Activation of the Zinc-sensing receptor GPR39 promotes T cell reconstitution after hematopoietic stem cell transplant

Prolonged lymphopenia represents a major clinical problem after cytoreductive therapies such as chemotherapy and the conditioning required for hematopoietic stem cell transplant (HCT), contributing toward the risk of infections and malignant relapse. Restoration of T cell immunity is dependent on tissue regeneration in the thymus, the primary site of T cell development; although the capacity of the thymus to repair itself diminishes over lifespan. However, although boosting thymic function and T cell reconstitution is of considerable clinical importance, there are currently no approved therapies for treating lymphopenia. Here we found that Zinc (Zn), is critically important for both normal T cell development as well as repair after acute damage. Accumulated Zn in thymocytes during development was released into the extracellular milieu after HCT conditioning, where it triggered regeneration by stimulating endothelial cell-production of BMP4 via the cell surface receptor GPR39. Dietary supplementation of Zn was sufficient to promote thymic function in a mouse model of allogeneic HCT, including enhancing the number of recent thymic emigrants in circulation; although direct targeting of GPR39 with a small molecule agonist enhanced thymic function without the need for prior Zn accumulation in thymocytes. Together, these findings not only define an important pathway underlying tissue regeneration, but also offer an innovative preclinical approach to treat lymphopenia in HCT recipients.

Damage-Induced Pyroptotic Cell Death Facilitates Regeneration of the Thymus

T cell reconstitution after transplant is critically dependent on the thymus; an inverse relationship between a transplant recipient's age and their capacity to generate T lymphocytes (in particular CD4+T cells) has been found in several studies, and thymic function pre-transplant can have a significant impact on clinical outcomes. Although the thymus has a remarkable ability to repair following damage, the mechanisms underlying this endogenous regeneration remain poorly understood. Despite this regenerative capacity, delayed T cell reconstitution is associated with an increased risk of infections, relapse of malignancy and the development of secondary malignancies. Therefore, there is a clinical demand for therapeutics that restore immune function after damage. Our recent studies have identified two key pathways driving thymic regeneration; centered on the secretion of BMP4 by endothelial cells (ECs) and IL-22 by innate lymphoid cells (Dudakov 2012 Science 336:91; Dudakov 2017 Blood130:933; Wertheimer 2018 Sci Immunol3:19). However, the specific regulatory mechanisms that trigger these regeneration-associated factors after damage remain unclear. Our previous work identified that the presence of homeostatic apoptotic CD4+CD8+ (DP) thymocytes, as apoptotic thymocytes form the bulk of developing T cells, suppress the production of IL-23 in dendritic cells (DCs), a key downstream mediator for IL-22, and BMP4 in ECs (Fig. 1A), and that the depletion of apoptotic thymocytes after damage precedes the production of these regenerative factors. Therefore, together with our findings that the metabolic needs of key thymus populations alter drastically following injury due to damage-induced metabolic remodeling, we hypothesized that further to the loss of DP-specific suppression, metabolic dysfunction in DPs after damage triggers mitochondrial-induced pyroptotic cell death, which can directly promote regeneration of the thymus. Consistent with this hypothesis, our preliminary data shows increased levels of cl-caspase 1 (pyroptotic caspase) and a decrease in cl-caspase 3 (apoptotic caspase) in DPs after SL-TBI (550 cGy), demonstrating a preferential induction of pyroptotic cell death in DPs after damage (Fig. 1B). Furthermore, we demonstrated an increase in extracellular lactate dehydrogenase (LDH) levels, HMGB-1 and TNF⍺[canonical damage-associated molecular patterns (DAMPs) released during ICD] acutely after damage caused by SL-TBI (Fig. 1C).Given our previous findings that stromal cells are more radio-resistant than DP thymocytes (Wertheimer 2018 Sci Immunol3:19), and evidence for mitochondrial-induced pyroptosis, we identified hyperpolarization of the mitochondrial membrane potential accompanied by increased levels of ROS in DPs, an effect not observed in TECs, suggesting metabolic stability confers protection against acute damage (Fig. 1D). Furthermore, co-culture of pyroptotic thymocytes results in increased IL12p40+ DCs and increased Foxn1 expression in TECs (Fig. 1E), strengthening our hypothesis that cell-cell communication drives thymic regeneration after damage by inducing regenerative factors as well as directly promoting TEC function via secreted factors from pyroptotic DPs. One way in which DAMPs, such as ATP, can initiate cell signaling is by the activation of cell surface purinergic receptors, including P2Y2 which is widely expressed on TECs, and here we demonstrate that in vitro treatment with ATP or P2Y2 agonist increases Foxn1 in cTECs, and P2Y2 antagonism reverses this effect (Fig 1F). As P2Y2 activation promotes Ca2+efflux from the ER, we have further demonstrated that stimulating the intracellular release of Ca2+, using tunicamycin, induced Foxn1 expression in cTECs, which was reversed upon inhibition of Ca2+release (Fig. 1G). Importantly, we demonstrate here that this pathway can be therapeutically targeted by activating P2Y2 signaling in vivo with MRS2568 or ATP enhances thymus cellularity and expands cTECs in models of acute injury (Fig. 1H&I). These findings not only reveal a novel metabolic-mediated molecular mechanism governing tissue regeneration; but also by targeting FOXN1 directly offers a potentially superior therapeutic strategy for boosting thymic regeneration and T cell reconstitution after damage such as that caused by HCT, infection or cytoreductive therapy. Disclosures No relevant conflicts of interest to declare.

UM171-Expanded Cord Blood Transplants Support Robust T-Cell Reconstitution with Low Rates of Severe Infections

Introduction Rapid T cell reconstitution following hematopoietic stem cell transplantation is essential for protection against infections and has been associated with lower incidence of chronic graft-vs-host disease (cGVHD), relapse and transplant-related mortality (TRM). While cord blood (CB) transplants are associated with lower rates of cGVHD and relapse, their low stem cell content results in slower immune reconstitution and higher risk of graft failure, severe infections and TRM. Recently, results of a Phase I/II trial revealed that single UM171-expanded CB transplant allowed the use of smaller CB units without compromising engraftment. We now report on T cell reconstitution and immune function in patients transplanted with UM171-expanded CB grafts. Methods We performed a retrospective analysis of 20 patients treated with UM171-expanded CB and compared it to a contemporary cohort of 12 patients treated in the same institution who received unmanipulated CB transplant with similar conditioning regimens. Of note, no patient received ATG as part of the conditioning in either cohort. We used flow cytometry and TCR sequencing to evaluate T cell reconstitution, and virus-specific ELISpot assays to evaluate T cell function in the first year post-transplantation. We also categorized infectious events as per definitions of infection severity in the BMT CTN Technical MOP Version 3.0 and report the mean cumulative count of infectious events for each cohort. Results While median T cell dose in graft was at least 2-3x lower for the cohort of patients treated with UM171-expanded CB due to the selection of smaller cords and to cell loss occurring during CD34 selection process, numbers and phenotype of T cells at 3, 6 and 12 months post-transplant were similar in patients treated with UM171-expanded or unmanipulated CB transplant. TCR sequencing analyses revealed that UM171 patients had greater T cell diversity and higher numbers of T cell clonotypes at 12 months post-transplant compared to patients who received unmanipulated CB. Younger UM171 patients (i.e. <40 years old) also showed a more pronounced increase in naïve T cells and recent thymic emigrants (RTE) between 3- and 12-months post-transplant compared to age-matched unmanipulated CB patients, suggesting that UM171-expansion improves thymopoiesis at least in the young patients. This also correlated with the demonstration that UM171 expands common lymphoid progenitors in vitro. ELISpot assays revealed that UM171 patients showed early virus-specific T cell reactivity, at 2- and 3-months post-transplant. Most importantly, UM171 patients had a 2-fold lower frequency of severe (i.e. grade 2-3) infections at 1 year post-transplant, even though time to engraftment of 500 neutrophils was similar between the two cohorts (17 and 20 days for the UM171-expanded and unmanipulated CB cohorts respectively, p=0.94). Conclusion Our data show that the relative T-cell paucity of the UM171 graft is rapidly compensated after transplant with no significant difference observed between the two cohorts in terms of numbers and phenotypes of T cells at 3, 6 or 12 months post-transplant. Although it is difficult to dissect the relative contribution of homeostatic expansion and de novo thymopoiesis, recipients of UM171 grafts had a greater TCR diversity at one year, which was more evident among patients younger than 40 years of age. The prompt immune reconstitution observed in UM171 patients translated into a low rate of severe (grade 2-3) infections and no infection-related mortality. These results support rapid and functional T cell reconstitution following UM171 expanded CB transplantation, which likely contributes to the absence of moderate/severe cGVHD, infection-related mortality and late TRM observed in this cohort. Figure legend: Mean cumulative counts of infectious events in patients transplanted with UM171-expanded (blue) or unmanipulated (red) CB. Mean cumulative counts are shown for all infectious events (A), bacterial (B) and viral (C) infections. Events were categorized by type and severity as per BMT CTN guidelines (Appendix 4A). Infectious events of grade 1-3 are shown in pale colors, while more severe events (grade 2-3) are shown in dark colors. Censored patients (including those who relapsed) are indicated with white circles. Figure 1 Disclosures Dumont-Lagacé: ExCellThera: Current Employment. Busque:Novartis: Honoraria; BMS: Honoraria; Pfizer: Honoraria. Sauvageau:ExCellThera: Current equity holder in private company, Other: CEO, Patents & Royalties. Cohen:ExCellThera: Consultancy, Other: principal investigator of an ongoing UM171 clinical trial.

CD4+ T-cell reconstitution predicts Survival Outcomes after acute Graft-versus-Host-Disease; a dual center validation

Acute Graft-versus-Host-Disease (aGvHD) is a major cause of morbidity and mortality after allogeneic hematopoietic cell transplantation (HCT). We previously showed that early CD4+ T-cell reconstitution (CD4+IR) predicts survival after HCT. Here, we studied the relation between CD4+ IR and survival in patients who developed aGvHD. Pediatric patients receiving their first allogeneic HCT at the UMC Utrecht / Princess Máxima Center (UMC/PMC) or Memorial Sloan Kettering Cancer Center (MSK), were included. Primary outcomes were non-relapse mortality (NRM) and overall survival (OS), stratified for aGvHD and CD4+IR; defined as ³50 CD4+ T-cells/uL within 100 days after HCT, or prior to aGvHD onset. Multivariate and time-to-event Cox Proportional Hazard models were applied. 591 Patients (N= 276 UMC/PMC; N= 315 MSK) were included. NRM in patients with aGvHD grade III-IV with or without CD4+IR within 100 days after HCT was 30% vs 80% (p=0.02) at UMC/PMC and 5% vs 67% (p=0.02) at MSK. This associated with lower OS without CD4+IR; 61% vs. 20% (p=0.04) at UMC/PMC, and 75% vs. 33% (p=0.12) at MSK. Inadequate CD4+IR prior to aGvHD onset associates with significantly higher NRM; 74% vs 12% (p<0.001), and inferior OS; 24% vs 78% (p<0.001). In this retrospective analysis we demonstratethat early CD4+ IR, a simple and robust markerpredictive of outcomes after HCT,associates with survival after moderate to severe aGvHD.These associations need to be confirmed in a prospective manner but suggest that strategies to improve T-cell recovery after HCT may influence survival in patients developing aGvHD.