Autologous Expanded Natural Killer Cells As a New Therapeutic Option for High-Risk Myeloma

Abstract 2918 Natural killer cells (NK) have the unique ability to kill target cells without priming. While their therapeutic potential against various malignancies is becoming more apparent, it has been restricted to the allogeneic setting; NK cells are inhibited by autologous targets by engaging killer immunoglobulin-like receptors with their ligands. Another major challenge to the clinical utility of NK cells is obtaining a sufficient number of NK cells for infusion. Co-culture of blood mononuclear cells (PBMNC) with the leukemic cell line K562, genetically modified to express membrane-bound IL15 and the co-stimulatory molecule 41BBL (K562mbIL15-41BBL) in the presence of IL2 results in robust expansion and activation of NK cells. To determine if NK cells derived from myeloma (MM) patients can be used therapeutically in the autologous setting, we explored the expansion of NK cells from MM patients, their gene expression profiles (GEP), and their ability to kill autologous and allogeneic MM cells from high-risk patients in vitro and in vivo , and compared these to NK cells from healthy donors (HD). PBMNC from MM patients (N=30) co-cultured with irradiated K562mbIL15-41BBL cells expanded a median of 351 fold (range20–10, 430), comparable to the expansion of HD-derived NK cells (N=15, median 803, range 127–1, 727; p=0.5). GEP of MM non-exp-NK differed from HD non-exp-NK in the expression of only one gene ( PRKCi ), underexpessed in MM (false discovery rate (FDR) −10 ). GEP of exp-NK cells from both MM patients and HD was very different from non-exp-NK cells (8 pairs each, 10, 639 differentially overexpressed and 26, 057 underexpressed probe sets, FDR The anti-MM activity of allogeneic and autologous exp-NK cells was further examined in vivo . NOD/SCID/IL2R γ-null mice were implanted subcutaneously with a human fetal bone, and primary MM cells or luciferase-transfected OPM2 MM cell line were engrafted into the bone. The tumor burden was determined by ELISA for human Ig and/or bio-imaging. The mice were randomized to control and exp-NK treatment groups. A total of 160 ×10 6 exp-NK cells, in 4 doses 48 hrs apart, were injected in the exp-NK treatment group via tail vein injection. The mice were administered 1000U of IL2 subcu daily to support the NK cells. The mice were bled on days 7, 14, 21 & 28 for the assessment of human Ig by ELISA and enumerating circulating NK cells by flow cytometry. Exp-NK treated mice had a significantly reduced MM burden by ELISA (p in vivo . Exp-NK cells trafficked to MM tumors and persisted in the myelomatous hu bone microenvironment for 4 weeks. The anti-MM activity of autologous exp-NK cells is exciting and avails a new therapeutic avenue for patients with GEP-defined high-risk disease. A phase II clinical trial of allogeneic and autologous exp-NK cell therapy for relapsed/refractory high-risk MM is in progress at our institution. Disclosures: No relevant conflicts of interest to declare.