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Triptolide, isolated from the herb Tripterygium wilfordii, has been shown to potently induce apoptosis in various malignant cells by inhibiting RNA synthesis and NF-κB activity. Previously, we showed that triptolide promotes apoptosis in acute myeloid leukemia (AML) cells via the mitochondria-mediated pathway, in part by decreasing levels of the anti-apoptotic proteins XIAP and Mcl-1. MRx102 is a triptolide derivative currently in preclinical development. Here, we show that MRx102 potently promoted apoptosis in AML cell lines, with EC50 values of 14.5 ± 0.6 nM and 37.0 ± 0.9 nM at 48 hours for OCI-AML3 and MV4-11 cells, respectively. MRx102, at low nanomolar concentrations, also induced apoptosis in bulk, CD34+ progenitor, and more importantly CD34+CD38− stem/progenitor cells from AML patients, even when they were protected by co-culture with bone marrow mesenchymal stromal cells. MRx102 decreased XIAP and Mcl-1 protein levels and inhibited RNA synthesis in OCI-AML3 cells. In vivo, MRx102 greatly decreased leukemia burden and increased survival time in NOD/SCID mice harboring Ba/F3-ITD cells. Collectively, we demonstrated that MRx102 has potent antileukemic activity both in vitro and in vivo, has the potential to eliminate AML stem/progenitor cells and overcome microenvironmental protection of leukemic cells, and warrants clinical investigation.
Triptolide, isolated from a Chinese herb Tripterygium wilfordii, has been used in Chinese medicine for centuries to treat inflammatory and autoimmune diseases. In recent years, triptolide has attracted attention for its ability to inhibit growth and promote death of tumor cells in vitro and in vivo(1–5) and to enhance the antitumor effects of various chemotherapeutic agents.(3, 6–10) Triptolide exerts potent anti-tumor activity through multiple mechanisms. Its ability to inhibit NF-κB(11, 12) and HSP70;(13) decrease levels of the anti-apoptotic proteins XIAP, Mcl-1, and Bcr-Abl;(3, 4, 14) induce expression of p53 and death receptor DR5;(9) and block the SDF-1/CXCR4 axis(15) are just a few examples. Most, if not all, of these functions are probably attributable to the ability of triptolide to target RNA polymerase, thereby decreasing the levels of short-lived anti-apoptotic proteins,(16–18) and its ability to inhibit tumor cellular proteasome activity, as recently reported.(19)
Antitumor activity of triptolide was first identified in leukemia.(20) We previously showed that triptolide decreased mRNA and protein levels of XIAP and Mcl-1 in myeloid leukemia cells; decreased the level of Bcr-Abl in chronic myeloid leukemia (CML) cells; induced apoptosis in both acute myeloid leukemia (AML) and CML cells; sensitized AML cells to TRAIL-induced apoptosis via decrease of XIAP and p53-mediated increase of DR5; and importantly, induced apoptosis independent of cellular responses to imatinib in blast crisis CML cells, including quiescent CD34+ primitive progenitor cells. (3, 4, 9) To optimize the activity of triptolide for clinical applications, new triptolide derivatives with improved pharmacokinetics and bioavailability have been designed and synthesized. Among them, PG490-88Na (F60008)(21;22) has entered clinical development and has been shown to have potent antitumor activity. Importantly, complete remissions were reported in a phase 1 study in patients with refractory or relapsing acute leukemias.(23
MRx102 is a potent triptolide derivative currently under development by MyeloRx. To determine the therapeutic potential of MRx102 in leukemia, we examined the effects of MRx102 on AML cells, including primary human AML cells and AML stem/progenitor cells and NOD/SCID mice injected with Ba/F3-ITD cells. Here, we report that MRx102 decreased XIAP and Mcl-1 protein levels, inhibited RNA synthesis in OCI-AML3 cells, and had potent activity not only against AML cell lines and bulk AML blasts but also against AML progenitor/stem cells, even when they were protected by co-culture with bone marrow (BM)-derived mesenchymal stromal cells (MSCs) in vitro and in a murine model of AML.
Human AML cell lines OCI-AML3 was kindly provided by Dr. M. Minden (Ontario Cancer Institute, Ontario, Canada) and MV4-11 was purchased from the American Type Culture Collection (Manassas, VA). Ba/F3-ITD cells, a murine pro-B lymphocyte line stably transfected with expression vector encoding human FLT3 with an internal tandem duplication (ITD) mutation, were generated by Dr. D. Small’s laboratory (Johns Hopkins University School of Medicine, Baltimore, MD). Ba/F3-ITD-GFP/Luc cells, which stably express Renilla luciferase and green fluorescent protein (GFP), were generated by infecting Ba/F3-ITD cells with a lentivirus-based construct as previously described.(24) All cell lines were cultured in RPMI 1640 medium supplemented with 10% heat-inactivated fetal calf serum, 2 mM L-glutamine, 100 U/mL penicillin, and 100 µg/mL streptomycin.
Fresh BM or peripheral blood (PB) samples from AML patients with high blast counts and BM samples from normal subjects were acquired after written informed consent had been obtained according to the Declaration of Helsinki, and the study protocol was approved by the MD Anderson Institutional Review Board. Mononuclear cells were purified by Ficoll-Hypaque (Sigma, St. Louis, MO) density-gradient centrifugation and cultured in the same medium as for the cell lines. The clinical characteristics of these samples are summarized in Table 1.
OCI-AML3 and MV4-11 cells (0.4 ×106/mL), Ba/F3-ITD-GFP/Luc cells (0.1 × 106/mL), or mononuclear cells from AML and normal BM samples (0.5 × 106/mL) were treated with various concentrations of MRx102 for up to 72 hours. An appropriate amount of dimethyl sulfoxide (DMSO) was used as the control. For treatment of AML cells co-cultured with MSCs, early-passage MSCs isolated from human BM as previously described(25) were pre-plated at 5 × 103/cm2 for 24–96 hours; AML cells were then added and treated.
Viable cell counts were determined by flow cytometry using CountBright absolute counting beads (Invitrogen, Carlsbad, CA) on annexin V-/7-amino-actinomycin D (7-AAD)negative cell events. Apoptosis was assessed by flow cytometry of phosphatidyl serine(26) externalization with annexin-V-Cy5 (BD Biosciences, San Diego, CA) using a FACSArray Bioanalyzer (BD Biosciences). Membrane integrity was simultaneously assessed by 7-AAD exclusion in the annexin V-stained cells. For AML patient samples, apoptosis was determined in bulk as well as in primitive and stem/progenitor cell compartments after cells were stained with anti-CD34 and anti-CD38 antibodies. For AML cells co-cultured with MSCs, apoptosis induction in various cell compartments was analyzed separately for detached cells (floaters) and attached (adherent) cells. Floaters were obtained by combining all cells in suspension and cells collected after washing the wells twice with PBS. Adherent cells were obtained by trypsinization. Leukemic cells were distinguished from MSCs by gating on CD45+ populations. Floaters or adherent cells were stained with CD45-APC-H7, CD34-PE, CD38-PE-Cy7, and annexin-V-Cy5 (BD Biosciences). Apoptosis was determined by flow cytometry of annexin-V-Cy5 positivity in bulk (CD45+), CD45+CD34+, CD45+CD34+CD38+, and CD45+CD34+CD38− cells. To eliminate the variation from spontaneous apoptosis in AML patient samples and normal controls, the apoptosis measured in these samples was expressed as specific apoptosis:
Mcl-1 and XIAP protein levels were determined by western blot analysis, as described previously.(27, 28) XIAP antibody was purchased from BD-Transduction Laboratories (BD Biosciences) and Mcl-1 antibody from Cell Signaling Technology (Danvers, MA). Signals were detected using the Odyssey Infrared Imaging System (LI-COR Biosciences, Lincoln, NE), and quantitated using Odyssey software version 3.0 (LI-COR Biosciences). β-Actin was used as a loading control.
RNA synthesis was measured by quantitating incorporation of [3H]uridine into the perchloric acid-insoluble materials. Briefly, MRx102-treated OCI-AML3 cells were labeled with [3H]uridine (10 µCi/mL) for 1 hour, washed twice with 10 mL of ice-cold PBS, and then lysed while vortexing with 0.5 mL of H2O and 0.5 mL of 0.8 N perchloric acid. The pellet was collected by centrifugation, washed once with 1 mL of 0.4 N perchloric acid, and then dissolved in 1 mL of H2O with 50 µL of 10 N potassium hydroxide overnight. The supernatant was then transferred to scintillation vials, and radioactivity was quantitated.
Ba/F3-ITD-GFP/Luc cells (0.3 × 106) were injected into the tail vein of 7-week-old female NOD/SCID mice (The Jackson Laboratory, Bar Harbor, ME). Starting on day 3, mice (11/group) were treated with vehicle control (PBS/DMSO), 1.5 mg of MRx102/kg/day, or 3.0 mg of MRx102/kg/day for 5 weeks intraperitoneally. The percentage of circulating Ba/F3-ITD-GFP/Luc cells was determined by flow cytometry of GFP in blood samples. Tumor infiltration was monitored by noninvasive bioluminescence imaging using the IVIS-200 in vivo imaging system (Xenogen, Hopkinton, MA) after mice were injected with the luciferase substrate coelenterazine (Biotium, Hayward, CA). The extent of leukemic infiltration of various organs was assessed by hematoxylin and eosin (H-&-E) or anti-GFP staining of selected mice from each group. Mouse survival time was recorded.
Experiments for cell lines were conducted 3 times, and results are expressed as mean ± standard deviation. For AML patient samples, results are expressed as mean ± standard error. IC50, the dose at which MRx102 inhibits cell growth by 50%, and EC50, the dose at which MRx102 induces apoptosis in 50% of cells were calculated using CalcuSyn software (Biosoft, Ferguson, MO). Statistical differences between groups or cell populations at each dose level were determined using paired Student’s t-test where significant differences were indicated (*) when p<0.05. Data of mouse survival time were analyzed using long-rank test.
To determine the efficacy of MRx102 in vitro in AML cells, we first treated AML cell lines with MRx102. We found that MRx102 had a potent antileukemic effect. MRx102, at low nanomolar concentrations, induced pronounced apoptosis, decreased viability, and inhibited growth of OCI-AML3 and MV4-11 cells (Figure 1). At 24 hours, EC50 = 108.0 ± 1.0 nM and IC50 = 92.4 ± 10.5 nM for MV4-11 cells and EC50 = 101.3 ± 3.5 nM and IC50 = 76.1 ± 6.5 nM for OCI-AML3 cells; at 48 hours, EC50 = 37.0 ± 0.9 nM and IC50 = 16.9 ± 1.1 nM for MV4-11 cells and EC50 = 14.5 ± 0.6 nM and IC50 = 6.9 ± 0.3 nM for OCI-AML3 cells, respectively.
We showed previously that triptolide promotes apoptosis in leukemic cells in part by decreasing expression of the short-lived anti-apoptotic proteins XIAP and Mcl-1.(3, 4) Subsequently, triptolide was reported to suppress RNA polymerase II-mediated RNA synthesis.(16–18) To determine whether the triptolide derivative MRx102 exerts its activity through similar mechanisms, we treated OCI-AML3 cells with MRx102 and examined XIAP and Mcl-1 protein levels at 24 hours, by western blot analysis, and RNA synthesis at 4 hours and 24 hours, by quantitating uridine incorporation into these cells. We found that, like triptolide, MRx102 greatly decreased protein levels of XIAP and Mcl-1 at 24 hours but had minimal effect on the long-lived Bcl-2 protein at 24 hours (Figure 2A). At 4 hours, RNA synthesis was inhibited by approximately 50% by 200 nM MRx102, whereas at 24 hours, RNA synthesis was completed inhibited even by 50 nM MRx102 (Figure 2B).
We next determined the efficacy of MRx102 in vitro in primary samples from patients with AML. Mononuclear cells from AML patient samples (n = 12; Table 1) and normal BM samples (n = 3) were treated with MRx102, and apoptosis was determined at 24 hours. We found that MRx102, at low nanomolar concentrations, effectively induced apoptosis in all the AML samples treated, regardless of the cytogenetics or clinical responses to various therapies of the patients at the time of sampling (Figure 3A, ED50 = 132.1 ± 7.5 nM; Table 1). MRx102 also promoted apoptosis in normal BM cells, but with less efficacy (Figure 3A, ED50 = 209.9 ± 56.8 nM; P = .003 at 300 nM MRx102).
To examine the ability of MRx102 to eliminate AML stem/progenitor cells, which in general are more resistant than bulk AML blasts to chemotherapy, we treated cells from AML patients with MRx102 and determined the viabilities of primitive CD34+ and CD34+CD38+ AML cells and CD34+CD38− AML progenitor/stem cells at 24 hours. Among 12 samples treated, 9 had sufficient cells for apoptosis analysis in all cell compartments (Table 1). We found that MRx102 potently promoted apoptosis in CD34+, CD34+CD38+, and CD34+CD38− AML cells, although CD34+CD38− cells were less sensitive than CD34+ cells at 150 nM (P = .033) and 300 nM (P = .015) (Figure 3B).
Further, to examine the efficacy of MRx102 in eradicating AML cells protected by the BM microenvironment, we co-cultured AML cells obtained from patients with BM-derived MSCs, treated them with MRx102, and determined apoptosis in cells detached (floaters) from and attached (adherent) to MSCs in CD34+, CD34+CD38+, and CD34+CD38− cells. We found that MRx102 efficiently promoted apoptosis in AML cells even when they were co-cultured with MSCs, in all cell compartments for both floaters and adherent cells (Figure 4). Note that for adherent CD34+CD38− cells under co-culturing conditions, apoptosis was determined only in 3 patient samples because of low numbers of cells; 7 samples were analyzed for all the other conditions.
To test the antileukemic activity of MRx102 in vivo in a Ba/F3-ITD-GFP/Luc NOD/SCID murine model, we first treated Ba/F3-ITD-GFP/Luc cells in vitro with MRx102 and found that MRx102 induced apoptosis and suppressed growth in these cells (Figure 5A). We then injected Ba/F3-ITD-GFP/Luc cells intravenously into NOD/SCID mice and started treatment on day 3 after the injection with 1.5 mg or 3.0 mg of MRx102/kg/day for 5 weeks. Antileukemic activity of MRx102 was monitored by bioluminescence imaging of mice, by recording mouse survival time, and by H-&-E and GFP staining for organ infiltration by leukemic cells.
No significant differences were observed in luciferase intensity between control and MRx102-treated groups at day 7 and day 14. At day 33, lower luciferase activity was detected in both MRx102 treatment groups compared with the untreated control group, especially in the group treated with 3.0 mg of MRx102/kg/day (Figure 5B), suggesting that treatment with MRx102 decreased the leukemic burden in Ba/F3-ITD NOD/SCID mice. We found that MRx102, administered at 1.5 mg/kg/day had no significant effect on the survival of Ba/F3-ITD NOD/SCID mice (P = .095, median survival time 35 days vs. 36 days for control, Figure C), suggesting that at this dose, although MRx102 decreased the leukemic burden, it was not effective in prolonging survival of these mice. Mice treated with MRx102 at 3.0 mg/kg/day had significantly longer survival time (median survival time 43 days) than control mice (P = .010) or mice treated with MRx102 at 1.5 mg/kg/day (P = .027), indicating that MRx102 has antileukemic activity in vivo.
H-&-E and GFP staining of various tissues showed that BM, spleens, livers, and lungs of control mice were infiltrated with leukemic cells, whereas the amounts of leukemic cells in these organs were lower in mice treated with MRx102 at 1.5 mg/kg/day and lowest in mice treated with MRx102 at 3.0 mg/kg/day (Figure 5D). However, we observed no decrease, but rather an increase in the number of circulating Ba/F3-ITD cells at day 35 in mice treated with MRx102 at 3.0 mg/kg/day compared with mice treated with MRx102 at 1.5 mg/kg/day and untreated control mice, as determined by flow cytometry of GFP in blood (n = 3, results not shown), probably because in the group treated with MRx102 at 1.5 mg/kg/day and in untreated control mice, only animals with lower numbers of circulating leukemic cells survived until day 35. No apparent treatment related toxicities such as weight loss or diarrhea were observed. After prolonged treatment with MRx102 at 3.0 mg/kg/day, mice showed signs of physical weakness that improved on stopping the treatment.
Triptolide has been shown to be a potent antitumor agent, and various triptolide derivatives have been developed or are being developed to optimize the activity and/or pharmacokinetic properties of triptolide for clinical applications. In this study, we showed that the triptolide derivative MRx102 is effective against AML cells in vitro and also in vivo in a murine model of AML. MRx102 promoted apoptosis not only in bulk AML cells but also in AML stem/progenitor cells even when they were protected by the BM microenvironment. In addition, MRx102 greatly decreased the leukemic burden and increased the survival time of NOD/SCID mice injected with Ba/F3-ITD cells.
MRx102 is believed to exert its biological activity after being converted to triptolide. Our findings that MRx102 decreases XIAP and Mcl-1 levels and inhibits RNA synthesis in AML cells, as triptodide does, support the notion that MRx102 acts through mechanisms similar to those of triptolide.
Despite a high response rate to therapy, most AML patients relapse, largely because AML stem/progenitor cells are not targeted effectively by available therapeutic regimens and are responsible for drug resistance and relapse. Importantly, we found that MRx102 induced apoptosis in all compartments of AML cells, with similar efficacies in bulk, CD34+CD38+, and CD34+CD38− cells. This result is not surprising given that as in the primitive CD34+ AML cells, NF-κB is constitutively activated in AML stem cells(29) and that triptolide is known to inhibit NF-κB. We previously showed that triptolide is effective in killing not only proliferating but also quiescent CML progenitor cells, independent of cellular response to imatinib.(4) The ability of MRx102 to eliminate AML stem/progenitor cells will likely enable improvement of the current treatment regimens for AML. Furthermore, increasing evidence demonstrates the critical role of the BM microenvironment in supporting the survival of leukemic cells; protecting AML cells, especially AML stem cells, from therapeutic agents; and maintaining the self-renewal of AML stem cells. Here, we showed that MRx102 was effective against AML stem/progenitor cells even when leukemic cells were co-cultured with BM-derived MSCs, suggesting the potential of MRx102 to overcome microenvironmental protection.
We found that MRx102 also killed normal BM cells, but with lower potency. A careful MRx102 dosing schedule is needed to minimize toxicity and maximize the antileukemic effect. Previous toxicology tests of MRx102 in rats with a 7-day subacute injections up to the top dose of 1.5 mg/kg and an acute single dose up to the top dose of 3.0 mg/kg showed no deaths and no adverse signs and the histopathology report showed no findings related to administration of MRx102.(30) The no-observable-adverse-effects level is ≥1.5 mg/kg/day for MRx102, whereas it is ≤0.1 mg/kg/day for other related compounds.(30) After prolonged treatment of Ba/F3-ITD NOD/SCID mice with MRx102 at 3.0 mg/kg/day, we did observe signs of physical weakness; these improved on stopping the treatment, suggesting that treatment-related toxicity that can be alleviated with proper scheduling. The fact that MRx102 markedly lowered the leukemic burden and prolonged the life of Ba/F3-ITD NOD/SCID mice suggests that MRx102 has in vivo antileukemic activity, supported by our previous data in a nude mouse subcutaneous xenograft model.(30)
Collectively, our results showed that MRx102, a triptolide derivative, has potent antileukemic activity in vitro and in a murine model of AML. MRx102 is a potential therapeutic agent in AML and warrants further investigation.
We thank Kate J Newberry and Deanna A Alexander for helping with the manuscript preparation.
Hyperlink to the published article: http://www.nature.com/leu/journal/v26/n3/pdf/leu2011246a.pdf
Disclosure of Conflict of Interest: JMF is an employee of MyeloRx and all the other authors have no conflict of interest to disclose.