Correspondence to Dr Leonid S Metelitsa; [email protected]

Insights

We report a case of lethal non-clonal hyperleukocytosis in a neuroblastoma patient treated on a phase 1 trial (NCT03294954) with autologous natural killer T cells (NKTs) expressing a GD2-specific chimeric antigen receptor and IL-15 (GD2-CAR.15) that may have been caused in part by overstimulation of NKTs with K562-based artificial antigen-presenting cells during manufacture.

Introduction

Neuroblastoma (NB) is one of the most common and deadly pediatric solid tumors with half of patients presenting as high-risk and only half of these cases remaining in remission long-term. The GD2 disialoganglioside is expressed at high levels in most NB tumors and has been validated as a therapeutic target for antibody-mediated immunotherapy.¹ GD2-specific CAR T cells have also been shown to mediate objective responses without causing significant toxicity in early-stage clinical trials.² In a recent interim analysis, we described the first clinical evaluation of natural killer T cells (NKTs), a sub-lineage of innate-like T cells, engineered to express a GD2-CAR and cytokine interleukin (IL)-15 (GD2-CAR.15) to treat children with relapsed/refractory NB (GINAKIT2, NCT03294954, online supplemental file 5).³ Results from the first 12 patients in this trial showed that GD2-CAR.15 NKTs are well tolerated and mediate a 25% objective response rate in heavily pretreated NB patients receiving up to 1×10⁸ GD2-CAR.15 NKTs/m² at dose level (DL) 4.³ Subsequently, the first patient treated on DL5 (3×10⁸ GD2-CAR.15 NKTs/m²) developed hyperleukocytosis with resulting multi-organ failure and eventual death. Here, we describe clinical and pathological manifestations of this unusual toxicity and present a root-cause analysis at the cellular and molecular level.

Case description

Patient P5-1 (DL5-patient 1) had relapsed/refractory, high-risk stage M (4) NB and underwent induction and consolidation for upfront therapy followed by four salvage regimens for refractory NB prior to enrollment on the GINAKIT2 study. At the time of enrollment, this patient’s disease involved multiple cranial bone lesions and retroperitoneal mass with a Curie score of 3. After meeting eligibility criteria, the patient was enrolled on DL5 and underwent lymphodepletion with cyclophosphamide and fludarabine followed by infusion of GD2-CAR.15 NKTs on day 0.

Patient P5-1 was admitted from day 0 to day 4 for fever that improved with supportive management (figure 1A); this admission was attributed to metapneumovirus infection unlikely related to GD2-CAR.15 NKTs. The patient was re-admitted on day 5 for fever that was initially managed with supportive measures. On day 7, tocilizumab was administered then anakinra on day 8 for cytokine release syndrome (CRS). The patient became afebrile on day 12 but exhibited nystagmus-like eye movements with EEG negative for seizure on day 11. Brain MRI showed enlargement of bony NB metastases concerning for progression versus pseudo-progression. On day 13, patient P5-1 developed strabismus and involuntary upward gaze and was started on 0.2 mg/kg q6h dexamethasone intravenously for possible immune effector cell-associated neurotoxicity syndrome.

On day 14, a significant increase in white cell count was noted (figure 1B) with drastic increases in absolute lymphocyte counts and ferritin level (figure 1C,D). C reactive protein level was initially elevated and decreased after tocilizumab and anakinra treatment (figure 1E). By day 16, the patient developed symptoms resembling sinusoid obstruction syndrome of the liver (attributed to leukostasis) with fluid retention, weight gain, and decreased renal function. On day 17, patient P5-1 was transferred to the intensive care unit due to progressively worsening hyperleukocytosis. The patient’s overall condition rapidly deteriorated, requiring intubation for mechanical ventilation and blood pressure support with epinephrine, norepinephrine, and vasopressin (figure 1F). Leukapheresis was performed on day 18 with moderate improvement in white cell count. Despite maximum cardiopulmonary support, the patient’s condition continued to deteriorate, and the family elected not to escalate care further. The patient died later on day 18. An autopsy confirmed hyperleukocytosis-driven, multi-organ, extensive vascular occlusion and infiltration by T and NK cells (antibody to distinguish NKT from T cells was not available in the pathology panel) (figure 1G, top and middle). Evaluation of residual tumors showed ganglional differentiation and absence of poorly differentiated neuroblasts, consistent with therapeutic response (figure 1G, bottom).

During the initial CRS event, several cytokines were elevated compared with baseline (day −4) including IL-1α/β, IL-2, IL-6, IL-7, IL-17α, IL-9, IL-10, IFNγ, IL-15, MIP1α/β, and TNFα. By day 14, the cytokine profile had changed with several previously elevated cytokines such as IL1α/β, IL-2, IL-7, and IL-9 showing decreased concentrations while others including IL-6, IL-15, IFNγ, MIP1α/β, and TNFα continued to increase. The highest absolute cytokine concentrations were detected for CXCL10, MCP1, TNFα, GRO, and MDC, and the greatest fold-change for FLT-3L, IL-15, IL-6, MIP1α, and TNFα (figure 1H). Several analytes including IL-15, CXCL10, TNFα, MIPα/β, IFNγ, and GM-CSF were detected at higher levels in this patient compared with mean concentrations in the first 12 patients (figure 1I).

Flow cytometry assessment of blood samples showed a rapid increase in CAR+ and CAR− populations of NKT, NK, and T cells beginning on day 14 (figure 1J,K). Notably, we observed a striking increase in CAR+ NK and γ/δ T cell numbers in day 14 peripheral blood mononuclear cells (PBMCs) compared with low levels in the pre-infusion product (online supplemental figure). Our analysis showed that this patient’s infusion product had similar levels of NKT purity and CAR expression as well as populations of contaminating CAR+ T and NK cells compared with products from the 12 other patients (online supplemental figure 2A). However, the striking expansion of NKT, NK, and T cells that occurred in the peripheral blood of patient P5-1 was not observed in the other patients (online supplemental figure 2B,C). These results indicate robust polyclonal lymphocyte expansion post-infusion with the greatest proportional increase in CAR+ NK and γ/δ T cell populations.

Next-generation exome sequencing analysis of the pre-infusion product, peripheral blood, and skin samples did not identify any variants of clinical significance in 79 genes known to be associated with various cancers (online supplemental table 1), suggesting that the hyperleukocytosis that occurred in this patient was unlikely the result of a known underlying genetic disorder. To assess clonality based on gamma-retroviral transgene integration sites, pre-infusion cells and PBMCs collected on days 14 and 17 were assessed using the SonicLength method at the University of Pennsylvania Viral/Molecular High Density Sequencing Core.^4–6 The pre-infusion product showed a high degree of heterogeneity with >1000 unique transgene integration sites. As the lymphocyte population that expanded the most, the CAR+ NK subset was determined to be non-clonal as the clone with the most frequent transgene integration sites was detected at only <0.6% (online supplemental figure 3A). Additionally, CAR+ NKT and CAR+ T subsets did not show evidence of clonal expansion (online supplemental figure 3B,C), thus excluding the possibility that the hyperleukocytosis event was driven by expansion of clonal cells. To determine whether IL-15 secretion by cells in the pre-infusion product contributed to this event, we challenged the products with tumor cells in vitro and found that P5-1 cells produced comparable levels of IL-15 (average 84.27 pg/mL/10⁵ cells, SD 3) to healthy donor NKTs transduced with the same construct as previously reported (range 83.3–177.6 pg/mL/10⁵ cells),⁷ suggesting that IL-15 overproduction was unlikely the cause of the aggressive cell expansion in patient P5-1.

Patient P5-1 was the first to be treated on DL5 and the first to receive CAR NKTs that underwent secondary stimulation with K562-based A4-4 artificial antigen-presenting cells (aAPCs) instead of the NKT-depleted fraction of autologous PBMCs; all other culture conditions remained the same between the two protocols. The manufacturing protocol (online supplemental file 4) was originally amended to use aAPCs to ensure the presence of sufficient stimulatory cells for large numbers of NKTs and to provide optimal stimulation for superior NKT functionality and antitumor activity as demonstrated in preclinical models.⁸ To evaluate the potential for autonomous growth, cells from the pre-infusion product of patient P5-1 were thawed and cultured for 3 weeks without additional antigen stimulation or exogenous cytokines. The cells underwent a burst of expansion and growth stabilized after day 14 (figure 2A). We also observed an outgrowth of NK cells after 11 days in culture (online supplemental figure 4).

Such expansion without exogenous cytokine support was not observed in pre-infusion products from previously treated patients that underwent either primary or primary and secondary stimulations with autologous PBMCs. However, three other products that were manufactured with aAPC secondary stimulation but have not been infused did undergo expansion in this assay (figure 2A). In one case, two different products were manufactured from a single patient, one with aAPC and one with PBMC secondary stimulation; a burst of expansion was only observed in the aAPC-stimulated product (figure 2B).

Next, CAR NKT products were manufactured from 12 healthy donors using either PBMCs or aAPCs for secondary stimulation. Only aAPC-stimulated CAR NKTs significantly expanded ex vivo, and this expansion was observed with the cells that were cryopreserved at early but not later timepoints (2 or 4 days vs 10 days post-stimulation) (figure 2C, online supplemental figure 5). Additionally, IL-15 levels were significantly higher in the culture of aAPC-stimulated versus PBMC-stimulated CAR NKTs (figure 2D). Collectively, these results suggest that using aAPCs for secondary stimulation of CAR NKTs contributes to transient ex vivo proliferation in the absence of exogenous cytokines, which may have enabled the extensive hyperleukocytosis seen in this patient.

Single-cell RNA sequencing of the aAPC-stimulated pre-infusion product from patient P5-1 revealed distinct gene expression clusters compared with products that underwent secondary stimulation with autologous PBMCs (patients P1-1, P1-2, P2-3, and P3-1). P5-1 cells were depleted for expression of genes in clusters 1 (NKT2 in G1 phase) and 2 (NKT2 mitotic phase) and enriched for genes in clusters 3 (NKT1 mitotic phase), 6 (NKT17 mitotic phase), and 7 (NKT1 S phase)⁹ (figure 2E, online supplemental table 2). This expression pattern differed from that of patients P1-1, P1-2, P2-3, and P3-1, whose products were more similar to each other. Cell cycle scoring indicated a bimodal distribution of cells in S phase for patient P5-1, with subpopulations of cells in clusters 3, 6, and 7 expressing high levels of proliferation-associated genes (figure 2F). Higher expression levels of BATF3 and TYMS in patient P5-1’s product indicate a memory-like phenotype and greater proliferative potential (online supplemental figure 6A). Additionally, lower levels of CD69 and IL2RA and higher levels of HLA-DRA and HLA-DRB5 suggest a later stage of activation in patient P5-1’s cells versus other patients (online supplemental figure 6B,C). These findings show that patient P5-1’s product has a distinct gene expression profile consistent with high proliferative potential and sustained activation.

Discussion

We report a case of a NB patient who developed hyperleukocytosis after GD2-CAR.15 NKT administration on a phase 1 clinical trial. Our root-cause analysis revealed no genetic alterations of known clinical significance and excluded the possibility of clonal expansion due to insertional mutagenesis. Based on our findings that aAPC- but not PBMC-stimulated CAR NKTs derived from both NB patients and healthy donors undergo a burst of ex vivo expansion when cultured in the absence of exogenous cytokines, we propose that stimulation of NKT and NK cells with A4-4 aAPCs may have led to stochastic activation of lymphocytes in patient P5-1’s product such that an initial burst of CAR NK/NKT proliferation was generated. This proliferation was potentially amplified following in vivo exposure to tumor antigen, resulting in a positive feedback loop of expansion and production of transgenic IL-15, which on reaching a critical systemic level fueled further expansion of IL-15-sensitive NK, γ/δ T, CD8 T, and NKT cells regardless of CAR expression.

The A4-4 clone was derived from K562 and specifically selected for stimulation of CAR NKT products manufactured for this trial based on its ability to mediate optimal stimulation and expansion of human NKT cells through expression of CD1d^med, CD86^high, 4-1BBL^med, and OX40L^high.⁸ K562-based aAPCs have been employed in other studies to expand multiple types of immune effector cells including NK and T cells,^{10 11} and this is the first clinical observation of potential aAPC-associated lymphoproliferation and lethal toxicity. The singularity of this event among the many patients who have been infused with aAPC-activated T or NK cell products suggests that it may be unique to this specific patient. Additionally, cytokine armoring is a common strategy for enhancing the efficacy of T- and NK-based therapeutics against multiple malignancies,^{12 13} and it warrants careful preclinical and clinical monitoring for severe toxicities. For example, CAR NK cells expressing IL-15 have been reported to cause toxicity in preclinical AML models.¹⁴ However, IL-15 levels secreted by patient P5-1’s product measured within an acceptable range and therefore cannot explain the triggering event that led to initial expansion of the infused cells. Instead, after accumulating systemically, IL-15 likely contributed at a later stage of this event by supporting the growth of both CAR+ and CAR− lymphocytes in patient P5-1, leading to uncontrolled lymphocytosis and toxicity. Alternatively, this hyperleukocytosis event may have been associated with a metapneumovirus infection that occurred in the patient at the time of CAR NKT infusion or an undetected mutation that predisposed the patient to higher IL-15 sensitivity.

Importantly, we did detect evidence of therapeutic response in residual tumors collected from patient P5-1 at autopsy. Our findings warrant the development of measures to control cell activation during manufacture and to regulate or pharmacologically control transgene expression in CAR-based immunotherapy products, particularly those that are cytokine-armed, such that potential clinical benefit can be achieved without toxicity. We found that culturing CAR NKTs for several additional days post-stimulation diminishes the aAPC-induced proliferative boost. Similarly, introduction of “rest” through treatment with the multi-kinase inhibitor dasatinib during manufacture has been reported to control CAR T cell overactivation and exhaustion, increasing therapeutic potential without toxicity.¹⁵ After infusion, safety switches such as inducible caspase 9 can be used to control or eliminate therapeutic cells as needed.¹⁶ Moreover, the next generation of CAR/cytokine constructs may benefit from synthetic regulatory circuits designed to keep engineered immune cell numbers and function within an optimal range to maximize therapeutic potency and minimize toxicity.

To address the findings in this case report, we have developed a mitigation strategy that includes: (1) reinstating autologous PBMCs for restimulation, (2) adding a modified ex vivo antigen-independent growth assay as a release criterion, and (3) increasing patient monitoring post-infusion. Following resumption of the clinical trial, we have treated four patients with PBMC-restimulated CAR NKTs without observing significant toxicity.

The authors are grateful to M Brenner, H Heslop, and B Grilley who serve as IND sponsors on this study and provide regulatory support and personnel of the cGMP facility at the Center for Cell and Gene Therapy for manufacturing CAR-NKTs. We also thank P Srivaths, director of the Pheresis Service at Texas Children’s Hospital. We are thankful for the excellent technical assistance provided by the staff of the Flow Cytometry Core Laboratory at the Texas Children’s Cancer and Hematology Center and the Single Cell Genomics Core at Baylor College of Medicine.

Ethics statements

Patient consent for publication

Not applicable.

Ethics approval

This study involves human participants and was approved by the Baylor College of Medicine Institutional Review Board (BCM: H-41003). Participants gave informed consent to participate in the study before taking part.

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