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Contents lists available at ScienceDirect Materials Science & Engineering C journal homepage: www.elsevier.com/locate/msec Synthesis and evaluation of the antiproliferative efficacy of BRM270 phytocomposite nanoparticles against human hepatoma cancer cell lines Meeta Geraa, Nameun Kima, Mrinmoy Ghoshb, Neelesh Sharmac, Do Luong Huynha, Nisansala Chandimalia, Hyebin Koha, Jiao Jiao Zhanga, Tae Yoon Kanga, Yang Ho Parkd, Taeho Kwona, Dong Kee Jeonga,⁎ a Laboratory of Animal Genetic Engineering and Stem Cell Biology, Department of Animal Biotechnology, Jeju National University, Jeju, Jeju-Do 690-756, Republic of Korea bDepartment of Biotechnology, Division of Research and Development, Lovely Professional University, Punjab 144411, India c Division of Veterinary Medicine, Faculty of Veterinary Science and Animal Husbandry, Sher-e-Kashmir University of Agricultural Sciences and Technology of Jammu, R.S. Pura, Jammu 181102, India d BRM Institute, Seoul 06111, Republic of Korea A R T I C L E I N F O Keywords: Anticancer activity BRM270 nanoparticles Human hepatoma cancer cells Mechanical-milling method Phyto-composite A B S T R A C T BRM270 is the most leading phytochemical extract that possesses potent anticancer properties. A major chal- lenge associated with this drug is its low bioavailability and thus requires high dosages for cancer treatment. Here, we report the novel nano-synthesis of phyto-composite, BRM270 for the first time by mechanical milling method with specific modifications for enhanced cytotoxicity against HepG2 human hepatoma cancer cells. Unlike free BRM270 and other phytomedicines, BRM270 nanoparticles (BRM270 NPs) are well-dispersed and small sized (23 to 70 nm) which is believed to greatly enhanced cellular uptake. Furthermore, the acidic tumor microenvironment attracts BRM270 NPs enhancing targeted therapy while leaving normal cells less affected. The comparative cytotoxicity analysis using MTT assay among the three treatment groups, such as free BRM270, BRM270 NPs, and doxorubicin demonstrated that BRM270 NPs induced greater cytotoxicity against HepG2 cells with an effective drug concentration of 12 μg/ml. From FACS analysis, we observed an apoptotic cell death of 44.4% at BRM270 NPs treated cells while only 12.5% found in the free BRM270 treated cells. Further, the comparative relative expression profiling of the candidate genes were showed significant (p 0.5 million annual mortalities, making it the third leading cause of cancer-related deaths [1]. Several types of chemotherapeutic drugs are available to treat hepatic cancer [2,3]. However, these drugs usually have some major drawbacks of cancer resistance due to multidrug resistance (MDR) [4,5], low apoptotic proteins, and high toxicity associated with the current treatment modalities, which are a big challenge [6,7]. There- fore, the last decade has witnessed a renewed interest in biologically safe and active naturally occurring compounds isolated from a plethora of plant sources for targeting cancer cells [8–10]. Phytochemicals have attracted researchers worldwide for various therapeutic purposes because of their minimal toxicity and maximum efficacy [11]; however, phytotherapeutics needs an investigative methodology to deliver the components in a sustained manner to in- crease cellular efficacy and avoid bulk drug administration [12]. https://doi.org/10.1016/j.msec.2018.11.055 Received 3 May 2018; Received in revised form 17 October 2018; Accepted 27 November 2018 ⁎ Corresponding author at: Department of Animal Biotechnology, Faculty of Biotechnology, Jeju National University, Ara-1 Dong, Jeju-Do 690-756, Republic of Korea. E-mail address: newdkjeong@gmail.com (D.K. Jeong). Materials Science & Engineering C 97 (2019) 166–176 Available online 28 November 2018 0928-4931/ © 2018 Published by Elsevier B.V. T http://www.sciencedirect.com/science/journal/09284931 https://www.elsevier.com/locate/msec https://doi.org/10.1016/j.msec.2018.11.055 https://doi.org/10.1016/j.msec.2018.11.055 mailto:newdkjeong@gmail.com https://doi.org/10.1016/j.msec.2018.11.055 http://crossmark.crossref.org/dialog/?doi=10.1016/j.msec.2018.11.055&domain=pdf Therefore, recently, nanotechnology-based strategies are being aggres- sively explored worldwide because of their ability to transport specific anticancer drugs to the tumor site with enhanced phytodrug bioavail- ability [13–15]. In addition, nanomedicine offers various additional benefits, such as improved cellular uptake, targeted drug delivery, ex- cellent stability, and controlled release functions, leading to enhance- ment of its pharmacological activities [16,17]. Herein, BRM270 is a phytocomposite extract formulated from seven plants (Saururus chi- nensis, Citrus unshiu markovich, Scutellaria baicalensis, Portulaca oleracea, Prunella vulgaris, Aloe vera, Arnebia euchroma) used as traditional Asian medicine that inhibits the proliferation of many types of cancer cells [18]. It is one of the most promising anticancer medicinal plant extract and widely distributed in Northeast Asia mainly China, Korea and Japan [19]. Among different anticancer drugs derived from natural resources available, a phyto-composite, BRM270 shows tremendous cytotoxic activity against different cancer cell lines might due to its versatile chemical nature of different plant extract composite or the presence of free hydroxyl groups. The present context of this research investigates the nanoformula- tions of a phytocomposite, BRM270, using an ingenious synthesis ap- proach. Their physicochemical characterization and its evaluation of anticancer activity against HepG2 cell lines. The uniquely prepared BRM270 NPs are highly stable and eco-friendly with increased bioa- vailability and exert significant inhibitory effects towards cancer cells. Earlier studies on free BRM270 have suggested that it plays an im- portant role in the inhibition of the NF-ĸB signaling cascade in MDR- induced stem-like cancer-initiating cells (SLCICs) and promotes pro- grammed cell death [20]. It has also been shown in previous studies that the BRM270 phytodrug was capable of inhibiting lipocalin-2-in- duced epithelial-mesenchymal transition (EMT) process in CD133 in A549 cells, the tumor-initiating cancer stem-like cell xenograft, by in- hibiting the NF-κB pathway [21]. The present study encompasses the preparation and characteriza- tion of nano-range particles of the phytodrug BRM270 for the effective antiproliferative activity against HepG2 cell lines. This nanoformulated phytodrug has the potential for effective intracellular delivery of a drug into cancer cells. It can be a suitable alternative to other chemother- apeutic modes of treatment against cancer cells. 2. Material and methods 2.1. Chemicals and reagents The BRM270 phytocomposite drug was procured from the Biological Response Modifier International Health Town Corp., Korea. The organic solvents used for the extraction were of analytical grade from Fisher Scientific (UK). Acetonitrile (HPLC grade, Fisher Scientific, UK) and phosphoric acid were of analytical grade (BHD, England). Ultrapure water from Milli-Qsystem (Millipore, Bedford, MA, USA) was used for the mobile phase preparation. Dimethylsulfoxide (DMSO) was purchased from Junsei Chemical Co. Ltd. (South Korea). The reagents used in the cell culture assay were of molecular biology grade. The reagent and culture media Dulbecco's modified eagle's medium (DMEM) were purchased from GIBCO®, Invitrogen Corporation (Carlsbad, CA, USA). The glutaraldehyde was purchased from Sigma- Aldrich Chemie GmbH (Munich, Germany). All the other reagents used in the present study were of analytical grade. 2.2. Preparation of BRM270 nanoparticles The total of 1ml solution was used from the standard BRM270 pack and sprayed dropwise into 50ml boiling water with a flow rate of 0.2 ml/min for 5min under constant stirring at 200 to 800 rpm at room temperature for 30min. After continuous stirring, the solution was kept in an ultrasonicator for 2 h with an ultrasonic power of 100W and a frequency of 30 kHz. After sonication, a clear pale yellow-orange co- lored solution was obtained. The solution was further concentrated up to 5ml under reduced pressure at 40 °C using a rotavapor and then freeze-dried to obtain an orange-brown powder using lyophilizer without using any cryoprotectant and stored at −20 °C for further use (Fig. 1). 2.2.1. Physico-chemical characterization of BRM270 NPs The synthesized BRM270 NPs were characterized using the LAMBDA25 ultraviolet (UV)-visible spectroscopy (Perkin Elmer, Waltham, MA, USA). The aqueous solution of BRM270 NPs was scanned within a wavelength ranging from 200 to 800 nm and the characteristic peaks were detected. The comparative analysis of surface Fig. 1. Schematic preparation of BRM270 nanoparticles using mechanical milling method. M. Gera et al. Materials Science & Engineering C 97 (2019) 166–176 167 morphology and the shape of the free BRM270 vs. BRM270 NPs was performed using the JSM-6700F field emission scanning electron mi- croscope (FE-SEM) (JEOL Ltd., Tokyo, Japan). The sample was pre- pared by spreading the aqueous dispersion of free BRM270 and BRM270 NPs separately over the carbon tape and drying it under a nitrogen stream. The sample was then coated with the OPC80 T osmium plasma sputter coated with a platinum layer 200 Å thick under vacuum conditions. The JEOL JEM 1200EX II high-resolution transmission electron microscope (HR-TEM) (JEOL Ltd., Tokyo, Japan) was used to examine the powdered BRM270 NPs and to record the exact NP size and shape. The samples for HR-TEM analysis were prepared by ultra- sonically dissolving the powdered free BRM270 and BRM270 NPs in double-distilled water. A drop of this solution was subsequently de- posited onto a carbon-coated copper grid and allowed to evaporate under ambient conditions. The vibrational spectra of BRM270 were recorded on a Nicolet 6700 Fourier transform infrared (FTIR) spectro- photometer (Thermo Electron Corporation, Pasadena, TX, USA). The dried NP sample was ground with KBr pellets and measured at a wa- velength ranging from 600 to 4000 cm−1. The FTIR analysis was per- formed to study the functional groups of the BRM270 molecules. The size distribution or average diameter of synthesized BRM270 NPs was further confirmed by Dynamic light scattering (DLS, Zetasizer Nano ZS, Malvern Instruments, UK). 2.2.2. Physico-chemical stability studies The stability analysis of BRM270 NPs was explored over time in phosphate-buffered saline (PBS; 0.01M) at different pH values of pH 4.5, pH 5.5 and pH 7.5. The BRM270 NPs were stored at 4 °C tem- perature. After every 24 h of incubation, the particle size of the BRM270 NPs was analyzed for evaluating the physicochemical stability. 2.2.3. In vitro drug-release study The BRM270 NPs release was investigated in a time-dependent manner in different buffers at pH 7.4 and pH 5.0 for 12 h at 37 °C. Accordingly, 1 mg/ml of the BRM270 NPs solution was transferred to the dialysis membrane tube (3.5 kDa). The released drug in the different pH buffers was analyzed at different time intervals by using the UV–visible spectrometer (Perkin Elmer, Waltham, MA, USA). 2.2.4. High-performance liquid chromatography (HPLC) analysis HPLC analysis was conducted on an Agilent 1200 liquid chroma- tography system (Agilent Technologies, Palo Alto, CA, USA), equipped with a double pump and a diode array detector. The separations were carried out on an Agilent Eclipse ODS C18 column (4.6 mm×250.0 mm×5.0 μm). The column temperature was set at 25 °C. The mobile phase consisted of 0.4% aqueous phosphoric acid (A) and acetonitrile (B). The gradient concentration was as follows: 15% B (v/v) at 0–16min, 15–25% B at 16–30min, 25% B at 30–32min, 25–30% B at 32–35min, 30% B at 35–37min, 30–33% B at 37–40min, 33% B at 40–45min, 33–48% B at 45–55min, 48–55% B at 55–75min, 55–80% B at 75–82min, and 80% B at 82–88min, and the re-equilibration time of gradient elution was 15min. The flow rate was 0.8 ml/min and the injection volume was 10 μl. The detection was carried out at a set wavelength of 280 nm. The absorption spectra of the compounds were recorded between 200 and 800 nm. 2.3. Cell culture and treatment conditions The human liver cancer cell lines, HepG2 was maintained in DMEM supplemented with 10.0% fetal bovine serum (FBS) (Hyclone, South Logan, UT, USA), penicillin (100.0 U/ml), and streptomycin (100mg/ ml) were then incubated under standardized conditions at humidified 37 °C and 5% CO2 atmosphere. The human bone marrow cells (hBMCs) were purchased from Korean Cell Line Bank, Seoul, South Korea (KCLB No. 10246). The potential hBMCs were further cultured in DMEM high glucose supplied with 10% FBS, 1% antibiotic-antimycotic, and 10 nM E9644-Sigma epithelial growth factor (Sigma-Aldrich, St. Louis, MO, USA). 2.3.1. Intracellular distribution of BRM270 NPs To investigate the dynamic intracellular distribution of BRM270 NPs, 6.0× 105 cells were seeded in each culture dish and allowed to adhere and acclimate for 1 day. BRM270 NPs at a concentration of 12 μg/ml were then exposed to each culture dish for 12 h. The cells then were harvested by trypsinization, fixed in ice-cold 2.5% glutaraldehyde, and preserved at 4 °C for further analysis. The cells were then post-fixed in 1% osmium tetraoxide in 2.5% glutaraldehyde, dehydrated in graded alcohol, embedded in Epon 812, sectioned with an ultramicrotome, and stained with uranyl acetate and lead citrate. The sections were ex- amined under the HR-TEM operating at 200 kV, with a point resolution of 0.23 nm and C3=1.0mm. 2.3.2. Evaluation of cytotoxicity assay Cytotoxicity of free BRM270, BRM270 NPs and doxorubicin was assessed by MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) assay against normal HBM and cancerous HepG2 cells. Both types of cells were seeded at a density of 5× 103 cells/well in a 96-well plate (Nunc™, Wiesbaden, Germany) in 100 μl of DMEM medium. The cells were incubated for 24 h to adhere properly, then the cells were treated with both free BRM270 and BRM270 NPs at concentrations ranging from 0.0 to 12 μg/ml and Doxorubicin (Dox) at 0 to 5 μM concentration. The DMEM medium itself was used as a solvent to dis- solve various drugs for the exposure in cells. After the further incuba- tion of 24 h, the drug-treated cells were washed twice with phosphate- buffered saline (1× PBS) and incubated for another 4 h with 0.5mg/ml MTT solution in the culture medium. In the cells, dehydrogenase, and reductase would reduce this solution into formazan, a purple color of artificial chromogenic products. After 4 h of incubation, the cells were lysed into 100 μl dimethyl sulfoxide (DMSO) and the absorbance was measured at the wavelength of 570 nm using a bio-assay reader (Bio- Rad, Berkeley, CA, USA). Cell viability was determined using the fol- lowing equation: = ×Number of viable cells Absorbance of sample Absorbance of control( / ) 100 Final results of the assay were reported as the mean value ± standard error of the mean (SEM) of triplicate independent experi- ments. 2.3.3. Apoptosis assayby flow cytometry The cells (1× 105) suspended in 2ml fresh DMEM media were seeded in each well of a 6-well flat-bottomed microtiter plate and in- cubated overnight. After the overnight incubation, the free BRM270 and BRM270 NPs have added an optimized concentration of 12 μg/ml in the media. After 24 h, cells were harvested and washed twice with pre-cold PBS followed by re-suspension in 1× Annexin V binding buffer (BD Biosciences, Franklin Lakes, NJ, USA) at a concentration of 1×106 cells/ml. Approximately 100 μl of such solution (1× 105 cells) was mixed with 5 μl of Annexin V-FITC and 5 μl of propidium iodide (PI, BD Biosciences, San Jose, CA, USA) according to the manufacturer's instructions. The mixed solution was incubated at room temperature (25 °C) in the dark for 15min. Then 400 μl of 1× dilution buffer was added to each tube. The analysis was performed by Beckman Coulter FC500 Flow Cytometry System with CXP Software (Beckman Coulter, Fullerton, CA, USA) within 1 h of the treatment of cells with dilution buffer. 2.3.4. DNA fragmentation using Hoechst 33258 staining The cells (5× 104) were seeded in sterile six-well microtitre plates (Nunc Nunclon™ Delta). After overnight growth, the cells were treated with free BRM270 and its NPs. The cells were later washed with 1× PBS (Gibco Life Technologies™, USA), fixed with 4% paraformaldehyde for 10min, and incubated with 50 μM Hoechst 33258 staining solution M. Gera et al. Materials Science & Engineering C 97 (2019) 166–176 168 for 5min. After three washes with cold PBS, the cells were viewed under a fluorescence microscope (Olympus, Tokyo, Japan) to analyze the apoptotic morphological changes in the nuclear chromatin of both the treated and non-treated cancer cells. 2.3.5. Annotation of Gene Ontology and pathway analysis The biological processes and pathway analysis of the candidate genes, i.e., IL6, CASP 9, BAX, BCL2, p53, MMP9; which are associated with the anticancer activity were investigated. To define the molecular mechanism of tumorigenesis in liver mediated by nanoparticles of BRM270, specific cancer-associated protein-protein interaction network was constructed. All protein-encoding genes were grouped and orga- nized through protein-protein associations using the web-based Search Tool for Retrieval of Interacting Genes/Proteins (STRING) software (v.9.1) (www.string-db.org/). The pathway mapping was performed using the Kyoto Encyclopedia of Genes and Genomes (KEGG) (www. genome.jp/kegg) tool. It is an integrated resource with associated software consisting of three types of databases for genomic, chemical and network information. The web-based ToppCluster (www. toppcluster.cchmc.org/) tool was used to visualize the shared and specific features associated with any number of genes involved in bio- logical processes. 2.3.6. Determination of relative expression of candidate genes by qRT-PCR Cells were seeded at a concentration of 1× 105 in sterile six-well plates and incubated overnight under standard culture conditions. After incubation, the cells were treated with free BRM270 and BRM270 NPs and incubated for 24 h. The cells were then detached with 0.5% trypsin-EDTA (Gibco) and total RNA was extracted with easy Blue (Intron Biotech, Seongnam-si, Gyeonggi-do, Korea). The purified RNA was quantified using a photometer (Bio-Rad Hercules, CA, and the USA). The reverse transcription was performed using a Superscript III first-strand cDNA synthesis kit and oligo (DT) primers (Invitrogen, Waltham, MA, USA). The cDNA was subjected to qRT- PCR for the quantification of the relative transcript levels of the in- flammatory cytokine IL6, pro-apoptotic/anti-apoptotic gene CASP 9, BAX, p53, BCL2, and MMP9 using the specific primers. The oligonu- cleotide primers for the targeted genes and β-actin as an endogenous gene were designed based on sequences available from the NCBI da- tabase using online program Primer-3 (https://www.ncbi.nlm.nih. gov/tools/primer-blast/) (Table 1). RT-PCR was conducted using 2.5 μl of cDNA with an Eppendorf Master Cycler gradient instrument. The thermal cycling reaction was conducted as follows: an initial 5 min at 94 °C; 35 cycles of 30 s at 94 °C, 30 s at 60 °C, and 1min at 72 °C; and a single extension period of 10min at 72 °C. Differential expressions of candidate genes were evaluated using real-time qRT-PCR using the Step-One Real-Time PCR system (Applied Biosystems). Each sample was quantified in triplicate using the dye Eva Green (Biotium, USA) under the following amplification conditions: 95 °C for 10min, followed by 40 cycles of 95 °C for 30 s and 60 °C for 60 s. The efficiency of gene amplification was normalized using β-actin with the mean cycle threshold value (Ct), and the 2−ΔΔCT method was used to measure the relative gene expression. 2.4. Statistical analysis Independent experiments were repeated at least three times, and data are presented as mean ± SEM for all duplicates within an in- dividual experiment. The relative quantitative expressions of the genes by qRT-PCR were analyzed using analysis of variance (ANOVA). The significant differences and multiple comparisons between the mean differential expressions of candidate genes in different treated groups at phttps://www.ncbi.nlm.nih.gov/tools/primer-blast/ nitro group, and NeH bending in primary amines respectively (Fig. 2f). Moreover, the physicochemical stability analysis of BRM270 NPs re- vealed that the particle size gradually increases over time. The BRM270 NPs in pH 7.5 showed a rapid increase in their size as compared to the acidic pH conditions such as pH 4.5 and pH 5.5 (Fig. 2g). The size distribution histogram of DLS indicated that the average size was 46.5 nm (Fig. 2h). 3.1.1. Drug release study of BRM270 nanoparticles BRM270 NPs released in different pH levels at 37 °C in different pH buffered solution at pH 5.0 and pH 7.4 (Fig. 2i). Maintaining the tem- perature at 37 °C mimics the normal physiological temperature. Low drug release was observed at pH 7.4 at 12 h but at pH 5, the drug release was nearly 80%. The release study suggested that BRM270 NPs was completely acidic pH-responsive thus releasing at the lower pH condi- tions. 3.1.2. HPLC fingerprints for BRM270 drug The HPLC chromatograms were detected at 280 nm for free BRM270 vs. BRM270 NPs (1mg/ml) solution showed major peaks at retention times 38.8, 65, and 67.5min, respectively (Fig. 2j). The spe- cific phytochemical compounds were identified by comparing their retention times and the UV–visible spectra with earlier reported study [16]. Thus, the purity of each chromatographic peak was well identified with their characteristic retention times at 280 nm wavelength. The peaks were observed and determined to be quercetin, dihydroguaiaretic acid and sauchinone. Fig. 2. Characterization of BRM270 NPs formulation (a) FE-SEM image of free BRM270 particles (scale bar 20 μm). (b) FE- SEM image of BRM270 NPs (scale bar 1 μm). (c) HR-TEM analysis of free BRM270 parti- cles (scale bar 20 μm). (d) HR-TEM analysis of BRM270 NPs (scale bar 2 μm). (e) Absorption spectra of the BRM270 NPs were analyzed using UV–visible spectroscopy. (f) Fourier transform infrared spectrum of the BRM270 NPs. (g) Physico-chemical stability analysis of BRM270 NPs over time in phos- phate buffer saline at pH 4.5, pH 5.5 and pH 7.5 levels at 4 °C (h) DLS histogram showing particle size distribution of synthe- sized silver nanoparticles (i) pH dependent release study of BRM270 NPs by calculating the amount of BRM270 NPs in acetate (pH 5.0) and phosphate (pH 7.4) buffer ana- lysis filtrate at different time intervals. (j) HPLC chromatograms of BRM270 methanol extract and BRM270 NPs. Quercetin, dihy- droguaiaretic acid, sauchinone. M. Gera et al. Materials Science & Engineering C 97 (2019) 166–176 170 3.1.3. Distribution and internalization mechanisms of BRM270 NPs in cancer cells The HR-TEM images of HepG2 cells treated with BRM270 NPs de- monstrated the distribution and internalization of the NPs into the HepG2 cells (Fig. 3). The control group of cells without any treatment was shown in Fig. 3a. Several dispersed BRM270 NPs appeared in the cell cytoplasm (Fig. 3b). More importantly, Fig. 3c & d shows the NPs that were residing completely within the nucleus. These results re- garding the detailed BRM270 NP location at the subcellular level have not been previously reported. BRM270 NPs were rapidly internalized into the cell after the NPs were added. TEM images showed that after 1 h of BRM270 NP treatment, the NPs reached the surrounding areas of the nucleus, and the cells continued to uptake the BRM270 NPs. The results showed that the intracellular distribution among the cells was the same regardless of the size of the particle. The presence of BRM270 NPs was found on the membrane while entering inside the cell (Fig. 3d & e). A typical endosome-like structure was found near the cell membrane containing two groups of BRM270 NPs, which later moved inside the cell (Fig. 3f). Cellular internalization was more efficient with the endocytosis process because of the smaller size of the NPs; there- fore, a greater accumulation of BRM270 NPs was observed in the cell membrane and cytoplasm. The presence of BRM270 NPs was found inside the nuclear membrane (Fig. 3g & h). All of these images indicate that endocytosis is the mechanism behind the internalization of BRM270 NPs in the HepG2 cells. 3.2. Cellular viability in HBM and HepG2 cells To understand the effect of free BRM270 vs. BRM270 NPs with Doxorubicin in both HepG2 and HBM cell proliferation, and to de- termine an effective concentration of BRM270 NPs, we performed an MTT assay following the treatment at a range of doses from 0 to 12 μg/ ml. BRM270 NPs caused a dose-dependent decrease in HepG2 cells and inhibited their proliferation (Fig. 4a). The results revealed that the Fig. 3. Intracellular distribution of BRM270 NPs in HepG2 cells. (a) Control cells without BRM270 NPs treatment. (b) Group of BRM270 NPs located inside the cytoplasm. (c, d) BRM270 NPs residing on and inside the nucleus. (e) BRM270 NPs entering inside the cytoplasm through the membrane. (f) Spherical nanoparticles are found in the cytoplasm. (g, h) BRM270 NPs residing inside and on the nuclear membrane (scale bar= 500 nm to 2 μm). M. Gera et al. Materials Science & Engineering C 97 (2019) 166–176 171 inhibitory effect of BRM270 NPs on the cancer cells was much stronger as compared to the free BRM270 particles and the standard drug dox- orubicin, the positive control at the same concentration at 24 h. How- ever, it was found that free BRM270, BRM270 NPs, and doxorubicin showed less or no effect on the growth of normal HBM cells. 3.2.1. Apoptosis assay by Annexin-V-FITC/PI staining The apoptotic cell death was measured with fluorescein iso- thiocyanate-conjugated Annexin V and PI staining of HepG2 cells after treatment with the optimized concentration of free BRM270 and BRM270 NPs. The results showed that the number of apoptotic cells (Annexin V-positive cells) increased in the BRM270 NP-treated cells after 24 h exposure. The Annexin V-FITC assay showed 12.5% of the free BRM270 treated cells and 44.4% of the BRM270 NPs treated cells within 24 h underwent apoptosis. No significant (papoptosis. Caspase 9 binds to Apaf-1 leading to the activation of the protease which then cleaves and activates caspase 3. It also promotes DNA damage-induced apoptosis in an ABL1/c-Abl-dependent manner and proteolytically, cleaves poly (ADP-ribose) polymerase (PARP). MMP9 plays an essential role in local proteolysis of the extracellular matrix and in leukocyte migration. The graphical network among the candidate genes was viewed using the “abstracted” option of ToppCluster, excluding the genes from the network and the “gene level” option. To provide a dissected gene level view, we choose the GO of the biological process shared among the genes expressed (Fig. 5b). From the abstracted network analysis, the distinct functional separation was observed. ToppCluster allows se- lecting the terms of interest to be included in the network. Notably, the pathway analysis revealed close associations of the variety of biological processes including transcriptional misregulation in cancer (p=0.00029) (IL6, p53, MMP9), PI3K-Akt signaling pathway (p=3.75E−05) (IL6, CASP9, BCL2, p53), HIF-1 (p=0.00485) (IL6, Fig. 4. Cell culture assay (a) cellular viability of HepG2 and HBM cells treated with BRM270, BRM270 NPs, and doxorubicin. Percentage of viable cells was evaluated using MTT assay. Each value represents the mean ± SE. (b) Apoptosis assay for the HepG2 cells treated with (a) free BRM270 and (b) BRM270 nanoparticles. (c) Confirmation of the DNA fragmentation apoptosis, condensation, and nuclei of early apoptotic cells show lobular or fragmented and shrunk blue bodies in the BRM270 NPs treated a group of cells. (For interpretation of the references to color in this figure legend, the reader is referred to the web version of this article.) M. Gera et al. Materials Science & Engineering C 97 (2019) 166–176 172 BCL2), TNF-signaling pathways (p=0.00491) (IL6, MMP9), apoptosis (p=2.26E−07) and p53 signaling pathway (p=2.61E−05) (CASP9, BAX, BCL2, p53), thyroid hormone signaling pathway (p=0.00532) (CASP9, p53), neurotrophin signaling pathway (p=8.92E−05) (BAX, BCL2, p53), proteoglycan signaling pathway (p=0.0143) (p53, MMP9). 3.2.3. Validation of the relative expression of candidate genes using qRT- PCR The relative gene expression levels of selected genes (IL6, Caspase 9, BAX, BCL2, p53, and MMP9) have been assessed by normalizing ex- pression levels of the samples from the different treated groups against the transcript levels of an endogenous reference GAPDH (Fig. 5c). The expression of multifunctional cytokine, IL6 showed significant (pbecause of their significant physicochemical properties within the nano-range, which makes it highly efficacious. In support of these findings, one of the previous studies conducted by Mongre et al. studied free BRM270 particles and showed cytotoxicity with relatively high concentrations of 125 μg/ml in Cal72 and SaOS-2 SLCICs [18]. This study concluded that for free BRM270 particles, there must be a need to expose the cancer cells to a high concentration of the drug because of its larger size and irregular shape, which restricts its cellular permeability and lowers bioavailability and the distribution of the cells; therefore, our prime aim was to systematically design a BRM270 within a nano-range for providing a minimum effective dose, which is critical for clinical trials in future experiments. In addition, BRM270 NPs were found to be more effective compared to free BRM270 in inducing apoptosis in HepG2 cells, inducing 44.4% late apoptosis at a minimum effective concentration of 12 μg/ml, while free BRM270 induced only 12.5% at the same drug concentration and incubation period. This demonstrates that BRM270 showed better therapeutic effects in its nano formulation form. Previous studies have shown that freeBRM270 induced 33.39% and 29.32% apoptotic cell death in Cal72 and SaOS-2 SLCICs, respectively [18]. This led us to confirm that the nano-range formulation of BRM270 is more effective than the free BRM270. Furthermore, to compare the effect of free BRM270 and BRM270 NPs with Dox, we targeted candidate genes mediating cancer progres- sion in the HepG2 cells treated with free BRM270, BRM270 NPs, and Dox revealed that the BRM270 NPs treated group of cells showed sig- nificantly (p(ag-NPs) against human breast (MCF-7), lung (A549) and pharynx (Hep-2) cancer cell lines, J. Photochem. Photobiol. B Biol. 173 (2017) 99–107. [10] S. Parani, G. Bupesh, E. Manikandan, K. Pandian, O.S. Oluwafemi, Facile synthesis of mercaptosuccinic acid-capped CdTe/CdS/ZnS core/double shell quantum dots with im- proved cell viability on different cancer cells and normal cells, J. Nanopart. Res. 18 (11) (2016) 347. [11] P. Thangavel, B. Viswanath, S. Kim, Synthesis and characterization of kaempferol-based ruthenium (II) complex: a facile approach for superior anticancer application, Mater. Sci. Eng. C 89 (2018) 87. [12] S.H. Ansari, M. Farha Islam, Influence of nanotechnology on herbal drugs: a review, J. Adv. Pharm. Technol. Res. 3 (2012) 142. [13] Z. Li, H. Huang, S. Tang, Y. Li, X.F. Yu, H. Wang, P. Li, Z. Sun, H. Zhang, C. Liu, P.K. Chu, Small gold nanorods laden macrophages for enhanced tumor coverage in photothermal therapy, Biomaterials 74 (2016) 144. [14] S. Jiang, L. Hua, Z. Guo, L. Sun, One-pot green synthesis of doxorubicin loaded-silica nanoparticles for in vivo cancer therapy, Mater. Sci. Eng. C 90 (2018) 257–263. [15] V. Krishnan, G. Bupesh, E. Manikandan, A.K. Thanigai, S. Magesh, R. Kalyanaraman, M. Maaza, Green synthesis of silver nanoparticles using Piper nigrum concoction and its anticancer activity against MCF-7 and Hep-2 cell lines, J. Antimicro. 2 (2016) 4172. [16] J. Shi, P.W. Kantoff, R. Wooster, O.C. Farokhzad, Cancer nanomedicine: progress, chal- lenges and opportunities, Nat. Rev. Cancer 17 (2017) 20. [17] S.D. Steichen, M. Caldarera-Moore, N.A. Peppas, A review of current nanoparticle and targeting moieties for the delivery of cancer therapeutics, Eur. J. Pharm. Sci. 48 (2013) 416. [18] R.K. Mongre, S.S. Sodhi, M. Ghosh, J.H. Kim, N. Kim, Y.H. Park, S.J. Kim, Y.J. Heo, N. Sharma, D.K. Jeong, The novel inhibitor BRM270 down regulates tumorigenesis by suppression of NF-κB signaling cascade in the MDR-induced stem-like cancer-initiating cells, Int. J. Oncol. 46 (2015) 2573. [19] B. Zhang, Q. Yuan, L. Huang, X. Liu, X. Li, S. Lin, M. Chen, X. Ge, Locality identification of Chinese medicinal plant Scutellaria baicalensis (Lamiaceae) population-level DNA bar- coding, Zhongguo Zhong Yao Za Zhi 37 (2012) 1100–1106 (in Chinese). [20] R.K. Mongre, S.S. Sodhi, N. Sharma, M. Ghosh, J.H. Kim, N. Kim, Y.H. Park, Y.G. Shin, S.J. Kim, Z.J. Jiao, D.L. Huynh, D.K. Jeong, Epigenetic induction of epithelial to me- senchymal transition by LCN2 mediates metastasis and tumorigenesis, which is abrogated by NF-κB inhibitor BRM270 in a xenograft model of lung adenocarcinoma, Int. J. Oncol. 48 (2016) 84. [21] H.J. Chen, X. Li, J.W. Chen, S. Guo, B.C. Cai, Simultaneous determination of eleven bioactive compounds in Saururus chinensis from different harvesting seasons by HPLC- DAD, J. Pharm. Biomed. Anal. 51 (2010) 1142. [22] E. Piktel, K. Niemirowicz, M. Wątek, T. Wollny, P. Deptuła, R. Bucki, Recent insights in nanotechnology-based drugs and formulations designed for effective anti-cancer therapy, J. Nanobiotechnol. 14 (2016) 39. [23] A. Diallo, E. Manikandan, V. Rajendran, M. Maaza, Physical & enhanced photocatalytic properties of green synthesized SnO2 nanoparticles via Aspalathus linearis, J. Alloys Compd. 681 (2016) 561–570. [24] A.H. Shah, E. Manikandan, M.B. Ahmed, V. Ganesan, Enhanced bioactivity of Ag/ZnO nanorods-a comparative antibacterial study, Nanomedicine and Nanotechnology, 2013, pp. 3–4. [25] F. Lu, H. Wu, Y. Hung, C.Y. Mou, Size effect on cell uptake in well-suspended, uniform mesoporous silica nanoparticles, Small 5 (2009) 1408–1413. [26] A.H. Shah, E. Manikandan, M.B. Ahamed, D.A. Mir, S.A. Mir, Antibacterial and blue shift investigations in sol–gel synthesized CrxZn1−xO nanostructures, J. Lumin. 145 (2014) 944–950. [27] B.D. Ngom, T. Mpahane, E. Manikandan, M. Maaza, ZnO nano-discs by lyophilization process: size effects on their intrinsic luminescence, J. Alloys Compd. 656 (2016) 758–763. [28] R. Devika, S. Elumalai, E. Manikandan, D. Eswaramoorthy, Biosynthesis of silver nano- particles using the fungus Pleurotus ostreatus and their antibacterial activity, Sci. Rep. 1 (2012) 557. [29] M.S. Zaman, N. Chauhan, M.M. Yallapu, R.K. Gara, D.M. Maher, S. Kumari, M. Sikander, S. Khan, N. Zafar, M. Jaggi, S.C. Chauhan, Curcumin nanoformulation for cervical cancer treatment, Sci. Rep. 6 (2016). [30] H. Maeda, Macromolecular therapeutics in cancer treatment: the EPR effect and beyond, J. Control. Release 164 (2016) 138–144. [31] K. Song, P. Xu, Y. Meng, F. Geng, J. Li, Z. Li, J. Xing, J. Chen, B. Kong, Smart gold nanoparticles enhance killing effect on cancer cells, Int. J. Oncol. 42 (2013) 597–608. [32] B.W. Mwakikunga, A. Forbes, E. Sideras-Haddad, M. Scriba, E. Manikandan, Self as- sembly and properties of C: WO3 nano-platelets and C: VO2/V2O5 triangular capsules of C: VO2/V2O5 fullerenes and quantum dots produced by laser solution photolysis, Nanoscale Res. Lett. 5 (2010) 389–397. [33] D.E. Owens, N.A. Peppas, Opsonization, biodistribution, and pharmacokinetics of poly- meric nanoparticles, Int. J. Pharm. 307 (2006) 93–102. [34] S. Abalde-Cela, P. Taladriz-Blanco, M.G. de Oliveira, C. Abell, Droplet microfluidics for the highly controlled synthesis of branched gold nanoparticles, Sci. Rep. 8 (2016) 2440. [35] E. Blanco, H. Shen, M. Ferrari, Principles of nanoparticle design for overcoming biological barriers to drug delivery, Nat. Biotechnol. 33 (2015) 941. [36] F.R. Santer, K. Malinowska, Z. Culig, I.T. Cavarretta, Interleukin-6 trans-signaling dif- ferentially regulates proliferation, migration, and adhesion and maspin expression in human prostate cancer cells, Endocr. Relat. Cancer 17 (2010) 241. [37] Q. Liu, G. Li, R. Li, Q. He, L. Deng, C. Zhang, J. Zhang, IL-6 promotion of glioblastoma cell invasion and angiogenesis in U251 and T98G cell lines, J. Neuro-Oncol. 100 (2010) 165. [38] E.H. Kim, H.S. Song, S.H. Yoo, M. Yoon, Tumor treating fields inhibit glioblastoma cell migration, invasion and angiogenesis, Oncotarget 7 (2016) 65125. [39] H. Liang, T.M. Block, M. Wang, B. Nefsky, R. Long, J. Hafner, A.S. Mehta, J. Marrero, R. Gish, P.A. Norton, Interleukin-6 and oncostatin M are elevated in liver disease in conjunction with candidate hepatocellular carcinoma biomarker GP73, Cancer Biomark. 11 (2014) 161–171. [40] S.C. Gupta, J.H. Kim, S. Prasad, B.B. Aggarwal, Regulation of survival, proliferation, in- vasion, angiogenesis, and metastasis of tumor cells through modulation of inflammatory pathways by nutraceutical, Cancer Metastasis Rev. 29 (2010) 405–434. [41] Y.X. Zhang, C.Z. Kong, H.Q. Wang, L.H. Wang, C.L. Xu, Y.H. Sun, Phosphorylation of Bcl- 2 and activation of caspase-3 via the c-Jun N-terminal kinase pathway in ursolic acid- induced DU145 cells apoptosis, Biochimie 91 (2009) 1173–1179. [42] R. Guo, B. Lin, J.F. Pan, Inhibition of caspase-9 aggravates acute liver injury through suppression of cytoprotective autophagy, Sci. Rep. 6 (2016) 32447. [43] K. Hientz, A. Mohr, D. Bhakta-Guha, T. Efferth, The role of p53 in cancer drug resistance and targeted chemotherapy, Oncotarget 8 (2017) 8921. Meeta Gera is working on the synthesis and application of phyto-nanoparticles for anti-cancer activity against various cancer stem cells. Nameun Kim is working on genetic engineering, NGS technology and stem cell research. M. Gera et al. Materials Science & Engineering C 97 (2019) 166–176 175 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0005 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0005 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0005 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0005 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0010 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0010 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0015 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0015 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0020 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0020 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0020http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0025 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0025 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0030 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0030 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0030 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http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0210 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0210 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0215 http://refhub.elsevier.com/S0928-4931(18)31253-0/rf0215 Mrinmoy Ghosh is working on genetic engineering, NGS technology and stem cell research. Neelesh Sharma is working on stem cell research and mastitis in dairy animals with emphasis on use of nano particles and herbal drugs for its management. Do Luong Huynh is working on cancer stem cell research in phytochemicals. Nisansala Chandimali is working on cancer stem cell re- search in phytochemicals. Hyebin Koh is working on cancer stem cell research in phytochemicals. Jiao Jiao Zhang is working on cancer stem cell research in phytochemicals. Tae Yoon Kang is working on cancer stem cell research in phytochemicals. Yang Ho Park is from Jeju National University Cancer Stem Cell and System Biology. He has published more than 80 papers in reputed journals. Taeho Kwon is working on cancer stem cell research in phytochemicals. Dong Kee Jeong is from Jeju National University Cancer Stem Cell and System Biology. He has published more than 80 papers in reputed journals. M. Gera et al. Materials Science & Engineering C 97 (2019) 166–176 176 Synthesis and evaluation of the antiproliferative efficacy of BRM270 phytocomposite nanoparticles against human hepatoma cancer cell lines Introduction Material and methods Chemicals and reagents Preparation of BRM270 nanoparticles Physico-chemical characterization of BRM270 NPs Physico-chemical stability studies In vitro drug-release study High-performance liquid chromatography (HPLC) analysis Cell culture and treatment conditions Intracellular distribution of BRM270 NPs Evaluation of cytotoxicity assay Apoptosis assay by flow cytometry DNA fragmentation using Hoechst 33258 staining Annotation of Gene Ontology and pathway analysis Determination of relative expression of candidate genes by qRT-PCR Statistical analysis Results Preparation and characterizationof BRM270 NPs Drug release study of BRM270 nanoparticles HPLC fingerprints for BRM270 drug Distribution and internalization mechanisms of BRM270 NPs in cancer cells Cellular viability in HBM and HepG2 cells Apoptosis assay by Annexin-V-FITC/PI staining Clustering of candidate genes and annotation of pathways Validation of the relative expression of candidate genes using qRT-PCR Discussion Conclusion Disclosure Acknowledgments References