Abstract
In hematopoietic cell transplants, alloreactive T cells mediate the graft-versus-leukemia (GVL) effect. However, leukemia relapse accounts for nearly half of deaths. Understanding GVL failure requires a system in which GVL-inducing T cells can be tracked. We used such a model wherein GVL is exclusively mediated by T cells that recognize the minor histocompatibility antigen H60. Here we report that GVL fails due to insufficient H60 presentation and T cell exhaustion. Leukemia-derived H60 is inefficiently cross-presented whereas direct T cell recognition of leukemia cells intensifies exhaustion. The anti-H60 response is augmented by H60-vaccination, an agonist αCD40 antibody (FGK45), and leukemia apoptosis. T cell exhaustion is marked by inhibitory molecule upregulation and the development of TOX+ and CD39−TCF-1+ cells. PD-1 blockade diminishes exhaustion and improves GVL, while blockade of Tim-3, TIGIT or LAG3 is ineffective. Of all interventions, FGK45 administration at the time of transplant is the most effective at improving memory and naïve T cell anti-H60 responses and GVL. Our studies define important causes of GVL failure and suggest strategies to overcome them.
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Introduction
Allogeneic hematopoietic stem cell transplantation (alloSCT) can cure patients with hematologic neoplasms, most commonly acute myeloblastic leukemia (AML). Much of the efficacy of alloSCT is due to alloreactive αβT cells in the donor graft, which can kill recipient leukemia cells, thereby mediating the graft-vs-leukemia (GVL) effect1. Unfortunately, alloreactive T cells also attack normal host (recipient) tissues, causing graft-vs-host disease (GVHD)2,3,4. When donors and recipients are MHC-matched, alloreactive T cells target minor histocompatibility antigens (miHAs), which are the peptide products of nonsynonymous polymorphisms that distinguish the donor and host5. Alloreactive T cells that recognize miHAs expressed by leukemia cells can mediate GVL.
Despite alloreactive T cells developing in all recipients of T cell-replete grafts, relapsed malignant disease remains the greatest single cause of post-transplant mortality6. Unfortunately, there has been little progress in reducing relapse, especially of myeloblastic leukemias7,8. A barrier to making progress has been an incomplete understanding of the biology of relapse7.
Several nonexclusive mechanisms could contribute to GVL failure. Leukemia clones resistant to T cell killing could emerge under immune selection. This has been documented in HLA-mismatched transplants wherein relapsed leukemic cells can lose the targeted unshared HLA allele9,10. Relapsed leukemia samples from alloSCT recipients can have lower levels of HLA expression relative to pre-transplant specimens, and this could have been a consequence of immune selection11,12. HLA could be increased in relapse specimens by IFN-γ13, consistent with mouse models14.
Alternatively, or in addition, alloreactive T cells could fail to mount a response of sufficient magnitude and duration to completely clear or suppress leukemia cells. In one extreme, T cells could retain their intrinsic ability to be activated post-transplant but, with the elimination of miHA-bearing host hematopoietic cells, there could be insufficient miHA presentation by antigen presenting cells (APCs) to sustain them15,16. In the other extreme, T cells could be exhausted and unable to mount a strong response even with quality antigen presentation. Given the importance IFN-γ may have in promoting GVL against AML11,13,14, T cell exhaustion, which results in low IFN-γ production17, would be anticipated to diminish GVL.
To fully understand mechanisms of leukemia relapse post-alloSCT it is necessary to unequivocally identify GVL-inducing miHA-reactive T cells. This has previously not been possible in polyclonal mouse models and with human samples from alloSCT recipients because in these situations alloreactive T cells target many miHAs, most of which are unknown, and GVL-inducing T cells cannot be easily tracked. Moreover, even if all miHA-reactive T cells could be specifically identified, it would difficult to know which specificities are critical for GVL.
To address these limitations, we used a tractable mouse model wherein GVL is exclusively mediated by polyclonal alloreactive CD8 cells that target the mouse miHA H6018. H60 is predominantly expressed on hematopoietic cells19, including leukemia cells, and therefore represents an ideal type of miHA that has been proposed as a clinical target5,20,21. H60 reactive T cells are specific in that they only mediate GVL against H60+ and not H60− leukemia cells18. In these studies a clinically relevant model of blast crisis chronic myelogenous leukemia (BC-CML) created by co-transducing H60-expressing mouse bone marrow (BM) with retroviruses that express cDNAs encoding the human bcr-abl and NUP98/HOXA9 translocations was used18,22. These are bona fide oncogenes, representative of the classes of molecular drivers of AML23. Along with gene-modified leukemias, gene-deficient and transgenic donors and recipients, we use these tools to dissect and therapeutically address mechanisms of GVL failure. We show here that GVL fails due to insufficient antigen presentation, and the development of T cell exhaustion. The former could be improved by H60-vaccination while the effect of T cell exhaustion was mitigated by an agonist antibody to CD40 given at the time of transplant and by PD-1-blockade. Taken together these data provide new insights into GVL failure and chart a path for improving adoptive immunotherapies in the future.
Results
A tractable GVL system
To create a population of trackable donor CD8 cells reactive against a miHA expressed by leukemia cells, we vaccinated C3H.SW (H-2b) or B6 (H-2b) mice against the Kb-restricted mouse miHA H6019 using an antibody against DEC205 which was modified to express the H60 epitope LTFNYRNL (DEC-H60) with an agonist antibody against CD40 (FGK45)18. CD8 memory cells (TM) reactive against H60 (TMH60) were mostly CD62L+CD44+ central memory cells (TCM) with fewer CD62L−CD44+ effector memory cells (TEM). In most experiments, B6.H60 mice (congenic for H6018) were irradiated and reconstituted with C3H.SW or B6 T cell-depleted BM (referred to as BM), with CD8+CD44+ TM from H60-vaccinated C3H.SW or B6 donors, with or without H60+ BC-CML18 (referred to as BC-CML). The number of transferred CD8+ TM was adjusted to give a defined number of TMH60 (between 3.5 and 10 × 103), but H60 tetramer-positive (TetH60+) cells were not sort-purified. While a mix of both TCM and effector memory TEM TetH60+ cells were transferred, most expansion was from the TCM TetH60+ cells (Supplementary Fig. 1).
BC-CML cells outstrip the anti-H60 T cell response
To define the kinetics of BC-CML and TetH60+ T cell expansion, we sacrificed cohorts 7, 14, and 21 days post-transplant in the C3H.SW→B6.H60 system. TetH60+ cells outnumbered BC-CML cells at day +7 and were roughly equivalent at day +14 (Fig. 1). There was no further increase in TetH60+ T cells after day +14, with or without BC-CML, whereas BC-CML cells continued to expand in spleen and were stable in the BM. Therefore, despite abundant antigen in the form of H60+ BC-CML cells, the anti-miHA T cell response flattens. These data were compatible with GVL being limited by the emergence of GVL-resistant clones or by a failure in the T cell response.
Immune selection does not account for GVL resistance
To address whether alloimmunity selects for GVL-resistant BC-CML cells, we performed in vivo CTL assays on nonselected BC-CML and relapsed BC-CML (Fig. 2a). Relapsed BC-CML cells were harvested from B6.H60 mice that had been transplanted with BC-CML cells and TMH60 25-28 days prior. Nonselected BC-CML cells were harvested from B6.H60 mice transplanted with BC-CML cells without TMH60. Nonselected (cell tracker violet-labeled), relapsed (DeepRed-labeled) and control H60−Kb−/− (unlabeled) BC-CML cells were injected into B6 mice that had or had not been immunized with DEC-H60 and FGK45 seven days prior. When analyzed 18 h later, fresh and relapsed BC-CML cells were equally killed by anti-H60 effectors (Fig. 2b, c).
We also compared killing of SIINFEKL-pulsed BC-CML cells by OT-1 transgenic T cells to account for possible selection of leukemias with reduced H60 expression. Unpulsed and SIINFEKL-pulsed unselected and relapsed BC-CML cells were transferred into B6 mice that had been seeded with OT-1 cells and vaccinated with an anti-DEC205 antibody modified to express ovalbumin and FGK45 seven days prior. Again, relapsed BC-CML cells were not resistant to T cell killing relative to unselected BC-CML cells (Fig. 2d, e). These data indicate that in our model immune selection does not account for GVL resistance. We therefore further investigated the anti-H60 CD8 response.
Ineffective antigen presentation limits GVL
Because H60 is mostly expressed by hematopoietic cells, effective antigen presentation may become limiting as host hematopoietic cells die from radiation and T cell killing15. Conversely, H60 would become increasingly available from expanding BC-CML cells; however, how well BC-CML cells directly stimulate T cells or whether their miHAs are effectively cross-presented by donor-derived cells was unknown. To measure antigen presentation at day 14 post-transplant, (when TetH60+ cells peak; Fig. 1), we infused congenic CD45.1+ C3H.SW TMH60 14 days after B6.H60 mice were transplanted with C3H.SW BM and CD45.2+ TMH60, with or without BC-CML. As a positive control for the capacity of day 14 (D14) TMH60 to respond to H60, some mice were also immunized with DEC-H60 and FGK45 (design, Fig. 3a). By day +21, CD45.1+ D14 TMH60 had undergone little expansion, nowhere near that of TMH60 infused on day 0 (Fig. 3b, c). Immunization with FGK45 + DEC-H60 increased D14 CD45.1+TetH60+ progeny more than 10-fold (with or without BC-CML) indicating that D14 cells can be activated with effective antigen presentation. Importantly, D14 TMH60 combined with FGK45 + DEC-H60 reduced BC-CML numbers in spleen and BM relative to infusion of only TMH60 (Fig. 3d).
Surprisingly, FGK45 alone augmented the anti-H60 response, even in the absence of BC-CML, indicating that there were sources of H60 not being effectively presented (Fig. 3g, h). FGK45 combined with D14 CD45.1+ TMH60 also improved GVL (Supplementary Fig. 2A). GVL promotion by FGK45 was not due to a direct action on BC-CML cells as FGK45 did not reduce BC-CML numbers in RAG2−/−γc−/− mice transplanted with BC-CML cells and no T cells (Supplementary Fig. 2B).
The addition of DEC-H60 to FGK45 consistently led to a greater increase of D14-derived TetH60+ cells in BM and expansion of day 0 (D0)-derived TetH60+ cells enumerated on day +21 (Fig. 3g). We therefore performed experiments wherein transplanted mice received D14 TMH60 alone, with DEC-H60 or with DEC-H60 + FGK45 (Supplementary Fig. 2C). DEC-H60 alone augmented expansion of D14 TMH60, though not as effectively as FGK45 + DEC-H60, indicating that both antigen and suboptimal APC activation limit H60-reactive T cell expansion.
To determine whether FGK45 was acting on donor and/or residual host-derived APCs we compared its effect in mice transplanted with wild type (wt) or CD40−/− BM using the B6→B6.H60 system as C3H.SW CD40−/− mice were not available. Irradiated B6.H60 mice were reconstituted with B6 or B6 CD40−/− BM. On day +14 all mice received B6 CD45.1 TMH60 and a cohort from each group was treated with FGK45. FGK45 had less of an impact on TetH60+ expansion in recipients of B6 CD40−/− BM, indicating that FGK45’s greatest activity is on donor APCs cross-presenting host H60 (Supplementary Fig. 2D). Because mice did not receive day 0 TMH60 there was likely a substantial number of residual recipient APCs, which may explain the activity of FGK45 in recipients of CD40−/− BM.
To determine whether donor dendritic cells (DCs) were essential, B6.H60 mice were transplanted with wt B6 CD45.2 TMH60 (to enhance the clearance of recipient APCs) and BM from B6 mice that express the diphtheria toxin receptor (DTR) under control of the CD11c gene (CD11c-DTR24) or B6 CD40−/− BM. Beginning on day +10, a cohort of CD11c-DTR BM recipients was injected with diphtheria toxin (DT) every other day to deplete donor-derived DCs. On day +14, all mice received B6 CD45.1+ TMH60, with or without FGK45 (design, Supplementary Fig. 2E). FGK45 was again less effective in recipients of B6 CD40−/− BM (Fig. 3i). Importantly, donor DC-depletion completely prevented FGK45’s augmentation of the TetH60 response, indicating that donor DCs that cross-present recipient H60 were the major FGK45 targets (Fig. 3i).
Effect of leukemia-derived H60 on the anti-H60 response
It was surprising that insufficient H60 presentation limited the activation of H60-reactive T cells in mice with a substantial burden of H60+BC-CML. To test how efficiently leukemia-derived miHAs are cross-presented, irradiated B6 mice were reconstituted with C3H.SW BM, C3H.SW TMH60 and B6 H60+Kb−/− BC-CML cells. At day +13 post transplantation, TetH60+ cells were few relative to similarly transplanted B6.H60 recipients and similar to control mice transplanted with H60−Kb−/− BC-CML cells (Fig. 4a), indicative of inefficient cross-presentation.
To determine how well leukemia cells directly stimulate alloreactive T cells, irradiated B6 beta-2-microglobulin-deficient (β2M−/−) mice were reconstituted with B6 β2M−/− BM, wt H60+ BC-CML, and B6 TMH60. In such mice only BC-CML cells were MHCI+ and capable of stimulating TMH60. At day +10 post-transplant we could not detect CD8+TetH60+ cells whereas there was a large TetH60+ response in control B6.H60 recipients (Fig. 4b).
To test whether leukemia cells need to be killed for their miHAs to be cross-presented we transplanted B6 mice with CD45.2+ C3H.SW BM, Kb−/−H60+ BC-CML along with C3H.SW CD4 cells, which mediate GVL in this model25. On day +14, mice received CD45.1+ TMH60 and FGK45. Despite significant CD4-mediated GVL, there was little TetH60+ expansion (Fig. 4c).
It was possible that the magnitude or timing of CD4+ T cell killing was suboptimal for effective cross-presentation. We therefore engineered H60+Kb−/− BC-CML cells to express an inducible caspase 9 (iCasp9)26. Treatment of mice harboring these leukemias with AP20187 (chemical induced dimerization; CID) rapidly induced apoptosis (Supplementary Fig. 3). Irradiated B6 or B6 Kb−/− mice (to restrict H60 presentation to donor cells) were reconstituted with C3H.SW BM and H60+Kb−/− iCasp9 BC-CML. Twelve to 14 days post-transplant, a cohort was injected with CID. On day +14, all mice received C3H.SW TMH60 and FGK45 (design, Fig. 4d) to measure cross-presentation. On day +21 there was robust TetH60+ T cell expansion in CID-treated B6 and B6 Kb−/− recipients and significant expansion even in untreated mice, likely due to spontaneous iCasp9 dimerization (Fig. 4e). Therefore, leukemia-derived antigens can be cross-presented by donor-derived APCs, but only after substantial leukemia apoptosis.
T cell exhaustion contributes to GVL failure
While DEC-H60 and FGK45 induced expansion of TMH60 infused on day +14, they less effectively stimulated the progeny of TMH60 infused on day 0 (Fig. 3c, g). Moreover, a smaller fraction of day 0 TMH60 progeny produced IFN-γ with peptide restimulation (Fig. 3e, f, h), characteristic of T cell exhaustion. We therefore further analyzed TMH60 progeny from B6.H60 mice transplanted with C3H.SW BM and TMH60, with or without H60+ BC-CML. By days +21–25, TetH60+ cells from BM and spleen had uniformly upregulated PD-1 and most progeny expressed Tim-3, TIGIT and LAG3, all associated with exhaustion (Fig. 5a, b and Supplementary Fig. 4A). They also had reduced IFN-γ production relative to fresh TMH60 and to TetH60+ cells harvested at day +7 post-transplant (Fig. 5c and Supplementary Fig. 4B, C).
Eomes and Blimp-1 were high in TetH60+ cells, again consistent with an exhaustion phenotype (Fig. 5d). Importantly, relative to mice transplanted without leukemia, TetH60+ cells from mice transplanted with BC-CML had more characteristics of exhaustion–increased inhibitory molecule expression, increased Blimp-1 and Eomes and reduced IFN-γ production–indicating that rather than being stimulatory, BC-CML cells augment exhaustion (Fig. 5a–d). This effect required cognate TCR:MHCI contact as Kb−/− H60+BC-CML did not intensify exhaustion (Fig. 5e). H60+PD-L1/L2−/− BC-CML induced similar exhaustion as did H60+PD-ligand-intact BC-CML indicating that antigen exposure and not PD-ligands promote exhaustion (Fig. 5f).
TetH60+ cells isolated post transplantation had metabolic characteristics of exhaustion27. Freshly isolated TMH60 had low-level 2-NBDG uptake and low mitochondrial mass and mitochondrial membrane potential as expected for quiescent cells (Supplementary Fig. 4D, E). In contrast, on day +7 post transplantation, splenic and BM TetH60+ cells had increased glucose uptake and mitochondrial mass, with a majority of cells also having bright TMRE staining, consistent with active respiration (Supplementary Fig. 4D, E). By day +21, however, TetH60+ cells had lost mitochondrial mass, with few being TMRE-bright (Fig. 5g and Supplementary Fig. 4D, E). The presence of BC-CML led to a modest increase in mitochondrial mass, but without a consistent change in mitochondrial depolarization (Fig. 5g).
Inhibition of PD-1 but not Tim-3, LAG3 or TIGIT, improves GVL
Given the evidence for T cell exhaustion, we investigated whether post-transplant PD-1 blockade would improve TMH60 performance. Irradiated B6.H60 mice were reconstituted with C3H.SW BM, C3H.SW TMH60, and B6.H60 BC-CML. α-PD1 or an isotype control was begun on day +7 to avoid adverse effects of PD-1 blockade on early T cell activation28. α-PD1 reduced the percentage of BC-CML cells in blood on day +14 and their numbers in spleen and BM on day +21. α-PD1 also increased the number of TetH60+ cells in BM (Fig. 6a, b). Importantly, in α-PD1 treated mice TetH60+ cells produced more IFN-γ and had a reduced expression of TIGIT (Fig. 6b–d). The increase in IFN-γ production with in vitro stimulation reflected increased in vivo IFN-γ production as MHCII expression on BC-CML cells, which is IFN-γ-regulated14, was higher with PD-1-blockade (Fig. 6e).
We next tested blockade of Tim-3, TIGIT and LAG3, alone or in combination with α-PD1 (design, Supplementary Fig. 5A). In all experiments α-PD1 improved GVL, increased the number of BM TetH60+ cells, the percentage of IFN-γ+TetH60+ cells in both BM and spleen, and decreased expression of Tim-3 and TIGIT (Fig. 6f–i; Supplementary Fig. 5). However, blockade of LAG3 (Fig. 6f), Tim-3 or TIGIT (Supplementary Fig. 5B, F) did not augment GVL, even in combination with α-PD1 under conditions in which α-PD1 was only partially effective. TIGIT-blockade diminished the number of TetH60+ cells while increasing the percentage that produced IFN-γ (Supplementary Fig. 5G, H), perhaps by depleting cells with the highest TIGIT expression. LAG3-blockade increased the percentage of TetH60+ cells that produced IFN-γ but did not blunt the upregulation of Tim-3 or TIGIT (Fig. 6h, i).
α-CD40 at time of transplantation improves GVL
Given how effectively FGK45 promoted the activation of TMH60 infused on day +14, we tested FGK45 in combination with TMH60 infused on day 0 in the C3H.SW→B6.H60 system. Day 0 FGK45 dramatically reduced BC-CML numbers in spleen and BM at day +21, coincident with an increase in the number of BM TetH60+ cells (Fig. 7a, b). FGK45 increased IFN-γ production by TetH60+ cells with fewer expressing high levels of TIGIT, PD-1 and Tim-3 (Fig. 7c, d). Consistent with the increase in IFN-γ+ cells, MHCII expression was higher in BC-CML cells harvested from FGK45-treated mice (Fig. 7e).
FGK45 primarily acted on recipient cells as there was no reduction in GVL in recipients of CD40−/− BM (Fig. 7f). It was possible that FGK45 increased direct presentation of Kb:LTFNYRNL; alternatively or in addition it could have improved cross-presentation. To address this, we made mixed BM chimeras in which recipient APCs could directly present H60 ([B6.H60 + B6]→B6 chimeras) or only cross-present H60 ([B6.H60 Kb−/− + B6]→B6 chimeras). After 8 weeks, these chimeras were reirradiated and retransplanted with B6 CD40−/− BM and B6 TMH60, with or without FGK45 (design, Supplementary Fig. 6A). FGK45 only augmented the TetH60+ response in the (B6.H60 + B6)→B6 chimeras in which H60 was directly presented whereas there was no effect in (B6.H60 Kb−/− + B6)→B6 chimeras wherein FGK45 could only promote H60 cross-presentation by B6 Kb-intact APCs (Fig. 7g). Nonetheless, TetH60+ cells ultimately expanded even in the (B6.H60 Kb−/− + B6)→B6 chimeras, confirming that cross-presentation does take place16. With only H60 cross-presentation, markers of exhaustion were reduced, suggesting that the intensity of miHA exposure drives exhaustion (Supplementary Fig. 6B, C).
Although recipient DCs are not required for GVHD in models wherein host hematopoietic cells are essential29,30, it was possible that FGK45’s activity was reliant on DCs. To test this we first crossed B6.H60 mice to B6 CD11c-DTR mice24 and then made B6.H60 CD11c-DTR→B6 Kb−/− BM chimeras in which the only host cells that can present H60 are derived from the B6.H60 CD11c-DTR BM. These chimeras were DT- or PBS-treated, reirradiated, and transplanted with C3H.SW BM and TMH60, with or without FGK45. FGK45 augmented the TetH60 response in both PBS- and DT-treated mice (Fig. 7h). Nonetheless, DT-treated mice that received FGK45 generated modestly fewer TetH60+ cells, suggesting that DCs, though not required, are FGK45 targets.
While an ideal target miHA would be hematopoietically-restricted, as is H60, some miHAs may also be expressed in other tissues. We previously showed that TMH60 cause little GVHD even in B6 actH60 mice, which express H60 ubiquitously driven by an actin promoter18. We therefore explored the impact of FGK45 on TMH60 and on GVL in actH60 recipients. Irradiated actH60 mice were reconstituted with C3H.SW BM, C3H.SW TMH60 and B6.H60 BC-CML. One group was treated with FGK45 on day 0 and mice were sacrificed on day 18. FGK45 dramatically reduced the number of BC-CML cells in BM and spleen (Fig. 7i). While the number of TetH60+ cells was not increased, there was an increase in the IFN-γ+ fraction in spleen and a reduction of TIGIT expression in both spleen and BM, indicative of improved T cell fitness (Fig. 7j–l).
We next focused on how day 0 FGK45 alters TetH60+ T cell activation (design, Supplementary Fig. 7A). By day +3, TetH60+ cells from FGK45-treated mice had increased expression of CD25, 4-1BB, GITR and OX40 (Fig. 8a). At day +4, a greater fraction had diluted CFSE (Fig. 8b). However, a greater fraction of TetH60+ cells from FGK45-treated mice were annexin V+ and 7-AAD+ (Fig. 8c), suggesting that increased proliferation primarily drives the FGK45 effect. By days +7 and +14, FGK45 treatment yielded a 5-10-fold increase in TetH60+ cells with no change in their IFN-γ production (Fig. 8d). However, TetH60+ cells from FGK45-treated mice had lower expression of PD-1, Tim-3 and TIGIT, with an increase in EomeslowTbethigh cells (Fig. 8e, f and Supplementary Fig. 7B, C) that have been reported to have a greater proliferative capacity31.
Exhaustion of naïve alloreactive progeny
We used donor TMH60 in our experiments so as we could track all GVL-inducing T cells. While TCM share much with naïve T cells (TN), we also explored exhaustion and the impact of FGK45 on H60-reactive progeny of CD8+ TN. Irradiated B6.H60 mice were reconstituted with C3H.SW BM and CD8 cells from unvaccinated donors. One group received FGK45 on day 0 and mice were sacrificed on days +7 and +14 for analysis. Although we did not sort TN, spontaneous TM do not mount an anti-H60 response18; therefore, all TetH60+ cells were derived from TN. By day +7, FGK45 increased TetH60+ cells in spleen and BM by ~100-fold (Fig. 9a, b). By day +14, there were more TetH60+ cells in spleen but not in BM (Fig. 9c). FGK45 reduced, but did not prevent, alloreactive T cell exhaustion. In spleen, IFN-γ production was similarly low in both groups; however, at day +14 more IFN-γ+TetH60+ cells were present in the BM of FGK45-treated mice. Consistent with this, FGK45 reduced the expression of PD-1, TIGIT and Eomes on TetH60+ cells.
FGK45 also had a strong effect on TetH60- cells in recipients of CD8 cells from unmanipulated C3H.SW donors (Supplementary Fig. 8). At day +7, FGK45 had increased the number of TetH60- CD8 cells in both BM and spleen more than 10-fold, coincident with a large increase in the fraction of cells that expressed PD-1, TIGIT and Tim-3. By day +14, the numbers of TetH60- CD8 cells were more similar in FGK45-treated and untreated mice as were the frequencies of cells expressing PD-1, TIGIT and Tim-3. Taken in the context of the increase of H60-reactive cells in the same FGK45-treated mice, these data suggest that FGK45 also accelerated the proliferation of donor CD8 cells reactive against miHAs other than H60.
FGK45 also promoted GVL mediated by H60-reactive progeny of CD8+ TN. To assure that only H60-reactive T cells mediated GVL we used the B6→B6.H60 system. Irradiated B6.H60 mice were reconstituted with B6 BM and CD8 cells and B6.H60 BC-CML, with or without FGK45. FGK45 reduced the number of BC-CML cells and increased the number of TetH60+ CD8 cells (Fig. 9d). FGK45 decreased the expression of TIGIT and Eomes on TetH60+ cells, suggestive of improved T cell fitness. While the fractions of IFN-γ+TetH60+ cells were similar in untreated and FGK45-treated mice, BC-CML MHCII expression was higher in FGK45-treated mice, indicative of greater in vivo IFN-γ exposure.
FGK45 similarly improved GVL mediated by CD8 cells responsive against miHAs other than H60. Irradiated B6 mice were reconstituted with B6 BC-CML and C3H.SW BM and CD8 cells. One group was treated with FGK45 on day 0. At day +18, FGK45 reduced BC-CML cells in spleen and BM by ~100-fold. While we could not track CD8 cells targeting a specific miHA, FGK45 increased the IFN-γ+ fraction of CD8 cells and reduced the frequency of CD8 cells with an exhaustion phenotype (Fig. 9e).
TOX+ and TCF-1+ alloreactive T cells develop post-transplant
We also explored whether the sustained availability of alloantigen in the transplant environment induces expression of TOX, a transcription factor recently shown to contribute to T cell exhaustion32,33,34,35,36,37. We further investigated whether a TCF-1+ subpopulation of TetH60+ cells emerged. Such cells have been proposed as precursors of exhausted T cells32,34,35,36,37,38,39.
Irradiated B6.H60 mice were reconstituted with C3H.SW BM and CD8 cells from either unmanipulated C3H.SW donors (referred to as TN) or TM from H60-vaccinated C3H.SW mice (TN). Cohorts were also injected with FGK45. TOX was uniformly induced in all TN or TMH60-derived TetH60+ cells in spleen (Fig. 10a, b; Supplementary Fig. 9A) and BM (Supplementary Fig. 9B), with higher TOX MFIs in TMH60 progeny. TOX expression correlated with PD-1 levels and TetH60 binding. FGK45 reduced TOX MFIs, especially in spleen, and reduced the frequency of TetH60+ cells with high MFIs for both TOX and PD-1 (Fig. 10b and Supplementary Fig. 9B). TOX expression in TN-derived TetH60-negative cells was bimodal, with discrete populations of PD-1highTOXhigh and PD-1lowTOXlow cells (Supplementary Fig. 9C, D). FGK45 increased the frequency of TetH60-PD-1highTOXhigh cells in spleen, perhaps by enhancing alloreactive CD8 cell expansion.
TetH60+TCF-1+ cells emerged in all groups by day + 7 (Fig. 10c, d; Supplementary Fig. 9E, F). These were CD39low with lower expression of KLRG-1, Tim-3, and PD-1 and higher expression of Ly108 (slamf6), relative to TCF-1− cells. This phenotype closely matches that of CD8+ T cells identified as precursors for exhausted T cells in chronic LCMV infection and in tumor models34,35,36,37,39. CD39−TCF-1+ cells comprised a smaller fraction of TetH60+ progeny of TMH60 than of TetH60+ progeny of CD8 cells from unvaccinated donors, and this frequency was not affected by FGK45, suggesting that TN may be more prone to develop into TCF-1+ cells. In contrast, FGK45 reduced the fraction of TN-derived TetH60+ cells that were CD39−TCF-1+ perhaps by reducing antigen exposure by creating a more effective response. In TN-recipients a substantial fraction of TetH60-negative cells also differentiated into TCF-1+ CD39lowKLRG1lowTIM3lowLy108highPD-1low cells (Fig. 10e, f). It is likely that these cells were alloreactive and that the generation of TCF-1+ cells is not restricted to those reacting to H60.
Discussion
A barrier to reducing leukemia relapse post-alloSCT has been an incomplete understanding of the mechanisms of GVL failure. Polyclonal T cell systems and human studies have been limited by the inability to track GVL-inducing T cells, which we addressed by developing a model wherein GVL is exclusively mediated by a defined population CD8 cells reactive against H60. This permitted us to unambiguously identify and manipulate these cells to test hypotheses on the mechanisms underlying leukemia relapse. We found that GVL was limited by both ineffective antigen presentation and the development of T cell exhaustion. Importantly, we demonstrate clinically applicable strategies that enhance antigen presentation, diminish exhaustion and, critically, augment GVL. And we for the first time describe the development of TCF-1+ alloreactive T cells derived from both TM and TN, which could be the precursors of terminally differentiated exhausted T cells, which may fuel alloimmune responses that persist with chronic antigen.
As recipient hematopoietic cells were eliminated, effective antigen presentation declined despite a growing mass of H60-bearing BC-CML cells which, rather than stimulating T cells, contributed to their exhaustion. Antigen presentation was improved by FGK45 and DEC-H60 immunization acting through donor DCs. It was surprising that leukemia-derived antigen was so ineffectively cross-presented, even when leukemia cell death was induced by alloreactive donor CD4 cells. In contrast, caspase-9-induced leukemia apoptosis timed with T cell infusions and FGK45 improved antigen presentation and alloreactive T cell activation. In sum these data highlight strategies to enhance the efficacy of donor leukocyte infusions, which as currently applied, have limited efficacy.
However, even with vaccination or induction of leukemia apoptosis, there was less expansion of TMH60 infused at day 14 than of TMH60 infused at day 0. This highlights how conducive the peri-transplant period is for T cell activation, an environment that was further improved by FGK45. The principle impact of day 0 FGK45 was to increase H60-reactive T cell division driven by recipient APCs directly presenting H60. CD40 engagement on APCs upregulates MHCI, CD80 and CD86 and ligands for the TRAF-binding TNF-receptor family members 4-1BB, OX40 and GITR40,41,42, which we found to be upregulated on TetH60+ cells from FGK45-treated mice. IL-2Rα expression was also increased on TetH60+ cells. In sum, these effects could have created a feed-forward process that drove expansion of TetH60+ cells. CD40 activation also promotes DC survival43 which could have prolonged direct presentation of H60 by host APCs. Further delineation of the relative impacts of each of these mechanisms will be the subject of future work.
T cell exhaustion and a role for PD-1 in suppressing alloreactive T cell responses have been previously reported12,44,45,46,47,48,49,50. However, unlike most prior work, we were able to specifically track alloreactive T cells, and in GVL models, those that definitively mediate GVL. This enabled us to make additional contributions towards understanding exhaustion and how to mitigate it. Exhausted TetH60+ cells expressed high levels of Eomes and Blimp-1 and lost mitochondrial mass and mitochondrial membrane potential. Taken together, the phenotypic, transcription factor and metabolic features of exhausted T cells in our experiments suggest that alloreactive T cell exhaustion in alloSCT is similar to that in chronic viral infections17,27,31,51, which is driven by antigen exposure. Consistent with this, BC-CML increased exhaustion via direct antigen presentation and not through expression of PD-L1/L2. We also add to prior studies by demonstrating that PD-1 is the dominant inhibitory checkpoint as blockade of Tim-3, TIGIT and LAG3 did not augment GVL, though LAG3-blockade increased the fraction of TetH60+ cells that produced IFN-γ, consistent with studies in chronic viral infection52.
We also for the first time demonstrate the generation of TCF-1+ miHA-reactive T cell progeny of both CD8+ TN and TMH60. These cells share phenotypic properties of TCF-1+ precursors of exhausted cells described in other models wherein there is also sustained antigen presentation, including being CD39lowTIM-3lowLy108+32,34,35,36,37,38,39. In our experiments their frequency was reduced by FGK45 administration, suggesting that by boosting the alloresponse, FGK45 accelerated H60 clearance. It is tempting to hypothesize that these TCF-1+ cells are important for GVHD maintenance, just as they sustain antiviral and antitumor responses. That alloreactive TMH60 progeny were less likely to develop into TCF-1+ cells could in part explain why TM induce less GVHD. These questions will need to be addressed in future studies.
Our studies suggest clinically applicable strategies for improving T cell immunotherapies. We targeted a hematopoietically-restricted miHA, a class of antigens which has been suggested to be ideal immunotherapy targets5,20,21 as CD8 cells that recognize these do not cause GVHD53. Our results are also applicable to T cell immunotherapies that target other types of antigens that are restricted to hematopoietic or leukemia cells54,55,56,57,58,59. MiHA-specific T cells are most potent when given at the time of transplant, when miHAs can be directly presented by recipient APCs. Their effect is augmented by early PD-1 blockade, and more dramatically, by anti-CD40, which we found to be safe and which has been used in the clinic60,61. This is in contrast to safety-driven designs wherein T cells are infused remote from transplant when the major source of hematopoietic antigen is leukemia cells, which we demonstrate promote exhaustion and which are poor sources of cross-presented antigen. If anti-leukemia T cells are infused remote from transplant or when antigens are restricted to leukemia cells, their efficacy would be enhanced by antigen immunization with anti-CD40 as an adjuvant. This approach may also improve the efficacy of adoptive T cell immunotherapies against solid tumors, wherein professional APC presentation of neoantigens is likely to be very limited62. In patients with overt leukemia an alternative to immunization would be therapies that spare T cells but lead to rapid leukemia apoptosis to promote cross-presentation, such as gemtuzumab, an anti-CD33 immunotoxin63.
Methods
Mice
C57BL/6J (CD45.2; H-2b), B6.SJL-Ptprca Pepcb/BoyJ (CD45.1, H-2b), B6 CD11c-DTR24, B6 CD40−/−, B6 beta-2-microglobulin-deficient (β2M−/−), B6 ubiquitin-GFP transgenic and B6 RAG−/− and C3H.SW (H-2b; H60−) mice were purchased from Jackson Labs (JAX) and were bred at the University of Pittsburgh (Pitt). B6 Kb−/− mice were purchased from Taconic. OT-1 RAG1−/− and B6-Rag2tm1Fwa II2rgtm1Wjl (RAG2−/−γc−/−) mice were provided by Fadi Lakkis (Pitt). B6.H60 mice were originally obtained from Derry Roopenian (JAX) and were bred at Pitt. B6.H60Kb−/− and B6.H60-CD11c.DTR mice were generated at Pitt. C3H.SW CD45.1+ mice were generated by crossing C3H.SW mice to B6.CD45.1+ mice (>10 generations). Animal breeding and experiments were performed in a specific pathogen-free animal facility in compliance with a protocol approved by Institutional Animal Care and Use Committee of the University of Pittsburgh, and we complied with all the ethical regulations.
Leukemia induction
BC-CML cells were generated as previously described25. Briefly, BM from 5FU-treated mice underwent two rounds of spin-infection with two MSCV2.2-based retroviruses—one encoding bcr-abl (coexpressing a nonsignaling human nerve growth factor receptor; NGFR) and a second expressing the NUP98/HOXA9 fusion cDNA (co-expressing GFP). iCasp9 B6.H60Kb−/− BC-CML was generated by spin-infection of B6.H60Kb−/− BM with bcr-abl and NUP98/HOXA9 retrovirus with an additional retrovirus encoding an iCasp-9 inducible suicide gene linked via a cleavable 2A-like sequence to a truncated human CD19 marker gene26 (gift from Cliona M. Rooney; Baylor College of Medicine). Multimerization and activation of iCasp9 was achieved by in vivo treatment with AP20187 (Clontech).
Vaccination
To create CD8+ H60-reactive memory T cells (TMH60) or effectors (Teff), C3H.SW or B6 background mice were injected with 50 μg anti-DEC205-H60 (a construct encoding an antibody against DEC-205 modified to express the LTFNYRNL epitope from H60;18 laboratory-prepared) and 50 μg of an agonist antibody against CD40 (FGK45; laboratory-prepared). TMH60 were harvested 3 months after vaccination. To generate OT-1 Teff, B6 mice were injected with 50 μg anti-DEC-OVA16 (laboratory-prepared) and 50 μg FGK45 after adoptive transfer of 105 OT-I Rag1−/− splenocytes.
Cell purifications
T cell purifications from lymph node (LN) and spleen cells were performed using EasySep negative selection reagents according to the manufacturer’s instructions (StemCell Technologies). Cell purities were >90% with <2% of contaminating CD4 cells. CD8+ memory T cells (TM) were isolated from H60-vaccinated mice by first using EasySep CD8 negative selection kit. Cells were then stained with antibodies against CD8 and CD44, followed by sorting on a FACS Aria (BD-Biosciences). Donor BM in all experiments was depleted of T cells using anti-Thy1.2 microbeads (EasySep) and is referred to as BM.
Bone marrow transplantation
All transplants were performed according to IACUC-approved protocols. All irradiation was from a cesium source. B6.H60 mice were irradiated with 900 cGy and reconstituted with 5 × 106 C3H.SW or B6-background BM cells, TMH60 from C3H.SW or B6 mice, with or without BC-CML cells. TMH60 were not sorted for TetH60+ cells. 200 μg of anti-NK1.1 (PKC136; lab-prepared) was given i.p. on days -2 and -1 in experiments with Kb−/− BC-CML to diminish NK cell-mediated killing of Kb− cells. In some experiments, fresh congenic TMH60 were transferred to recipient mice at day +14 post BMT, following treatment with DEC-H60 (50 μg/mice), FGK45 (50 μg/mice) or both.
BM chimeras
To create B6.H60 CD11c.DTR→B6 Kb−/− BM chimeras, B6 Kb−/− mice received 2 × 500-cGy fractions (separated by 3 h) followed by reconstitution with 107 B6.H60+/−CD11c.DTR+/− BM. To create mixed BM chimeras, donor BM from B6.H60Kb−/− or B6.H60 mice were mixed in a 1:1 ratio with B6 BM to reconstitute irradiated B6 mice. Donor BM reconstitution was verified 8 weeks after transplantation by flow cytometric analysis of peripheral blood.
In vivo CTL assay
To create BC-CML that had escaped a GVL response, B6.H60 mice were irradiated and reconstituted with C3H.SW BM, B6.H60 BC-CML and C3H.SW TM containing 104 TMH60. When relapsed BC-CML was harvested more than 50% of splenocytes were BC-CML cells. Fresh BC-CML cells were isolated from irradiated B6.H60 mice that were reconstituted with B6.H60 BC-CML and C3H.SW BM alone. Fresh and relapsed BC-CML cells were subjected to in vivo CTL assays as follows. To test killing directed against H60, fresh and resistant H60+ BC-CML and negative control H60−kb−/− BC-CML were injected i.v. into B6 mice that had been vaccinated 7 days prior with DEC-H60 and FGK45. To test killing directed to SIINFEKL, B6 mice were seeded with OT-1 cells followed by vaccination with DEC-OVA and FGK45. Seven days later, fresh and relapsed BC-CML cells that were or were not pulsed with SIINFEKL were injected into OT-1-seeded or unmanipulated B6 mice. Different BC-CML cells were distinguished by cell trace violet (CTV) and cell tracker DeepRed (CTR; ThermoFisher) staining. Mice were sacrificed 18 h later for BC-CML enumeration.
Tetramer, antibodies, and other reagents
H60 tetramers were produced by the NIH tetramer facility. Antibodies (Ab) and sources are as follows. Antibodies specific for CD44 (IM7), CD62L (MEL-14), CD45.1 (A20), CD45.2 (104), CD11b (M1/70), H2-Kb(AF6-88.5), I-A/I-E (M5/114.15.2), ICAM-1 (YN1/1.7.4), PD-1 (29F.1A12), Tim-3 (RMT3-23), TIGIT (1G9), 4-1BB (17B5), OX-40 (OX-86), IL-2Rα (PC61), TNF-α (MP6-XT22) KLRG1 (2F1), Ly108 (330-AJ) and Blimp-1 (5E7) were from BioLegend. GITR (DTA-1) and IFN-γ (XMG1.2) were from BD Biosciences. Eomes (Dan11mag), T-bet (4B10), TOX (TXRX10) and CD39 (24DMS1) were from ThermoFisher. CD8α (53-6.7) was laboratory prepared. LAG3 (4-10-C9) was provided by Dario Vignali and Creg Workman (Pitt).
Propidium iodide (Sigma) or Fixable Viability Dye eFluor 780 (ThermoFisher) were used to exclude dead cells. T cell restimulations were performed using the H60 peptide LTFNYRNL (Genescript) for 5 h. GolgiStop (BD Biosciences) was added for the final 3 h. Intracellular cytokine staining was performed using the BD Cytofix/Cytoperm kit. Transcription factor and Annexin V staining was performed using the FoxP3 staining (ThermoFisher) and Annexin V (BioLegend) kits, respectively. For metabolism assays cells were pulsed with 50 mM 2-NBDG (ThermoFisher) in FBS-free media for 30 min at 37 °C. Cells were surface stained and loaded with MitoTracker DeepRed or TMRE (ThermoFisher). For antibody blocking experiments, BC-CML-bearing mice were injected with 200 μg/mouse αPD-1 (RMP1-14, BioLegend), 200 μg/mice αLAG3 (C9B7W;64 gift of Dario Vignali and Creg Workman), 200 μg/mice αTim-3 (RMT3-23, BioLegend), 500 μg/mice αTIGIT (10A7, Genentech) or respective murine or rat isotype controls (BioXCell), i.p. three times per week for 2 weeks starting from day 7 post BMT. Diphtheria toxin (DT) was from List Biological Laboratories. Flow cytometry was performed on a BD LSR II (BD) and data was analyzed using FlowJo (v10.5.3).
Statistical analysis
Bars on scatter plots are mean values. Statistical significance was calculated using an unpaired Student two-sided t-test (GraphPad Prism) except in CTL assays wherein a paired two-sided t-test was employed to compare fresh and relapsed BC-CML cells in the same mice.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
The authors declare that all of the data supporting the findings of this study are available within the paper and its supplementary information files. Raw data are included in the Source data file. Source data are provided with this paper.
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Acknowledgements
This work was supported by R01 HL117855 with additional support from the UPMC Hillman Cancer Center and the UPMC Immune Transplant and Therapy Center. We also thank the animal technicians at the University of Pittsburgh for their diligent care.
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W.D.S. conceived of experiments, analyzed data and wrote the paper. M.Z. conceived and executed experiments, analyzed data and wrote the paper. F.S. provided technical advice and performed experiments. K.Z. and S.R. assisted in performing experiments.
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W.D.S. declares that he is a founder, shareholder and consultant for BlueSphere Bio. The other authors declare no competing interests.
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Zhou, M., Sacirbegovic, F., Zhao, K. et al. T cell exhaustion and a failure in antigen presentation drive resistance to the graft-versus-leukemia effect. Nat Commun 11, 4227 (2020). https://doi.org/10.1038/s41467-020-17991-y
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DOI: https://doi.org/10.1038/s41467-020-17991-y
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