Selective susceptibility of human skin antigen presenting cells to productive dengue virus infection.

Daniela Cerny,Florent Ginhoux,Katja Fink,Michael Poidinger,Amanda Shin,Ern Yu Tan,Paul Bigliardi,Muzlifah Haniffa,Bernett Lee,Bien Keem Tan,Richard J Kuhn

doi:10.1371/journal.ppat.1004548

Abstract

Dengue is a growing global concern with 390 million people infected each year. Dengue virus (DENV) is transmitted by mosquitoes, thus host cells in the skin are the first point of contact with the virus. Human skin contains several populations of antigen-presenting cells which could drive the immune response to DENV in vivo: epidermal Langerhans cells (LCs), three populations of dermal dendritic cells (DCs), and macrophages. Using samples of normal human skin we detected productive infection of CD14+ and CD1c+ DCs, LCs and dermal macrophages, which was independent of DC-SIGN expression. LCs produced the highest viral titers and were less sensitive to IFN-β. Nanostring gene expression data showed significant up-regulation of IFN-β, STAT-1 and CCL5 upon viral exposure in susceptible DC populations. In mice infected intra-dermally with DENV we detected parallel populations of infected DCs originating from the dermis and migrating to the skin-draining lymph nodes. Therefore dermal DCs may simultaneously facilitate systemic spread of DENV and initiate the adaptive anti-viral immune response.

Highlights

Aedes mosquitoes are the primary vectors for the transmission of dengue virus (DENV)
Further analysis showed that only distinct subsets of dendritic cells (DCs) and macrophages were infected and efficiently produced viral progeny
Langerhans cells were most susceptible to infection despite lacking DC-SIGN, a previously described Dengue virus (DENV) receptor

Summary

Introduction

Aedes mosquitoes are the primary vectors for the transmission of dengue virus (DENV). Studies using mosquitoes infected with the closely-related West Nile virus showed that more than 99% of the viral particles could be recovered from around the feeding site on mice, indicating that most of the virus is not injected directly into the blood but rather pools in the local tissue [1]. How such viruses, including West Nile and DENV, spread to cause systemic infection is currently unknown. Mice in which LCs have been depleted still generate protective skin-specific T cell responses [6]

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