Non-Viral Sleeping Beauty Transposon Engineered CD19-CAR-NK Cells Show a Safe Genomic Integration Profile and High Antileukemic Efficiency

Background: Natural Killer (NK) cells are known for their high intrinsic cytotoxic capacity. Recently, we and others showed that virally transduced NK cells equipped with a synthetic chimeric antigen receptor (CAR) targeting CD19 induced enhanced killing of acute lymphoblastic leukemia (ALL) cells. Here, we demonstrate for the first time that primary NK cells can be engineered using the non-viral Sleeping Beauty (SB) transposon/transposase system to stably express a CD19-CAR with a safe genomic integration profile and high anti-leukemic efficiency in vitro and in vivo. Methods: Primary NK cells were isolated from PBMCs from healthy donors. SB transposons vectorized as minicircles (MC), which encode either a Venus fluorescent protein or a CD19-CAR together with truncated EGFR (tEGFR) as a marker, were introduced in combination with the hyperactive SB100X transposase into primary NK cells via nucleofection. The genetically engineered NK cells were expanded using IL-15 cytokine stimulation under feeder-cell free conditions. Vector integration sites were mapped by analyzing the genomic region around each insertion site in genomic DNA from long-term cultivated gene-modified NK cells, engineered ether by lentiviral (LV) or SB-based technology. Stable gene delivery and biological activity were monitored by flow cytometry and cytotoxicity of CD19-CAR NK cells against CD19-positive ALL and CD19-negative cell lines. Results: Applying a protocol optimized with respect to nucleofection pulses, time points and plasmid ratios, primary NK cells showed long-lasting Venus expression (up to 50%) upon SB-mediated gene delivery with similar viability as non-treated (NT) NK cells during feeder-cell free ex-vivo expansion using IL-15. Likewise, SB transposon-engineered CD19-CAR NK cells displayed high viability, durable transgene expression (Fig 1 A), and no significant change in the NK cell phenotype profile. Next, we assessed vector integration into genomic safe harbors (GSH). GSH are defined as regions of human chromosomes that fulfill the following five criteria: not ultraconserved, >300 kb away from miRNA genes, >50 kb away from transcriptional start sites (TSS), >300 kb away from genes involved in cancer and outside transcription units. CD19-CAR NK cells generated using SB100X showed a significantly higher frequency of vector integration into GSH compared to LV-transduced CAR-NK cells and a significantly more-close to random nucleotide frequency (computer-generated random positions in the genome map to GSHs; random 43.68%; LV 14.78%, SB100X 23.99%; p<0.05) (Fig 1 B). MC.CD19-CAR NK cells generated with the SB platform demonstrated significantly higher cytotoxicity compared to NT NK cells against CD19-positive Sup-B15 ALL cells after long-term cultivation for two to three weeks and no loss of natural intrinsic cytotoxicity. After 4-hour co-culture, significantly enhanced specific tumor cell lysis was found for MC.CD19-CAR NK cells vs NT NK cells at all effector to target cell ratios (E:T) tested (E:T 20:1 83.88% vs 43.13%; E:T 10:1 75.18% vs 31.32%; E:T 5:1 67.38 vs 32.22%; E:T 1:1 42.54 vs 10.19%; p<0.05) (Fig 1 C). With regard to intrinsic natural cytotoxicity of NK cells, no significant decrease in cell killing was overserved for SB-gene-modified CD19-CAR NK cells compared to NT NK cells against CD19-negative K562 cells (E:T 5:1 83%; p<0.05) (Fig 1 D). Significantly enhanced antitumor potential of SB-generated CD19-CAR NK cells was confirmed in a systemic CD19-positive lymphoma xenograft model (NSG-Nalm-6/Luc) in vivo. After injection of 0.5x10 6 tumor cells per mouse and lymphoma engraftment, animals were treated with a single dose of 10x10 6 SB-modified CD19-CAR NK cells pooled from three different donors with a mean tEGFR/CAR expression of 34%. MC.CD19-CAR NK cell therapy resulted in rapid lymphoma eradication in all treated mice (n=4; p<0.05), whereas mice receiving similar amounts of NT NK cells showed progressive lymphoma growth comparable to untreated control mice (Fig 1 E-F). Conclusion: Taken together, the Sleeping Beauty transposon system represents an innovative gene therapy approach for non-viral engineering of safe, highly functional and relatively cost-efficient CAR-NK cells that may not only be suitable for ALL therapy but also for a broad range of other applications in cancer therapy. Figure 1 Figure 1. Disclosures No relevant conflicts of interest to declare.

188 Development of WU-NK-101, a feeder cell-free expanded allogeneic memory NK cell product with potent anti-tumor activity

BackgroundAllogeneic Natural Killer (NK) cells are emerging as a safe and effective modality for the treatment of cancer, overcoming several limitations associated with adoptive T cell therapies. Cytokine induced memory-NK cells offer several advantages over conventional NK cells, including enhanced functional persistence, efficacy, and metabolic fitness. Additionally, unlike iPSC and cord blood derived NK cells, they do not require engineering to enable functionality. Here we describe the use of WU-PRIME, a GMP-grade fusion protein complex to generate memory NK cells, and WU-EXPAND, a feeder cell free expansion system to expand memory-NK cells and create WU-NK-101. Further cryopreservation enables the large-scale, off-the-shelf manufacture of memory NK for cancer immunotherapy, with high anti-tumor activity.MethodsNK cells derived from healthy donor leukopheresate were either activated with WU-PRIME and then expanded with WU-EXPAND to form WU-NK-101 or immediately expanded with WU- EXPAND as controls and then cryopreserved. We compared NK cell expansion as well as post- thaw NK cell functionality as assessed by cytokine secretion and short-term and long-term anti- tumor functionality, long-term persistence in NSG mice, as well as anti-tumor activity in vivo.ResultsNK cells activated with WU-PRIME followed by WU-EXPAND (WU-NK-101), expand robustly in large-scale reactions, over 250-fold in 14 days. The cells maintain durable expression of CD25 after expansion, as well as several other hallmarks of the memory-NK phenotype as assessed by mass cytometry. As compared to cells expanded with WU-EXPAND only, WU-NK-101 cells have improved in vitro activity against K562 cells, as well as AML cell lines (TF-1, THP-1, and HL-60). Notably, this functionality is maintained long-term upon repeated challenge. In vivo, WU-NK-101 cells, compared to expanded NK cells have improved in vivo persistence (figure 1; 50,290 v. 9,623, p<0.0001). In vivo anti-tumor activity was also assessed in leukemia models, where Memory NK cells demonstrate superior anti-tumor activity compared to expanded NK cells.Abstract 188 Figure 1NK cell persistence in tumor-bearing mice. 10e6 cryopreserved NK cells were injected into K562 tumor-bearing mice, and supported with 50,000IU human IL-2 every other day. After 9 days, blood was harvested by cheek bleed and assessed for NK cells (hCD45+, CD56+, CD3) in the blood by flow cytometry.ConclusionsThe data demonstrate that WU-NK-101 generated using a feeder cell-free expansion system has a memory phenotype and improved in vitro and in vivo anti-tumor activity compared to conventional NK cells. This activation and expansion platform will enable the development and clinical translation of multiple allogeneic NK cell therapies.

Rejuvenating Effector/Exhausted CAR T Cells to Stem Cell Memory–Like CAR T Cells By Resting Them in the Presence of CXCL12 and the NOTCH Ligand

T cells with a stem cell memory (TSCM) phenotype provide long-term and potent antitumor effects for T-cell transfer therapies. Although various methods for the induction of TSCM-like cells in vitro have been reported, few methods generate TSCM-like cells from effector/exhausted T cells. We have reported that coculture with the Notch ligand–expressing OP9 stromal cells induces TSCM-like (iTSCM) cells. Here, we established a feeder-free culture system to improve iTSCM cell generation from expanded chimeric antigen receptor (CAR)-expressing T cells; culturing CAR T cells in the presence of IL7, CXCL12, IGF-I, and the Notch ligand, hDLL1. Feeder-free CAR-iTSCM cells showed the expression of cell surface markers and genes similar to that of OP9-hDLL1 feeder cell–induced CAR-iTSCM cells, including the elevated expression of SCM-associated genes, TCF7, LEF1, and BCL6, and reduced expression of exhaustion-associated genes like LAG3, TOX, and NR4A1. Feeder-free CAR-iTSCM cells showed higher proliferative capacity depending on oxidative phosphorylation and exhibited higher IL2 production and stronger antitumor activity in vivo than feeder cell–induced CAR-iTSCM cells. Our feeder-free culture system represents a way to rejuvenate effector/exhausted CAR T cells to SCM-like CAR T cells. Significance: Resting CAR T cells with our defined factors reprograms exhausted state to SCM-like state and enables development of improved CAR T-cell therapy.

Continuous ES/Feeder Cell-Sorting Device Using Dielectrophoresis and Controlled Fluid Flow

Pluripotent stem cells (PSCs) are considered as being an important cell source for regenerative medicine. The culture of PSCs usually requires a feeder cell layer or cell adhesive matrix coating such as Matrigel, laminin, and gelatin. Although a feeder-free culture using a matrix coating has been popular, the on-feeder culture is still an effective method for the fundamental study of regenerative medicine and stem cell biology. To culture PSCs on feeder cell layers, the elimination of feeder cells is required for biological or gene analysis and for cell passage. Therefore, a simple and cost-effective cell sorting technology is required. There are several commercialized cell-sorting methods, such as FACS or MACS. However, these methods require cell labeling by fluorescent dye or magnetic antibodies with complicated processes. To resolve these problems, we focused on dielectrophoresis (DEP) phenomena for cell separation because these do not require any fluorescent or magnetic dyes or antibodies. DEP imposes an electric force on living cells under a non-uniform AC electric field. The direction and magnitude of the DEP force depend on the electric property and size of the cell. Therefore, DEP is considered as a promising approach for sorting PSCs from feeder cells. In this study, we developed a simple continuous cell-sorting device using the DEP force and fluid-induced shear force. As a result, mouse embryonic stem cells (mESCs) were purified from a mixed-cell suspension containing mESCs and mouse embryonic fibroblasts (MEFs) using our DEP cell-sorting device.

Human Caesarean scar-derived feeder cells: a novel feeder cell type for culturing human pluripotent stem cells without exogenous basic fibroblast growth factor supplementation

In a feeder-dependent culture system of human pluripotent stem cells (hPSCs), coculture with mouse embryonic fibroblasts may limit the clinical use of hPSCs. The aim of this study was to determine the feasibility of using human Caesarean scar fibroblasts (HSFs) as feeder cells for the culture of hPSCs. HSFs were isolated and characterised and cocultured with hPSCs, and the pluripotency, differentiation ability and karyotypic stability of hPSCs were determined. Inactivated HSFs expressed genes (including inhibin subunit beta A (INHBA), bone morphogenetic protein 4 (BMP4), fibroblast growth factor 2 (FGF2), transforming growth factor-β1 (TGFB1), collagen alpha-1(I) (COL1A1) and fibronectin-1 (FN1) that have been implicated in the maintenance of hPSC pluripotency. When HSFs were used as feeder cells, the pluripotency and karyotypic stability of hPSC lines did not change after prolonged coculture. Interestingly, exogenous FGF2 could be omitted from the culture medium when HSFs were used as feeder cells for hESCs but not hiPSCs. hESCs cocultured with HSF feeder cells in medium without FGF2 supplementation maintained their pluripotency (as confirmed by the expression of pluripotency markers and genes), differentiated invitro into embryonic germ layers and maintained their normal karyotype. The present study demonstrates that HSFs are a novel feeder cell type for culturing hPSCs and that supplementation of exogenous FGF2 is not necessary for the Chula2.hES line.

Membrane bound IL-21 based NK cell feeder cells drive robust expansion and metabolic activation of NK cells

NK cell adoptive therapy is a promising cancer therapeutic approach, but there are significant challenges that limiting its feasibility and clinical efficacy. One difficulty is the paucity of clinical grade manufacturing platforms to support the large scale expansion of highly active NK cells. We created an NK cell feeder cell line termed ‘NKF’ through overexpressing membrane bound IL-21 that is capable of inducing robust and sustained proliferation (>10,000-fold expansion at 5 weeks) of highly cytotoxic NK cells. The expanded NK cells exhibit increased cytotoxic function against a panel of blood cancer and solid tumor cells as compared to IL-2-activated non-expanded NK cells. The NKF-expanded NK cells also demonstrate efficacy in mouse models of human sarcoma and T cell leukemia. Mechanistic studies revealed that membrane-bound IL-21 leads to an activation of a STAT3/c-Myc pathway and increased NK cell metabolism with a shift towards aerobic glycolysis. The NKF feeder cell line is a promising new platform that enables the large scale proliferation of highly active NK cells in support of large scale third party NK cell clinical studies that have been recently intiatied. These results also provide mechanistic insights into how membrane-bound IL-21 regulates NK cell expansion.