ABSTRACT
Downregulation of miR26A1 has been reported in various B-cell malignancies; however, the mechanism behind its deregulation remains largely unknown. We investigated miR26A1 methylation and expression levels in a well-characterized series of chronic lymphocytic leukemia (CLL) and mantle cell lymphoma (MCL). From 450K methylation arrays, we first observed miR26A1 (cg26054057) as uniformly hypermethylated in MCL (n = 24) (all >75%), while CLL (n = 18) showed differential methylation between prognostic subgroups. Extended analysis using pyrosequencing confirmed our findings and real-time quantitative PCR verified low miR26A1 expression in both CLL (n = 70) and MCL (n = 38) compared to normal B-cells. Notably, the level of miR26A1 methylation predicted outcome in CLL, with higher levels seen in poor-prognostic, IGHV-unmutated CLL. Since EZH2 was recently reported as a target for miR26A1, we analyzed the expression levels of both miR26A1 and EZH2 in primary CLL samples and observed an inverse correlation. By overexpression of miR26A1 in CLL and MCL cell lines, reduced EZH2 protein levels were observed using both Western blot and flow cytometry. In contrast, methyl-inhibitor treatment led to upregulated miR26A1 expression with a parallel decrease of EZH2 expression. Finally, increased levels of apoptosis were observed in miR26A1-overexpressing cell lines, further underscoring the functional relevance of miR26A1. In summary, we propose that epigenetic silencing of miR26A1 is required for the maintenance of increased levels of EZH2, which in turn translate into a worse outcome, as shown in CLL, highlighting miR26A1 as a tumor suppressor miRNA.
KEYWORDS: Chronic lymphocytic leukemia, DNA methylation, mantle cell lymphoma, microRNA, tumor suppressor
Introduction
MicroRNAs (miRNAs) belong to the class of small (∼22 nucleotides) noncoding RNAs, known to play critical regulatory roles in normal cell development as well as during tumorigenesis.1-4 The importance of miRNAs in tumor development was first documented for the miR-15a/16-1 family in chronic lymphocytic leukemia (CLL), where the deletion of this cluster on chromosome 13q14 was reported in over two-thirds of CLL patients.5 A number of studies have subsequently revealed the biological and clinical relevance of different miRNAs in various types of cancer, including CLL and the clinically more aggressive mantle cell lymphoma (MCL).6-11
One of these miRNAs, miR26A1, was reported to be deregulated in several cancer types, such as thyroid anaplastic carcinoma, Burkitt lymphoma, and rhabdomyosarcoma, and was proposed to function as a tumor suppressor miRNA.12-14 miR26A1 is known to be involved in several key signaling pathways (e.g., p53, TGF-β signaling) and to regulate several transformation-related targets, such as SMAD115 and EZH2.13 The latter is a member of the polycomb group (PcG) and a histone methyltransferase catalyzing H3K27me3 methylation, which is known to be overexpressed in different cancer types, including CLL and MCL, and linked to poor outcome.16-18 Recently, the direct effect of miR26A1 on EZH2 regulation was indicated in lung cancer and nasopharyngeal carcinoma, where miR26A1 overexpression led to downregulation of EZH2, inhibition of cell proliferation, and induction of apoptosis by blockage of the G1/S phase transition.13,19
In CLL and MCL, miR26A1 expression was shown to be noticeably lower in patient samples compared to normal B-cells.20-22 However, the role of miR26A1 and the mechanism behind its deregulation remains unknown. To gain insight into this issue, we investigated the methylation status and gene expression of miR26A1 in a well-characterized CLL (70 patients) and MCL (65 patients) material. While MCL uniformly showed high levels of miR26A methylation and low miR26A expression, CLL patients showed a more varying methylation spectrum that correlated with outcome. By overexpressing miR26A1 in CLL and MCL cell lines, we showed downregulation of EZH2, supporting a direct regulatory role of miR26A1.
Results
DNA hypermethylation of miR26A1 in CLL and MCL
From our recent 450K DNA methylation array analysis in CLL,23 we observed a differentially methylated CpG site in miR26A1 (cg26054057) between prognostic subgroups based on IGHV gene mutational status,24,25 with IGHV-unmutated cases displaying a significantly higher methylation level than IGHV-mutated patients (median 53.0% vs. 83.7%, P = 0.006; Fig. 1A). In MCL, we performed 450K array analysis on 24 MCL cases [12 high proliferative (HP) + 12 low proliferative (LP)] and miR26A1 was found to be homogeneously hypermethylated in all MCL samples (median 96.0% and 96.6% in LP and HP samples, respectively; Fig. 1B).
In order to extend these observations, we performed pyrosequencing to analyze the methylation status of miR26A1 (average of 4 CpG sites) in an additional 38 MCL and 70 CLL samples. Compared to normal controls, we observed that all CLL and MCL samples were hypermethylated (Fig. 1C). In MCL, all samples showed hypermethylation with high median percentage of miR26A1 methylation (84.8%; range: 80.2-89.0%) (Fig. 1C), with no difference between HP and LP cases, which is in line with our array data. Similarly, the CLL samples showed a wider range of miR26A1 methylation (80%; range: 58.6-89.3%). Again, IGHV-unmutated cases showed significantly higher methylation levels (median 88.9%), similar to MCL samples, as compared to IGHV-mutated samples (median 62%, P < 0.00001; Fig. 1D).
DNA methylation status of miR26A1 predicts survival in CLL
CLL patients were divided into cases with high or low miR26A1 methylation based on median value as cutoff (80%). Indeed, CLL patients with high methylation levels showed a poorer overall survival compared to the patients with low methylation levels (median survival 6.0 vs 17.2 years, P < 0.0001; Fig. 2A). Interestingly, when we correlated the percentage of methylation to survival time in years (Fig. 2B), we observed that most of the IGHV-mutated cases (17 out of 19 cases, 89%) with long survival times (>10 years) showed lower methylation levels. On the other hand, most IGHV-unmutated cases (15 out of 18 cases, 83%) with survival times below 10 y showed higher methylation levels (Fig. 2B).
Deregulated expression of miR26A1 in CLL and MCL
Using real-time quantitative PCR (RQ-PCR), we determined the miR26A1 expression levels in 38 MCL and 70 CLL patient samples and compared to CD19+ sorted B-cells from 6 healthy, age-matched controls. As previously reported,20,22 both MCL and CLL samples uniformly showed several-fold lower miR26A1 expression compared to normal B-cell controls (Supplementary Fig. 1A). Hence, no differential miR26A1 expression was observed between IGHV-mutated/unmutated CLL samples or between HP and LP MCL samples (Supplementary Fig. 1B). Accordingly, no differences in survival were detected in relation to miR26A1 expression, based on the median value as cutoff level (0.000676) (P = 0.88; Supplementary Fig. 1C). Nevertheless, most IGHV-mutated CLL cases showed high miR26A1 expression and long overall survival (8 out of 11 cases, 72%) and vice versa for IGHV-unmutated CLL (13 out of 16 cases, 81%; Supplementary Fig. 1D).
miR26A1 targets EZH2 in CLL and MCL
Recently, miR26A1 was shown to target EZH2 and reduce its expression in nasopharyngeal and hepatocellular carcinomas.26,27 To examine this potential link further, we first selected primary CLL samples exhibiting high (10 samples) and low (10 samples) miR26A1 expression and analyzed the EZH2 mRNA expression levels using RQ-PCR. As shown in Fig. 3A, a significant negative correlation (P = 0.04, r = −0.45) was observed. Next, we overexpressed miR26A1 in 4 CLL and MCL cell lines (HG3, MEC1, Z138 and GRANTA519) using Amaxa nucleofection: all 4 cell lines showed a significant overexpression of miR26A1 with a few thousand-fold increase after transfection (Fig. 3B). Even though no significant decrease in EZH2 mRNA expression levels was seen (Supplementary Fig. 2A-B), we observed a significant downregulation of EZH2 protein levels compared to the negative control using 2 independent methods, i.e., Western blot analysis (Fig. 3C) and flow cytometry (Fig. 3D and Supplementary Fig. 2C), hence suggesting that that EZH2 is a target for miR26A1 in both CLL and MCL.
Loss of DNA methylation results in upregulation of miR26A1 expression
To investigate the direct role of DNA methylation in regulating miR26A1 expression, we treated the 4 MCL/CLL cell lines with increasing concentrations of the methyl inhibitor DAC. As shown in Fig. 4A-B, a corresponding increase of miR26A1 expression was demonstrated for all 4 cell lines with different DAC concentrations. Since miR26A1 was negatively correlated with EZH2 expression, we also analyzed EZH2 expression in these DAC treated cell lines, showing a corresponding reduction of EZH2 with increasing miR26A1 (Fig. 4C-D).
Overexpression of miR26A1 leads to increased apoptosis
Finally, to study the role of miR26A1 in inducing apoptosis, we performed Annexin V staining in cells overexpressing miR26A1 demonstrating that increased levels of miR26A1 coincided with increased apoptosis in all 3 leukemic cell lines investigated (HG3, Z138, and GRANTA 519) (Fig. 5 and Supplementary Fig. 3).
Discussion
miR26A1 was recently suggested to act as a tumor suppressor miRNA, and studies of CLL and MCL have revealed generally lower miR26A1 expression levels compared to normal B-cells.28-30 However, little is known about the mechanism leading to deregulation of miR26A1 in lymphoid malignancies. From preliminary observations based on 450K methylation array analysis, we noted that miR26A1 was hypermethylated in most CLL and MCL samples, though with differential methylation between IGHV-mutated and unmutated CLL, while all MCL samples appeared to be more uniformly hypermethylated. This initial finding pointed to a potential involvement of aberrant DNA methylation in regulating miR26A1 expression.
To study this further, we decided to investigate larger series of CLL and MCL patients using a more quantitative technology, i.e., pyrosequencing. Indeed, miR26A1 was found to be differentially methylated between favorable-prognostic IGHV-mutated and poor-prognostic IGHV-unmutated CLL cases, where the latter subgroup displayed significantly higher methylation levels, well in line with recent high-throughput studies showing differential methylation between these subgroups.23,28,31,32 The degree of miR26A1 methylation was also associated with a worse outcome in CLL, with significantly shorter overall survival in patients with high miR26A1 methylation levels. Notably, the CLL cohort investigated did not contain any 11q- or 17p-deleted case (which are already known to render a poor outcome) to avoid biased results. In contrast, in MCL, miR26A1 was highly methylated in almost all patient samples, independently of whether they were judged as high or low proliferative, indicating a more uniform silencing in MCL.
Next, we analyzed the miR26A1 expression in primary CLL and MCL samples using RQ-PCR, overall demonstrating, as expected, very low expression levels in both malignancies (including both IGHV-mutated/unmutated CLL and HP/LP MCL) compared to normal B-cells. To scrutinize the direct role of DNA methylation in regulating miR26A1 expression, we treated 4 CLL and MCL cell lines with the methyl inhibitor DAC and observed a corresponding increase of miR26A1 expression. From these data, we conclude that epigenetic silencing of miR26A1 through DNA methylation appears to represent an important event in the pathobiology of both CLL and MCL. This was further underscored by our findings that miR26A1 overexpression in cell lines led to induction of apoptosis, supporting its tumor suppressor properties, now also in these 2 B-cell malignancies.
Overexpression of EZH2, a well-studied chromatin modifier, is known to be associated with tumor invasion, tumor progression, and poor prognosis in many different cancer types, including CLL and MCL.16,33,34 A key role of EZH2 in MCL pathobiology was recently suggested from studies showing that i) upregulated EZH2 conferred reduced expression of the tumor suppressor miR29A, and ii) epigenetic silencing of HOX genes in MCL was directed by EZH2.35 Since EZH2 most recently was indicated as a direct target of miR26A1 in other cancer types,26 we decided to investigate the potential consequence of miR26A1 deregulation on EZH2 expression. To do this, we overexpressed miR26A1 in CLL and MCL cell lines, which all showed reduced protein expression levels of EZH2 using both Western blot and FACS analysis. Importantly, this negative correlation was also seen in primary CLL samples, where EZH2 expression was significantly higher in samples with low miR26A1 expression and vice versa. In addition, in our re-induction experiments of miR26A1 expression using the methyl inhibitor treatment, we observed a corresponding decrease in EZH2 expression. Hence, our data strongly suggests that silenced miR26A1 expression is a necessity for maintaining high levels of EZH2 in CLL and MCL, which renders these cells a proliferative and survival advantage.
In summary, this study highlights the importance of epigenetic silencing of miR26A1 miRNA in CLL and MCL. Indeed, overexpression of miR26A1 resulted in decreased levels of EZH2, which in turn led to induction of apoptosis, further supporting miR26A1 as an important tumor suppressor micro-RNA. While hypermethylation was a uniform finding for all MCL samples, a more varying degree of miR26A1 methylation was seen in CLL, with high methylation predicting significantly shorter survival, a finding that deserves further investigation. Our novel observations further reinforces that EZH2 could be one of the therapeutic targets with clinical impact in CLL.
Methods
Patient materials
Peripheral blood mononuclear cells (PBMCs) from 70 CLL cases (36 were IGHV-mutated and 34 IGHV-unmutated), collected from the Biobank at Uppsala University Hospital, Sweden, and University Hospital Brno, Czech Republic, were included in the study. All CLL cases were diagnosed according to recently revised iwCLL criteria36 and tumor samples were obtained before treatment and had a high tumor percentage ≥70 %. The MCL samples used for 450K array analysis (i.e., 12 HP + 12 LP lymph node samples; all FACS sorted) were diagnosed according to the WHO classification37 and collected from the Biobank at Karolinska University Hospital, Huddinge, Sweden. For validation, an additional 38 MCL samples (17 HP + 21 LP lymph node samples; tumor percentage ≥70 %) were collected from the Department of Molecular Medicine, University of Pavia, Italy. All MCL samples were classified as HP and LP based on the percentage of Ki-67 staining using 25% as cutoff. Clinicobiological characteristics of the CLL and MCL cohorts are summarized in Supplementary Table 1. All patients provided informed consent in accordance with the Helsinki Declaration and the study was approved by the local ethics review boards. As normal healthy controls, CD19+ sorted B-cells were isolated from 6 age-matched healthy donors (range: 62–75 years).
Methylation arrays
Bisulfite-converted DNA prepared from sorted MCL samples was hybridized to the HumanMethylation450 (450K) BeadChip Arrays (Illumina, San Diego, CA, USA) and processed as previously detailed.23
Pyrosequencing
The methylation status for the miR26A1 target region (127 bp) containing 4 CpG sites was assessed using pyrosequencing; this includes the CpG site which was shown to be differentially methylated in primary CLL and MCL samples using 450K arrays (ILMNID: cg26054057; Index: 152130). Genomic DNA was bisulfite converted using the EZ DNA Methylation Gold kit (D5005, Zymo Research, Irvine, USA) according to manufacturer's protocol.38 The PyroMark™ software (Qiagen) was applied to design pyrosequencing primer sets and the primer sequences are as follows; forward primer (5′-GGTTTTAGGGTTGGGGTTAGAA-3′), reverse primer (Biotin 5′-ACCTACACAACCTATCCTAAATTACT-3′) and sequencing primer (5′-GTTGGGGTTAGAAATTTT-3′). The pyrosequencing was performed according to the manufacturer's instructions using the PyroMark™ Q24 Advanced pyrosequencer (Qiagen). The average percentage of methylation for all 4 CpG sites was calculated.
miR26A1 expression analysis using real-time quantitative PCR
Total RNA was extracted using miRNeasy Mini Kit (217004, Qiagen, Hilden, Germany) according to the manufacturer's protocol. Reverse transcription was performed using the TaqMan micro RNA transcription kit (4366596, Applied Biosystems, Foster City, USA). Real-time PCR was performed using the 7900HT Fast Real-time PCR System instrument (Applied Biosystems, Warrington, UK) using TaqMan gene expression assay for miR-26A1 (has-miR-26a1, PN 4427975, Applied Biosystems, Foster City, USA) according to manufacturer's instructions. RNU6B (PN 4440887, Applied Biosystems, Foster City, USA) was used as internal control. All samples were run in triplicates. The relative expression of miR-26A1 to RNU6B (the standard reference control miRNA) was calculated using the ΔCt method.
Cell lines and culture conditions
Four B-cell lymphoma cell lines, 2 CLL-derived (HG339 and MEC140) and 2 MCL-derived (Z13841 and GRANTA 51942) were cultured in RPMI 1640 (R0883, Sigma-Aldrich, St. Louis, USA) supplemented with 10% fetal bovine serum (Sigma-Aldrich, St. Louis, USA), 1× penicillin/streptomycin (P4333, Sigma-Aldrich, St. Louis, USA) and 100 mM and 200 mM L-Glutamine (G7513, Sigma-Aldrich, St. Louis, USA) for CLL and MCL cell lines, respectively.
Overexpression of miR26A1
miR26A1 transfection was performed on CLL and MCL cell lines using custom designed miR26A1 oligo (has-miR-26a1, 4464066, Life technologies, Carlsbad, USA). The miR mimic negative (mirVana miRNA mimic negative control, 4464058, Life technologies, Carlsbad, USA) was used as negative control. Transient transfection was carried out on an Amaxa Nucleofection Device II (Nucleofector 2b device, Lonza group AG, Basel, Switzerland) according to the manufacturer's instruction. In brief, cells were split at a density of 1×106/mL in medium without antibiotics 24 h before transfection. Thereafter, 2×106 cells were collected and resuspended in 100 μL Amaxa Cell Line Nucleofector Kit V with 100 pmol of miR26A1 mimic or miR mimic negative control using the X-001 electroporation program and cells were harvested after 24-72 h of transfection depending on the downstream assay used.
DNA methyl inhibitor treatment
To investigate the effect of CpG methylation on gene expression, cells were treated with the 5'-Aza-2'-deoxycytidine (DAC) methyl inhibitor using CLL and MCL cell lines cultured in RPM1 media as described previously.28 Briefly, the cultured cells were checked for viability (>98 %) and split to contain 1×106/mL. Cells were subsequently cultured over 3 d in supplemented RPMI media treated with increasing concentrations of DAC (0, 5, 10, and 20 μM DAC; A3656, Sigma-Aldrich, St. Louis, USA). DAC was changed every 24 h during treatment. Control cells were cultured in similar way but with no drugs added. We performed at least 2 independent experiments for every treatment condition on all cell lines. DNA and RNA were extracted after harvesting the cells to analyze miR26A1 methylation and expression levels by RQ-PCR and pyrosequencing, respectively.
Western blot analysis
Western blot analysis was performed using nuclear extracts of transfected CLL and MCL cell lines, which were extracted using the NE-PER Nuclear and Cytoplasmic Extraction Kit (Thermo Scientific, Rockford, USA) according to manufacturer's protocol. Equal amounts of nuclear lysates were loaded on NUPAGE 10% Bis-Tris gels (Invitrogen, Carlsbad, USA) and transferred to membranes (Amersham Hybond ECL; GE Health Care Life Sciences, Sweden). After blocking in TBS with the addition of 5% BSA, the membranes were incubated with the appropriate primary and secondary antibodies, followed by washes with TBS containing 0.05% Triton X-100. Blots were visualized with SuperSignal West Dura Extended Duration Substrate (Thermo Scientific, Rockford, USA) using the ChemiDoc XRS+ (Bio-Rad) instrument. Primary antibodies used for western blotting were: EZH2 (3147, Cell Signaling Technology, Danvers, USA) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) (SC-25778; Santa Cruz Biotechnology, Dallas, USA), while the secondary antibodies were anti-mouse IgG (Cell Signaling Technology, Danvers, USA) and anti-rabbit IgG (Cell Signaling Technology, Danvers, USA).
Annexin V and EZH2 expression levels using FACS analysis
Apoptosis was measured by flow cytometry using a BD FACSAria cell sorter and analyzed using the FACSDiva version 6 software (BD Biosciences). The FITC Annexin V Apoptosis Detection Kit I (556547, BD Biosciences, New Jersey, USA) and 7-AAD (A1310, Thermo Scientific, Rockford, USA was used to measure apoptosis and cell death for transfected cells according to the manufacturer's instructions. To analyze EZH2 protein levels, cells were permeabilized with solution B (Intrasure kit, 641778, BD Biosciences, New Jersey, USA) followed by incubation with diluted EZH2 primary antibody (PA5-24594, Thermo Scientific, Rockford, USA) and APC conjugated goat anti-rabbit IgG secondary antibody (A-10931, Thermo Scientific, Rockford, USA).
Statistical analysis
Differences in gene expression and methylation levels between groups were assessed using 2-tailed Student's t-test. Patients were classified as low or high expressing and low or high methylated based on the median value. Overall survival was calculated from time of diagnosis until date of death or last follow-up. Kaplan-Meier analysis was performed to construct survival curves and log-rank test was applied to evaluate differences between subgroups. Correlation of expression level of miR26A1 and EZH2 was assessed by Spearman's rank correlation coefficient. All statistical analyses were carried out using Statistica Software version 12 (Stat Soft, Tulsa, OK, USA) and GraphPad Prism version 6 (GraphPad Software, La Jolla California, USA).
Supplementary Material
Disclosure of potential conflicts of interest
No potential conflicts of interest were disclosed.
Acknowledgments
This study was supported by the Swedish Research Council, the Swedish Cancer Society, AGFond, “FoU Västra Götalandsregionen,” Lion's Cancer Foundation in Uppsala, the Ministry of Education, Youth and Sports of the Czech Republic under the project CEITEC 2020 (LQ1601) and the Horizon2020 Program Twinning (MEDGENET/2016-2018/no.692298).
Authorship Contributions
PK and SB contributed equally to this study, performed research, analyzed the data and wrote the paper. LA, KP, SP, AW and GC performed research. LM, BS, and MP analyzed data. RR analyzed data and wrote the paper. MK was the principle investigator, performed research, analyzed data and wrote the paper.
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