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Human immunity to Toxoplasma gondii

Innate immune response and Toxoplasma detection

Toxoplasma gondii (Tg) is an apicomplexan parasite able to invade any nucleated cell in warm-blooded animals. Approximately 30% of all humans harbour a chronic and asymptomatic infection [1]. Health risks include severe encephalitis in the immunocompromised, congenital defects, and ocular disease prevalent mostly in South America [2]. Felines are Tgs definitive host, and human infection occurs mostly through consumption of contaminated food or water [3]. Following ingestion, an initial site of infection develops in the tissue surrounding the intestines, causing inflammation. From there, Tg disseminates via the blood stream, establishing a chronic infection and entering immune-privileged sites, including the brain [4]. As humans are dead-end hosts, the interaction between host and parasite differs from that of rodents, and it is surprising how little is known about several levels of the human response to infection [5,6]. Hence, the use of mice as a model can only contribute partially to the study of the human response to Tg-infection. In this review, we explore data available on the human immune response to Tg-infection on a systemic level, in the response of individual cells, and to the complete control of infection. We also discuss Tg entering immune-privileged sites—causing disease in healthy individuals—and propose areas of interest for future research.

The innate immune system is the first to respond to infection with production of interleukin (IL)-12 by neutrophils, dendritic cells (DCs), and monocytes but not macrophages that have phagocytosed Tg [79]. Intracellular sensing differs from mice as humans do not have functional equivalents to murine toll-like receptors (TLRs)11 and 12 [10,11]. Monocytes sense Tg-infection through Alarmin S100A11 secreted from infected cells, which results in production of the chemokine (C-C motif) ligand 2 (CCL2) [12]. Additionally, cytosolic recognition of Tg in monocytes relies partly on the NLR family pyrin domain containing 1 (NLRP1) and NLRP3 inflammasome, leading to cell death at later time points and early secretion of IL-1β [13,14]. Interestingly, neutrophils and macrophages do not sense Tg-infection in the same way since they do not display pyroptosis or IL-1β secretion [14,15].

Based on in vivo mouse and human in vitro models, cytokine production in the inflamed tissue triggers interferon gamma (IFNγ)-production by T helper cell (Th)1 and natural killer (NK) cells, which leads to a robust adaptive Th1-immune response to control Tg-infection (see Fig 1) [16,17].

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Fig 1. Systemic and cellular human response to Toxoplasma infection.

Left: Systemic response to Tg-infection: Infected cells and cells that have phagocytosed Tg parasites at a site of infection sense the presence of the pathogen via the indicated PRRs and defence proteins and react by production of proinflammatory cytokines and chemokines like CCL2, IL-1β, and IL-12. This cytokine presence will trigger IFNγ–production by Th1 and NK cells. Right: Cellular response to Tg-infection: IFNγ and potentially other cytokines trigger infected cells to mount a cell-intrinsic defence against the PV. Mechanisms include ubiquitin-driven non-canonical autophagy of the entire PV and growth stunting; marking the PV with Ub, LAMP1, and the autophagy adapter proteins NDP52 and p62, followed by acidification of the vacuoles and killing of the parasite; recruitment of GBP1 to Tg vacuoles to disrupt them and expose the parasite within or growth restriction of Tg by GBP1 without translocation to the vacuole; and host cell death in response to opened PVs and leakage of pathogen-associated molecular patterns into the cytosol for detection by PRRs. The exact mechanisms highly depend on the cell type and the Tg strain infecting the cells. AIM, absent in melanoma 2; ASC, apoptosis-associated speck-like protein containing a CARD; CASP, caspase; CCL, chemokine (C-C motif) ligand; GBP, guanylate binding protein; IL, interleukin; IFNγ, interferon gamma; LAMP, lysosome-associated membrane protein; NDP52, nuclear domain 10 protein 52; NK, natural killer; NLRP, nucleotide-binding oligomerization domain, Leucine rich repeat and Pyrin domain containing; PAMP, pathogen-associated molecular patterns; PRR, pattern recognition receptor; PV, parasitophorous vacuole; Tg, Toxoplasma gondii; Th, T helper cell; TNFα, tumour necrosis factor α; Ub, Ubiquitin.

https://doi.org/10.1371/journal.ppat.1008097.g001

Cellular response to Toxoplasma infection

The human cellular response to Tg-infection is highly dependent on cell type [18] and the infecting strain of Tg [19]. Interestingly, although the principal cytokine controlling Tg-infection is IFNγ, other cytokines have been implicated. For example, brain microglial cells control Tg growth by production of tumour necrosis factor α (TNFα) and IL-6 [20]. TNFα is proposed to mediate Tg killing in patients with IFNγ receptor 1 (IFNGR1) deficiency, partially compensating for lack of IFNγ-responsiveness [21]. Furthermore, IFNγ-independent control of Tg has been reported via cluster of differentiation (CD)40-induced autophagy of parasitophorous vacuoles (PV) in human macrophages [22], with the caveat that Tg activates epidermal growth factor receptor (EGFR) to combat its own autophagic clearance [23]. It is likely that several different host response pathways act in concert to control Tg-infection. However, for the purposes of this review, we will focus on the role of IFNγ-induced defence mechanisms (see Fig 1).

We recently showed that the IFNγ dose-dependent restriction of Tg-infection depends on cell type, with epithelial cells displaying a sharp parasiticidal effect, in contrast to macrophages, fibroblasts, and endothelial cells demonstrating a dose-dependent response [24]. A common initial response is to mark PVs with ubiquitin [2426], but the ubiquitinated substrate(s) and the E3 ligases involved in this process remain to be defined. Following ubiquitination, epithelial cells control parasites through an incomplete autophagy, involving recruitment of autophagy adapter proteins p62 (SQSTM1) and NDP52 (CALCOCO2) and the autophagy-related protein 8 (Atg8) protein microtubule-associated protein-1A/1B light chain 3 (LC3B), but this fails to mature to autophago-lysosomes [25]. Endothelial cells follow this path up to the recruitment of adapter proteins, but then deviate from it, either by shuttling the marked PV into the endo-lysosomal pathway or directly acidifying the PVs [26]. Both cell types maintain the integrity of the PV and restrict the parasite within.

Conversely, macrophages are able to open Tg vacuoles, as we have recently demonstrated [27]. This induces an atypical apoptosis pathway relying on DNA-sensing by absent in melanoma 2 (AIM2) and execution of apoptosis via an apoptosis-associated speck-like protein containing a CARD (ASC)-caspase 8 (CASP8) signalling axis [29], whereas Tg is able to block apoptosis in other human cells [28]. This cell death phenotype is dependent on IFNγ-induced guanylate binding proteins (GBPs), of which GBP1 translocates to Tg vacuoles and releases Tg-derived molecular ligands of cellular receptors [27]. Similarly, GBP1 translocates to Tg vacuoles in mesenchymal stem cells [29] but not in epithelial cells [30]. In both cell types, the protein was able to restrict Tg independent of its recruitment [29,30]. Thus, recruited GBP1 seems to uniquely induce host cell death in macrophages. In contrast to death of macrophages, IFNγ-primed fibroblasts die through an uncharacterised form of cell death [31].

Similar to GBP1’s function in restricting Tg growth remotely from the PV, other cell-intrinsic mechanisms act on Tg from a distance: IFNγ-induced indoleamine-2,3-dioxygenase 1 (IDO) can deplete cells of tryptophan, which slows down growth of tryptophan-auxotrophic Tg [32]. This mechanism can be counteracted by the Tg effector protein inhibitor of STAT1 transcriptional activity (TgIST) [33] and has been shown to be dispensable in human umbilical vein endothelial cells (HUVECs) [34]. In general, the secreted Tg virulence factor TgIST is able to shut down many IFNγ-mediated responses to infection by blocking transcription of IFNγ-induced genes [35,36]. Furthermore, in contrast to mouse cells, nitric oxide was not relevant in restriction of Tg in HUVECs [34].

Parasites that escape within a few hours of entering the host cells may be an important unexplored consequence of IFNγ-dependent host restriction, as has been observed in human fibroblasts and endothelial cells [31]. This phenomenon is difficult to quantitate and may be larger than the 5%–10% reported. Whether the escaped Tg parasites are viable remains an open question.

Taken together, cell-intrinsic defence to Tg-infection not only differs largely between species but also between different cell types, and much work is needed to uncover new mechanisms.

Dissemination in the infected host and entering of immune-privileged sites

While the host responds to Tg-infection with cell death and cytokine production in the infected tissue, some parasites leave the site of primary infection and disseminate in the body [4]. Under pressure from the adaptive immune response, Tg converts to the bradyzoite stage and forms tissue cysts, surviving until death of the host [37]. Tg is believed to travel to immune-privileged sites of the brain and eye and also cross the placenta of an infected woman and infect the foetus congenitally [4]. In primary infections, this can result in abortion or foetal abnormalities such as hydrocephalus and retinochoroiditis [2,3].

Retinochoroiditis is the most common form of congenital toxoplasmosis, with the infection leading to an increase in HIF1α and vascular endothelial growth factor (VEGF) expression, resulting in increased vascularisation [38]. An increase in IL-1β, IL-6, granulocyte-macrophagecolony-stimulating factor (GM-CSF), and intercellular adhesion molecule (ICAM)-1 produced by retinal pigment epithelial cells was also described [39]. Intraocular fluid of Tg-infected eyes contain elevated levels of TGF-β [40,41], which may modulate the effects of IFNγ that inhibit Tg replication in human primary retinal pigment epithelial cells by tryptophan starvation [42]. Differences between French and Colombian clinical cases of ocular toxoplasmosis highlight the importance of understanding disease severity. Decreased intraocular IFNγ and IL-17, and higher IL-13 and IL-6 expression were detected in Colombian patients [43], suggesting the increased severity of ocular disease caused by South American strains could be attributed to an inhibition of protection afforded by IFNγ.

Concluding remarks and future studies

The immune response to Tg has been extensively studied in mice. Since mice are an intermediate host to Tg, many mechanisms are unique to this host–pathogen pair and cannot be extrapolated to the human host. Key areas of research for the future are as follows:

  1. IFNGR1-deficient patients possibly do not suffer from a higher incidence of Tg-borne disease. Is IFNγ the main cytokine responsible for Tg control in humans in all cell types?
  2. South American atypical Tg strains cause ocular toxoplasmosis, but other strains do not cause this disease. What makes these strains unique in being a disease-causing pathogen?
  3. Virulence of the clonal Tg strains was defined based on the mouse system and is not transferable to the human host. What are Tg virulence factors in humans and which strains are they derived from?
  4. Different human cell types show varying responses to Tg-infection. Why is there no unified defence strategy?
  5. Recruitment of host effectors to vacuole is only 30%–50% at any one time point. Which host defence mechanisms operate away from the vacuole?
  6. How many Tg tachyzoites escape acute phase control? What host response triggers parasites to escape the cell and are they still viable?

These and other open points will have to be addressed in future studies to uncover new mechanisms of the human response to Tg-infection.

Acknowledgments

We would like to thank Wei Lun Ng and Robert Evans for critical reading of the manuscript and the Frickel lab for productive discussions.

References

  1. 1. Pappas G, Roussos N, Falagas ME. Toxoplasmosis snapshots: Global status of Toxoplasma gondii seroprevalence and implications for pregnancy and congenital toxoplasmosis. Int J Parasitol. 2009 Oct 1;39[12]:1385–94. pmid:19433092
  2. 2. Xiao J, Yolken RH. Strain hypothesis of Toxoplasma gondii infection on the outcome of human diseases. Acta Physiol. 2015 Apr;213[4]:828–45.
  3. 3. Hill D, Dubey JP. Toxoplasma gondii: transmission, diagnosis and prevention. Clin Microbiol Infect. 2002 Oct 1;8[10]:634–40. pmid:12390281
  4. 4. Harker KS, Ueno N, Lodoen MB. Toxoplasma gondii dissemination: a parasite’s journey through the infected host. Parasite Immunol. 2015 Mar 1;37[3]:141–9. pmid:25408224
  5. 5. Gazzinelli RT, Mendonça-Neto R, Lilue J, Howard J, Sher A. Innate resistance against Toxoplasma gondii: An evolutionary tale of mice, cats, and men. Cell Host Microbe. 2014 Feb 12;15[2]:132–8. pmid:24528860
  6. 6. Haldar AK, Foltz C, Finethy R, Piro AS, Feeley EM, Pilla-Moffett DM, et al. Ubiquitin systems mark pathogen-containing vacuoles as targets for host defense by guanylate binding proteins. Proc Natl Acad Sci. 2015;112[41]:E5628–37. pmid:26417105
  7. 7. Bliss SK, Marshall AJ, Zhang Y, Denkers EY. Human Polymorphonuclear Leukocytes Produce IL-12, TNF-α, and the chemokines macrophage-inflammatory protein-1α and -1β in response to Toxoplasma gondii antigens. J Immunol. 1999 Jun 15;162[12]:7369–7375. pmid:10358188
  8. 8. Aldebert D, Durand F, Mercier C, Brenier-Pinchart M-P, Cesbron-Delauw M-F, Pelloux H. Toxoplasma gondii triggers secretion of interleukin-12 but low level of interleukin-10 from the THP-1 human monocytic cell line. Cytokine. 2007;37[3]:206–11. pmid:17512211
  9. 9. Tosh KW, Mittereder L, Bonne-Annee S, Hieny S, Nutman TB, Singer SM, et al. The IL-12 response of primary human dendritic cells and monocytes to Toxoplasma gondii is stimulated by phagocytosis of live parasites rather than host cell invasion. J Immunol. 2016 Jan 1;196[1]:345–56. pmid:26597011
  10. 10. Yarovinsky F, Zhang D, Andersen JF, Bannenberg GL, Serhan CN, Hayden MS, et al. TLR11 activation of dendritic cells by a protozoan profilin-like protein. Science. 2005 Jun 10;308[5728]:1626–1629. pmid:15860593
  11. 11. Koblansky AA, Jankovic D, Oh H, Hieny S, Sungnak W, Mathur R, et al. Recognition of profilin by Toll-like receptor 12 is critical for host resistance to Toxoplasma gondii. Immunity. 2013 Jan 24;38[1]:119–30. pmid:23246311
  12. 12. Safronova A, Araujo A, Camanzo ET, Moon TJ, Elliott MR, Beiting DP, et al. Alarmin S100A11 initiates a chemokine response to the human pathogen Toxoplasma gondii. Nat Immunol. 2019 Jan;20[1]:64–72. pmid:30455460
  13. 13. Witola WH, Mui E, Hargrave A, Liu S, Hypolite M, Montpetit A, et al. NALP1 influences susceptibility to human congenital toxoplasmosis, proinflammatory cytokine response, and fate of Toxoplasma gondii-infected monocytic cells. Infect Immun. 2011 Feb;79[2]:756–66. pmid:21098108
  14. 14. Gov L, Schneider CA, Lima TS, Pandori W, Lodoen MB. NLRP3 and potassium efflux drive rapid IL-1β release from primary human monocytes during Toxoplasma gondii infection. J Immunol. 2017;199[8]:2855–64. pmid:28904126
  15. 15. Lima TS, Gov L, Lodoen MB. Evasion of human neutrophil-mediated host defense during Toxoplasma gondii infection. MBio. 2018 Feb 13;9[1]:e02027–17. pmid:29440572
  16. 16. Suzuki Y, Orellana MA, Schreiber RD, Remington JS. Interferon-gamma: the major mediator of resistance against Toxoplasma gondii. Science. 1988 Apr 22;240[4851]:516–518. pmid:3128869
  17. 17. Däubener W, Mackenzie C, Hadding U. Establishment of T-helper type 1- and T-helper type 2-like human Toxoplasma antigen-specific T-cell clones. Immunology. 1995 Sep;86[1]:79–84. pmid:7590886
  18. 18. Saeij JP, Frickel E-M. Exposing Toxoplasma gondii hiding inside the vacuole: a role for GBPs, autophagy and host cell death. Curr Opin Microbiol. 2017;40:72–80. pmid:29141239
  19. 19. Saeij JPJ, Boyle JP, Boothroyd JC. Differences among the three major strains of Toxoplasma gondii and their specific interactions with the infected host. Trends Parasitol. 2005 Oct 1;21[10]:476–81. pmid:16098810
  20. 20. Chao CC, Gekker G, Hu S, Peterson PK. Human microglial cell defense against Toxoplasma gondii. The role of cytokines. J Immunol. 1994 Feb 1;152[3]:1246–1252. pmid:8301129
  21. 21. Janssen R, van Wengen A, Verhard E, de Boer T, Zomerdijk T, Ottenhoff THM, et al. Divergent role for TNF-α in IFN-γ-induced killing of Toxoplasma gondii and Salmonella typhimurium contributes to selective susceptibility of patients with partial IFN-γ receptor 1 deficiency. J Immunol. 2002 Oct 1;169[7]:3900–3907. pmid:12244188
  22. 22. Andrade RM, Wessendarp M, Gubbels M-J, Striepen B, Subauste CS. CD40 induces macrophage anti–Toxoplasma gondii activity by triggering autophagy-dependent fusion of pathogen-containing vacuoles and lysosomes. J Clin Invest. 2006 Sep 1;116[9]:2366–77. pmid:16955139
  23. 23. Muniz-Feliciano L, Van Grol J, Portillo J-AC, Liew L, Liu B, Carlin CR, et al. Toxoplasma gondii-induced activation of EGFR prevents autophagy protein-mediated killing of the parasite. PLoS Pathog. 2013 Dec 19;9[12]:e1003809–e1003809. pmid:24367261
  24. 24. Fisch D, Yakimovich A, Clough B, Wright J, Bunyan M, Howell M, et al. Defining host–pathogen interactions employing an artificial intelligence workflow. Elife. 2019 Feb 12;8 e40560. pmid:30744806
  25. 25. Selleck EM, Orchard RC, Lassen KG, Beatty WL, Xavier RJ, Levine B, et al. A noncanonical autophagy pathway restricts Toxoplasma gondii growth in a strain-specific manner in IFN-γ-activated human cells. MBio. 2015 Sep 8;6[5]:e01157–15. pmid:26350966
  26. 26. Clough B, Wright JD, Pereira PM, Hirst EM, Johnston AC, Henriques R, et al. K63-linked ubiquitination targets Toxoplasma gondii for endo-lysosomal destruction in IFNγ-stimulated human cells. PLoS Pathog. 2016;12[11]:e1006027. pmid:27875583
  27. 27. Fisch D, Bando H, Clough B, Hornung V, Yamamoto M, Shenoy AR, et al. Human GBP1 is a microbe‐specific gatekeeper of macrophage apoptosis and pyroptosis. EMBO J. 2019 May 31;e100926. pmid:31268602
  28. 28. Besteiro S. Toxoplasma control of host apoptosis: the art of not biting too hard the hand that feeds you. Microb cell. 2015 May 30;2[6]:178–81. pmid:28362004
  29. 29. Qin A, Lai D-H, Liu Q, Huang W, Wu Y-P, Chen X, et al. Guanylate-binding protein 1 [GBP1] contributes to the immunity of human mesenchymal stromal cells against Toxoplasma gondii. Proc Natl Acad Sci. 2017 114[6]:1365–1370. pmid:28123064
  30. 30. Johnston AC, Piro A, Clough B, Siew M, Virreira Winter S, Coers J, et al. Human GBP1 does not localize to pathogen vacuoles but restricts Toxoplasma gondii. Cell Microbiol. 2016 Aug;18[8]:1056–64. pmid:26874079
  31. 31. Niedelman W, Sprokholt JK, Clough B, Frickel E-M, Saeij JPJ. Cell death of gamma interferon-stimulated human fibroblasts upon Toxoplasma gondii infection induces early parasite egress and limits parasite replication. Infect Immun. 2013 Dec;81[12]:4341–9. pmid:24042117
  32. 32. Pfefferkorn ER. Interferon gamma blocks the growth of Toxoplasma gondii in human fibroblasts by inducing the host cells to degrade tryptophan. Proc Natl Acad Sci. 1984 Feb;81[3]:908–12. pmid:6422465
  33. 33. Bando H, Sakaguchi N, Lee Y, Pradipta A, Ma JS, Tanaka S, et al. Toxoplasma effector TgIST targets host IDO1 to antagonize the IFN-γ-induced anti-parasitic response in human cells. Vol. 9, Frontiers in Immunology. 2018. p. 2073. pmid:30283439
  34. 34. Woodman JP, Dimier IH, Bout DT. Human endothelial cells are activated by IFN-gamma to inhibit Toxoplasma gondii replication. Inhibition is due to a different mechanism from that existing in mouse macrophages and human fibroblasts. J Immunol. 1991 Sep 15;147[6]:2019–2023. pmid:1909738
  35. 35. Olias P, Etheridge RD, Zhang Y, Holtzman MJ, Sibley LD. Toxoplasma effector recruits the Mi-2/NuRD complex to repress STAT1 transcription and block IFN- γ -dependent gene expression. Cell Host Microbe. 2016;20[1]:72–82. pmid:27414498
  36. 36. Gay G, Braun L, Brenier-Pinchart M-P, Vollaire J, Josserand V, Bertini R-L, et al. Toxoplasma gondii TgIST co-opts host chromatin repressors dampening STAT1-dependent gene regulation and IFN-γ-mediated host defenses. J Exp Med. 2016;213[9]:1779–98. pmid:27503074
  37. 37. Dzierszinski F, Nishi M, Ouko L, Roos DS. Dynamics of Toxoplasma gondii differentiation. Eukaryot Cell. 2004 Aug 1;3[4]:992–1003. pmid:15302832
  38. 38. Spear W, Chan D, Coppens I, Johnson RS, Giaccia A, Blader IJ. The host cell transcription factor hypoxia-inducible factor 1 is required for Toxoplasma gondii growth and survival at physiological oxygen levels. Cell Microbiol. 2006 Feb 1;8[2]:339–52. pmid:16441443
  39. 39. Nagineni CN, Detrick B, Hooks JJ. Toxoplasma gondii infection induces gene expression and secretion of interleukin 1 [IL-1], IL-6, granulocyte-macrophage colony-stimulating factor, and intercellular adhesion molecule 1 by human retinal pigment epithelial cells. Infect Immun. 2000 Jan;68[1]:407–10. pmid:10603418
  40. 40. Streilein JW, Wilbanks GA, Cousins SW. Immunoregulatory mechanisms of the eye. J Neuroimmunol. 1992 Aug 1;39[3]:185–200. pmid:1644895
  41. 41. Nagineni CN, Detrick B, Hooks JJ. Transforming growth factor-beta expression in human retinal pigment epithelial cells is enhanced by Toxoplasma gondii: a possible role in the immunopathogenesis of retinochoroiditis. Clin Exp Immunol. 2002 May;128[2]:372–8. pmid:11985530
  42. 42. Nagineni CN, Pardhasaradhi K, Martins MC, Detrick B, Hooks JJ. Mechanisms of interferon-induced inhibition of Toxoplasma gondii replication in human retinal pigment epithelial cells. Infect Immun. 1996 Oct;64[10]:4188–96. pmid:8926087
  43. 43. de-la-Torre A, Sauer A, Pfaff AW, Bourcier T, Brunet J, Speeg-Schatz C, et al. Severe South American ocular Toxoplasmosis is associated with decreased IFN-γ/IL-17 α and increased Il-6/Il-13 intraocular levels. PLoS Negl Trop Dis. 2013 Nov 21;7[11]:e2541. pmid:24278490