key: cord-0026562-x6shdibb authors: Li, Ching-Li; Wang, Chien-Che; Pai, Hsin-Te; Tu, Stan-Ley; Hou, Pin-Yuan; Huang, Chien-Yu; Huang, Ming-Te; Chang, Yu-Jia title: The Natural Compound Dehydrocrenatidine Attenuates Nicotine-Induced Stemness and Epithelial-Mesenchymal Transition in Hepatocellular Carcinoma by Regulating a7nAChR-Jak2 Signaling Pathways date: 2022-01-24 journal: Dis Markers DOI: 10.1155/2022/8316335 sha: a442711e04915117943367d80f018442872b82ff doc_id: 26562 cord_uid: x6shdibb BACKGROUND: Exposure to nicotine has been observed associated with tumor progression, metastasis, and therapy resistance of many cancers. Hepatocellular carcinoma (HCC) is one major cancer related to the liver and the most difficult to treat malignancies worldwide. The underlying mechanism of nicotine in the stimulation of HCC tumorigenesis is still not studied well. METHODS: Classically, nicotine binds to nicotinic acetylcholine receptors (nAChRs) and induces many downstream cancer-associated signaling pathways. Big data analysis is used to explore the importance of a7nAChR-Jak2 axis in the progression of hepatocellular carcinoma. Bioinformatic analysis was performed to determine gene associated with a7nAChR-Jak2 axis of HCC patients. Biological importance of a7nAChR-Jak2 axis was investigated in vitro (Hun7 and HepG2 cell lines), and athymic nude mouse models bearing HepG2-HCC cells xenografts were established in vivo. RESULT: We found that nicotine exposure stimulated the HCC tumorigenicity by inducing the expression of one of the key nAChRs subunit that is α7nAChR as well as the expression of Janus kinase (JAK)-2. In both the in vitro and in vivo studies, the reduced overexpression of α7nAChR and increased sensitization of HCC towards treatment is observed with dehydrocrenatidine (DHCT), a novel and potent JAK family kinase inhibitor. Interestingly, DHCT treatment results in the reduction of the epithelial-mesenchymal transition process which leads to a significant reduction of clonogenicity, migratory, and invasive ability of HCC cells. Moreover, DHCT treatment also inhibits the cancer stem cell phenotype by inhibiting the tumor-sphere formation and reducing the number of ALDH1+ cells population in nicotine-stimulated HCC cells. CONCLUSIONS: Taken together, the presented results indicate the positive effect of inhibition of nicotine induced overexpression of α7nAChR and JAK2, unique to HCC. Thus, these findings suggest the nicotine effect on HCC progression via α7nAChR-mediated JAK2 signaling pathways, and DHCT treatment enhances the therapeutic potential of HCC patients via overcoming/reversing the effect of nicotine in HCC patients. Currently, over a billion people in the world, including approximately 19% of adults, actively smoke tobacco [1] . Smoking releases more than 4000 harmful chemicals, which adversely affects almost all organs [2] , including the liver [2] . Smoking is a well-known risk factor for many diseases, including cancers [3] . However, how cigarette smoking contributes to the development of liver cancer remains underinvestigated. Nicotine, which is a major addictive chemical component of cigarette smoking, poses much serious health; this compound influences numerous biological function such as modulation of gene expression, DNA damage, oxidative stress, proliferation, apoptosis, angiogenesis, and regulation of secretion of hormones [4] . This compound exerts its effects via stimulation of the nicotinic acetylcholine receptors (nAChRs) that are ligand-activated ion channels [5] . Among various subtypes of nAChR receptors, alpha7subtype of nAChR (α7nAChR) has been seen to exert special significance on the cellular process [6, 7] . α7nAChR is expressed and it is involved in regulation of a variety of human cancer and normal cells and tissues, such as liver cancer [6, 7] . It modulates many cancer-associated properties in most cancers and interestingly plays a vital role in the regulation of inflammatory markers expression, which regulates various other pathological conditions [8] [9] [10] [11] . Such a broad role of α7nAChR and the effect of nicotine have a significant impact in defining the long-term faith of different cancers. It is noticed that the number of different nicotine-related malignancies is on the rise [12] . Among, them, hepatocellular carcinoma (HCC) is one of the most common, and often diagnosed malignancies, which ranks number the second leading reason of cancer-related mortality worldwide with approximately 800,000 new cases reported every year [13] . Despite advancements in early detection and diagnostic techniques and treatment modalities, the prognosis of HCC patients remained poor even after the curative liver resection [14] . Several epidemiologic studies have reported that smoking tobacco is connected with HCC development [15] . However, the biological effect of tobacco and the underlying molecular mechanism in HCC remain elusive. In the previous study by our group, we demonstrated by applying the HCC patient's clinical samples that smoking is an independent risk factor for HCC progression through the α7nAChR and JAK2 signalling [16] . In the cholinergic system, α7nAChRs facilitates many different pathways, it is extensively studied in association with the antiinflammatory pathways [17] . In monocytes and macrophages, α7nAChR triggers and attracts the cytosolic JAK2 protein, leading to the initiation of the formation of a heterodimer complex that triggers STAT3 signal transduction [18] . The JAK2/STAT3 signaling pathways also play a critical role in the growth, proliferation, and metastasis of cancers [19] . The JAK2-modulated STAT3 transcription factors are involved in many processes, such as immune response, inflammation, and cancer progression, by activating proinflammatory cytokines, growth factors, and onco-genes [20, 21] . Apart from α7nAChR negative regulatory role in the inflammatory response, the role of α7nAChR together with JAK2, in connection with exposure to nicotine in HCC, remains unclear. This prompted us to identify new potential drugs to overcome the effects of nicotine on HCC. For example, the natural compound dehydrocrenatidine (DHCT), a novel and potent JAK family kinase inhibitor that modulates JAK/STAT3 expression [22] in HCC, can sensitize HCC cells against nicotine. In the current study, we investigated the functional significance of nicotine and α7nAChR in HCC progression and therapy resistance, the molecular mechanisms underlying its oncogenic role in HCC, and the potential of DHCT treatment to reverse the effects of nicotine in HCC. Gene expression profiles, GSE14323, were downloaded from the Gene Expression Omnibus database (http://www.ncbi. nlm.nih.gov/geo/), and expression of α7nAChR and JAK2 was analyzed using the Oncomine platform (https://www. oncomine.org/resource/) [23] . 2.4. Cell Viability Test. The DHCT stock was prepared by dissolving 20 mg/mL of the mixture in DMSO. The stocks of each drug were stored at −20°C until use. The effects of DHCT on cell proliferation were detected using the Cell Counting Kit-8 (CCK-8) assay (Dojindo Laboratories, Kumamoto, Japan), according to manufacturer's instructions. 2.5. Cell Cycle Analysis. The distribution of cell cycles was determined by staining cells with the propidium iodide (PI), after treatment, according to manufacturer's instructions. To determine the effect on the cell cycle, HCC cells were exposed to DHCT for 48 h. Next, the cells were washed, fixed with 70% ethanol, washed again, resuspended, and stained with 10 μg/mL of PI in PBS for 30 min at room temperature in the dark. The cells were analyzed through by flow cytometry (Becton Dickinson, Mountain View, CA, USA), and the population of cells in each phase was counted. 2.6. Aldehyde Dehydrogenase Assay. Aldehyde dehydrogenase (ALDH) activity in HCC cells was assayed using the . Separated proteins were transferred onto a polyvinylidene fluoride (PVDF) membrane by using the Trans-Blot Turbo Transfer System (Bio-Rad), which was followed by blocking with Tris-buffered saline plus skimmed milk. These PVDF membranes were then probed with the respective primary antibodies followed by the secondary antibody. An enhanced chemiluminescence detection kit was used to detect the proteins of interest. Images were captured and analyzed using the UVP BioDoc-It system (Upland, CA, USA). Quantitative reverse-transcription (RT) polymerase chain reaction (PCR) was performed by isolating total RNA using TRIzol-based protocol (Life Technologies) provided by the manufacturer. In brief, 1 μg of total RNA was reverse transcribed using a QIA-GEN OneStep RT-PCR kit (QIAGEN, Taiwan), and PCR was performed using a Rotor-Gene SYBR Green PCR kit (400; QIAGEN, Taiwan). The Commercial antibodies and primers used in this study are shown in Supplementary Table S1 and Supplementary Table S2 , respectively. 2.8. Colony Formation Assay. As per the protocol for colony formation assay described previously [24] , 400 liver cancer cells were seeded in six-well plates and treated with DHCT. The cells were allowed to grow for another week and then harvested, fixed, and counted. The image was captured and quantified using ImageJ software (https://imagej.nih.gov/ij/ download.html). 2.11. Sphere Formation Assay. Cells (5 × 10 3 /well) were plated in ultralow-attachment six-well plates (corning) containing stem cell medium consisting of serum-free RPMI 1640 medium supplemented with 10 ng/mL of human basic fibroblast growth factor (bFGF; Invitrogen, Grand Island, NY, USA), 1× B27 supplement, and 20 ng/mL epidermal growth factor (Invitrogen). The medium was changed every 72 h. After 14 days of incubation, the formed spheres were counted and photographed. 2.12. Animal Studies. This study was approved by the Institutional Animal Care and Use Committee (IACUC) of Taipei Medical University. All procedures were performed according to guidelines of IACUC, and all efforts were made to minimize animal suffering and the number of animals used. Twenty-seven male athymic nude mice at 4 weeks of age were used for this study. The mice were divided into three groups (N = 6 per group) and repeat experiments 3 times. The mice were maintained under pathogen-free conditions and were provided with sterilized food and water. The antiproliferative effect of DHCT on HepG2-HCC cells in vivo was investigated by using HepG2 cell xenograft mouse model of human HCC carcinoma. First, 1 × 10 6 HepG 2 cells along with proper controls were subcutaneously injected into the right flank near the hind leg of each nude mouse. When the tumor was palpable (tumor volume of approximately 100 mm 3 ), they were randomly divided into control (100 μL of normal saline [NS] by intraperitoneal injection plus 100 μL of 1% DMSO), nicotine was administered, and the role of DHCT treatment in overcoming the effect of nicotine (200 mg/kg/day by intraperitoneal injection plus 100 μL of 1% DMSO and 0.5% CMC-Na sterile water). The treatments were performed 5 times/week for 4 weeks. Tumor volume was measured using a standard vernier calliper, the tumor volume was calculated using the established formula. Tumor volume = 1/2 ðlength × width2Þ in mm 3 [25] . Upon the completion of the experiments, all the mice were euthanized by CO 2 asphyxiation followed by cervical dislocation, and the tumors were then immediately removed, weighted ex vivo and photographed for further analysis. 2.13. Immunohistochemistry (IHC) Staining. The tumor tissue was fixed in 10% neutral-buffered formalin, embedded in paraffin wax, and cut into sections of 3 μm thickness. α7nAChR in both the Huh7 and HepG2 cells. Real-Time Quantitative Reverse Transcription (qRT)-PCR analysis of the mRNA expression level showed the level of Ki67, Cyclin D1, JAK2, and α7nAChR in Huh7 and HepG2 cells was significantly higher in the nicotine-treated cells compared to the control-treated group (Figure 1(d) ; * p < 0:01). Furthermore, bioinformatics analysis of publicly available dataset (GSE14323) by using Oncomine an online tool (https:// www.oncomine.org/resource/) [23] also demonstrated (Figures 1(e) and 1(f)) the expression of JAK2 and α7nAChR, considerably higher in the HCC patients samples compared to the normal counterpart, whereas the expression of α7nAChR correlates positively with the expression of JAK2 expression in HCC patients' samples ( Figure 1(g) ), and the poor overall survival of HCC patients was observed in patients exhibiting higher expression of α7nAChR (Figure 1(h) ). All of these in vitro and in silico results indicated the nicotine treatment induces the HCC tumorigenesis by inducing the expression of α7nAChR-JAK2. 3.2. Nicotine Enhances Migratory, Invasive, Self-Renewal, and EMT Processes of HCC Cells. Furthermore, we evaluated the effect to evaluate the effect of nicotine treatment on HCC cell migratory, invasive, self-renewal, metastasis, and other malignant biological behaviour. The result indicates nicotine (0.5 μM)-treated cells after 24 h stimulated the Huh7 and HepG2 cells to migrate more quickly and close the scratch wounds (Figure 2(a) ). Furthermore, we conducted a Transwell invasion assay to evaluate the effect of nicotine on the invasive properties of HCC cells. The results demonstrated that both the HCC, Huh7, and HepG2 cells significantly enhanced the ability to invade through the Matrigel matrix, and the number of cells that invaded through the Matrigel matrix was significantly higher after the nicotine treatment, compared to the control (Figure 2(b) ). Studies have shown that cancer stem cells (CSCs) are characterized by unlimited proliferative properties and showing uncontrolled cellular growth [23] . Here, we performed the colony-formation and tumor-sphere abilities of nicotine-treated HCC cell (Huh7 and HepG2) results and demonstrated that nicotine treatment significantly induced the colony and tumor-sphere generating abilities of treated HCC cells compared to the control group (Figures 2(c) and 2(d) ). The epithelial to mesenchymal transition (EMT) process indicates the tumor invasiveness and angiogenesis of cancer cells. Hence, we investigated the expression of markers associated with the EMT process together with the expression status of p-JAK2 and cancer stem cell markers' (CSCs) markers. Western blot image depicted in Figure 2 (e) results demonstrated that the expression level of epithelial-marker vimentin (Vim) and CSC's marker (CD133) was induced together with the expression of p-JAK2 after the nicotine exposure of both the HCC (Huh7 and HepG2) cells. Expression of α7nAChR-JAK2. To examine the potential role of DHCT as a potential drug that targets α7nAChR-JAK2 may reverse the effect of nicotine from tobacco smoke in HCC (Huh7 and HepG2) cells. DHCT, a novel and potent JAK family kinase inhibitor, inhibits JAK/STAT3 expression [26] (Chemical structure of DHCT, Figure 3(a) ). Furthermore, we treated Huh7 and HepG2 cells with the serial dose of DHCT. As shown in Figure 3 (Figure 4 (a)) and invasion (Figure 4(b) ) capacity of cells, showing that JAK/STAT3 inhibitor effectively reduced the motility and invasiveness of nicotine stimulated HCC cells when compared with the nontreated control counterpart. EMT plays a key role in the invasion and metastasis of HCC cells [27] . Furthermore, the effect of DHCT on EMT properties and expression of EMT markers, E-cadherin and vimentin, were determined through Western blotting (Figure 4(c) ). The results indicated the increased expression of E-cadherin and reduced expression of vimentin. These results advocated the DHCT effects in preventing and neutralizing the effect of nicotine on the migratory and invasive potential of HCC cells. Tumorigenicity and Self-Renewal Abilities of HCC Cells. To further examine the effect of DHCT in modulating the effect of nicotine on tumorigenic properties of HCC cells, we assayed the colony and tumor sphere formation of the human HCC cell lines Huh7 and HepG2. Colony and tumor sphere formation assays are important for the identification of stemness [28, 29] . DHCT treatment suppressed tumor sphere and colony formation of HCC cells (Figures 5(a) 6 Disease Markers 7 Disease Markers and 5(b)). Interestingly, tumor sphere and self-renewal markers, such as CD133 and SOX2, were significantly reduced at the protein level ( Figure 5 (c)) after treatment with DHCT compared to nicotine only treated group cells. FACS analysis also demonstrated the reduction in the generation of ALDH1+ cells in DHCT treated cells compared to the nicotine only treated group ( Figure 5(d) ). These results indicate DHCT potential in inhibiting the self-renewal phenotype of nicotine-stimulated HCC cells. 3.6. In Vivo Suppressive Effect of DHCT on Nicotine-Induced HepG2 Tumorigenesis. After establishing the DHCTs' anti-HCC role on in vivo nude mice model. In vivo study, we evaluated the DHCT effects using a xenograft mice HepG2 tumor model. After the tumors were palpable in mice, the mice were randomly divided into three groups, control (n = 5; saline treatment only), nicotine (n = 5; nicotinetreated), and DHCT+nicotine (n = 5; DHCT+nicotinetreated) groups. The tumor volume was monitored once per week for another 5 weeks. As depicted in Figure 6 (a), the nicotine-treated group mice are showing enhanced tumor growth as compared with that of the saline only control and DHCT+nicotine treatment group, suggesting the combination treatment of DHCT+nicotine leads to a significant reduction in tumor volume ( * * p < 0:01). Moreover, the overall survival time was higher in mice treated with the DHCT+nicotine combination compared with that in mice treated with nicotine and nontreated control groups (Figure 6(b) ). Moreover, comparative real-time PCR analyses showed (Figure 6(c) ) a reduced level of tumor aggressiveness Ki-67 expression markers, induced apoptotic Caspase-3 and TUNEL-positive marker in the DHCT+nicotine combination group in comparison with saline and nicotine treatment. Furthermore, IHC analysis results of tissue sections in mice were consistent with the results of qRT-PCR. IHC result demonstrated that combination treatment of DHCT +nicotine suppresses the Ki-67 marker, i.e., tumor proliferation, oncogenicity, and tumorigenesis, and induced apoptosis was observed as compared with saline and nicotine treatment (Figure 6(d) ) animal group. Nicotine, a major by-product of cigarette smoking, may be responsible for the initiation, progression, and therapy outcomes of various cancers [26] . It influences various biological processes by altering gene expression and inducing oxidative stress, DNA damage, apoptosis, cell proliferation, and angiogenesis [26, 27] . It also contributes to carcinogenesis in various cancer types, affects cancer progression, and is associated with poor prognosis [28, 29] . Nicotine binds to nAChRs and induces many downstream cancer-associated signaling pathways [29] . Epidemiological studies have reported that smoking tobacco significantly increases the initiation and progression of HCC [30] . Nicotine regulates many cancer-associated properties in most cancers and plays a vital role in inflammatory marker expression, which then regulates various other pathological conditions [8] [9] [10] [11] . Many malignancies are associated with increased exposure to nicotine [29] , notably HCC, which is a common type of liver cancer and is one of the most difficult to treat malignancies worldwide [31] . Our previous study highlighted smoking as an independent risk factor for HCC progression through α7nAChR and JAK2 signaling. [16] . In this study, we investigated the mechanisms underlying nicotine's effects on HCC progression through α7nAChR and JAK2 signaling and the reversal of those effects by DHCT, a novel kinase inhibitor. In the present study, we demonstrated that nicotine treatment induced the HCC cells' proliferation, invasion, and self-renewal abilities (Figures 1 and 2 ) by stimulating and inducing α7nACh, JAK2, Ki67, and cyclin D1 expression (Figure 1 ). Ki67 and cyclin D1 expression indicate the proliferative abilities of cancer cells [32] . Moreover, nicotine exposure significantly modulates the EMT [33] , which is associated with invasion, metastasis, and self-renewal (CSCs) [34] of HCC cancer cells (Figure 2 ). This agrees with recent studies reporting that nicotine exposure stimulates α7nAChR expression in cancer cells [35] . de Jonge et al. [18] and Krafft et al. [36] have demonstrated that the expressions of α7nAChR and JAK2 are strongly correlated. Notably, α7nAChR and JAK2 expression was associated with poor 10 Disease Markers overall survival in patients with HCC [16, 37] . Thus, the α7nAChR gene might play a key role in HCC through JAK2 signaling. Furthermore, DHCT significantly inhibited the in vitro growth and proliferation of HCC cells and sensitized them to nicotine treatment. DHCT treatment reduced the expression of α7nAChR, JAK2, and markers of prolifera-tion and cell cycle arrest (Figure 3 ). Regarding in vitro mobility, migration and invasion are associated with the metastatic potential of HCC cells [38] . Our data confirmed (Figure 4 ) that DHCT effectively inhibited the effects of α7nAChR and JAK2 in nicotine-treated HCC cells, which subsequently reduced their migration/invasion abilities by disturbing the Often, patients with HCC have chemoresistance, which is enhanced by nicotine exposure (Figure 2 ). The expression of CSCs is connected to drug resistance [34] , which is a major challenge in HCC therapy [39] . CSCs contribute to tumorigenicity, self-renewal abilities, and chemoresistance [40, 41] . Notably, DHCT treatment of HCC cells resulted in the reduced expression of α7nAChR, JAK2, and cancer stemness markers (CD133, KLF4, and SOX2) as well as decreased ALDH1 activity ( Figure 5) , thereby suppressing the colony-forming and tumor sphere generation abilities of HCC cells. To further confirm the effect of DHCT in modulating and sensitizing the nicotine effect in vivo. HepG2 cells were subcutaneously injected into the xenograft mice models. Nicotine alone or in combination with DHCT+nicotine and saline control was administered. Reduction in tumor burden, reduced expression of Ki-67, and induced tumor apoptosis were observed in the DHCT+nicotine treatment group, which results in the reduction/neutralizing effect of nicotine on tumor-initiating abilities in xenograft models ( Figure 6 ). In conclusion, as shown in the pictorial abstract of Figure 7 , it demonstrated that the natural compound dehydrocrenatidine attenuates nicotine-induced HCC cell stemness and EMT potential through a7nAChR-Jak2 signaling disruption and a series of experimental designs. Our results revealed that nicotine exposure-induced tumorigenicity in HCC cells by inducing the expression of α7nAChR and JAK2, which was effectively suppressed by DHCT treatment. This led to a reduction of CSC genes and antitumor efficacy in HCC cells. Thus, DHCT treatment could overcome/reverse the nicotine-induced progression of HCC cells, which may serve as a useful therapeutic strategy in patients with HCC. The datasets used and analyzed in the current study are publicly accessible as indicated in the manuscript. Highlights. (i) Natural compound dehydrocrenatidine attenuates nicotine-induced stemness in hepatocellular carcinoma. (ii) Natural compound dehydrocrenatidine attenuates nicotine-induced epithelial-mesenchymal transition in hepatocellular carcinoma. (iii) Natural compound dehydrocrenatidine regulating a7nAChR-Jak2 signaling pathways in hepatocellular carcinoma. We confirm that we have no known conflicts of interest associated with this publication, and no significant financial support for this work could have influenced its outcome. 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Therapeutic implications of cancer initiating cells The authors thank all research assistants of the Translational Research Laboratory and Core Facility Center, Taipei Medi-cal University-Shuang Ho Hospital, for their assistance with the flow cytometry and molecular and cell-based assays. The author also thanks the Gene Targeting Core Lab at Taipei Medical University in Taiwan for providing technical support. The authors would like to acknowledge Taipei Medical University for the technical support of professional English proofreading and editing services. Ching-Li Li is responsible for the study conception and experimental design; Chien-Che Wang, Hsin-Te Pai, Stan-Ley Tu, and Pin-Yuan Hou performed the experiments; Chien-Yu Huang is responsible for the data collation and analysis; Ming-Te Huang and Yu-Jia Chang for the manuscript writing; Ming-Te Huang and Yu-Jia Chang for the provided reagents, materials, and experimental infrastructure; and all authors read and approved the final submitted version of the manuscript. Supplementary