Abstract
Background
Recently different forms of nanographene were proposed as the material with high anticancer potential. However, the mechanism of the suppressive activity of the graphene on cancer development remains unclear. We examined the effect of oxygenated, reduced and pristine graphene on the gene expression in glioblastoma U87 cell line.
Results
Conducting microarrays and RT-qPCR analysis we explored that graphene oxide (rather than reduced graphene oxide and pristine graphene) down-regulates the mRNA expression of mitochondrial oxidative phosphorylation (OXPHOS) nuclear genes of complexes I, III, IV and V. The presented results provide first evidence for the hypothesis that the suppressed growth of GBM can be the consequence of down-regulation of OXPHOS protein expression and decreased ATP level.
Conclusions
We suggest that changes in the expression of OXPHOS genes identified in our study may mediate the anti-proliferative and anti-migratory effects of graphene oxide in glioblastoma cells. However, further investigations with different cell lines, regarding expression, regulation and activity of OXPHOS genes identified in our study is necessary to elucidate the mechanism mediating the anti-proliferative and anti-migratory effects of graphene oxide in glioblastoma cells.
Electronic supplementary material
The online version of this article (10.1186/s12867-018-0119-2) contains supplementary material, which is available to authorized users.
Keywords: Graphene, Graphene oxide, Glioblastoma, Gene expression, OXPHOS
Background
Graphene is a nanomaterial with unique properties and great application potential. It is expected to revolutionize various medical fields, including oncology. Many biomedical applications of graphene and its derivatives have been proposed in cancer diagnosis [1], biomedicine [2], photothermal therapy [3, 4], cancer cell imaging [5], and drug delivery [6, 7]. Graphene is a single atomic layer of sp2-bonded carbon nanostructure [8], with a higher ratio of peripheral to central carbon atoms compared to similar nanomaterials. Graphene appears to be biocompatible, with preferential affinity to the cell membrane, and is less toxic than other carbon nanoparticles [9, 10]. Regarding biomedical applications, graphene oxide (GO) and reduced graphene oxide (rGO) are the most commonly described [11]. One of the crucial differences between the forms is their hydrophobic (rGO) or hydrophilic (GO) characteristic [12]. We previously performed the comparative toxicity studies, evaluating their effect on organism development and cancer growth in both in vitro and in vivo models [13–16]. Furthermore, it has been reported that nanocarbons can affect cell morphology and viability and can also influence DNA damage, RNA efflux and gene expression [1, 17, 18]. Hydrophilic GO possesses a large aromatic surface with reactive COOH and OH groups which facilitate connections with cellular molecules [19]. Compared to other graphene types, GO is smaller, possesses smooth edges and forms more regular structures. Based on the comparative studies previously published, we decided to perform the presented experiments using 100 nm graphene platelets in the concentration of 25 ppm [12]. The detailed description of graphene structure and its distribution within glioblastoma cells were previously extensively analyzed [12].
It was demonstrated that GO effectively inhibits tumor-sphere formation in breast, ovarian, prostate, lung, pancreas and brain cell lines [16, 17]. GO can suppress the development and migration of cancer cells by impairing mitochondrial respiration [20, 21]. Also, in vivo studies presented GO to be a suppressing agent of cancer development [22].
In the chicken embryo model, we have demonstrated that GO and rGO significantly decreased volume and weight of the glioblastoma tumor (GBM) [15, 23, 24]. Furthermore, it has been indicated and that functionalized GO might be applied as the drug delivery agent in the GBM therapy [25]. Moreover, after treatment with rGO, the apoptosis markers were significantly increased, suggesting that rGO may be involved in the inhibition of tumor development.
Importantly, graphene can directly and physically interact with DNA, causing the deregulation of gene expression [17]. GO treatment at concentrations of 10 and 100 mg/mL altered gene expression patterns, and mediated DNA-damage control, cell apoptosis, cell cycle, and metabolism [1].
Based on these investigations and continuing our previous research indicating the suppressive effect of GO and rGO on GBM growth, we hypothesized that different graphene forms (GO, rGO and pG—pristine graphene) may inhibit GBM development by regulation of the genes encoding proteins responsible for mitochondrial oxidative phosphorylation (OXPHOS). The presented study is considered as the first step in validating this hypothesis.
Results
Using microarrays, we have analyzed transcriptomic patterns elicited in GBM cells by treatment with either GO, rGO or pG. GO surface profile is presented on Fig. 1. GO treatment increased the expression of 90 and decreased the expression of 227 known transcripts in GBM cells. All probes reporting statistically significant differences between experimental groups are presented in Additional file 1. The treatment of GBM cells with pG changed the expression of FOS and C8orf4 genes, while GR changed only the expression of the FOS gene. Thus, we propose that rGO and pG do not notably modulate mRNA expression levels, at least under the conditions of the current experiment. Using the Enrichr tool [26] we performed enrichment analysis on the list of genes deregulated by GO treatment.
We have identified multiple overrepresented terms (Additional file 2) including: 120 biological processes, 25 cellular components, 17 molecular functions, 42 biological pathways, 291 unique transcriptional regulators (Additional file 2) and 13 unique hub proteins or protein complexes. Data from several independent databases, queried in our enrichment analysis, showed that genes involved in the activity of the electron transport chain were robustly overrepresented in our list of differentially expressed genes.
Additional file 1 presents identified terms related to the electron transport chain, which were characterized in our analysis by the highest adjusted P-values of enrichment. Figure 2 presents the differentially expressed genes associated with the electron transport chain pathway.
Microarray results were validated by RT-qPCR. We have analyzed 10 genes involved in the electron transport chain. The results of RT-qPCR analysis confirmed the findings of the microarray study (Fig. 3). The correlation coefficient between the results of RT-qPCR and microarray analyses, calculated using the Spearman rank correlation method, was equal to 0.88.
Discussion
It was already widely presented that GO suppresses the growth of the different cancers in both in vivo and in vitro studies, however, the mechanism responsible for the inhibition remains unknown [22, 25, 27, 28].
In the present work, we used U87 cell line from the American Type Culture Collection. The studies of U87 cell markers [29] and recent genetic profiling and transcriptome analysis in human glioma cell lines indicate that this cell line is a glioblastoma cell line [30]. The comparison studies between different glioma cell lines treated with graphene were previously evaluated in our laboratory and thoroughly described [6].
Using microarrays, we showed for the first time on the U87 cell line, that GO (but not rGO and pG) down-regulates the genes responsible for OXPHOS. The differentially expressed genes detected in the presented experiments, after GO, rGO and pG treatment of GBM cells, are reported in Additional file 1 and Fig. 3. Figure 3 shows the identified genes for which the differential expression was confirmed via RT-qPCR analysis. Both experimental methods show that GO down-regulates the mRNA of OXPHOS nuclear genes of complexes I, III, IV and V.
Interestingly, our experiments did not detect any changes in the expression of the analyzed genes after rGO and pG treatment. We assume that the observed impact of GO on gene expression is the result of its unique chemo-physical properties. Compared to rGO and pG, GO is hydrophilic and possesses reactive COOH and OH groups, which facilitates its connection to DNA [1, 19, 31]. The anticancer activity of rGO and pG observed in other studies [14, 15] could be the result of different cytotoxic mechanisms. In contrast to GO, rGO and pG forms remain surrounded by the active and conductive delocalized electrons, which may inhibit cell viability via ROS generation and/or affect membrane integrity [32, 33]. Moreover, hydrophobic rGO shows lower water solubility than GO and frequently aggregates in salt-containing physiological buffers due to its different electrostatic charge [30]. rGO commonly forms nonspecific bindings to proteins and lipids. Strong hydrophobic interactions of rGO with the cell membrane lipids might result in its accumulation, which may eventually lead to cell membrane damages. Surface modifications of graphene (like addition of oxygen groups) improve its solubility in water. GO does not affect cell membranes as effectively as rGO, so it remains longer within the cells and consequently it may impact the cell molecular mechanisms [30]. Nevertheless, the cytotoxic activity mechanisms for rGO and pG need to be evaluated; however, it was not the primary interest of the presented study.
The function of electron transport chain Complex I is to remove electrons from NADH and transfer them to ubiquinone. It is one of the main sites of ROS production [34]. Among the other differentially regulated genes revealed in the microarray analysis, RT-qPCR confirmed that GO modulates expression of the following genes: NDUFA1, NDUFB3 and NDUFS4. The proteins encoded by those genes were described as critical for complex I functioning [35]. Decreased Complex I activity may reduce cancer growth and induce cell death via oxidative stress [36].
Complex III is involved in the GBM development and mediates resistance to drugs for glioma [37, 38]. Transcripts of UQCR11 and UQCRQ, the down-regulation of which was verified in our study via RT-qPCR, were also described to be regulated in carcinoma [39, 40]. Mutations of genes involved in complex III and IV activity were shown to be associated with glioblastoma growth [38]. Moreover, increased cytochrome c oxidase (Complex IV) activity was associated with the acquisition of chemoresistance in GBM [41]. Our RT-qPCR analysis confirmed that mRNAs of COX7B and COX17 genes, which protein products participate in Complex IV, were down-regulated Interestingly COX17 was proposed as the therapeutic target in lung cancer [42], while COX7B was shown to be overexpressed in carcinoma and its expression was decreased by anti-tumor agents in the glioblastoma treatment [43]. Complex V functions as an ATP synthase. ATP5E transcript that was identified as down-regulated in our experiment was proposed as the tumor marker in thyroid cancer [44].
We hypothesized that the significant changes in gene expression might notably affect the tumor development and OXPHOS activity. Our results, presenting down-regulation of OXPHOS mRNA expression correspond with the protein level changes reported by Zhou et al. [21]. The authors showed decreased protein level in the mitochondrial electron transfer chain complexes in breast cancer cells exposed to GO via quantitative proteomic analysis. Interestingly, they showed that GO treatment increased COX17 protein level, while we found down-regulation of COX17 mRNA. Unfortunately, the publication did not include the data of other proteins encoded by genes with deregulated mRNAs detected in our study. Most of the other genes presented in the abovementioned study were down-regulated. It was presented that the proteins of the subunits comprising every complex were also therefore down-regulated. Also, in another work [20], it was shown that graphene oxide inhibits the activity of electron transport complexes I, III and IV in a dose-dependent manner. Similarly, we found that GO inhibits the expression of genes encoding proteins belonging to the same OXPHOS complexes. It was concluded [20] that the activity of the electron transport chain proteins was decreased as the nanographene affected the iron sulfur centers of the complexes. Our research indicates that the activity of OXPHOS may also be decreased via the down-regulation of nuclear genes.
Deregulation of cellular energy metabolism is necessary to effectively support neoplastic proliferation (reviewed [45]). It was described that some of the cancer cells meet their energy demands mostly by glycolysis followed by lactic acid fermentation, as opposed to typical cells, which preferentially use mitochondrial oxidative phosphorylation. This phenomenon is known as a Warburg effect [46]. Nevertheless, both, the mentioned mechanism and a high ATP level are required for the growth of cancer [21]. GO significantly decreased the proliferation of MDA-MB-231, MDA-MB-436 and SK-BR-3 breast cancer cells via the down-regulation of OXPHOS activity without any changes in glycolysis [21]. Decreased OXPHOS activity inhibits the migratory and invasive characteristics of cancer [21].
Moreover, the growing GBM is composed of different subpopulations of cells and the population of cancer stem cells (CSC) seems to be crucial for tumor initiation and self-renewal [47, 48]. Independent of the glycolysis and differently from differentiated tumor cells, CSC activity fully depends on OXPHOS [48, 49]. Therefore, the inhibition of OXPHOS in GBM may suppress tumor expansion via the disruption of CSC functioning [48].
Disrupted OXPHOS significantly reduces ATP production and cytoskeletal function, which consequently affects the migratory and invasive activity of cancer [20]. Decreased energy production in cancer cells impairs their metastasis potential. Migration of the cells is the result of the lamellipodia or filopodia movement, which is regulated by the cytoskeleton [20, 50]. It was also shown that GO disrupts F-actin cytoskeletal functioning [20, 21]. In vivo experiments in mice revealed that GO inhibits the migration of metastatic cancer nodules [21]. Our results provide further support for the hypothesis that the suppressed growth of GBM can be the result of down-regulation of OXPHOS protein expression and decreased ATP levels. Such growth suppression may inhibit cancer migration and metastasis.
We also propose that down-regulation of the expression of nuclear genes encoding mitochondrial proteins may be a result of the mitochondrial dysfunction caused by GO. We previously reported that chicken embryo cells treated with different types of graphene possessed disrupted mitochondria [16] and GBM cells grown in ovo and treated with GO and rGO had degraded mitochondria [15]. Furthermore, mitochondrial fluorescence was quenched by graphene, suggesting that graphene nanoparticles were located inside and around the mitochondria of cancer cells [18]. The overproduction of ROS by the mitochondrial electron transport chain may be one of the mechanisms of GO mediated mitochondria disruption. It was suggested [51] that ROS can be involved in the toxic effects of graphene-based nanomaterials. The other researchers indicated that plasma membrane damage and oxidative stress are the key factors in graphene-induced cytotoxicity of HepG2 cells [52]. In murine macrophages, GO-induced cytotoxicity through depletion of the mitochondrial membrane potential, increasing the production of intracellular ROS and triggering apoptosis [53]. Interestingly, mitochondrial dysfunction and altered dynamics (processes of fusion and fission) were shown to regulate migration and invasion of the cancer cells [54]. Importantly, it was shown that dysfunctional mitochondria can regulate nuclear gene expression (reviewed [55]). Gene expression changes can be induced by iron-sulfur cluster (ISC) biogenesis, which is altered in dysfunctional mitochondria [56]. Based on previous studies and our present research, we speculate that GO affects mitochondrial function of cancer cells, not only via a previously proposed direct impact on ROS generation, but also via modulation of expression of the genes involved in mitochondrial activity.
Conclusions
We demonstrated that GO treatment caused changes in the mRNA expression of genes involved in OXPHOS in GBM cells, while pG and rGO had no effect. We suggest that changes in the expression of OXPHOS genes identified in our study comprise an interesting candidate mechanism which explains the anti-proliferative and anti-migratory effects of GO in GBM cells. Further studies of tumor proliferation, protein expression panel and the effects of knock-out of genes identified in current study, are still necessary to further evaluate the presented hypothesis.
Methods
Nanoparticles
pG powder, produced by liquid-phase exfoliation of graphite, was purchased from Skyspring Nanomaterials (Huston, TX, USA). GO and rGO were obtained from the Institute of Electronic Materials Technology (Warsaw, Poland). GO was prepared by a modified Hummers method from natural graphite flakes (Asbury Carbon). The Zeta potential of pG, GO and rGO suspended in milli-Q water was measured on a Zetasizer Nano-ZS90 (Malvern Instruments, Worcestershire, UK). For details of graphene powder preparations cf. [16].
AFM graphene oxide structure analysis
200 µl of graphene oxide suspension was placed on the silicic substrate, previously polished and cleaned in the preparation for atomic force microscope (AFM) measurement. The samples were dried in an exicator for 24 h. Afterwards the surface topography of the prepared samples was analyzed in the AFM measurement system (Nanosurf FLEX-Axiom). The scan sizes areas were analyzed in the range of 5 × 5 to 20 × 20 µm. The measurements were conducted in the tapping mode. The time of line scanning and amplitude of oscillation were matched properly for each analyzed sample.
Cell culture and treatment
Human glioblastoma cell line U87 was purchased from the American Type Culture Collection (Manassas, VA, USA). The cells were maintained in Dulbecco’s modified Eagle’s culture medium containing 10% fetal bovine serum (Life Technologies, Houston, TX, USA), 1% penicillin and streptomycin (Life Technologies) at 37 °C in a humidified atmosphere of 5% CO2/95% air in a DH AutoFlow CO2 Air-Jacketed Incubator (NuAire, Plymouth, MN, USA). 0.01 g of graphene (pG, GO or rGO) powder was dissolved in 10 mL of milli-Q water to obtain concentration of 1000 ppm. Then, the prepared stocks of graphene were added to Dulbecco’s Modified Eagle’s culture Medium to obtain the concentration of 25 ppm of each type of graphene. U-87 MG glioblastoma cells were seeded in 75 cm2 culture flasks (1 × 106 cells per flask) and incubated to reach 70% confluency. Then, the cells were washed by phosphate-buffered saline (Sigma-Aldrich) and subsequently Modified Eagle’s culture Medium with addition of graphene was added into each flask. After 24 h, cells were disassociated by 0.25% trypsin with EDTA, harvested and suspended in fresh DMEM medium. Then the cells were centrifuged at 1200 rpm for 5 min, washed with phosphate buffered saline and centrifuged to obtain a pellet. The cells were suspended in RNA later (Thermo Fisher Scientific, USA) and stored at 4 °C for the analysis. For the control, the cells were cultured in the Dulbecco’s modified Eagle’s culture medium containing 10% fetal bovine serum (Life Technologies, Houston, TX, USA) without the addition of graphene.
RNA isolation
Total RNA was isolated from 1 × 106 cells using Blood/Cell RNA Mini Kit (Syngen, Wroclaw, Poland) according to the manufacturer’s instructions. To remove potential traces of genomic DNA, the extracted RNA samples were treated with a TURBO DNA-free™ Kit (Ambion, Austin, TX, USA) for 30 min at 37 °C. RNA concentration was quantified by UV absorption (Nanodrop, LabTech International, UK) and RNA quality was assessed using an Agilent 2100 Bioanalyzer© and RNA 6000 Nano Kit (Agilent, Santa Clara, CA, USA). For all RNA samples, the RIN (RNA integrity number) value was above 8, ensuring the high quality of isolated RNA.
Microarray analysis
Gene expression profiles were determined using GeneChip® Human Gene 1.0 ST arrays (Affymetrix, Santa Clara, CA, USA) according to the manufacturer’s protocols. Briefly, 100 ng of total RNA per sample was reverse-transcribed, amplified, fragmented, and labeled using the Ambion® WT Expression Kit and Affymetrix GeneChip® WT Terminal Labeling Kit with included quality controls. Hybridization to the microarrays was conducted for 17 h at 45 °C in an Affymetrix GeneChip Hybridization Oven 640. Following hybridization, the microarrays were washed and stained on an Affymetrix GeneChip Fluidics Station 450 and scanned on an Affymetrix GCS 3000 GeneArray Scanner.
Quality analyses were performed using the Affymetrix Expression Console™ Software and standard Affymetrix quality metrics. Raw microarray data were background corrected, log transformed, and quantile normalized using the robust multi-array average (RMA) algorithm as implemented in the Partek® Genomics Suite™ software (Partek Inc., St. Louis, MO, USA). The statistical significance of the results was estimated by analysis of variance (ANOVA). Differentially expressed genes were identified using the fold change (FC) of gene expression ratios > 1.5 and P value< 0.05 corrected for false discovery rate (FDR) as significance criteria.
Validation of mRNA levels by RT-qPCR
To validate the microarray results, the expression levels of 10 selected genes in the cultured cells treated with GO (compared with cultured cells treated with buffer) were quantified by real-time reverse transcription-polymerase chain reaction (RT-qPCR). cDNA was synthesized from 400 ng of total RNA using the QuantiTect Reverse Transcription kit (Qiagen, Hilden, Germany) according to the manufacturer’s protocol. Amplification primers were designed using the Clone Manager Suite (Sci-Ed Software, Morrisville, USA). RT-qPCR assays were carried out using the LightCycler®480 and LightCycler®480 FastStart SYBR Green I Master (Roche Diagnostics GmbH, Germany). All assays were run in triplicate. Quantification cycles (Cq) were calculated using the second derivative method (LightCycler®480 Software, Roche). The fold change in gene expression levels, corrected by efficiency, was analyzed using Relative Expression Software Tool (REST 2009) (Qiagen; [57]). The expression data were normalized to the polymerase (RNA) II (DNA directed) polypeptide A (POLR2A) and ribosomal protein L29 (RPL29) genes, which in a RefFinder algorithm-based selection were the most stable among the 4 candidate reference genes tested. All experiments were performed according to the MIQE guidelines [58].
Enrichment analysis
The list containing names of genes, the expression of which was regulated in GBM cells by GO treatment, was annotated with overrepresented (enriched) biological terms using the Enrichr tool (http://amp.pharm.mssm.edu/Enrichr/) [26]. Such terms include: (1) ontologies, which are defined groups of biological entities, such as “biological processes” or “molecular functions”; (2) transcriptional regulators, which are molecules crucial for modulating gene expression; (3) biochemical pathways; and (4) hub proteins, which interact with large numbers of molecular partners. Enrichr calculates P-values of enrichment using Fisher’s Exact Test. Only terms showing the statistical significance of enrichment of at least P = 0.05, after adjustment for multiple testing (Benjamini–Hochberg method), were considered to be genuinely enriched and were included in the results. The enrichment method for analysis of transcriptomic data is resistant to potential false positive findings, inevitably resulting from large scale microarray studies.
Additional files
Authors’ contributions
MS, ES and AC conceived and designed the experiments; MS, AS, KU, BB, MG and MGr performed the experiments; SJ, AC, MK and MW analyzed the data; MGr and ES guided the experiments and data analysis; MS and AC wrote the manuscript. All authors read and approved the final manuscript.
Acknowledgements
This report is a part of Maciej Szmidt habilitation thesis.
Competing interests
The authors declare that they have no competing interests.
Availability of data
All data is included in the article and additional files.
Consent to publish
Not applicable.
Ethics approval and consent to participate
Not applicable.
Funding
This work was supported by the Grant NCN OPUS 2011/03/B/NZ9/03387 and the KNOW (Leading National Research Centre) Scientific Consortium “Healthy Animal - Safe Food”, decision of Ministry of Science and Higher Education No. 05-1/KNOW2/2015.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abbreviations
- GBM
glioblastoma multiforme
- RT-qPCR
real-time reverse transcription polymerase chain reaction
- OXPHOS
mitochondrial oxidative phosphorylation
- GO
graphene oxide
- rGO
reduced graphene oxide
- pG
pristine grapheme
- ROS
reactive oxygen species
- CSC
cancer stem cells
Contributor Information
Maciej Szmidt, Email: maciej.szmidt@acurian.com.
Adrian Stankiewicz, Email: adrianstankiewicz85@gmail.com.
Kaja Urbańska, Email: kaja_urbanska@sggw.pl.
Sławomir Jaworski, Email: jaworski.slawek@gmail.com.
Marta Kutwin, Email: marta_kutwin@sggw.pl.
Mateusz Wierzbicki, Email: mateusz_wierzbicki@sggw.pl.
Marta Grodzik, Email: marta_grodzik@sggw.pl.
Beata Burzyńska, Email: atka@ibb.waw.pl.
Monika Góra, Email: mgora@ibb.waw.pl.
André Chwalibog, Email: ach@sund.ku.dk.
Ewa Sawosz, Email: ewa_sawosz@sggw.pl.
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