Abstract
The role of IL-22-producing CD4(+) T cells in intracellular pathogen infections is poorly characterized. IL-22-producing CD4(+) T cells may express some effector molecules on the membrane, and therefore synergize or contribute to antimicrobial effector function. This hypothesis cannot be tested by conventional approaches manipulating a single IL-22 cytokine at genetic and protein levels, and IL-22(+) T cells cannot be purified for evaluation due to secretion nature of cytokines. In this study, we surprisingly found that upon activation, CD4(+) T cells in Mycobacterium tuberculosis-infected macaques or humans could evolve into T effector cells bearing membrane-bound IL-22 after de novo IL-22 production. Membrane-bound IL-22(+) CD4(+) T effector cells appeared to mature in vivo and sustain membrane distribution in highly inflammatory environments during active M. tuberculosis infection. Near-field scanning optical microscopy/quantum dot-based nanoscale molecular imaging revealed that membrane-bound IL-22, like CD3, distributed in membrane and engaged as ∼100-200 nm nanoclusters or ∼300-600 nm nanodomains for potential interaction with IL-22R. Importantly, purified membrane-bound IL-22(+) CD4(+) T cells inhibited intracellular M. tuberculosis replication in macrophages. Our findings suggest that IL-22-producing T cells can evolve to retain IL-22 on membrane for prolonged IL-22 t(1/2) and to exert efficient cell-cell interaction for anti-M. tuberculosis effector function.