NK-cell resistance to transduction is a major technical hurdle for developing NK-cell immunotherapy. By using Baboon envelope pseudotyped lentiviral vectors (BaEV-LVs) encoding eGFP, we obtained a transduction rate of 23.0 ± 6.6% (mean ± SD) in freshly-isolated human NK-cells (FI-NK) and 83.4 ± 10.1% (mean ± SD) in NK-cells obtained from the NK-cell Activation and Expansion System (NKAES), with a sustained transgene expression for at least 21 days. BaEV-LVs outperformed Vesicular Stomatitis Virus type-G (VSV-G)-, RD114-and Measles Virus (MV)-pseudotyped LVs (p < 0.0001). mRNA expression of both BaEV receptors, ASCT1 and ASCT2, was detected in FI-NK and NKAES, with higher expression in NKAES. Transduction with BaEV-LVs encoding for CAR-CD22 resulted in robust CAR-expression on 38.3 ± 23.8% (mean ± SD) of NKAES cells, leading to specific killing of NK-resistant pre-BALL -RS4;11 cell line. Using a larger vector encoding a dual CD19/CD22-CAR, we were able to transduce and re-expand dual-CAR-expressing NKAES, even with lower viral titer. These dual-CAR-NK efficiently killed both CD19 KO-and CD22 KO-RS4;11 cells. Our results suggest that BaEV-LVs may efficiently enable NK-cell biological studies and translation of NK-cell-based immunotherapy to the clinic.
Although clinical studies have yet to demonstrate clearly the use of intravenous immunoglobulin (IVIG) for prevention of graft-versus-host disease (GVHD), their effective use in a xenogeneic mouse model has been demonstrated. We aimed to determine the mechanism of action by which IVIG contributes to GVHD prevention in a xenogeneic mouse model. NOD/LtSz-scidIL2rg(-/-) (NSG) mice were used for our xenogeneic mouse model of GVHD. Sublethally irradiated NSG mice were injected with human peripheral blood mononuclear cells (huPBMCs) and treated weekly with PBS or 50 mg IVIG. Incidence of GVHD and survival were noted, along with analysis of cell subsets proliferation in the peripheral blood. Weekly IVIG treatment resulted in a robust and consistent proliferation of human natural killer cells that were activated, as demonstrated by their cytotoxicity against K562 target cells. IVIG treatment did not inhibit GVHD when huPBMCs were depleted in natural killer (NK) cells, strongly suggesting that this NK cell expansion was required for the IVIG-mediated prevention of GVHD in our mouse model. Moreover, inhibition of T cell activation by either cyclosporine A (CsA) or monoclonal antihuman CD3 antibodies abolished the IVIG-induced NK cell expansion. In conclusion, IVIG treatment induces NK cell proliferation, which is essential for IVIG-mediated protection of GVHD in our mouse model. Furthermore, activated T cells are mandatory for effective IVIG-induced NK cell proliferation. These results shed light on a new mechanism of action of IVIG and could explain why the efficacy of IVIG in preventing GVHD in a clinical setting, where patients receive CsA, has never been undoubtedly demonstrated.
NK-cell resistance to transduction is a major technical hurdle for developing NK-cell immunotherapy. By using Baboon envelope pseudotyped lentiviral vectors (BaEV-LVs) encoding eGFP, we obtained a transduction rate of 23.0±6.6% in freshly-isolated NK-cells (FI-NK) and 83.4±10.1% in NK-cells obtained from the NK-cell Activation and Expansion System (NKAES), even at low MOI, with a sustained transgene expression for at least 21 days. BaEV-LVs outperformed Vesicular Stomatitis Virus type-G (VSV-G)-, RD114-and Measles Virus (MV)-pseudotyped LVs (p<0.001). mRNA expression of both BaEV receptors, ASCT1 and ASCT2, was detected in FI-NK and NKAES, with much higher expression in NKAES. Transduction with BaEV-LVs encoding for CAR-CD22 resulted in robust CAR-expression on 44.2%±14.2% of NKAES cells, which allowed the specific killing of the NK-resistant pre-B-ALL-RS4;11 cell line. Using a larger vector, encoding a dual CD19/CD22-CAR separated by T2A, we were able to transduce and re-expand dual-CAR-expressing NKAES, even with low viral titer. These dual-CAR-NK efficiently and specifically killed both CD19KO-and CD22KO-RS4;11 cells, which may overcome antigen-loss escape in the clinical setting. Our results suggest that BaEV-LVs may efficiently enable NK-cell biological studies and translation of NK-cell-based immunotherapy to the clinic.
acting form of recombinant human interleukin-7 fused with hybrid Fc (rhIL-7-hyFc, NT-I7) in vivo using a CD19 + lymphoma xenograft model. Methods: To create anti-CD19 universal CART (UCART19), we activated human T cells on CD3/CD28 beads, electroporated the T cells with Cas9 mRNA and a TRAC gRNA, and virally transduced an anti-CD19 scFv 3 rd generation CAR containing a peptidase 2A-cleaved human CD34 construct for both purification and tracking in vivo. Residual TRAC+ cells were depleted using magnetic selection. For xenograft tumor modeling in vivo, we injected NSG mice with 5 £ 10 5 Ramos CBR-GFP cells four days prior to UCART19 (2 £ 10 6 cells). Mice were treated with NT-I7 (10mg/kg SC) on days +1, +15 and +29 post UCART19 infusion. Results: Ramos CBR-GFP mice receiving NT-I7 without UCART19 (NT-I7 only group) survived marginally longer (24 day med survival) than mice receiving Ramos CBR-GFP cells alone (No tx group) (21 day medium survival, p=0.018, NT-I7 only vs. No Tx). While Ramos CBR-GFP mice treated with UCART19 alone (UCART19 group) survived 33 days, 100% of Ramos CBR-GFP mice treated with UCART19 and NT-I7 (UCART19+NT-I7 group) were alive at 80 days (Fig 1a), with no mouse showing signs of xenogeneic GVHD (p<0.0001, UCART19+NT-I7 vs. UCART19). At three weeks post UCART19 infusion, bioluminescent imaging (BLI) revealed minimal tumor signal in UCART19+NT-I7 treated mice (10 8 vs. 10 10 photon flux/s, p<0.05, UCART19+NT-I7 vs. UCART19) and near-undetectable photon flux/s at four weeks (10 7 vs 10 11 photon flux/s, p<0.0001, UCART19+NT-I7 vs. UCART19). Quantitative 17-parameter flow cytometric analyses of the blood, bone marrow, and spleens revealed an up to »8000-fold increase in UCART19 cells in NT-I7-treated mice four weeks post UCART19 infusion (Fig 1a). These UCART19 cells demonstrated a predominantly effector and effector memory phenotype. Discussion: Here, we demonstrate that a pharmacological grade long-acting interleukin-7 agonist can potentiate adoptive cellular therapies. Specifically, NT-I7 can dramatically enhance gene modified T cell proliferation, persistence and tumor killing in vivo, resulting in enhanced survival. Unlike genetic strategies to potentiate IL-7 signaling in CART, NT-I7 provides a tunable clinic-ready adjuvant for reversing suboptimal CART activity in vivo.
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