Eduardo Leiva

Respiratory syncytial virus impairs T cell activation by preventing synapse assembly with dendritic cells

Respiratory syncytial virus (RSV) infection is one of the leading causes of infant hospitalization and a major health and economic burden worldwide. Infection with this virus induces an exacerbated innate proinflammatory immune response characterized by abundant immune cell infiltration into the airways and lung tissue damage. RSV also impairs the induction of an adequate adaptive T cell immune response, which favors virus pathogenesis. Unfortunately, to date there are no efficient vaccines against this virus. Recent in vitro and in vivo studies suggest that RSV infection can prevent T cell activation, a phenomenon attributed in part to cytokines and chemokines secreted by RSV-infected cells. Efficient immunity against viruses is promoted by dendritic cells (DCs), professional antigen-presenting cells, that prime antigen-specific helper and cytotoxic T cells. Therefore, it would be to the advantage of RSV to impair DC function and prevent the induction of T cell immunity. Here, we show that, although RSV infection induces maturation of murine DCs, these cells are rendered unable to activate antigen-specific T cells. Inhibition of T cell activation by RSV was observed independently of the type of TCR ligand on the DC surface and applied to cognate-, allo-, and superantigen stimulation. As a result of exposure to RSV-infected DCs, T cells became unresponsive to subsequent TCR engagement. RSV-mediated impairment in T cell activation required DC-T cell contact and involved inhibition of immunological synapse assembly among these cells. Our data suggest that impairment of immunological synapse could contribute to RSV pathogenesis by evading adaptive immunity and reducing T cell-mediated virus clearance.

Protective T cell immunity against respiratory syncytial virus is efficiently induced by recombinant BCG

Respiratory syncytial virus (RSV) is one of the leading causes of childhood hospitalization and a major health burden worldwide. Unfortunately, because of an inefficient immunological memory, RSV infection provides limited immune protection against reinfection. Furthermore, RSV can induce an inadequate Th2-type immune response that causes severe respiratory tract inflammation and obstruction. It is thought that effective RSV clearance requires the induction of balanced Th1-type immunity, involving the activation of IFN-γ-secreting cytotoxic T cells. A recognized inducer of Th1 immunity is Mycobacterium bovis bacillus Calmette–Guérin (BCG), which has been used in newborns for decades in several countries as a tuberculosis vaccine. Here, we show that immunization with recombinant BCG strains expressing RSV antigens promotes protective Th1-type immunity against RSV in mice. Activation of RSV-specific T cells producing IFN-γ and IL-2 was efficiently obtained after immunization with recombinant BCG. This type of T cell immunity was protective against RSV challenge and caused a significant reduction of inflammatory cell infiltration in the airways. Furthermore, mice immunized with recombinant BCG showed no weight loss and reduced lung viral loads. These data strongly support recombinant BCG as an efficient vaccine against RSV because of its capacity to promote protective Th1 immunity.

Modulation of nuclear factor‐κB activity can influence the susceptibility to systemic lupus erythematosus

Autoimmune diseases, such as systemic lupus erythematosus (SLE), result from deficiencies in self‐antigen tolerance processes, which require regulated dendritic cell (DC) function. In this study we evaluated the phenotype of DCs during the onset of SLE in a mouse model, in which deletion of the inhibitory receptor FcγRIIb leads to the production of anti‐nuclear antibodies and glomerulonephritis. Splenic DCs from FcγRIIb‐deficient mice suffering from SLE showed increased expression of co‐stimulatory molecules. Furthermore, diseased mice showed an altered function of the nuclear factor‐κB (NF‐κB) transcription factor, which is involved in DC maturation. Compared with healthy animals, expression of the inhibitory molecule IκB‐α was significantly decreased in mice suffering from SLE. Consistently, pharmacological inhibition of NF‐κB activity in FcγRIIb‐deficient mice led to reduced susceptibility to SLE and prevented symptoms, such as anti‐nuclear antibodies and kidney damage. Our data suggest that the occurrence of SLE is significantly influenced by alterations of NF‐κB function, which can be considered as a new therapeutic target for this disease.

Salmonella pathogenicity island 1 differentially modulates bacterial entry to dendritic and non-phagocytic cells

Salmonella enterica serovar Typhimurium can enter non‐phagocytic cells, such as intestinal epithelial cells, by virtue of a Type Three Secretion System (TTSS) encoded in the Salmonella Pathogenicity Island 1 (SPI‐1), which translocates bacterial effector molecules into the host cell. Salmonella can also be taken up by dendritic cells (DCs). Although the role of SPI‐1 in non‐phagocytic cell invasion is well established, its contribution to invasion of phagocytic cells has not been evaluated. Here, we have tested the invasive capacity of a S. Typhimurium strain lacking a key component of its TTSS‐1 (ΔInvC) leading to defective translocation of SPI‐1‐encoded effectors. Whereas this mutant Salmonella strain was impaired for invasion of non‐phagocytic cells, it was taken up by DCs at a significantly higher rate than wild‐type Salmonella. Similar to wild‐type Salmonella, the ΔInvC mutant strain retained the capacity to avoid antigen presentation to T cells. However, mice infected with the ΔInvC mutant strain showed higher survival rate and reduced organ colonization. Our data suggest that, besides promoting phagocytosis by non‐phagocytic cells, SPI‐1 modulates the number of bacteria that enters DCs. The SPI‐1 could be considered not only as an inducer of epithelial cell invasion but as a controller of DC entry.

Natural attenuation process via microbial oxidation of arsenic in a high Andean watershed

Rivers in northern Chile have arsenic (As) concentrations at levels that are toxic for humans and other organisms. Microorganism-mediated redox reactions have a crucial role in the As cycle; the microbial oxidation of As (As(III) to As(V)) is a critical transformation because it favors the immobilization of As in the solid phase. We studied the role of microbial As oxidation for controlling the mobility of As in the extreme environment found in the Chilean Altiplano (i.e., > 4000 meters above sea level (masl) and < 310 mm annual rainfall), which are conditions that have rarely been studied. Our model system was the upper Azufre River sub-basin, where the natural attenuation of As from hydrothermal discharge (pH 4-6) was observed. As(III) was actively oxidized by a microbial consortium, leading to a significant decrease in the dissolved As concentrations and a corresponding increase in the sediments As concentration downstream of the hydrothermal source. In-situ oxidation experiments demonstrated that the As oxidation required biological activity, and microbiological molecular analysis confirmed the presence of As(III)-oxidizing groups (aroA-like genes) in the system. In addition, the pH measurements and solid phase analysis strongly suggested that the As removal mechanism involved adsorption or coprecipitation with Fe-oxyhydroxides. Taken together, these results indicate that the microorganism-mediated As oxidation contributed to the attenuation of As concentrations and the stabilization of As in the solid phase, therefore controlling the amount of As transported downstream. This study is the first to demonstrate the microbial oxidation of As in Altiplano basins and its relevance in the immobilization of As.

Activating and inhibitory Fcγ receptors can differentially modulate T cell-mediated autoimmunity

The molecular bases responsible for the loss of T cell tolerance to myelin antigens leading to the onset of multiple sclerosis remain obscure. It has been shown that balanced signaling through activating and inhibitory receptors is critical for the maintenance of tolerance to self antigens in autoimmune disorders. However, although FcγR have been shown to influence experimental autoimmune encephalomyelitis (EAE) development, their role during pathogenesis remains controversial. Here we have evaluated whether relative expression of activating (FcγRIII) and inhibitory (FcγRIIb) FcγR can modulate myelin‐specific T cell response, as well as the susceptibility to develop EAE in mice. While FcγRIIb–/– mice showed a significant increase in EAE severity, an FcγRIII deficiency protected mice from disease. In addition, FcγRIIb–/– mice showed enhanced activation of myelin‐specific effector T cells, which were significantly more effective at causing EAE in adoptive transfer experiments than were T cells from wild‐type mice. In contrast, FcγRIII–/– mice showed a significantly reduced activation of myelin‐specific T cells and these cells failed to adoptively transfer EAE. Consistently, increased expansion of regulatory T cells (Treg) during EAE was observed only for FcγRIII–/– mice, which were able to suppress disease when adoptively transferred to recipient mice. These findings suggest that the balance between activating and inhibitory FcγR signaling can contribute to the maintenance of T cell tolerance to myelin antigens and modulate EAE progression.

Arsenic removal mediated by acidic pH neutralization and iron precipitation in microbial fuel cells

Abstract High concentrations of arsenic (As) in natural waters are a growing concern worldwide. In northern Chile, fluvial systems enriched in As from natural and anthropogenic sources have been found to contain microbial communities with exoelectrogenic activity. Previous work performed with Microbial Fuel Cells (MFCs) resulted in a neutralizing microbial community developed from a consortium extracted from northern Chile. Considering that the formation of iron minerals, which have been reported as good As sorbents, would be favored by pH neutralization, the use of neutralizing MFCs could result in a sustainable alternative for Fe and As removal. In this work, we quantified the removal of As and Fe from acidic waters in air-cathode single-chamber MFCs. Our results show a removal ~80% of As and Fe and, simultaneously, a pH neutralization from ~3.7 to ~7.2. Additionally, non-MFC experiments indicate that the removal of As and Fe is dependent only on the activity of the microbial community developed during MFC operation and not on the MFC electrochemical performance. In addition, scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDS) analysis showed spatial associations between Fe and As on the surface of cathodes, suggesting the idea that iron oxyhydroxides formation would be associated with the higher oxygen concentration near the cathodes. Powder X-ray diffraction (XRD) analysis showed the dominance of iron amorphous minerals, which may be favoring the removal of As. These results indicate that acid/metal-tolerant bacteria favor pH neutralization and consequently the removal of Fe and As by processes of surface sorption and/or As-Fe co-precipitation. Furthermore, these findings expand the possible MFC applications to the simultaneous removal of Fe and As from acidic waters, enabling its use as an energetically sustainable bioremediation alternative.