Abstract
Overexpression of survivin is frequently observed in human malignancies and is associated with poor prognosis. The present study found that survivin is highly expressed in nasopharyngeal carcinoma (NPC) tumor tissues. Depleting survivin with shRNA inhibited cell viability, colony formation, and in vivo tumorigenesis of NPC cells. With a natural product screening, we identified Butein as a potential anti-tumor compound for NPC by reducing survivin protein level. Butein shortened the half-life of survivin and enhanced ubiquitination-mediated degradation. The mechanism study showed that Butein promoted the interaction between survivin and E3 ligase Fbxl7, and the knockdown of Fbxl7 compromised Butein-induced survivin ubiquitination. Butein suppressed the Akt-Wee1-CDK1 signaling and decreased survivin Thr34 phosphorylation, facilitating E3 ligase Fbxl7-mediated survivin ubiquitination and degradation. Moreover, Butein exhibited a strong in vivo anti-tumor activity, as the tumor volume of Butein-treated xenografts was reduced significantly. Butein alone or combined with cisplatin (CDDP) overcame chemoresistance in NPC xenograft tumors. Overall, our data indicate that Butein is a promising anti-tumor agent for NPC treatment.
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Introduction
Nasopharyngeal carcinoma (NPC) is one of the most commonly diagnosed malignant tumors that arise from the nasopharynx's epithelial lining. The incidence of NPC exhibits prominent ethnic, regional, and familial epidemiological characteristics. NPC causes a heavy public-health burden in Southeast Asia, Southern China, the Arctic, North Africa, and the Middle East, and approximately 47.7% of all new cases of NPC globally were diagnosed in Southern China1,2. To date, the precise mechanism of NPC tumorigenesis remains unclear. However, a panel of risk factors has been described, including ethnicity, EBV infection, hereditary trends, dietary habits, and tobacco consumption2,3,4. Due to NPC's special location and occult nature, over 70% of patients were diagnosed at an advanced stage. Although concurrent radiationtherapy/chemotherapy significantly improves the prognosis of NPC, metastasis is the leading cause of therapy failure and cancer-related death2,5,6,7. Thus, further elucidating the mechanisms of NPC tumorigenesis and discovery of novel anti-tumor targets are still the urgent demand for NPC treatment.
Survivin plays a crucial role in G2/M cell cycle transition and apoptosis inhibition8. Survivin binds with Aurora B, INCENP, and Borealin to form the chromosomal passenger complex (CPC), which guarantees proper chromosomes and segregation during mitosis9. Accumulating evidence indicates that survivin is frequently overexpressed in human cancers, including non-small cell lung cancer10, prostate cancer11, colorectal cancer12, gastric cancer13, and hepatocellular carcinoma14. Highly expressed survivin is associated with radio/chemotherapy resistance, tumor recurrence, and poor prognosis, making survivin a fantastic therapeutic target for anticancer treatment15. Survivin localizes in both cytoplasm and nuclear and exhibits various subcellular functions. Survivin is predominantly expressed in the cytoplasm and binds with caspase-3 to maintain the survival of cancer cells, whereas the nuclear-localized survivin is an essential subunit of CPC complex to orchestrate mitosis16,17. Thus, as an oncoprotein that is both required for cell cycle progression and apoptosis suppression, survivin is emerging as a promising anti-tumor target for clinical treatment.
The natural product Butein is a potent anti-tumor agent against human malignancies17,18. Previous studies have shown that Butein suppresses osteosarcoma19, cervical cancer20,21, colorectal cancer22, hepatocellular carcinoma23, breast cancer24,25, lung cancer26, and oral squamous cell carcinoma27. The mechanism studies have identified multiple intracellular targets of Butein, including AurkB, mTOR, NF-κB, EGFR, and c-Met17,28,29,30. Butein induces cell cycle arrest, promotes apoptosis, suppresses angiogenesis/metastasis, and compromises glycolysis17. However, the antitumor effect of Butein on NPC and the potential synergistic function of Butein on chemoresistance is unclear.
In this study, we found that survivin is overexpressed in NPC tissues and required for maintaining the malignant phenotype of NPC cells. We demonstrated that the natural product Butein is a potential anti-tumor compound for NPC treatment. We investigated the inhibitory effect of Butein on NPC cells and determined the underlying mechanism of this anti-tumor efficacy.
Materials and methods
Cell culture and antibodies
The chemicals, including the natural product Butein, cycloheximide (CHX), and proteasome inhibitor MG132, were obtained from Selleck Chemicals (Houston, TX). Human NPC cell lines, including CNE2 (a low-differentiated NPC epithelial cell line derived from a primary tumor biopsy), HONE1 (latently infected with Epstein-Barr virus and derived from primary nasopharyngeal carcinomas), and SUNE1 (epithelial cancer cells derived from primary nasopharyngeal carcinomas), were purchased from the Cell Bank of Central South University, Changsha, China, and maintained in a 37 °C humidified incubator with 5% CO2 according to the standard protocols. All cell lines were routinely tested for mycoplasma contamination and subjected to a cytogenetic test to confirm identity. Cell culture medium and supplies, including RPMI-1640 and Fetal Bovine Serum (FBS), were obtained from Invitrogen (Grand Island, NY). The primary antibodies against survivin (#2808), cleaved-caspase 3 (#9664), cleaved-PARP (#5625), cytochrome C (#11940), Bax (#5023), VDAC1(#4661), α-Tubulin(#3873), ubiquitin (#3936), Flag-tag (#8146), HA-tag (#3724), and β-actin (#4970) were purchased from Cell Signaling Technology, Inc. (Beverly, MA). The anti-ki67 (ab16667) and FbxL7 (#ab59149) antibodies were products of Abcam (Cambridge, United Kingdom). The Flag-Survivin construct was purchased from Origene (RC205935), and the T34A mutant was generated using the Q5 Site-Directed Mutagenesis kit (Cat. #E0554S, NEB, Ipswich, MA) following the manufacturer’s standard protocol and verified by DNA sequencing.
Cell viability assay
The MTS assay was performed to analyze cell viability. Briefly, NPC cells were counted and seeded into the 96-well plates at 3000 cells/well density and maintained overnight. Cells were exposed to different doses of Butein and culture for 24, 48, and 72 h. The MTS reagent (#G3580, Madison, WI) was added to the cell culture medium, and cell viability was examined following the standard protocol.
Anchorage-independent cell growth
The colony formation in soft agar was performed as described previously18. Briefly, the 0.6% agar containing Eagle’s basal medium was mixed with 10% FBS, and various dose of Butein was used as an agar base in a 6-well plate. The cells were counted and resuspended at a density of 8000 cells/ml using the Eagle’s basal medium containing 0.3% agar, 10% FBS, and various concentration of Butein. The mixture was overlaid into a 6-well plate with a 0.6% agar base and maintained for 2 weeks for colony counting.
Clinical tissue sample collections
A total of 30 cases of NPC tissues and matched adjacent non-tumor tissues were collected from 30 patients with written informed consent by the Department of Pathology, Hunan Cancer Hospital of Central South University, Changsha, Hunan, China. All the patients received no treatment before surgery.
Western blotting
The cells were treated with Butein, and the whole-cell extract (WCE) was prepared using the commercial RIPA buffer (#89901, Thermo Fisher Scientific) with proteasome inhibitor. WCE was concentrated using the BCA protein assay kit (#23228, Thermo Fisher Scientific) and subjected to immunoblotting (IB) analysis. Briefly, WCE (a total of 15 μg) was boiled with loading buffer at 95 °C for 5 min and subjected to SDS-PAGE electrophoresis and electrotransfer to the PVDF membrane. After being blocked with 5% non-fat milk, the membrane was incubated with primary and second antibodies. The ECL substrate (#34579, Thermo Fisher Scientific) was used for target protein visualization. The membranes were cut prior to hybridization with antibodies, therefor the images of adequate length were absence. All uncropped western blots results were included in Supplemental Fig. 4.
Natural compound screening
The 82 compounds of interest were selected from the Natural Product Library (Cat. No. L1400-01/02) from Selleck Chemicals (Houston, TX). CNE2 cells were seeded in a 96-well plate. After overnight incubation, cells were treated with DMSO (control) or natural compounds (5 µM) for 48 h. Cell viability was examined by the MTS assay. Tested compounds are listed in Supplementary Table 1.
Generation of survivin knockdown stable cell lines
To generate survivin knockdown stable cells, pLKO.1-shsurvivin lentivirus plasmids (TRCN0000073718, TRCN0000073721, Millipore Sigma) were cotransfected into 293 T cells with PSPAX2 and PMD2-G. Three days later, the viral supernatant fractions were harvested and filtered through a 0.45 mm filter, followed by infection into cells with 5 mg/mL polybrene. The puromycin (1 μg/ml) containing fresh medium was replaced 36 h after infection and maintained for 1 week for colony selection.
In vivo tumor growth
The xenograft mouse model was approved by the Institutional Animal Care and Use Committee (IACUC) of Central South University (Changsha, China). In vivo tumor growth was performed by s.c.injection of CNE2 cells (3 × 106) into the right flank of 7-week-old athymic nude mice (n = 5). Tumor volume was recorded, and Butein administration was initiated when tumor volume reached 100 mm3. The control group was administered the vehicle control, whereas the compound-treated group was administered Butein (20 mg/kg) every 2 days by i.p. injection. For the combination treatment, the tumor-bearing mice were randomly divided into four groups (n = 5): 1,vehicle control (0.5% dimethyl sulfoxide, 100 µL/every 2 days, i.p.); 2, Butein (10 mg/kg/ every 2 days, i.p.); 3, CDDP (3 mg/kg/ every 2 days, i.p.); 4, Butein (10 mg/kg/ every 2 days, i.p.) + CDDP (3 mg/kg/ every 2 days, i.p.). The mice were euthanized with CO2 (3 L/min) for 5 min at the endpoint. Tumor volume was determined using the following formula: length × width × width/2.
Immunohistochemical staining (IHC)
Tumor tissues from clinical samples and mouse xenograft tumors were fixed and subjected to IHC analysis as described previously19. Briefly, the tissue slides were deparaffinized and rehydrated by incubation with xylene and ethanol, then submerged into sodium citrate buffer (10 mM, pH 6.0) and boiled for 10 min for antigen retrieval. The activity of endogenous horseradish peroxidase was quenched by incubation with 3% H2O2 in methanol for 10 min. Tissue slides were washed with PBS and blocked with 50% goat serum albumin. After incubating the primary and second antibodies, the target protein was visualized using the DAB substrate and counterstained by hematoxylin.
Statistical analysis
Statistical analysis was performed using GraphPad Prism 5 (GraphPad 5.0, San Diego, CA, USA). All quantitative data were performed from three independent experiments and expressed as mean ± sd. The difference was evaluated using the Student's t-test or ANOVA. A probability value of p < 0.05 was used as the criterion for statistical significance.
Ethics approval and consent to participate
The animal experiments were approved by the Medical Research Animal Ethics Committee, Central South University, China.
Results
Survivin is highly expressed in nasopharyngeal carcinoma and is required for maintaining tumorigenic properties
To investigate the oncogenic function of survivin in nasopharyngeal carcinoma (NPC), we determined the protein level of survivin in tumor tissues. The result showed that survivin is overexpressed in NPC tissues compared to the paired non-tumor adjacent tissue (Fig. 1A). We next constructed survivin knockdown stable cells in CNE2 and HONE1 cells. The colony formation assay revealed that the depletion of survivin inhibited anchorage-independent cell growth of CNE2 and HONE1 cells, as the colony number was reduced by around 70% compared to that of survivin proficient cells (Fig. 1B). Consistently, the MTS data indicated that knockdown of survivin significantly suppressed the cell viability of NPC cells (Fig. 1C). We next examined the in vivo tumorigenesis of survivin knockdown cells. The xenograft model showed that depletion of survivin inhibited tumor development. The CNE2-shsurvivin-derived xenograft tumors exhibited smaller tumor volume and weight (Fig. 1D–F). The IHC data showed that the population of Ki67 positive cells was attenuated significantly in shsurvivin-expression xenograft tumors (Fig. 1G). Our results suggest that survivin is highly expressed in NPC tissues, and knockdown of survivin impaired the tumorigenic properties of NPC cells.
Butein inhibits NPC cells in vitro
To discover natural compounds (Supplementary Table 1) that can suppress NPC cells and reduce survivin protein levels, we screened a customized natural compound library containing 82 compounds of interest by MTS assay. We found that only Butein caused a reduction of cell viability in CNE2 cells by around 30% at a single dose of 5 μM (Fig. 2A, Supplementary Fig. 1). Butein (Fig. 2B) exhibits strong anti-tumor activities in human cancer models. However, the anti-tumor potential of Butein on NPC cells is not clear. We found that Butein significantly inhibited the cell viability of CNE2, SUNE1, and HONE1 cells dose-dependently (Fig. 2C–E). Exposure to Butein (20 μM) for 72 h decreased the cell viability of all tested NPC cells by over 80%. However, Butein failed to inhibit the cell viability of immortalized non-tumor cell NP460 (Fig. 2F). We next tested the antitumor activity of Butein using the soft agar assay. The non-tumor cell NP460 failed to form the colony in the soft agar (Fig. 2G). However, the efficacy of colony formation of NPC cells in soft agar was impaired significantly after Butein treatment. The inhibitory effect of Butein was enhanced dose-dependently, and 10 μM Butein reduced the colony number by over 60% in CNE2, HONE1, and CNE1 cells. Moreover, 20 μM Butein decreased the colony number by over 85% in SUNE1 and HONE1 cells and over 75% in CNE2 cells, respectively (Fig. 2G). These data indicate that Butein inhibits NPC cells in vitro.
Butein promotes survivin degradation in NPC cells
We next determined the mechanisms of how Butein inhibited NPC cells in vitro. The Immunoblotting data showed that treatment of MG132, a proteasome inhibitor, restored the protein level of survivin in Butein-treated NPC cells (Fig. 3A,B), indicating that Butein might affect the stability of survivin protein. As shown in Fig. 3C, exposure to Butein reduced the half-life of survivin in CNE2 cells. We next determined the ubiquitination of survivin in Butein-treated cells. The result showed that Butein promoted survivin ubiquitination in CNE2 and HONE1 cells (Fig. 3D, Supplementary Fig. 2A). Furthermore, the co-IP data indicated that treatment with Butein enhanced the interaction between survivin and the E3 ligase Fbxl7 (Fig. 3E). The ubiquitination assay revealed that Butein enhanced Fbxl7-mediated survivin ubiquitination (Fig. 3F, Supplementary Fig. 2B). To determine whether Fbxl7 is required for survivin ubiquitination in Butein-treated NPC cells, we silenced Fbxl7 using siRNA in CNE2 cells. We found that knockdown of Fbxl7 impaired Butein-induced survivin ubiquitination (Fig. 3G, Supplementary Fig. 2C). Mutation of the residues K90/91 compromised Fbxl7-induced survivin ubiquitination in CNE2 and HONE1 cells (Fig. 3H, Supplementary Fig. 2D), which is consistent with previous studies that K90/91 plays crucial role in survivin stability. Furthermore, our data showed that mutation of K90/91 reduced Butein-induced survivin ubiquitination in CNE2 and HONE1 cells (Fig. 3I, Supplementary Fig. 2E). These results imply that Butein promotes survivin ubiquitination and degradation.
Butein-decreased Akt phosphorylation is required for survivin ubiquitination
Phosphorylation of Thr34 stabilizes survivin20. We therefore determined whether Butein reduces survivin phosphorylation. The results showed that Butein suppressed survivin Thr34 phosphorylation dose-dependently in CNE2, HONE1, and SUNE1 cells (Fig. 4A). Treatment with Butein reduces Akt Ser473 phosphorylation and the downstream target Wee1 (Fig. 4B). Furthermore, down-regulation of Wee1 phosphorylation at Ser642 increased CDK1 phosphorylation on Tyr15. Consistently, the phosphorylation of CDK1 on Thr161, a marker for CDK1 activation, was suppressed dose-dependently (Fig. 4B). Knockdown of Akt with siRNA caused a reduction of the phosphorylation of Wee1 (Ser642), CDK1 (Thr161), and survivin (Thr34) (Fig. 4C). Overexpression of Myr-Akt1, a constitutively activated Akt, compromised Butein-induced decrease of phosphorylation of Wee1 (Ser642), CDK1 (Thr161), and survivin (Thr34) (Fig. 4D). The MTS data indicated that transfected with Myr-Akt1 rescued cell viability in Butein-treated CNE2 cells (Fig. 4E). Moreover, the activated cleaved-caspase 3 was down-regulated significantly (Fig. 4F), and cleaved-caspase 3 and -PARP expression was also inhibited (Fig. 4G). Mutation of survivin Thr34 to Ala34 caused stronger ubiquitination of survivin in Butein-treated CNE2 cells (Fig. 4H). Importantly, wild-type (WT) survivin, but not the T34A mutant, rescued cell viability (Fig. 4I) and reduced caspase 3 activity (Fig. 4J). Our data suggest that inhibition of Akt phosphorylation is required for survivin ubiquitination and degradation.
Butein induces apoptosis in NPC cells
We further examined whether Butein activates apoptosis signaling in NPC cells. IB data showed that Butein increased the protein level of cleaved-PARP and -caspase 3 dose-dependently in CNE2 and HONE1 cells (Fig. 5A). Notably, caspase 3 was significantly elevated in Butein-treated cells (Fig. 5B), indicating that Butein promotes apoptosis in NPC cells. We next isolated the subcellular fractions in CNE2 cells after Butein treatment. The result showed that Butein promoted the release of cytochrome C from the mitochondrial to the cytoplasm. Consistently, the protein level of Bax in mitochondrial was upregulated along with the increased concentration of Butein (Fig. 5C). This evidence suggests that Butein activates apoptosis signaling. To determine whether Butein-induced apoptosis is related to survivin destruction, we overexpressed survivin in CNE2 cells. MTS data showed that overexpression of survivin restored cell viability (Fig. 5D), compromised apoptosis (Fig. 5E), and decreased the protein level of cleaved-caspase 3 and -PARP (Fig. 5F) in Butein-treated CNE2 cells. We further isolated subcellular fractions and found that overexpression of survivin rescued Butein promoted intrinsic apoptosis, as the release of cytochrome C from mitochondrial and the protein level of Bax in mitochondrial was decreased substantially (Fig. 5G). Our data suggest that Butein induces mitochondrial apoptosis in NPC cells.
Butein inhibits in vivo tumor growth
Xenograft mouse models were conducted using CNE2 and HONE1 cells to examine the in vivo anti-tumor effect of Butein. Our data showed that treatment with Butein significantly delayed CNE2 xenograft tumor growth, as two-thirds reduced the tumor volume compared to the vehicle-treated tumors (Fig. 6A). Moreover, the weight of tumor mass was down-regulated by over 60% in the Butein-treated group (Fig. 6B,C). Butein exhibited a similar inhibitory effect on HONE1 xenograft tumors (Fig. 6D–F). We further examined the protein level of survivin in CNE2-derived tumor tissues. The IHC results showed that Butein significantly decreased the population of Ki67-positive cells. The number of survivin-positive cells was reduced by nearly 80% in the Butein-treated group (Fig. 6G,H). IB data also revealed that the total protein level of survivin was reduced consistently (Fig. 6I). Our data indicate that Butein suppresses in vivo tumor development of CNE2 cells.
Butein overcomes chemoresistance in NPC cells
To determine whether Butein affects chemotherapy of NPC cells, we first examined the inhibitory efficacy of Butein in combination with CDDP treatment in CNE2 and HONE1 cells. The MTS data showed that CDDP or Butein alone reduced cell viability by around 25–30%, whereas the combination treatment enhanced this anti-tumor efficacy by over 80% (Supplementary Fig. 3A). The colony formation was consistently blocked by over 90% in CNE2 and HONE1 cells after the combination treatment (Supplementary Fig. 3B). Importantly, these inhibitory effects were observed in CDDP-resistant CNE2-R and HONE1-R cells with Butein and CDDP treatment (Fig. 7A,B). The western blotting results revealed that survivin is overexpressed in chemoresistant CNE2-R and HONE1-R cells (Fig. 7C). Butein, but not CDDP alone, reduced the protein level of survivin and promoted the expression of cleaved-caspase 3/-PARP. In addition, caspase 3 activity increased with Butein treatment and further enhanced with the combination treatment (Fig. 7D,E), indicating that Butein induced apoptosis. The IB data showed that treatment with Butein facilitated CDDP-induced DNA damage, as the phosphorylation of H2AX was dramatically upregulated (Fig. 7F). We next examined whether Butein overcomes chemoresistance in vivo. The results showed that the CDDP alone failed to restrict the in vivo tumor development of CNE2-R and HONE1-R xenograft. However, Butein alone delayed tumor development, and the combination of Butein sensitized CNE2-R and HONE1-R xenograft to CDDP treatment (Fig. 7G,H), indicating that Butein overcomes chemoresistance of NPC cells in vivo. Moreover, the IHC staining showed that Butein, but not CDDP alone, reduced survivin protein levels in xenograft tumor tissues, and this inhibitory effect was further enhanced in the combination treatment group (Fig. 7I,J). These results indicate that Butein suppressed tumor growth and exhibited the potential to overcome CDDP resistance.
Discussion
Butein (2′,3,4,4′-tetrahydroxychalcone) is a polyphenol compound found in several plants and has been found to exhibit potent antioxidant, anti-inflammatory, and also anti-tumor effects against multiple cancer types21. However, its effect on NPC and CDDP chemoresistance is not studied yet. Our data showed that Butein inhibited the cell viability of NPC cells and overcame chemoresistance by activating the intrinsic apoptosis signaling. Butein reduced the protein level of survivin dose-dependently and enhanced survivin ubiquitination by promoting the interaction between survivin and E3 ligase Fbxl7. Importantly, our data indicated that depletion of Fbxl7 compromised Butein-induced survivin destruction. Our data discovered a novel anti-tumor mechanism of Butein and suggested that targeting survivin is a promising alternative strategy for NPC treatment.
Survivin is frequently dysregulated in human cancers. The high protein level of survivin accelerates cell cycle progression and confers chemo/radioresistance by suppressing the apoptosis cascade. For instance, survivin highly expressed head and neck squamous carcinoma cells (HNSCC) exhibited a robust therapeutic resistance towards lapatinib22. Downregulation of survivin overcomes osimertinib and radiotherapy resistance in glioma cells and oral squamous cell carcinoma cells23,24, respectively. Recent studies indicate that overexpression of survivin enhanced angiogenesis and metastasis. Pharmaceutical inhibition of survivin, or reduction of survivin protein level, suppressed metastasis of breast25, ovarian26, and lung cancer27. Moreover, the high protein level of survivin is corrected with the poor prognosis of HNSCC and NPC28,29,30. Our data revealed that survivin depletion blunted the malignant phenotype of NPC cells, including the inhibitory effects on cell viability, colony formation, and in vivo tumor development. This evidence suggests that targeting survivin is an alternative strategy for clinical treatment in multiple cancer models.
The expression of survivin is tightly regulated by ubiquitination in mammalian cells. Dysfunction of ubiquitination-mediated degradation is considered a major mechanism to cause the accumulation of survivin in human cancer cells. So far, two E3 ligases, the F-box Protein Fbxl7 and the X-linked inhibitor of apoptosis (XIAP) have been identified to catalyze survivin ubiquitination31,32. In addition, overexpression of deubiquitinase, such as CSN5 and FAT1033,34, can specifically remove the K-48 linked ubiquitination chains, stabilize survivin, and inhibit apoptosis in humans cancer cells. Recent studies showed that targeting survivin induced cancer cell apoptosis and enhanced radio/chemotherapy-mediated tumor-killing efficacy. Silencing survivin using antibody-conjugated poly (Propylene Imine)-based polyplexes inhibits the growth of PSCA-positive tumors35. MiR-34a-mediated survivin inhibition improves the antitumor activity of selinexor in triple-negative breast cancer36. Translational suppression of survivin expression by natural product licochalcone A inhibits non-small cell lung cancer cells37. Moreover, reduced expression of BIRC5 by Salinomycin and xanthohumol enhances radiotherapy sensitivity of NPC and oral squamous cell carcinoma cells, respectively23,38. In the present study, we found that Butein promoted the interaction between survivin and Fbxl7, facilitating Fbxl7-mediated ubiquitination in NPC cells. We discovered that Butein suppressed survivin Thr34 phosphorylation by inhibiting Akt-Weel-CDK1 signaling, and overexpression of activated Akt1 rescued Butein-induced survivin destruction. YM15539,40 is a survivin suppressant that can specifically inhibit the transcription of survivin by disrupting the binding of Sp1 and the core promoter of survivin, exerting a robust anti-tumor activity in human cancer cells. Our results indicate that Butein is a novel survivin inhibitor that exhibits the anti-tumor effect by decreasing the stability of survivin protein.
Overall, this study suggests that a high protein level of survivin is required for maintaining the malignant phenotype of NPC cells. The natural compound Butein inhibits NPC cells by downregulation of survivin in an Akt-Weel-CDK1 signaling-dependent manner. We demonstrated that Butein inhibits survivin phosphorylation, which induced Fbxl7-induced survivin ubiquitination and degradation. Our study extends the anti-tumor mechanism of Butein and suggests that Butein is a promising therapeutic agent for NPC treatment.
Data availability
Materials are available upon request.
Change history
31 January 2023
A Correction to this paper has been published: https://doi.org/10.1038/s41598-023-28989-z
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Acknowledgements
We would like to thank Shiming Tan at the Third Xiangya Hospital for technical assistance.
Funding
This work was supported by the National Natural Science Foundation of China (81972837, 82003203), the Natural Science Foundation of Hunan Province (2021JJ31011, 2021JJ41058), the Scientific Research Program of Hunan Provincial Health Committee (20200763, 202208024824), the Climbing plan of Hunan Cancer Hospital (QH2021006), and the Basic Research Project of Changsha Science and Technology Bureau (kq2004127).
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Conception and design: L.X., W.-B.L., L.Z., X.D., W.L.; Development of methodology: L.X., W.-B.L., X.L., L.Z., X.D., W.L..; Acquisition of data: L.X., W.-B.L., X.L., L.Z., X.D., W.L.; Analysis and interpretation of data: L.X., W.-B.L., X.D., L.Z., W.L.; Writing, review, and/or revision of the manuscript: L.X., X.D., L.Z., W.L.; Administrative, technical, or material support: L.X., X.D., W.L.; Study supervision: X.D., L.Z., W.L.
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The original online version of this Article was revised: In the original version of this Article, Xin Dong was incorrectly affiliated with ‘Department of Head and Neck Surgery, Hunan Cancer Hospital/The Affiliated Cancer Hospital of Xiangya School of Medicine, Central South University, Changsha 410013, Hunan, China’. The correct affiliation is listed here. Department of Clinical Laboratory, National Cancer Center/National Clinical Research Center for Cancer/Cancer Hospital, Chinese Academy of Medical Sciences and Peking Union Medical College, Beijing 100021, China.
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Dong, X., Liu, W., Li, X. et al. Butein promotes ubiquitination-mediated survivin degradation inhibits tumor growth and overcomes chemoresistance. Sci Rep 12, 20644 (2022). https://doi.org/10.1038/s41598-022-21839-4
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DOI: https://doi.org/10.1038/s41598-022-21839-4
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