Cell Mediated Immunity Against RSV and Influenza in a Human Experimental Challenge

Respiratory viruses including influenza and respiratory syncytial virus (RSV) are among the most important causes of severe disease globally, infecting everyone repeatedly throughout life. Understanding of how to prevent infection is incomplete but boosting immunity with vaccines remains the best strategy. T cells have been shown in animals to be essential for clearing respiratory viral infection and are likely to be helpful if stimulated by vaccines. However, where these cells originate from and how they develop in the human lung are still unclear. The investigators will inoculate volunteers with influenza or RSV to examine the relationship between T cells in their blood and lungs and the outcome of infection. By tracking these specialised cells, the investigators aim to develop a better understanding of how they are generated in order to harness them with future vaccines.

Influenza and Respiratory Syncytial Virus (RSV) are the two most common causes of severe viral respiratory tract infection. Seasonal influenza has an overall incidence of 10-20% per annum with frequent complications, and the annual mortality in the USA has been estimated at up to 9.9 deaths per 100,000. According to World Health Organization (WHO) estimates, RSV causes around 64 million infections per annum and 160,000 deaths. It is the leading cause of severe respiratory illness in young children (associated with severe infant wheezing illness) and is also a significant problem in susceptible adults (including the elderly and those with airways disease) in whom RSV is responsible for around 22% of winter respiratory illnesses with a case fatality rate of 2-8%. No vaccines or specific antivirals are available for RSV and those licensed for influenza remain suboptimal. Further understanding of the human immune response to these viruses particularly in the context of the respiratory tract is therefore essential. Experimental human infection studies have the advantage of studying these pathogens in their natural host with the capacity to sample different anatomical sites intensively. Thus the investigators aim to use these models in helping to test vaccines and therapeutics as well as providing critical information on immunity and pathogenesis. The investigators will use previously characterised Good Manufacturing Practices-certified RSV and influenza viruses derived from recent clinical isolates to investigate the response to infection in healthy adult volunteers. Subjects will be recruited via advertisement and screened at Imperial College London. Healthy individuals will be enrolled in the study and undergo baseline investigations including sampling from blood, upper and lower respiratory tract. They will then be inoculated with RSV or influenza by intranasal drops and quarantined for 10 days. During this time, they will have further blood and respiratory sampling. After the 10 day isolation period, they will be discharged and followed up for up to 6 months post-infection. These samples will undergo analysis for antibody, B and T cell responses to correlate with outcome of inoculation, which may include no infection, asymptomatic or symptomatic infection. Thus the investigators will infer the role of immune correlates in protection against infection or symptomatic disease.