Myeloid cells activate iNKT cells to produce IL-4 in the thymic medulla.

Interleukin-4 (IL-4) is produced by a unique subset of invariant natural killer T (iNKT) cells (NKT2) in the thymus in the steady state, where it conditions CD8+ T cells to become "memory-like" among other effects. However, the signals that cause NKT2 cells to constitutively produce IL-4 remain poorly defined. Using histocytometry, we observed IL-4-producing NKT2 cells localized to the thymic medulla, suggesting that medullary signals might instruct NKT2 cells to produce IL-4. Moreover, NKT2 cells receive and require T cell receptor (TCR) stimulation for continuous IL-4 production in the steady state, since NKT2 cells lost IL-4 production when intrathymically transferred into CD1d-deficient recipients. In bone marrow chimeric recipients, only hematopoietic, not stromal, antigen-presenting cells (APCs), provided such stimulation. Furthermore, using different Cre-recombinase transgenic mouse strains to specifically target CD1d deficiency to various APCs, together with the use of diphtheria toxin receptor (DTR) transgenic mouse strains to deplete various APCs, we found that macrophages were the predominant cell to stimulate NKT2 IL-4 production. Thus, NKT2 cells appear to encounter and require different activating ligands for selection in the cortex and activation in the medulla.

ARTC2.2/P2RX7 Signaling during Cell Isolation Distorts Function and Quantification of Tissue-Resident CD8+ T Cell and Invariant NKT Subsets.

Peripheral invariant NKT cells (iNKT) and CD8+ tissue-resident memory T cells (TRM) express high levels of the extracellular ATP receptor P2RX7 in mice. High extracellular ATP concentrations or NAD-mediated P2RX7 ribosylation by the enzyme ARTC2.2 can induce P2RX7 pore formation and cell death. Because both ATP and NAD are released during tissue preparation for analysis, cell death through these pathways may compromise the analysis of iNKT and CD8+ TRM Indeed, ARTC2.2 blockade enhanced recovery of viable liver iNKT and TRM The expression of ARTC2.2 and P2RX7 on distinct iNKT subsets and TRM is unclear, however, as is the impact of recovery from other nonlymphoid sites. In this study, we performed a comprehensive analysis of ARTC2.2 and P2RX7 expression in iNKT and CD8+ T cells in diverse tissues, at steady-state and after viral infection. NKT1 cells and CD8+ TRM express high levels of both ARTC2.2 and P2RX7 compared with NKT2, NKT17, and CD8+ circulating memory subsets. Using nanobody-mediated ARTC2.2 antagonism, we showed that ARTC2.2 blockade enhanced NKT1 and TRM recovery from nonlymphoid tissues during cell preparation. Moreover, blockade of this pathway was essential to preserve functionality, viability, and proliferation of both populations. We also showed that short-term direct P2RX7 blockade enhanced recovery of TRM, although to a lesser degree. In summary, our data show that short-term in vivo blockade of the ARTC2.2/P2RX7 axis permits much improved flow cytometry-based phenotyping and enumeration of murine iNKT and TRM from nonlymphoid tissues, and it represents a crucial step for functional studies of these populations.

Ultrasound Guided Intra-thymic Injection to Track Recent Thymic Emigrants and Investigate T Cell Development.

To track recent thymic emigrants (RTEs) or study T cell development in the thymus, intra-thymic injection of a cellular tag or precursor cells for various T cell lineages is often desired. However, the traditional surgical approach to expose the thymus for intra-thymic injection is time-consuming and can cause a high level of pain and stress to animals, which might disrupt immune homeostasis, potentially confounding the results. Here, we introduce an ultrasound guided intra-thymic injection procedure, which is non-surgical and minimally invasive to animals. This technique is relatively easy to learn and offers an efficient and accurate tool to track RTEs or perform intra-thymic transfer of various cell types to investigate their differentiation.