Matrine reverses the drug resistance of K562/ADM cells to ADM and VCR via promoting autophagy.

BACKGROUND: This study aimed to investigate the effects of matrine (MAT) on the drug resistance of K562/ADM cells.
METHODS: K562/S and K562/ADM cells were treated with different concentrations of vincristine (VCR), adriamycin (ADM), and/or MAT for 48 h. The cell viability was determined by MTT assay, and the drug-resistant multiple and drug-resistant reversal multiple were calculated based on half-inhibitory concentration (IC50). The cell apoptosis, as well as cell cycle were detected by flow cytometry. The autophagy was evaluated by transmission electron microscope and GFP-LC3 staining. Autophagy-related protein levels of LC3 II, and P62 were detected by Western blot.
RESULTS: MAT reduced the viability of K562/S and K562/ADM cells in a dose-dependent manner, and 0.5 mg/mL was identified as the non-cytotoxic concentration. MAT eliminated the drug resistance of K562/ADM cells to ADM and VCR, and the drug resistance reversal multiple was 10.12 and 4.91, respectively. Chloroquine (CQ), a lysosomal inhibitor significantly reversed the inhibitory effect of MAT on the viability of K562/ADM cells. In addition, MAT induced the apoptosis of K562/ADM cells through arresting the cell cycle at G0/G1 phase in a dose-dependent manner. MAT also increased the autophagic vacuoles, the LC3+ punctate fluorescence, as well as the LC3 II protein level, and decreased P62 protein level in K562/ADM cells in a dose-dependent manner.
CONCLUSIONS: MAT reversed the drug resistance of K562/ADM cells to ADM and VCR through promoting autophagy. 2020 Translational Cancer Research. All rights reserved.

Introduction

Leukemia is a common malignant tumor in human (1). In clinical practice, chemotherapy is the main treatment strategy for Leukemia. However, multidrug resistance of leukemia cells greatly limits the outcomes of leukemia patients, and high recurrence has become one of the main manifestation of treatment failure (2,3). Multidrug resistance refers to the fact that tumor cells are not only resistant to one anti-tumor drug, but also resistant to other anti-tumor drugs with different molecular structures and effects. Multidrug resistance greatly reduces the treatment efficacy of anti-tumor drugs (4,5). At present, the multidrug resistance of tumors to different chemotherapeutic drugs is still the main cause of chemotherapy failure, which is also a major problem in cancer treatment, including leukemia. Thus, in order to improve the therapeutic efficacy, inhibiting the multidrug resistance of leukemia cells is urgently needed.

Matrine (MAT) is an alkaloid extracted from the root of Sophora flavescens (6). It had been proved that MAT exerts obvious anti-tumor effects, as well as anti-inflammatory effects (7). For example, MAT suppresses the progression of prostate cancer through stimulating the expression of GADD45B (8). MAT enhances the apoptosis, and weakens the invasion ability of cervical cancer cells (9). MAT inhibits the invasion and epithelial-mesenchymal transition of pancreatic cells through regulating ROS/NF-κB/MMPs pathway (10). MAT exerts significant anti-tumor activity against gastric cancer, and both apoptosis and autophagy are activated in gastric cancer by MAT (11). MAT is also able to accelerate the apoptosis of leukemia cells (12). Note worthily, MAT has also reported to be involved in the regulation of multidrug resistance in tumors. It has been reported that MAT reverses the multidrug resistance of breast cancer cells via regulating PI3K/AKT signal pathway (13). However, the effect of MAT on multidrug resistance of leukemia cells is still unclear. Since multidrug resistance of leukemia is still a difficult problem in clinical practice, this article was devoted to investigate the specific effects of MAT on multidrug resistance of leukemia cells. Our findings may reveal a novel multidrug resistance inhibitor on leukemia cells.

Methods

Cell culture

Human leukemia cell line K562/S and multidrug-resistant cell line K562/ADM were both provided by Tianjin Institute of Hematology, Chinese Academy of Medical Sciences. Cells were cultured in RPMI 1640 medium containing 10% fetal bovine serum (FBS) in an incubator at 37 °C with 5% CO2. RPMI 1640 medium containing 1.0 µg/mL adriamycin (ADM) (Doxorubicin hydrochloride, C27H29NO11·HCl, Sigma, St Louis, USA) was used to maintain the drug-resistance of K562/ADM cells. Two weeks before experiments, K562/ADM cells were maintained in normal RPMI 1640 medium without ADM.

Cell treatments

K562/S and K562/ADM cells in logarithmic growth phase were used for treatments. K562/S and K562/ADM cells were incubated in 96-well plates (5×105 cells/mL, 100 µL per well), and treated with 0, 0.5, 1, 2, and 4 mg/mL MAT (Matrine, C15H24N2O, Baiyunshan Mingxing, Guangzhou, China) for 48 h. Another part of K562/S and K562/ADM cells were treated with 0, 0.01, 0.1, 1.0, and 10 µg/mL vincristine (VCR) (Vincristine sulfate, C46H56N4O10·H2SO4, Wanle, Shenzhen, China) or ADM for 48 h, respectively. In addition, 0.5 mg/mL MAT per-treated K562/ADM cells (30 min of MAT treatment) were treated with VCR or ADM for another 48 h (MAT + VCR, MAT + ADM). Another part of MAT per-treated K562/ADM cells were treated with chloroquine (CQ) (a lysosomal inhibitor) combined with VCR or ADM for 48 h.

Cell viability assay by MTT

The cell viability was determined by MTT assay. Briefly, after 48 h of treatment, MTT solution (20 µL, 5 mg/mL) was added into each well, and incubated for 4 h at 37 °C. Dimethyl sulfoxide (DMSO) at a volume of 100 µL was used to replace the residual liquid in each well. Ten min later, the absorbance value at 490 wavelength (A490 value) of each well was measured on an automatic microplate reader. Cell viability was obtained with the following formula: Viability (%) = (A490 value of treated cells/A490 value of control) ×100%. The half-inhibitory concentration (IC50) was calculated by the drug concentration-viability curve. Furthermore, drug-resistant multiple (IC50 value of drug-resistant cells/IC50 value of drug-sensitive cells) and drug-resistant reversal multiple (IC50 value before reversal of drug-resistant cells/IC50 value after reversal of drug-resistant cells) was calculated.

Apoptosis assay by flow cytometry

The cell apoptosis was detected by flow cytometry. Briefly, after 48 h of treatment, cells were washed with pre-cooled PBS (1 mL) for twice. Then cells were resuspended in a mixture of 500 µL binding buffer and 5 µL Annexin V-FITC. After 20 min incubation at room temperature in darkness, the apoptosis rate was detected on flow cytometry.

Cell cycle assay by flow cytometry

The cell cycle was also detected by flow cytometry. Briefly, after 48 h of treatment, cells were washed with pre-cooled PBS for twice, and resuspended in 75% pre-chilled ethanol for 12 h at −20 °C. After 5 min of centrifugation at 1,000 r/min, cells were resuspended in 10 mL pre-cooled PBS, and then incubated in PBS containing 200 µL of propidium iodide (PI) for 30 min at 4 °C in darkness. The cell cycle was detected on flow cytometry.

Detection of autophagic vacuoles by transmission electron microscope

MAT-treated K562/ADM cells were washed with PBS, and fixed in glutaraldehyde for 12 h at 4 °C. Then cells were incubated with tannic acid for 1.5 h at 4 °C, washed with PBS for 3 times (5 min each time), and dehydrated with gradient ethanol (50%, 70%, 90% and 100%) and 100% acetone. After incubated in embedding agent and acetone (1:1) for 2 h at 25 °C, cells were embedded in epoxy resin at 35 °C overnight, cured in an oven for 24 h at 45 °C, and sectioned. Followed by 12 h of staining with uranyl acetate and lead citrate at 66 °C, cells were observed under transmission electron microscope.

Observation of autophagy by GFP-LC3 staining

K562/ADM cells were transfected with GFP-LC3 (Invitrogen) for 48 h by using lipofectamine 3000 (Invitrogen). Then these cells were treated with MAT (0, 0.5, 1, 2 mg/mL) for 48 h. After washed with PBS, the LC3+ punctate fluorescence was observed under a fluorescence microscope.

Detection of autophagy-related protein levels by Western blot

MAT-treated K562/ADM cells were lysed in RIPA Lysis buffer (Biyuntian, Shanghai, China). Total proteins were quantified by using BCA kit (Biyuntian), separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and transferred to PVDF membrane. Then the membrane was blocked with 5% skim milk for 2 h, and incubated with primary antibodies, anti-LC3 and anti-P62 (mouse anti-human, 1:1,000, Abcam, Cambridge, UK) for 12 h at 4 °C. Followed by 1 h of incubation with alkaline phosphatase-labeled secondary antibody (goat anti-mouse, 1:5,000, Zhongshan Jinqiao, Beijing, China) at 25 °C, protein bands were visualized with enhanced chemiluminescence (ECL) (Pierce, Rockford, IL, USA). β-actin was served as the internal control.

Statistical analysis

All data were processed using SPSS 21.0 (SPSS Inc., Chicago, IL, USA) statistical software. Measurement data were expressed as mean ± standard deviation. T-test was used for comparison between two groups. One-way analysis of variance was used for comparison among multiple groups. P<0.05 meant statistically significant difference.

Results

MAT reversed the drug-resistance of K562/ADM cells to ADM and VCR

MAT reduced the viability of K562/S and K562/ADM cells in a dose-dependent manner. No significant difference on the cell viability was revealed between K562/S cells and K562/ADM cells at the same concentrations of MAT (). The IC50 value of MAT on K562/S cells and K562/ADM cells was 2.33 and 2.50 mg/mL, respectively. The concentration of MAT at 0.5 mg/mL with a cell inhibition rate of less than 5% was set as the non-cytotoxic concentration.

Figure 1

Reversal effect of MAT on drug-resistance of K562/ADM cells. (A) MAT reduced the viability of K562/S and K562/ADM cells in a dose-dependent manner; (B) VCR and ADM reduced the viability of K562/S cells in a dose-dependent manner; (C) MAT eliminated the drug resistance of K562/ADM cells to VCR; (D) MAT eliminated the drug resistance of K562/ADM cells to ADM. *, P<0.05 when compared with VCR/ADM, and VCR/ADM + MAT + CQ.

Both ADM and VCR could significantly reduce the viability of K562/S cells in a dose-dependent manner (). MAT eliminated the drug resistance of K562/ADM cells to ADM and VCR. The cell viability was significantly lower in VCR + MAT-treated K562/ADM cells than in VCR-treated K562/ADM cells, and significantly lower in ADM + MAT-treated K562/ADM cells than in ADM-treated K562/ADM cells (P<0.05). Noteworthy, the intervention of CQ significantly reversed the inhibitory effect of MAT on the viability of K562/ADM cells (P<0.05) ().

The drug resistance multiple of K562/ADM cells to VCR and ADM was 39.2 and 77.23, respectively. The drug resistance reversal multiple of MAT to VCR and ADM was 10.12 and 4.91, respectively (). The intervention of CQ significantly reduced the drug resistance reversal multiples of MAT to VCR and ADM (P<0.05). All these results indicated that MAT reversed the drug-resistance of K562/ADM cells to VCR and ADM, and CQ reversed the effects of MAT.

Table 1

Drug-resistant (DR) multiple and DR reversal multiple of K562/ADM cells to VCR and ADM (IC50 µg/mL)

Drugs	K562/S	K562/ADM	K562/ADM + MAT	K562/ADM + MAT + CQ	DR multiple	DR reversal multiplea	DR reversal multipleb
VCR	0.24±0.065	9.414±3.95	0.93±0.77*	2.83±1.08*#	39.2	10.12	3.32&
ADM	0.59±0.113	45.57±2.67	9.28±3.23*	24.17±5.15*#	77.23	4.91	1.89&

Note: DR multiple = IC50 (K562/ADM cells)/IC50 (K562/S cells). DR reversal multiplea = IC50 (K562/ADM cells)/IC50 (K562/ADM + MAT cells). DR reversal multipleb = IC50 (K562/ADM cells)/IC50 (K562/ADM + MAT + CQ cells). *, P<0.05 when compared with K562/S and K562/ADM cells; #, P<0.05 when compared with K562/ADM + MAT cells; &, P<0.05 when compared with DR reversal multiplea.

MAT promoted the apoptosis of K562/ADM cells through arresting the cell cycle at G0/G1 phase

As shown in , the MAT treatment significantly increased the apoptosis rate of K562/ADM cells in a dose-dependent manner (P<0.05). The apoptosis rate of K562/ADM cells reached 60% at the concentration of 2 mg/mL. It could also be noticed in that, MAT significantly increased the proportion of K562/ADM cells in G0/G1 phase and decreased the proportion of K562/ADM cells in S phase in a dose-dependent manner (P<0.05) (). These results indicated that MAT induced the apoptosis of K562/ADM cells through arresting the cell cycle at G0/G1 phase in a dose-dependent manner.

Figure 2

MAT induced the apoptosis of K562/ADM cells and arrested cell cycle in G0/G1 phase. (A) MAT induced the apoptosis of K562/ADM cells in a dose-dependent manner; (B) MAT arrested cell cycle in G0/G1 phase in a dose-dependent manner; (C) MAT eliminated the drug resistance of K562/ADM cells to ADM and VCR. *, P<0.05; #, P<0.05; &, P<0.05 when compared with the other three groups.

Noteworthy, the apoptosis rate was significantly higher in VCR + MAT-treated K562/ADM cells than in VCR-treated K562/ADM cells, and significantly lower in ADM + MAT-treated K562/ADM cells than in ADM-treated K562/ADM cells (P<0.05). These results further indicated that MAT eliminated the drug resistance of K562/ADM cells to ADM and VCR ().

MAT induced autophagy in K562/ADM cells

The autophagy of K562/ADM cells was observed by transmission electron microscopy and GFP-LC3 staining. With the increasing of MAT concentration, the autophagic vacuoles in K562/ADM cells was gradually increased (), and the LC3+ punctate fluorescence around the nucleus was also gradually increased (). These results indicated that MAT induced the autophagy of K562/ADM cells in a dose-dependent manner.

Figure 3

MAT induced the autophagy in K562/ADM cells. (A) The autophagic vacuoles in K562/ADM cells were increased gradually in a dose-dependent manner; (B) the LC3+ punctate fluorescence around the nucleus was gradually increased in a dose-dependent manner. Yellow arrow represented autophagic vacuole.

MAT regulated autophagy-related protein levels in K562/ADM cells

The effects of MAT on autophagy-related protein levels were monitored in K562/ADM cells by Western blot. With the increasing of MAT concentration, relative LC3 II protein level was remarkably increased (P<0.05), whereas relative P62 protein level was decreased gradually (P<0.05) (). These results indicated that MAT promoted the conversion of LC3I to LC3II, as well as the degradation of P62 in a dose-dependent manner.

Figure 4

MAT regulated autophagy-related protein levels in K562/ADM cells. Relative LC3 II protein level was obviously increased, whereas relative P62 protein level was decreased gradually in a dose-dependent manner. *, P<0.05; #, P<0.05; &, P<0.05 when compared with the other three groups. Relative protein levels of LC3II and p62 were normalized to β-actin.

Discussion

MAT is an alkaloid complex extracted from the traditional Chinese medicine Sophora flavescens, which exerts diverse biological activities with low toxicity (14,15). MAT exhibits obvious anti-tumor effects through inhibiting the proliferation and inducing the differentiation and apoptosis in diverse cancers, such as lung cancer, esophageal cancer, gastric cancer, breast cancer, colon cancer, ovarian cancer, lymphoma, and multiple myeloma (16,17). It has been proved that MAT can reduce the adverse reactions of chemotherapy and radiotherapy, thereby improving the life quality of patients. MAT can also synergize with radiotherapy and chemotherapy by regulating immune function, thereby further improving the therapeutic effect (18). However, it is still unclear whether MAT can alleviate the multidrug resistance of leukemia cells to chemotherapy. In this article, the effect of MAT on multidrug resistance of leukemia cells was studied, and we found that MAT reversed the drug resistance of K562/ADM cells to VCR and ADM through promoting apoptosis and autophagy.

MAT stimulated the apoptosis of K562/ADM cells in a dose-dependent manner in this research. Inactivation of apoptosis contributes to the survival and therapeutic resistance of cancer cells. MAT can suppress the tumor progression by promoting apoptosis in multiple tumors. Wang et al. (19) showed that, declined Bcl-2 and increased Bax are observed in human hepatocellular carcinoma HepG2 cells treated by MAT, thereby interfering the metabolism of lipid proteins and destroying cell structure. Xu et al. (20) revealed that MAT promotes the apoptosis of osteosarcoma cells, as well as apoptotic factor Bax expression in a dose dependent manner. MAT can also induce the apoptosis of cisplatin-resistant lung cancer cells in vitro (21). However, there is no literature documenting the effect of MAT on the apoptosis of multidrug resistant leukemia cells. This paper discovered for the first time that MAT could induce the apoptosis of multidrug resistance K562/ADM cells in a dose-dependent manner.

MAT is also proved to be able to affect the cell cycle of tumor cells in previous researches. It is well known that the cell cycle is one of the important indicators for monitoring the proliferation of tumor cells. Zhang et al. (22) proved that MAT blocks gastric cancer cells in G1 phase by down-regulating the expression of G1/S essential protein Cyclin E. P21 protein is a cell cycle negative regulator with the broadest range of kinase inhibitory activity. It has been proved that MAT is able to block retinoblastoma cells in the G0/G1 phase by up-regulating p21 protein expression (23). Zhou et al. (24) suggested that, after being treated by MAT for 48 h, human hepatocellular carcinoma HepG2 cells are arrested in G0/G1 phase, accompanied by obvious morphological changes, including cell atrophy, increased nuclear heterochromatin and perinuclear space, as well as differentiation and even lysis. Moreover, MAT induces the differentiation and apoptosis of tumor cells by up-regulating the levels of proapoptotic proteins (such as Caspase-3) and surface differentiation antigen CD11b. Our results showed that MAT blocked K562/ADM cells in G0/G1 phase in a dose-dependent manner, which further illustrated that MAT regulated the cell cycle of K562/ADM cells.

Autophagy is a process that lysosomes degraded the damaged organelles and macromolecules to maintain normal cell biological function (25,26). Recent studies have been shown that autophagy plays an important role in the pathogenesis and treatment of leukemia, and is also involved in multidrug resistance mechanisms. Auberger et al. (27) pointed out that, suppression of autophagy accelerates the progression of acute myelogenous leukemia. Kaewpiboon et al. (28) proved that, Feroniellin A enhances the apoptosis of multidrug resistant lung cancer cells through promoting autophagy. The pharmacological regulation of autophagy is considered as a promising cancer treatment strategy. It has been reported that MAT enhances the autophagy of human hepatoma cells through regulating p53/AMPK signaling pathway (29). Wu et al. (30) demonstrated that MAT acts as a tumor suppressor in acute myelocytic leukaemia by promoting autophagy. In this study, MAT promoted the conversion of LC3 I to LC3 II, as well as the degradation of P62 in a dose-dependent manner. It is known that, the conversion of LC3 I to LC3 II indicates the enhancement of autophagy. P62 protein can inhibit autophagy flux, and is considered as a treatment target for suppression of autophagy in tumors (31-33). Our findings illustrated that MAT induced the autophagy of K562/ADM cells.

Conclusions

In conclusion, MAT reversed the multidrug resistance of K562/ADM cells to ADM and VCR through promoting autophagy. Thus, in clinical practice, MAT may use as a promising pharmaceutical formulation to enhance the sensitivity of multidrug resistant leukemia to chemotherapeutic drugs. This article provided a novel therapeutic strategy against multidrug resistant leukemia.