Murine induced pluripotent stem cells can be derived from and differentiate into natural killer T cells
Hiroshi Watarai, Shin-ichiro Fujii, Daisuke Yamada, Andrei Rybouchkin, Sakura Sakata, Yuko Nagata, Midori Iida-Kobayashi, Etsuko Sekine-Kondo, Kanako Shimizu, Yohei Shozaki, Jafar Sharif, Masashi Matsuda, Shinobu Mochiduki, Takanori Hasegawa, Genta Kitahara, Takaho A. Endo, Tetsuro Toyoda, Osamu Ohara, Ken-ichi Harigaya, Haruhiko Koseki, Masaru Taniguchi
Hiroshi Watarai, Shin-ichiro Fujii, Daisuke Yamada, Andrei Rybouchkin, Sakura Sakata, Yuko Nagata, Midori Iida-Kobayashi, Etsuko Sekine-Kondo, Kanako Shimizu, Yohei Shozaki, Jafar Sharif, Masashi Matsuda, Shinobu Mochiduki, Takanori Hasegawa, Genta Kitahara, Takaho A. Endo, Tetsuro Toyoda, Osamu Ohara, Ken-ichi Harigaya, Haruhiko Koseki, Masaru Taniguchi
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Technical Advance Oncology

Murine induced pluripotent stem cells can be derived from and differentiate into natural killer T cells

Abstract

NKT cells demonstrate antitumor activity when activated to produce Th1 cytokines by DCs loaded with α-galactosylceramide, the prototypic NKT cell–activating glycolipid antigen. However, most patients do not have sufficient numbers of NKT cells to induce an effective immune response in this context, indicating a need for a source of NKT cells that could be used to supplement the endogenous cell population. Induced pluripotent stem cells (iPSCs) hold tremendous potential for cell-replacement therapy, but whether it is possible to generate functionally competent NKT cells from iPSCs has not been rigorously assessed. In this study, we successfully derived iPSCs both from embryonic fibroblasts from mice harboring functional NKT cell–specific rearranged T cell receptor loci in the germline and from splenic NKT cells from WT adult mice. These iPSCs could be differentiated into NKT cells in vitro and secreted large amounts of the Th1 cytokine IFN-γ. Importantly, iPSC-derived NKT cells recapitulated the known adjuvant effects of natural NKT cells and suppressed tumor growth in vivo. These studies demonstrate the feasibility of expanding functionally competent NKT cells via an iPSC phase, an approach that may be adapted for NKT cell–targeted therapy in humans.

Authors

Hiroshi Watarai, Shin-ichiro Fujii, Daisuke Yamada, Andrei Rybouchkin, Sakura Sakata, Yuko Nagata, Midori Iida-Kobayashi, Etsuko Sekine-Kondo, Kanako Shimizu, Yohei Shozaki, Jafar Sharif, Masashi Matsuda, Shinobu Mochiduki, Takanori Hasegawa, Genta Kitahara, Takaho A. Endo, Tetsuro Toyoda, Osamu Ohara, Ken-ichi Harigaya, Haruhiko Koseki, Masaru Taniguchi

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Figure 2

In vitro generation of NKT cells from iPSCs in the 25-day culture system.

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In vitro generation of NKT cells from iPSCs in the 25-day culture system...
(A) Expression of cell surface markers on iPSC-derived NKT cells (7a-NKT and 7g-NKT). 7a-NKT and 7g-NKT cells generated in vitro were gated as the α-GalCer/CD1d dimer+TCR-β+ population and further analyzed for the expression of the indicated markers, NK1.1 versus CD3ε and CD4 versus CD8. Numbers show percentage of each gate. (B) Quantitative PCR analysis. Indicated genes in iPSC-derived NKT cells and FACS-sorted thymic NKT and CD4 T cells were analyzed for mRNA levels by quantitative real-time PCR (2 × 103 cells/sample). (C and D) Proliferative response (C) and cytokine production (D) of iPSC-derived NKT cells upon stimulation with α-GalCer. The 7a-NKT, 7g-NKT, or WT splenic NKT cells (106/ml) were cocultured with bone marrow–derived DCs (105/ml) in the presence of the indicated dose of α-GalCer (0, 1, 10, 100 ng/ml). Mean ± SD of triplicate wells is shown. One representative experiment of 3 is shown.