Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Adoptive transfer of donor regulatory T cells (Treg) is a promising treatment option for Graft-versus-Host disease (GvHD), but has not yet found its way into routine clinical practice. To map distinctive properties of protective Treg (generated by either polyclonal or allogeneic in vitro expansion), we followed their fate in recipient organs (spleen, liver, colon) in a prophylactic mouse model of MHC-mismatched bone-marrow transplantation (BMT). Using comprehensive gene expression and T cell receptor profiling, we show that both in vitro expansion protocols generated Treg products that preserved hallmark Treg properties, ameliorated GvHD symptoms, retained their phenotypic plasticity and rapidly acquired organ-specific gene expression profiles after BMT, comparable to their tissue-resident counterparts. When co-transplanted with GvHD-inducing T cells, Treg enabled hallmark suppressive and cytotoxic features, most evidently in the colon. Dominant Treg T cell receptor clonotypes were evenly distributed between organs and across recipients, suggesting a major role of ubiquitous alloantigen-specific Treg in controlling GvHD. Effective protection inversely correlated with the relative abundance of organ-specific Treg, that were transcriptionally distinct, less “activated” and preferentially accumulated in the colon of recipients receiving polyclonally expanded Treg. In summary, we provide a detailed atlas of Treg selection and adaptation in the prophylactic therapy of GvHD.

Project description:Adoptive transfer of donor regulatory T cells (Treg) is a promising treatment option for Graft-versus-Host disease (GvHD), but has not yet found its way into routine clinical practice. To map distinctive properties of protective Treg (generated by either polyclonal or allogeneic in vitro expansion), we followed their fate in recipient organs (spleen, liver, colon) in a prophylactic mouse model of MHC-mismatched bone-marrow transplantation (BMT). Using comprehensive gene expression and T cell receptor profiling, we show that both in vitro expansion protocols generated Treg products that preserved hallmark Treg properties, ameliorated GvHD symptoms, retained their phenotypic plasticity and rapidly acquired organ-specific gene expression profiles after BMT, comparable to their tissue-resident counterparts. When co-transplanted with GvHD-inducing T cells, Treg enabled hallmark suppressive and cytotoxic features, most evidently in the colon. Dominant Treg T cell receptor clonotypes were evenly distributed between organs and across recipients, suggesting a major role of ubiquitous alloantigen-specific Treg in controlling GvHD. Effective protection inversely correlated with the relative abundance of organ-specific Treg, that were transcriptionally distinct, less “activated” and preferentially accumulated in the colon of recipients receiving polyclonally expanded Treg. In summary, we provide a detailed atlas of Treg selection and adaptation in the prophylactic therapy of GvHD.

Project description:Adoptive transfer of donor regulatory T cells (Treg) is a promising treatment option for Graft-versus-Host disease (GvHD), but has not yet found its way into routine clinical practice. To map distinctive properties of protective Treg (generated by either polyclonal or allogeneic in vitro expansion), we followed their fate in recipient organs (spleen, liver, colon) in a prophylactic mouse model of MHC-mismatched bone-marrow transplantation (BMT). Using comprehensive gene expression and T cell receptor profiling, we show that both in vitro expansion protocols generated Treg products that preserved hallmark Treg properties, ameliorated GvHD symptoms, retained their phenotypic plasticity and rapidly acquired organ-specific gene expression profiles after BMT, comparable to their tissue-resident counterparts. When co-transplanted with GvHD-inducing T cells, Treg enabled hallmark suppressive and cytotoxic features, most evidently in the colon. Dominant Treg T cell receptor clonotypes were evenly distributed between organs and across recipients, suggesting a major role of ubiquitous alloantigen-specific Treg in controlling GvHD. Effective protection inversely correlated with the relative abundance of organ-specific Treg, that were transcriptionally distinct, less “activated” and preferentially accumulated in the colon of recipients receiving polyclonally expanded Treg. In summary, we provide a detailed atlas of Treg selection and adaptation in the prophylactic therapy of GvHD.

Project description:Donor regulatory T cells rapidly adapt to recipient tissues to control acute graft-versus-host disease

Project description:Donor regulatory T cells rapidly adapt to recipient tissues to control acute graft-versus-host disease [TCR-seq]

Project description:Donor regulatory T cells rapidly adapt to recipient tissues to control acute graft-versus-host disease [bulk RNA-seq]

Project description:Adoptive transfer of freshly isolated natural occurring CD4(+)CD25(+)Foxp3(+) regulatory T cells (Treg) prevents graft-versus-host disease (GVHD) in several animal models and following hematopoietic cell transplantation (HCT) in clinical trials. Donor-derived Treg have been mainly used, as they share the same MHC with CD4(+) and CD8(+) conventional T cells (Tcon) that are primarily responsible for GVHD. Third party-derived Treg are a promising alternative for cellular therapy, as they can be prepared in advance, screened for pathogens and activity, and banked. We explored MHC disparities between Treg and Tcon in HCT to evaluate the impact of different Treg populations in GVHD prevention and survival. Third-party Treg and donor Treg are equally suppressive in ex vivo assays, whereas both donor and third-party but not host Treg protect from GVHD in allogeneic HCT, with donor Treg being the most effective. In an MHC minor mismatched transplantation model (C57BL/6 → BALB/b), donor and third-party Treg were equally effective in controlling GVHD. Furthermore, using an in vivo Treg depletion mouse model, we found that Treg exert their main suppressive activity in the first 2 d after transplantation. Third-party Treg survive for a shorter period of time after adoptive transfer, but despite the shorter survival, they control Tcon proliferation in the early phases of HCT. These studies provide relevant insights on the mechanisms of Treg-mediated protection from GVHD and support for the use of third-party Treg in clinical trials.

Project description:Donor regulatory T cells rapidly adapt to recipient tissues to control acute graft-versus-host disease [scRNA-seq & scTCR-seq]

Project description:Transplantation and pregnancy, in which two diploid genomes reside in one body, can each lead to diseases in which immune cells from one individual target antigens encoded in the other's genome. One such disease, graft-versus-host disease (GVHD) after hematopoietic stem cell transplantation (HSCT, or bone marrow transplant), is common even after transplants between HLA-identical siblings, indicating that cryptic histocompatibility loci exist outside the HLA locus. The immune system of an individual whose genome is homozygous for a gene deletion could recognize epitopes encoded by that gene as alloantigens. Analyzing common gene deletions in three HSCT cohorts (1,345 HLA-identical sibling donor-recipient pairs), we found that risk of acute GVHD was greater (odds ratio (OR) = 2.5; 95% confidence interval (CI) 1.4-4.6) when donor and recipient were mismatched for homozygous deletion of UGT2B17, a gene expressed in GVHD-affected tissues and giving rise to multiple histocompatibility antigens. Human genome structural variation merits investigation as a potential mechanism in diseases of alloimmunity.