Abstract
In vitro cell cultures are frequently used to define the molecular background of drug resistance. The majority of currently available data have been obtained from 2D in vitro cultures, however, 3D cell culture systems (spheroids) are more likely to behave similarly to in vivo conditions. Our major aim was to compare the gene expression signature of 2D and 3D cultured BRAFV600E mutant melanoma cell lines. We successfully developed BRAF-drug resistant cell lines from paired primary/metastatic melanoma cell lines in both 2D and 3D in vitro cultures. Using Affymetrix Human Gene 1.0 ST arrays, we determined the gene expression pattern of all cell lines. Our analysis revealed 1049 genes (562 upregulated and 487 downregulated) that were differentially expressed between drug-sensitive cells grown under different cell cultures. Pathway analysis showed that the differently expressed genes were mainly associated with the cell cycle, p53, and other cancer-related pathways. The number of upregulated genes (72 genes) was remarkably fewer when comparing the resistant adherent cells to cells that grow in 3D, and were associated with cell adhesion molecules and IGF1R signalling. Only 1% of the upregulated and 5.6% of the downregulated genes were commonly altered between the sensitive and the resistant spheroids. Interestingly, we found several genes (BNIP3, RING1 and ABHD4) with inverse expression signature between sensitive and resistant spheroids, which are involved in anoikis resistance and cell cycle regulation. In summary, our study highlights gene expression alterations that might help to understand the development of acquired resistance in melanoma cells in tumour tissue.
Similar content being viewed by others
Introduction
Melanoma is the most serious type of skin cancer, which develops from pigment-producing cells known as melanocytes [1]. Approximately 40–60% of melanomas harbour an activating mutation in the BRAF oncogene. The most common mutation is a substitution of valine to glutamic acid (V600E) that became one of the most successful therapeutic targets of metastatic melanomas [2]. Pre-clinical and clinical studies show that targeting BRAF using RAF-selective inhibitors results in remarkable tumour shrinkage in BRAFV600E mutant melanomas; however, many of the treated patients exhibit therapy resistance due to the highly heterogeneous tumour profile [3]. Molecular mechanisms associated with BRAF inhibitor (BRAFi) resistance have shown that signal transduction pathways, such as the IGF1R/PI3K/AKT and MAPK are over-activated when the RAS/RAF/MAPK/ERK pathway is blocked by BRAFi. Combined treatment targeting the MAPK and PI3K pathways is a promising strategy to overcome BRAFi resistance in BARF mutated tumours. Combining MAPK and PI3K signaling pathway inhibitors is effective treatment of advanced stage and metastatic melanoma [4]. Studies have highlighted that overexpression of different proteins including EGFR, CRAF, N-RAS, cyclin D1 and FGF Receptor 3 also contribute to BRAFi resistance [5]. It was just recently described that long-term vemurafenib treatment in BRAF-mutant melanoma cells can lead to increased migration in association with elevated EGFR expression [6]. Molnar et al. found that high levels of EGFR are associated with a lower sensitivity against BRAF- and EGFR inhibitors and cells with high EGFR expression show significantly lower sensitivity to vemurafenib treatment and represents higher Erk activation [6]. By using preclinical model, it was proven that EGFR inhibition enhanced the antitumor effect of vemurafenib in BRAF-mutant human melanoma [7]. Beside different genetic alterations, BRAF and MITF amplifications as well as PTEN loss are also responsible for resistance to targeted therapies [8]. Amplification of MITF was found in BRAF/MEK inhibitor resistant tumours [9], which is probably associated with growth advantage when the MAPK pathway is inhibited [10].
Cell culture is a widely used in vitro tool to gain insight into cellular events [11]. The traditionally used 2D cell cultures have several limitations if we compare them to the 3D tumour tissues, including differences in cellular communication, cell morphology, cell and extracellular medium interactions that are responsible for differentiation, proliferation, gene and protein expression, responsiveness to stimuli, drug metabolism and other cellular functions. Therefore, the 2D cell culture conditions do not accurately reflect the natural structure of tissue [12]. Several studies have also suggested that adherent cell culturing changes the gene expression pattern due to unlimited access to oxygen, nutrients, metabolites and signalling molecules [13, 14].
3D spheroid culture is an improved cellular model that offers more contact space for mechanical inputs for cell adhesion, accurate atmosphere for cell migration, differentiation, survival, and growth, variable access to oxygen, nutrients, metabolites, and signalling molecules [15]. The presence of different cell types, including proliferative and necrotic cell populations, reflects the heterogeneity of tumour tissues [16]. Spheroid cell culture also reflects growth kinetics, metabolic activity and resistance to radiotherapy and chemotherapy that is more similar to tumour cells in vivo [17]. Extended cell to cell, cell to extracellular fluid interaction also alters gene expression patterns that play a crucial role in proliferation, angiogenesis, migration, invasion and drug response due to limited access to nutrients, oxygen, and waste products into and out of the compact spheroids. This results in a more compact composition of spheroids, consisting of proliferating cells, followed by quiescent cells in the middle and necrotic cells in the centre of the spheroid [18]. Three-dimensional cultures show a reduction in proliferation and increase in Beta4 and Beta1 integrin’s that are markers for cell polarization and differentiation [19].
The gene expression pattern of 3D spheroid is more comparable to in vivo solid tumours than cells cultured in monolayer [15]. Overexpressed genes are involved in cancer progression, invasion and metastasis development in other types of cancer cells including colorectal cancer and hepatocellular carcinoma besides melanoma [20]. Moreover, upregulation of metabolic, stress-response, structural, signal transduction, and cellular transport proteins in spheroids compared to 2D cultured cells have been described before [21]. Several studies described that 3D cultured cells were more resistant against an anti-cancer drug (5-FU) than 2D cultured cells due to less drug penetration into the centre cell mass (quiescent cells) and since the drug especially targets only the outer, proliferating cells [15]. On the other hand, Tirapazamine (TPZ) was more effective in spheroids than 2D cultures, likely because TPZ is more potent in during oxygen consumption [22]. It was described that structural modifications of the architecture of tumour cell cultures result in a significant upregulation of the expression of a number of genes previously shown to play a role in melanoma progression and metastatic process [18]. Three dimensional in vitro tumour models could enhance drug manufacturer’s capability to develop more effective drugs for cancer treatment [23].
The aim of our study was to develop reproducible three-dimensional melanoma spheroid models from BRAFV600E mutant melanoma cell lines that are sensitive and resistant to a BRAF inhibitor (BRAFi). Concurrently, we aimed to compare the gene expression signature of the 2D and 3D melanoma cell lines in both sensitive and resistant model systems. We successfully generated spheroids form BRAFV600E mutant BRAFi sensitive primary WM983A and metastatic WM983B cell lines originated from the same patient. Resistant cell lines were established through long-term, high dose vemurafenib analog PLX4720 inhibitor treatment.
Material and Methods
Cell Culture
2D Cell Culture
Melanoma cell lines (WM983A and WM983B) were obtained from the Coriell Institute for Medical Research (Camden, New Jersey, USA). Cell lines were cultured in RPMI-1640 growth medium (Lonza Group Ltd., Basel, Switzerland) and supplemented with 10% foetal bovine serum (FBS from Gibco, Carlsbad, California, USA), 2 mmol/l glutamine and 50 mg/ml penicillin and streptomycin. Cell cultures was maintained at 37 °C under 5% CO2 atmosphere. Both cell lines harbour the BRAFV600E mutation and are wild type for NRAS. The clinicopathological characteristics of the cell lines are summarized in Table 1.
Establishment of BRAF Inhibitor Resistant Cell Lines
Resistant cell lines were established as described before, by continuously increasing the concentration of Vemurafenib analogue PLX4720 with every passage for 3 months [24]. In brief, WM983A, WM983B cell lines were seeded at low densities in T25 flasks until cell confluence reached about 80%. Then, the cells were switched to medium containing 5 μM PLX4720 and cultured. The surviving cells were given medium containing PLX4720 every 3 days until they reached 80% confluence (~10 weeks). The resistant cell lines were designated as WM983ARES and WM983BRES.
3D Cell Culture
Spheroid cultures were established by seeding 1.8 × 104 cells/well into Corning® Costar® Ultra-Low Attachment 6 well plates containing RPMI-1640 supplemented with 2 mmol/l glutamine and 50 mg/ml penicillin and streptomycin. After 72 h the medium was complemented with 10%, FBS and the spheroids were grown for a week in complete medium. The visible spheroids were transferred into a cell culture flask and leaved to attach (~ 6 h). After attachment, the spheroids were washed, cell debris were removed by 1XPBS. Spheroids were assigned as WM983ASPH, WM983BSPH, WM983ARES-SPH and WM983BRES-SPH.
RNA Isolation and Microarray Hybridization
Total RNA were extracted by using RNeasy Mini Kit (Qiagen GmbH, Hilden, Germany) according to the manufacturer’s instructions. RNA quantity and concentration were determined by using a Nano Drop ND-1000 UV Vis spectrophotometer. Only RNA samples with 260/280 nm ratio greater than 1.8 were used for further analysis. RNA quality was determined using an Agilent 2100 Bioanalyzer (Agilent Technologies Inc., Santa Clara, California, USA). RNA integrity were evaluated by RNA Integrity Number and samples with high integrity number (RNA integrity number > 7.5) were included for Affymetrix Human Gene 1.0 microarrays (Affymetrix Inc., Santa Clara, California, USA). Labelling, hybridization, and imaging setup were performed by UD-GenoMed Medical Genomic Technologies Ltd. (Clinical Genomic Center, University of Debrecen, Debrecen, Hungary) using 500 ng of sample RNA.
Gene Expression Analysis
Analysis of gene expression microarray data were carried out as described previously [25]. After background correction, log2 transformation and normalization, intensity data were inserted to Bioconductor BRB-Array Tools 4.6.0 Richard Simon and Amy Peng Lam (National Cancer Institute, Bethesda, USA). After normalization, quality control, and filtering steps of the data, 9653 genes were used in further analyses. To reveal the differentially expressed genes between cells growing in 2D and 3D, paired t-tests with a random variance model were applied, considering a P value 0.01 or less to be statistically significant. The microarray data were deposited in the Gene Expression Omnibus (GEO) repository (http://www.ncbi.nlm.nih.gov/gds) under accession under accession numbers GSE114443 and GSE148638. The filtering and normalization were performed as previously described [25].
Pathway Analysis
To identify significant pathways that are associated with specific gene expression patterns, we used web-based application EnrichR (http://amp.pharm.mssm.edu/Enrichr/#). Only significantly altered signalling pathway (p < 0.05) were included, applying FDR < 0.05 (Benjamini Hochberg adjusted) as a cut-off and considered pathways presented with at least 5 genes.
Real Time Quantitative PCR
Relative expression of commonly altered genes were determined by performing real-time PCR (qRT-PCR) by using a Light Cycler 480 Real-Time PCR System (Roche Diagnostics GmbH, Mannheim, Germany). Reverse transcription of the total RNA (600 ng) was performed by using a High Capacity cDNA Archive Kit (Applied Bio-systems, Foster City, California, USA). SYBR Premix Ex Taq (Takara Holding Inc., Kyoto, Japan) were used to perform qRT-PCR. Raw PCR data were analysed using the Livak method (2-ΔΔCt) with glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as an internal control gene and cultured melanocyte or pooled nevi (n = 8) as the calibrator sample [26]. The primer sequences are listed in Supplementary Table 1. We used these primers to validate the microarray data for the selected genes and to analyse transcript levels for genes with significant changed in different direction.
Statistical Analysis
Statistical analyses were performed using SPSS 19.0 (SPSS Inc., Chicago, Illinois, USA). Pearson’s correlation coefficient was calculated to correlate the microarray and qPCR data. Only P values less than 0.05 were considered statistically significant. All included data were the average of at least three independent experiments with ± standard deviation.
Results
Gene Expression Profiles of BRAFi Sensitive and BRAFi Resistant Melanoma Cell Lines Cultured under 2D and in 3D Conditions
First, we analysed the gene expression profiles of the adherent WM983A and WM983B cell lines and their corresponding spheroids using Affymetrix Human gene 1.0 ST array. The gene expression patterns of the adherent cells were compared to the spheroids (WM98ASPH and WM983BSPH). Figure 1. clearly shows the gene expression differences between the sensitive and resistant cell lines grown under different cell culture conditions.
Unsupervised hierarchical clustering of genes that were differentially expressed in BRAFi sensitive and resistant melanoma cell lines cultured under 2D and 3D conditions. (A) Hierarchical cluster analysis was performed on 1049 genes that were differently expressed in BRAFi sensitive adherent cells (WM983A and WM983B) and spheroids (WM983ASPH and WM983BSPH). (B) Hierarchical cluster analysis of 297 significantly altered genes in BRAFi resistant spheroids (WM983ASPH-RES and WM983BSPH-RES) compared to the resistant 2D cultured cells (WM983RES and WM983BRES). Cell lines are displayed vertically and genes displayed horizontally. The colour of each cell represents the median-adjusted expression value of each gene. Red colour indicates increased expression and green colour represents decreased expression
Figure 1a displays the result of hierarchical clustering of 1049 genes that were differently expressed between the 2D and 3D cultured BRAFi sensitive cells. The list of genes are summarized in Supplementary Table 2. Among the differentially expressed genes, 562 were upregulated and 487 were downregulated in the spheroids compared to the adherent cell lines.
In addition, we used pathway analysis to determine the functional association of all of the 1049 differently expressed genes in the BRAFi sensitive cells. A summary of the upregulated genes (n = 562) is listed in Supplementary Table 3. Based on the pathway analysis, upregulated genes are involved mainly in cell cycle regulation, G2/M checkpoints, DNA replication, the p53 signalling pathway, Rho GTP-ase signalling, DNA repair, and other cancer-related pathways (Fig. 2.). The list of the downregulated genes (n = 487) is presented in Supplementary Table 4. Downregulated genes were associated with cellular responses to external stimuli and stress, TP53 regulated transcription of cell death and other cancer related pathways (Fig. 3). The functional involvement of differently expressed genes was validated by using the Database for Annotation, Visualization and Integrated Discovery (DAVID).
Pathway analysis of the significantly upregulated genes (n = 562) in sensitive melanoma spheroid cells compared to the sensitive adherent cells. Altered molecular pathways with at least five observations are shown for the selected gene subset
Pathway analysis of the significantly downregulated genes (n = 487) in sensitive melanoma spheroid cells compared to the sensitive adherent cells. Altered molecular pathways with at least five observations are shown for the selected gene subset
Gene expression analysis of BRAFi resistant adherent melanoma cell lines (WM983ARES and WM983BRES) and their corresponding spheroids (WM983ARES-SPH and WM983BRES-SPH) revealed 297 significantly altered genes. Figure 1b shows the results of the unsupervised hierarchical cluster analysis of the resistant cell lines that were cultured under different conditions (2D and 3D). Based on the analysis 72 genes were upregulated and 225 were downregulated in the resistant spheroids compared to resistant adherent cell lines. Pathway analysis of the differentially downregulated genes (n = 225) revealed that the genes are mainly involved in cellular and mitochondrial translation, ROBO receptor signalling, axon guidance, G2/M checkpoints and other cancer related pathways (Fig. 4). Upregulated genes in the resistant spheroids were not significantly enriched in any pathway according to our criteria.
Pathway analysis of the significantly downregulated genes (n = 225) in resistant melanoma spheroid cells compared to the resistant adherent cells. Altered molecular pathways with at least five observations are shown for the selected gene subset
Comparative Analysis of the Gene Expression Signature of the Sensitive and Resistant Cell Lines
To define the gene expression similarities and differences of the sensitive and resistant cell lines during spheroid formation, we compared the down- and upregulated genes of the WM983A and WM983B cell lines and defined the number of commonly and differently altered genes. As a result, we found a group of genes that were downregulated only in the sensitive (447 genes) and resistant (185 genes) spheroids, respectively. The number of upregulated genes in the BRAFi sensitive spheroids was 556, while 66 genes were found in the resistant spheroids (Fig. 5). Altogether 46 genes were commonly altered in both types of spheroids (Fig. 5). The list of the 46 genes are summarized in Supplementary Table 8. Most of the shared genes were downregulated (40 genes) including MMP16, IGF1R, FLOT1 and CEP19. The 6 commonly upregulated genes (HIST1H2BM, DDAH1, UCP2, MBD3L5, DEFB124 and MLF2) are involved in the Interleukin-2 signalling pathway and negative regulation of cell proliferation.
Comparison of upregulated genes in the BRAFi sensitive spheroids and resistant spheroids. Venn diagrams showing the number of genes differentially expressed by BRAFi resistant spheroids of melanoma cell lines (WM983ARES-SPH and WM983B RES-SPH, compared to respective sensitive spheroid (WM983ASPH and WM983B SPH). The diagram also shows the number of genes upregulated (6) and downregulated (40) in common between sensitive and resistant spheroid
We also defined the main gene expression differences between the sensitive and resistant spheroids. We observed that a small portion (10 genes) of all upregulated genes (712 genes) were downregulated in the resistant spheroids, but upregulated in the sensitive spheroids (Table 2). In contrast, SCN8A, RING1 and ABHD4 genes were downregulated in the sensitive spheroids and upregulated in the resistant spheroids. Some of the inversely expressed genes are involved in cell cycle (CENPF, LOXL2, BNIP3) and epigenetic (HIST1H2BB) regulation of gene expression.
Validation of Microarray Data
We performed qRT-PCR to confirm the gene expression alterations of eight genes (ABHD4, HIST1H2BB, SCN8A, CMSS1, DCUN1D1, IKBIP, SMC3 and ZNF639). Supplementary Table 7. summarizes the qRT-PCR data for all the sensitive and resistant cell lines. We compared the fold change levels that were obtained from Affymetrix microarray analysis with the qRT-PCR results, and found that five out of the eight genes tested (DCUN1D1, CMSS1, ZNF639, ABHD4, and HIST1H2BB) showed the same direction of gene expression in the sensitive- and in the resistant spheroids. In addition, strong correlation was observed between the Affymetrix array and qRT-PCR data in case of the ABHD4 and SCN8A genes (R > 0.7; P value <0.05).
Discussion
Three dimensional cell culturing, especially multicellular spheroids, has been gaining interest in molecular biology in the past decades to mimic the structure of tumour tissues more effectively than 2D monolayer cell cultures [11, 12]. Several methods can be applied to generate multicellular spheroids; however, extensive manipulation leads to alterations in the original features [27]. Development of 3D models for in vitro anti-cancer drug testing can give new insights into cancer cell behaviour [28]. Recently pharmaceutical companies are highly interested in new in vitro cellular models to test potential drugs [29]. The relevance of using 3D-, in addition to monolayer cell cultures was evaluated for breast cancer drug sensitivity and resistance by Breslin et al., and they concluded that the biological information represented by 3D and 2D cell cultures is substantially different [30]. They described that 3D cell cultures demonstrate higher innate resistance to anti-cancer drugs compared to the adherent cell cultures. It was just recently reported by Ryabaya et al. [31] that binimetinib (MEK inhibitor) combined with metformin is a promising therapy against melanoma and described that this combination of drugs has a synergistic effect on melanoma cells. In addition, the combined treatment provides pronounced spheroid disruption in comparison with either drug alone. Several studies have reported specific, differently expressed genes involved in BRAF inhibitor resistance in melanoma cell lines, however most of these studies are based on monolayer cell cultures [32]. However, very few data are available about the gene expression differences between melanoma cells cultured as monolayer (2D) and spheroids (3D) [14]. No data were published yet about the gene expression differences between drug sensitive and resistant melanoma cells growing under different cell culture (2D and 3D) conditions.
Our study is the first to investigate the gene expression differences between BRAFi (PLX4720, a vemurafenib analogue) sensitive and resistant melanoma cell lines growing under adherent- and three dimensional (spheroid) cell culture conditions. After long term treatment, we successfully developed BRAFi sensitive and resistant spheroids from primary tumour (WM983A) and metastasis (WM983B) originated cell lines, and compared the gene expression patterns to the corresponding monolayer cell lines. Based on our data we found that the gene expression signature of the BRAFi sensitive and resistant spheroids are highly different compared to the gene expression of the sensitive adherent cells. The number of differently expressed genes were 1049 (562 upregulated and 487 downregulated). Among the top 10-upregulated genes in the sensitive 3D cultured cells, we found SPC25, CCL2, CCNE2 and PLK1. These genes have been identified previously to have functional roles in cell migration and metastasis formation and are all involved in cell cycle regulation through different pathways [33,34,35]. The top 10 downregulated genes are involved in different signalling pathways, such as the CHN2 gene in the regulation of RAC1 activity, the FOS gene in EGFR signalling and ITGA7 in integrin pathways and Akt signalling and in tumour initiation and progression [36,37,38].
When comparing the gene expression of BRAFi resistant spheroid cells to those growing in monolayer we found 297 differentially expressed (225 downregulated and 72 upregulated) genes. Pathway analysis of the downregulated genes showed that these genes are mainly involved in different translation pathways, ROBO receptor signalling, axon guidance, G2/M checkpoints and other cancer related pathways. Argast et al. has published previously that axon guidance genes are repressed by oncogenic B-Raf/MKK/ERK signalling in melanoma [39]. Genes of this signalling pathway were down-regulated in our resistant spheroids as well, including plexin B1 and semaphorin 3D genes, as well as R-RAS, known to mediate plexin-semaphorin signaling [39]. On the other hand a significant loss of the ROBO receptors was published in melanoma by Denk et al., and it is important to note that these receptors are best known for mediating axon guidance through attraction or repulsion of growth cones [40].
Differential expression analysis revealed a sets of genes that were differentially expressed in the resistant and sensitive spheroids. A group of genes were down- or upregulated only in the sensitive and resistant spheroids, respectively. Altogether 46 genes were commonly altered in both type of spheroids. Most of the shared genes (40 genes) were downregulated including MMP16, IGF1R, FLOT1 and CEP19 and are functionally involved in several types of cancers, including melanoma [39,40,41]. The 6 commonly upregulated genes (HIST1H2BM, DDAH1, UCP2, MBD3L5, DEFB124 and MLF2) have roles in interleukin-2 signalling pathway and negative regulation of cell proliferation.
We also defined the main gene expression differences between the sensitive and resistant spheroids. We observed that a small portion (10 genes) of all the upregulated genes (712 genes) were downregulated in the resistant spheroids, but upregulated in the sensitive spheroids (Table 2). In contrast, SCN8A, RING1 and ABHD4 genes were downregulated in the sensitive spheroids and upregulated in the resistant spheroids. Some of the inversely expressed genes are involved in the cell cycle (CENPF, LOXL2, BNIP3) and epigenetic (HIST1H2BB) regulation of gene expression. Dave et al. has described that myeloid leukemia factor 2 (MLF2) plays important an role in tumour initiation and metastasis in breast cancer [41]. Changes in expression of uncoupling protein 2 (UCP2) are tightly related to changes in cell proliferation, and that it plays a vital role in molecular events associated with carcinogenesis. Using either a genetic or pharmacological approach, induction of UCP2 sensitizes melanomas to programmed cell death protein-1 blockade treatment and elicits effective anti-tumour responses [42]. Based on the published data approximately 80% of melanoma cell lines show overexpressed DDAH-1 that represent a potential target for control of nitric oxide production in melanoma cell line [43]. On the other hand suppression of S-phase histone HIST1H2BB can improve treatment outcome in melanoma cells [44]. In contrast, genes that were commonly downregulated in sensitive and resistant melanoma spheroids, including MMP16, IGF1R and FLOT1, are associated with malignancy, and several studies have reported that these genes are related to the aggressive behaviour of melanoma [45, 46]. We assume that the commonly altered genes in the sensitive and resistant spheroids are essential in the formation of melanoma spheroids. In addition, beside the commonly expressed genes, our comparative study revealed differently altered genes as well. Alteration of the SCN8A gene (encoding type VIII alpha subunit of voltage gated sodium channel), which was down-regulated in the sensitive- and upregulated in the resistant spheroids, was described for several tumour types and it has been found that SCN8A gene expression level is significantly lower in tumour tissues compared to paired normal tissues [47]. Similarly, ring finger protein-1 (RING1) was also found as a differently expressed gene, which is involved in epigenetic regulation in cancer [48], where it acts as a transcriptional repressor and plays an important role in the development of aggressive phenotypes in melanoma [49]. Furthermore, upregulation of the ABHD4 gene was also common in resistant spheroids compared to sensitive ones. This gene was identified as a potential regulator of anoikis sensitivity that is one of primary events of tumour metastasis [50], highlighting that the resistant cell lines have an aggressive phenotype. Anoikis is a specific type of cell death (an endogenous death program), in which normal cells undergo apoptosis after they disconnect from the surrounding tissue cells and their extracellular matrix (ECM) [50]. Anoikis resistance is one of the hallmarks of cancer that enables tumour cells to survive in foreign environment to promote metastatic potential [51]. Interestingly, this mechanism is seems to be upregulated specifically in resistant spheroids, however, this observation requires further investigation.
On the other hand, a small cohort of genes (HIST1H2BB, CENPF, LOXL2, BNIP3, DCUN1D1, CMSS1, SMC3, ZNF639, IKBIP and IFT57) was upregulated in the sensitive spheroids, and downregulated in the resistant 3D cultures. Several of these genes are associated with tumour initiation and progression but not well documented at the field of melanoma, however, according to the results of this present study, they might have roles in BRAFi resistance. cBioPortal for Cancer Genomics database supports the idea that seventeen canonical histone H2B genes including HIST1H2B, HIST1H2BM has been found to be involved in cancer progression [44], however no direct role of the genes are described yet. Kim et al. reported that CENPF is functionally involved in the tumorigenesis of human cancers and cancer driver genes [52]. Lysyl oxidase-like 2 (LOXL2) plays a part in epithelial-mesenchymal transition by stabilizing the transcription factor SNAI1 and works as a tumour promoters in human melanoma cells by enhancing their invasive potential and several tumorigenic events including evasion of apoptosis, cell proliferation and has been found to be overexpressed in primary and metastatic melanoma and other human cancers, therefore it might have important role in vivo in the development of resistance [53]. Overexpression of hypoxia responsive protein BNIP3 in cancerous cells is highly controversial as it has been reported to be associated with promoting cell death, and it has tumour suppresser activity, however, it could also enhance aggressive behaviour of tumours such as cell migration [54, 55]. Ubiquitin-like ligase DCUN1D1 is involved in the malignant transformation of squamous cell lineage and has been identified as a potential cancer driver gene [56]. SMC3 gene expression has been reported in many cancers including acute myeloid leukaemia, bladder, and colorectal cancer [57]. The zinc-finger protein ZNF639 has been identified to be overexpressed in oesophageal squamous cell carcinomas [58]. Resisting cell death is one of the hallmarks of cancer that is associated with the IFT57 gene [59].
Development of acquired resistance after initial response leads to tumour regrowth [24]. Both genetic and epigenetic alterations are involved in the development of acquired resistance [2]. The identification of the molecular background of acquired resistance has been one of the major focuses of melanoma research in the past few years. Our study highlights important gene expression alterations that might help to understand the development of acquired resistance in melanoma cells.
Summary
Taken together, our data provide the first insight on differently expressed genes that might be involved in 3D spheroid formation in BRAFi sensitive and resistant melanoma cells. Generally, these results underline the molecular background of spheroid formation and highlight important molecular pathways that are different between 2D and 3D cell culture. We provide large-scale gene expression analysis data between the traditional 2D and 3D melanoma cell culture, as well as detailed analysis to clearly show gene expression differences between BRAFi sensitive- and resistant melanoma spheroids. The data presented here clearly shows the major differences of gene expressions between the traditional and 3D cell culture and these data might be useful to better understand the resistance profile of melanoma cells in tumour tissue. Although remarkable achievements have been made during the last decades, there a lot of questions that remain to be answered. Further studies and consistent results are needed to identify the responsible key pathway(s) associated with drug resistance in melanoma.
References
Bandarchi B, Jabbari CA, Vedadi A, Navab R (2013) Molecular biology of normal melanocytes and melanoma cells. J Clin Pathol 66(8):644–648
Davies H, Bignell GR, Cox C, Stephens P, Edkins S, Clegg S, Teague J, Woffendin H, Garnett MJ, Bottomley W, Davis N, Dicks E, Ewing R, Floyd Y, Gray K, Hall S, Hawes R, Hughes J, Kosmidou V, Menzies A, Mould C, Parker A, Stevens C, Watt S, Hooper S, Wilson R, Jayatilake H, Gusterson BA, Cooper C, Shipley J, Hargrave D, Pritchard-Jones K, Maitland N, Chenevix-Trench G, Riggins GJ, Bigner DD, Palmieri G, Cossu A, Flanagan A, Nicholson A, Ho JWC, Leung SY, Yuen ST, Weber BL, Seigler HF, Darrow TL, Paterson H, Marais R, Marshall CJ, Wooster R, Stratton MR, Futreal PA (2002) Mutations of the BRAF gene in human cancer. Nature 417(6892):949–954
Seghers AC, Wilgenhof S, Lebbé C, Neyns B (2012) Successful rechallenge in two patients with BRAF-V600-mutant melanoma who experienced previous progression during treatment with a selective BRAF inhibitor. Melanoma Res 22(6):466–472
Aasen SN, Parajuli H, Hoang T, Feng Z, Stokke K, Wang J, Roy K, Bjerkvig R, Knappskog S, Thorsen F (2019) Effective treatment of metastatic melanoma by combining MAPK and PI3K signaling pathway inhibitors. Int J Mol Sci 20(17):4235
Wang J, Huang SK, Marzese DM, Hsu SC, Kawas NP, Chong KK, Long GV, Menzies AM, Scolyer RA, Izraely S, Sagi-Assif O, Witz IP, Hoon DSB (2015) Epigenetic changes of EGFR have an important role in BRAF inhibitor-resistant cutaneous melanomas. J Invest Dermatol 135(2):532–541
Molnar E, Garay T, Donia M, Baranyi M, Rittler D, Berger W, Timar J, Grusch M, Hegedus B (2019) Long-term Vemurafenib exposure induced alterations of cell phenotypes in melanoma: increased cell migration and its association with EGFR expression. Int J Mol Sci 20(18):4484
Kenessey I, Kramer Z, Istvan L, Cserepes MT, Garay T, Hegedus B, Dobos J, Timar J, Tovari J (2018) Inhibition of epidermal growth factor receptor improves antitumor efficacy of vemurafenib in BRAF-mutant human melanoma in preclinical model. Melanoma Res 28(6):536–546
Timar J, Vizkeleti L, Doma V, Barbai T, Raso E (2016) Genetic progression of malignant melanoma. Cancer Metastasis Rev 35(1):93–107
Van Allen EM, Wagle N, Sucker A et al (2014) The genetic landscape of clinical resistance to RAF inhibition in metastatic melanoma. Cancer Discov 4(1):94–109
Kakadia S, Yarlagadda N, Awad R, Kundranda M, Niu J, Naraev B, Mina L, Dragovich T, Gimbel M, Mahmoud F (2018) Mechanisms of resistance to BRAF and MEK inhibitors and clinical update of US Food and Drug Administration-approved targeted therapy in advanced melanoma. Onco Targets Ther 11:7095–7107
Kapałczyńska M, Kolenda T, Przybyła W, Zajączkowska M, Teresiak A, Filas V, Ibbs M, Bliźniak R, Łuczewski Ł, Lamperska K (2018) 2D and 3D cell cultures - a comparison of different types of cancer cell cultures. Arch Med Sci 14(4):910–919
Antoni D, Burckel H, Josset E, Noel G (2015) Three-dimensional cell culture: a breakthrough in vivo. Int J Mol Sci 16(3):5517–5527
Birgersdotter A, Sandberg R, Ernberg I (2005) Gene expression perturbation in vitro-a growing case for three-dimensional (3D) culture systems. Semin Cancer Biol 15(5):405–412
Fontoura JC, Viezzer C, dos Santos FG, Ligabue RA, Weinlich R, Puga RD, Antonow D, Severino P, Bonorino C (2020) Comparison of 2D and 3D cell culture models for cell growth, gene expression and drug resistance. Mater Sci Eng C 107:110264
Ravi M (2017) Applications of three-dimensional cell cultures in the early stages of drug discovery, focusing on gene expressions, drug metabolism, and susceptibility. Crit Rev Eukaryot Gene Expr 27(1):53–62
Souza AG, Silva IBB, Campos-Fernandez E, Barcelos LS, Souza JB, Marangoni K, Goulart LR, Alonso-Goulart V (2018) Comparative assay of 2D and 3D cell culture models: proliferation, gene expression and anticancer drug response. Curr Pharm Des 24(15):1689–1694
Castiaux AD, Spence DM, Martin RS (2019) Review of 3D cell culture with analysis in microfluidic systems. Anal Methods 11(33):4220–4232
Ghosh S, Spagnoli GC, Martin I, Ploegert S, Demougin P, Heberer M, Reschner A (2005) Three-dimensional culture of melanoma cells profoundly affects gene expression profile: a high density oligonucleotide array study. J Cell Physiol 204(2):522–531
Duval K, Grover H, Han L-H, Mou Y, Pegoraro AF, Fredberg J, Chen Z (2017) Modeling physiological events in 2D vs. 3D cell culture. Physiology 32(4):266–277
Furney SJ, Higgins DG, Ouzounis CA, López-Bigas N (2006) Structural and functional properties of genes involved in human cancer. BMC Genomics 7(1):3
Kumar HR, Zhong X, Hoelz DJ, Rescorla FJ, Hickey RJ, Malkas LH, Sandoval JA (2008) Three-dimensional neuroblastoma cell culture: proteomic analysis between monolayer and multicellular tumor spheroids. Pediatr Surg Int 24(11):1229–1234
Tung YC, Hsiao AY, Allen SG, Torisawa YS, Ho M, Takayama S (2011) High-throughput 3D spheroid culture and drug testing using a 384 hanging drop array. Analyst 136(3):473–478
Brancato V, Oliveira JM, Correlo VM, Reis RL, Kundu SC (2020) Could 3D models of cancer enhance drug screening? Biomaterials 232:119744
Szász I, Koroknai V, Kiss T, Vízkeleti L, Ádány R, Balázs M (2019) Molecular alterations associated with acquired resistance to BRAFV600E targeted therapy in melanoma cells. Melanoma Res 29(4):390–400
Vizkeleti L, Kiss T, Koroknai V, Ecsedi S, Papp O, Szasz I, Adany R, Balazs M (2017) Altered integrin expression patterns shown by microarray in human cutaneous melanoma. Melanoma Res 27(3):180–188
Livak KJ, Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2-ΔΔCT method. Methods 25(4):402–408
Gencoglu MF, Barney LE, Hall CL, Brooks EA, Schwartz AD, Corbett DC, Stevens KR, Peyton SR (2018) Comparative study of multicellular tumor spheroid formation methods and implications for drug screening. ACS Biomater Sci Eng 4(2):410–420
Lee MA, Bergdorf KN, Phifer CJ, Jones CY, Byon SY, Sawyer LM, Bauer JA, Weiss VL (2019) Novel three dimensional cultures provide insights into thyroid cancer behavior. Endocr Relat Cancer 27(2):111–121
Ryan SL, Baird AM, Vaz G, Urquhart AJ, Senge M, Richard DJ, O'Byrne KJ, Davies AM (2016) Drug discovery approaches utilizing three-dimensional cell culture. Assay Drug Dev Technol 14(1):19–28
Breslin S, O'Driscoll L (2016) The relevance of using 3D cell cultures, in addition to 2D monolayer cultures, when evaluating breast cancer drug sensitivity and resistance. Oncotarget 7(29):45745–45756
Ryabaya O, Prokofieva A, Akasov R, Khochenkov D, Emelyanova M, Burov S, Markvicheva E, Inshakov A, Stepanova E (2019) Metformin increases antitumor activity of MEK inhibitor binimetinib in 2D and 3D models of human metastatic melanoma cells. Biomed Pharmacother 109:2548–2560
Ahn JH, Hwang SH, Cho HS, Lee M (2019) Differential gene expression common to acquired and intrinsic resistance to BRAF inhibitor revealed by RNA-seq analysis. Biomol Ther 27(3):302–310
Qiu T, Wang H, Wang Y, Zhang Y, Hui Q, Tao K (2015) Identification of genes associated with melanoma metastasis. Kaohsiung J Med Sci 31(11):553–561
Lim SY, Yuzhalin AE, Gordon-Weeks AN, Muschel RJ (2016) Targeting the CCL2-CCR2 signaling axis in cancer metastasis. Oncotarget 7(19):28697–28710
Schmit TL, Zhong W, Setaluri V, Spiegelman VS, Ahmad N (2009) Targeted depletion of polo-like kinase (Plk) 1 through lentiviral shrna or a small-molecule inhibitor causes mitotic catastrophe and induction of apoptosis in human melanoma cells. J Invest Dermatol 129(12):2843–2853
Kazanietz MG, Caloca MJ (2017) The Rac GTPase in Cancer: from old concepts to new paradigms. Cancer Res 77(20):5445–5451
Eckert RL, Adhikary G, Young CA, Jans R, Crish JF, Xu W, Rorke EA (2013) AP1 transcription factors in epidermal differentiation and skin Cancer. J Skin Cancer 2013:537028
Bhandari A, Xia E, Zhou Y, Guan Y, Xiang J, Kong L, Wang Y, Yang F, Wang O, Zhang X (2018) ITGA7 functions as a tumor suppressor and regulates migration and invasion in breast cancer. Cancer Manag Res 10:969–976
Argast GM, Croy CH, Couts KL, Zhang Z, Litman E, Chan DC, Ahn NG (2009) Plexin B1 is repressed by oncogenic B-Raf signaling and functions as a tumor suppressor in melanoma cells. Oncogene 28(30):2697–2709
Denk AE, Braig S, Schubert T, Boserhof AK (2011) Slit3 inhibits activator protein 1-mediated migration of malignant melanoma cells. Int J Mol Med 28(5):721–726
Dave B, Granados-Principal S, Zhu R, Benz S, Rabizadeh S, Soon-Shiong P, Yu KD, Shao Z, Li X, Gilcrease M, Lai Z, Chen Y, Huang THM, Shen H, Liu X, Ferrari M, Zhan M, Wong STC, Kumaraswami M, Mittal V, Chen X, Gross SS, Chang JC (2014) Targeting RPL39 and MLF2 reduces tumor initiation and metastasis in breast cancer by inhibiting nitric oxide synthase signaling. Proc Natl Acad Sci U S A 111(24):8838–8843
Cheng WC, Tsui YC, Ragusa S, Koelzer VH, Mina M, Franco F, Läubli H, Tschumi B, Speiser D, Romero P, Zippelius A, Petrova TV, Mertz K, Ciriello G, Ho PC (2019) Uncoupling protein 2 reprograms the tumor microenvironment to support the anti-tumor immune cycle. Nat Immunol 20(2):206–217
Wang Y, Hu S, Gabisi AM, Er JAV, Pope A, Burstein G, Schardon CL, Cardounel AJ, Ekmekcioglu S, Fast W (2014) Developing an irreversible inhibitor of human DDAH-1, an enzyme upregulated in melanoma. ChemMedChem 9(4):792–797
Arimura Y, Ikura M, Fujita R, Noda M, Kobayashi W, Horikoshi N, Sun J, Shi L, Kusakabe M, Harata M, Ohkawa Y, Tashiro S, Kimura H, Ikura T, Kurumizaka H (2018) Cancer-associated mutations of histones H2B, H3.1 and H2A.Z.1 affect the structure and stability of the nucleosome. Nucleic Acids Res 46(19):10007–10018
Xin H, Lei M, Zhang Z, Li J, Zhang H, Luo X, Wang A, Deng F (2018) Suppression of IGF1R in melanoma cells by an adenovirus-mediated one-step knockdown system. Mol Ther - Nucleic Acids 12:861–871
Eriksson J, Le Joncour V, Nummela P, Jahkola T, Virolainen S, Laakkonen P, Saksela O, Hölttä E (2016) Gene expression analyses of primary melanomas reveal CTHRC1 as an important player in melanoma progression. Oncotarget 7:15065–15092
Igci YZ, Bozgeyik E, Borazan E, Pala E, Suner A, Ulasli M, Gurses SA, Yumrutas O, Balik AA, Igci M (2015) Expression profiling of SCN8A and NDUFC2 genes in colorectal carcinoma. Exp Oncol 37(1):77–80
Huang JM, Hornyak TJ (2015) Polycomb group proteins - epigenetic repressors with emerging roles in melanocytes and melanoma. Pigment Cell Melanoma Res 28(3):330–339
Chen J, Peng C, Lei L, Zhang J, Zeng W, Chen X (2017) Nuclear envelope-distributed CD147 interacts with and inhibits the transcriptional function of RING1 and promotes melanoma cell motility. PLoS One 12(8):e0183689
Simpson CD, Hurren R, Kasimer D, MacLean N, Eberhard Y, Ketela T, Moffat J, Schimmer AD (2012) A genome wide shRNA screen identifies α/β hydrolase domain containing 4 (ABHD4) as a novel regulator of anoikis resistance. Apoptosis 17(7):666–678
Paoli P, Giannoni E, Chiarugi P (2013) Anoikis molecular pathways and its role in cancer progression. Biochim Biophys Acta 1833(12):3481–3498
Kruiswijk F, Hasenfuss SC, Sivapatham R, Baar MP, Putavet D, Naipal KAT, Van Den Broek NJF, Kruit W, Van Der Spek PJ, Van Gent DC, Brenkman AB, Campisi J, Burgering BMT, Hoeijmakers JHJ, De Keizer PLJ (2016) Targeted inhibition of metastatic melanoma through interference with Pin1-FOXM1 signaling. Oncogene 35(17):2166–2177
Abourbih DA, Di Cesare S, Orellana ME, Antecka E, Martins C, Petruccelli LA, Burnier MN (2010) Lysyl oxidase expression and inhibition in uveal melanoma. Melanoma Res 20(2):97–106
Romano E, Rufo N, Korf H, Mathieu C, Garg AD, Agostinis P (2018) BNIP3 modulates the interface between B16-F10 melanoma cells and immune cells. Oncotarget 9:17631–17644
Maes H, Van Eygen S, Krysko DV, Vandenabeele P, Nys K, Rillaerts K, Garg AD, Verfaillie T, Agostinis P (2014) BNIP3 supports melanoma cell migration and vasculogenic mimicry by orchestrating the actin cytoskeleton. Cell Death Dis 5(3):e1127
Sarkaria I, O-Charoenrat P, Talbot SG, Reddy PG, Ngai I, Maghami E, Patel KN, Lee B, Yonekawa Y, Dudas M, Kaufman A, Ryan R, Ghossein R, Rao PH, Stoffel A, Ramanathan Y, Singh B (2006) Squamous cell carcinoma related oncogene/DCUN1D1 is highly conserved and activated by amplification in squamous cell carcinomas. Cancer Res 66(19):9437–9444
Sarogni P, Palumbo O, Servadio A, Astigiano S, D'Alessio B, Gatti V, Cukrov D, Baldari S, Pallotta MM, Aretini P, Dell'Orletta F, Soddu S, Carella M, Toietta G, Barbieri O, Fontanini G, Musio A (2019) Overexpression of the cohesin-core subunit SMC1A contributes to colorectal cancer development. J Exp Clin Cancer Res 38(1):108
Imoto I, Yuki Y, Sonoda I, Ito T, Shimada Y, Imamura M, Inazawa J (2003) Identification of ZASC1 encoding a Krüppel-like zinc finger protein as a novel target for 3q26 amplification in esophageal squamous cell carcinomas. Cancer Res 63(18):5691–5696
Gervais FG, Singaraja R, Xanthoudakis S, Gutekunst CA, Leavitt BR, Metzler M, Hackam AS, Tam J, Vaillancourt JP, Houtzager V, Rasper DM, Roy S, Hayden MR, Nicholson DW (2002) Recruitment and activation of caspase-8 by the Huntingtin-interacting protein Hip-1 and a novel partner Hippi. Nat Cell Biol 4(2):95–105
Funding
Open access funding provided by University of Debrecen. This research was co-financed by the National Research Development and Innovation Fund (grant number K-112327), by the European Regional Development Fund (GINOP-2.3.2-15-2016-00005), by the ÚNKP-19-3 New National Excellence Program of the Ministry for Innovation and Technology as well as by the Hungarian Academy of Sciences (MTA11010 and TK2016–78).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of Interest
The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Koroknai, V., Patel, V., Szász, I. et al. Gene Expression Signature of BRAF Inhibitor Resistant Melanoma Spheroids. Pathol. Oncol. Res. 26, 2557–2566 (2020). https://doi.org/10.1007/s12253-020-00837-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12253-020-00837-9