SUMMARY Ebola virus subtype Zaire (Ebo‐Z) induces acute haemorrhagic fever and a 60–80% mortality rate in humans. Inflammatory responses were monitored in victims and survivors of Ebo‐Z haemorrhagic fever during two recent outbreaks in Gabon. Survivors were characterized by a transient release in plasma of interleukin‐1β (IL‐1β), IL‐6, tumour necrosis factor‐α (TNFα), macrophage inflammatory protein‐1α (MIP‐1α) and MIP‐1β early in the disease, followed by circulation of IL‐1 receptor antagonist (IL‐1RA) and soluble receptors for TNFα (sTNF‐R) and IL‐6 (sIL‐6R) towards the end of the symptomatic phase and after recovery. Fatal infection was associated with moderate levels of TNFα and IL‐6, and high levels of IL‐10, IL‐1RA and sTNF‐R, in the days before death, while IL‐1β was not detected and MIP‐1α and MIP‐1β concentrations were similar to those of endemic controls. Simultaneous massive activation of monocytes/macrophages, the main target of Ebo‐Z, was suggested in fatal infection by elevated neopterin levels. Thus, presence of IL‐1β and of elevated concentrations of IL‐6 in plasma during the symptomatic phase can be used as markers of non‐fatal infection, while release of IL‐10 and of high levels of neopterin and IL‐1RA in plasma as soon as a few days after the disease onset is indicative of a fatal outcome. In conclusion, recovery from Ebo‐Z infection is associated with early and well‐regulated inflammatory responses, which may be crucial in controlling viral replication and inducing specific immunity. In contrast, defective inflammatory responses and massive monocyte/macrophage activation were associated with fatal outcome.
SUMMARYIn a recent study we identified certain asymptomatic individuals infected by Ebola virus (EBOV) who mounted specific IgG and early and strong inflammatory responses. Here, we further characterized the primary immune response to EBOV during the course of asymptomatic infection in humans. Inflammatory responses occurred in temporal association with anti-inflammatory phase composed by soluble antagonist IL-1RA, circulating TNF receptors, IL-10 and cortisol. At the end of the inflammatory process, mRNA expression of T-cell cytokines (IL-2 and IL-4) and activation markers (CD28, CD40L and CTLA4) was up-regulated, strongly suggesting T-cell activation. This T-cell activation was followed by EBOV-specific IgG responses (mainly IgG3 ang IgG1), and by marked and sustained up-regulation of IFNg, FasL and perforin mRNA expression, suggesting activation of cytotoxic cells. The terminal down-regulation of these latter markers coincided with the release of the apoptotic marker 41/7 NMP in blood and with the disappearance of viral RNA from PBMC, suggesting that infected cells are eliminated by cytotoxic mechanisms. Finally, RT-PCR analysis of TCR-Vb repertoire usage showed that TCR-Vb12 mRNA was never expressed during the infection. Taken together, these findings improve our understanding about immune response during human asymptomatic Ebola infection, and throw new light on protection against Ebola virus.
The recent demonstration that purified natural killer (NK) cells lyse Plasmodium falciparum-parasitized red blood cells (Pf-pRBCs) suggests that innate immunity is important in malaria. NK cell killing--presumably an early host response to infection--requires intimate contact between NK natural cytotoxicity receptors (NCRs) and ligands expressed on the surface of Pf-pRBCs. We investigated whether the Duffy binding-like (DBL)-1 alpha domain of P. falciparum erythrocyte membrane protein-1 (PfEMP-1) expressed on parasitized erythrocytes rendered Pf-pRBCs susceptible to NK cell lysis. We showed that with NKp30-immunoglobulin and NKp46-immunoglobulin fusion proteins and DBL-1alpha peptides NCRs are involved in the NK cell-Pf-pRBC interaction. This interaction was direct, specific, and functional, leading to perforin production and granzyme B release. The prior treatment of NK cells with DBL-1 alpha peptides abolished both this interaction and killing activity, suggesting that DBL-1 alpha -NCRs interaction is the key recognition mechanism leading to parasite killing by NK cells.
SummaryThe surface density of the triggering receptors (e.g. NKp46 and NKp30) responsible for natural killer (NK) cell-mediated cytotoxicity determines the ability of NK cells to kill susceptible target cells. In this study, we show that prolactin up-regulates and cortisol down-regulates the surface expression of NKp46 and NKp30. The prolactin-mediated activation and the cortisol-mediated inhibition of natural cytotoxicity receptor (NCR) surface expression reflects gene regulation at the transcriptional level. NKp46 and NKp30 are the major receptors involved in the NK-mediated killing of K562, a human chronic myelogenous leukaemia cell line. Accordingly, the prolactin dramatically increased the NK-mediated killing of the K562 cell line, whereas cortisol abolished this activity. Our data suggest a mechanism by which prolactin activates the lytic function of NK cells, and cortisol inhibits the NK-mediated attack.
We measured natural killer (NK) cell cytotoxicity and cortisol and prolactin concentrations in peripheral venous blood samples obtained from pregnant Gabonese women at the time of delivery. The NK cell-mediated cytotoxicity against Plasmodium falciparum-infected erythrocytes in vitro was lower in samples obtained from primiparous women than in samples obtained from multiparous women; cortisol concentrations were significantly higher in primiparous women than in multiparous women, and prolactin concentrations were significantly lower. The highest cortisol concentrations were found in the plasma of P. falciparum-infected primiparous women. A positive correlation was found between cortisol concentration and parasite load; an inverse correlation was found between the magnitude of the NK cell cytolytic effect and cortisol production. A positive correlation was found between this effect and prolactin production. Thus, depressed NK cell cytotoxicity against P. falciparum-infected erythrocytes is correlated with high cortisol concentrations and may contribute to increased susceptibility to malaria during pregnancy.
In 1913 Albert Schweitzer founded one of the first modern hospitals in Africa dedicated to the health of the local population. The Albert Schweitzer Hospital is located in Lambaréné, a small town in Gabon. In 1981 a research department--the Medical Research Unit--was established with the aim to perform research in the field of infectious diseases ( www.lambarene.org ). The main focus lies on clinical research on malaria and other parasitic diseases. Studies on the molecular biology and immunology of parasitic diseases are fostered since the inauguration of a novel building dedicated for basic science. A training program in clinical research in tropical diseases for African scientists has been set up recently.
Background: In areas where malaria is endemic, pregnancy is associated with increased susceptibility to malaria. It is generally agreed that this risk ends with delivery and decreases with the number of pregnancies. Our study aimed to demonstrate relationships between malarial parasitaemia and age, gravidity and anaemia in pregnant women in Libreville, the capital city of Gabon.
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