A fetal wave of human type 3 effector gamma delta cells with restricted TCR diversity persists into adulthood

Accumulating evidence suggests that the mouse embryonic thymus produces distinct waves of innate effector gamma delta T cells. However, it is unclear whether this process occurs similarly in humans and whether it comprises a dedicated subset of innate-like type 3 effector gamma delta T cells. Here, we present a protocol for high-throughput sequencing of TRG and TRD pairs that comprise the clonal gamma delta TCR. In combination with single-cell RNA sequencing, multiparameter flow cytometry, and TCR sequencing, we reveal a high heterogeneity of gamma delta T cells sorted from neonatal and adult blood that correlated with TCR usage. Immature gamma delta T cell clusters displayed mixed and diverse TCRs, but effector cell types segregated according to the expression of either highly expanded individual V delta 1(+) TCRs or moderately expanded semi-invariant V gamma 9V delta 2(+) TCRs. The V gamma 9V delta 2(+) T cells shared expression of genes that mark innate-like T cells, including ZBTB16 (encoding PLZF), KLRB1, and KLRC1, but consisted of distinct clusters with unrelated V gamma 9V delta 2(+) TCR clones characterized either by TBX21, FCGR3A, and cytotoxicity-associated gene expression (type 1) or by CCR6, RORC, IL23R, and DPP4 expression (type 3). Effector gamma delta T cells with type 1 and type 3 innate T cell signatures were detected in a public dataset of early embryonic thymus organogenesis. Together, this study suggests that functionally distinct waves of human innate-like effector gamma delta T cells with semi-invariant V gamma 9V delta 2(+) TCR develop in the early fetal thymus and persist into adulthood

Single-Cell Transcriptomics Identifies the Adaptation of Scart1+ Vγ6+ T Cells to Skin Residency as Activated Effector Cells

IL-17-producing γδ T cells express oligoclonal Vγ4+ and Vγ6+ TCRs, mainly develop in the prenatal thymus, and later persist as long-lived self-renewing cells in all kinds of tissues. However, their exchange between tissues and the mechanisms of their tissue-specific adaptation remain poorly understood. Here, single-cell RNA-seq profiling identifies IL-17-producing Vγ6+ T cells as a highly homogeneous Scart1+ population in contrast to their Scart2+ IL-17-producing Vγ4+ T cell counterparts. Parabiosis demonstrates that Vγ6+ T cells are fairly tissue resident in the thymus, peripheral lymph nodes, and skin. There, Scart1+ Vγ6+ T cells display tissue-specific gene expression signatures in the skin, characterized by steady-state production of the cytokines IL-17A and amphiregulin as well as by high expression of the anti-apoptotic Bcl2a1 protein family. Together, this study demonstrates how Scart1+ Vγ6+ T cells undergo tissue-specific functional adaptation to persist as effector cells in their skin habitat.ISSN:2666-3864ISSN:2211-124

CD4+ T cells produce GM-CSF and drive immune-mediated glomerular disease by licensing monocyte-derived cells to produce MMP12

Despite glomerulonephritis being an immune-mediated disease, the contributions of individual immune cell types are not clear. To address this gap in knowledge, Paust et al. characterized pathological immune cells in samples from patients with glomerulonephritis and in samples from mice with the disease. The authors found that CD4+ T cells producing granulocyte-macrophage colony-stimulating factor (GM-CSF) licensed monocytes to promote disease by producing matrix metalloproteinase 12 and disrupting the glomerular basement membrane. Targeting GM-CSF to inhibit this axis reduced disease severity in mice, implicating this cytokine as a potential therapeutic target for patients with glomerulonephritis

Pathogen-induced tissue-resident memory T(H)17 (T(RM)17) cells amplify autoimmune kidney disease

Although it is well established that microbial infections predispose to autoimmune diseases, the underlying mechanisms remain poorly understood. After infection, tissue-resident memory T (T-RM) cells persist in peripheral organs and provide immune protection against reinfection. However, whether T-RM cells participate in responses unrelated to the primary infection, such as autoimmune inflammation, is unknown. By using high-dimensional single-cell analysis, we identified CD4(+) T-RM cells with a T(H)17 signature (termed T(RM)17 cells) in kidneys of patients with ANCA-associated glomerulonephritis. Experimental models demonstrated that renal T(RM)17 cells were induced by pathogens infecting the kidney, such as Staphylococcus aureus, Candida albicans, and uropathogenic Escherichia coli, and persisted after the clearance of infections. Upon induction of experimental glomerulonephritis, these kidney T(RM)17 cells rapidly responded to local proinflammatory cytokines by producing IL-17A and thereby exacerbate renal pathology. Thus, our data show that pathogen-induced T(RM)17 cells have a previously unrecognized function in aggravating autoimmune disease.erman Research Foundation (DFG) SFB1192 SFB1286 SFBTR57 Deutsche Nierenstiftung Deutsche Gesellschaft fur Nephrologie Werner Otto Stiftung eMed Consortia "Fibromap" from the Federal Ministry of Education and Research Comision Nacional de Investigacion Cientifica y Tecnologica (CONICYT) AFB 170004 Conicyt/FONDEQUIP/EQM140016 Else Kroner-Fresenius Foundatio