BRAF V600E mutation and 9p21: CDKN2A/B and MTAP co-deletions - Markers in the clinical stratification of pediatric gliomas

Analysis was performed in paraffin embedded material or fresh tumor samples of patients with pediatric gliomas that were referred to the Portuguese Institute of Oncology (IPOFG-Lisbon, Portugal) from 1992 to 2015 following Patient and Institutional Ethical Board Committee approval.

In total, 100 pediatric gliomas (PG) were selected for genetic analysis: 67 grade I gliomas, 11 grade II gliomas, 13 grade III gliomas, and 9 grade IV gliomas. Since the aim of this study was to investigate the influence of BRAF V600E mutation and 9p21 gene loss, grade I and II lesions were assembled in one group, referred as Low-Grade Gliomas (LGG) and grade III and IV in another group, referred as High-Grade Gliomas (HGG). Histological classification was performed and revised according to WHO (2007) criteria. The patients’ clinical characteristics (tumor’s location, histologic classification, WHO grade, patient’s age-ranges and gender) and outcomes are depicted in Fig. 1 and Additional file 1: Table S1. In grade I gliomas (referred in Additional file 1: Table S1 as LGG1 to LGG66, and LGG82): 32 cases were females and 35 were males, the mean age in this group was of: 9.25 years (range from 5 months to 17 years); In grade II gliomas (referred as LGG68; LGG70 to 76; LGG78, 80 and 81 in Additional file 1: Table S1): 6 cases were females, 5 males, the mean age in this group was: 6.02 years (range from 1 year to 17 years). As to grade III gliomas (referred in Additional file 1: Table S1 1 as HGG1–2; HGG5 to 15): 3 were females, 10 were males and the mean age of this group was: 9.36 years (range from 9 months to 16 years). In grade IV glioma group of this study (referred in Additional file 1: Table S1 as HGG3; HGG16 to 23): 2 patients were females and 7 males, the mean age in this group was 10.44 years (range from 5 years to 15 years).

In accordance with WHO 2007 criteria, patients were considered to have a recurrent tumor when exhibiting a glioma of the same histologic grade after at least 1 year of remission. They were considered to have a de novo tumor when exhibiting a glioma of the same grade, with a different histological type and at a different localization. Patients were only considered as having a transformation of LGG to HGG if they exhibited one of the following features: i) consecutive histologic diagnosis of LGG and HGG as per the WHO 2007 criteria, ii) histological diagnosis LGG follow by at least 1 year of stable disease, followed by clinical and radiological progression to HGG.

FISH technique was used to identify heterozygous and homozygous deletions of the 9p21 chromosomal region. It was performed in interphase nuclei with DNA probes indirectly labeled. A locus-specific BAC probe (RP11–14912) directed to the chromosomal location 9p21.3 within chromosome 9–21,909,260 and 22,010,414 (Ensembl Homo sapiens version 86.38 (GRCh38.p7) - was used to identify the 9p21 chromosomal region. An enumeration probe for chromosome 9 (pMR9A) was also used. The 9p21 chromosomal region probe was labeled with digoxigenin and the chromosome 9 probe with biotin using the BioPrime^R DNA Labeling System (Invitrogen™,by Thermo Fisher Scientific, USA). These labels were then detected with specific antibodies: anti-digoxigenin-fluorescein (Roche Diagnostics, Germany) and streptavidin combined with cyanine 3 (Cy3) fluorophore (Jackson ImmunoResearch Laboratories, USA), respectively. FISH signal evaluation was performed in an AxioImager fluorescence microscope linked to aCytoVision® software (Applied Imaging, UK). Analysis was performed by counting at least 100 cells per slide with intact, non-overlapping nuclei taken from different, randomly chosen fields of view. Deletion was defined as more than 40% containing 9p21 probe: cep9 probe ≤0.5.

In the context of this work, sequencing using Sanger methodology was used to identify a single point mutation (V600E) in the exon 15 of the BRAF gene. DNA for gene analysis was extracted by different procedures according to the material used (fresh material or paraffin embedded material). Target gene amplification was achieved through polymerase chain reaction (PCR), using the forward primer ^5’TCATAATGCTTGCTCTGATAGGA^3’ and the reverse primer ^5’CCGGTTTTTAAATTAGTCACCT^3’ at an annealing temperature of 58–59.5 °C. To sequence samples, an automatic sequencer, ABI PrismTM 3130 Genetic Analyser (Applied Biosystems), was used. Electrophoretograms were compared with the reference DNA sequence of the studied gene to identify the presence or absence of mutations. Reference DNA sequences were obtained from Ensembl data base, available at: http://​www.​ensembl.​org/​index.​html.

In cases with 9p21 deletions (detected by FISH) expression analysis was performed by real-time qPCR, using commercial TaqMan probes for the CDKN2A (Hs00233365_m1) and MTAP (Hs00559618_m1) genes (ThermoFisher Scientific, USA). Analysis was performed using QuantStudio5-Applied Biosystems Real-Time PCR System. ABL1 probes as described by Beillard E et al. [19] were used as endogenous control for gene expression assays. RNA from 3 sample cases (CN1, CN2, and CN3), defined as non-neoplastic brain lesions by pathology, were used as calibrator controls. We were not able to extract RNA with sufficient quality and purity, as analysed by agarose gel electrophoresis and Nanodrop spectrophotometry (NanoDrop Technologies,USA), from all cases with 9p21 loss of this cohort. Total RNA extraction and single-strand cDNA synthesis could only be performed for 3 LGG presenting 9p21 heterozygous loss: LGG64, LGG73 and LGG74 and for 3 HGG (grade IV) with 9p21 homozygous loss: HGG3, HGG18 and HGG23. Total RNA was extracted from 30 mg of the tumor specimens using the RNeasy® Mini Kit (Qiagen) and c-DNA synthesis was performed using the superscript II kit (Invitrogen, ThermoFisher Scientific). Gene expression was quantified on QuantStudio5 (Applied Biosystems, ThermoFisher Scientific, USA). Real-Time PCR System was performed as per manufactures protocol. CDKN2A and MTAP expression were normalized with to reference gene ABL1 and the fold change relative to CN1, CN2, CN3 samples was calculated.

Statistical analyses were carried out using GraphPad Prism 5 software (San Diego, USA). The two-tailed Fisher’s exact test was used to determine the correlations between the presence or absence of genetic alterations and patients’ gender, tumors’ WHO grade, histology and location. The Mann-Whitney test was used to study the presence or absence of genetic alterations with patient’s age. Survival curves were compared using the Log-Rank (Mantel-Cox) test using the IBM SPSS Statistics 24 Software. Differences were considered statistically significant at p-value < 0.05.

In total, 94 pediatric gliomas were analyzed for the BRAF V600E mutation and 15 were found to harbor this mutation (Fig. 1 and Additional file 1: Table S1): 9/62 (14,5%) grade I gliomas (6 pilocytic astrocytomas (PA) and 3 gangliogliomas (GG)); 2/11 (18,2%) grade II gliomas (1 diffuse astrocytoma (DA) and 1 pleomorphic xanthoastrocytoma (XP) classified as a grade II lesion); 2/13 (15,4%) grade III gliomas (1 anaplastic astrocytoma (AA) and 1 anaplastic XP); and 2/9 (22,2%) grade IV gliomas (one astroblastoma and one glioblastoma (GBM)).

The presence of BRAFV600E mutation did not show any correlation with tumor’s WHO grade, histologic subtype, patients’ age (p = 0.9299) and patients’ gender (p = 0.1539). This mutation was not found in tumors located in the cerebellum (p = 0.0355).

Regarding the correlation of BRAF V600E mutation with the overall survival rate of the patients, although no statistically significant correlation could be observed (p = 0,375), a trend toward a better overall survival (OS) was detected (Fig. 2). No statistically significant correlation (p = 0,299) was observed when analyzing progression free survival (PFS) differences between BRAF wild type (BRAFwt) and BRAF V600E mutated (BRAFmut) tumors (Fig. 2).

For the 9p21 chromosomal region, 76 gliomas were analyzed, and its deletion was identified in 16 cases, as depicted in Fig. 1 and Additional file 1: Table S1. 9p21 chromosomal region deletions were observed in 10/59 (16,9%) LGG (cases LGG: 6, 12, 37, 46, 47, 64, 72 to 74 and 81) in which all deletions were heterozygous. 6/17 (35,3%) HGG (HGG: 3, 9, 18, 19, 21 and 23) presented 9p21 deletions, four of which had a homozygous 9p21 chromosomal region deletion.

Statistical analysis demonstrated that 9p21 chromosomal region deletion did not correlate with tumor location, patients’ age (p = 0.6093) and patients’ gender (p = 0.7831), but it did correlate with gliomas’ grade. The 9p21 chromosomal region deletion was rare in grade I gliomas (12.2%, p = 0.0178) but frequent in grade IV gliomas (62.5%, p = 0.0087). Moreover, this deletion also correlated with the histology categorization of tumors, a p = 0 .0012 was found between 9p21 loss and glioblastoma histology.

Furthermore, as depicted in Fig. 2 the 9p21 chromosomal region deletion was correlated with a worse overall survival rate (p = 0.011). The PFS values of 9p21 loss group were also significantly (p = 0.016) worse than those of the group with no deletion at 9p21 as observed in Fig. 2.

Of the 100 gliomas evaluated in our series during a 23-year period it was observed that in the 78 LGG group, 7 recurred (8,9%) (LGG 2, 3, 34, 36, 40, 54, 68) and 2 (2,6%) showed progression to HGG (LGG81 and LGG82) (Table 1). It must be noted that the development of gliomas in the patient identified as LGG68 was very interesting. This patient (ruled out as having Neurofibromatosis type 1) was diagnosed at the age of 4 with a diffuse astrocytoma of the optical nerve, which was positive for the BRAF V600E mutation and presented a recurrence, 3 years later, that also was positive for BRAF V600E. However, at the age of 5 (two years before recurrence) he also had a pilocytic astrocytoma, which developed at the cerebral cortex that did not present BRAF V600E mutation. These findings suggest that the cortical and the optical nerve’s LGG of the patient had different cells of origin. This tumor was therefore considered as de novo glioma.

In grade III HGG group, five patients showed progressive disease and died (cases HGG1, 8, 9, 10 and 11), 4 patients were alive (HGG5, 6, 12 and 14) and in 3 cases follow-up was lost.

As for grade IV HGG group (n = 9) three patients died (HGG 3, 18, 23) of progressive disease. HGG18 was considered a secondary HGG. This patient had been diagnosed in 1998 at age of 4 with acute lymphoblastic leukemia type B (ALL-B), received a medullar transplant and was treated with radiotherapy. He was considered at remission between 2003 and 2009 but, in 2009 at the age of 15, he was diagnosed as having a glioblastoma. Of the other grade IV gliomas of our series, two (HGG15 and 16) were still alive in 2015. Both tumors were classified as astroblastomas. One, HGG15 had a BRAF V600E mutation. However, none of them presented a deletion of 9p21 region. Four cases (HGG19, 20, 21, 22) were lost for follow-up.

The expression levels for the CDKN2A and MTAP genes in both the LGG and HGG are depicted in Additional file 2: Figure S1 and in Additional file 3. In the LGG cases expression levels for the CDKN2A gene mRNA levels were normal or elevated. A similar situation was observed for the MTAP gene for cases LGG64 and LGG73. However, in LGG74, identified as pilomyxoid astrocytoma BRAFwt, MTAP gene levels were slightly down-regulated. In all HGG, expression levels for both genes were significantly down-regulated.