Relative expression of rRNA transcripts and 45S rDNA promoter methylation status are dysregulated in tumors in comparison with matched-normal tissues in breast cancer

  • Authors:
    • Gurbet Karahan
    • Nilufer Sayar
    • Gokcen Gozum
    • Betul Bozkurt
    • Ozlen Konu
    • Isik G. Yulug
  • View Affiliations

  • Published online on: April 28, 2015     https://doi.org/10.3892/or.2015.3940
  • Pages: 3131-3145
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Abstract

Ribosomal RNA (rRNA) expression, one of the most important factors regulating ribosome production, is primarily controlled by a CG-rich 45S rDNA promoter. However, the DNA methylation state of the 45S rDNA promoter, as well as its effect on rRNA gene expression in types of human cancers is controversial. In the present study we analyzed the methylation status of the rDNA promoter (-380 to +53 bp) as well as associated rRNA expression levels in breast cancer cell lines and breast tumor-normal tissue pairs. We found that the aforementioned regulatory region was extensively methylated (74-96%) in all cell lines and in 68% (13/19 tumor-normal pairs) of the tumors. Expression levels of rRNA transcripts 18S, 28S, 5.8S and 45S external transcribed spacer (45S ETS) greatly varied in the breast cancer cell lines regardless of their methylation status. Analyses of rRNA transcript expression levels in the breast tumor and normal matched tissues showed no significant difference when normalized with TBP. On the other hand, using the geometric mean of the rRNA expression values (GM-rRNA) as reference enabled us to identify significant changes in the relative expression of rRNAs in the tissue samples. We propose GM-rRNA normalization as a novel strategy to analyze expression differences between rRNA transcripts. Accordingly, the 18S rRNA/GM-rRNA ratio was significantly higher whereas the 5.8S rRNA/GM-rRNA ratio was significantly lower in breast tumor samples than this ratio in the matched normal samples. Moreover, the 18S rRNA/GM-rRNA ratio was negatively correlated with the 45S rDNA promoter methylation level in the normal breast tissue samples, yet not in the breast tumors. Significant correlations observed between the expression levels of rRNA transcripts in the normal samples were lost in the tumor samples. We showed that the expression of rRNA transcripts may not be based solely on promoter methylation. Carcinogenesis may cause dysregulation of the correlation between spliced rRNA expression levels, possibly due to changes in rRNA processing, which requires further investigation.

Introduction

Breast cancer, the most common type of cancer among women, was also the primary and secondary cause of cancer-related deaths among women living in less developed (14.3% of all cancer-related deaths) and more developed regions (15.4% after lung cancer) in 2012, respectively (1). Familial or somatic mutations of BRCA1, BRCA2 and TP53 (alias p53) are well-known high risk factors for breast cancer formation while others (PALB2, BRIP1, ATM, CHEK2, PTEN and CDH1) have been estimated to have moderate or weak effects (2).

Contrary to mutations that modify the DNA sequence itself, epigenetic alterations affect gene expression via DNA methylation, histone modifications and chromatin remodeling. DNA methylation, the frequently studied epigenetic modification in the context of embryogenesis, X chromosome inactivation and imprinting (35), is also important for the protection of genome integrity and hence cancer. Global hypomethylation of the genome, commonly observed in multiple cancers, increases genome instability and activates protooncogenes while hypermethylation of promoter CpG islands silences the expression of tumor suppressor genes (68). Promoter DNA methylation, identified at the promoter region of many genes, contributes to breast tumorigenesis; however, DNA methylation of the rDNA region has been overlooked in DNA methylation studies related to breast cancer.

Ribosome synthesis is closely related to the cell metabolism involved in cell growth and proliferation, and is tightly correlated with ribosomal RNA (rRNA) synthesis (9). The human genome contains ~300–400 copies of rRNA genes but only a fraction of these genes are actively transcribed depending on the cell type, external signals and the cell stage, while the rest of the genes remain inactive (10). rRNA genes are organized in tandem repeated arrays within nucleolar organizing regions (NORs) located on the short arms of five human acrocentric chromosomes: chromosome 13, 14, 15, 21 and 22 (11). rRNA genes (except 5S, which is transcribed by RNA polymerase III) are transcribed from the 45S rDNA promoter by RNA polymerase I (Pol I). Since ~60% of the total RNA of a cell consists of Pol I products (12), rRNA genes are regulated tightly at different levels that include pre-initiation complex (PIC) formation, initiation, promoter escape, elongation, termination, re-initiation, RNA processing and post-transcriptional modifications (13).

The entire promoter region of rRNA genes is contained in an intergenic spacer region (IGS) between rDNA units. The promoter region of rDNA repeating unit consists of two important elements: the core promoter and upstream control element (UCE). The core promoter is located between −50 to +20 bp and is essential for basal transcription, whereas the UCE is located 150–200 bp upstream of the transcription start site and is required for efficient pre-initiation complex formation (14) (Fig. 1A). Cooperative binding of the HMG1 box containing upstream binding factor (UBF) and the selectivity factor (SL1 or TIF-IB) to the promoter region is required for Pol I recruitment (15,16). rRNA genes are transcribed as long precursors known as 45S pre-RNA which are then rapidly spliced into the 18S, 28S and 5.8S rRNA transcripts (17). Processed and modified rRNA transcripts are assembled into respective ribosomal subunits in the nucleolus (18,19).

The association between the nucleolus and cancer has long been known. Abnormal morphology of the nucleolus in cancer cells has drawn the attention of tumor pathologists since the 19th century. However, only recently has the molecular biology of rRNA synthesis and ribosome biogenesis in cancer cells begun to be explored.

CpG island methylation at the promoters of tumor suppressor genes is known to be an important factor in the formation and progression of many types of cancer (20). The promoter and transcribed regions of rRNA genes are rich in CG dinucleotide yet they are longer than regular 1 to 2 kb CpG islands (21). A limited number of studies analyzing the DNA methylation status of the rDNA promoter region in cancer have focused on the relationship between rDNA promoter methylation and the expression levels of rRNA genes.

Methylation at the 45S rDNA promoter region decreased the expression of rRNA genes in hepatocellular carcinoma (22) and in CD34+ cells of patients with myelodysplastic syndromes (23). On the other hand, other studies have shown no relationship or a positive correlation between promoter methylation and rRNA transcription (24,25).

Although rRNA genes and particularly 18S RNA are frequently used in qRT-PCR as housekeeping genes, recent studies have shown that 18S is differentially expressed in breast tumor and normal samples (2628). Furthermore, changes in the relative amount of spliced rRNA products from 45S have not been tested in the context of breast cancer.

CpG methylation of rDNA has been identified as a prognostic factor in ovarian, endometrial and breast cancer (2931). A recent study also revealed that the 45S rDNA promoter as well as the 5′ regions of 18S and 28S rDNA are hypermethylated in breast cancer tissues compared to paired normal tissues. Notably, methylation levels of these regions exhibited a correlation with nuclear grade and nuclear size values (32). However, none of the previous breast cancer studies examined the ratio of rRNA transcript levels and rDNA promoter methylation levels in tumors and normal tissues comparatively.

In the present study, we analyzed the methylation levels of the 45S rDNA promoter in breast cancer cell lines as well as in primary breast tumor tissues and matched normal samples. We also determined the expression levels of rRNA transcripts in the same samples in order to understand the role of rDNA promoter methylation on rRNA gene expression in breast cancer. We showed for the first time that the relative expression ratio of 18S and 5.8S rRNA was differentially modulated in tumors in comparison to adjacent normal tissues. In addition, relative rRNA expression in normal tissues was significantly and negatively correlated with the methylation status but this was not observed in the breast tumors. Furthermore, the high correlation between expression of rRNA transcripts in normal breast tissue was lost in tumors. Our findings suggest a significant dysregulation of relative rRNA expression in conjunction with promoter methylation.

Materials and methods

Cell culture, 5-aza-2′-deoxycytidine (5-AZA) and trichostatin A (TSA) treatments

MCF7, MDA-MB-453, MDA-MB-468, BT20, MDA-MB-231 and CAMA-1 breast cancer cell lines were grown in 10% fetal bovine serum (FBS) (HyClone, Thermo Scientific, USA) and 1% penicillin/streptomycin (P/S) supplemented with low glucose Dulbecco’s modified Eagle’s medium (DMEM) (both from HyClone). ZR-75-1 cell line was grown in 10% FBS, 1% P/S and 2 mM glucose (Sigma-Aldrich, USA) supplemented with RPMI-1640 medium (HyClone). BT-474 cell line was propagated in 10% FBS, 1% P/S and 10 μg/ml insulin (Sigma-Aldrich) supplemented with low glucose DMEM. MDA-MB-157 and MDA-MB-361 cell lines were grown in 10% FBS, 1 mM sodium pyruvate (Gibco, Invitrogen, USA) and 1% P/S supplemented with low glucose DMEM. HCC-1937 cell line was propagated in 10% FBS, 1% P/S and 1 mM sodium pyruvate supplemented with RPMI-1640 medium. MCF10A was grown in 10% FBS, 1% P/S, 10 μg/ml insulin, 20 ng/ml EGF and 0.5 mg/ml hydrocortisone (both from Sigma-Aldrich) supplemented with DMEM/Ham’s F-12 (1:1) medium (Biochrome, Merck Millipore, Germany). SKBR-3 cell line was grown in 10% FBS and 1% P/S supplemented with McCoy’s 5A medium (HyClone). CAL-51 cell line was propagated in 20% FBS and 1% P/S supplemented with high glucose medium. All cells were grown in 5% CO2 and 95% air at 37°C in a cell culture incubator. All cell lines except MCF-10A and CAL-51 cells were purchased from the American Type Culture Collection (ATCC; Rockville, MD, USA). MCF-10A and CAL-51 were kindly provided by Assistant Professor Dr A. Elif Erson (Middle East Technical University). Short tandem repeat profiling was used to verify the authenticity of all cell lines.

A total of 10 breast cancer cell lines (MCF7, MDA-MB-231, MDA-MB-453, MDA-MB-468, BT-474, ZR-75-1, BT-20, MDA-MD-361, SKBR-3 and CAL-51) and one non-tumorigenic breast cell line (MCF-10A) were treated with 5-AZA or TSA. Cells seeded at a density of 750,000/100 mm were treated with either 5 μM 5-AZA (Sigma-Aldrich) or dimethyl sulfoxide (DMSO) (same amount used to solubilize 5-AZA). Drugs were changed every day along with the medium, and cells were collected on day 5. 400 nM TSA or DMSO (same amount used to solubilize TSA) was administered to the cells 24 h after cell plating, and the cells were collected after 48 h.

A total of 10 cell lines (MCF7, MDA-MB-231, MDA-MB- 453, MDA-MB-468, BT-474, ZR-75-1, BT-20, SKBR-3, CAL-51 and MCF-10A) were treated with both 5-AZA and TSA (combination treatment). 5-AZA (5 μM) was added at the day of seeding and 400 nM TSA was added 72 h later in combination treatment (5-AZA+TSA); the cells were collected on day 5.

Patients and tissue samples

Primary breast tumors and matched normal tissues were obtained from 19 patients at Ankara Numune Research and Teaching Hospital (Table I). Clinical tissue samples were used with the approval of the Research Ethics Committee of Ankara Numune Research and Teaching Hospital, and consent was obtained from the patients according to the Helsinki Declaration.

Table I

Clinicopathological characteristics of the patients.

Table I

Clinicopathological characteristics of the patients.

Patient no.Age (years)ERPRDiagnosisPath lymph nodeGradeClinical gradeDM-DM month
11363+IDC+1Grade 3B+20
11557Papillary carcinoma3Grade 2A
9639+IDC2Grade 2A
11674IDC+2Grade 2A
13742+Medullary3Grade 2B
14649++ILC+Grade 2B
14870+IDC+2Grade 3A+15
15432IDC+3Grade 3B
15930+Metaplastic2Grade 2A
16141IDC2Grade 2B+47
16474++IDC2Grade 2B
16655+IDC+2Grade 2A
16844+IDC+2Grade 2B
17060IDC+2Grade 3B
17649++IDC+2Grade 2A
17747+IDC+2Grade 3A+48
18144IDC+2Grade 1
133a
173a

a Patients with missing information. ER, estrogen receptor status; PR, progesterone receptor status; IDC, infiltrating ductal carcinoma; Path lymph node, pathological lymph node status; DM, distant metastasis status.

Tissues acquired from patients during surgery were immediately frozen with liquid nitrogen and stored at −80°C until RNA or DNA extraction was performed. Pathological examinations were carried out with hematoxylin and eosin staining. Only the tumor samples identified by pathological examination consisting of >80–90% tumor cells were included in the present study.

DNA extraction and bisulfite treatment

Genomic DNA was extracted from the breast cancer cell lines as well as the clinical breast cancer and matched normal tissue samples using the NucleoSpin Tissue DNA extraction kit (Macherey-Nagel, Germany) following the manufacturer’s instructions.

Sodium bisulfite treatment of DNA, which converts unmethylated cytosine residues to uracil leaving methylated cytosine residues unaffected, was performed with 1 μg genomic DNA using the EpiTect Bisulfite kit (Qiagen, Germany). Elution was performed using 20 μl of elution buffer.

Bisulfite-specific PCR, gel extraction and bisulfite genomic sequencing

Bisulfite-converted DNA (1 μl) was amplified with Taq DNA polymerase (Fermentas, Thermo Scientific, USA) using bisulfite DNA-specific primers (22) targeting the 45S rDNA promoter (45S bisulfite sequencing forward and reverse primer sequences are listed in Table II). PCR products were extracted from the gel using the QIAquick Gel Extraction kit (Qiagen). Purified products were cloned into the pGEM-T Easy Vector using the pGEM-T Easy Vector system (Promega, USA). The transformation protocol was performed according to the pGEM-T Easy Vector system manual using competent E. coli DH5α. Bacteria were plated on LB-agar containing ampicillin (AppliChem, Germany), IPTG and X-Gal (both from Fermentas) and positive clones (five colonies from cell lines and 10 colonies from tissue samples) were randomly selected.

Table II

Primers used in the present study.

Table II

Primers used in the present study.

PrimerSequenceProduct size (bp)Efficiency value
45S bisulfite sequencing primers
45S bisulfite sequencing primers
Forward
Reverse
5′-GAGTCGGAGAGCGCTCCCTGAG-3′
5′-CTGGAGAGGTTGGGCCTCCG-3′
434
18S rRNA
18S rRNA
Forward
Reverse
5′-AAACGGCTACCACATCCAAG-3′
5′-CCTCCAATGGATCCTCGTTA-3′
1541.95
28S rRNA
28SS rRNA
Forward
Reverse
5′-CAGGGGAATCCGACTGTTTA-3′
5′-ATGACGAGGCATTTGGCTAC-3′
1511.85
5.8S rRNA
5.8S rRNA
Forward
Reverse
5′-CTCTTAGCGGTGGATCACTC-3′
5′-GACGCTCAGACAGGCGTAG-3′
1552.00
45S ETS
45S ETS
Forward
Reverse
5′-CGATCTGAGAGGCGTGCCTT-3′
5′-GGCAGCGCTACCATAACGGA-3′
871.93
TBP
TBP
Forward
Reverse
5′-TGCACAGGAGCCAAGAGTGAAAT-3′
5′-CACATCACAGCTCCCCACCA-3′
1342.20

[i] rRNA, ribosomal RNA; ETS, external transcribed spacer.

Small-scale isolation of plasmid DNA (mini-prep) was performed with the NucleoSpin Plasmid Isolation kit (Macherey-Nagel) according to the manufacturer’s instructions. Plasmids containing the cloned inserts were confirmed with PCR using T7 and SP6 universal primers. The insert-containing plasmids were sequenced with SP6 primers using the dideoxy chain-termination method (Iontek, Turkey).

Methylation analysis

Raw bisulfite sequencing data were analyzed using the Quantification tool for Methylation Analysis) (QUMA), a web-based quantification tool for methylation analysis (http://quma.cdb.riken.jp) (33). Bisulfite conversion rates of raw sequencing data were determined by analyzing unconverted cytosine residues in non-CG sites. Clones with a bisulfite conversion rate of <95% were excluded. Clones from each sample were trimmed, aligned and displayed as lollipop graphs using QUMA.

RNA isolation and cDNA synthesis

The frozen tumor (4–5 slices for each sample) and normal (20–25 slices for each sample) tissue samples were cut into 60-μm sections and used for RNA isolation. Tissue samples were lysed in 1 ml TRI reagent RT (Molecular Research Center, USA) with a homogenizer and passed through a 21-gauge needle several times. After a 5-min incubation at room temperature, 50 μl of 4-bromoanisole (Molecular Research Center) was added/ml of TRI reagent. Tubes were vortexed for 15 sec and incubated at room temperature for 2–3 min. After incubation, the mixture was centrifuged at 12,000 x g for 15 min at 4°C and then the aqueous phase was collected into a clean tube. Isopropanol (0.5 ml) was added to the aqueous phase/1 ml of TRI reagent used. The mixture was incubated at room temperature for 10 min and then centrifuged at 12,000 x g for 15 min at 4°C to recover the RNA. The supernatant was removed, and the pellet was washed with 75% ethanol twice and centrifuged at 7,500 x g for 5 min at 4°C. The pellet was air-dried and dissolved in diethylpyrocarbonate (DEPC)-treated H2O. In order to avoid DNA contamination of the total RNA acquired from the tissue samples, DNase I treatment was performed with the Message Clean kit (GenHunter, USA) according to the manufacturer’s instructions. Total RNA (500 ng) was used in random primed cDNA synthesis with the RevertAid First Strand cDNA Synthesis kit (Fermentas).

RNA isolation from the cell lines was performed using the NucleoSpin RNA II RNA isolation kit (Macharey-Nagel) following the manufacturer’s protocol. Total RNA (1 μg) was used in random primed cDNA synthesis with the RevertAid First Strand cDNA Synthesis kit.

Real-time PCR

Real-time PCR was performed with primers targeting 45S ETS, 18S, 28S and 5.8 rRNA transcripts. All primer sequences are listed in Table II. Randomly primed cDNAs from both cell lines and frozen tissue samples were diluted in a 1/5 ratio. Diluted cDNA (1 μl) was used in every reaction containing 10 μl of DyNAmo SYBR-Green qPCR kit (Thermo Scientific) and 10 pmol of forward and reverse primers in a final volume of 20 μl. Thermal cycling conditions were as follows: initial denaturation for 5 min at 95°C, 40 cycles of 30 sec at 95°C, 30 sec at 60°C and 30 sec at 72°C followed by melting curve. All reactions were set as duplicates. The Stratagene Mx3005P Real-Time PCR System (Agilent, USA) was used for real-time PCR experiments.

The relative expression levels of rRNAs were evaluated using log2 (2ΔCt) calculation. TBP was used as the reference gene both for cell lines and clinical tissue samples to assess the amount of cDNA. The geometric mean of the rRNA expression values (GM-rRNAs) (18S, 28S, 5.8S and 45S ETS) was also used as a reference gene in tissue samples in order to understand the relative changes of rRNAs with respect to each other.

Statistical analysis

Raw bisulfite sequencing data were aligned, trimmed and quality checked using QUMA. Lollipop graphs and pie charts of the methylation status were also generated using QUMA (33). The Wilcoxon matched pairs signed rank test was used to assess both sample-wise and CpG-wise significant methylation differences between breast tumor and matched normal samples. Significant expression differences were determined using the paired t-test. Correlations between 45S rDNA promoter methylation and rRNA expression levels, as well as rRNA transcripts with each other were analyzed using Spearman correlation.

The association of rDNA promoter methylation and rRNA expression with clinical variables was evaluated with Spearman correlation. p<0.05 was accepted as statistically significant for all statistical analyses. All statistical analyses of methylation and expression data were performed using IBM SPSS software version 21.0 or GraphPad Prism 6.0.

Results

45S rDNA promoter is highly methylated in breast cancer cell lines

To identify the methylation levels of the 45S rDNA promoter region in breast cancer in vitro, we performed bisulfite genomic sequencing for the 45S rDNA promoter region in 10 breast cancer cell lines and a non-tumorigenic breast cell line (MCF-10A). Bisulfite sequencing primers were obtained from a previous study (22), which amplified a 434-bp region spanning two important elements: UCE and the core promoter (34) (Fig. 1B). Isolated DNAs from the cell lines were treated with sodium bisulfite reagent, allowing for integration of epigenetic information (DNA methylation) into genetic information. Five randomly selected clones from each cell line were sequenced, aligned and analyzed using QUMA (33). All cell lines, including a non-tumorigenic breast cell line, MCF-10A, exhibited very high levels of methylation (varying between 74 and 96%) in their 45S rDNA promoter regions (Fig. 2).

Breast tumors are heavily methylated compared to their normal matched tissues in the 45S rDNA promoter region

We analyzed 19 breast tumor and matched normal frozen tissues (Table I) using the same bisulfite genomic sequencing method to test whether methylation levels of the 45S rDNA promoter region in patient samples were similar to those of the cell lines. Ten randomly selected clones were sequenced, aligned and analyzed from each of the breast tumor and normal pairs using QUMA (33). We used the Wilcoxon signed rank test for testing the paired differences instead of the Mann-Whitney U test offered by the QUMA tool. Our results revealed that 13 out of 19 (68%) breast cancer tissue samples had higher methylation levels of the 45S rDNA. On the other hand, three samples showed significantly higher methylation levels in normal samples compared to their tumor pairs, whereas there was no significant difference between promoter methylation levels in breast tumor and matched normal tissues in the remaining three samples (Fig. 3A). Normal samples were not fully unmethylated and instead showed a mosaic methylation pattern, a relatively common observation for human rDNA promoters (22). Methylation patterns of tumor and normal pairs showed a significant correlation with each other. To test whether this correlation was due to patient-specific methylation of rDNA promoters, we performed a correlation analysis between randomly selected tumor and normal samples; and these showed similar degrees of correlation (data not shown). In addition, the analysis of individual CpGs in tumor and normal pairs revealed significant methylation levels in different CpGs identified with the Wilcoxon matched pairs signed rank test (Fig. 3B).

No significant correlation was identified between rDNA promoter methylation levels and patient clinical variables.

Expression levels of rRNA transcripts in breast cancer

TBP, GAPDH and ACTB have been used as reference genes to determine rRNA expression levels in several studies (23,24,35) but these RNA polymerase II (Pol II) transcribed genes are variably expressed in numerous types of cancer (36,37). However, several studies advise against using rRNA levels to determine mRNA levels (26,27). Accordingly, using mRNA levels to normalize rRNA levels may have a similar drawback. Herein, we propose that GM-rRNA, the geometric mean of expression from an rRNA pool (18S, 28S, 5.8S and 45S ETS) synthesized by Pol I, can be used to analyze relative changes in rRNAs with respect to each other between tumor and normal samples, as well as in cell lines. We performed our analyses using both TBP and GM-rRNA normalization to test the effect of normalization on expression changes in rRNA transcripts.

Expression of rRNA transcripts is highly variable in breast cancer cell lines

It is known that promoter DNA methylation has a repressive effect, particularly on Pol II transcribed genes in cancer (20,38) and increased methylation levels are implicated in decreased levels of rRNA transcription (22,23). Thus, we hypothesized that rRNA transcription levels may also be downregulated in these breast cancer cell lines with a hypermethylated 45S rDNA promoter. Total RNA was isolated and tested in cell lines with qRT-PCR using primers targeting Pol I products 18S, 28S, 5.8S and 45S external transcribed spacer (ETS) region.

All of the rRNA transcripts were expressed at varying levels among the cell lines when normalization was performed with the TBP gene (Fig. 4A). Similar results were obtained when we used GM-rRNA to determine changes in the ratio of the rRNA transcripts (Fig. 4B).

Epigenetic drugs 5-AZA and 5-AZA+TSA modulate expression of rRNA transcripts

To further establish the relationship between 45S rDNA promoter methylation and rRNA expression, we used the hypomethylating agent, 5-AZA, which prevents DNA methylation by inhibiting DNA methyltransferases (39) and leads to increased RNA transcription. TBP normalized expression levels of 5.8S and 45S ETS transcripts were significantly decreased upon 5-AZA treatment (Fig. 5A). However, proportion of rRNA transcripts did not exhibit significant differences between 5-AZA- and DMSO-treated samples (normalization with GM-rRNA) (Fig. 5B).

TSA is a non-specific histone deacetylase (HDAC) inhibitor. TSA treatment of cells affects the acetylation status of H3 and H4 and thus TSA indirectly upregulates gene expression by dispersion of the chromatin structure (39). Therefore, TSA was used to determine whether other mechanisms (such as histone acetylation) are involved in the rRNA synthesis besides DNA methylation. TSA treatment alone did not significantly alter the expression levels or the relative proportions of the rRNA transcripts when normalized with TBP or GM-rRNA, respectively (data not shown). Treatment with 5-AZA and TSA together (5-AZA+TSA) did not significantly affect the TBP normalized expression levels of the rRNA transcripts (Fig. 6A). However, the 5.8S proportion of rRNAs was significantly decreased in the 5-AZA+TSA-treated samples compared to the DMSO-treated samples (Fig. 6B).

Relative expression levels of 18S and 5.8S transcripts are altered in breast tumors

Next, we tested whether increased levels of methylation of the 45S rDNA promoter in tumor samples led to repressed expression levels of rRNA transcripts. RNA isolation was performed from the same tissue samples used in the methylation analysis (only 14 of 19 paired tissue samples had enough tissue for RNA isolation). Expression levels, when analyzed using TBP as a reference gene, did not differ between the tumors and corresponding adjacent normal tissues for any of the rRNA transcripts (Fig. 7A). However, when normalized with GM-rRNA, the proportion of 18S was significantly decreased in the tumor samples whereas that of 5.8S rRNA was significantly increased (Fig. 7B).

rRNA transcripts are expressed independent from 45S rDNA promoter methylation levels in breast cancer cell lines

There was no significant correlation of rDNA methylation levels with rRNA expression levels or rRNA ratios in the breast cancer cell lines or in the MCF10A cells (non-tumorigenic cell line). rRNA expression levels, as well as relative rRNA proportions in cell lines were found to be independent of their promoter methylation levels (data not shown). These results indicate that rRNA transcripts were expressed even in the presence of heavy methylation at the 45S rDNA promoter.

Correlation between 45S rDNA promoter methylation and 18S rRNA expression is disrupted in breast tumors

Next, Spearman’s correlation analysis was performed to test whether the 45S rDNA promoter methylation levels in the breast tumor and matched normal samples were correlated with either rRNA expression levels or rRNA proportions in the rRNA pool. When rRNA expression levels were normalized with TBP expression, no correlation between expression and methylation was observed (data not shown). The increase in methylation of the rDNA promoter levels in the normal samples was inversely correlated with the 18S rRNA/GM-rRNA expression ratio (Spearman r=−0.6571 and p=0.0128), yet promoter hypermethylation did not exhibit any correlation with 18S rRNA/GM-rRNA ratios in the tumor samples (Fig. 8).

Furthermore, Ct values of rRNAs transcribed from the 45S rDNA promoter were highly correlated with each other in the normal samples, yet this correlation was lost in the tumor samples (Table III).

Table III

Correlation analysis between rRNA transcripts in tumor and normal samples.

Table III

Correlation analysis between rRNA transcripts in tumor and normal samples.

SampleTranscript28S rRNA5.8S rRNA45S ETS
Normal18S rRNA0.837 (p<0.01)a0.824 (p<0.01)a0.818 (p<0.01)a
28S rRNA0.833 (p<0.01)a0.674 (p=0.012)a
5.8S rRNA0.57 (p=0.033)a
Tumor18S rRNA0.042 (p=0.887)−0.051 (p=0864)0.288 (p=0.318)
28S rRNA0.521 (p=0.056)0.349 (p=0.221)
5.8S rRNA0.543 (p=0.045)a

[i] Significant correlation (ap<0.05) was identified using Spearman correlation coefficients (r) and p-values. rRNA, ribosomal RNA; ETS, external transcribed spacer.

rRNA expression levels were correlated with the grade of breast cancer

Expression of the 45S ETS region (TBP normalization) in tumor samples (n=11) was positively correlated with the grade of breast cancer (Spearman r=0.650, p=0.03). Additionally, the 28S/GM-rRNA ratio of tumor samples was also positively correlated (Spearman r=0.725, p=0.012) while the 18S/GM-rRNA ratio was negatively correlated with the grade (Spearman r=−0.714, p=0.014).

Discussion

A high expression of rRNA transcripts characterizes cancer cells but only a few studies have analyzed the expression of 18S rRNA in breast cancer tissues and matched normal samples. Previous studies have mostly focused on testing whether rRNA genes are suitable as reference genes (26,27). One of these studies found that 18S rRNA was expressed at lower levels in breast tumors compared to matched normal tissues in contrast to the general acceptance of higher rRNA expression in tumors (26). None of the studies, however, investigated whether the expression difference between breast cancer and normal pairs was due to rDNA promoter methylation or whether the ratios of spliced products of the 45S precursor were differentially expressed between tumor and normal pairs in breast cancer.

DNA methylation is a well-known phenomenon that inactivates transcription by interfering with Pol II binding to the promoter (40); since Pol I and Pol II share common features and transcription factors (4143), DNA methylation in the 45S rDNA promoter may have a similar effect on expression of rRNA genes.

We used both breast cancer cell lines and clinical breast cancer tissues to investigate the methylation levels of rDNA promoters and expression differences of rRNA transcripts, as well as their relationship with each other in breast cancer. We found that breast cancer cell lines were hypermethylated (74–96% methylation) at the 45S rDNA promoter region (Fig. 2). High methylation levels of rDNA promoters are frequently identified in many transformed cell lines such as Jurkat, CEM, HeLa, KB (44), NIH 3T3 (45) and HEK293 (46). A genome-wide analysis of aberrant methylation changes with aging in mammals identified the rDNA gene locus in which methylation levels increased age-dependently in both spermatozoa and rat liver cells (47). If the rDNA locus is sensitive to accumulating random methylation over time, the high methylation levels found in breast cancer cell lines may be explained with long-continued culturing, a common characteristic of cancer cell lines.

We could not identify two populations of alleles (one population with a hypermethylated promoter, the other population with a hypomethylated promoter; Fig. 2) in breast cancer cell lines as proposed earlier by other studies (2225). Considering the repetitive nature of rRNA genes, this result may be due to the low number of clones (5 clones) analyzed for each cell line. Breast cancer cell lines with hypermethylated 45S rDNA promoters did not repress or alter the ratio of rRNA transcripts (Fig. 4). rRNA expression levels and proportions of rRNA transcripts were found to be independent of the rDNA promoter methylation levels; this result may indicate that the methylation of the 45S rDNA promoter may not be solely responsible for rRNA expression or proportion changes in breast cancer cell lines. Completely methylated (Xenopus leavis sperm DNA) and unmethylated rDNA constructs were found to be transcribed with equal efficiency when transfected to Xenopus leavis oocytes (48). This is consistent with our results in which expression of rRNA transcripts was found to be relatively independent of their rDNA promoter methylation levels.

Upon 5-AZA treatment of breast cancer cell lines, expression of some forms of mature rRNA transcripts (significant for 5.8S RNA and 45S ETS) unexpectedly decreased compared to the DMSO-treated group when normalized with TBP (Fig. 5A), while rRNA proportions were not significantly altered within the rRNA pool (Fig. 5B). A recent study demonstrated that the loss of CpG methylation of the rDNA promoter (either with 5-AZA treatment or DNMT knockout) regions caused cryptic transcription of RNA polymerase II from 45S rDNA promoters. Cryptic transcription from rDNA promoters by RNA polymerase II significantly correlates with reduced modification and processing of rRNA transcripts (25). Loss of CpG methylation at rDNA promoter regions in 5-AZA-treated breast cancer cell lines may be affected by this cryptic RNA polymerase II transcription, which explains the downregulation of 5.8S and 45S ETS rRNA transcripts in the 5-AZA-treated cell lines. This mechanism, which acts as a negative feedback loop, may be a strategy developed by cells to achieve a balanced expression of rRNA transcripts and prevent energy loss in cells in the absence of CpG methylation.

Gene expression is usually regulated by a combination of DNA methylation, histone modifications and the activities of chromatin remodeling complexes (49). TSA treatment alone and 5-AZA+TSA treatment did not result in a significant increase in rRNA levels (Fig. 6A), yet the 5.8S rRNA ratio was decreased in the 5-AZA+TSA treated group (Fig. 6B). rRNA transcription may predominantly be regulated by other transcriptional or post-transcriptional mechanisms rather than epigenetic regulatory processes (at least DNA methylation and histone acetylation) in breast cancer cell lines.

The discrepancy between rRNA expression levels (TBP normalization) and rRNA ratios (GM-rRNAs) in the 5-AZA- and 5-AZA+TSA-treated groups, compared to their controls, may result from expression changes of TBP upon drug treatment. The change may also be due to some indirect effect of the drugs through other genes as both drugs affect several other genes along with the rDNA genes.

Further analysis of rDNA promoter methylation with the Wilcoxon matched-pairs signed rank test in tissues showed that most of the breast tumors (13/19) had significantly higher methylation levels than their normal counterparts (Fig. 3A). Our findings indicated similarities of methylation patterns within tumors and between tumor and adjacent normal tissues, indicating tissue- and/or locus-specificity of methylation. Methylation analysis of the same region in different tissues and types of cancer may reveal whether the methylation pattern of this region is tissue-specific, cancer-specific or neither, since different tissues display different methylation patterns at different loci (50).

Previous studies have identified rDNA methylation as a prognostic factor in some cancer types (31,51) including breast cancer (30). However, the correlation analysis of methylation levels with clinicopathological characteristics (as described in Table I) of the patients used in the present study did not show any significance (data not shown). Similarly, a breast carcinoma study on 45 paired breast tumor and normal samples could not identify any significant associations between methylation of rDNA promoters, 5′ regions of 18S and 28S rDNA and ER, PR, grade and other clinicopathological features, except nuclear size and grade (32). The use of larger sample sizes may help clarify the clinical importance of rDNA methylation in breast cancer. rRNA transcript expression (45S/TBP and 28S/GM-rRNA) in tumors on the other hand showed a positive correlation with the grade of the tumor. Nuclear pleomorphism is one of the criteria used in the grading of breast cancer, which includes classification of tumors by the size and the shape of the nucleoli (52). An increase in the expression or the ratio of rRNA transcripts may be responsible for the abnormal appearance of nucleoli in higher grade breast cancer samples.

Expression analyses of rRNA transcripts with TBP and GM-rRNA normalizations revealed different sides of the same coin. While the former enables measurement of expression with respect to a stable mRNA pool, use of the latter reflects changes in the relative ratios of rRNA transcript levels. Our data accordingly revealed that 5.8S and 45S rRNA transcripts were downregulated in the 5-AZA-treated cell lines with TBP normalization (Fig. 5A). However, 5-AZA treatment did not affect rRNA ratios in the cell lines (Fig. 5B). Unlike the cell line results, expression analysis of rRNA genes in the breast tumor and matched normal tissues showed no significant difference when normalized with TBP (Fig. 7A) while 18S and 5.8S rRNAs were proportionally altered in the breast tumor tissue samples (Fig. 7B). As stated earlier, the disparity between TBP and GM-rRNA normalizations could be due to the fact that they analyze separate aspects of rRNA expression.

A recent study with results supporting our findings demonstrated that two rRNA forms (5.8S and 45S precursors) were overexpressed (TBP normalization) in clinical prostate cancer tissues compared to matched-benign tissues. However, methylation levels of the 45S rDNA promoter in the same prostate tumor and normal pairs were not significantly different (24). Another study showed that loss of CpG methylation at the rDNA promoter surprisingly decrease rRNA transcript levels by disrupting rRNA synthesis and processing via activating cryptic transcription of rRNA genes by Pol II (25).

Different studies have used various reference genes, TBP and ACTB being among the most common, to determine rRNA expression levels in cancer (23,24,35). We used TBP (a RNA polymerase II transcribed gene) to normalize rRNA gene expression and found no significant differences between the breast tumor and matched normal samples. ACTB also failed to identify such differences in our cohort (data not shown). We propose that the geometric mean (GM) of rRNAs synthesized by RNA polymerase I (18S, 5.8S, 28S and 45S ETS) to normalize rRNA expression can be used to detect relative changes in rRNAs with each other. GM-rRNA may be less prone to changes than Pol II gene transcripts since it is calculated from the rRNA transcripts synthesized by Pol I. When GM-rRNA was used for normalization, 5.8S and 18S rRNA expression levels were significantly upregulated and downregulated, respectively, in the tumor samples compared to the normal pairs (Fig. 7B). Our data indicate that the proportion of 18S and 5.8S rRNA in the total rRNA pool changed in the opposite direction while total rRNA levels may be relatively constant. We found that methylation levels of normal samples (which exhibit mixed methylation patterns) showed a negative correlation with the 18S rRNA/GM-rRNA expression level but this correlation was disrupted in the tumor samples (Fig. 8). As far as we are aware, this is the first study to show that the methylation status may be reflected in the expression of one or more rRNA transcripts but not all.

Some forms of polycistronic mRNAs and miRNAs that are expressed from the same promoter have been shown to be post-transcriptionally regulated and exist at different levels in plants (53,54). The SNRPN-SNURF gene, possessing a biscistronic structure and sharing a common promoter, for example, is differentially expressed, as identified by both northern blot and microarray analysis in mammalian cells (55,56). As reported in other studies, genes that are expressed from the same promoter can be differentially expressed by other mechanisms apart from the effect of basal transcription machinery.

The maturation of ribosomes is a complex process assisted by multiple factors (~200) that need to be orchestrated in harmony (57,58). Alteration in the methylation levels of rDNA promoters may have an effect on rRNA stabilization, which could leads to this non-proportional change in rRNA transcripts. Moderate levels of rDNA promoter methylation (as observed in normal samples) may still be regulating 18S rRNA levels but this correlation is disrupted in tumor samples, possibly due to the high methylation levels found in the 45S rDNA promoter. Another possibility is that methylation levels can indirectly affect splicing, post-transcriptional modifications and stabilization of rRNA transcripts (25). The fact that normal samples showed a higher correlation between rRNA transcript expression while this correlation was disrupted in tumor samples supported this possibility (Table III), indicating that the methylated promoter of 45S rDNA in tumors may have an effect on the processing of rRNAs.

Since rRNA processing and modification are largely dependent on snoRNAs, any change in snoRNA levels globally may be reflected in the rRNA ratios. U50 is a box C/D snoRNA that is required for 2′-O-methylation of two specific positions in the 28S rRNA and was shown to be altered by somatic rearrangements, mutations and deletions in prostate cancer (59), breast carcinoma (60), B-cell lymphoma (61) and colon cancer (62). Another snoRNA, GAS5, was also found to be downregulated in breast cancer (63). Increased methylation levels of rDNA promoters and their effect on rRNA modification and processing need to be better analyzed in future studies.

In conclusion, we found that rRNA transcripts were expressed independently of the hypermethylated 45S rDNA promoter region in breast cancer cell lines. However, the 18S rRNA/GM-rRNA ratios were significantly correlated with methylation levels in the normal samples but not in the tumor samples. Promoter methylation of rDNA promoters appears to have a different role than regulating the expression of rRNA transcripts in breast cancer. It may be used as a mechanism to stabilize and protect these essential genes under any circumstances. rDNA repeats have been proposed to be responsible for genomic stability (64) and hypomethylation of rDNA promoter has been implicated in decreased genomic stability (65,66). Increased methylation of the rDNA promoter in tumor cells may be an indicator of the tumor cell effort to restore impaired genomic stability. Future research is needed to evaluate the cause of relative expression changes observed among rRNA transcripts in tumors and their relationship with rDNA promoter methylation.

Acknowledgments

The present study was supported by the Scientific and Technical Research Council of Turkey (TUBITAK) (grant no. TBAG-107T181). We thank Dr Daniel Press for the English editing of the manuscript.

Abbreviations:

rRNA

ribosomal RNA

rDNA

ribosomal DNA

GM-rRNA

geometric mean of rRNA expression values

5-AZA

5-aza-2′-deoxycytidine

TSA

trichostatin A

References

1 

Ferlay J, Soerjomataram I, Ervik M, Dikshit R, Eser S, Mathers C, Rebelo M, Parkin DM, Forman D and Bray F: GLOBOCAN 2012 v1.0, Cancer Incidence and Mortality Worldwide. (IARC CancerBase No. 11). http://globocan.iarc.fr. 2013

2 

Lalloo F and Evans DG: Familial breast cancer. Clin Genet. 82:105–114. 2012. View Article : Google Scholar : PubMed/NCBI

3 

Jaenisch R and Bird A: Epigenetic regulation of gene expression: How the genome integrates intrinsic and environmental signals. Nat Genet. 33(Suppl): S245–S254. 2003. View Article : Google Scholar

4 

Salozhin SV, Prokhorchuk EB and Georgiev GP: Methylation of DNA - one of the major epigenetic markers. Biochemistry. 70:525–532. 2005.

5 

Nafee TM, Farrell WE, Carroll WD, Fryer AA and Ismail KM: Epigenetic control of fetal gene expression. BJOG. 115:158–168. 2008. View Article : Google Scholar

6 

Esteller M: Aberrant DNA methylation as a cancer-inducing mechanism. Annu Rev Pharmacol Toxicol. 45:629–656. 2005. View Article : Google Scholar : PubMed/NCBI

7 

Karpinets TV and Foy BD: Tumorigenesis: The adaptation of mammalian cells to sustained stress environment by epigenetic alterations and succeeding matched mutations. Carcinogenesis. 26:1323–1334. 2005. View Article : Google Scholar : PubMed/NCBI

8 

Baylin SB and Ohm JE: Epigenetic gene silencing in cancer - a mechanism for early oncogenic pathway addiction? Nat Rev Cancer. 6:107–116. 2006. View Article : Google Scholar : PubMed/NCBI

9 

Dez C and Tollervey D: Ribosome synthesis meets the cell cycle. Curr Opin Microbiol. 7:631–637. 2004. View Article : Google Scholar : PubMed/NCBI

10 

McKnight SL and Miller OL Jr: Ultrastructural patterns of RNA synthesis during early embryogenesis of Drosophila melanogaster. Cell. 8:305–319. 1976. View Article : Google Scholar : PubMed/NCBI

11 

Schmickel RD: Quantitation of human ribosomal DNA: Hybridization of human DNA with ribosomal RNA for quantitation and fractionation. Pediatr Res. 7:5–12. 1973. View Article : Google Scholar : PubMed/NCBI

12 

Warner JR: The economics of ribosome biosynthesis in yeast. Trends Biochem Sci. 24:437–440. 1999. View Article : Google Scholar : PubMed/NCBI

13 

Russell J and Zomerdijk JC: RNA-polymerase-I-directed rDNA transcription, life and works. Trends Biochem Sci. 30:87–96. 2005. View Article : Google Scholar : PubMed/NCBI

14 

Paule MR and White RJ: Survey and summary: Transcription by RNA polymerases I and III. Nucleic Acids Res. 28:1283–1298. 2000. View Article : Google Scholar : PubMed/NCBI

15 

Learned RM, Learned TK, Haltiner MM and Tjian RT: Human rRNA transcription is modulated by the coordinate binding of two factors to an upstream control element. Cell. 45:847–857. 1986. View Article : Google Scholar : PubMed/NCBI

16 

Clos J, Buttgereit D and Grummt I: A purified transcription factor (TIF-IB) binds to essential sequences of the mouse rDNA promoter. Proc Natl Acad Sci USA. 83:604–608. 1986. View Article : Google Scholar : PubMed/NCBI

17 

Eichler DC and Craig N: Processing of eukaryotic ribosomal RNA. Prog Nucleic Acid Res Mol Biol. 49:197–239. 1994. View Article : Google Scholar : PubMed/NCBI

18 

Trapman J, Retèl J and Planta RJ: Ribosomal precursor particles from yeast. Exp Cell Res. 90:95–104. 1975. View Article : Google Scholar : PubMed/NCBI

19 

Venema J and Tollervey D: Ribosome synthesis in Saccharomyces cerevisiae. Annu Rev Genet. 33:261–311. 1999. View Article : Google Scholar

20 

Esteller M: Epigenetic gene silencing in cancer: The DNA hypermethylome. Hum Mol Genet. 16:R50–R59. 2007. View Article : Google Scholar : PubMed/NCBI

21 

Worton RG, Sutherland J, Sylvester JE, Willard HF, Bodrug S, Dubé I, Duff C, Kean V, Ray PN and Schmickel RD: Human ribosomal RNA genes: Orientation of the tandem array and conservation of the 5′ end. Science. 239:64–68. 1988. View Article : Google Scholar : PubMed/NCBI

22 

Ghoshal K, Majumder S, Datta J, Motiwala T, Bai S, Sharma SM, Frankel W and Jacob ST: Role of human ribosomal RNA (rRNA) promoter methylation and of methyl-CpG-binding protein MBD2 in the suppression of rRNA gene expression. J Biol Chem. 279:6783–6793. 2004. View Article : Google Scholar

23 

Raval A, Sridhar KJ, Patel S, Turnbull BB, Greenberg PL and Mitchell BS: Reduced rRNA expression and increased rDNA promoter methylation in CD34+ cells of patients with myelodys-plastic syndromes. Blood. 120:4812–4818. 2012. View Article : Google Scholar : PubMed/NCBI

24 

Uemura M, Zheng Q, Koh CM, Nelson WG, Yegnasubramanian S and De Marzo AM: Overexpression of ribosomal RNA in prostate cancer is common but not linked to rDNA promoter hypomethylation. Oncogene. 31:1254–1263. 2012. View Article : Google Scholar :

25 

Gagnon-Kugler T, Langlois F, Stefanovsky V, Lessard F and Moss T: Loss of human ribosomal gene CpG methylation enhances cryptic RNA polymerase II transcription and disrupts ribosomal RNA processing. Mol Cell. 35:414–425. 2009. View Article : Google Scholar : PubMed/NCBI

26 

Gur-Dedeoglu B, Konu O, Bozkurt B, Ergul G, Seckin S and Yulug IG: Identification of endogenous reference genes for qRT-PCR analysis in normal matched breast tumor tissues. Oncol Res. 17:353–365. 2009. View Article : Google Scholar : PubMed/NCBI

27 

Tricarico C, Pinzani P, Bianchi S, Paglierani M, Distante V, Pazzagli M, Bustin SA and Orlando C: Quantitative real-time reverse transcription polymerase chain reaction: Normalization to rRNA or single housekeeping genes is inappropriate for human tissue biopsies. Anal Biochem. 309:293–300. 2002. View Article : Google Scholar : PubMed/NCBI

28 

de Kok JB, Roelofs RW, Giesendorf BA, Pennings JL, Waas ET, Feuth T, Swinkels DW and Span PN: Normalization of gene expression measurements in tumor tissues: Comparison of 13 endogenous control genes. Lab Invest. 85:154–159. 2005. View Article : Google Scholar

29 

Chan MW, Wei SH, Wen P, Wang Z, Matei DE, Liu JC, Liyanarachchi S, Brown R, Nephew KP, Yan PS, et al: Hypermethylation of 18S and 28S ribosomal DNAs predicts progression-free survival in patients with ovarian cancer. Clin Cancer Res. 11:7376–7383. 2005. View Article : Google Scholar : PubMed/NCBI

30 

Yan PS, Rodriguez FJ, Laux DE, Perry MR, Standiford SB and Huang TH: Hypermethylation of ribosomal DNA in human breast carcinoma. Br J Cancer. 82:514–517. 2000. View Article : Google Scholar : PubMed/NCBI

31 

Powell MA, Mutch DG, Rader JS, Herzog TJ, Huang TH and Goodfellow PJ: Ribosomal DNA methylation in patients with endometrial carcinoma: An independent prognostic marker. Cancer. 94:2941–2952. 2002. View Article : Google Scholar : PubMed/NCBI

32 

Bacalini MG, Pacilli A, Giuliani C, Penzo M, Treré D, Pirazzini C, Salvioli S, Franceschi C, Montanaro L and Garagnani P: The nucleolar size is associated to the methylation status of ribosomal DNA in breast carcinomas. BMC Cancer. 14:3612014. View Article : Google Scholar : PubMed/NCBI

33 

Kumaki Y, Oda M and Okano M: QUMA: Quantification tool for methylation analysis. Nucleic Acids Res. 36:W170–W175. 2008. View Article : Google Scholar : PubMed/NCBI

34 

Haltiner MM, Smale ST and Tjian R: Two distinct promoter elements in the human rRNA gene identified by linker scanning mutagenesis. Mol Cell Biol. 6:227–235. 1986.PubMed/NCBI

35 

Brown SE and Szyf M: Dynamic epigenetic states of ribosomal RNA promoters during the cell cycle. Cell Cycle. 7:382–390. 2008. View Article : Google Scholar : PubMed/NCBI

36 

Guo C, Liu S, Wang J, Sun MZ and Greenaway FT: ACTB in cancer. Clin Chim Acta. 417:39–44. 2013. View Article : Google Scholar

37 

Guo C, Liu S and Sun MZ: Novel insight into the role of GAPDH playing in tumor. Clin Transl Oncol. 15:167–172. 2013. View Article : Google Scholar

38 

Esteller M, Corn PG, Baylin SB and Herman JG: A gene hyper-methylation profile of human cancer. Cancer Res. 61:3225–3229. 2001.PubMed/NCBI

39 

Ballestar E and Esteller M: Epigenetic gene regulation in cancer. Adv Genet. 61:247–267. 2008. View Article : Google Scholar : PubMed/NCBI

40 

Eden S and Cedar H: Role of DNA methylation in the regulation of transcription. Curr Opin Genet Dev. 4:255–259. 1994. View Article : Google Scholar : PubMed/NCBI

41 

Sentenac A: Eukaryotic RNA polymerases. CRC Crit Rev Biochem. 18:31–90. 1985. View Article : Google Scholar : PubMed/NCBI

42 

Sharp PA: TATA-binding protein is a classless factor. Cell. 68:819–821. 1992. View Article : Google Scholar : PubMed/NCBI

43 

Comai L, Tanese N and Tjian R: The TATA-binding protein and associated factors are integral components of the RNA polymerase I transcription factor, SL1. Cell. 68:965–976. 1992. View Article : Google Scholar : PubMed/NCBI

44 

Kochanek S, Hosokawa K, Schiedner G, Renz D and Doerfler W: DNA methylation in the promoter of ribosomal RNA genes in human cells as determined by genomic sequencing. FEBS Lett. 388:192–194. 1996. View Article : Google Scholar : PubMed/NCBI

45 

Németh A, Guibert S, Tiwari VK, Ohlsson R and Längst G: Epigenetic regulation of TTF-I-mediated promoter-terminator interactions of rRNA genes. EMBO J. 27:1255–1265. 2008. View Article : Google Scholar : PubMed/NCBI

46 

Brown SE and Szyf M: Epigenetic programming of the rRNA promoter by MBD3. Mol Cell Biol. 27:4938–4952. 2007. View Article : Google Scholar : PubMed/NCBI

47 

Oakes CC, Smiraglia DJ, Plass C, Trasler JM and Robaire B: Aging results in hypermethylation of ribosomal DNA in sperm and liver of male rats. Proc Natl Acad Sci USA. 100:1775–1780. 2003. View Article : Google Scholar : PubMed/NCBI

48 

Macleod D and Bird A: Transcription in oocytes of highly methylated rDNA from Xenopus laevis sperm. Nature. 306:200–203. 1983. View Article : Google Scholar : PubMed/NCBI

49 

Richards EJ and Elgin SC: Epigenetic codes for heterochro-matin formation and silencing: Rounding up the usual suspects. Cell. 108:489–500. 2002. View Article : Google Scholar : PubMed/NCBI

50 

Muangsub T, Samsuwan J, Tongyoo P, Kitkumthorn N and Mutirangura A: Analysis of methylation microarray for tissue specific detection. Gene. 553:31–41. 2014. View Article : Google Scholar : PubMed/NCBI

51 

Chan MW, Wei SH, Wen P, Wang Z, Matei DE, Liu JC, Liyanarachchi S, Brown R, Nephew KP, Yan PS, et al: Hypermethylation of 18S and 28S ribosomal DNAs predicts progression-free survival in patients with ovarian cancer. Clin Cancer Res. 11:7376–7383. 2005. View Article : Google Scholar : PubMed/NCBI

52 

Egner JR: AJCC Cancer Staging Manual. JAMA J Am Med Assoc. 304:17262010. View Article : Google Scholar

53 

Jia F and Rock CD: MIR846 and MIR842 comprise a cistronic MIRNA pair that is regulated by abscisic acid by alternative splicing in roots of Arabidopsis. Plant Mol Biol. 81:447–460. 2013. View Article : Google Scholar : PubMed/NCBI

54 

Malik Ghulam M, Courtois F, Lerbs-Mache S and Merendino L: Complex processing patterns of mRNAs of the large ATP synthase operon in Arabidopsis chloroplasts. PLoS One. 8:e782652013. View Article : Google Scholar : PubMed/NCBI

55 

Li SS, Yu SL and Singh S: Epigenetic states and expression of imprinted genes in human embryonic stem cells. World J Stem Cells. 2:97–102. 2010. View Article : Google Scholar

56 

Gray TA, Saitoh S and Nicholls RD: An imprinted, mammalian bicistronic transcript encodes two independent proteins. Proc Natl Acad Sci USA. 96:5616–5621. 1999. View Article : Google Scholar : PubMed/NCBI

57 

Kiss T, Fayet E, Jády BE, Richard P and Weber M: Biogenesis and intranuclear trafficking of human box C/D and H/ACA RNPs. Cold Spring Harb Symp Quant Biol. 71:407–417. 2006. View Article : Google Scholar

58 

Terns M and Terns R: Noncoding RNAs of the H/ACA family. Cold Spring Harb Symp Quant Biol. 71:395–405. 2006. View Article : Google Scholar

59 

Dong XY, Rodriguez C, Guo P, Sun X, Talbot JT, Zhou W, Petros J, Li Q, Vessella RL, Kibel AS, et al: SnoRNA U50 is a candidate tumor-suppressor gene at 6q14.3 with a mutation associated with clinically significant prostate cancer. Hum Mol Genet. 17:1031–1042. 2008. View Article : Google Scholar : PubMed/NCBI

60 

Dong XY, Guo P, Boyd J, Sun X, Li Q, Zhou W and Dong JT: Implication of snoRNA U50 in human breast cancer. J Genet Genomics. 36:447–454. 2009. View Article : Google Scholar : PubMed/NCBI

61 

Tanaka R, Satoh H, Moriyama M, Satoh K, Morishita Y, Yoshida S, Watanabe T, Nakamura Y and Mori S: Intronic U50 small-nucleolar-RNA (snoRNA) host gene of no protein-coding potential is mapped at the chromosome breakpoint t(3;6) (q27;q15) of human B-cell lymphoma. Genes Cells. 5:277–287. 2000. View Article : Google Scholar : PubMed/NCBI

62 

Pacilli A, Ceccarelli C, Treré D and Montanaro L: SnoRNA U50 levels are regulated by cell proliferation and rRNA transcription. Int J Mol Sci. 14:14923–14935. 2013. View Article : Google Scholar : PubMed/NCBI

63 

Mourtada-Maarabouni M, Pickard MR, Hedge VL, Farzaneh F and Williams GT: GAS5, a non-protein-coding RNA, controls apoptosis and is downregulated in breast cancer. Oncogene. 28:195–208. 2009. View Article : Google Scholar

64 

Kobayashi T: Ribosomal RNA gene repeats, their stability and cellular senescence. Proc Jpn Acad Ser B Phys Biol Sci. 90:119–129. 2014. View Article : Google Scholar : PubMed/NCBI

65 

Peng JC and Karpen GH: H3K9 methylation and RNA interference regulate nucleolar organization and repeated DNA stability. Nat Cell Biol. 9:25–35. 2007. View Article : Google Scholar

66 

Kobayashi T: A new role of the rDNA and nucleolus in the nucleus - rDNA instability maintains genome integrity. Bioessays. 30:267–272. 2008. View Article : Google Scholar : PubMed/NCBI

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June-2015
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Spandidos Publications style
Karahan G, Sayar N, Gozum G, Bozkurt B, Konu O and Yulug IG: Relative expression of rRNA transcripts and 45S rDNA promoter methylation status are dysregulated in tumors in comparison with matched-normal tissues in breast cancer. Oncol Rep 33: 3131-3145, 2015.
APA
Karahan, G., Sayar, N., Gozum, G., Bozkurt, B., Konu, O., & Yulug, I.G. (2015). Relative expression of rRNA transcripts and 45S rDNA promoter methylation status are dysregulated in tumors in comparison with matched-normal tissues in breast cancer. Oncology Reports, 33, 3131-3145. https://doi.org/10.3892/or.2015.3940
MLA
Karahan, G., Sayar, N., Gozum, G., Bozkurt, B., Konu, O., Yulug, I. G."Relative expression of rRNA transcripts and 45S rDNA promoter methylation status are dysregulated in tumors in comparison with matched-normal tissues in breast cancer". Oncology Reports 33.6 (2015): 3131-3145.
Chicago
Karahan, G., Sayar, N., Gozum, G., Bozkurt, B., Konu, O., Yulug, I. G."Relative expression of rRNA transcripts and 45S rDNA promoter methylation status are dysregulated in tumors in comparison with matched-normal tissues in breast cancer". Oncology Reports 33, no. 6 (2015): 3131-3145. https://doi.org/10.3892/or.2015.3940