Transmission of acute viral infections through blood transfusion during large epidemics is a serious public health issue, particularly for newly emerging infections for which no sensitive FDA-approved tests are available. Arboviruses can be serious acute infections leading to serious long-term complications, and are noted for their massive epidemic, as recently demonstrated with first chikungunya virus (CHIKV) and then Zika virus. Despite possessing many of the characteristics required for blood transfusion transmission (TT), such as high loads of infectious virus in blood and the ability to infect via intravenous inoculation, there have never been any CHIKV TT events reported. This is despite large-scale epidemics where up to 2% of blood donations have been found to be RNA reactive. We have preliminary data supporting the fact that CHIKV can be transfusion-transmitted in mice, and that transfusion of RBC attenuated CHIKV pathogenesis. The central hypothesis behind this study is that TT does occur, however a number of factors drive infection towards being asymptomatic or mild. Further, immune modulation during transmission, in this case via the blood transfusion itself, leads to an attenuation of disease. Specifically, we and others have demonstrated a number of innate immune factors are both modulated by transfusion and able to alter CHIKV outcomes. These include innate lymphoid cells and regulatory T cells and the cytokines both upstream and downstream of their stimulation. This study will use a murine model of CHIKV pathogenesis to investigate these findings further. Additionally, it will mimic blood transfusions, TT of CHIKV, and study immune parameters and disease outcomes. Beyond understanding the interplay between pathogenesis and blood transfusion, these studies will have a wider impact on acute viral infections in general. It is likely that similar immune factors can have dramatic effects on viral replication and/or pathogenesis, and thus a deeper understanding of how these mechanisms are mediated will allow better planning for screening efforts and potentially even interventions during serious epidemics. This will allow improved capabilities and decision making in responding rapidly to a new viral threat to blood safety and availability.
Large epidemics of emerging viruses pose a particular threat to the nation?s blood supply. It is well known that a blood transfusion can elicit dramatic responses from the recipient immune system; however, it is not known how those responses may alter resulting virus infection. The goal of this application is to determine how this immune response may modulate the balance of viral disease, allowing improved capabilities and decision making in responding rapidly to a new viral threat to blood safety and availability.