Abstract: Donor-recipient incompatibility for human leukocyte antigen (HLA) ligands of killer cell immunoglobulin-like receptors (KIRs) in haploidentical hematopoietic stem cell transplantation (HSCT), has been associated with a selective graft versus leukemia (GvL) effect mediated by donor-derived alloreactive natural killer (NK) cells expressing KIRs whose ligands are missing in the recipient. In this study, we show that NK cells arising from hematopoietic stem cell progenitors after transplantation into haploidentical recipients, acquire a receptor repertoire that is compatible with patient-specific tolerance due to engagement of patient HLA ligands by inhibitory NK receptors. Using four-color immunofluorescence with monoclonal antibodies (mAbs) specific for the receptors CD94/NKG2A, KIR2DL1/2DS1, KIR2DL2/2DL3/2DS2 and KIR3DL1, we have analyzed NK receptor reconstitution kinetics in eleven adult patients affected by acute myeloid (n=9) or lymphoblastic (n=2) leukemia, who underwent HSCT from a KIR ligand matched (n=5) or mismatched (n=6) haploidentical family donor, using high doses (median 12.5x106/kg) of purified CD34+ progenitors. Nine patients achieved long-term ( & gt;150 days) complete remission of disease, independently from disease status at time of transplantation, and, importantly, from the presence (n=5) or absence (n=4) of donor NK alloreactivity. Within the first two months after transplantation, the vast majority (96% at 30 days, 86% at 60 days; SD 2% and 11%, respectively) of NK cells arising in the patients expressed the inhibitory receptor CD94/NKG2A, whose ligand HLA-E is ubiquitously expressed by cells positive for classical HLA class I molecules including leukemic blasts. As shown by mAb inhibition studies, lysis of patient-derived phytohemagglutinin-activated T cell blasts by these early arising NK cells was specifically inhibited by engagement of CD94/NKG2A. KIR expression was restored with variable kinetics in the later post-transplantation phase (3–9 months). Interestingly, however, during this period, NK cells devoid of CD94/NKG2A were found to express at least one KIR specific for an HLA ligand present in the patient, suggesting functional silencing of NK cells arising in the later phases after transplantation by acquisition of specific KIRs. Taken together, these data challenge current broad view on putative antileukemic effect of alloreactive NK cells reconstituting from haploidentical donor CD34+ cells and suggest that optimal exploitation of NK alloreactivity for GvL requires the presence of NK cells matured in the context of the donor’s rather than the recipient’s HLA repertoire. Ultimately, these findings provide a rationale for emerging clinical evidence in favor of efficacy of NK-based immunotherapy with mature donor NK cells.

Abstract: Background Chimeric Antigen Receptor (CAR)-T cell therapy has been successfully clinically deployed in the context of B-cell malignancies, paving the way for further development also in Acute Myeloid Leukemia (AML), a still unmet clinical need in the field of oncohematology. Among the potential AML targetable antigens, CD33 is so far one of the main validated molecule. Objectives The aim of the present study was to optimize a non-viral gene transfer method to engineer Cytokine-Induced Killer (CIK) cells with a CD33.CAR by using a novel version of the Sleeping Beauty (SB) transposon system, named "SB100X-pT4". Further, a preclinical assessment of SB-modified CD33.CAR-CIK cells was performed in chemoresistant AML Patient-Derived Xenografts (PDX), in order to address the unmet need of targeting drug-resistant AML cells. Methods Donor derived-CIK cells were stably transduced with a CD33.CAR by exploiting the novel hyperactive SB100X transposase and the pT4 transposon (SB100X-pT4). The novel SB system has been in vitro compared to the previous established SB11-pT. In vitro anti-AML activity of CD33.CAR-CIK cells was assessed by flow cytometry-based cytotoxicity (AnnV-7AAD), proliferation (CFSE) and cytokine production (intracellular IFNg and IL2 detection) assays. In vivo efficacy was evaluated in NSG mice transplanted with MA9-NRas AML cell line or PDX samples. A xenograft chemotherapy model mimicking induction therapy ("5+3" Ara-C and doxorubicin) was exploited to examine the potential benefit of CD33.CAR-CIK cells on chemoresistant/residual AML cells. Results By significantly reducing the amount of DNA transposase, the novel SB100X-pT4 combination resulted in higher CAR levels than the SB11-pT. SB100X-pT4-modified CD33.CAR CIK cells showed efficient expansion after 3 weeks (median fold increase of 38.89, n=4). Both transpositions conferred to CD33.CAR-CIK cells a specific killing (up to 70%) against CD33+ AML target cell lines and primary AML cells. The anti-AML proliferative response of SB-modified CD33.CAR-CIK cells was also considerable (up to 70% of CFSE diluted CAR-CIK cells), as well as the cytokine production (up to 35% for IFN-γ and up to 25% for IL-2). To evaluate the effect of SB100X-pT4-modified CD33.CAR-CIK cells particularly on Leukemia Initiating Cells (LICs), CD33.CAR-CIK cells were administered as an "early treatment" in mice transplanted with the MA9-NRas cell line, which retains a high frequency of LICs. At sacrifice, CD33.CAR-CIK cell-treated mice showed a significant bone marrow (BM) engraftment reduction (median 27.80 for the untreated group and 22.60 for the unmanipulated CIK cells vs 6.45 for CD33.CAR-CIK cell, n=4 NSG mice per group, p= 0.02). PDX of two different AML samples at the onset were established to be used as models mimicking different disease conditions. In an "early treatment" model using secondary transplanted PDX, a setting which presumably reflects the typical LIC properties, a clear engraftment reduction in the treated cohort was observed, nearly undetectable in 2/5 mice, as compared to the untreated mice (up to 70% in BM). A significant leukemia reduction was also measured in the peripheral blood and spleen of treated mice, showing CD33.CAR-CIK cell potential of reducing AML dissemination in the periphery. When ex vivo re-exposed to CD33.CAR-CIK cells residual AML cells were still sensitive to the treatment, indicating that no resistance mechanisms occurred. CD33.CAR-CIK cells were also effective in a second model by which the treatment started when AML engraftment was clearly manifested in the BM ( 〉 1%). Finally, when starting CD33.CAR-CIK cell treatment after disease recurrence post induction therapy, a significant disease reduction was observed in the CD33.CAR-CIK-treated group, reaching undetectable levels in half of the mice, as compared to chemotherapy-only treated mice (up to 60% of engraftment in BM)(Figure 1). Conclusions The employment of a non-viral SB-based CD33.CAR-gene transfer approach, which is overall associated to less cumbersome protocols and reduces the cost of goods, offers a unique alternative to current viral-based strategies to be explored in the setting of resistant forms of AML. Disclosures No relevant conflicts of interest to declare.

Abstract: Introduction Allogeneic Chimeric Antigen Receptor (CAR) T cells engineered with non-viral methods offer a modality to reduce costs and logistical complexity of the viral process and allow lymphodepleted patients to access CAR T cell treatment. We recently proposed the use of Sleeping Beauty (SB) transposon to engineer donor-derived T cells differentiated according to the cytokine-induced killer (CIK) cell protocol (Magnani CF et al. J Clin Invest. 2021). We report here outcomes on B-cell acute lymphoblastic leukemia (B-ALL) patients, relapsing after transplantation, treated with donor-derived anti-CD19 CAR T cells (CARCIK-CD19). Methods We conducted an academic, multi-center, phase I/II dose-escalation trial in patients relapsed after allogeneic hematopoietic stem cell transplantation (HSCT). The infusion product was manufactured in-house starting from 50 mL of peripheral blood from the HSCT donor by electroporation with GMP-grade plasmids. All patients underwent lymphodepletion with Fludarabine (30 mg/m 2/day x 4 days) and Cyclophosphamide (500 mg/m 2/day x 2 days), before proceeding to CARCIK-CD19 infusion. We used the Bayesian Optimal Interval (BOIN) design to define a four-dose escalation scheme. Primary objectives were to define the Maximum Tolerated Dose (MTD), safety, and feasibility. Secondary objectives included the assessment of complete hematologic response (CR), duration of response (DOR), progression-free (PFS), event-free (EFS), and overall survival (OS). This study was registered at ClinicalTrials.gov, NCT03389035. Results From January 2018 to June 2021, a total of 32 patients were screened, 26 enrolled (6 children and 20 adults) and 21 infused (4 children and 17 adults). Reasons for not receiving infusion included consent withdrawal (N=1), disease progression not controlled by bridging therapy (N=3), acquisition of myeloid phenotype (N=1). The median number of prior therapies was 4 (range, 1-7) with a median time interval from HSCT to relapse of 9 months. The median BM blasts was 60% (range, 5-100%) at enrollment and 7% (range, 0-96%) post lymphodepletion. Of the 21 patients infused, CARCIK-CD19 were obtained by HLA-identical sibling (n=6, 29%), matched unrelated (n= 7, 33%), and haploidentical donors (n=8, 38%). Three patients (14%) received the first dose level of 1x10 6 CARCIK-CD19 cells/Kg, three (14%) the second of 3x10 6, and three (14%) the third of 7.5x10 6 whereas 12 patients (57%) received the fourth and last planned dose level of 15x10 6 cells/Kg, as no dose limiting toxicity (DLT) was observed. CRS was observed in six patients (three grade I and three grade II) and immune effector cell-associated neurotoxicity in two patients at the highest dose. Although 9 out of 21 had experienced acute or chronic graft-versus-host disease (GvHD) after the previous HSCT, secondary GvHD was never induced by CARCIK-CD19. Complete response was achieved by 13 out of 21 patients (61.9%, 95%CI=38-82%) and by 11 out of 15 patients treated with the 2 highest doses (73.3%, 95%CI=45-92%). Eleven of these responders were MRD-negative. Notably, the type of donor did not influence the achievement of CR 28 days post-infusion. At a median follow up of 21.6 months (range, 1.0-38.4 months), 10 patients (47.6%) are alive in CR (9 in the 2 highest dose levels). Overall, the median OS and EFS were 9.7 and 3.2 months, respectively, with a median DOR of 4.0 months (range, 1.0-23.5 months). Patients in CR at 28-days had a 6-months relapse-free survival of 48.4% (SE=14.9). EFS at 6 months was 26.5% (SE=9.9) and OS was 67.6% (SE=11.1). Among the 13 patients who achieved CR, two children underwent consolidation with a second allo-HSCT in complete remission. Adult patients did not receive any additional anti-leukemic therapies unless a relapse occurred, and four of them remained in remission and alive (+24, +9, +6, and +4 months). Robust CARCIK-CD19 cell expansion was achieved in most patients and CARCIK-CD19 cells were measurable for up to 22 months. Conclusions SB-engineered CAR T cells induce sustained responses in B-ALL patients relapsed after HSCT irrespective of the donor type and without severe toxicities. Disclosures Lussana: Incyte: Honoraria; Pfizer: Honoraria; Astellas Pharma: Honoraria; Amgen: Honoraria. Gritti: Takeda: Consultancy; Roche: Consultancy; Kite Gilead: Consultancy; IQvia: Consultancy; Italfarmaco: Consultancy; Clinigen: Consultancy. Biondi: Incyte: Consultancy, Other: Advisory Board; Bluebird: Other: Advisory Board; Novartis: Honoraria; Amgen: Honoraria; Colmmune: Honoraria.

Abstract: Background Significant efforts over the past few years led Chimeric Antigen Receptor (CAR) T cell therapy to success in relapsed and refractory (r/r) B-cell malignancies. Still logistical complexity, high costs and toxicities are currently the main barriers to the use of CAR T cell therapy. We therefore propose non-viral engineering of an allogeneic T cell population according to cytokine induced killer (CIK) cell protocol of differentiation. Methods We reported the updated results of our phase I/II trial in B-cell acute lymphoblastic leukemia (B-ALL) patients relapsed after allogeneic hematopoietic stem cell transplantation (HSCT) using donor-derived CD19 CAR T cells generated with the Sleeping Beauty (SB) transposon and differentiated into CIK (CARCIK-CD19) according to the method enclosed in the filed patent EP20140192371. After lymphodepletion with Fludarabine (30 mg/m2/day) x 4 days and Cyclophosphamide (500 mg/m2/day) x 2 days, CARCIK-CD19 were infused following a four-dose escalation scheme (1x106, 3x106, 7.5x106 and 15x106 transduced CAR+ T cells/kg) according to the Bayesian Optimal Interval Design (BOIN). During the cell manufacturing period, bridging anti leukemic therapy from patient registration to the beginning of the lymphodepletion, was allowed. The primary endpoint was to define the Maximum Tolerated Dose (MTD) and the safety assessment. Key secondary endpoints included the assessment of complete hematologic response (CR), defined as & lt; 5% bone marrow (BM) blasts, circulating blasts & lt; 1%, no clinical evidence of extramedullary disease, as well as the characterization of CARCIK-CD19 persistence in PB and BM (NCT03389035). Results The cellular product was produced successfully for all patients starting from the donor-derived peripheral blood (PB) and consisted mostly of CD3+ lymphocytes (mean 98.85% ±SD 1.19%) with a mean of 38.6% CAR expression (range 15.10%-73.17%). From January 2018 to July 2020, a total of 24 patients were screened, and 15 were enrolled (4 children and 11 adults) and infused with a single dose of CARCIK-CD19 (n=3 HLA identical sibling, n=4 MUD, n=8 haploidentical donor). The leukemic burden in the BM post lymphodepletion/pre-infusion ranged from 0% to 96%. Robust expansion was achieved in the majority of the patients. The maximal expansion reached about 1x106 transgene copies per μg DNA and 70% of CAR+ T cells in PB. CD8+ T cells represented the predominant circulating CAR+ T cell subset. Persistence of central memory CAR+ T cells was observed after infusion and CAR T cells were measurable up to 9 months. CARCIK-CD19 were characterized by a high profile of safety in all treated patients. Toxicities reported were two grade I and two grade II cytokine release syndrome (CRS) cases at the highest dose in the absence of graft-versus-host disease (GvHD), neurotoxicity, or dose-limiting toxicities. Seven out of 9 patients, receiving the highest doses, achieved CR and CRi at day 28. MRD-negative status for all responders was achieved by 6 out of 9 patients (1 currently in evaluation). The two patients in CR but with MRD+ relapsed with a CD19+ disease at +2.3 and +1.9 months post infusion, respectively. Among the 6 patients who achieved MRD-negative CR, two children underwent consolidation with a second allo-HSCT and are still alive and disease free (+17 and +13 months), two adult patients died of subsequent CD19+ disease relapse and two adult patients are still alive and disease free (+14 and +12 months) without additional therapies. The distribution profile of integration sites (IS) showed no preference for gene dense or promoter regions, and no particular differences between pre- and post- infusion sample IS. Samples harvested at early time points after infusion showed a highly polyclonal repertoire. At later time points (≥ 28 days after infusion) the repertoire of IS showed a marked reduction towards oligoclonality, in absence of specific dominant clones. Conclusions We can conclude that SB-engineered CAR T cells expand and persist in pediatric and adult B-ALL patients relapsed after HSCT. Sustained response was achieved without severe toxicities. All analyzed samples appear to have a highly polyclonal IS repertoire and no signs of genotoxicity by transposon insertions could be observed. Disclosures Gritti: IQVIA: Consultancy; Amgen: Honoraria; Autolus: Consultancy; Italfarmaco: Consultancy; F. Hoffmann-La Roche Ltd: Honoraria; Jannsen: Other: Travel Support; Takeda: Honoraria; Kite: Consultancy. Rambaldi:Sanofi: Honoraria, Other: TRAVEL, ACCOMMODATIONS, EXPENSES (paid by any for-profit health care company); Omeros: Honoraria, Other: TRAVEL, ACCOMMODATIONS, EXPENSES (paid by any for-profit health care company); Amgen: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees, Other: TRAVEL, ACCOMMODATIONS, EXPENSES (paid by any for-profit health care company). Research grant from Amgen Inc.; Pfizer: Honoraria, Membership on an entity's Board of Directors or advisory committees, Other: TRAVEL, ACCOMMODATIONS, EXPENSES (paid by any for-profit health care company). Advisory board and speaker fees from Pfizer.; Novartis: Honoraria, Membership on an entity's Board of Directors or advisory committees, Other: TRAVEL, ACCOMMODATIONS, EXPENSES (paid by any for-profit health care company); Gilead: Honoraria, Membership on an entity's Board of Directors or advisory committees, Other: Travel support from Gilead.; Roche: Honoraria, Membership on an entity's Board of Directors or advisory committees, Other: Support of parent study and funding of editorial support. Received travel support., Research Funding; University of Milan: Current Employment; BMS/Celgene: Honoraria, Other: TRAVEL, ACCOMMODATIONS, EXPENSES (paid by any for-profit health care company); Astellas: Honoraria, Other: TRAVEL, ACCOMMODATIONS, EXPENSES (paid by any for-profit health care company).

Abstract: Background Immunotherapy using patient-derived CAR T cells has achieved complete remission and durable response in highly refractory populations. However, logistical complexity and high costs of manufacturing autologous viral products limit CAR T cell availability. Allogeneic Cytokine Induced Killer (CIK) cells, a T-cell population characterized by the enrichment of CD3+CD56+ cells, have demonstrated a high profile of safety in acute lymphoblastic leukemia (ALL) patients (Introna M et al. Biol Blood Marrow Transplant. 2017). CIK cells could be easily engineered by the non-viral Sleeping Beauty (SB) transposon for the clinical application (Magnani CF et al, Hum Gene Ther. 2018, Biondi A et al. J Autoimmun. 2017). Methods CIK cells were generated from 50 ml of donor-derived peripheral blood (PB) by electroporation with the GMP-grade CD19.CAR/pTMNDU3 and pCMV-SB11 plasmids according to the method enclosed in the filed patent EP20140192371. After lymphodepletion with Fludarabine (30 mg/m2/day) x 4 days and Cyclophosphamide (300 mg/m2/day) x 2 days, CARCIK-CD19 were infused in pediatric and adult B-cell ALL (B-ALL) patients relapsed after allogeneic hematopoietic stem cell transplantation (HSCT). The clinical trial follows a four-dose escalation scheme (1x106, 3x106, 7.5x106 and 15x106 transduced CAR+ T cells/kg) using the novel Bayesian Optimal Interval Design (BOIN). During the cell manufacturing period, bridging anti leukemic therapy from patient registration to the beginning of the lymphodepletion, was allowed. The primary endpoint was to define the Maximum Tolerated Dose (MTD) and a safety assessment. Key secondary endpoints included the assessment of complete hematologic response (CR), defined as & lt; 5% bone marrow (BM) blasts, circulating blasts & lt; 1%, no clinical evidence of extramedullary disease, as well as the characterization of CARCIK-CD19 persistence in PB and BM (NCT03389035). Results We manufactured eighteen batches by seeding a median of 126.8x106 allogeneicPBMCs. At the end of expansion, the mean harvesting was 6.46x109 nucleated cells (range 1.39 - 16.00x109). Manufactured cells were mostly CD3+ lymphocytes (mean 98.90% ±SE 0.30%). Of these, 43.57%±3.73% were CAR+, 47.07%±2.74% were CD56+, 80.44%±2.53% were CD8+. The quality requirements for batch release were met in 17 productions. As of the data cut-off date (July 19, 2019), 4 pediatric and 7 adult patients were infused with a single dose of CARCIK-CD19 (n=2 HLA identical sibling, n=4 MUD, n=5 haploidentical donor). The leukemic burden in the BM post lymphodepletion/pre-infusion ranged from 0% to 96%. CARCIK-CD19 were characterized by a high profile of safety in all treated patients. Toxicities reported were a grade I cytokine release syndrome and an infusion-related DMSO-associated seizure, with absence of dose-limiting toxicities, neurotoxicity and graft-versus-host disease (GvHD) in any of the treated patients. Four out of 5 patients, receiving the highest doses, achieved CR and CRi at day 28. The 3 patients in CR were also MRD- (by flow cytometry and RT-PCR) while the CRi was MRD+ and relapsed at day+49. Robust expansion was achieved in the majority of the patients as defined by detectable CAR T-cell detection (vector copy number VCN, range 4645-977992 transgene copies/ug) and flow (range 0.5-30%) in PB. The median time to peak engraftment was 14 days. The magnitude of expansion was correlated with the CD19+ burden in the BM at the time of the infusion (P value = 0.0006, R square 0.7469). CD8+ T cells represented the predominant CARCIK-CD19 T-cell subset (78.88%±5.33% d14 n=6) along with CD3+CD56+ CIK cells and CD4+ T cells to a lesser extent. The majority of CAR T cells had a central and effector memory phenotype. CAR T cells were measurable by VCN up to 6 months with a mean persistence of 70.5 ± 14.85 days (follow up ranging from 28 days to 1 year). No major difference was observed by integration analyses of the patients' PB and the cell products. The vector integration sites reflected the classical random distribution of SB without any tendency for gene dense regions. Conclusions Our ongoing phase I/II trial demonstrates that SB-engineered CARCIK-CD19 cells are able to expand and persist in pediatric and adult B-ALL patients relapsed after HSCT, with important implications for a non-viral technology. These encouraging results prompted us to expand our study. Disclosures Gritti: Autolus Ltd: Honoraria; Roche: Other: Not stated; Abbvie: Other: Not stated; Becton Dickinson: Other: Not stated. Rambaldi:Celgene: Membership on an entity's Board of Directors or advisory committees, Other: travel support, Speakers Bureau; Roche: Membership on an entity's Board of Directors or advisory committees, Other: travel support, Research Funding, Speakers Bureau; Jazz: Membership on an entity's Board of Directors or advisory committees, Speakers Bureau, travel support; Pfizer: Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; Gilead: Membership on an entity's Board of Directors or advisory committees, Other: travel support, Speakers Bureau; Amgen: Membership on an entity's Board of Directors or advisory committees, Other: travel support, Research Funding, Speakers Bureau; Novartis: Membership on an entity's Board of Directors or advisory committees, Other: travel support, Speakers Bureau; Italfarmaco: Membership on an entity's Board of Directors or advisory committees, Other: travel support, Research Funding, Speakers Bureau; Omeros: Membership on an entity's Board of Directors or advisory committees, Speakers Bureau.

Abstract: Introduction Acute Myeloid Leukemia (AML) arises from the accumulation of mutations within the hematopoietic stem and progenitor cells (HSPC), leading to the emergence of a population of malignant leukemia-initiating cells (LIC). AML-LICs maintain high phenotypic similarity with their cells-of-origin and can cause post-treatment relapse. Immunotherapy with chimeric antigen receptor (CAR) T cells is an innovative approach to tackle cancer via surface-expressed cancer-associated antigens. We recently proposed the use of CAR T cells specific for the CD117 antigen to deplete LIC and replace HSPC by allogeneic hematopoietic stem cell transplantation (HSCT) (Myburgh R et al. Leukemia 2020). This concept implies early termination of CAR T-cell activity to prevent subsequent graft rejection. Here, we exploit a non-viral technology for the generation of anti-CD117 CAR T cells incorporating a safety switch. Methods We designed a Sleeping Beauty (SB) transposon vector that includes the inducible Caspase 9 (iC9) switch and the anti-CD117CAR, separated by a 2A peptide. SB allows the generation of CAR T cells with potent anti-leukemic activity (Magnani CF et al. J Clin Invest. 2020). The vector has an optimized donor vector architecture and allows for the stoichiometric expression of the two transgenes. iC9 allows for rapid termination of CAR T cells by activation of the apoptotic pathway in case of treatment with a small molecule that acts as a chemical inducer of dimerization (CID). The hyperactive SB100X transposase, supplied as plasmid DNA or mRNA, catalyzes transgene integration. As an alternative approach, we used mRNA encoding an anti-CD117 CAR in human T cells. Results With the purpose of transduction optimization, we compared total PBMC and selected T cells as starting material in the presence of different concentrations of plasmids or mRNA. The procedure of generating CAR T cells with SB did not affect T cell memory differentiation but increased the CD8/CD4 proportion compared to non-transduced (NT) cells (75.63% vs. 41.63%, p= 0.0124). Based on higher transduction efficiency and favored in vitro expansion, we defined the lead protocol (selected T cells, PT4:SB100X plasmid 3:1 ratio, or PT4:SB100X mRNA 1:2 ratio). CAR T cells had a high level of viability, retained a high proportion of naïve-like (mean 36.38%, SEM 8.80) and T stem cell memory populations (mean 39.21%, SEM 8.43), and showed low levels of the exhaustion markers PD-1 (mean 2.21%, SEM 1.04), LAG3 (mean 61.20%, SEM 9.61), and TIM3 (mean 35.72%, SEM 10.79). Anti-CD117 CAR T cells exhibited potent cytotoxicity against the AML cell line MOLM-14, transduced and sorted to express human CD117, luciferase, and GFP. The addition of 200nM of the CID to cultures of anti-CD117 CAR T cells induced apoptosis of transduced CAR T cells within 24h but had no effect on the viability of NT cells. Anti-CD117 CAR T cells mediated depletion of CD117+ MOLM-14 cells in vivo, leading to a significant survival advantage compared to mice treated with NT cells (median overall survival for NT= 22.5 days vs. SB= not reached, p= 0.0122, Mantel-Cox). Notably, SB-transduced CAR T cells were as efficient as CAR T cells transduced with lentiviral vectors. In NSG mice reconstituted with human CD34+ cord blood cells, anti-CD117 CAR T cells were able to achieve complete CD117+ HSPC depletion. Treatment with a combination of CID and anti-thymocyte globulin (ATG) eliminated anti-CD117 CAR T cells and T cells of the previous transplant donor. Finally, transient expression of anti-CD117 CAR by mRNA conferred T cells the ability to kill CD117+ targets throughout 72 hours post mRNA electroporation. The cytotoxic activity decreased over time as mRNA-electroporated CAR T cells proliferate and lose CAR expression upon 3-5 divisions. Treatment of humanized NSG mice with two subsequent doses of anti-CD117 CAR mRNA T cells resulted in HSPC depletion. Conclusions Anti-CD117 CAR T cells engineered with the SB vector showed anti-leukemic activity and completely depleted healthy HSPC in vivo. iC9 transgene induced CAR T cell apoptosis and allowed rapid CAR T cell depletion that alternatively also could be achieved with mRNA electroporation of the anti-CD117 CAR. The ability to control CAR T cell pharmacokinetic properties is attractive to enable subsequent HSCT and to terminate unexpected toxicities. Anti-CD117 CAR T cells could be used prior to HSCT in refractory or minimal residual disease AML. Disclosures Myburgh: University of Zurich: Patents & Royalties: CD117xCD3 TEA. Shizuru: Forty seven Inc: Other: Inventor on a patent licenses by Forty Seven. Forty seven was acquired by Gilead in 2020; Jasper Therapeutics, Inc.: Current holder of stock options in a privately-held company, Membership on an entity's Board of Directors or advisory committees, Other: Chair of scientific advisory board. Neri: Philogen S.p.A.: Current Employment, Current equity holder in publicly-traded company, Divested equity in a private or publicly-traded company in the past 24 months, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties: Multiple patents on vascular targeting; ETH Zurich: Patents & Royalties: CD117xCD3 TEA. Manz: CDR-Life Inc: Consultancy, Current holder of stock options in a privately-held company; University of Zurich: Patents & Royalties: CD117xCD3 TEA.

Abstract: Adoptive transfer of chimeric antigen receptor (CAR) T lymphocytes is a powerful technology that has revolutionized the way we conceive immunotherapy. The impressive clinical results of complete and prolonged response in refractory and relapsed diseases have shifted the landscape of treatment for hematological malignancies, particularly those of lymphoid origin, and opens up new possibilities for the treatment of solid neoplasms. However, the widening use of cell therapy is hampered by the accessibility to viral vectors that are commonly used for T cell transfection. In the era of messenger RNA (mRNA) vaccines and CRISPR/Cas (clustered regularly interspaced short palindromic repeat–CRISPR-associated) precise genome editing, novel and virus-free methods for T cell engineering are emerging as a more versatile, flexible, and sustainable alternative for next-generation CAR T cell manufacturing. Here, we discuss how the use of non-viral vectors can address some of the limitations of the viral methods of gene transfer and allow us to deliver genetic information in a stable, effective and straightforward manner. In particular, we address the main transposon systems such as Sleeping Beauty (SB) and piggyBac (PB), the utilization of mRNA, and innovative approaches of nanotechnology like Lipid-based and Polymer-based DNA nanocarriers and nanovectors. We also describe the most relevant preclinical data that have recently led to the use of non-viral gene therapy in emerging clinical trials, and the related safety and efficacy aspects. We will also provide practical considerations for future trials to enable successful and safe cell therapy with non-viral methods for CAR T cell generation.