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Original Article
Effects of Sophorae Radix on Human Gastric and Colorectal Adenocarcinoma Cells
- Sophorae Radix and Cancer Cells -
Min-Chul Kim 1 **, Bora Lim 1 **, Hee-Jung Lee 1 **, Hyung-Woo Kim 2, Young-Kyu Kwon 1, Byung-Joo Kim 1 *
1 Division of Longevity and Biofunctional Medicine, Pusan National University School of Korean Medicine, Yangsan, Korea
2 Division of Pharmacology, Pusan National University School of Korean Medicine, Yangsan, Korea
* Byung-Joo Kim. Division of Longevity and Biofunctional Medicine, Pusan National University School of Korean Medicine, Beomeo-ri, Mulgeum-eup, Yangsan, Gyeongnam 626-870, Korea. Tel: +82-51-510-8469 Fax: +82-51-510-8420 E-mail: vision@pusan.ac.kr
** M. C. Kim, B. Lim and H. J. Lee contributed equally to this work and should be considered as joint first authors.
[received date: 2012-04-04 / accepted date: 2012-05-31]
Abstract
The purpose of this study was to investigate the anti-cancer effects of Sophorae Radix (SR) and doxorubicin (DOX) in human gastric and colorectal adenocarcinoma cells. We used the human gastric and colorectal adenocarcinoma cell lines (MKN-45 and WIDR cells, respectively). We examined cell death by using the MTT(3-[4, 5-dimethylthiazol-2-yl]-2, 5- diphenyltetrazolium bromide) assay and the caspase 3 assay with SR. To examine the inhibitory effects of SR, we performed a cell cycle (sub G1) analysis for the MKN-45 and WIDR cells after three days with SR. The reversibility of SR was examined for one-day to five-day treatments with SR. SR inhibited the growth of MKN-45 and WIDR cells in a dosedependent manner. Also, we showed that SR induced apoptosis in MKN-45 and WIDR cells by using the MTT assay, the caspase 3 assay and the sub-G1 analysis. SR combined with DOX markedly inhibited the growth of MKN-45 and WIDR cells compared to SR or DOX alone. After 3 days of treating MKN-45 and WIDR cells with SR, the fraction of cells in the sub-G1 phase was much higher than that of the control group. Our findings provide insights into unraveling the effects of SR on human gastric and colorectal adenocarcinoma cells and into developing therapeutic agents for use against gastric and colorectal adenocarcinomas.
Keywords
Sophorae Radix, human gastric and colorectal adenocarcinoma cells, MKN-45, WIDR cells, doxorubicin
Open Access
This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
1. Introduction
Gastrointestinal cancer refers to malignant conditions of the gastrointestinal tract, including the esophagus, stomach, biliary system, pancreas, bowels, and anus. The symptoms relate to the organ affected and can include obstruction (leading to difficulty swallowing or defecating), abnormal bleeding, or other associated problems. Among gastrointestinal cancer, stomach and colorectal cancer are the most common cancer in South Korea [1] and the second cause of cancer mortality worldwide [1]. The diagnosis often requires endoscopy, followed by biopsy of suspicious tissue. The treatment depends on the location of the tumor, as well as the type of cancer cell and whether it has invaded other tissues or spread elsewhere in the body [2]. In the middle of treatment, several nonoperative treatment modalities, such as chemotherapy and radiotherapy, are tried, but frequently survival is not prolonged, and side effects are severe [3]. As side effects of chemotherapeutic agents without survival advantage are not trivial, development of new agents exerting anticancer activity through novel mechanisms of action is needed to reduce side effects and increase efficacy [3].

Multiple organ failure caused by cancer progression is the major cause of death in cancer patients. Cancer progression is a multistep process and involves a series of processes including deregulation of cell growth and resistance to apoptosis, cellular adhesion and invasion through the basement membrane, transfer via circulation, extravasation, and proliferation at distant sites [4, 5]. Therefore, prevention of tumor progression is one of the primary goals of cancer prevention and control. However, agents that are currently being used for cancer therapy are generally cytotoxic, with serious side effects that can diminish the quality of life of cancer patients [6]. Recently, many efforts have been made to find non- or low-cytotoxic bioactive compounds that are present in the diet and that have potential anticancer effects [7]. One focus is on compounds found in medicinal plants, which are able to inhibit one or more steps of cancer cell progression [8- 10]. For example, the intestinal metabolite of ginseng saponin, compound K (CK), has various chemopreventive and chemotherapeutic activities, including anti-tumor activity by targeting the NF-κB p65 nuclear export and the reduction of MMP2/9 expression [11].

The roots of Sophorae flavescens Aiton (Sophorae Radix, SR) are used as a traditional Chinese medicine and have various physiological activities, including antioxidant, antibacterial, antiinflammatory, antipyretic, antiarrhythmic, antiasthmatic, antiulcerative, and antineoplastic effects. They are used to treat jaundice, leucorrhea, carbuncles, pyogenic infections of the skin, scabies, enteritis, and dysentery [12]. Additionally, a recent study found that quinolizidine alkaloids, flavonoids, benzofuran, and triterpenoid could be isolated from the roots of SR [8-24]. However, no studies have examined the combined effect of SR and other chemotherapeutic agents on gastric and colorectal adenocarcinoma cells.

In the present study, the effect of SR on the growth of human gastric (MKN-45 cell line) and colorectal adenocarcinoma cells (WIDR cell line) and the combined effects of doxorubicin (DOX) and SR were examined. A cell cycle analysis examined the mechanisms of the inhibitory effects of SR on the proliferation of MKN-45 and WIDR cells.

2. Material and methods
2.1. Preparation of the extract from sophorae radix
Dried root of Sophora flavescens Aiton (Sophorae Radix, SR) was purchased from Kwangmyungdang Medicinal Herbs (Ulsan, Korea). Fifty (50) g of SR were immersed in 1,000 ml of methanol, sonicated for 30 mins, and then extracted for 24 hrs. The extract was filtered with Whatman filter paper (No. 20) and evaporated under reduced pressure using a vacuum evaporator (Eyela, Japan). The condensed extract was then lyophilized using a freeze dryer (Labconco, USA). Finally, 6.43 g of lyophilized powder was obtained (yield: 12.9%).

2.2. Cells
Human gastric (MKN-45) and colorectal (WIDR) adenocarcinoma cell lines were used. All cell lines were established at the Cancer Research Center, College of Medicine, Seoul National University, Korea. All cell lines were propagated in RPMI-1640 medium (Gibco-BRL) supplemented with 10% heat-inactivated fetal bovine serum and 20 μg/ml of penicillin and streptomycin in an atmosphere of 5% CO2 at 37℃.

2.3. MTT (3-[4, 5-dimethylthiazol-2-yl]-2, 5-diphenyl- tetrazolium bromide) assay
Cell viability was assessed by using a MTT (3-[4, 5- dimethylthiazol-2-yl]-2, 5-diphenyltetrazolium bromide) assay. The MKN-45 and WIDR cells were seeded into each well of 12- well culture plates and then cultured in RPMI-1640 supplemented with other reagents for 72 hrs. After incubation, 100 μL of MTT solution (5 mg/mL in PBS) was added to each well, and the plates were then incubated for 4 hrs at 37℃. After removing the supernatant and shaking with 200 μLof dimethyl sulfoxide (Jersey Lab Supply, Livingston, NJ, USA) for 30 mins, we measured the absorbance at 570 nm. All experiments were repeated at least three times.

2.4. Caspase-3 assay
Caspase-3 assay kits (Cellular Activity Assay Kit Plus) were purchased from BioMol (Plymouth, PA, USA). After experimental treatment, cells were centrifuged (1,000 g, 4℃, 10 minutes) and washed with PBS (phosphate buffered saline). Cells were resuspended in ice-cold cell lysis buffer and incubated on ice for 10 mins. Samples were centrifuged at 1,000 g (4℃, 10 mins), and the supernatant was removed. Supernatant samples (10 μL) were incubated with 50 μL of substrate (400 μ M Ac-DEVD-pNA) in 40 μL of assay buffer at 37℃. The absorbance at 405 nm was read at several time-points. The pNA concentration in samples was extrapolated from a standard created with absorbances of sequential pNA concentrations.

2.5. Flow cytometric analysis
In order to investigate whether the cell cycles of the MKN-45 and the WIDR cells were redistributed, we used a flow cytometric analysis with propidium iodine (PI) stain [25, 26]. Cells, 1 × 106, were placed in an e-tube. An ice-cold fixation buffer (ethyl alcohol), 700 μL, was slowly added with vortexing. Tubes were sealed with parafilm and incubated at 4°C overnight. Samples were spun for 3 mins at 106 g at 4°C, and the supernatant was aspirated and discarded. The cell pellet was resuspended by using 200 μL of PI staining solution (PI [5 mg/mL], 2 μL, and RNase, 2 μL, in PBS, 196 μL) at 20,817 g for 5 secs. After 30 mins in the dark at room temperature, sam-ples were analyzed in a fluorescence-activated cell sorter (FACScan; Becton-Dickinson, Mountain View, CA, USA) at λ= 488 nm by using Cell-Quest software (Becton-Dickinson). The DNA content distribution of normal growing cells was characterized by using two peaks, those of the G1/G0 and the G2/M phases. The G1/G0 phase comprises the normal functioning and resting state of the cell cycle with the most diploid DNA content while the DNA content in the G2/M phase is more than diploid. Cells in the sub- G1 phase have the least DNA content in the cell cycle distribution; this is termed hypodiploid. The hypoploid DNA contents represent DNA fragmentation [26].

2.6. Statistical analysis
Data are expressed as mean ± SEM (Standard Error of the Mean). Differences between the data were evaluated by using the Student’s t-test. A P-value of 0.05 was taken to indicate a statistically significant difference.

3. Results
3.1. Inhibition of cell survival by SR
We investigated whether SR influenced the survival of MKN-45 and WIDR cells. SR inhibited the growth of MKN-45 and the WIDR cells (Fig 1) As the concentrations were increased, the growth of the MKN-45 and WIDR cells was increasingly retarded in a dose-dependent manner. In the case of MKN-45 cells, following treatment with a 200 μg/ml concentration of SR for 3 days, survival of MKN-45 cells was reduced by 35.1 ± 9%, compared with controls. Treatment with 400-and 500-μg/ml concentrations of SR exhibited considerable antiproliferative effects on the MKN-45 cells. In case of WIDR cells, following treatment with a 100 μg/ml concentration of SR for 3 days, survival of WIDR cells was reduced by 68.2 ± 7%, compared with controls. Treatment with 300-and 400-μg/ml concentrations of SR exhibited considerable antiproliferative effects on the WIDR cells.

Fig. 1
Effect of SR extract on cytotoxicity in MKN-45 and WIDR cells.

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  • MKN-45 (A) and WIDR cells (B) were incubated with SR extract at the indicated dose (μg/ml). After 3 days, cell viability was measured by using a MTT assay as described in materials and methods. The values are expressed as percent (%) of control, and each column represents the mean ± S.D. *P < 0.05. **P < 0.01.
3.2. Inhibition of cell survival by SR leads to increased apoptosis
To determine whether MKN-45 and WIDR cells death occurred by apoptosis, we used a sub-G1 analysis and the method of specific proteolytic cleavage of the DNA repair enzyme poly (ADP-ribose) polymerase (PARP). As a method to analyze the mode of cell death in MKN-45 and WIDR cells treated with SR, we used a sub-G1 analysis [27, 28]. In this protocol, treated cells are stained with a fluorescent DNA stain (such as PI). Due to the action of endogenous endonucleases in apoptotic cells, the DNA is cleaved into endonucleosomal fragments of typical sizes. These DNA fragments are extracted from the cells. This loss of DNA is detectable by a FACS analysis, as the reduced nuclear staining of apoptotic cells results in a novel (sub-G1) fluorescence peak to the left of the regular fluorescence peak. The sub- G1 fraction in MKN-45 cells treated with SR was markedly increased by 20.1 ± 4.1% at 200 μg/ml, 35.2 ± 3.2% at 300 μ g/ml, 40.2 ± 3.4% at 400 μg/ml, and 45.4 ± 2.3% at 500 μg/ml (Fig 2A). In the case of WIDR cells, the sub-G1 fraction was markedly increased by 15.3 ± 4.2% at 100 μg/ml, 18.2 ±4.1% at 200 μg/ml, 35.3 ± 2.3% at 300 μg/ml, and 44.1 ± 3.4% at 400 μ g/ml (Fig 2B). Caspase-3 activation is one of the hallmarks of apoptotic cell death [29]. We measured the enzyme activity in MKN-45 and WIDR cells treated with SR. Using a synthetic substrate, we found caspase-3 activity in MKN-45 and WIDR cells to be 10.3±1.7 nmol pNA/min/μg protein and 11.2±0.9 nmol pNA/min/μg protein, respectively. In MKN-45 cells, after 72 hours of being treated with 500 μg/ml of SR, elevated caspase- 3 activity was 45.3 ±2.1 nmol pNA/min/μg protein (P<0.01; Fig 3A). In WIDR cells, after 72 hrs of being treated with 400 μ g/ml of SR, elevated caspase-3 activity was 44.2 ± 3.2 nmol pNA/min/μg protein (P <0.01; Fig 3B).

Fig. 2
SR extract induces apoptosis in MKN-45 and WIDR cells.

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  • Caspase 3 activities of MKN-45 (A) and WIDR (B) cells measured by using enzyme assays. The specific activity was obtained from three samples per group. *P < 0.05. **P < 0.01.
Fig. 3
SR extract leads to increase apoptosis in MKN-45 and WIDR cells.

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  • MKN-45 (A) and WIDR (B) cells were incubated with SR extract at the indicated dose (ß∂/ml). After 3 days, the sub-G1 peak was measured by using FACScan as described in materials and methods. The values are expressed as percent (%) of control, and each column represents the mean ± S.D. *P < 0.05. **P < 0.01.
3.3. Reversibility of inhibition
The growth of the SR-treated MKN-45 and WIDR cells remained inhibited with exposure to SR for 1, 2, 3, 4, or 5 days (Fig. 4). After 4 days of incubation, the MKN-45 cells in the SRremoved group exhibited about 15% growth inhibition whereas about 81% inhibition was observed for continuous treatment with SR. After 4 days of incubation, the WIDR cells in the SRremoved group exhibited about 5% growth inhibition whereas about 61% inhibition was observed for continuous treatment with SR. Also, survival of MKN-45 and WIDR cells in the SRremoved group was increased to about 95% and 97% compared with about 115% and 110%, respectively, for the control group at 5 days.

Fig. 4
Reversibility of effects of SR extract in MKN-45 and WIDR cells.

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  • Closed squares, control group MKN-45 (A) and WIDR (B) cells; closed circles, SR treatment for 24 hrs followed by replacement with SR free medium; closed triangles, SRtreated group. *P < 0.05. **P < 0.01.
3.4. Synergistic effects of SR and DOX
Combined treatment with SR and DOX significantly increased the growth inhibition of MKN-45 and WIDR cells compared with SR or DOX alone (P < 0.05, Table 1 and 2). After 3 days of treatment, the inhibition rates for MKN-45 cell proliferation for 100 μg/ml of SR and 500 nM of DOX were about 42% and 32%, respectively. However, combined treatment with 100 μg/ml of SR and 500 nM of DOX exhibited about 87% inhibition against MKN-45 cells. As the concentration of SR combined with DOX was increased, the growth of the MKN-45 cells was retarded in a dose-dependent manner. In particular, 100 μg/ml of SR, combined with 1 μM of DOX, markedly inhibited the growth of MKN-45 cells (Table 1). After 3 days of treatment, the inhibition rates for WIDR cell proliferation for 100 μg/ml of SR and 500 nM of DOX were about 31% and 5%, respectively. However, combined treatment with 100 μg/ml of SR and 500 nM of DOX exhibited about 57% inhibition against WIDR cells. As the concentration of SR combined with DOX was increased, the growth of the WIDR cells was retarded in a dose-dependent manner. In particular, 100 μg/ml of SR, combined with 1 μM of DOX, markedly inhibited the growth of WIDR cells (Table 2).

Table. 1
Effects of Sophorae Radix extract(SR) and/or Doxorubicin(DOX) at varied concentrations on growth of MKN-45 human gastric cancer cells after 3 days of treatment

SR(μg ± DOX Inhibition rate (%)
Control 0
SR(50) 11
SR(100) 42
DOX(500 nM) 32
DOX(1 uM) 81
DOX(500 nM) + SR(50) 53
DOX(500 nM) + SR(100) 87
DOX(1 uM) + SR (50) 97
DOX(1 uM) + SR (100) 99

Table. 2
Effects of Sophorae Radix extract(SR) and/or Doxorubicin(DOX) at vried concentrations on growth of WIDR human colorectal adenocarcinoma cells after 3 days of tratment

SR (μg ± DOX)Inhibition rate (%)
Control 0
SR (50) 10
SR (100) 31
DOX(500 nM) 5
DOX(1 uM) 32
DOX(500 nM) + SR (50) 24
DOX(500 nM) + SR (100) 57
DOX (1 uM) + SR (50) 68
DOX (1 uM) + SR (100) 87

  • Closed squares, control group MKN-45 (A) and WIDR (B) cells; closed circles, SR treatment for 24 hrs followed by replacement with SR free medium; closed triangles, SRtreated group.
4. Discussion
In this study, SR significantly inhibited the growth of MKN-45 and WIDR cells compared with controls (P<0.01). The inhibitory effects of SR on the growth of MKN-45 and WIDR cells were first observed at a 200-μg/ml and a 100-μg/ml concentration, respectively and this inhibitory effect was dose-dependent up to 400 μg/ml. These data suggest that SR has a significant antiproliferative effect in MKN-45 and WIDR cells, as has been observed in other cancer cells [30-33]. SR is the dried roots of Sophora flavescens AITON (Leguminosae) and is distributed widely in Korea. It has been used in Oriental traditional medicine for treatment of skin and mucosal ulcers, sores, gastrointestinal hemorrhage, diarrhea, inflammation and arrhythmia [34-36]. As its chemical constituents, alkaloids and flavonoids have so far been reported [37]. Also, in the course of screening for biological activities of Sophora flavescens, we found that SR has potent cell anti-proliferation activity in HepG2 hepatoblastomas, Hep3B hepatocellular carcinomas, MDA-MB231 breast carcinomas, A549 lung cancer and KG-1 acute myelogenous leukemia [31]. However, we found that aqueous extract of SR has potent cell proliferation activity of human oral mucosal fibroblasts via cell cycle regulation [30]. SR in combination with DOX exerted an antiproliferative effect against MKN-45 and WIDR cells in a synergistic fashion, and this is the first report that has shown a synergistic effect of SR and DOX in gastric and colorectal adenocarcinoma cell lines, which suggests SR can become a useful agent for the treatment of gastric and colorectal adenocarcinomas, not only alone, but also in combination with DOX.

In the present study, inhibition was lost when SR was removed by media change after 24 hrs of SR treatment and was not different from the control group thereafter, suggesting reversibility of the effect of SR against MKN-45 and WIDR cells. The reversibility of growth inhibition suggests that SR is not a nonspecific cytotoxin but has a specific mechanism for inhibiting proliferation of MKN-45 and WIDR cells.

Apoptotic cell death pathways are induced by a variety of signals. One mechanism which is consistently implicated in apoptosis is the activation of a series of cytosolic proteases, the caspases [34]. Caspases are synthesized as inactive proenzymes that are processed in cells undergoing apoptosis by self-proteolysis and/or cleavage by another protein. In MKN-45 and WIDR cells, after 72 hrs of being treated with SR, caspase-3 activity is increased (Fig 3).

In conclusion, SR significantly inhibited the growth of MKN-45 and WIDR cells in a dose-dependent manner. The inhibitory effect of SR on the growth of MKN-45 and WIDR cells was reversible, for the growth of MKN-45 and WIDR cells after removal of SR by media change after 24 hrs of treatment was not different from that of the control group. The reversibility of growth inhibition suggests that SR is not a nonspecfic cytotoxin for MKN-45 and WIDR cells. This is the first report that SR may be very useful for the treatment of gastric and colorectal adenocarcinomas, especially in conjunction with DOX. More studies employing animal experiments and clinical trials are needed to establish the efficacy of SR as an anticancer drug for treating human gastric and colorectal adenocarcinomas.

References
  1. Park JG, Park KJ, Ahn YO, Song IS, Choi KW, Moon HY, et al. Risk of gastric cancer among Korean familial adenomatous polyposis patients. Report of three cases. Dis Colon Rectum. 1992;35(10);996-8
  2. Resende C, Thiel A, Machado JC, Ristimaki A. Gastric cancer: basic aspects. Helicobacter. 2011;16(Suppl1):38-44.
  3. Yamada T. Textbook of Gastroenterology, 3rd ed. Philadelphia: Lippincott Williams & Wilkins; 1999. p.1500-20.
  4. Fidler IJ, Kripke ML. Metastasis results from preexisting variant cells within a malignant tumor. Science. 1977;197(4306):893-5.
  5. Nagase H, Woessner JF Jr. Matrix metalloproteinases. J Biol Chem. 1999:274(31):21491-4.
  6. Braun-Falco M, Holtmann C, Lordick F, Ring J. [Follicular drug reaction from cetuximab: a common side effect in the treatment of metastatic colon carcinoma]. Hautarzt. 2006;57(8):701-4. [In German]
  7. Kelloff GJ, Crowell JA, Steele VE, Lubet RA, Boone CW, Malone WA, et al. Progress in cancer chemoprevention. Ann N Y Acad Sci. 1999;889:1-13.
  8. Lin SS, Lai KC, Hsu SC, Yang JS, Kuo CL, Lin JP, et al. Curcumin inhibits the migration and invasion of human A549 lung cancer cells through the inhibition of matrix metalloproteinase- 2 and -9 and Vascular Endothelial Growth Factor (VEGF). Cancer Lett. 2009;285(2):127-33.
  9. Yodkeeree S, Garbisa S, Limtrakul P. Tetrahydrocurcumin inhibits HT1080 cell migration and invasion via downregulation of MMPs and uPA. Acta Pharmacol Sin. 2008;29(7):853-60.
  10. Pitchakarn P, Suzuki S, Ogawa K, Pompimon W, Takahashi S, Asamoto M, et al. Kuguacin J, a triterpeniod from Momordica charantia leaf, modulates the progression of androgenindependent human prostate cancer cell line, PC3. Food Chem Toxicol. 2012;50(3-4):840-7.
  11. Ming Y, Chen Z, Chen L, Lin D, Tong Q, Zheng Z, et al. Ginsenoside compound K attenuates metastatic growth of hepatocellular carcinoma, which is associated with the translocation of nuclear factor-κB p65 and reduction of matrix metalloproteinase-2/9. Planta Med. 2011;77(5):428-33.
  12. Chang HM, But PPH. Pharmacology and applications of Chinese materia medica. Singapore: World Scientific; 1986. p.736-7.
  13. Ueno A, Morinaga K, Fukushima S, Iitaka Y, Koiso Y, Okuda S. Studies on lupin alkaloids. VI. Isolation and structure of (+)-isomatrine. Chem Pharm Bull. 1975;26(11):2560-6.
  14. Wu LJ, Miyase T, Ueno A, Kuroyanagi M, Noro T, Fukushima S. Studies on the constituents of Sophora flavescens. Ait. III. Chem Pharm Bull. 1985;33:3231-38.
  15. Kyogoku K, Hatayama K, Komatsu M. Constituents of Chinese crude drug Kushen (the root of Sophora flavescens Ait.). Isolation of five new flavonoids and formononetin. Chem Pharm Bull. 1973;21(12):2733-8.
  16. Yamamoto H, Ichimura M, Ishikawa N, Tanaka T, Iinuma M, Mizuno M. Localization of prenylated flavonoids in Sophora flavescens var. angustifolia plants. Phytochemistry. 1991;30:1732-8.
  17. Yamahara J, Mochizuki M, Fujimura T, Takaishi Y, Yoshida M, Tomimatsu T, et al. Antiulcer action of Sophora flavescens root and an active constituent. I. J Ethnopharmacol. 1990;29(2):173-7.
  18. Ding Y, Tian RH, Kinjo J, Nohara T, Kitagawa I. Three new oleanene glycosides from Sophora flavescens. Chem Pharm Bull. 1992;40(11):2990-4.
  19. Woo ER, Kwak JH, Kim HJ, Park H. A new prenylated flavonol from the roots of Sophora flavescens. J Nat Prod. 1998;61(12):1552-4.
  20. Kang TH, Jeong SJ, Ko WG, Kim NY, Lee BH, Inagaki M, et al. Cytotoxic lavandulyl flavanones from Sophora flavescens. J Nat Prod. 2000;63(5):680-1.
  21. Son JK, Park JS, Kim JA, Kim Y, Chung SR, Lee SH. Prenylated flavonoids from the roots of Sophora flavescens with tyrosinase inhibitory activity. Planta Med. 2003;69(6):559-61.
  22. Kim SJ, Son KH, Chang HW, Kang SS, Kim HP. Tyrosinase inhibitory prenylated flavonoids from Sophora flavescens. Bio Pharm Bull. 2003;26(9):1348-50.
  23. Ding P, Chen D, Bastow KF, Nyarko AK, Wang X, Lee KH. Cytotoxic isoprenylated flavonoids from the roots of Sophora flavescens. Helv Chim Acta. 2004;87(1):2574-80.
  24. Sato S, Takeo J, Aoyama C, Kawahara H. Na+-glucose cotransporter (SGLT) inhibitory flavonoids from the roots of Sophora flavescens. Bioorg Med Chem. 2007;15(10):3445-9.
  25. Nicoletti I, Migliorati G, Pagliacci MC, Grignani F, Riccardi C. A rapid and simple method for measuring thymocyte apoptosis by propidium iodide staining and flow cytometry. J Immunol Methods.
  26. Wang BJ, Won SJ, Yu ZR, Su CL. Free radical scavenging and apoptotic effects of Cordyceps sinensis fractionated by supercritical carbon dioxide. Food Chem Toxicol.
  27. Hotz MA, Gong J, Traganos F, Darzynkiewicz Z. Flow cytometric detection of apoptosis: comparison of the assays of in situ DNA degradation and chromatin changes. Cytometry. 1994;15(3):237-44.
  28. Vermes I, Haanen C, Reutelingsperger C. Flow cytometry of apoptotic cell death. J Immunol Methods. 2000;243(1-2):167-90.
  29. Faleiro L, Kobayashi R, Fearnhead H, Lazebnik Y. Multiple species of CPP32 and Mch2 are the major active caspases present in apoptotic cells. EMBO J. 1997;16(9):2271-81.
  30. Kim HA, You HK, Shin HS, Kim YC, Kang TH, Yu HH, et al. Effects of aqueous extract of Sophora flavescens on the expression of cell cycle regulatory proteins in human oral mucosal fibroblasts. Am J Chin Med. 2003;31(4):563-72.
  31. Chui CH, Lau FY, Tang JC, Kan KL, Cheng GY, Wong RS, et al. Activities of fresh juice of Scutellaria barbata and warmed water extract of Radix Sophorae Tonkinensis on antiproliferation and apoptosis of human cancer cell lines. Int J Mol Med. 2005;16(2):337-41.
  32. Long G, Wang G, Ye L, Lin B, Wei D, Liu L, et al. Important role of TNF-alpha in inhibitory effects of Radix Sophorae Flavescentis extract on vascular restenosis in a rat carotid model of balloon dilatation injury. Planta Med. 2009;75(12):1293-9.
  33. Wang S, Sun M, Zhang Y, Du H, He L. A new A431/cell membrane chromatography and online high performance liquid chromatography/mass spectrometry method for screening epidermal growth factor receptor antagonists from Radix sophorae flavescentis. J Chromatogr A. 2010;1217(32):5246-52.
  34. Patel T, Gores GJ, Kaufmann SH. The role of proteases during apoptosis. FASEB J. 1996;10(5):587-97.
  35. Liu D, Xin X, Su DH, Liu J, Wei Q, Li B, et al. Two new lavandulyl flavonoids from Sophora flavescens. Nat Prod Commun. 2010;5(12):1889-91.
  36. Piao XL, Piao XS, Kim SW, Park JH, Kim HY, Cai SQ. Identification and characterization of antioxidants from Sophora flavescens. Biol Pharm Bull. 2006;29(9):1911-5.
  37. Jin JH, Kim JS, Kang SS, Son KH, Chang HW, Kim HP. Antiinflammatory and anti-arthritic activity of total flavonoids of the roots of Sophora flavescens. J Ethnopharmacol. 2010;127(3):589-95.
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