Figures
Abstract
In an ongoing clinical phase I/II study, 16 pediatric patients suffering from high risk leukemia/tumors received highly purified donor natural killer (NK) cell immunotherapy (NK-DLI) at day (+3) +40 and +100 post haploidentical stem cell transplantation. However, literature about the influence of NK-DLI on recipient's immune system is scarce. Here we present concomitant results of a noninvasive in vivo monitoring approach of recipient's peripheral blood (PB) cells after transfer of either unstimulated (NK-DLI(unstim)) or IL-2 (1000 U/ml, 9–14 days) activated NK cells (NK-DLI(IL-2 stim)) along with their ex vivo secreted cytokine/chemokines. We performed phenotypical and functional characterizations of the NK-DLIs, detailed flow cytometric analyses of various PB cells and comprehensive cytokine/chemokine arrays before and after NK-DLI. Patients of both groups were comparable with regard to remission status, immune reconstitution, donor chimerism, KIR mismatching, stem cell and NK-DLI dose. Only after NK-DLI(IL-2 stim) was a rapid, almost complete loss of CD56(bright)CD16(dim/−) immune regulatory and CD56(dim)CD16(+) cytotoxic NK cells, monocytes, dendritic cells and eosinophils from PB circulation seen 10 min after infusion, while neutrophils significantly increased. The reduction of NK cells was due to both, a decrease in patients' own CD69(−) NCR(low)CD62L(+) NK cells as well as to a diminishing of the transferred cells from the NK-DLI(IL-2 stim) with the CD56(bright)CD16(+/−)CD69(+)NCR(high)CD62L(−) phenotype. All cell counts recovered within the next 24 h. Transfer of NK-DLI(IL-2 stim) translated into significantly increased levels of various cytokines/chemokines (i.e. IFN-γ, IL-6, MIP-1β) in patients' PB. Those remained stable for at least 1 h, presumably leading to endothelial activation, leukocyte adhesion and/or extravasation. In contrast, NK-DLI(unstim) did not cause any of the observed effects. In conclusion, we assume that the adoptive transfer of NK-DLI(IL-2 stim) under the influence of ex vivo and in vivo secreted cytokines/chemokines may promote NK cell trafficking and therefore might enhance efficacy of immunotherapy.
Citation: Brehm C, Huenecke S, Quaiser A, Esser R, Bremm M, Kloess S, et al. (2011) IL-2 Stimulated but Not Unstimulated NK Cells Induce Selective Disappearance of Peripheral Blood Cells: Concomitant Results to a Phase I/II Study. PLoS ONE 6(11): e27351. https://doi.org/10.1371/journal.pone.0027351
Editor: Francesco Dieli, University of Palermo, Italy
Received: June 3, 2011; Accepted: October 14, 2011; Published: November 9, 2011
Copyright: © 2011 Brehm et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This project was supported by the “Deutsche Forschungsgemeinschaft (DFG)” (GRK 1172), “Frankfurter Stiftung für krebskranke Kinder” and “Hilfe für krebskranke Kinder Frankfurt e.V.”, the “A. Gutermuth Stiftung”, as well as the “LOEWE Center for Cell and Gene Therapy Frankfurt” funded by: Hessisches Ministerium für Wissenschaft und Kunst (HMWK); funding reference number: III L 4- 518/17.004 (2010). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Advanced cell therapy trials with donor natural killer (NK) cells post haploidentical stem cell transplantation (haplo-SCT) provide a promising treatment option for patients with high risk leukemia and tumors. While the established T cell therapies are associated with the risk of graft-versus-host disease (GvHD), NK cells may mediate graft-versus-leukemia/tumor (GvL/T) effects without induction of GvHD. Therefore, immunotherapy with highly purified NK cell donor lymphocyte infusions (NK-DLI) in recipients of haplo-SCT could serve as an attractive alternative cell therapy [1]–[3].
NK cells are key players of the innate immune system, able to distinguish between healthy and malignant cells. NK cell cytotoxicity is mediated by a balance of activating and inhibitory signals [4]. Activating receptors like the natural cytotoxicity receptors (NCR) NKp30, NKp44, and NKp46 and the NK group 2D (NKG2D) receptor trigger cytotoxicity against malignant cells [5]. In contrast, the predominance of inhibitory signals is mediated by killer immunoglobulin-like receptors (KIR) [6]–[8]. Human CD56+CD3− NK cells in the peripheral blood (PB) can be subdivided into a major CD56dimCD16+ population which is highly cytotoxic and a smaller immune regulatory CD56brightCD16dim/− population with a potent cytokine producing capacity [9]. In the early phase of reconstitution post SCT, an unusually high percentage of CD56brightCD16dim/− NK cells can be determined, which gradually declines in the post-transplant period [10]. A part of these emerging cells are immature with impaired cytotoxic function [11], which makes adoptive donor NK cell immunotherapy post SCT needful to enhance GvL/T effects. To date, first trials and ongoing clinical phase I/II studies show the feasibility of using freshly purified or interleukin-2 (IL-2) activated NK-DLIs for the treatment of high risk patients suffering from leukemia or tumors in both, non-transplant settings and after haplo-SCT as an additional immunotherapy [1]–[3], [12]–[16]. These first immunotherapy trials show that NK-DLIs are infused without immediate adverse events. Moreover, a clinical benefit was reported by Rubnitz et al. showing a 2-year event-free survival of 100% for ten children with favorable- and intermediate-risk acute myeloid leukemia (AML) in first complete remission post haploidentical NK cell immunotherapy [3].
However, to date there is a lack of literature concerning studies investigating the influence of allogeneic NK-DLIs on the immune system of the host. Here, we present concomitant data about the noninvasive approach of an in vivo monitoring of recipient's cells of the innate and adaptive immune system following treatment with unstimulated in comparison to IL-2 activated NK cells post haplo-SCT. Quantification of various leukocyte subsets together with analysis of cytokine/chemokine plasma levels before and after NK-DLI applications revealed novel information on the immune status of patients undergoing adaptive NK cell therapies.
Materials and Methods
Ethics Statement
The study was approved by the Medical Ethics Committee of the Frankfurt University Hospital in 2003 (Ref. number 262/03). Written informed consent was obtained from all children and parents/legal guardians of the children.
Study design of phase I/II NK cell immunotherapy
Between 2003 and 2011, 16 pediatric patients suffering from high risk leukemia or tumors underwent haplo-SCT and additionally received NK cells from their respective donor (Clin Gov No. NCT 01386619, Table 1+2). For haplo-SCT, peripheral blood stem cells (PBSC) were purified immunomagnetically either by CD34-selection or CD3/CD19-depletion (Clin Gov No. NCT 00945126) as described previously [16], [17]. After haplo-SCT, highly purified donor NK cells were transfused around (+d 3), +d 40 and +d 100 as we described earlier (Fig. S1A+B) [1], [12], [18]. So far, nine patients received highly purified, freshly isolated unstimulated NK cells (NK-DLIunstim, group I) and nine patients were treated with further ex vivo IL-2 activated NK cells along with their corresponding ex vivo secreted cytokines/chemokines (NK-DLIIL-2 stim, group II). In two patients both, NK-DLIunstim and NK-DLIIL-2 stim were administered (No. 8 and 9). In summary, 29 NK-DLIs were transfused (n = 15 NK-DLIIL-2 stim and n = 14 NK-DLIunstim); of those 14 freshly and 15 following cryopreservation (Table 2 and Fig. S1A+B). According to the study protocol, cryopreservation was an option to verify two to three NK cell applications and reduce the physical loading of repeating leukapheresis for the donors. Targeted cell doses were ≥1×107/kg BW CD56+CD3− NK cells, with <1×105/kg BW contaminating CD3+ T cells. Defined study exclusion criteria prior to NK-DLI were graft failure or patients with persisting acute or chronic GvHD. Study discontinuation criteria were severe GvHD (≥grade III) or other toxicities.
Purification of CD56+CD3− NK cells, ex vivo activation and quality control
NK cells were collected from two unstimulated leukapheresis products, without G-CSF stimulation, from healthy haploidentical donors. The two-step purification procedure (CliniMACSs cell selection system; Miltenyi Biotec, Bergisch Gladbach, Germany) included first a CD3+ T cell depletion step with an ensuing CD56+ NK cell selection from the CD3− fraction, obeying good manufacturing practice (GMP) as we described previously [1], [18]. In case of group I patients receiving NK-DLIunstim, the leukapheresis was performed at day −10 prior and +40 post SCT (Fig. S1A). At day +40, NK-DLIunstim was split while one part was applied freshly directly at the end of the purification process, and the other part was cryopreserved for the day +100 application. The processed NK-DLIunstim from day −10 was also split and cryopreserved for the NK cell applications on day +3 and +100. For cryopreservation, NK cell products were concentrated and resuspended in X-VIVO 10 media diluted 1∶2 with 20% dimethyl sulfoxide (DMSO).
In case of group II patients receiving NK-DLIIL-2 stim, two leukapheresis products collected on day +29 and +30 post SCT were pooled for the NK cell purification process (Fig. S1B). Following the two-step CD3-depletion/CD56-selection purification procedure, NK cells were further expanded and activated using 1000 U/mL rhIL-2 (Proleukin® Novartis Pharma GmbH, Nürnberg, Germany) for 10 (9 to 14) days obeying GMP. NK cells were cultured in X-VIVO 10 media in VueLife™ cell culture bags (CellGenix Technology, Freiburg, Germany), supplemented with 5% heat-inactivated human fresh frozen plasma (Red Cross Blood Donor Service, Baden-Württemberg-Hessen, Frankfurt, Germany) at 37°C and 5% CO2. Fresh media and IL-2 were added every three days. Following the ex vivo stimulation, the NK cell product was split up, while one half was infused freshly at day +40 and the other was cryopreserved and applied at day +100 post SCT (Fig. S1B).
For quality control, analyses of purity of NK cells, residual T cells, cell viability, NK cell receptor repertoire (NCRs, NKG2D) and cytotoxic activity against K562 cells were performed [16], [19].
Sample collection and preparation
Immune reconstitution of various leukocyte subsets in the PB of all patients was monitored regularly; within the first three months post SCT weekly, from month four to six twice a month, followed by a period of monthly analyses. For our concomitant in vivo monitoring during NK-DLI, PB samples were collected before (pre), 10 min, 1 h, 4 h and 24 h after the end of NK cell infusion (Fig. S1C). Flow cytometric analyses were performed within 4 h. For cytokine/chemokine analyses, plasma of PB samples collected during in vivo monitoring and supernatants of NK-DLIIL-2 stim collected immediately prior to infusion, were stored at −80°C until analysis.
Flow cytometric analysis for quantification of leukocyte subsets and cytotoxicity assay
Flow cytometric analyses were performed to determine (i) quality control of the administered NK-DLI, (ii) the specific influence of NK-DLI on the patient's immune system and (iii) the overall cellular immune reconstitution post SCT in all 16 patients. Monoclonal antibodies (mAB) conjugated with fluorescein-isothiocyanate (FITC), phycoerythrin (PE), phycoerythrin-Texas Red®tandem (ECD), phycoerythrin-cyanine-5 (PC-5) and phycoerythrin-cyanine-7 (PC-7) were used against following antigens (clones): CD3 (UCHT1) and (SK7)#, CD4 (13B8.2), CD4 (SFCI12T4D11), CD8 (SFCI21Thy2D3(T8)), CD14 (RMO52)2, CD14+CD16 (RMO522+3G8), CD16 (3G8), CD19 (J3-119), CD33 (D3HL60.251), CD45 (B3821F4A)1, CD45 (J.33), CD56 (N901) and (NCAM16.2)1#, CD62L (DREG56), CD69 (TP1.55.3)1, CD85k/ILT-3 (ZM3.8), CD123 (107D2), CD336/NKp44 (Z231), (1IgG2b, 2IgG2a, all other IgG1 isotypes) (#BD Biosciences, Heidelberg, Germany, all other Beckman Coulter, Marseille, France). For assessment of viability 7-Amino-Actinomycin D (7-AAD) was used. An automated lyse/no-wash procedure was used with a fixation step on a TQ-Prep™ Workstation (Beckman Coulter, Krefeld, Germany). Absolute lymphocyte subset counts were calculated via leukocyte counts measured by Coulter® Ac.T diff™Counter (Beckman Coulter, Krefeld, Germany). Measurements of myeloid DC, plasmacytoid DC and NK cells were carried out in a single-platform approach using Flow-Count™ fluorospheres (Beckman Coulter, Marseille, France) [17], [20]. On both, CD56dimCD16+ and CD56brightCD16dim/− NK cells, surface expression of NKp44, CD69 activation and the lymph node homing molecule CD62L were investigated. NK cell cytotoxicity of NK-DLIIL-2 stim and NK-DLIunstim was tested against the MHC class I negative cell line K562 at the ratios 1∶1 and 10∶1 based on a 5-color flow cytometric single platform assay (Fig. S2A) [19]. Cytotoxicity was defined as the loss of viable target cells in relation to the mono-cultured control. All analyses were performed on a 4- or 5-color flow cytometer, respectively (EPICS® L™and FC500, Beckman Coulter, Krefeld, Germany) and data were further analyzed using CXP v2.2 software (Beckman Coulter, Krefeld, Germany).
Cytokine and chemokine analysis
Cytokines and chemokines in the plasma of PB samples obtained during in vivo monitoring and supernatants of the 9–14 days stimulated NK-DLIIL-2 stim were measured using BD™ Cytometric Bead Array (CBA) in combination with the BD FACSArray™ bioanalyzer (BD Biosciences, Heidelberg, Germany). The human Flex Set was used to detect the secretion of interleukin (IL) -1β, IL-2, IL-4, IL-6, IL-7, IL-8, IL-10, IL-12p70, IL-12/IL-23p40, IL-13, tumor necrosis factor-α (TNF-α), TNF-β, interferon-γ (IFN-γ) IFN-γ-inducible protein (IP-10), monocyte chemotactic protein-1 (MCP-1), macrophage inflammatory protein-α (MIP-1-α), MIP-1β, regulated on activation, normal T cell expressed and secreted (RANTES), Fas ligand (FasL), granulocyte colony-stimulating factor (G-CSF), granulocyte macrophage colony-stimulating factor GM-CSF. In short, 50 µl of the provided standards or plasma samples were mixed with capture beads specific for one cytokine and PE detection, and processed according manufacturer's instructions. The assay lower detection limit ranged from 0.2 to 14.7 pg/ml.
KIR and HLA genotyping and chimerism analysis
Typing of KIR genes in PB of both, donors and patients was performed by PCR-sequence-specific primers and was used to detect the presence or absence of 19 KIR genes (2DL1-5B, 3DL1-3, 2DS1-5, 3DS1, 2DP1, 3DP1) as described previously [21]. HLA were typed using sequence-specific probes and sequence-based typing (SBT) analysis. KIR/HLA-ligand matching or mismatching in donor-recipient pairs was evaluated using the KIR receptor – HLA-ligand mismatch model (“missing KIR ligand model”). For quantitation of donor chimerism in the PB and bone marrow (BM), a semi-quantitative PCR assay based on the amplification of short tandem repeat (STR) markers was used [22].
Statistical Analyses
Statistical analyses were performed using GraphPad Prism 5.03 (GraphPad Software, San Diego, USA). Biological data were compared by paired Student t test, Wilcoxon matched-pairs signed rank test and Mann-Whitney-test depending on paired or unpaired and Gaussian or non-Gaussian distribution of values. Differences were considered as significant for p<0.05, p<0.01, and p<0.001 indicated as *, **, and ***, respectively.
Results
Comparison of NK-DLIunstim and NK-DLIIL-2 stim
In a clinical phase I/II study, 16 pediatric patients received either freshly isolated, unstimulated NK-DLIs (NK-DLIunstim; group I) or ex vivo IL-2 stimulated NK-DLIs (NK-DLIIL-2 stim; group II) from their respective donors, from one up to three times post haplo-SCT (Table 2). According to the study protocol, the median application date post SCT was day +2 (range 2–3), +42 (range 11–54) and +101 (range 70–126). After processing, the median purity of the CD56+CD3− NK cell product was 95% (range 84.4–98.6). The majority of the concomitant cells were antigen presenting cells like monocytes and dendritic cells (mDC, pDC) as we could show previously [23]. The overall median yield during processing procedure was 54% (range 38.7–84.1). Patients of both groups received similar NK cell doses in the DLI: 14.6×106/kg BW (range 6.0–45.1) and 13.1×106/kg BW (range 3.2–38.3) for NK-DLIIL-2 stim and NK-DLIunstim with no differences between freshly and cryopreserved DLIs. Concomitant CD3+ T cells in the NK-DLI were higher in group II with a median of 34.6×103/kg BW (range 7.7–98.3) compared to 4.3×103/kg BW (range 0.4–53.4) in group I patients. Concerning fresh NK-DLIs this difference was not statistically significant, thus a statistical difference was seen in regard to all NK-DLI applications. Of note, of these overall CD3+ cells, in group II approximately two-thirds belonged to the CD56+CD3+ NK-like T cells and one-third to CD56−CD3+ T cells, only. Median NK cell cytotoxicity against MHC class I negative K562 cells in the effector∶target ratios 1∶1 and 10∶1 was 67% and 88% for NK-DLIIL-2 stim compared to 30% and 75% for NK-DLIunstim (Fig. S2A). The improved cytotoxicity of NK-DLIIL-2 stim was related to a high up-regulation of the activating receptors NKp30, NKp44, NKp46 and NKG2D. The CD69 activation marker expression was strongly enhanced as well, whereas the lymph node homing molecule CD62L was significantly down-regulated upon IL-2 stimulation as we showed previously [16]. Freshly administered NK-DLIunstim showed a high viability (median 93%) compared to NK-DLIIL-2 stim which showed a decrease in vital NK cell count to 30–70% during the first three days, followed by a period of enhanced growth and increasing viability during 9–14 days of IL-2 expansion [16], [18].
The applied CD34+ stem cell dose in the graft was similar in both groups with a 6.2 times higher CD3+ T cell count in grafts of group II compared to group I patients (13.5×103/kg BW vs. 84.5×103/kg BW, difference not significant). This was due to a change in graft purification from CD34-selection to CD3/CD19-depletion (Table 1). Therefore, patients transplanted with CD3/CD19 depleted grafts received mycophenolate mofetil (MMF) as an immunosuppressive therapy to avoid severe GvHD and graft rejection. Because of a possible negative impact of MMF on NK cell functionality, the early time point of NK-DLI at day +3 post SCT has been omitted for these patients. To validate if the differing graft purifications in group I have any influence of our presented results, we exemplarily excluded the four patients receiving CD34 selected grafts from our analyses, whereof only two fresh NK-DLIunstim were applied (data not shown). Since we did not see any differences in our results and it confirmed the overall conclusion, we decided to remain with the total patient group.
NK-DLI was well tolerated in both groups, besides transient fever and chills for 24 h in group II patients receiving NK-DLIIL-2 stim. In two patients (No. 9 and 13) steroids were temporarily administered during NK-DLI because of more adverse effects (vomiting and blood pressure fluctuation). Patients of group II did not develop GvHD>grade II in response to NK-DLIIL-2 stim, independent of the amount of stimulated T cells. In group I, one patient (No. 1) treated with NK-DLIunstim containing >50.000×103/kg BW CD3+ cells and the patient with the highest amount of residual T cells in the graft (No. 5) developed GvHD>grade II. Following the full myeloablative conditioning regime, patients were in aplasia until engraftment was seen in both patients' subgroups, excluding patient No. 2 and No. 16, on days 7, 12 and 14 for platelets (>50.000/µl), leukocytes (>1000/µl) and neutrophils (>1000/µl), respectively.
Therefore, data of all day +3 NK-DLIunstim applications were not evaluable, since to that early time point post SCT, patients were still in aplasia (median cell counts in PB at day +3: leukocytes 120/µl, lymphocyte 0/µl, NK cells 0/µl, monocytes 0/µl). Because infusion of NK-DLIunstim at day +3 did not lead to any changes, analyses were not included in any of the following figures. Specific immune reconstitution of CD56+CD3− NK cells post haplo-SCT was very similar in both groups (Fig. S2B). Chimerism analyses of PB and bone marrow beginning between day +11 and +15 showed complete donor chimerism in 14/16 patients to that early time point post SCT. Complete chimerism retained in 14/16 patients at day +40 and in 14/15 at day +100 post haplo-SCT (Table 1). Also subtype chimerism analyses of CD56+ NK cells were performed in 5/16 patients which reflected results of total PB and BM chimerism (data not shown). The only patient that did not reach complete chimerism at day +40 (No. 2) rejected the stem cell graft and underwent a second SCT. Further, in patient No. 16 no chimerism analyses could be performed because of failure of immune reconstitution and early death at day +27.
Overall, 7/9 patients receiving NK-DLIIL-2 stim and 5/9 receiving NK-DLIunstim have not been in remission (NR) or in partial remission (PR) at the time point of SCT, while all patients in remission were ≥second complete remission (CR2). Furthermore, 44% of these high risk patients are alive with regard to both NK-DLIIL-2 stim and NK-DLIunstim groups with a mean follow up of 20 and 45 months, respectively. KIR mismatch was seen in 6/9 patients of group I and 8/9 in group II in GvL/T direction and in 6/9 in both groups in HvG direction (Table 2). Nevertheless, in this heterogeneous patient cohort, no clear influence on survival, GvHD and rejection with regard to KIR mismatch could be seen.
Of note, effects of NK-DLIIL-2 stim application on PB leukocytes in patient No. 16 were not evaluable because of failure of immune reconstitution (Table 1). Further, measurements of the 2nd NK-DLIIL-2 stim application of patient No. 14 (d +98, cryopreserved) were excluded, since the DLI has been washed prior to administration because the patient had shown severe reaction to DMSO previously.
NK-DLIIL-2 stim but not NK-DLIunstim led to a significant decrease of CD56+CD3− NK cells in patient's PB
Monitoring of the leucocyte subsets in patient's PB before and 10 min, 1 h, 4 h and 24 h after NK-DLI was performed to receive first insights of the host immune reaction on donor NK cell immunotherapy (Fig. S1C). We focused our main interest on fresh NK-DLI applications, because the cryopreservation process (cell centrifugation, concentration in a smaller volume and dilution in DMSO) results in cell count and cytokine/chemokine reduction and could lead to an impairment of NK cell and cytokine functionality.
All NK cell infusions were associated with a reduction in circulating NK cells within 10 min of infusion, but this was significantly greater in patients receiving NK-DLIIL-2 stim (Fig. 1A fresh NK-DLIs). After a 5.5-fold decrease in absolute NK cell counts 10 min post infusion of freshly applied NK-DLIIL-2 stim in contrast to NK-DLIunstim (1.2-fold) (Fig. 1B, left), NK cell counts recovered within 24 h to prior values. DLI volume did not artificially lead to the reduced absolute NK cell count, since NK-DLIIL-2 stim volumes made up around ¼ of patient's PB volume, respectively (Fig. 1B, middle). In addition, in both subgroups the ratio of the administered NK-DLI dose compared to the patient's NK cells in the PB newly reconstituted post haplo-SCT was very similar (Fig. 1B, right). Importantly, the decrease in CD56+CD3−NK cells was not due to a down-regulation or loss of CD56 expression (Fig. S3B).
A) Absolute number of NK cells in the PB of the patients was significantly reduced 10 min post NK-DLIIL-2 stim (grey) in contrast to NK-DLIunstim (white), which showed minimal influence only. 24 h after NK-DLIIL-2 stim absolute number of NK cells recovered to the level before DLI. Only freshly applied NK-DLIs infused around day +40 post SCT are shown and were used for statistical calculations (n = 7 NK-DLIIL-2 stim, n = 6 NK-DLIunstim). Box and whiskers plots show minimum, lower quartile, median, upper quartile and maximum of all measured data. For the 4 h level post NK-DLIunstim two values were available, only. p<0.05 indicated as *. B) Mean and SEM of all freshly applied NK-DLIIL-2 stim (grey) and NK-DLIunstim (white) applied around day +40 post SCT. Striped bars indicate estimated patient's PB volume and peripheral NK cell count at the time point of NK-DLI infusion. Left graph shows a mean 5.5-fold reduction of absolute NK cell count in the PB as early as 10 min post NK-DLIIL-2 stim compared to a 1.2-fold decrease for NK-DLIunstim. Middle graph shows relation of NK-DLI volume to total blood volume of patients (NK-DLIIL-2 stim volume: 825 ml±249, compared to PB volume: 3060 ml±789; NK-DLIunstim volume: 128 ml±19, compared to PB volume 3093 ml±749). DLI volume did not artificially lead to the reduced absolute NK cell count, since NK-DLIIL-2 stim volumes made up maximally around ¼ of patient's PB volume. Right graph shows mean NK-DLI cell dose ×106/kg BW (NK-DLIIL-2 stim 19.2±4.5; NK-DLIunstim 18.8±5.1) in relation to patient's PB NK cells newly reconstituted post haplo-SCT around d +40 prior to NK-DLI (NK-DLIIL-2 stim 26.0±8.5; NK-DLIunstim 31.9±4.0). Applied NK dose compromised about 80% of PB NK cells, illustrating the high dose of administered NK-DLI. C) Density plots (CD56 vs. CD16) and box and whiskers plots show a significant change in the distribution of the cytotoxic CD56dimCD16+ and immune regulatory CD56brightCD16dim/− NK cell subsets. This was due to an absolute reduction of the CD56brightCD16dim/− NK cell subpopulation in the PB 10 min after freshly applied NK-DLIIL-2 stim applications infused around d +40 (left; n = 7). This could not be shown after NK-DLIunstim (right; n = 6). Plots are gated on CD56+CD3− NK cells. For the 4 h level post NK-DLIunstim 2 values were available, only. p<0.05 indicated as *.
Effects of total NK-DLIIL-2 stim applications (fresh and cryopreserved) were similar, thus NK cell disappearing was delayed, compared to the fast diminishing after fresh infusions (compare Fig. 1A and Fig. S4 total NK-DLIs).
Moreover, infusion of NK-DLIIL-2 stim led to a change in the proportion of CD56brightCD16dim/− and CD56dimCD16+ NK cell subpopulations which was due to a more pronounced loss of CD56brightCD16dim/− NK cells (Fig. 1C fresh NK-DLIs). Similar effects were seen after total NK-DLIIL-2 stim applications (Fig. S4 total NK-DLIs). Patients receiving NK-DLIunstim showed no change in the proportion of NK cell subpopulations.
Of note, NK cells with the characteristics of the ex vivo IL-2 activated phenotype (CD56brightCD16+/−CD69+NCRhighCD62L−) could not be detected in the PB at any time during in vivo monitoring, thus not returning post 24 h (Fig. S3A+B). In addition, CD62L+ expressing PB NK cells declined 10 min post NK-DLIIL-2 stim in the same manner like total NK cells, also recovering within 24 h (Fig. S3B+C). Therefore, reduction in total NK cell count post NK-DLIIL-2 stim was due to both, a rapid decrease in transferred and peripheral blood NK cells.
Loss of antigen presenting cells (APCs) in the PB after infusion of NK-DLIIL-2 stim but not after NK-DLIunstim
Shortly after infusion of NK-DLIIL-2 stim there was a significant loss of CD14+ monocytes in the PB of all patients (median 15-fold reduction). After disappearing almost completely, monocyte counts recovered within 4 to 24 h to normal values like the ones prior to infusion. This was the case following fresh NK-DLIIL-2 stim as shown in Fig. 2A, as well as after all NK-DLIIL-2 stim applications in total (Fig. S4 total NK-DLIs). In contrast, monocyte counts following NK-DLIunstim remained unaffected. Furthermore, total CD45+CD14−CD16−HLA-DR+CD85k+CD33+ myeloid dendritic cell (mDC) and CD45+CD14−CD16−HLA-DR+CD85k+CD123+ plasmacytoid dendritic cell (pDC) count also significantly decreased directly after NK-DLIIL-2 stim, recovering subsequently to normal values within 24 h to 1 week (Fig. S4). Again, these effects could not be observed after infusion of NK-DLIunstim. Measurements of DCs were carried out in a single-platform approach verifying reliable data even in low cell counts.
A) Significant reduction of absolute CD14+ monocyte count could be demonstrated in patient's PB 10 min after application of fresh NK-DLIIL-2 stim (n = 7), while recovering to normal values within the next 24 h. This was not seen after NK-DLIunstim (n = 6). Density plots show side scatter (SSC) vs. CD14 gated on CD45+ leukocytes. For the 4 h level post NK-DLIunstim 2 values were available, only. p<0.05 indicated as *. B) We observed a distinct influence of NK-DLIIL-2 stim on neutrophil and eosinophil granulocyte count. A massive increase of neutrophils (SSChighCD45lowCD16+) with its peak at 4 h was combined with a significant reduction of eosinophil granulocytes (SSChighCD45brightCD16−) in the PB after fresh NK-DLIIL-2 stim (n = 7). This was not observed after unstimulated NK cell applications (data not shown). p<0.05 indicated as *.
Distinct influence of NK-DLIIL-2 stim and NK-DLIunstim on granulocytes, and T and B cells in the PB
Following all applications of NK-DLIIL-2 stim a significant loss of eosinophil granulocytes (SSChighCD45brightCD16−) combined with a massive increase in absolute white blood cell (WBC) count was observed (average 4-fold). This was caused by an intensive gain of the main CD45+ leukocyte proportion of neutrophil granulocytes (SSChighCD45lowCD16+) leading to its peak after 4 h and then returning to normal values prior to infusion (Fig. 2B fresh NK-DLIs). Similar effects were seen after total NK-DLIIL-2 stim applications (Fig. S4 total NK-DLIs). In contrast, the distinctly increased absolute WBC count in the PB of the monitored patients could not be noted after NK-DLIunstim applications (data not shown).
According to a delayed immune reconstitution of T and B cells in the patients' PB post haplo-SCT compared to an early NK cell recovery, CD3+ T cell and CD19+ B cell counts at the time point of NK-DLI at day +40 were relatively low (median 50/µl CD3+, and 58/µl CD19+). NK-DLIIL-2stim led to a very slight decrease in absolute T cell count within 4 h post NK-DLIIL-2 stim while B cell count was not affected (data not shown).
Only after NK-DLIIL-2 stim a significant increase in cytokine/chemokine concentration in patients' PB was demonstrated, thus varying from levels from the ex vivo engineered DLI
Ex vivo IL-2 stimulation of highly purified donor NK cells led to the secretion of high amounts of various chemokines e.g. IL-8, MIP-1β, MCP-1, IP-10 and RANTES which play crucial roles in leukocyte activation and chemo-attraction, as well as the inflammatory cytokine IFN-γ (Fig. 3A). In contrast, the median concentration of the pro-inflammatory cytokine IL-6 was below 10 pg/ml. The indicated IL-2 concentration was due to the supplementary addition of 1000 U/ml IL-2 during expansion procedure. Since NK-DLIs have not been washed prior to infusion according to the study protocol, to avoid loss of NK cells, the total amount of the indicated cytokines/chemokines was applied during fresh NK-DLIIL-2 stim.
A) Box and whiskers plots show the respective cytokine/chemokine concentration present in the NK-DLIIL-2 stim product (n = 12) immediately prior to infusion. The nine to 14 days ex vivo IL-2 stimulation of highly purified donor NK cells led to the secretion of high amounts of various chemokines i.e. IL-8 and MIP-1β, as well as the pro-inflammatory cytokine IFN-γ. Whereas, the median concentration of the pro-inflammatory cytokine IL-6 was <10 pg/ml. The indicated IL-2 concentration was due to addition during expansion procedure (see Material and Methods). Y-axis shows cytokine/chemokine concentration, range 1–1.000.000 pg/ml. B) Cytokine analyses of cryopreserved plasma samples collected before (pre) and 10 min, 1 h, 4 h and 24 h after fresh NK-DLIIL-2 stim (⧫, n = 6). Significant increases of in vivo cytokine/chemokine concentration of IL-2, IL-6, IL-8, IFN-γ, MCP-1 and MIP-1β in patient's plasma following NK-DLIIL-2 stim were observed. Levels peaked after 10 min to 1 h post infusion, remained enhanced over a period of 4 h and returned to base level within the next 24 h. In contrast, no increase in cytokine/chemokine PB concentration following NK-DLIunstim was seen (•, n = 2). p<0.05 and <0.01 indicated as * and **.
In vivo analyses of cytokine/chemokine concentration in patient's PB post NK-DLIIL-2 stim revealed significant increases in plasma levels up to 4 h following infusion. The pro-inflammatory cytokine IL-6 and IFN-γ, as well as the chemokine IL-8, MCP-1 and MIP-1β plasma concentrations peaked within 10 min to 1 h post NK-DLIIL-2 stim while recovering to their base level within the next 24 h (Fig. 3B fresh NK-DLIs). In addition, high plasma levels of the chemokines IP-10 and RANTES, acting on both leukocyte activation and attraction, were detected but not varying (data not shown). Similar results post infusions of cryopreserved NK-DLIIL-2 stim were obtained, but to a slighter extent, which was probably due to a reduction in cytokine/chemokine concentration during the cryopreservation process. Nevertheless, analyses of all NK-DLIIL-2 stim in total showed identical results and did not change the overall conclusion (Fig. S4 total NK-DLIs). In comparison, no increase in plasma concentration of the indicated cytokines/chemokines following NK-DLIunstim was detected (Fig. 3B). Besides, TNF-α, TNF-β, GM-CSF, MIP-1α, FasL, IL-13 were secreted during ex vivo IL-2 NK cell expansion, but either they could not be detected in patient's PB, or NK-DLIIL-2 stim did not lead to any changes in present plasma concentrations (data not shown). IL-1β, IL-4, IL-7, IL-10, IL-12p70, IL12/23 and G-CSF were analyzed as well, but were not detected in NK-DLI and PB.
When focusing on one hand on the ex vivo cytokine/chemokine levels in the NK-DLIIL-2 stim products and on the other hand on patients' PB levels measured directly after infusion, marked variations occurred. Being aware that besides other factors i.e. dilution effects need to be considered, IL-2, IL-8, IFN-γ and especially MIP-1β were found in lower concentrations in the PB than in the NK-DLIIL-2 stim (Fig. 3A+B).
Discussion
Here we present first interesting insights from our clinical NK cell phase I/II study using allogeneic NK-DLIunstim compared to NK-DLIIL-2 stim in pediatric patients suffering from high risk malignancies. Although, we, among others, have shown that the infusion of unstimulated as well as previously ex vivo IL-2 stimulated allogeneic NK cells post haplo-SCT is well tolerated without inducing severe GvHD>grade II [2], [12], [14], [16], possible risks or disadvantages need to be critically discussed. As it stands, literature is scarce about the fate and behavior of adoptively transferred allogeneic NK cells in humans and about the potential distinct influences of unstimulated NK cells in contrast to previously ex vivo activated NK cells on patient's adaptive and innate immune system.
Several studies in animals have addressed the question concerning the capability to traffic to specific tissues, the regulation of homing, and the survival of adoptively transferred cells in vivo. NK cell trafficking to spleen, lymph nodes, lung, liver, gastrointestinal tissue and tumor side with a survival up to four weeks following transfer was observed by a bioluminescence-based strategy, which correlated with an observed anti-tumor effect [24]–[26]. However, to date only one small clinical trial in humans was performed, where three adult patients with renal cell carcinoma received stimulated allogeneic NK cells labeled with the radioactive substance Indium-111 oxine [27]. After an initial accumulation in the lungs, NK cells redistributed to liver, spleen and bone marrow as well as in two of four metastases in lung and liver. Unfortunately, it has been reported as well that Indium labeling significantly affects the cellular integrity [28]. Even though it is still of particular interest if adoptively transferred NK cells in humans actually reach their side of action, clinical trials using NK cell labeling with potentially harmful substances will not obtain approval in the treatment of pediatric malignancies. Therefore, approaches using more noninvasive strategies have to be considered. Our investigation is based on a comprehensive in vivo cytokine/chemokine monitoring and on flow cytometric analyses of quantification, constitution and distribution of various PB leukocyte subsets before and after NK-DLI application.
In our study we have reported markedly diverse effects between NK-DLIunstim and NK-DLIIL-2 stim. Shortly after infusion of NK-DLIIL-2 stim only, a rapid almost complete loss of cells dominantly from the innate immune system from patient's PB circulation appeared which was accompanied by significant increases in plasma concentration of various cytokines and chemokines. Whereas neutrophil granulocytes markedly increased within 4 h post NK-DLIIL-2 stim, monocytes, dendritic cells, eosinophils and especially NK cells massively decreased as early as 10 min post infusion, while recovering within the next 24 h.
Moreover, when analyzing NK cells more into detail, we were able to clearly discriminate between adoptively transferred and patients' PB NK cells by a distinct CD69, NCR and CD62L expression. We have shown previously that ex vivo IL-2 stimulation leads to a predominantly CD56brightCD16+/− phenotype with a strongly enhanced expression of the activation marker CD69, while CD62L becomes down-regulated. Further, surface receptors involved in NK cell cytotoxicity become highly up-regulated. While only one-third of unstimulated NK cells, a median of 95% of IL-2 stimulated NK cells show expression of NCRs. In detail, NKp44, NKp30, NKp46 and NKG2D expression significantly increased 33-fold, 12-fold, 3-fold and 4-fold, respectively [16]. Furthermore, the IL-2 stimulation led to a consistent increase in NK cell killing activity against a neuroblastoma cell line [16] and the leukemic cell line K562 (Fig. S2A). In addition, Penack et al. showed that the CD16− NK cell subset is responsible for anti-tumor responses [29].
NK cells with the characteristics of the ex vivo IL-2 stimulated phenotype (CD56brightCD16+/−CD69+NCRhighCD62L−) were not detected in patients' PB at any time point during in vivo monitoring. Furthermore, we could clearly show that the significant reduction of CD56+CD3− NK cells from blood circulation following NK-DLIIL-2 stim was due to both, a decrease in patients' own PB CD62L+ NK cells as well as a rapid diminishing of the transferred, stimulated NK cells from the NK-DLI with the CD62L− phenotype.
In contrast, PB cell subpopulations remained constant after NK-DLIunstim. This effect was not due to NK-DLI dose, a PB dilution effect after infusion, application date or host's NK cell immune reconstitution. All these variables were very similar in both, patients receiving NK-DLIunstim and those receiving NK-DLIIL-2 stim. The only difference was the IL-2 for generation of NK-DLIIL-2 stim and the high amount of cytokines and chemokines such as IFN-γ, IL-8, MCP-1, IP-10, RANTES, MIP-1β secreted in the course of ex vivo expansion. Those factors were only transfused to patients treated with NK-DLIIL-2 stim.
In accordance with our results, early studies have reported a rapid diminishing of various types of PB lymphoid cells, especially NK cells, 15 min after in vivo bolus single cytokine administration of very high doses of recombinant IL-2 (up to 1×106 U/kg BW). Similar to our study, cells also recovered within the next 24 h. Furthermore, IL-2 was rapidly cleared from the plasma with a half-life of 6.9 min [30], [31]. It has been suggested that the IL-2 induced disappearance of NK cells may be related to a massive adhesion to the activated endothelium [31], [32]. Our observed effects cannot be attributed to one single cytokine/chemokine but to the whole cytokine “cocktail” applied with the NK-DLIIL-2 stim product, but the IL-2 dose applied by our NK-DLI study was extremely lower (∼2×104 U/kg BW) in comparison to the discussed data by Lotze et al. (∼1×106 U/kg BW). Apparently, much lower concentrations of IL-2 but in combination with our indicated cytokines/chemokines administered by NK-DLIIL-2 stim led to a comparable effect to high dose single IL-2 application with regard to PB leukocyte diminishing.
Measuring cytokine/chemokine production is an integral part of measuring immune response during immunotherapy. Because cytokines act in networks and have overlapping functions, monitoring of a single cytokine may be of limited use [33]. Following NK-DLIIL-2 stim we have shown significant increases in plasma concentration of several chemotactic and inflammatory cytokines and chemokines which remained enhanced up to 4 h post DLI (Fig. 3B). The majority of the analyzed increases were probably induced by the infusion of high amounts of ex vivo generated cytokines/chemokines in the NK-DLIIL-2 stim. We assume that these changes in the natural cytokine milieu of the PB led to the observed cell migration processes. The massive increase of blood neutrophils, which represent the major early cell type to invade inflammatory foci, is likely mediated by the transfer of high amounts of IL-8 that were produced in the course of ex vivo NK cell stimulation. Notably, IL-8 has been described to be the major chemo-attractant for neutrophil granulocytes. Neutrophils are described to be potent producers of various cytokines (i.e. IL-6, IL-8, IP-10, MIP-1α/β) which may be in relation to the prolonged enhanced cytokine/chemokine levels 4 h post NK-DLIIL-2 stim application [34], [35].
Furthermore, the disappearance of various leukocyte subsets occurring only after NK-DLIIL-2 stim may be mediated by two alternative or complementary mechanisms: (i) adherence to the activated endothelium induced by high amounts of co-infused cytokines/chemokines, (ii) leukocyte migration from the PB into the extravascular compartment.
Although normal endothelial cells exhibit low affinity for circulating lymphocytes, the high amount of the cytokines and chemokines present in the PB (i.e. IFN-γ, MIP-1β, IL-8), similar to those released in the course of inflammation and other immune reactions, leads to endothelial activation associated with an increased expression of surface antigens which interact with all leukocytes [31]. This might result in endothelial adherence and therefore diminishing of leukocytes from blood circulation. Further, it is known that soluble cytokines and chemokines bind endothelial molecules including glycosaminoglycans (GAGs) and the Duffy antigen/receptor for chemokines (DARC), which are involved in the trans-endothelial transport of several chemokines, i.e. MIP-1β, IL-8, RANTES, MCP-1 and IP-10 [36]–[38]. Chemokines bound at the luminal endothelial cell surface could provide a trans-cellular chemotactic gradient guiding leukocyte extravasation [39]. Therefore, we assume that following the firm attachment to the activated endothelium, the cells migrate across the endothelium barrier into the tissue, actually leaving PB blood circulation. Although 7-AAD analyses revealed no increase in dead cells over the whole period of in vivo monitoring (data not shown), a cell reduction in PB circulation due to cell death cannot be excluded completely.
In addition to the discussed trans-endothelial transport of cytokines/chemokines, cytokine stability in circulation, renal clearance as well as dilution effects during infusion must be regarded as parameters that have likely contributed to the described discrepancy between high ex vivo levels in the NK-DLI and much lower in vivo PB levels. In our study we found a significant reduction of the immune regulatory CD56brightCD16dim/− NK cell subpopulations 10 min after NK-DLIIL-2 stim. An explanation for the overall higher susceptibility of the CD56brightCD16dim/− NK cell subpopulation might be the high expression of various chemokine receptors i.e. the MIP-1β corresponding CCR5 receptor on the cell surface of the CD56brightCD16dim/− subpopulation, only [40].
Finally, IL-6 was the only cytokine which was secreted much higher in the PB of our patients compared to those during NK cell expansion, leading us to suspect a secondary production of the patient's body in response to NK-DLIIL-2 stim. We speculate that this could be due to both, the secretion of endothelial cells in reaction to the changing cytokine milieu, neutrophil granulocytes and monocytes that transiently adhere to the endothelial surface. In addition, the increase of IL-6 in patients' blood plasma as a response to NK-DLIIL-2 stim correlated with our clinical observations of transient fever and chills; therefore serving as a surrogate marker of the biological activity of the ex vivo secreted and co-infused cytokines and chemokines.
Till now, very little is known about the effects of NK cell administration post SCT. These concomitant results to a clinical immunotherapy study provide first insights on the distinct influence of unstimulated vs. ex vivo IL-2 stimulated NK cell infusions. Nevertheless, we are fully aware that dissimilarities in the study design and the heterogeneous small patient cohort may have a potential effect on the results and that further studies have to verify the discussed data.
Moreover, an open issue remains the clinical benefit of NK-DLIIL-2 stim compared to NK-DLIunstim applications. Due to our heterogeneous patient cohort regarding different high risk diseases, with multiple and advanced relapses, mostly not in remission (NR), a clear evidence cannot be made. Anyhow, in the present study we could show a superior cytotoxicity of ex vivo IL-2 stimulated compared to unstimulated NK cells against the MHC-I negative cell line K562 and against a neuroblastoma (NB) cell line as well [16]. Cautiously it has to be noted, that 78% of the high risk group II patients treated with NK-DLIIL-2 stim has not been in remission during haplo-SCT, but reached a survival of 44%. In addition in this group, two out of four patients suffering from high risk NB stadium IV with a very poor prognosis are still alive >2 years post NK-DLIIL-2 stim, which seems promising and is in accordance with the enhanced lytic activity of IL-2 stimulated NK cells compared to NK-DLIunstim against NB [16].
Conclusively, we were able to show that the adoptive transfer of NK-DLIIL-2 stim results in massive cell migrating processes under the influence of various ex vivo and most likely also in vivo secreted cytokines and chemokines. Since IL-2 activation leads to an improved cytotoxic capacity of the adoptively transferred NK cells, the co-transfused cytokine milieu may promote NK cell trafficking as well as an enhanced efficacy of NK cell immunotherapy.
Supporting Information
Figure S1.
Study designs of the clinical phase I/II NK-DLI and our concomitant in vivo monitoring analyses. A) In a phase I/II clinical feasibility study starting in the year 2003, haploidentical donor NK cells were isolated from unstimulated leukapheresis and purified by a two-step CD3-depletion/CD56-selection procedure. For haplo-SCT (d 0), peripheral blood stem cells (PBSC) were purified immunomagnetically either by CD34-selection or CD3/CD19-depletion. For NK cell collection, leukapheresis was performed at day −10 prior and +40 post SCT. At day +40, NK-DLIunstim was applied freshly, directly at the end of the purification process, while the processed NK-DLIunstim from day −10 was split and cryopreserved for the NK cell application on day +3 and +100. B) In an amendment of the study starting in the year 2005 two leukapheresis products collected on day +29 and +30 post SCT were pooled for the CD3-depletion/CD56-selection NK cell purification process. Following purification, NK cells were further ex vivo expanded and activated using 1000 U/ml IL-2 for 10 (9 to 14) days obeying GMP. After ex vivo stimulation, the NK cell product was split up, while one half was infused freshly at day +40 and the other was cryopreserved and applied at day +100 post SCT. For haplo-SCT (d 0), peripheral blood stem cells (PBSC) were purified immunomagnetically by CD3/CD19-depletion. C) For our concomitant in vivo monitoring study during NK-DLI, PB samples were collected at the day of application before (pre), 10 min, 1 h, 4 h and 24 h after the end of NK-DLI application.
https://doi.org/10.1371/journal.pone.0027351.s001
(TIF)
Figure S2.
A) NK cell cytotoxicity of NK-DLIunstim vs. NK-DLIIL-2 stim. Cytotoxic activity of donor NK cells against K562 was significantly enhanced by IL-2 stimulation. The killing activity against the MHC class I negative leukemic cell line K562 of IL-2 stimulated NK-DLIs (grey, n = 9) was significantly greater compared to unstimulated NK cells (white, n = 9) at both effector∶target ratios 1∶1 and 10∶1. NK cell cytotoxicity of freshly isolated unstimulated or IL-2 stimulated products was tested previously to application to the patients and/or before cryopreservation. Cytotoxicity was analyzed based on a 5-color flow cytometric single platform assay [19] and defined as the loss of viable target cells in relation to the mono-cultured control. p<0.01 and <0.001 indicated as ** and ***. B) In vivo NK cell immune reconstitution post haplo-SCT. Similar NK cell immune reconstitution post haplo-SCT in both patients' groups receiving NK-DLIIL-2 stim and NK-DLIunstim respectively. Very similar NK cell immune reconstitution was seen in both patient subgroups NK-DLIunstim (□, n = 7) and NK-DLIIL-2 stim (▴, n = 6). Immune reconstitution of all patients was monitored regularly; within the first three months post SCT weekly, from month four to six twice a month, followed by a period of monthly analyses. Shown are all measurements and median performed in each interval which were similar in both groups.
https://doi.org/10.1371/journal.pone.0027351.s002
(TIF)
Figure S3.
In vivo NK cell phenotype in patients PB differs from that of ex vivo expanded NK-DLIIL-2 stim. A) Upon 9–14 days of IL-2 stimulation, CD56, NKp44 and the activation marker CD69 become highly up-regulated, while the expression of the lymph node homing molecule CD62L declines. This figure exemplarily shows the ex vivo IL-2 stimulated NK cell phenotype present in the fresh NK-DLIIL-2stim. Density plots show CD56 vs. CD16 (CD56-PE, gated on lymphocytes excluding CD3+ T cells and CD19+ B cells), CD56 vs. NKp44, CD56 vs. CD69 and CD56 vs. CD62L (CD56-PC7, gated on CD56+CD3− NK cells). B) The NK cell phenotype of the NK-DLIIL-2 stim (Fig. S3A) was not present at any time following NK-DLIIL-2 stim application in patients' PB. This was indicated by the red circles. The blue squares highlight the CD62L expression of PB NK cells of the patients, illustrating the loss of the CD62L+ expressing PB NK cell phenotype as early as 10 min post NK-DLIIL-2 stim infusions, and the recovering after 24 h. In addition, CD56 was not down-regulated after NK-DLIIL-2 stim application. Density plots show CD56 vs. CD16 (CD56-PE, gated on lymphocytes excluding CD3+ T cells and CD19+ B cells), CD56 vs. NKp44, CD56 vs. CD69 and CD56 vs. CD62L (CD56-PC7, gated on CD56+CD3− NK cells). C) The decline in CD62L expressing PB NK cells was further illustrated by a box and whiskers plot. In the PB nearly all of the minor CD56bright and about 40% of the major CD56dim NK cell subpopulation are CD62L+. As early as 10 min post NK-DLIIL-2 stim applications (n = 4) a significant reduction in CD62L+ expressing PB CD56+CD3− NK cells was seen, while returning after 24 h. p<0.05 is indicated as *.
https://doi.org/10.1371/journal.pone.0027351.s003
(TIF)
Figure S4.
Impact of total NK-DLIIL-2 stim applications on leukocyte subpopulations and cytokine/chemokine levels. This figure gives an overview of all NK-DLIIL-2 stim applications, fresh and cryopreserved, in total. All effects of freshly applied NK-DLIIL-2 stim on leukocyte subpopulations shown in Fig. 1, 2, 3 were comparable to those presented in the overall of all NK-DLIIL-2 stim applications (n = 13). Box and whiskers plots show minimum, lower quartile, median, upper quartile and maximum of all measured data. Cytokine analyses of PB plasma samples collected before (pre) and 10 min, 1 h, 4 h and 24 h after fresh and cryopreserved NK-DLIIL-2 stim in total. Similar significant increases of in vivo cytokine/chemokine concentration of IL-2, IL-6, IL-8, IFN-γ, MCP-1 and MIP-1β in patient's plasma compared to exclusively fresh NK-DLIIL-2 stim applications (Fig. 3) were observed. Y-axis shows cytokine/chemokine concentration, range 1–1.000.000 pg/ml. p<0.05, p<0.01 and p<0.001 are indicated as *, ** and ***, respectively.
https://doi.org/10.1371/journal.pone.0027351.s004
(TIF)
Acknowledgments
The authors would like to thank all patients, nurses and physicians of the Pediatric Institute of the University Hospital-Frankfurt as well as all members of the Laboratory of Stem Cell Transplantation and Immunotherapy (Pediatric Hematology and Oncology) for their technical support.
Author Contributions
Conceived and designed the experiments: UK. Performed the experiments: CB SH AQ MB. Analyzed the data: CB SH AQ HM RE SK. Wrote the paper: CB UK. Patient enrollment: TK PB JS. Clinical study design: DS JRP UK. Chimerism analysis: HK PB. KIR/HLA genotyping: PSAB CS.
References
- 1. Passweg JR, Koehl U, Uharek L, Meyer-Monard S, Tichelli A (2006) Natural-killer-cell-based treatment in haematopoietic stem-cell transplantation. Best Pract Res Clin Haematol 19: 811–824.
- 2. Passweg JR, Stern M, Koehl U, Uharek L, Tichelli A (2005) Use of natural killer cells in hematopoetic stem cell transplantation. Bone Marrow Transplant 35: 637–643.
- 3. Rubnitz JE, Inaba H, Ribeiro RC, Pounds S, Rooney B, et al. (2010) NKAML: a pilot study to determine the safety and feasibility of haploidentical natural killer cell transplantation in childhood acute myeloid leukemia. J Clin Oncol 28: 955–959.
- 4. Lanier LL (2005) NK cell recognition. Annu Rev Immunol 23: 225–274.
- 5. Moretta A, Bottino C, Vitale M, Pende D, Cantoni C, et al. (2001) Activating receptors and coreceptors involved in human natural killer cell-mediated cytolysis. Annu Rev Immunol 19: 197–223.
- 6. Farag SS, Fehniger TA, Ruggeri L, Velardi A, Caligiuri MA (2002) Natural killer cell receptors: new biology and insights into the graft-versus-leukemia effect. Blood 100: 1935–1947.
- 7. Ljunggren HG, Malmberg KJ (2007) Prospects for the use of NK cells in immunotherapy of human cancer. Nat Rev Immunol 7: 329–339.
- 8. Ruggeri L, Capanni M, Urbani E, Perruccio K, Shlomchik WD, et al. (2002) Effectiveness of donor natural killer cell alloreactivity in mismatched hematopoietic transplants. Science 295: 2097–2100.
- 9. Cooper MA, Fehniger TA, Caligiuri MA (2001) The biology of human natural killer-cell subsets. Trends Immunol 22: 633–640.
- 10. Dulphy N, Haas P, Busson M, Belhadj S, Peffault de Latour R, et al. (2008) An unusual CD56(bright) CD16(low) NK cell subset dominates the early posttransplant period following HLA-matched hematopoietic stem cell transplantation. Journal of immunology 181: 2227–2237.
- 11. Nguyen S, Dhedin N, Vernant JP, Kuentz M, Al Jijakli A, et al. (2005) NK-cell reconstitution after haploidentical hematopoietic stem-cell transplantations: immaturity of NK cells and inhibitory effect of NKG2A override GvL effect. Blood 105: 4135–4142.
- 12. Koehl U, Sorensen J, Esser R, Zimmermann S, Gruttner HP, et al. (2004) IL-2 activated NK cell immunotherapy of three children after haploidentical stem cell transplantation. Blood Cells Mol Dis 33: 261–266.
- 13. Miller JS, Soignier Y, Panoskaltsis-Mortari A, McNearney SA, Yun GH, et al. (2005) Successful adoptive transfer and in vivo expansion of human haploidentical NK cells in patients with cancer. Blood 105: 3051–3057.
- 14. Passweg JR, Tichelli A, Meyer-Monard S, Heim D, Stern M, et al. (2004) Purified donor NK-lymphocyte infusion to consolidate engraftment after haploidentical stem cell transplantation. Leukemia 18: 1835–1838.
- 15. Rizzieri DA, Storms R, Chen DF, Long G, Yang Y, et al. (2010) Natural killer cell-enriched donor lymphocyte infusions from A 3-6/6 HLA matched family member following nonmyeloablative allogeneic stem cell transplantation. Biology of blood and marrow transplantation : journal of the American Society for Blood and Marrow Transplantation 16: 1107–1114.
- 16. Huenecke S, Zimmermann SY, Kloess S, Esser R, Brinkmann A, et al. (2010) IL-2-driven regulation of NK cell receptors with regard to the distribution of CD16+ and CD16− subpopulations and in vivo influence after haploidentical NK cell infusion. J Immunother 33: 200–210.
- 17. Koehl U, Bochennek K, Esser R, Brinkmann A, Quaritsch R, et al. (2008) ISHAGE-based single-platform flowcytometric analysis for measurement of absolute viable T cells in fresh or cryopreserved products: CD34/CD133 selected or CD3/CD19 depleted stem cells, DLI and purified CD56+CD3− NK cells. Int J Hematol 87: 98–105.
- 18. Koehl U, Esser R, Zimmermann S, Tonn T, Kotchetkov R, et al. (2005) Ex vivo expansion of highly purified NK cells for immunotherapy after haploidentical stem cell transplantation in children. Klin Padiatr 217: 345–350.
- 19. Zimmermann SY, Esser R, Rohrbach E, Klingebiel T, Koehl U (2005) A novel four-colour flow cytometric assay to determine natural killer cell or T-cell-mediated cellular cytotoxicity against leukaemic cells in peripheral or bone marrow specimens containing greater than 20% of normal cells. J Immunol Methods 296: 63–76.
- 20. Huenecke S, Behl M, Fadler C, Zimmermann SY, Bochennek K, et al. (2008) Age-matched lymphocyte subpopulation reference values in childhood and adolescence: application of exponential regression analysis. Eur J Haematol 80: 532–539.
- 21. Becker S, Tonn T, Fussel T, Uhrberg M, Bogdanow M, et al. (2003) Assessment of killer cell immunoglobulinlike receptor expression and corresponding HLA class I phenotypes demonstrates heterogenous KIR expression independent of anticipated HLA class I ligands. Human immunology 64: 183–193.
- 22. Kreyenberg H, Holle W, Mohrle S, Niethammer D, Bader P (2003) Quantitative analysis of chimerism after allogeneic stem cell transplantation by PCR amplification of microsatellite markers and capillary electrophoresis with fluorescence detection: the Tuebingen experience. Leukemia : official journal of the Leukemia Society of America, Leukemia Research Fund, UK 17: 237–240.
- 23. Kloess S, Huenecke S, Piechulek D, Esser R, Koch J, et al. (2010) IL-2-activated haploidentical NK cells restore NKG2D-mediated NK-cell cytotoxicity in neuroblastoma patients by scavenging of plasma MICA. Eur J Immunol 40: 3255–3267.
- 24. Nishimura R, Baker J, Beilhack A, Zeiser R, Olson JA, et al. (2008) In vivo trafficking and survival of cytokine-induced killer cells resulting in minimal GVHD with retention of antitumor activity. Blood 112: 2563–2574.
- 25. Olson JA, Zeiser R, Beilhack A, Goldman JJ, Negrin RS (2009) Tissue-specific homing and expansion of donor NK cells in allogeneic bone marrow transplantation. Journal of immunology 183: 3219–3228.
- 26. Pegram HJ, Haynes NM, Smyth MJ, Kershaw MH, Darcy PK (2010) Characterizing the anti-tumor function of adoptively transferred NK cells in vivo. Cancer immunology, immunotherapy : CII 59: 1235–1246.
- 27. Meller B, Frohn C, Brand JM, Lauer I, Schelper LF, et al. (2004) Monitoring of a new approach of immunotherapy with allogenic (111)In-labelled NK cells in patients with renal cell carcinoma. Eur J Nucl Med Mol Imaging 31: 403–407.
- 28. Nowak B, Weber C, Schober A, Zeiffer U, Liehn EA, et al. (2007) Indium-111 oxine labelling affects the cellular integrity of haematopoietic progenitor cells. Eur J Nucl Med Mol Imaging 34: 715–721.
- 29. Penack O, Gentilini C, Fischer L, Asemissen AM, Scheibenbogen C, et al. (2005) CD56dimCD16neg cells are responsible for natural cytotoxicity against tumor targets. Leukemia : official journal of the Leukemia Society of America, Leukemia Research Fund, UK 19: 835–840.
- 30. Lotze MT, Matory YL, Ettinghausen SE, Rayner AA, Sharrow SO, et al. (1985) In vivo administration of purified human interleukin 2. II. Half life, immunologic effects, and expansion of peripheral lymphoid cells in vivo with recombinant IL 2. Journal of immunology 135: 2865–2875.
- 31. Salvo G, Samoggia P, Masciulli R, Boccoli G, Allavena P, et al. (1992) Interleukin-2 bolus therapy induces immediate and selective disappearance from peripheral blood of all lymphocyte subpopulations displaying natural killer activity: role of cell adhesion to endothelium. European journal of cancer 28A: 818–825.
- 32. Aronson FR, Libby P, Brandon EP, Janicka MW, Mier JW (1988) IL-2 rapidly induces natural killer cell adhesion to human endothelial cells. A potential mechanism for endothelial injury. Journal of immunology 141: 158–163.
- 33. Siebert JC, Walker EB (2010) Monitoring cytokine profiles during immunotherapy. Immunotherapy 2: 799–816.
- 34. Cassatella MA (1995) The production of cytokines by polymorphonuclear neutrophils. Immunology today 16: 21–26.
- 35. Cassatella MA, Gasperini S, Calzetti F, Bertagnin A, Luster AD, et al. (1997) Regulated production of the interferon-gamma-inducible protein-10 (IP-10) chemokine by human neutrophils. European journal of immunology 27: 111–115.
- 36. Gardner L, Patterson AM, Ashton BA, Stone MA, Middleton J (2004) The human Duffy antigen binds selected inflammatory but not homeostatic chemokines. Biochemical and biophysical research communications 321: 306–312.
- 37. Horne K, Woolley IJ (2009) Shedding light on DARC: the role of the Duffy antigen/receptor for chemokines in inflammation, infection and malignancy. Inflammation research : official journal of the European Histamine Research Society [et al] 58: 431–435.
- 38. Schnabel RB, Baumert J, Barbalic M, Dupuis J, Ellinor PT, et al. (2010) Duffy antigen receptor for chemokines (Darc) polymorphism regulates circulating concentrations of monocyte chemoattractant protein-1 and other inflammatory mediators. Blood 115: 5289–5299.
- 39. Middleton J, Patterson AM, Gardner L, Schmutz C, Ashton BA (2002) Leukocyte extravasation: chemokine transport and presentation by the endothelium. Blood 100: 3853–3860.
- 40. Gregoire C, Chasson L, Luci C, Tomasello E, Geissmann F, et al. (2007) The trafficking of natural killer cells. Immunological reviews 220: 169–182.