High-mobility group AT-hook protein 2 expression and its prognostic significance in MGMT methylated and unmethylated glioblastoma
- Authors:
- Published online on: February 17, 2016 https://doi.org/10.3892/ijo.2016.3397
- Pages: 1485-1492
Abstract
Introduction
High-mobility group (HMG) proteins are heterogeneous non-histone DNA-binding factors that organize active chromatin (1). High-mobility group AT-hook protein 2 (HMGA 2) belongs to this family and is located at chromosome 12q14 and encodes an 109 amino acid protein. The functional unit of all HMGA proteins are 3 copies of a conserved DNA-binding peptide motif (‘AT-hooks’) that cause the binding to adenine- thymine (AT)-rich regions of nuclear DNA (2,3). HMGA 2 is expressed primarily in the early embryonic development, and is suppressed in differentiated cells (4). Some reports suggest that HMG proteins regulate the expression of one or more genes that control embryonic cell growth and differentiation (1,4). Furthermore, HMG may also affect the expression of oncogenes and tumor suppressor genes (5). HMGA 2 is regulated by let-7, a tumor suppressor microRNA (miRNA), which is downregulated in regards to cancer development (6). A directly regulatory relationship between let-7a (member of let-7 family) and HMGA 2 regulation has been confirmed in breast, lung and esophageal cancers (7–9).
HMGA 2 is not expressed in normal human adult tissue but it can be detected in many human tumors including lipoma, leiomyoma and pituitary tumors, which are benign tumors but they can be very invasive (10,11). Furthermore, HMGA 2 is also expressed in malignant neoplasms such as colorectal, lung, gastric, ovarian and breast cancers, neuroblastoma and glioblastoma (12–19).
Prior studies showed that miR-142-3p, a miRNA in pluripotent stem cells, suppresses the expression of HMGA 2 targeting the 3′UTR, and thus, decreasing the expression of Sox2, a transcription factor in stem cells. HMGA 2 increases the transcription of Sox2 through directly binding to the Sox2 promoter gene region. Patients with an upregulated HMGA 2 expression demonstrated a poor overall survival (20). miRNA alterations are involved in the initiation and progression of human cancer (6). Morishita et al (21) conducted a study demonstrating the molecular mechanisms of HMGA 2 in tumor pathogenesis through activation of the TGFβ signaling pathway, a major inducer of the epithelial-mesenchymal-transition (EMT), in epithelial carcinomas. Their results showed that HMGA 2 plays a critical role in inducing tumor invasion, and metastasis in EMT by activating the TGFβ signaling pathway.
A study by Liu et al (16) presented a significant correlation of HMGA 2 expression, and glioblastoma cell proliferation, invasion and survival. Glioblastomas are highly invasive, rapidly growing, scatter along the white matter tracts and their structure is poorly differentiated. Furthermore, glioblastoma represents the most aggressive type of glial brain tumors. Treatment is rarely effective despite gross total resection, chemotherapy, radiotherapy or all of them (22). MGMT (O-6-methylguanine-DNA methyltransferase) methylation status and the analysis of IDH1 and IDH2 mutations has become diagnostic and prognostic standards, and there are numerous studies investigating new molecular markers for a better characterization of this tumor entity (23–25).
Unfortunately, the recurrence of glioblastoma is still inevitable after a median progression-free period of 6.8 months (26). Consequently, novel therapies targeting cell proliferation and invasion e.g. through gene therapy may become a more effective strategy (27).
Based on the available data, HMGA 2 could be a biomarker and a potential target in glioblastoma therapy. Therefore, in the present study, we investigated the expression of HMGA 2 in glioblastoma patients, and we correlated the expression data with clinical parameters, survival and MGMT methylation status.
Materials and methods
Patient data
A retrospective analysis of medical records was conducted and clinical data were extracted. Variables assessed include: birth date, gender, date of diagnosis, date of operation/reoperation, type/date of chemotherapy, type/date of radiotherapy, MRI follow-up reports, relapse status, date of relapse, date of last follow-up, and vital status at last follow-up. All patients were periodically followed for survival. The follow-up period was calculated from the date of surgery to the date of last contact. The time of progression-free survival (PFS) was defined as at the time of initial surgical therapy to tumor recurrence.
Tissue specimens
A total of 44 diagnostically confirmed cases of glioblastoma (WHO IV) were retrieved as formalin-fixed, paraffin-embedded tissue blocks and kryopreserved tissue between 2006 and 2012 from the Department of Neuropathology, University of Giessen, Giessen, Germany. Five normal brain tissue specimens were used as reference for tumor-free brain tissue and a breast cancer specimen was used as a positive control provided by the same institution. The present study was approved by the local ethics committee (application number: AZ 07/09).
RNA-isolation, quantitative real-time PCR
RNA-isolation was performed from frozen specimens stored in fluid nitrogen using the RNeasy Lipid Tissue Mini kit® from Qiagen GmbH (Hilden, Germany). RNA concentration was measured photometrically (peqLab NanoDrop® 1000 Spectrophotometer; VWR International GmbH Life Science Competence Center, Erlangen, Germany). Total RNA (1 μg) was used for cDNA synthesis with the QuantiTect® reverse transcription kit (Qiagen). Quantitative real-time PCR (qPCR) was performed along with the following human primers with the Mastercycler Gradient Thermal Cycler® (Eppendorf, Hamburg, Germany): actin-β, human (Hs99999903), IPO8, human (Hs00914040), HMGA 2, human (Hs00171569_m1), TBP, human (Hs00427620) (all from Life Technologies Inc., Carlsbad, CA, USA). Reaction setup and cycling conditions adhered to the kit manual. Reaction efficiency was determined using standard curves, gene expression levels calculated by the ΔΔCt method and expressed as efficiency corrected log2 values. Additionally, the linear n-fold expression ratio of cases/controls was calculated by first converting the log2 values to linear and calculating the ratio of cases/controls to facilitate easy comprehension of the gene expression changes.
Raw cycle threshold (Ct) data of qPCR experiments were processed by subtracting the mean Ct of all endogenous control genes (actin-β, IPO8 and TBP) from the Ct of the according gene of interest (HMGA 2). Taking into account the exponential nature of PCR methodology, relative expression was obtained from the resulting ΔCt value using the formula of 2−ΔCt.
In preliminary experiments, we analyzed samples from the individual frontal, parietal, temporal, occipital and cerebellar lobes for HMGA 2 expression using qPCR. No significant differences in expression were found between these anatomical regions (data not shown). Therefore, we did not further match the control samples to the anatomical brain regions of the tumors.
Immunohistochemistry
Of all samples investigated using qPCR, a subset of 44 tumor samples and 5 non-tumorous brain tissue samples were available as paraffin-embedded tissue and used for immunohistochemistry. Samples from breast cancers were used as positive controls. Immunohistochemical staining was performed using the BenchMark XT IHC fully automated staining instrument (Ventana Medical Systems, Tucson, AZ, USA) following the manufacturer's instructions on 3-μm paraffin sections. A polyclonal rabbit antibody against HMGA 2 (ab52039; Abcam, Cambridge, UK) was used with a final dilution of 1:25.
Quantification of immunohistochemical staining
The sections were microscopically (Leica DMLB microscope; Leica Microsystems, Wetzlar, Germany) assessed in ×200 and x400 magnification by two investigators (C.W. and F.P.S.) who were blinded to patient characteristics and outcome. Immunoreactivity score (IRS) was determined using staining intensity and number of positively stained cells (nuclear expression). Staining intensity was determined on the following scale: 0 (no staining), 1 (weak staining, light yellow), 2 (moderate staining, yellowish brown), and 3 (strong staining, brown). In addition, the percentage of positive cells was semi-quantitatively determined (0–100% in 10% steps). IRS was calculated as the product of staining intensity and percentage of positive tumor cells, resulting in a value ranging from 0 to 30. The k-statistics of the analyzed immunohistochemical stained slides revealed a kappa value of 0.534 for HMGA 2. Differences in assessment were discussed until consensus was reached.
Calculation of HMGA 2 gene expression and statistical analysis
qPCR and calculation of gene expression
Gene expression calculations were performed using the ΔΔCt method in GenEx 6 (Multid Analyses AB, Göteborg, Sweden). Stable expression of housekeeping genes β-actin (ACTB), TATA-binding protein (TBP) and importin (IPO) were assessed using the NormFinder algorithm, hereby confirming suitability of all 3 genes to be used as references in our samples. Normalization of HMGA 2 was performed against these three housekeeping genes and expression levels were calculated for normal brain tissue and glioblastoma specimens. To allow direct comparison, data are shown as 2−ΔCt values unless otherwise indicated.
Statistical analysis
The following statistical assessments were performed using the Mann-Whitney U test: gene expression levels in MGMT methylated vs. unmethylated patients, gene expression levels between patient groups, both for qPCR and immunohistochemical data. The relationship between HMGA2 expression, regression-free survival and overall survival was analyzed using the Kaplan-Meier method and the log-rank test. Survival analysis was performed by dividing patients into low and high expression groups. Low expression was defined as normalized gene expression levels equal or below the mean expression of each respective tumor group, while all other patients within this group were classified as high expression. To analyze further the influence of HMGA 2 expression, we performed a multivariate analysis of variance (MANOVA) stratified according to age, HMGA 2 gene expression on mRNA and protein levels, MGMT methylation status, progression-free survival (PFS) and overall survival (OS). P-values of <0.05 were considered statistically significant throughout the analyses.
Results
Patient collective
The patient collective included 44 gross total resected glioblastoma (WHO grade IV) patients, 40 of whom were diagnosed with primary, and 4 with secondary glioblastoma. Mean age at diagnosis was 57.4±15.7 years. The study population consisted of 31 male and 13 female patients. The patients' median survival time was 16 months (SE 2.8; 95% CI, 10.6–21.4). Two of the patients had received chemotherapy or radiotherapy prior to first surgery.
Further details are listed in Table I. Five normal brain tissue specimens were used as reference for tumor-free brain tissue.
HMGA 2 mRNA expression in glioblastoma and normal brain tissue
A subset of 40 glioblastoma specimens along with 5 normal brain tissues were analyzed performing qRT-PCR. The HMGA 2 expression on mRNA levels in glioblastomas were upregulated (mean, 0.35; SD, 0.27) compared to non-tumorous brain tissue (mean, 0.03; SD, 0.05). HMGA 2 gene expression was significantly higher in glioblastoma (P=0.001) (Figs. 1 and 2).
HMGA 2 protein expression in glioblastoma and normal brain tissue
Forty-four glioblastoma specimens along with 5 normal brain tissues were analyzed by immunohistochemistry confirming the expression difference seen in the qRT-PCR analysis: IRS of HMGA 2 was significantly higher in glio-blastoma tissue (mean, 17.21; SD, 7.43) than in normal brain tissue (mean, 3.20; SD, 1.68) (P<0.001). Thus, HMGA 2 gene expression was significantly higher in glioblastoma than in non-tumorous brain tissue (Figs. 1 and 2).
HMGA 2 expression as a parameter of MGMT methylation status
The analysis of HMGA 2 expression as a parameter of MGMT methylation status showed no significant differences in qPCR and immunohistochemistry analysis. On protein level there were no expression differences of HMGA 2 between methylated and unmethylated patients (P=0.87). On mRNA levels a slightly higher HMGA 2 expression was seen for unmethylated patients (P=0.09) (Fig. 3).
Progression-free survival (PFS) time as a parameter of MGMT-methylation status and HMGA 2 mRNA and protein expression
Progression-free survival (PFS) time in primary glioblastoma patients with surgical resection and adjuvant combined radio-chemotherapy with temozolomide and 60-Gy concomitant irradiation, stratified by MGMT promoter methylation was shorter with HMGA 2 upregulation (Fig. 4.) On mRNA levels 8 patients with positive MGMT promoter methylation status who had primary glioblastoma with high HMGA 2 levels had a median PFS time of 10.0 months (SE, 2.1; 95% CI, 5.8–14.2), whereas 7 patients with primary glioblastoma and low HMGA 2 expression and methylated MGMT had a median PFS time of 21.0 months (SE, 5.2; 95% CI 10.7–31.3) (P=0.14).
Three negative MGMT promoter methylation status patients with high HMGA 2 levels had a median PFS time of 8.0 months (SE, 2.4; 95% CI, 3.2–12.8), whereas 5 patients with primary glioblastoma and low HMGA 2 expression and negative MGMT promoter methylation status had a median PFS of 5.0 months (SE, 3.3, 95% CI 0.0–11.4) (P=0.90).
Overexpression of HMGA 2 showed a tendency to a shorter PFS time. These results on mRNA level were confirmed by IRS and showed no statistical significance (Fig. 4).
Overall survival (OS) time as a parameter of MGMT-methylation status and HMGA 2 mRNA and protein expression
The effect of HMGA 2 expression on overall survival (OS) time in primary glioblastoma patients with surgical resection and adjuvant combined radio-chemotherapy with temozolomide and 60-Gy concomitant irradiation, stratified by MGMT promoter methylation, showed a shorter OS time when HMGA 2 expression was upregulated (Fig. 4).
On mRNA levels 9 patients with positive MGMT promoter methylation status who had primary glioblastoma with high HMGA 2 levels had a median OS time of 20 months (SE, 6.0; 95% CI, 8.3–31.7), whereas 12 patients with primary glioblastoma and low HMGA 2 expression and positive MGMT promoter methylation status had a median OS time of 28.0 months (SE, 9.5; 95% CI, 9.3–46.7) (P=0.38). Eight negative MGMT promoter methylation status patients with high HMGA 2 levels had a median OS of 11 months (SE, 2.1; 95% CI, 6.8–15.2), whereas, 6 patients with primary glioblastoma and low HMGA 2 expression and negative MGMT promoter methylation status had a median OS time of 8 months (SE, 5.5; 95% CI, 0.0–20.8) (P=0.52).
Overexpression of HMGA 2 was associated with a tendency to a shorter OS time. These results on mRNA level were confirmed by IRS and showed no statistical significance (Fig. 4).
Multivariate analysis
The multivariate analysis of variance (MANOVA) showed no statistical significance except for HMGA 2 expression in tumor vs. normal brain tissue (P<0.05).
Discussion
In the past decades advances in neuroimaging, treatment paradigms and molecular approaches enabled neurosurgeons to better understand glioblastoma and its treatment (22,23,28–30). Numerous studies have been done on the invasive behavior of malignant gliomas, and there are many studies investigating new molecular markers to better characterize this tumor entity and improve clinical decision (23,31–38). The current standard of care consists of microsurgical gross total resection, if possible, concurrent radiotherapy, and temozolomide chemotherapy followed by adjuvant temozolomide (39,40).
Despite ongoing research efforts and aggressive treatment the median survival of glioblastoma patients still yields poor outcomes. The complete resection of the tumor is almost impossible because of the invasive growth of tumor cells and the lack of a clear border (41,42). New chemotherapy approaches with temozolomide showed an improvement of survival from 12 to 14.6 months (43).
To the best of our knowledge, this is the first study analyzing on HMGA 2 expression in glioblastoma with respect to the MGMT methylation status. Our results showed that HMGA 2 overexpression has an influence on progression-free and overall survival time of glioblastoma patients.
Previous research showed that HMGA 2 is not expressed in normal brain tissue (16). Also in the present series no HMGA 2 expression was found in five normal brain tissue controls.
Furthermore, HMGA 2 is associated with poor prognosis, malignancy and invasiveness in tumors such as gastric and lung cancer, retinoblastoma and pituitary adenoma (11,14,15,44). The expression of HMGA 2 correlates with the degree of malignancy of astrocytic brain tumors and shows an increase in higher grade gliomas. The highest HMGA 2 overexpression was detected in glioblastoma (16).
Inhibition of HMGA 2 leads to tumor growth inhibition and an increase of apoptosis in ovarian cancer (13). Halle et al (45) showed a possible mechanism to regulate the mRNA level of HMGA 2 due to repression of let-7a through local drug delivery with the convection-enhanced delivery (CED) technique. They showed an in vivo and in vitro de-repression of HMGA 2 after intratumoral therapy with CED. Thus, miRNAs and especially oncogenic miRNAs have the potential to impact on future cancer therapy (45).
In line with the study of Liu et al (16) in glioblastoma samples and on other human malignancies, the present study study showed that HMGA 2 was expressed in glioblastoma and not in normal brain tissue. Furthermore, overexpression of HMGA 2 in glioblastoma is reported to be closely correlated with poor survival prognosis (16,44). In the present study, the overall and tumor progression-free survival time tended to be shorter in the group of patients with overexpression of HMGA 2, on IRS and qPCR levels.
Previous studies showed that MGMT promoter methylation is used to identify patients who benefit from alkylating chemotherapy. Additionally, MGMT methylation leads to a longer PFS and OS in glioblastoma patients (40,46,47).
Liu et al (44) reported that aberrant HMGA 2 was associated with long-term survival of glioblastoma patients. However, in the present study patients with HMGA 2 showed a tendency to a shorter survival time (PFS and OS). Moreover, our results showed that the MGMT promoter methylation did not lead to a longer survival time in the group of patients with HMGA 2 overexpression.
Furthermore, Lee et al (48) presented in HMGA2 knocked down tumor cells a reduction of cell invasion and migration. They showed the downregulation of multiple EMT-factors such as N-cadherine (mesenchymal marker), β-catenin, transcriptional factors like Snail and Zeb 1 and upregulation of E-cadherine (epithelial marker). HMGA2 overexpression through its relationship to EMT-pathway seems to intensify invasion of cancer cells.
Morishita et al (21) showed in their in vitro experiments that HMGA 2 converts non-invasive cell types into their invasive counterparts through the induction EMT. Cells at the ‘invasive front’ of human tumors preferentially express HMGA 2 where the tumor cells exhibit the EMT. According to their results HMGA 2 is localized to the ‘invasive front’ of tumors and enables tumor cells to migrate. These findings could be a further explanation for infiltration of glioblastomas into normal brain tissue and, thus, the impossibility of a complete tumor resection and curative treatment so far. This hypothesis is speculative because it is based on other tumor entities and not glioblastomas.
As Halle et al (45) showed, the de-repression of miRNA levels of HMGA 2 through anti-let-7a application via convection-enhanced delivery (CED), HMGA 2 could be a potential target in future glioblastoma therapies with strategies for manipulating the expression of HMGA 2-regulating miRNAs.
There are several limitations of the present study. First of all there is the retrospective character of the study with the well-known shortcomings of this study design. Furthermore, the study population is small and heterogeneous, so that a selection bias cannot be excluded.
In conclusion, the present study indicated that HMGA 2 overexpression had a tendency towards poor prognosis of glioblastoma patients independent of their MGMT methylation status. The high expression of HMGA 2 could lead to shorter survival time and poor prognosis, whereas, glioblastoma patients with low HMGA 2 expression have longer survival times (OS and PFS). HMGA 2 is an informative biomarker, which is associated with poor prognosis of patients with glioblastoma. This hypothesis may have potential implications for glioblastoma survival prediction, the choice of treatment regimens and may be helpful to create novel strategies for glioma therapy and prevention.
Acknowledgements
The authors thank sincerely Nga Rötering for excellent technical assistance, Dr Karl Quint for assistance in statistical analysis, Sabine Gräf and Boyan Garvalov for the analysis of MGMT promoter methylation.
Abbreviations:
EMT |
epithelial-mesenchymal-transition |
GBM |
glioblastoma multiforme |
HMG |
high-mobility group |
IHC |
immunohistochemistry |
IRS |
immunoreactive score |
MGMT |
O-6-methylguanine-DNA methyltransferase |
mRNA |
messenger RNA |
OS |
overall survival |
PFS |
progression-free survival |
qPCR |
real-time quantitative PCR |
RCT |
radiochemotherapy |
RNA |
ribonucleic acid |
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