Kevin N. Couper

IL-10: The Master Regulator of Immunity to Infection

IL-10 is an anti-inflammatory cytokine. During infection it inhibits the activity of Th1 cells, NK cells, and macrophages, all of which are required for optimal pathogen clearance but also contribute to tissue damage. In consequence, IL-10 can both impede pathogen clearance and ameliorate immunopathology. Many different types of cells can produce IL-10, with the major source of IL-10 varying in different tissues or during acute or chronic stages of the same infection. The priming of these various IL-10-producing populations during infections is not well understood and it is not clear whether the cellular source of IL-10 during infection dictates its cellular target and thus its outcome. In this article we review the biology of IL-10, its cellular sources, and its role in viral, bacterial, and protozoal infections.

IL-10 from CD4(+)CD25(-)Foxp3(-)CD127(-) adaptive regulatory T cells modulates parasite clearance and pathology during malaria infection

The outcome of malaria infection is determined, in part, by the balance of pro-inflammatory and regulatory immune responses. Failure to develop an effective pro-inflammatory response can lead to unrestricted parasite replication, whilst failure to regulate this response leads to the development of severe immunopathology. IL-10 and TGF-β are known to be important components of the regulatory response, but the cellular source of these cytokines is still unknown. Here we have examined the role of natural and adaptive regulatory T cells in the control of malaria infection and find that classical CD4+CD25hi (and Foxp3+) regulatory T cells do not significantly influence the outcome of infections with the lethal (17XL) strain of Plasmodium yoelii (PyL). In contrast, we find that adaptive IL-10-producing, CD4+ T cells (which are CD25−, Foxp3−, and CD127− and do not produce Th1, Th2, or Th17 associated cytokines) that are generated during both PyL and non-lethal P. yoelii 17X (PyNL) infections are able to down-regulate pro-inflammatory responses and impede parasite clearance. In summary, we have identified a population of induced Foxp3− regulatory (Tr1) T cells, characterised by production of IL-10 and down regulation of IL-7Rα, that modulates the inflammatory response to malaria.

Cerebral malaria: why experimental murine models are required to understand the pathogenesis of disease.

Cerebral malaria is a life-threatening complication of malaria infection. The pathogenesis of cerebral malaria is poorly defined and progress in understanding the condition is severely hampered by the inability to study in detail, ante-mortem, the parasitological and immunological events within the brain that lead to the onset of clinical symptoms. Experimental murine models have been used to investigate the sequence of events that lead to cerebral malaria, but there is significant debate on the merits of these models and whether their study is relevant to human disease. Here we review the current understanding of the parasitological and immunological events leading to human and experimental cerebral malaria, and explain why we believe that studies with experimental models of CM are crucial to define the pathogenesis of the condition.

Incomplete depletion and rapid regeneration of Foxp3+ regulatory T cells following anti-CD25 treatment in malaria-infected mice.

Investigation of the role of regulatory T cells (Treg) in model systems is facilitated by their depletion using anti-CD25 Abs, but there has been considerable debate about the effectiveness of this strategy. In this study, we have compared the depletion and repopulation of CD4+CD25+Foxp3+ Treg in uninfected and malaria-infected mice using 7D4 and/or PC61 anti-CD25 Abs. We find that numbers and percentages of CD25high cells, but not Foxp3+ cells, are transiently reduced after 7D4 treatment, whereas treatment with PC61 alone or in combination with 7D4 (7D4 plus PC61) reduces but does not eliminate Foxp3+ cells for up to 2 wk. Importantly, all protocols fail to eliminate significant populations of CD25−Foxp3+ or CD25lowFoxp3+ cells, which retain potent regulatory capacity. By adoptive transfer we show that repopulation of the spleen by CD25highFoxp3+ cells results from the re-expression of CD25 on peripheral populations of CD25−Foxp3+ but not from the conversion of peripheral Foxp3− cells. CD25highFoxp3+ repopulation occurs more rapidly in 7D4-treated mice than in 7D4 plus PC61-treated mice, reflecting ongoing clearance of emergent CD25+Foxp3+ cells by persistent PC61 Ab. However, in 7D4 plus PC61-treated mice undergoing acute malaria infection, repopulation of the spleen by CD25+Foxp3+ cells occurs extremely rapidly, with malaria infection driving proliferation and CD25 expression in peripheral CD4+CD25−Foxp3+ cells and/or conversion of CD4+CD25−Foxp3− cells. Finally, we reveal an essential role for IL-2 for the re-expression of CD25 by Foxp3+ cells after anti-CD25 treatment and observe that TGF-β is required, in the absence of CD25 and IL-2, to maintain splenic Foxp3+ cell numbers and a normal ratio of Treg:non-Treg cells.

Parasite-Derived Plasma Microparticles Contribute Significantly to Malaria Infection-Induced Inflammation through Potent Macrophage Stimulation

There is considerable debate as to the nature of the primary parasite-derived moieties that activate innate pro-inflammatory responses during malaria infection. Microparticles (MPs), which are produced by numerous cell types following vesiculation of the cellular membrane as a consequence of cell death or immune-activation, exert strong pro-inflammatory activity in other disease states. Here we demonstrate that MPs, derived from the plasma of malaria infected mice, but not naive mice, induce potent activation of macrophages in vitro as measured by CD40 up-regulation and TNF production. In vitro, these MPs induced significantly higher levels of macrophage activation than intact infected red blood cells. Immunofluorescence staining revealed that MPs contained significant amounts of parasite material indicating that they are derived primarily from infected red blood cells rather than platelets or endothelial cells. MP driven macrophage activation was completely abolished in the absence of MyD88 and TLR-4 signalling. Similar levels of immunogenic MPs were produced in WT and in TNF−/−, IFN-γ−/−, IL-12−/− and RAG-1−/− malaria-infected mice, but were not produced in mice injected with LPS, showing that inflammation is not required for the production of MPs during malaria infection. This study therefore establishes parasitized red blood cell-derived MPs as a major inducer of systemic inflammation during malaria infection, raising important questions about their role in severe disease and in the generation of adaptive immune responses.

IFN-γ–Producing CD4+ T Cells Promote Experimental Cerebral Malaria by Modulating CD8+ T Cell Accumulation within the Brain

It is well established that IFN-γ is required for the development of experimental cerebral malaria (ECM) during Plasmodium berghei ANKA infection of C57BL/6 mice. However, the temporal and tissue-specific cellular sources of IFN-γ during P. berghei ANKA infection have not been investigated, and it is not known whether IFN-γ production by a single cell type in isolation can induce cerebral pathology. In this study, using IFN-γ reporter mice, we show that NK cells dominate the IFN-γ response during the early stages of infection in the brain, but not in the spleen, before being replaced by CD4+ and CD8+ T cells. Importantly, we demonstrate that IFN-γ–producing CD4+ T cells, but not innate or CD8+ T cells, can promote the development of ECM in normally resistant IFN-γ−/− mice infected with P. berghei ANKA. Adoptively transferred wild-type CD4+ T cells accumulate within the spleen, lung, and brain of IFN-γ−/− mice and induce ECM through active IFN-γ secretion, which increases the accumulation of endogenous IFN-γ−/− CD8+ T cells within the brain. Depletion of endogenous IFN-γ−/− CD8+ T cells abrogates the ability of wild-type CD4+ T cells to promote ECM. Finally, we show that IFN-γ production, specifically by CD4+ T cells, is sufficient to induce expression of CXCL9 and CXCL10 within the brain, providing a mechanistic basis for the enhanced CD8+ T cell accumulation. To our knowledge, these observations demonstrate, for the first time, the importance of and pathways by which IFN-γ–producing CD4+ T cells promote the development of ECM during P. berghei ANKA infection.

Essential Role for IL-27 Receptor Signaling in Prevention of Th1-Mediated Immunopathology during Malaria Infection

Successful resolution of malaria infection requires induction of proinflammatory immune responses that facilitate parasite clearance; however, failure to regulate this inflammation leads to immune-mediated pathology. The pathways that maintain this immunological balance during malaria infection remain poorly defined. In this study, we demonstrate that IL-27R–deficient (WSX-1−/−) mice are highly susceptible to Plasmodium berghei NK65 infection, developing exacerbated Th1-mediated immune responses, which, despite highly efficient parasite clearance, lead directly to severe liver pathology. Depletion of CD4+ T cells—but not CD8+ T cells—prevented liver pathology in infected WSX-1−/− mice. Although WSX-1 signaling was required for optimal IL-10 production by CD4+ T cells, administration of rIL-10 failed to ameliorate liver damage in WSX-1−/− mice, indicating that additional, IL-10–independent, protective pathways are modulated by IL-27R signaling during malaria infection. These data are the first to demonstrate the essential role of IL-27R signaling in regulating effector T cell function during malaria infection and reveal a novel pathway that might be amenable to manipulation by drugs or vaccines.

Macrophage-Mediated but Gamma Interferon-Independent Innate Immune Responses Control the Primary Wave of Plasmodium yoelii Parasitemia

ABSTRACT In most models of blood-stage malaria infection, proinflammatory immune responses are required for control of infection and elimination of parasites. We hypothesized therefore that the fulminant infections caused in mice by the lethal strain of Plasmodium yoelii (17XL) might be due to failure to activate a sufficient inflammatory response. Here we have compared the adaptive CD4+ T-cell and innate immune response to P. yoelii 17XL with that induced by the self-resolving, nonlethal strain of P. yoelii, 17X(NL). During the first 7 to 9 days of infection, splenic effector CD4+ T-cell responses were similar in mice with lethal and nonlethal infections with similar levels of activation in vivo and equivalent proliferation in vitro following mitogenic stimulation. Nonspecific T-cell hyporesponsiveness was observed at similar levels during both infections and was due, in part, to suppression mediated by CD11b+ cells. Importantly, however, RAG−/− mice were able to control the initial growth phase of nonlethal P. yoelii infection as effectively as wild-type mice, indicating that T cells and/or B cells play little, if any, role in control of the primary peak of parasitemia. Somewhat unexpectedly, we could find no clear role for either NK cells or gamma interferon (IFN-γ) in controlling primary P. yoelii infection. In contrast, depletion of monocytes/macrophages exacerbated parasite growth and anemia during both lethal and nonlethal acute P. yoelii infections, indicating that there is an IFN-γ-, NK cell-, and T-cell-independent pathway for induction of effector macrophages during acute malaria infection.

The CTLA-4 and PD-1/PD-L1 Inhibitory Pathways Independently Regulate Host Resistance to Plasmodium-induced Acute Immune Pathology.

The balance between pro-inflammatory and regulatory immune responses in determining optimal T cell activation is vital for the successful resolution of microbial infections. This balance is maintained in part by the negative regulators of T cell activation, CTLA-4 and PD-1/PD-L, which dampen effector responses during chronic infections. However, their role in acute infections, such as malaria, remains less clear. In this study, we determined the contribution of CTLA-4 and PD-1/PD-L to the regulation of T cell responses during Plasmodium berghei ANKA (PbA)-induced experimental cerebral malaria (ECM) in susceptible (C57BL/6) and resistant (BALB/c) mice. We found that the expression of CTLA-4 and PD-1 on T cells correlates with the extent of pro-inflammatory responses induced during PbA infection, being higher in C57BL/6 than in BALB/c mice. Thus, ECM develops despite high levels of expression of these inhibitory receptors. However, antibody-mediated blockade of either the CTLA-4 or PD-1/PD-L1, but not the PD-1/PD-L2, pathways during PbA-infection in ECM-resistant BALB/c mice resulted in higher levels of T cell activation, enhanced IFN-γ production, increased intravascular arrest of both parasitised erythrocytes and CD8+ T cells to the brain, and augmented incidence of ECM. Thus, in ECM-resistant BALB/c mice, CTLA-4 and PD-1/PD-L1 represent essential, independent and non-redundant pathways for maintaining T cell homeostasis during a virulent malaria infection. Moreover, neutralisation of IFN-γ or depletion of CD8+ T cells during PbA infection was shown to reverse the pathologic effects of regulatory pathway blockade, highlighting that the aetiology of ECM in the BALB/c mice is similar to that in C57BL/6 mice. In summary, our results underscore the differential and complex regulation that governs immune responses to malaria parasites.

Neuropathogenesis of human and murine malaria

White et al.[1] make some important points cautioning the extrapolation of findings from animal models to human cerebral malaria (CM). However, in doing so they overlook a substantial body of research that offers a rather different interpretation of the literature than the one they put forward. There is a danger that their article may create an unnecessary and potentially detrimental divide between clinicians and basic biomedical researchers.