Abstract
Hepatocellular carcinoma (HCC), the most prevalent liver cancer, is considered one of the most lethal malignancies with a dismal outcome mainly due to frequent intrahepatic and distant metastasis. In the present study, we demonstrated that oroxylin A, a natural product extracted from Scutellaria radix, significantly inhibits transforming growth factor-beta1 (TGF-β1)-induced epithelial–mesenchymal transition (EMT) and metastasis in HCC. Oroxylin A blocked the TGF-β1/Smad signaling via upregulating the non-steroidal anti-inflammatory drug-activated gene-1 (NAG-1) expression. Oroxylin A promoted NAG-1 transcription by regulating the acetylation of CCAAT/enhancer binding protein β (C/EBPβ), a transcription factor that binds to the NAG-1 promoter. In terms of the underlying mechanism, oroxylin A may interact with histone deacetylase 1 (HDAC1) by forming hydrogen bonds with GLY149 residue and induce proteasome-mediated degradation of HDAC1 subsequently impairing HDAC1-mediated deacetylation of C/EBPβ and promoting the expression of NAG-1. Taken together, our findings revealed a previously unknown tumor-suppressive mechanism of oroxylin A. Oroxylin A should be further investigated as a potential clinical candidate for inhibiting HCC metastasis.
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Introduction
Hepatocellular carcinoma (HCC) is the most common type of liver cancer, mainly occurring in people with chronic liver diseases [1]. The poor prognosis often results from its high recurrence and metastasis after clinical treatments with unclear reasons [2]. As per one of the theories, inadequate surgical removal eventually leads to dissemination or micro-metastasis [3]. With the development of liver carcinogenesis, advanced stage HCCs present a vast molecular heterogeneity resulting from the neoplastic transformation in both epithelial cell-like hepatocytes and progenitor cells. This transformation is mediated by a well-known phenomenon, epithelial–mesenchymal transition (EMT) [4]. Given the complexity of EMT-involved metastasis in HCCs, therapeutics inhibiting HCC metastasis are urgently needed.
The transforming growth factor-beta (TGF-β) pathway mediates a broad spectrum of cellular processes and is implicated in cancer [5]. TGF-β was identified as a critical driver of EMT both during cell development and cancer. Following EMT, transcriptional reprogramming occurs, allowing the cells to acquire the capacity to detach and migrate from the primary tumor [6]. Interestingly, while TGF-β acts as an anti-tumorigenesis factor in the early stages of tumor development, it becomes a pro-tumorigenesis factor in the advanced stages of malignancies [6, 7]. The canonical TGF-β signaling pathway entailing TGF-β-induced activation of receptors usually involves the phosphorylation of Smad2/3. The phosphorylation of Smad2/3 form a complex with Smad4 and gets translocated to the nucleus to trigger or repress the transcription of a series of target genes (Snail family, Zeb family, and bHLH family), resulting in repression of epithelial marker gene expression and activation of mesenchymal gene expression [8]. NAG-1, one of the TGF-β family members, translocates to the nucleus and interferes with the TGF-β1-induced Smad signaling pathway [9]. NAG-1 is often identified as a poor prognostic signature in a series of cancers, and circulating NAG-1 correlates with high rates of metastasis and recurrence [10]. The use of the combination of alpha-feto protein (AFP) and NAG-1 increases the sensitivity of HCC diagnosis [11]. Several reports have highlighted the diverse roles of NAG-1 in cancers. In human hepatocellular carcinoma cell lines, overexpression of NAG-1 has pro-apoptotic and anti-tumorigenic properties [12, 13]. In Apcmin NAG-1 conditional knockout mice, NAG-1 mediates chemoprevention by sulindac in heritable colon cancer [14]. The intricacies of the roles of NAG-1 in cancer progression remain elusive and paradoxical. In this context, the underlying switching mechanism of TGF-β-mediated signaling acquires further investigation.
Oroxylin A (OA, 5,7-dihydroxy-6-methoxyflavone), a natural compound extracted from Scutellaria radix, possesses multiple anti-carcinoma properties–apoptosis induction, differentiation, and overcoming drug resistance in various cells [15, 16]. OA inhibits invasion and metastasis of breast cancer cells and non-small-cell-lung cancer cells [17, 18]. In the present study, we demonstrate that the antineoplastic function of OA in HCC is related to its ability to inhibit cell metastasis in vivo and in vitro, and centered on the ability to induce the expression of NAG-1.
Materials and methods
Reagents and antibodies
OA (purity >99%) and Biotin-OA (purity >99%) were kindly provided by Professor. Zhiyu Li (China Pharmaceutical University, Nanjing, China). OA (purity >99%) and Biotin-OA were dissolved in DMSO (Sigma Aldrich, St. Louis, USA) to prepare a 50 mM stock solution, which was stored at −20 °C. Human recombinant TGF-β1 was purchased from MedChemExpress (Shanghai, China) and dissolved in sterile water. Cycloheximide (CHX) and MG132 were purchased from MedChemExpress (Shanghai, China) and dissolved in DMSO. Antibodies for Smad2/3 (#8685), phospho-Smad2 (Ser465/467)/Smad3 (Ser423/425) (#8828), E-cadherin (#14472), phospho-C/EBPβ (Thr235) (#3084), HDAC1 (#5356), acetylated-lysine (#9441), Lamin A/C (#4777), α/β-Tubulin (#2148), and p300 (#86377) were purchased from Cell Signaling Technology (Beverly, MA, USA). Antibodies for NAG-1 (#sc377195), C/EBPβ (#sc7962), GAPDH (#sc32233), and β-Actin (#sc47778) were purchased from Santa Cruz Biotechnology (Santa cruz, CA, USA). Antibodies for Vimentin (#P08670), N-cadherin (#P199022) were purchased from Bioworld Technology (St.Louis Park, MN, USA). Antibody for Twist1 (#A15596) was purchased from Abclonal (Wuhan, China). Antibodies for c-Myc Epitope Tag (#MA1980) and Alexa FluorTM 488 phalloidin (#A12379) were purchased from Thermo Fisher Scientific (USA). Antibody for GFP-Tag (#M2004) was purchased from AbMART (Shanghai, China).
Plasmid construction and mutagenesis
The SBE4 luciferase reporter gene plasmids (SBE4-Luc), pLkO.1 hygro vectors, pMD2G, psPAX2, pRL-TK, and pLenti-GFP-puro were purchased from Addgene. pGL3-C/EBPβ was purchased from Promega. The TGF-β-inducible reporter construct (p3TP-Lux) was a gift from Joan Massague & Jeff Wrana. pLKO shNAG-1 plasmid was constructed according to the manufacturer’s instructions. We amplified HDAC1 (codons 88-1536) from a cDNA library prepared from HEK 293 T RNA. This fragment was ligated into the pGEX-6P-1 and pLenti-GFP-vectors. Site-directed mutagenesis was carried out using the Mut Express®II Fast Mutagenesis Kit V2 (Vazyme Biotec, Nanjing, China). All the constructs were confirmed by sequencing. Detail primer sequences are given in Supplementary Table 1.
RNA isolation and real-time polymerase chain reaction
Total RNA was isolated from the cells using RNAiso plus reagent (Takara Biomedical Technology, Dalian, China). 1 μg of RNA was reverse-transcribed using HiScript II Q RT SuperMix (Vazyme Biotech, Nanjing, China) according to the manufacturer’s instructions. Real-time PCR was carried out using ChamQ SYBR qPCR master mix (Vazyme Biotech, Nanjing, China). The primer sequences are given in Supplementary Table 2.
Chromatin immunoprecipitation assay
After treatment with OA or vehicle, Chromatin immunoprecipitation (CHIP) assay was carried out using EZ-Magna CHIPTM A/G chromatin immunoprecipitation kit (Merck & Millipore, Massachusetts, USA) according to the manufacturer’s instructions. The detailed primer sequences are given in Supplementary Table 2.
Statistical analysis
Data were presented as mean ± standard deviation (SD). Statistical analysis was performed as described in each figure legend, and sample sizes were shown in each corresponding figure legend. P < 0.05 was considered statistically significant.
Detailed descriptions of all methods are provided in Supplementary materials and methods.
Results
Oroxylin A inhibits TGF-β1-induced migration and invasion of HCC cells
Although the previous studies reported OA-mediated inhibition of migration in breast cancer and lung cancer cells [17, 18], we explored OA’s anti-metastatic effect in HCC cells. Since TGF-β1 is an inducer of EMT and is vital for tumor metastasis [8], we pretreated the cells with TGF-β1 for 12 h, followed by incubation with OA (50 μM) for a total of 48 h. OA remarkably suppressed TGF-β1-induced migration and invasion of HCC cells (Figs. 1a–1d, Supplementary Figs. 1a–1d). Moreover, OA did not induce significant cytotoxicity (Fig. 1e). After 48 h treatment, OA (50 μM) induced apoptosis in SMMC-7721 cells, but the apoptosis rate was lower than 10% (Fig. 1f, g). These observations demonstrate that OA significantly inhibits TGF-β1 induced migration and invasion of HCC cells.
Oroxylin A represses TGF-β1-induced EMT in HCC cells
EMT as a pivotal step that confers carcinoma cells with invasive and metastatic properties [19]. TGF-β1 is widely used as an EMT inducer that induces loss of cell polarity, decreases cell adhesion, and increases migration. Here, we investigated the role of OA in TGF-β1-induced EMT in HCC cells, TGF-β1 induced an elongated, fibroblast-like phenotype in HCC cells, which was attenuated by OA treatment (Fig. 2a). Moreover, the distribution of filamentous actin (F-actin) was visualized by phalloidin staining, the data revealed that cytoskeletal rearrangement in the TGF-β1-treated HCC cells was significantly blocked by OA treatment (Fig. 2b and Supplementary Fig. 2a). We also analyzed the expression patterns of EMT-related proteins and found that E-cadherin levels deceased after TGF-β1 treatment, while those of N-cadherin, Vimentin, and Twist1 increased. OA treatment repressed TGF-β1-induced changes in expression patterns of various EMT markers (Fig. 2c, Supplementary Fig. 2b, c). Also, MMP2, and MMP9 are responsible for tumor invasion and metastasis. As per the qPCR results, TGF-β1 decreased the mRNA levels of E-cadherin and increased the mRNA levels of TWIST1, MMP2 and MMP9. These manifestations were reversed by OA treatment (Fig. 2d). These findings suggest that OA suppresses TGF-β1 induced EMT in HCC cells.
Oroxylin A inhibits the TGF-β1/Smad pathway without affecting Smad2/3 phosphorylation
Since OA was found to suppress TGF-β1-induced EMT in HCC cells, we investigated the role of OA in TGF-β1/Smad mediated transcriptional responses. The expression levels of PAI-1, a target gene of the TGF-β1 signaling pathway, were effectively reduced in OA-treated HCC cell lines (Fig. 3a) [20]. Furthermore, we used p3TP-Lux containing three consecutive TGF-β response elements, and SBE4-Luc containing four copies of the Smad binding sites, to examine the effect of OA on the TGF-β signaling pathway [21]. OA treatment significantly inhibited TGF-β signaling activity (Fig. 3b, c). TGF-β triggers EMT accompanied by Smad2/3 phosphorylation and Smad complex nuclear translocation [22]. We found that OA failed to impact TGF-β1 induced Smad2/3 phosphorylation and Smad complex nuclear translocation (Fig. 3d–f). Taken together, OA inhibits the TGF-β1/Smad pathway without affecting Smad2/3 phosphorylation and Smad complex nuclear translocation.
Oroxylin A inhibits the TGF-β1/Smad pathway through upregulating NAG-1 expression
NAG-1, a TGF-β superfamily protein, translocates to the nucleus and contributes to the inhibition of the Smad pathway by interrupting the Smad complex.[9] We found that OA treatment significantly induces NAG-1 expression in the cytoplasm and nucleus of HCC cells (Fig. 4a, b and Supplementary Fig. 3a). To further explore the role of NAG-1 in OA-mediated inhibition of the TGF-β1/Smad pathway, we established a stable NAG-1 knockdown SMMC-7721 cell line. Knock-down of NAG-1 (shNAG-1) abolished OA mediated inhibition of TGF-β1/Smad pathway, as evidenced by the change in expression of E-cadherin and Twist1 after TGF-β1 treatment (Fig. 4c). We analyzed the transcription factor activity of the Smad complex using SBE4-Luc. We found that NAG-1 knock-down abolished OA mediated inhibition of Smad transcription factor activity and the mRNA levels of MMP2 and MMP9, induced by TGF-β1 treatment (Fig. 4d, e). Meanwhile, OA has a limited inhibitory effect on TGF-β1 induced cell invasion in stable NAG-1 knock-down SMMC-7721 cells (Fig. 4f). Further, we overexpressed NAG-1 in SMMC-7721 cells (Supplementary Fig. 3b). The mRNA levels of MMP9 in cells overexpressing NAG-1 were downregulated, and the mRNA levels of E-cadherin were upregulated (Supplementary Fig. 3c). Furthermore, ectopic expression of NAG-1 weakened cell motility and decreased the response of cells to TGF-β1 (Supplementary Fig. 3d). But, OA showed modest anti-metastasis efficacy in the NAG-1 overexpression group after TGF-β1 treatment. The underlying reason may be that the ectopic exorbitant expression of NAG-1 attenuated the anti-metastasis capacity of OA at the treatment dose. These results suggested that the induction of NAG-1 expression mediates OA-induced inhibition of metastasis in HCC.
Oroxylin A activates NAG-1 transcription through the C/EBPβ binding motif
To further explore the underlying mechanism of OA-mediated NAG-1 upregulation, we evaluated the mRNA levels of NAG-1 in SMMC-7721 cells after OA treatment. OA upregulated NAG-1 mRNA expression in a time- and dose-dependent manner (Fig. 5a, b). We further investigated the role of OA in the transcriptional regulation of NAG-1 using a shorter upstream region (−133 to +41 relative to TSS) and a longer region (−1086 to +41 relative to TSS) ahead of the reporter gene. Similar results were obtained from the shorter and longer promoters of NAG-1. We found that the potential transcription factor binding motif involved in this process was located most proximally to the TSS (−133 to +41) (Fig. 5c). Several potential motifs, including C/EBPβ, Sp1, XF1, and RARα, are located in the region (−133 to +41). Some of these motifs play essential roles in NAG-1 transcription (Supplementary Fig. 4a). Moreover, OA promotes NAG-1 transcription in wild-type (WT) promoter or promoters with mutations in Sp1, XF1, and RARα binding sites, except for promoters with C/EBPβ binding site mutation in SMMC-7721 cells, suggesting that C/EBPβ motif may be involved in OA mediated NAG-1 transcription (Fig. 5d). Finally, OA promoted the activity of the C/EBPβ transcription factor (Fig. 5e). Together, these data suggest that OA may activate NAG-1 transcription by regulating the C/EBPβ transcription factor activity.
Oroxylin A promotes acetylation of C/EBPβ
Since C/EBPβ plays an essential role in OA-mediated NAG-1 transcription, we investigated the role of OA in regulating the C/EBPβ expression and phosphorylation. Firstly, OA was not found to affect C/EBPβ expression and phosphorylation (Fig. 6a). Secondly, OA did not affect the nuclear translocation of C/EBPβ (Fig. 6b). However, the CHIP assay showed that OA treatment increased the binding of C/EBPβ to NAG-1 promoter, indicating that OA treatment might affect the posttranslational modification of C/EBPβ besides phosphorylation, which is vital for the DNA binding affinity of C/EBPβ (Fig. 6c). The acetylation of C/EBPβ facilitates its binding to the DNA, thereby stimulating C/EBPβ-dependent transcription [23]. Here, we showed that treatment with OA significantly improves the acetylation level of C/EBPβ (Fig. 6d).
The dynamic regulation of the acetylation state of C/EBPβ relies on acetyltransferase and deacetylase. Nuclear coactivator p300 with intrinsic acetyltransferase activity modify multiple lysine sites of C/EBPβ, these modifications are essential for the function of C/EBPβ transcriptional factor [24]. However, treatment of SMMC-7721 cells with OA does not affect exogenous and endogenous levels of p300 protein (Fig. 6e). In SMMC-7721 cells, OA significantly decreased the levels of HDAC1 protein, a modulator of C/EBPβ acetylation (Fig. 6f). These observations suggest that OA can facilitate C/EBPβ acetylation by inhibiting the HDAC1 expression. Next, we found no significant changes in the HDAC1 mRNA levels after OA treatment, suggesting that OA regulated HDAC1 expression at posttranslational level (Fig. 6g). To directly investigate whether OA affects HDAC1 protein stability, we blocked the de novo synthesis of HDAC1 protein using cycloheximide (CHX) and examined HDAC1 degradation. OA reduced the HDAC1 protein stability by decreasing the half-life of HDAC1 (Fig. 6h). Moreover, OA-induced reduction of HDAC1 was attenuated after treatment with a proteasome inhibitor, MG132 (Fig. 6i). Overall, these findings suggest that OA facilitates proteasome-mediated degradation of HDAC1 and promotes C/EBPβ acetylation.
Gly149 is essential for the binding of HDAC1 with oroxylin A
To further explore the mechanism underlying the attenuation of HDAC1 protein expression by OA, we investigated the binding between OA and the crystal structure of HDAC1 [PDB ID:5ICN] using molecular docking techniques. We found several critical directional interactions between the OA scaffold and the HDAC1, a hydrogen bond between the oxygen atom of the carbonyl group and Gly149, a second hydrogen bond between 5-hydroxyl and Asn95. The 2-aryl ring of OA is sandwiched between the hydrophobic residues (mainly Phe150 and Phe205) in a lipophilic region. The Pi-anion interaction between the OA scaffold and the carboxyl of Asp99 further anchors the ligand (OA) in the pocket (Fig. 7a). The proximity of Asp99, Gly149, Phe205, and Phe150 to the HDAC1 active site increases the activity of HDAC1 [25]. To analyze the critical amino acids of HDAC1 involved in interactions with OA, we induced an alanine mutation and extracted the GST-fusion protein (Fig. 7b). We also conducted pull-down assays with biotin-OA and observed that Gly149 was required to bind with OA (Fig. 7c). Further, we performed MST assay to evaluate the dissociation kinetics of OA. OA showed a 4-fold lower binding affinity to HDAC1-G149A (Kd = 208.56 μM) than wild-type HDAC1 (Kd = 48.9 μM) (Fig. 7d). We compared the stability of wild-type HDAC1 and HDAC1-G149A mutant proteins following OA treatment. Treatment of transfected SMMC-7721 cells with OA reduced the GFP-HDAC1-WT protein levels in a dose-dependent manner; treatment with 100 μM OA reduced the GFP-HDAC1-G149A mutant protein levels (Fig. 7e). Further, SMMC-7721 cells transfected with HDAC1-WT/HDAC1-G149A in the presence of CHX (100 μg/mL) to block the newly protein synthesis and examine the degradation of HDAC1-WT/HDAC1-G149A protein levels after OA treatment. HDAC1-WT protein degraded more rapidly than HDAC1-G149A after OA treatment, suggesting that Gly149 mutation weakened the interactions between HDAC1 and OA; Gly149 played a role in OA-mediated HDAC1 degradation (Fig. 7f).
Oroxylin A reduces pulmonary metastasis of SMMC-7721 cells in vivo
We established a lung metastasis model using 5-week-old female BALB/c nude mice to investigate the anti-metastasis ability of OA and NAG-1’s role in vivo. OA treatment reduced lung mass colonization in the control group, whereas OA does not affect shNAG-1 cell implanted mice (Fig. 8a–c). Administration of OA rescued the loss of body weight in the control group but failed to do so in shNAG-1 group, suggesting that knock-down of NAG-1 aggravates the progression of HCC metastasis (Fig. 8d). Survival curves demonstrated that mice bearing shNAG-1 cells and the control cells began to die on the 51st and 64th day, respectively. While mice in control group received OA administration began to die on the 77th day, they had a prolonged survival time compared to the other groups (Fig. 8e). Bodyweight analysis and survival curves validated that OA treatment efficiently reduces HCC metastasis in the control group mice but failed in mice with implanted shNAG-1 cells. The expression levels of E-cadherin, Vimentin, and Twist1 in lung tissues were evaluated using immunohistochemistry. In the control group, treatment with OA promoted E-cadherin expression and reduced the expression of Vimentin and Twist1. As compared with the control group, the shNAG-1 group had a lower expression of E-cadherin and significantly higher expression of Vimentin and Twist1. Also, the administration of OA did not affect the expression levels of EMT-related proteins in the shNAG-1 group (Fig. 8f). These results suggested that knocking down NAG-1 enhances the mobility of HCC cells and that NAG-1 plays an indispensable role in OA’s inhibition of HCC metastasis. Using H&E staining, we observed no significant pathological changes of the liver among the mice of different groups (Fig. 8g).
The in vitro results showed that OA regulates the expression of NAG-1 by directly interacting with HDAC1. To validate these results in vivo, we constructed HDAC1 overexpression plasmids and stably transfected SMMC-7721 cells by lentivirus. The efficiency of HDAC1 overexpression in SMMC-7721 cells was then evaluated using Western blot (Supplementary Fig. 5a). We observed increased lung mass colonization in mice bearing pLenti-HDAC1 cells compared with pLenti-Con group mice, while treatment with OA had a limited effect on the pLenti-HDAC1 group mice (Supplementary Fig. 5b, c). So, the overexpression of HDAC1 promoted the metastasis of SMMC-7721 cells and blocked OA-induced anti-metastasis in vivo. These observations suggest that a reduction in HDAC1 expression mediates the anti-metastasis effect of OA.
Discussion
HCC is one of the most lethal tumors in the world. At advanced stages, HCC carries a high risk of metastasis and results in shorter overall survival. OA, a flavonoid derivative with potent bioactivity, has exhibited significant potency in pre-clinical studies [15]. In this study, we report that OA inhibits HCC metastasis in vitro and in vivo and that the expression of NAG-1 plays a crucial role in the process. Further, OA elevated the acetylation level of C/EBPβ by interacting with HDAC1, thereby promoting the expression of NAG-1 (Fig. 7g).
EMT is a developmental phenomenon that enables the carcinoma cells to acquire attributes of invasion and metastasis [26,27,28,29]. TGF-β1 acts as a promoter at advanced stages of tumor progression, paving the way for the initiation of EMT. Sources of TGF-β1 in tumors vary and include the cancer cells themselves as well as tumor stroma [8]. In our study, OA inhibited the metastasis of HCC cells in the presence or absence of exogenous TGF-β1. Although exogenous TGF-β1 was absent, we hypothesized that a certain amount of TGF-β1 derived from the serum of culture medium and autocrine of HCC cells must have been present in our culture system. Phosphorylation of Smad is known to propagate TGF-β signal in cells. We found that OA treatment did not affect TGF-β1-induced phosphorylation of Smad2/3 and its nuclear translocation, but the binding of Smad complex to DNA was reduced. NAG-1 inhibits TGF-β1 signaling by interrupting the DNA binding activity of the Smad complex [9]. We observed that OA induced NAG-1 expression in the cytoplasm and nucleus in a dose-dependent manner. The downregulation of NAG-1 increased the DNA binding activity of the Smad complex. Therefore, we hypothesize that NAG-1 will act as a key point in HCC therapy. In this study, NAG-1 induction was found to be implicated in anti-HCC metastasis. Downregulation of NAG-1 promoted the metastatic ability and EMT of HCC cells. At the same time, overexpression of NAG-1 showed the opposite results. We further demonstrate that silencing of NAG-1 abolishes OA-induced repression of metastasis in vivo, suggesting that NAG-1 plays an indispensable role in HCC development.
Multiple mechanisms regulate the basal transcription of NAG-1. Various transcription factors involved in the regulation, such as p53, C/EBPβ, EGR1, and Sp1, have been identified [30]. This study found that C/EBPβ was critical to OA-enhanced transcription of NAG-1 in HCC cell lines. These observations suggest that NAG-1 might be a target gene of C/EBPβ. C/EBPβ play a crucial role in controlling the cell cycle, and promoting metastasis in multiple carcinomas [23]. For instance, C/EBPβ is vital for liver physiology, liver disease, and liver development [31]. Hui et al. found that OA increases the protein expression of C/EBPβ in leukemia cells [32]. However, in HCC cells, we found that OA did not affect expression, phosphorylation, and nuclear translocation of C/EBPβ but increases its transcriptional activity. Further, OA promoted the binding of C/EBPβ to NAG-1’s promoter. Based on these observations, we concluded that OA regulates C/EBPβ at the posttranslational level in HCC cells.
Protein acetylation contributes to some critical protein interaction with DNA and/or other proteins [33]. A disrupted equilibrium with the dominance of the deacetylases leads to the transcriptional repression of genes [34, 35]. Silencing of promoters of various tumor suppressor genes such as p53, C/EBPα, and GSK3β increases the C/EBPβ-HDAC1 complex levels and contributes to the development of HCC [36]. Here, we showed that OA-induced downregulation of HDAC1 in HCC cells increases the acetylation level of C/EBPβ, promoting its transcription activity.
Previous studies show that histone modification plays a critical role in NAG-1 expression in glioblastoma cell lines. Trichostatin A (TSA), a histone deacetylase inhibitor, increases NAG-1 promoter activity and mRNA stability [37]. In our study, OA downregulated the HDAC1 expression. Using molecular docking approaches, we identified several potential active sites for studying the binding between OA and HDAC1. OA demonstrated a moderate affinity with HDAC1 as compared with commercial HDAC inhibitors. Classical HDAC inhibitors such as TSA and suberoylanilide hydroxamic acid (SAHA) inhibit the HDAC activity by interacting with the catalytic sites of HDACs, thereby blocking the substrate access [38, 39]. OA is a natural compound isolated from natural flavonoids with a broad spectrum of pharmacological functions and low toxicity. We found that the proteasome degradation pathway is involved in the OA-reduced downregulation of HDAC1. Using MST and biotin-pulldown assays, we found that Gly149 residue of HDAC1 is essential for its binding with OA. Compared with HDAC1-WT protein, HDAC1-G149A protein is more resistant to degradation by OA because of its weaker interactions with OA. Taken together, we conclude that the Gly149 site is critical for the stability of HDAC1 during its interaction with OA.
Conclusion
In conclusion, OA exhibited a notable anti-metastasis effect in HCC cells in vitro and in vivo. This anti-metastasis effect is due to an OA-induced increase in NAG-1 expression levels. Our study revealed a previously unknown mechanism underlying the tumor-suppressive effect of OA and provided a foundation for further investigation of potential therapeutic strategies to target NAG-1 in HCC.
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Acknowledgements
We are grateful to Dr. Seung Joon Baek, (University of Tennessee, Knoxville, TN, USA) for kindly providing the plasmids pGL3 NAG-1-1086/+41, pGL3 NAG-1-133/+41 and the mutation plasmids pGL3 m C/EBPβ, pGL3 mRARα, pGL3 mXF1, pGL3 mSp1. And Dr. Zhao-qiu Wu (China Pharmaceutical university, Nanjing, China) for kindly providing pGEX-6P-1 plasmids. And Dr. Chang-ying Guo (China Pharmaceutical university, Nanjing, China) for kindly providing pLuciferase-IRES-mCherry plasmids. This work was supported by the General Program of National Natural Science Foundation of China (81772911, 81973522, 81974425, and 81903648); the Postgraduate Research & Practice Innovation Program of Jiangsu Province (KYCX20-0654); the Natural Science Foundation of Jiangsu Province (BK20170744); the Six Talent Peaks Project in Jiangsu Province (SWYY-095).
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LQ and XBZ supervised the project, designed experiment and wrote the manuscript. TXH, XPW, and YH performed experiments and analyzed data. ZY performed in vivo study, BK performed molecular docking study. QLG provided technical assistance of pharmacology. All authors read and approved the final manuscript.
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Huo, Tx., Wang, Xp., Yu, Z. et al. Oroxylin A inhibits the migration of hepatocellular carcinoma cells by inducing NAG-1 expression. Acta Pharmacol Sin 43, 724–734 (2022). https://doi.org/10.1038/s41401-021-00695-4
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DOI: https://doi.org/10.1038/s41401-021-00695-4
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