Multifunctional cytokine production reveals functional superiority of memory CD4 Tcells.

Lotus M Westerhof,Carl S Goodyear,Joshua I Gray,Kris McGuire,Lindsay MacLellan,Megan KL MacLeod,Ashley Flynn,Matthew Thomas

doi:10.1002/eji.201848026

Lotus M Westerhof, Carl S Goodyear + Show 6 more

Open Access

https://doi.org/10.1002/eji.201848026

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Abstract

T cell protective immunity is associated with multifunctional memory cells that produce several different cytokines. Currently, our understanding of when and how these cells are generated is limited. We have used an influenza virus mouse infection model to investigate whether the cytokine profile of memory T cells is reflective of primary responding cells or skewed toward a distinct profile. We found that, in comparison to primary cells, memory T cells tended to make multiple cytokines simultaneously. Analysis of the timings of release of cytokine by influenza virus‐specific T cells, demonstrated that primary responding CD4 T cells from lymphoid organs were unable to produce a sustained cytokine response. In contrast CD8 T cells, memory CD4 T cells, and primary responding CD4 T cells from the lung produced a sustained cytokine response throughout the restimulation period. Moreover, memory CD4 T cells were more resistant than primary responding CD4 T cells to inhibitors that suppress T cell receptor signaling. Together, these data suggest that memory CD4 T cells display superior cytokine responses compared to primary responding cells. These data are key to our ability to identify the cues that drive the generation of protective memory CD4 T cells following infection.

Highlights

Immunological memory provides superior immune protection from pathogens for two reasons
Memory cells in peripheral tissue are thought to be more differentiated than those in lymphoid organs and the bone marrow has been proposed as a site of memory T cell maintenance [24,25,26,27,28,29]
We examined the ex vivo cytokine responses of CD4 and CD8 T cells isolated from mice infected with influenza A virus (IAV) at the peak of the primary responses, day 9, and at two memory time points, days 30 and 75

Summary

Introduction

Immunological memory provides superior immune protection from pathogens for two reasons. Memory cells are intrinsically different from naıve cells: they are located in peripheral organs as well as in sec-. This tailored response is defined by the effector cytokines T cells express and is one of the main mechanisms of T cellmediated immune protection. The ability to track antigen-specific T cells via their cytokine profile is essential to understand their protective potential. This cytokine profile is shaped by pathogentriggered signals during the primary response [3]. These signals drive the effector cytokine production, such as IFN-γ, IL-4, or IL-17, most effective at coordinating pathogen control [2, 4]

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