Peripheral blood mononuclear cells (PBMC) or αβ T cell‐depleted PBMCs from healthy adult volunteers were isolated by density gradient centrifugation using Ficoll‐Paque™ Plus (GE Healthcare). αβ T cell‐depleted PBMCs were isolated using CliniMACS (Miltenyi Biotec), as previously described.¹³ All of the participants provided written informed consent. All of the procedures were approved by the Institutional Review Board, Asan Medical Center, Seoul, Korea (Approval No. 2015‐0307). The study was performed ethically, following the Declaration of Helsinki. Isolated cells were immediately frozen in heat‐inactivated fetal bovine serum (FBS) (Sigma‐Aldrich) containing 10% dimethyl sulfoxide (Sigma‐Aldrich) and were maintained in liquid nitrogen until use. The PBMCs were cultured at 6 × 10⁵ cells/well in 24‐well plates in Rosewell Park Memorial Institute (RPMI) 1640 (Corning) supplemented with 10% heat‐inactivated FBS, 100 IU/ml penicillin plus 100 μg/ml streptomycin (Corning), 1 mM sodium pyruvate (Sigma), and 55 μM 2‐mercaptoethanol (Gibco) in the presence of 100 U/ml recombinant human interleukin‐2 (IL‐2) (PeproTech) and 1 μM Zol (Selleckchem). Every 2 days, fresh IL‐2 was added.

Jurkat cells (ATCC) were cotransfected with the HVEM CRISPR/Cas9 KO plasmid (Santa Cruz) and the HVEM HDR plasmid (Santa Cruz) according to the manufacturer's instructions. After 48 h, all transfected cells were selected with media containing 2 μg/ml puromycin (TOCRIS Bioscience) for at least 2 weeks. Before use, the reduction of HVEM expression in the selected cells was confirmed by flow cytometry. The cells expressing lower levels of HVEM were named HVEM^low Jurkat cells. Jurkat cell lines were maintained in RPMI 1640 supplemented with 10% inactivated FBS, 100 IU penicillin plus 100 μg/ml streptomycin, and 1 mM sodium pyruvate. All cells were incubated in a humidified CO₂ incubator.

PBMCs were washed and resuspended in phosphate‐buffered saline (PBS) (Biosesang). Then, the cells were labeled with cell proliferation Dye eFluor™ 670 (EF670) (Thermo Fisher Scientific) according to the manufacturer's instructions.

For inactivation of the Jurkat cells, they were treated with 25 μg/ml mitomycin C (Sigma) for 2 h and then it was washed away three times with 1× PBS. EF670‐labeled PBMCs at 3 × 10⁵ cells were cultured in 96‐well plates with or without the indicated monoclonal antibody and mitomycin C‐treated Jurkat cells at 1.5 × 10⁵ cells in the presence of 100 U/ml rhIL‐2 and 1 μM Zol. Anti‐human PD‐L1 blocking antibody (clone 29E.2A3; Biolegend) was added at 1 μg/ml at the beginning of the culture. Fresh IL‐2 was added every 2 days. In some experiments, BLTA/HVEM blocking peptides (Ac‐YRVKEACGELTGTVCEP‐NH₂; Peptron),³³ and anti‐PD‐1 mAb (clone EH12.2H7; Biolegend) were used. As control, scrambled peptide (Ac‐ELCAGPVTRKVECTYGE‐NH₂; Peptron) and isotype control (clone MOPC‐21; Biolegend) were also used. The cultured cells were treated with FcR blocking reagent (Miltenyi Biotec) for 5 min and stained with phycoerythrin (PE)‐conjugated anti‐human TCRγδ (clone MOPC‐21; Biolegend) and APC‐H7‐conjugated anti‐human CD3 antibody (clone SK7; BD Biosciences) for 30 min. The EF670 dilution was analyzed by FACS Canto Ⅱ (BD Biosciences) or CytoFLEX (Beckman Coulter Life Sciences) flow cytometers and FlowJo (Tree Star, Inc.) software.

In the presence of anti‐human CD107a (clone eBioH4A3; eBioscience) monoclonal antibody, ex vivo expanded PBMC were incubated with tumor cells at a 1:1 ratio of effector:target. After 1 h, 50 μM monensin (eBioscience) was added. Following overnight incubation and washing, the cells were treated with FcR blocking reagent for 5 min, and stained with fluorescein isothiocyanate (FTIC)‐conjugated anti‐human TCRγδ (clone B1.1; eBioscience) and APC‐H7‐conjugated anti‐human CD3 antibody (clone SK7; BD Biosciences), then analyzed by FACS Canto Ⅱ or CytoFLEX flow cytometers and FlowJo software (Tree Star).

Cytotoxicity was analyzed using annexin V (AV) and propidium iodide (PI) assays. Target cells were washed and resuspended in PBS. Then, the cells were labeled with carboxyfluorescein succinimidyl ester (CFSE) by using Cell Trace Cell Proliferation Kits (Molecular Probes) according to the manufacturer's instructions. Expanded γδ T cells were resuspended in media and incubated with CFSE‐labeled target cells. After 1 day, the cells were washed with AV‐binding buffer (BD Biosciences). The cells were treated with FcR blocking reagent for 5 min and stained with anti‐AV‐APC antibody (BD Biosciences) and PI (Biolegend). Early and late apoptosis was evaluated within the CFSE positive target cells by flow cytometry with FACS Canto Ⅱ or CytoFLEX. The data were analyzed by FlowJo software.

In vitro expanded γδ T cells were harvested and stained with the following antibodies: PE‐conjugated anti‐human TCRγδ (clone MOPC‐21; Biolegend), APC‐H7‐conjugated anti‐human CD3 antibody (clone SK7; BD Biosciences), FITC‐conjugated anti‐human CD279 antibody (clone EH12.2H7; Biolegend), and APC‐conjugated anti‐human CD272 antibody (clone MIH26; Biolegend). For analysis of the differentiation subsets, the following antibodies were used: FITC‐conjugated anti‐human TCRγδ (clone B1.1; eBioscience), APC‐H7‐conjugated anti‐human CD3 antibody (clone SK7; BD Biosciences), PE‐conjugated anti‐human CD45RA antibody (clone HI100; Biolegend), and APC‐conjugated anti‐human CD27 antibody (clone O323; eBioscience). Differentiation subsets were determined by CD45RA and CD27 expression within the γδ T cells. In some experiments, interferon‐γ (IFN‐γ) (clone 4S.B3; Biolegend) was intracellularly stained using BD Cytofix/Cytoperm™ (BD Biosciences). Data were acquired by flow cytometry. Flow cytometry was conducted by FACS Canto Ⅱ or CytoFLEX. The data were analyzed by FlowJo software.

Jurkat cells were preincubated with anti‐human PD‐L1 blocking antibody (Biolegend) for 30 min in the presence of FcR blocking Ab and then treated with 100 μM pervanadate, an inhibitor of phosphatases, which was used as a phosphorylation inducer.³⁴ In the presence of IL‐2 and Zol, PBMC and tumor cells were coincubated for 20 min and immediately fixed in a 4% paraformaldehyde solution. After washing with PBS containing 2% FBS, the cells were permeabilized with BD™ Phosflow Perm Buffer Ⅲ (BD Biosciences) for 30 min on ice. Then, they were incubated with anti‐pSHP‐2 (clone L99‐921; BD Biosciences), anti‐pAKT (Clone M89‐61; BD Biosciences), anti‐pERK1/2 (ab212153; Abcam), anti‐pSHP‐1 (ab192669; Abcam) antibody or IgG1κ isotype control for 1 h, following FcR blocking. For pSHP‐1 staining, PE‐conjugated goat antirabbit IgG Ab (ab72465; Abcam) was treated. Thirty minutes before washing the cells, FTIC‐conjugated TCRγδ (clone B1.1, eBioscience) and APC‐H7‐conjugated CD3 antibody (clone SK7; BD Biosciences) were additionally added. Flow cytometry was conducted by CytoFLEX (Beckman Coulter Life Sciences). The data were analyzed by FlowJo (Tree Star, Inc.) software to understand the phosphorylation status of SHP‐1/2, ERK1/2, and AKT.

Growth curves were analyzed by Friedman test, nonparametric repeated‐measures analysis of variance using InStat (GraphPad Software). Other results were analyzed using paired two‐tailed t tests by GraphPad Prism Ver. 6.0 software (GraphPad Software). When the p value was less than .05, the difference was considered to be significant.

We found that the proliferation of γδ T cells in the peripheral blood (PB) from healthy donors induced by IL‐2 and Zol was significantly impaired by coincubation with mitomycin C‐inactivated wild‐type (WT) Jurkat cells, which express HVEM (Figures 1A and S1). The differences between the control group, which was treated only with IL‐2 and Zol (IL‐2 + Zol(−)), and the groups coincubated with WT Jurkat in the absence or presence of anti‐PD‐L1 were statistically significant at Day 10. To determine whether blocking BTLA and/or PD‐1 signaling could improve the proliferation of the γδ T cells, PBMC were cultured with HVEM^low or WT Jurkat cells in the presence or absence of anti‐PD‐L1 blocking monoclonal antibody (mAb). The HVEM^low Jurkat cells were produced using a CRISPR/Cas9 system to delete the HVEM gene. As expected, HVEM expression was downregulated in HVEM^low Jurkat cells relative to mock‐transfected WT Jurkat cells (Figure S1). The expression of PD‐L1 was not changed by the deletion of HVEM in Jurkat cells (Figure S1, lower panel).

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1 Figure. Blocking BTLA/HVEM interactions increase γδ T cell proliferation. (A) αβ T cell‐depleted PBMCs were cultured with inactivated Jurkat cells with or without anti‐human PD‐L1 blocking antibodies in the presence of IL‐2 and zoledronate(−). The gating strategy is shown in Figure S2. The frequency of γδ T cells (CD3+TCRγδ+) was determined by flow cytometry. The absolute numbers of γδ T cells (CD3+TCRγδ+) was calculated at the indicated days. Data were shown as mean ± SEM of six independent experiments (donor no. n = 6, except n = 3 for isotype control group). Friedman test was performed (*p < .05). (B) After EF670‐labeling, PBMCs were stimulated as described above. The top plots were only treated with IL‐2 and zoledronate(−) (Zol) and the lower plots were cultured with inactivated leukemic cells as indicated on the left. Cells were harvested at 6 or 8 days after culture, and the proliferation was determined by EF670 dilution by flow cytometry. Representative histograms are shown out of three independent experiments. (C) Experiment was performed as above, except that BTLA/HVEM blocking peptides and anti‐PD‐1 mAb were used instead of HVEMlow Jurkat cells and anti‐PD‐L1 Ab(−), IL‐2‐ and Zol‐treated. BTLA, B‐ and T‐lymphocyte attenuator; HVEM, herpes virus entry mediator; IL‐2, interleukin‐2; mAB, monoclonal antibody; mIgG1k, isotype control; PBMC, peripheral blood mononuclear cell; PD‐1, programmed cell death‐1; PD‐L1, programmed death‐ligand 1

The inhibited proliferation of the γδ T cells in coculture with WT Jurkat cells was rescued by HVEM^low Jurkat cells (Figure 1A; p = .065). The gating strategy to identify γδ T cells was depicted in Figure S2. HVEM^low HL‐60 cells also increased γδ T cell proliferation, compared with WT HL‐60 cells (Figure S3A,B). Blocking PD‐1/PD‐L1 signaling increased the number of γδ T cells only in the presence of HVEM^low Jurkat cells. The treatment with anti‐PD‐L1 mAb alone failed to increase γδ T cell proliferation when BTLA/HVEM signaling was intact. These results were confirmed by EF670 dilution, as seen in Figure 1B. By Day 8, EF670^low/− proliferating cells were 97.5% when treated only with IL‐2 and Zol. Deletion of HVEM in Jurkat cells rescued the proliferating cells over 95% at Day 8, compared with 57.3% when cultured with WT Jurkat cells. The averages of the results were summarized in Figure S4. The treatment of BLTA/HVEM blocking peptides during culture increased γδ T cell proliferation which was inhibited by WT Jurkat cells, and anti‐PD‐1 Ab alone did not increase it (Figure 1C). Taken together, these results suggest that reduction of BTLA/HVEM signaling is a prerequisite for the optimal proliferation of Vδ2 γδ T cells, whereas PD‐1/PD‐L1 signaling has a limited role in their proliferation.

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2 Figure. Blocking the BTLA/HVEM interaction reduces the terminally differentiated γδ T cell subset. (A) PBMC from healthy donors expanded in the presence of IL‐2 and zoledronate (Zol) for 14 days. Representative dot plots showing the phenotype of baseline or in vitro expanded cells (left panels) and the CD45RA and CD27 expression of the γδ T (CD3+TCRγδ+) cells (right panels). Representative data are shown out of three to four independent experiments using distinct donors. (B) PBMC were activated in the indicated culture condition for 14 days. The frequency of differentiation subsets in the in vitro expanded γδ T cells. The following subtypes were used for analysis: T naive (CD45RA+CD27+), TCM (CD45RA−CD27+), TEM (CD45RA−CD27−), and TEMRA (CD45RA+CD27−). Data were shown as mean ± SEM of three to four independent experiments using distinct donors per groups. BTLA, B‐ and T‐lymphocyte attenuator; HVEM, herpes virus entry mediator; IL‐2, interleukin‐2; PBMC, peripheral blood mononuclear cell; TCM, central memory T; TEM, effector memory T; TEMRA, terminally differentiated T. Paired t test was used (**p < .01 and p = .0093)

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3 Figure. The targeted cell death by in vitro expanded γδ T cells was not altered by the blockade of BTLA/HVEM interaction. WT Jurkat cells were stained with CFSE and incubated with in vitro expanded γδ T cells at an effector to target cell ratio of 1:1 for 1 day. Cells were harvested and stained with PI and annexin V to detect apoptosis by flow cytometry. (A) Gating strategy to evaluate the PI and annexin V positive cells among the target cells. (B) Representative dot plots showing the proportion of early apoptosis (PI−Annexin V+) and late apoptosis (PI+Annexin V+) in the CFSE+ target cells. Left panel indicates the baseline (Day 0) and the right panel indicates after 1 day of incubation Representative data are shown out of three to seven independent experiments using distinct donors. (C) The percentage of PI−Annexin V+ apoptotic target cells in the experimental group were normalized by dividing by that of the control group Data were shown as mean ± SEM of three to seven independent experiments (donor no. n = 3–7). BTLA, B‐ and T‐lymphocyte attenuator; CFSE, carboxyfluorescein succinimidyl ester; HVEM, herpes virus entry mediator; mIgG1k, isotype control; PI, propidium iodide; WT, wild‐type. Paired t test was used (*p < .05 and p = .0471)

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4 Figure. Blockade of the BTLA/HVEM signaling does not affect the degranulation of in vitro expanded γδ T cells. (A) Representative histograms showing CD107a expression in the γδ T cells. Gray lines indicate the isotype control. (B) Cells were expanded in the indicated culture condition for 14 days. In the presence of anti‐human CD107a mAb, in vitro expanded γδ T cells with the indicated inactivated cells (on top) were incubated overnight with WT Jurkat (upper panel) or HVEMlow Jurkat (lower panel) cells. Representative data are shown out of three to four independent experiments using distinct donors. (C) The percentages of CD107a+ γδ T cells in the anti‐PD‐L1 treated group were normalized by dividing by that of the untreated group. Data were shown as mean ± SEM of three to four independent experiments using distinct donors. Paired t test was used (*p < .05). Each P value is .0190, .0345, and .0103 from left to right. (D) The gating strategy to identify intracellular IFN‐γ is depicted. (E) Expanded γδ T cells with the indicated inactivated cells (on top) were incubated overnight with WT Jurkat cells in the presence of BTLA/HVEM blocking peptides and anti‐PD‐L1 Ab or adequate controls for IFN‐γ intracellular staining. (F) The percentages of IFN‐γ+ γδ T cells were summarized. N = 2. BTLA, B‐ and T‐lymphocyte attenuator; HVEM, herpes virus entry mediator; IFN‐γ, interferon; mAB, monoclonal antibody; PD‐L1, programmed death‐ligand 1; WT, wild‐type

PD‐1 expression on γδ T cells was assessed to determine whether the reduction of BTLA/HVEM or PD‐1/PD‐L1 signaling during the ex vivo expansion altered PD‐1 expression on the γδ T cells. Stimulation with IL‐2 and Zol for 10 days significantly upregulated BTLA and PD‐1 expression on the γδ T cells, and reduction of BTLA and PD‐1 signaling did not change BTLA and PD‐1 expression on the γδ T cells (Figure S5).

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5 Figure. BTLA/HVEM and PD‐1/PD‐L1 signals do not additively activate the downstream molecules. Phosphorylation of AKT, ERK1/2, and SHP‐2 in γδ T cells was measured by flow cytometry. WT or HVEMlow Jurkat cells were pretreated with anti‐human PD‐L1 antibody for 30 min. In the presence of pervanadate, PBMCs were stimulated with IL‐2 and zoledronate and coincubated with indicated cells for 20 min. After fixation/permeabilization by PFA and methanol, the cells were stained with anti‐human CD3, TCRγδ, phospho‐AKT, ERK, and SHP‐2 Abs. (A) The gating strategy was depicted. (B) Representative histograms are shown. (C, F) The percentages and mean fluorescence indices of pAKT. Data were shown as mean ± SEM of eight to nine independent experiments. (D, G). The percentages and mean fluorescence indices of pERK1/2. Data were shown as mean ± SEM of three independent experiments. (E, H) The percentages and mean fluorescence indices of pSHP‐2. Data were shown as mean ± SEM of eight to nine independent experiments. BTLA, B‐ and T‐lymphocyte attenuator; HVEM, herpes virus entry mediator; IL‐2, interleukin‐2; PBMC, peripheral blood mononuclear cell; PD‐1, programmed cell death‐1; PD‐L1, programmed death‐ligand 1; SHP, src homology region 2 domain‐containing phosphatase; WT, wild‐type. Paired t test was used (*p < .05). Individual p values as below: (C) p = .0384 and 0.0311 from left to right; (E) p = .0480; (F) p = .0307; (H) p = .0377

It has been suggested that the more differentiated T cells are, the less antitumor efficacy they have,³⁵ and thus the subsets of expanded γδ T cells were analyzed by flow cytometry. As seen in Figure 2, coincubation with HVEM^low Jurkat cells reduced the proportion of terminally differentiated CD27⁻CD45RA⁺ γδ T cells significantly, compared with that incubated with WT Jurkat cells. Coincubation with WT Jurkat cells slightly increased the number of CD27⁺CD45RA⁺ naïve T cells, and coincubation with HVEM^low Jurkat cells in the presence of PD‐L1 blockade increased the number of CD27⁺CD45RA⁻ central memory T cells, although the differences were not statistically significant. These results imply that inhibiting BTLA signaling pathway during expansion could be beneficial for cancer immunotherapy by preventing terminal differentiation of γδ T cells.

To evaluate the effect of a blockade of BTLA/HVEM and PD‐1/PD‐L1 signaling on the effector function of γδ T cells, PBMCs were treated with anti‐human PD‐L1 mAb while cocultured with HVEM^low Jurkat or WT Jurkat cells in the presence of IL‐2 and Zol. We then examined the antitumor activity of ex vivo expanded γδ T cells using PI and AV in tumor cells. The cells expanded under the conditions shown in Figure 4 were incubated with the same number of CFSE‐labeled Jurkat cells for 1 day (Figure 3A). PBMC proliferated by IL‐2 and Zol treatment effectively induced apoptosis in all Jurkat cell lines (Figure 3B,C). Likewise, γδ T cells cultured with WT Jurkat cells or HVEM^low Jurkat cells caused apoptosis of the target cells comparable to the PBMC control group. Contrary to expectations, anti‐PD‐L1 mAb treatment did not increase both the early and late apoptosis of the target cells, despite increased expression of CD107a (Figure 4).

The expanded γδ T cells were challenged by HVEM^low Jurkat or WT Jurkat cells, and then, CD107a expression was measured to detect the degranulation of the ex vivo expanded γδ T cells. Ex vivo expanded γδ T cells in all five groups expressed similar levels of CD107a in response to HVEM^low Jurkat and WT Jurkat cells. Inhibitory signaling by the WT and the HVEM^low Jurkat cells did not affect the degranulation of γδ T. However, the expression of CD107a on γδ T cells cocultured with HVEM^low Jurkat cells was significantly upregulated by the additional inhibition of PD‐L1 signaling. Taken together, PD‐L1 signaling, rather than HVEM signaling, regulated the degranulation of γδ T cells. The experiments with HVEM^low HL‐60 cells also had no significant effect on degranulation (Figure S6). Collectively, the reduced HVEM signaling did not alter the target cell death by γδ T cells during the culture as well as the reaction period.

γδ T cells could produce cytokines, such as IFN‐γ, upon stimulation. Thus we assessed intracellular IFN‐γ by flow cytometry (Figure 4D,E). γδ T cells were cultured with inactivated WT or HVEM^low Jurkat cells in the presence or absence of anti‐PD‐L1 Ab for 2 weeks, and the cells were stimulated with WT Jurkat cells in the presence of BTLA/HVEM blocking peptides and/or anti‐PD‐L1 Ab to measure intracellular IFN‐γ. Blocking PD‐1 signaling clearly increased IFN‐γ production, whereas that of BTLA had only minor effects. In summary, the reduction of BTLA signaling during expansion did not affect the function of γδ T cells.

BTLA and PD‐1 control cell proliferation and apoptosis through downstream molecules, such as AKT, ERK, and SHP‐2, which mediate T cell activating and inhibitory signalings, respectively. Thus, we next investigated the effects of immediate BTLA/HVEM and PD‐1/PD‐L1 signaling on the phosphorylation of AKT, ERK, and SHP‐2 in resting γδ T cells. PBMCs were incubated with WT Jurkat or HVEM^low Jurkat cells and/or anti‐PD‐L1 mAb in the presence of IL‐2 and Zol for 20 min, and the expression of the phosphorylated protein was evaluated in γδ T cells by flow cytometry. We observed that the phosphorylation of AKT was increased slightly by blockade of the PD‐1/PD‐L1 interaction, and a reduction of BTLA/HVEM signaling in addition to it further increased pAKT, which was statistically significant in the percentages as well as MFI (Figures 5C and 5F). Likewise, coincubation with HVEM^low Jurkat cells also increased pAKT, compared with that of WT Jurkat cells. The activation of ERK was not changed in the presence of IL‐2 and Zol (Figures 5D and 5G). The induction of pSHP‐2 was slightly repressed by anti‐human PD‐L1 treatment in MFI, and inhibition of the BTLA/HVEM interaction reduced the percentage of pSHP‐2⁺ γδ T cells. However, BTLA/HVEM and PD‐1/PD‐L1 signaling had no synergistic or additive effects on the phosphorylation of SHP‐2 (Figures 5E and 5H).

The data that support the findings of this study are available from the corresponding author upon reasonable request.