Granulomatous response to Coxiella burnetii, the agent of Q fever: the lessons from gene expression analysis.

The formation of granulomas is associated with the resolution of Q fever, a zoonosis due to Coxiella burnetii; however the molecular mechanisms of granuloma formation remain poorly understood. We generated human granulomas with peripheral blood mononuclear cells (PBMCs) and beads coated with C. burnetii, using BCG extracts as controls. A microarray analysis showed dramatic changes in gene expression in granuloma cells of which more than 50% were commonly modulated genes in response to C. burnetii and BCG. They included M1-related genes and genes related to chemotaxis. The inhibition of the chemokines, CCL2 and CCL5, directly interfered with granuloma formation. C. burnetii granulomas also expressed a specific transcriptional profile that was essentially enriched in genes associated with type I interferon response. Our results showed that granuloma formation is associated with a core of transcriptional response based on inflammatory genes. The specific granulomatous response to C. burnetii is characterized by the activation of type 1 interferon pathway.

Defective monocyte dynamics in Q fever granuloma deficiency.

BACKGROUND: The outcome of Q fever, an infectious disease caused by Coxiella burnetii, is associated with granuloma formation. Granulomas are present in patients with resolutive Q fever but are lacking in patients with chronic Q fever. METHODS: Study of granuloma formation requires invasive approaches. Here, we took advantage of a recently described method that enables in vitro generation of human granulomas specific for C. burnetii. RESULTS: Circulating mononuclear cells progressively accumulated around beads coated with C. burnetii extracts, and complete granulomas were generated in 8 days. Granuloma cells consisted of macrophages, lymphocytes, and, to a lesser extent, epithelioid cells and multinucleated giant cells. Early events that govern granuloma formation were studied using live-imaging microscopy. Monocytes migrated toward C. burnetii-coated beads independently of the presence of T lymphocytes and then recruited T lymphocytes. About 90% of patients with chronic Q fever failed to form granulomas. This deficiency was associated with defective migration of monocytes toward coated beads. CONCLUSIONS: Monocytes were involved in the early stages of granuloma formation and recruited T lymphocytes to complete granuloma formation. This article describes a direct relationship between defective granuloma formation and defective migration of monocytes.

Coxiella burnetii, the agent of Q fever, replicates within trophoblasts and induces a unique transcriptional response.

Q fever is a zoonosis caused by Coxiella burnetii, an obligate intracellular bacterium typically found in myeloid cells. The infection is a source of severe obstetrical complications in humans and cattle and can undergo chronic evolution in a minority of pregnant women. Because C. burnetii is found in the placentas of aborted fetuses, we investigated the possibility that it could infect trophoblasts. Here, we show that C. burnetii infected and replicated in BeWo trophoblasts within phagolysosomes. Using pangenomic microarrays, we found that C. burnetii induced a specific transcriptomic program. This program was associated with the modulation of inflammatory responses that were shared with inflammatory agonists, such as TNF, and more specific responses involving genes related to pregnancy development, including EGR-1 and NDGR1. In addition, C. burnetii stimulated gene networks organized around the IL-6 and IL-13 pathways, which both modulate STAT3. Taken together, these results revealed that trophoblasts represent a protective niche for C. burnetii. The activation program induced by C. burnetii in trophoblasts may allow bacterial replication but seems unable to interfere with the development of normal pregnancy. Such pathophysiologocal processes should require the activation of immune placental cells associated with trophoblasts.

3D reconstruction of granulomas from transmitted light images implemented for long-time microscope applications.

Image analysis tools are essential to describe and quantify dynamic biological phenomena, such as early stages of granuloma formation. Granulomas are constituted of a collection of immune cells that contain pathogens, leading to their elimination. We presented here a new method to obtain granuloma 3D reconstruction from transmitted light images. Granulomas were generated by incubating peripheral blood mononuclear cells with beads coated with sonicated Coxiella burnetii, a bacterial pathogen. Biological samples were observed under a confocal microscope, and recorded during several hours, providing a large set of data of several gigabytes. Our image processing, called Focus Detection Plugin (FDP), allowed to extract relevant images from large datasets and to perform a deblurring of image stacks. This FDP method, that was implemented as an ImageJ plugin, did not require powerful computer resources and was simple to use. To validate our FDP method, we compared our results with 3D reconstruction of fluorescent images. Both methods yielded comparable results. We concluded that our FDP method was able to generate processed images yielding robust 3D reconstruction of whole cell bodies, and presented major advantages for long-time recordings since no cell labeling was needed. This method was convenient to study the early stages of granuloma formation and may be applied to other complex biological systems.

Var2CSA DBL6-epsilon domain expressed in HEK293 induces limited cross-reactive and blocking antibodies to CSA binding parasites.

BACKGROUND: Pregnancy-associated malaria (PAM) is a serious consequence of Plasmodium falciparum-infected erythrocytes sequestration in the placenta through the adhesion to the placental receptor chondroitin sulfate A (CSA). Although women become resistant to PAM as they acquire transcending inhibitory immunity against CSA-binding parasites, hundreds of thousands of lives could be saved if a prophylactic vaccine targeting the surface proteins of placental parasites could be designed. Recent works point to the variant protein var2CSA as the key target for the development of a pregnancy-associated malaria vaccine. However, designing such a prophylactic vaccine has been hindered by the difficulty in identifying regions of var2CSA that could elicit broadly neutralizing and adhesion-blocking antibodies. METHODS: Var2CSA is a very large protein with an estimated molecular weight of 350 kDa, and can be divided into six cysteine rich Duffy binding-like domains (DBL). The human embryonic kidney 293 cell line (HEK293) was used to produce secreted soluble recombinant forms of var2CSA DBL domains. The Escherichia coli expression system was also assessed for the domains not expressed or expressed in low amount in the HEK293 system. To investigate whether var2CSA binding DBL domains can induce biologically active antibodies recognizing the native var2CSA and blocking the interaction, mice were immunized with the refolded DBL3-X or the HEK293 secreted DBL6-epsilon domains. RESULTS: Using the HEK293 expression system, DBL1-X, DBL4-epsilon and DBL6-epsilon were produced at relatively high levels in the culture supernatant, while DBL3-X and DBL5-epsilon were produced at much lower levels. DBL2-X and DBL3-X domains were obtained after refolding of the inclusion bodies produced in E. coli. Importantly, mice antisera raised against the recombinant DBL6-epsilon domain, specifically reacted against the surface of CSA-binding parasites and revealed adhesion blocking activity. CONCLUSION: This is the first report showing inhibitory binding antibodies obtained through a var2CSA recombinant DBL domain immunization protocol. These results support the current strategies using var2CSA as immunogen in the aim of blocking placental sequestration of malaria parasites. This work is a step towards the development of a var2CSA based vaccine that will prevent pregnancy-associated malaria and improve pregnancy outcomes.

Natural killer cell and macrophage cooperation in MyD88-dependent innate responses to Plasmodium falciparum.

IFN-gamma secretion by natural killer (NK) cells is pivotal to several tumor and viral immune responses, during which NK and dendritic cells cooperation is required. We show here that macrophages are mandatory for NK cell IFN-gamma secretion in response to erythrocytes infected with Plasmodium falciparum (Pf), a causative agent of human malaria. In addition, direct sensing of Pf infection by NK cells induces their production of the proinflammatory chemokine CXCL8, without triggering their granule-mediated cytolytic programs. Despite their reported role in Pf recognition, Toll-like receptor (TLR) 2, TLR9, and TLR11 are individually dispensable for NK cell activation induced by Pf-infected erythrocytes. However, IL-18R expression on NK cells, IL-18 production by macrophages, and MyD88 on both cell types are essential components of this previously undescribed pathway of NK cell activation in response to a parasite infection.

Placenta cryosections for study of the adhesion of Plasmodium falciparum-infected erythrocytes to chondroitin sulfate A in flow conditions.

The adhesion of Plasmodium falciparum-infected erythrocytes (IEs) to chondroitin-4-sulfate (CSA) via the PfEMP1-CSA parasite ligand domain is correlated with placental malaria in primigravidae. The recent identification of parasite genes encoding CSA adhesion molecules and the development of pan-reactive monoclonal antibodies against the Pf(CSA) ligand have opened up new avenues for the development of anti-IE sequestration therapies for the prevention of placental malaria. A model closely mimicking placental sequestration of IEs during pregnancy is needed for the preclinical and clinical evaluation of candidate molecules for the induction of antibodies that could protect pregnant women from placental malaria. We found that normal placenta cryosections were a specific and highly consistent support for the binding of IEs to CSA in flow conditions under physiological conditions. This model makes possible the quantitative and qualitative analysis of IE adhesion. We identified distinct CSA-binding phenotypes within the FCR3(CSA)-selected parasites in flow analyses, but not in static analyses. We also analyzed inhibitors of placental parasite binding such as soluble CSA and antibodies directed against the Pf(CSA) ligand. Our data demonstrate that placenta cryosections could be used to standardize assays between laboratories, potentially advancing the development of therapies against placental malaria.

Platelets reorient Plasmodium falciparum-infected erythrocyte cytoadhesion to activated endothelial cells.

Severe malaria is characterized by the sequestration of Plasmodium falciparum-infected erythrocytes (IEs). Because platelets can affect tumor necrosis factor (TNF)-activated endothelial cells (ECs), we investigated their role in the sequestration of IEs, using IEs that were selected because they can adhere to endothelial CD36 (IE(CD36)), a P. falciparum receptor that is expressed on platelets. The results of coincubation studies indicated that platelets can induce IE(CD36) binding to CD36-deficient brain microvascular ECs. This induced cytoadhesion resisted physiological shear stress, was increased by EC stimulation with TNF, and was abolished by anti-CD36 monoclonal antibody. Immunofluorescence and scanning electron microscopy results showed that platelets serve as a bridge between IEs and the surface of ECs and may therefore provide receptors for adhesion to microvascular beds that otherwise lack adhesion receptors. This novel mechanism of cytoadhesion may reorient the sequestration of different parasite phenotypes and play an important role in the pathogenesis of severe malaria.