ALBERT

Description: Background: T effector cells (Teff) within the stem cell graft in allogeneic hematopoietic stem cell transplantation (HSCT) can elicit disabling acute graft-versus-host disease (aGvHD) contributing to transplant-related mortality. Teff as donor lymphocyte infusion (DLI) are a therapeutic option to re-induce complete remission (CR) after leukemia relapse. Usually DLIs are given in dose escalating regimens until CR is achieved or first signs of aGvHD develop. To monitor the DLI induced allo-immune response and the efficacy of aGvHD treatment is a clinical challenge, since no established biomarkers are available. T regulatory cells (Tregs) are thought to play an important role in balancing immune responses and studies have shown effects of adoptive Treg transfer as a therapeutic option in GvHD. T cell receptor (TCR) sequencing of T cell subsets, such as Tregs, after DLI might allow the identification of clones inducing control of GvHD. Here we report data of 29 DLI patients with a median follow-up of 〉1 year allowing us to thoroughly analyze differences of the TCR repertoire in patients with or without aGvHD. Aims: We aimed to analyze Treg TCR diversity and clonality changes over time as a potential biomarker for development and treatment response of aGvHD following DLI. Patients and Methods: The study cohort consisted of 29 leukemia patients after HSCT who received DLI treatment for recurrence of disease, molecular relapse or high risk phenotype. Blood samples were taken before and after DLI. A median of 4 (range 2-6) blood samples per patient were available for TCR-sequencing. The last sample was taken at a median of 123 (27-530) days post DLI. After generation of PBMCs CD4+CD127-CD25+ Tregs were FACS-sorted for cDNA-based CDR3-region amplification of the TCR-β chain. CDR3 amplicons were sequenced on the Illumina MiSeq platform and annotated using the IMGT.org database. Further bioinformatic analyses were based on VDJtools and the tcR R-package. Results: In 18/29 patients we observed clinical symptoms of aGvHD, with blood samples available of the acute onset in 12/18 cases. Treg frequencies and absolute numbers did not differ between aGvHD and noGvHD samples. Treg TCR diversity, assessed via inverse Simpson's diversity index (1/D) increased on average by 322% at the first occurrence of aGvHD compared to the previous sample (Figure 1A, B). Stratifying for aGvHD severity (total grade 1-2 vs. 3-4) did not reveal any group differences. However, stratifying by organ involvement (skin vs. GI/liver) showed a more pronounced increase of 1/D in patients with aGvHD of the GI tract and/or the liver. Moreover, in 11 subjects blood samples were available a median of 7 (3-14) days prior to aGvHD diagnosis. Already at this preclinical time point we detected an increased 1/D of +361% (Figure 1A, B). Again, aGvHD organ involvement significantly affected the result, with GI/liver involvement mainly driving this effect (+567% vs. +1% 1/D). In contrast, patients who did not develop aGvHD at any time after DLI showed on average a slight decrease of -8% 1/D compared to the previous time point. Next, we analyzed all aGvHD patients with at least one sample available after initiation of treatment (local and/or systemic steroids). Control or remission of aGvHD symptoms was accompanied by decreased 1/D of on average -58% compared to the previous samples (Figure 2). In 9/11 patients we saw a focusing of the Treg TCR repertoire; in the other two (Figure 2, red lines) no or only partial clinical response to systemic steroids was reported. Conclusion: Our data describe detailed changes in the Treg compartment on the TCR level following development and treatment of aGvHD. Currently, aGvHD diagnosis following DLI treatment relies solely on clinical symptoms, deciding whether further dose increments of DLI can be administered. As our data suggest, Treg TCR sequencing may support transplant specialists with (1) detection of patients at risk for aGvHD, even prior to clinical symptoms, (2) identification of patients eligible for further dose increments (compare Figure 1B), and (3) assessment of aGvHD treatment with guidance whether higher dosage of steroids and/or alternative immunosuppressive treatment might be required (compare Figure 2, red lines). Future prospective studies are needed to replicate these findings in a large cohort, potentially enabling identification of specific Treg TCR clones controlling the allo-immune response in aGvHD. Disclosures Ganser: Novartis: Membership on an entity's Board of Directors or advisory committees. Koenecke:BMS: Consultancy; abbvie: Consultancy; Amgen: Consultancy; Roche: Consultancy.

Description: Acute Graft versus Host Disease (aGvHD) remains a major complication and leading cause of mortality after allogeneic stem cell or bone marrow transplantation (BMT). Current strategies for treatment are still based on unspecific immunosuppressive therapy. Over the last decade, there have been major advances in the field of adoptive immunotherapy using regulatory CD4+CD25+Foxp3+ T cells (Treg cells). Nonetheless, not much is known about the exact mechanisms of Treg-mediated suppression, and even less about the importance of T cell receptor (TCR) specificity and its diversity on the functionality of Tregs. We hypothesized that an optimal Treg TCR repertoire is necessary for successful prevention of aGvHD. To test this hypothesis, we sequenced the TCR repertoire of 8 patients who were diagnosed with aGvHD on day 30 post transplantation and compared it with the TCR repertoire of nine GvHD-free patients. Analysis of GvHD-free patients on day 30 (and 100 days-follow up) revealed a lower TCR diversity when compared to the patients suffering from GvHD. A more detailed analysis of the TCR repertoire showed that in patients without GvHD, fewer clonotypes were needed to comprise 50% of the whole repertoire as compared with samples from patients with GvHD (Figure 1A). Thus, expansion of protective clones indicates their potent immunosuppressive capabilities. Next, we employed a well-described murine model of allogeneic BMT (BL/6--〉Balb/c) with co-injection of Tregs. Recipient Balb/c mice transplanted in this fashion were previously shown to be protected from aGvHD. However, the mechanisms involved in this Treg-mediated protection are not fully understood. Therefore, Tregs were FACS sorted from B6.Cg-Foxp3tm1Mal/J mice based on their Foxp3 expression. Recipient mice were transplanted with T-cell depleted bone marrow and a mixture of conventional T cells (Tconv) and Tregs in 1:1 ratio. Transferred Tregs were re-sorted on day 7 and day 14 from secondary lymphoid organs based on the congenic marker Thy 1.1 and Foxp3 expression. Using this model, we investigated the kinetics of the Treg TCR repertoire early after BMT in 5 independent experiments. We found a consistently similar narrowing of the repertoire and clonal expansion in mice protected from GvHD (Figure 1B). Diversity analysis using inverse Simpson Index also confirmed our findings. These data further support the notion that a clonal expansion of Tregs is necessary for an optimal immunosuppression of an allogeneic response, both in human and in mice. To test the functionality and phenotype of such expanded Tregs, they were re-sorted from BMT-recipient mice 14 days after transplantation. These Tregs were expanded using α-CD3 and α-CD28 antibodies and were functionality tested in an in vitro Treg suppression assay. Re-sorted Tregs after expansion showed expression of established Treg surface and intracellular markers such as Helios, CD25, GITR and CTLA-4. For the suppression assay, responder CD4 Tconv were stained with a proliferation tracking dye eFluor670 and stimulated in vitro with CD3 and CD28 beads in the presence of different ratios of re-sorted and expanded, or polyclonaly activated Tregs as the control. Allo-specific ex vivo Tregs exhibited a superior suppressive potential when compared with polyclonaly activated Tregs in vitro. Taken together, our current study highlights the importance of specific Treg driven allo-response in GvHD prevention. Further studies are needed, particularly in larger patient cohorts to confirm these findings. However, we propose that this approach might lead to identification and subsequent use of specific Treg clones with high immunosuppressive capacity for the prevention of aGvHD. Disclosures Ganser: Novartis: Membership on an entity's Board of Directors or advisory committees. Koenecke:abbvie: Consultancy; BMS: Consultancy; Roche: Consultancy; Amgen: Consultancy.