Langerhans cells are susceptible to measles virus infection and actively suppress T cell proliferation.

International audienceWe have previously reported that the measles virus (MV) could productively infect human dendritic cells (DC), derived in vitro from CD34+ cord blood progenitors in the presence of GM-CSF and TNF-alpha. In this study, we provide evidence that freshly isolated Langerhans cells (LC), which are immature dendritic cells located in skin and mucosal epithelia, are susceptible to MV infection in vitro as assessed by viral antigen expression by both LC syncytia and LC remaining as single cells. Moreover, MV-infected LC completely block naive allogeneic CD4+ T cell proliferation in response to uninfected LC. This active inhibitory effect is not due to virus transmission from infected LC, is independent of the maturation stage of LC at the time of infection and is antigen non-specific and MHC-unrestricted. Thus, both immature and mature LC are susceptible to measles virus infection, which turns these efficient antigen-presenting cells into active tolerogenic cells. LC infection may explain the long lasting immune suppression observed during natural measles infection.We have previously reported that the measles virus (MV) could productively infect human dendritic cells (DC), derived in vitro from CD34+ cord blood progenitors in the presence of GM-CSF and TNF-alpha. In this study, we provide evidence that freshly isolated Langerhans cells (LC), which are immature dendritic cells located in skin and mucosal epithelia, are susceptible to MV infection in vitro as assessed by viral antigen expression by both LC syncytia and LC remaining as single cells. Moreover, MV-infected LC completely block naive allogeneic CD4+ T cell proliferation in response to uninfected LC. This active inhibitory effect is not due to virus transmission from infected LC, is independent of the maturation stage of LC at the time of infection and is antigen non-specific and MHC-unrestricted. Thus, both immature and mature LC are susceptible to measles virus infection, which turns these efficient antigen-presenting cells into active tolerogenic cells. LC infection may explain the long lasting immune suppression observed during natural measles infection

Differentiation and immune function of human dendritic cells following infection by respiratory syncytial virus

RSV causes annual epidemics of bronchiolitis in winter months resulting in the hospitalization of many infants and the elderly. Dendritic cells (DCs) play a pivotal role in coordinating immune responses to infection and some viruses skew, or subvert, the immune functions of DCs. RSV infection of DCs could alter their function and this could explain why protection after natural RSV infection is incomplete and of short duration. In this study, this interaction between DCs and RSV was investigated using a human primary culture model. DCs were generated from purified healthy adult volunteer peripheral blood monocytes. Effects of RSV upon DC phenotype with RSV primed DCs was measured using flow cytometry. Changes to viability and proliferation of cocultured DCs and T-cells were determined using microscopy with fluorescent dyes (Hoechst 33342 and propidium iodide). DC maturation was not prevented by the RSV challenge. RSV infected a fraction of DCs (10–30%) but the virus replicated slowly in these cells with only small reduction to cell viability. DCs challenged with RSV stimulated T-cell proliferation less well than lipopolysaccharide. This is the first study to demonstrate RSV infection of human monocyte derived DCs and suggests that the virus does not significantly interfere with the function of these cells and potentially may promote cellular rather than humoral responses