimalarial drug target using an integrated chemical biology approach

Human GBP 1 is a microbe‐specific gatekeeper of macrophage apoptosis and pyroptosis

K63-Linked Ubiquitination Targets Toxoplasma gondii for Endo-lysosomal Destruction in IFNγ-Stimulated Human Cells

Cell Death of Gamma Interferon-Stimulated Human Fibroblasts upon Toxoplasma gondii Infection Induces Early Parasite Egress and Limits Parasite Replication

A Subtilisin-like Protein in Secretory Organelles of Plasmodium falciparum Merozoites

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