Pathogen manipulation of B cells: the best defence is a good offence

International audienceB cells have long been regarded as simple antibody production units, but are now becoming known as key players in both adaptive and innate immune responses. However, several bacteria, viruses and parasites have evolved the ability to manipulate B cell functions to modulate immune responses. Pathogens can affect B cells indirectly, by attacking innate immune cells and altering the cytokine environment, and can also target B cells directly, impairing B cell-mediated immune responses. In this Review, we provide a summary of recent advances in elucidating direct B cell-pathogen interactions and highlight how targeting this specific cell population benefits different pathogens

Monitoring Shigella flexneri vacuolar escape by flow cytometry

International audienceInvasive bacterial pathogens such as Shigella flexneri force their uptake into non-phagocytic host cells. Upon internalization, they rupture the endocytic vacuole and escape into the host cell cytoplasm. Recent studies applying fluorescence resonance energy transfer (FRET) based methods to track host-pathogen interactions have provided insights into the process of bacterial infection at the single cell level. We have previously reported that the vacuolar escape of invasive bacteria into the host cellular cytosol can be tracked by fluorescence microscopy using a FRET CCF4/β-Lactamase reporter assay. Here, we show that our vacuolar rupture assay can also be analyzed by flow cytometry constituting an important alternative to data acquisition by microscopy. Whereas analysis of our assay by fluorescence microscopy offers precise spatiotemporal resolution, flow cytometry analysis represents a high-throughput method that allows efficient and fast quantification of a large number of events and can further improve future research on vacuolar escape

Expression of the Wnt Receptor Frizzled-4 in the Human Enteric Nervous System of Infants

The Wnt signalling pathway plays a crucial role in the development of the nervous system. This signalling cascade is initiated upon binding of the secreted Wnt ligand to a member of the family of frizzled receptors. In the present study, we analysed the presence of frizzled-4 in the enteric nervous system of human infants. Frizzled-4 could be identified by immunohistochemistry in a subpopulation of enteric neuronal and glial cells in the small and large intestine. Detection of frizzled-4 in the tunica muscularis by RT-PCR confirmed this receptor’s expression on the mRNA level. Interestingly, we observed distinct cell populations that co-expressed frizzled-4 with the intermediate filament protein nestin and the neurotrophin receptor p75NTR, which have been reported to be expressed in neural progenitor cells. Flow cytometry analysis revealed that 60% of p75NTR positive cells of the tunica muscularis were positive for frizzled-4. Additionally, in pathological samples of Hirschsprung’s disease, the expression of this Wnt receptor correlated with the number of myenteric ganglion cells and decreased from normoganglionic to aganglionic areas of large intestine. The expression pattern of frizzled-4 indicates that this Wnt receptor could be involved in postnatal development and/or function of the enteric nervous system

B lymphocytes undergo TLR2-dependent apoptosis upon Shigella infection mediated by the virulence factor IpaD

International audienceShigella is a gram-negative enteroinvasive bacterium and the causative agent of bacillary dysentery, an acute recto-colitis. Antibody-mediated natural immunity to Shigella requires several episodes of infection to get primed and is short-lasting, suggesting that the B cell response is functionally impaired. Here we show that upon ex vivo infection of human colonic tissue, invasive S. flexneri interacts with and invades B lymphocytes. We observe the induction of a type three secretion apparatus (T3SA)-dependent B cell death in vitro, both in lamina propria B lymphocytes and the human CL-01 B cell line. This cell death and the parallel reduction of the B cell pool can also be observed in an in vivo mouse infection model. Intriguingly, Shigella-induced B cell death does not require bacterial invasion or injection of virulence effectors via the T3SA in vitro. Instead, the virulence factor IpaD triggers mitochondrial B cell apoptosis in the presence of bacterial co-signals that render B lymphocytes prone to die. We provide evidence that IpaD binds to and induces apoptosis via TLR2, a signaling pathway that has thus far only been considered as a mitogenic stimulus for B lymphocytes. Apoptotic B lymphocytes in close contact with Shigella displaying IpaD are also detected in isolated lymphoid follicles of rectal biopsies of naturally-infected individuals. These findings reveal a novel mechanism of T3SA action to induce B cell death by the binding of a virulence factor and reveal an efficient strategy by which entero-invasive pathogens could impair the priming of a protective immune response

Wnt Receptor Frizzled-4 as a Marker for Isolation of Enteric Neural Progenitors in Human Children

Identification and isolation of neural progenitor cells from the human enteric nervous system (ENS) is currently hampered by the lack of reliable, specific markers. Here, we define the Wnt-receptor frizzled-4 as a marker for the isolation of enteric neural progenitor cells derived from paediatric gut samples. We show that the Wnt-receptor frizzled-4 is expressed in the human colon and in Tunica muscularis-derived enterospheres. To obtain a purified culture, we carried out fluorescence-activated cell sorting (FACS) using PE-conjugated frizzled-4 antibodies. Frizzled-4positive cells gave rise to neurosphere-like bodies and ultimately differentiated into neurons as revealed by BrdU-proliferation assays and immunocytochemistry, whereas in frizzled-4negative cultures we did not detect any neuronal and glial cells. By using a patch-clamp approach, we also demonstrated the expression of functional sodium and potassium channels in frizzled-4positive cell cultures after differentiation in vitro

Shigella impairs T lymphocyte dynamics in vivo

International audienceThe Gram-negative enteroinvasive bacterium Shigella flexneri is responsible for the endemic form of bacillary dysentery, an acute rectocolitis in humans. S. flexneri uses a type III secretion system to inject effector proteins into host cells, thus diverting cellular functions to its own benefit. Protective immunity to reinfection requires several rounds of infection to be elicited and is short-lasting, suggesting that S. flexneri interferes with the priming of specific immunity. Considering the key role played by T-lymphocyte trafficking in priming of adaptive immunity, we investigated the impact of S. flexneri on T-cell dynamics in vivo. By using two-photon microscopy to visualize bacterium-T-cell cross-talks in the lymph nodes, where the adaptive immunity is initiated, we provide evidence that S. flexneri, via its type III secretion system, impairs the migration pattern of CD4(+) T cells independently of cognate recognition of bacterial antigens. We show that bacterial invasion of CD4(+) T lymphocytes occurs in vivo, and results in cell migration arrest. In the absence of invasion, CD4(+) T-cell migration parameters are also dramatically altered. Signals resulting from S. flexneri interactions with subcapsular sinus macrophages and dendritic cells, and recruitment of polymorphonuclear cells are likely to contribute to this phenomenon. These findings indicate that S. flexneri targets T lymphocytes in vivo and highlight the role of type III effector secretion in modulating host adaptive immune responses

The Shigella flexneri Type Three Secretion System Effector IpgD Inhibits T Cell Migration by Manipulating Host Phosphoinositide Metabolism.

International audienceShigella, the Gram-negative enteroinvasive bacterium that causes shigellosis, relies on its type III secretion system (TTSS) and injected effectors to modulate host cell functions. However, consequences of the interaction between Shigella and lymphocytes have not been investigated. We show that Shigella invades activated human CD4(+) T lymphocytes. Invasion requires a functional TTSS and results in inhibition of chemokine-induced T cell migration, an effect mediated by the TTSS effector IpgD, a phosphoinositide 4-phosphatase. Remarkably, IpgD injection into bystander T cells can occur in the absence of cell invasion. Upon IpgD-mediated hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP(2)), the pool of PIP(2) at the plasma membrane is reduced, leading to dephosphorylation of the ERM proteins and their inability to relocalize at one T cell pole upon chemokine stimulus, likely affecting the formation of the polarized edge required for cell migration. These results reveal a bacterial TTSS effector-mediated strategy to impair T cell function

Bioimage analysis of Shigella infection reveals targeting of colonic crypts

International audienceFew studies within the pathogenic field have used advanced imaging and analytical tools to quantitatively measure pathogenicity in vivo. In this work, we present a novel approach for the investigation of host-pathogen processes based on medium-throughput 3D fluorescence imaging. The guinea pig model for Shigella flexneri invasion of the colonic mucosa was used to monitor the infectious process over time with GFP-expressing S. flexneri. A precise quantitative imaging protocol was devised to follow individual S. flexneri in a large tissue volume. An extensive dataset of confocal images was obtained and processed to extract specific quantitative information regarding the progression of S. flexneri infection in an unbiased and exhaustive manner. Specific parameters included the analysis of S. flexneri positions relative to the epithelial surface, S. flexneri density within the tissue, and volume of tissue destruction. In particular, at early time points, there was a clear association of S. flexneri with crypts, key morphological features of the colonic mucosa. Numerical simulations based on random bacterial entry confirmed the bias of experimentally measured S. flexneri for early crypt targeting. The application of a correlative light and electron microscopy technique adapted for thick tissue samples further confirmed the location of S. flexneri within colonocytes at the mouth of crypts. This quantitative imaging approach is a novel means to examine host-pathogen systems in a tailored and robust manner, inclusive of the infectious agent