Abstract
Diffuse, histologically lower grade astrocytomas of adults (LGAs) are classified based on the mutational status of the isocitrate dehydrogenase (IDH) genes. While wild-type (WT) LGAs often evolve quickly to glioblastoma (GBM), mutant tumors typically follow an indolent course. To find possible effectors of these different behaviors, we compared their respective transcriptomes. Unlike mutant LGAs, platelet-derived growth factor (PDGF) signaling was significantly enriched in WT tumors, and PDGFA was the top overexpressed gene in the pathway. Moreover, methylation of the PDGFA and PDGFD promoters emerged as a possible mechanism for their low expression in mutant tumors. Copy number gain of chromosome 7 co-occurred with high expression of PDGFA in WT cases, and high expression of PDGFA was associated with aneuploidy, extracellular matrix (ECM)-related immunosuppressive features and poor prognosis. We also noted that high PDGFA expression in WT cases occurred irrespective of tumor grade and that multiple mechanisms of p53 pathway inactivation accompanied progression to GBM in PDGFA-overexpressing tumors. Conversely, TP53 point mutations were an early and constant feature of mutant LGAs. Our results suggest that members of the PDGF gene family, in concert with different p53 pathway alterations, underlie LGA behaviors.
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Introduction
Diffuse fibrillary astrocytomas of adults (WHO grades II and III), collectively termed lower grade astrocytomas (LGAs), are a group of deadly brain cancers with unknown etiology1. A significant insight into their biology and variable clinical behavior began to emerge when isocitrate dehydrogenase 1 and 2 (IDH1/2) mutations were discovered in 10% of glioblastomas (GBMs) and subsequently in a large proportion of LGAs2. Further characterization revealed that IDH wild-type (WT) LGAs usually arose in older adults and tended to evolve rapidly to GBM, whereas IDH mutant LGAs occurred in younger adults, grew slowly, and only sometimes evolved into a GBM-like high-grade cancer2,3,4. Despite their similar histology, IDH WT and mutant LGAs had different natural histories. It should be noted that a clinical nuance of the IDH WT LGAs, namely their predictable evolution to higher grades, has been muted now that many of them have been re-designated, GBMs. Soon thereafter, molecular and biochemical features that distinguish IDH WT LGAs from mutant tumors were identified, including amplification of chromosome 7, deletion of chromosome 10, and mutations of the TERT gene promoter in IDH WT cases versus loss of the alpha-thalassemia x-linked (ATRX) gene, point mutations of the TP53 gene, and production of the oncometabolite, 2-hydroxyglutarate (2-HG) in IDH mutant LGAs5,6. How these IDH-dependent alterations influence the behavior of LGAs is unknown7.
To address this issue, we analyzed whole transcriptome data from non-1p/19q co-deleted LGAs in The Cancer Genome Atlas (TCGA)5 and found interesting differences between IDH WT and mutant LGAs with respect to PDGF signaling, especially the association of PDGFA and PDGFD gene expression with promoter methylation and copy number variations (CNVs) in LGAs. We also found an association between overexpression of PDGFA and PDGFD and aneuploidy, markers of immuno-suppression, and poor survival outcome. Furthermore, we noted that the progression of WT LGAs to GBM was associated with inactivation of multiple elements of the p53 pathway and differed from mutant LGAs in this respect, where p53 point mutations were an early and constant finding. Our results point to the cooption of aberrant PDGF and p53 signaling in the progression of IDH WT astrocytomas.
Results
PDGF pathway enrichment and high expression of PDGFA were observed in IDH WT LGAs
To explore putative mechanisms underlying the differences in behavior of IDH WT and mutant LGAs, we performed differential expression analysis (DEA) on all LGAs from a filtered TCGA dataset (n = 347) stratified by IDH1/2-mutation status. In this analysis we found 2,175 overexpressed and 517 downregulated genes in IDH WT LGAs (n = 94) versus IDH mutant cases (n = 250; adjusted P value = 0.001, log2(fold change) = 1; Fig. 1a). To assess the functional significance of differentially expressed genes, we performed canonical Reactome pathway analysis: enriched pathways in IDH WT tumors included ECM deregulation (adjusted P = 2.3 * 10−7), collagen biosynthesis (adjusted P = 7.6 * 10−7), and PDGF signaling (adjusted P = 6.3 * 10−4) (Fig. 1b). Enrichment of ECM pathways8 and prominence of the PDGF pathway were of interest because of the invasive nature of LGAs and because overexpression of PDGFA has been implicated in the pathogenesis IDH WT GBM9 and exposure to PDGFA is able to transform p53 null neural progenitor cells10.
The most differentially expressed gene in the PDGF family11 was PDGFA (Fig. 1a, b). PDGFA (adjusted P = 2.7 * −110, log2(fold change) = 2.33), like PDGFD (adjusted P = 8.3 * 10−26, log2(fold change) = 1.86), was significantly upregulated in IDH WT LGAs compared to mutant LGAs (Fig. 1a, d), where in contrast to the PDGFA/PDGFD ligands, the receptor PDGFRA12 was overexpressed (Fig. 1a). Other members of the PDGF pathway such as PDGFB, PDGFC and PDGFRB were not differentially expressed in IDH WT versus mutant LGAs.
We then explored mechanisms underlying the differential expression of PDGFA and PDGFD in LGAs. Aware that hypermethylation is a feature of IDH mutant tumors13, we asked whether promoter methylation was associated with PDGFA/PDGFD expression and documented a strong negative correlation between expression and methylation of both genes across all LGAs (PDGFA: P < 2.2 * 10−16, Spearman’s Rho = −0.68, n = 347, Fig. 1d) (PDGFD: P < 2.2 * 10−16, Spearman’s Rho = −0.51, n = 347, Fig. 1e). Significantly lower amounts of PDGFA (Fig. 1f) and PDGFD (Fig. 1g) promoter methylation was observed in IDH WT LGAs (n = 94) compared to mutant cases (n = 250) (univariate comparisons for both genes: P = 2.2 * 10−16). The negative correlation between expression and promoter methylation persisted when IDH WT and mutant LGAs were analyzed separately (Supplementary Fig. 1a–d), indicating that promoter methylation may be an important regulatory mechanism of PDGFA/PDGFD expression in both LGA subtypes.
Next, we investigated the correlation between gene expression and copy number to assess whether chromosome 7 (containing the PDGFA locus) and 11 (containing the PDGFD locus) gains were associated with differential expression of these genes. As previously reported14, we found that a significantly higher proportion of WT LGAs displayed amplification of the portion of chromosome 7 containing PDGFA (hg19: Chr 7: 536897 base pairs (bp) to 559481 bp) than mutant LGAs (P = 2.2 * 10−16, n = 343, Supplementary Fig. S2a. In contrast to PDGFA, segmental amplification of PDGFD (hg19: Chr 11: 103777914 bp to 104035027 bp) was not a feature of WT LGAs. Fifty-six percent of WT tumors had PDGFA amplification (Supplementary Fig. S2a) but only 1% displayed PDGFD amplification (Supplementary Fig. S3A). Indeed, for PDGFD, the frequency of amplification was higher in mutant tumors (P = 0.036, n = 345, Supplementary Fig. S2b), although the percentage of mutant tumors with amplification of PDGFD was relatively low at 7% (Supplementary Fig. S2b).
Furthermore, the absolute copy number of the PDGFA-containing segment on chromosome 7 significantly correlated with PDGFA expression in IDH WT LGAs (P = 0.0022, Spearman’s Rho = +0.31, n = 93, Supplementary Fig. S2c), but not in mutant cases (P = 0.97, Spearman’s Rho = +0.00, n = 247, Supplementary Fig. S2d). In a multivariate linear regression model, both PDGFA promoter methylation (P < 2.2 * 10−16, t-value = −17.804) and the copy number of the PDGFA-containing segment (P = 0.0062, t-value = 2.755) were significantly associated with its expression in all LGAs (n = 347) (Fig. 1h). These results reveal a previously unrecognized mechanism by which PDGF signaling can be regulated in LGAs. In IDH WT LGAs, absence of promoter methylation of PDGFA and PDGFD and amplification of chromosome 7 contribute to higher gene expression, whereas in IDH mutant LGAs, hypermethylation of the PDGFA and PDGFD promoters and absence of chromosome 7 amplification are significantly associated with the decreased expression of PDGFA and PDGFD.
Gene expression and promoter methylation of PDGFA and PDGFD, and amplification of PDGFA, were significantly associated with prognosis among LGA patients
Cox proportional hazards (PH) analysis was performed, and Kaplan–Meier (KM) curves were generated to assess whether gene expression and/or promoter methylation of PDGFA and PDGFD were prognostic factors in LGAs. Higher PDGFA expression was associated with significantly worse overall survival (OS) (P = 8 * 10−13, HR = 1.67, 95% C.I. [1.45, 1.93], n = 347, disease specific survival (DSS) (P = 2.8 * 10−12, HR = 1.69, 95% C.I. [1.46, 1.95], n = 347, and progression-free interval (PFI) (P = 8.9 * 10−14, HR = 1.00, 95% C.I. [1.00, 1.00], n = 347, (Fig. 2a–c). These results were confirmed in two additional datasets: REpository for Molecular BRAin Neoplasia DaTa (REMBRANDT)15 (P = 5.9 * 10−6, HR = 2.22, 95% C.I. [1.57, 3.14], n = 109 (Fig. 2d) and GSE1601116 (P = 0.0031, HR = 1.67, 95% C.I. [1.19, 2.35], n = 32 (Fig. 2e), suggesting that PDGFA expression is a prognostic biomarker in LGA. Similar prognostic associations were observed for PDGFD expression (Supplementary Fig. S3a–e). Lower PDGFA and PDGFD promoter methylation (Supplementary Fig. S4a–f) and amplification of the chromosome segment containing PDGFA (Fig. 2f–h) were also associated with shorter OS, DSS, and PFI. These data suggest that mechanisms regulating the expression of PDGFA and PDGFD affect the clinical outcomes and biology of patients with LGAs.
PDGFA and PDGFD gene expression and IDH WT status were associated with aneuploidy and markers of immuno-suppression
Given the worse prognosis of IDH WT LGAs patients that overexpress PDGFA, we assessed additional biological features of these tumors that might explain their propensity for more aggressive behavior. Having recently reported that in vitro exposure to PDGFA leads to chromosomal instability in neural progenitor cells10, we assessed aneuploidy in LGAs in relation to IDH mutational status and PDGFA expression. We observed that IDH WT LGAs were significantly more aneuploid than their IDH mutant counterparts (P = 2.2 * 10−16, n = 341, Fig. 3a). We further observed that aneuploidy was a distinguishing feature of LGAs that expressed high levels of PDGFA and PDGFD. Aneuploidy score (AS)17 was significantly associated with expression of PDGFA (P = 6.8 * 10−13, Spearman’s Rho = +0.38, n = 338) and PDGFD (P = 6.9 * 10−12, Spearman’s Rho = +0.36, n = 338) in univariate analysis (Fig. 3b, c, respectively). Furthermore, univariate Cox PH analyses revealed that higher AS was associated with worse OS (P = 1.1 * 10−11, HR = 1.76, 95% C.I. [1.50, 2.07], n = 341, DSS (P = 2.7 * 10−11, HR = 1.78, 95% C.I. [1.50, 2.10], n = 334, and PFI (P = 1.2 * 10−9, HR = 1.50, 95% C.I. [1.32, 1.71], n = 341) (Supplementary Fig. S5a–c). In multivariate Cox PH analysis, both AS (P = 9.5 * 10−5, HR = 1.42, 95% C.I. [1.19, 1.70]) and IDH status (P = 3.2 * 10−10, HR = 4.20, 95% C.I. [2.69, 6.57]) remained independent predictors of overall survival in LGAs (n = 347, Fig. 3d). These analyses indicate that the presence of aneuploidy has prognostic value independent of IDH status in LGAs, and that aneuploidy is associated with high expression of the PDGFA and PDGFD genes.
We then explored the potential of LGAs for immune evasion, a hallmark of poor prognosis across cancers18,19. As observed in our pathway enrichment analysis, ECM genes were upregulated in IDH WT LGAs (Fig. 1b). This is an intriguing observation given that we have previously reported that ECM dysregulation is an effector of TGF-β-induced immuno-suppression in the tumor microenvironment20. To explore this result further, we investigated immune suppression in LGAs with respect to their IDH mutational status and documented that WT LGAs had significantly higher expression of cancer-associated ECM (C-ECM) genes (P = 2.2 * 10−16, n = 344, Fig. 3e) and TGF-β upregulated target genes (P = 2.2 * 10−16, n = 344, Fig. 3f). Furthermore, in all LGAs (n = 347), the expression of PDGFA and PDGFD were positively correlated with both features (Supplementary Fig. S6a–d). The expression of immunosuppressive checkpoint genes such as PDCD1 (encodes PD-1) (P = 2.3 * 10−11) and CD274 (encodes PD-L1) (P = 1.1 * 10−9) were also increased in IDH WT LGAs (Fig. 3g, h, n = 344), suggesting that WT tumors may be able to suppress the local immune response to enhance their aggressiveness.
Sustained overexpression of PDGFA and progressive inactivation of the p53 pathway characterized the evolution of IDH WT LGAs
To further explore the more aggressive behavior of IDH WT LGAs and to better understand how they evolve to higher grades, we evaluated the expression of PDGFA and PDGFD genes in WHO grade II, and grade III tumors and in GBMs. We found that a high level of expression of PDGFA and PDGFD was a constant feature of the IDH WT disease, irrespective of histological grade (n = 219, Fig. 4a, b). These observations reveal that overexpression of PDGFA is an early feature of IDH WT LGAs that persists as grade 2 tumors evolve to grade 3 lesions and on to GBM.
We then assessed the mutational status of the p53 pathway, because loss or inactivation of TP53 has been hypothesized to cooperate with PDGF signaling to promote IDH WT GBM9, and because TP53 compromise (i.e., null or heterozygous) is a prerequisite for PDGFA-mediated in vitro transformation of neural progenitor cells10. First, we assessed single nucleotide variants (SNVs) in TP53. Unlike IDH mutant LGAs, which had a high proportion of TP53 SNVs (Supplementary Fig. S7a) in tumors of all WHO grades (P = 0.75, n = 231), SNVs were not found in grade II WT LGAs and were only detected in some grade 3 tumors and GBMs (P = 0.0078, n = 354, Fig. 4c). Since alterations of the p53 pathway can occur in ways other than point-mutation, we assessed copy number variants (CNVs) of CDKN2A, which encodes the positive regulator of p53, p14ARF, and variants of the negative regulators of p53, MDM2 and MDM421. We noted a progressive increase in the frequency of CDKN2A and MDM2/MDM4 alterations with increasing grade in WT tumors (P = 5.3 * 10−5, n = 354, Fig. 4d). Moreover, pathway disruption accompanied progression to GBM from a lower grade WT tumor in virtually all cases (P = 5.4 * 10−11, n = 354; Supplementary Fig. S7b).
Lastly, we sought confirmation that deletion of CDKN2A and amplification of MDM2 or MDM4 deregulated the p53 pathway in IDH WT LGAs. Gene set enrichment analysis (GSEA) identified a negative association between a specified list of TP53 target genes and an alteration of CDKN2A/MDM2/MDM4 in IDH WT LGAs (Fig. 4e). IDH WT tumors with alterations in CDKN2A/MDM2/MDM4 cluster had elevated expression of PDGFA versus LGAs in which at least one of CDKN2A, MDM2, or MDM4 was unaltered (P = 0.00017, n = 222, Fig. 4f). These data imply that a determinant of the progression of WT grade 2 LGAs, to grade 3 LGAs, and beyond to GBMs, may be inactivation of the p53 pathway by one of several mechanisms.
Discussion
The biology that underlies the contrasting clinical features of IDH WT and IDH mutant LGAs is poorly understood. Here, we report differences in the expression of PDGF gene-family members, particularly PDGFA; differences in expression of biomarkers of invasiveness, immune evasion, and genomic instability; and differences in the type and temporality of p53 pathway alterations that suppress function. Each of these features significantly associates with IDH mutational status and may contribute to the aggressive behavior and short survival of patients with WT tumors, on the one hand, and to the indolent nature and long survival of those with mutant tumors on the other4. However, with regard to the behavior of the IDH WT cases, readers are cautioned that the databases upon which this study is based were assembled before grade 2 and grade 3 IDH WT diffuse fibrillary astrocytic gliomas with TERT promoter mutations, EGFR amplification, and/or a combination of gain of complete chromosome 7 and loss of complete chromosome 10 (+7/−10) were renamed GBMs. Hence, some of the lower grade tumors in this analysis would now be listed as GBMs. A possible effect of this shift in classification on our survival analyses is acknowledged.
Two findings that emerge from this analysis warrant further comment. First, PDGFA was highly differentially expressed between IDH WT and mutant IDH LGAs. Overexpression in WT cases is consistent with the report of Ozawa et al.9 in which overexpression of PDGFA was predicted to be an early alteration in the pathogenesis of human non-GCIMP (i.e., IDH WT) GBM, and when overexpressed in p53 null mice, led to the generation of GBM-like tumors. Moreover, in our hands, continuous exposure to PDGFA induced the malignant transformation of cultured p53 null and heterozygous murine neural progenitor cells isolated from the Sub-Ventricular Zone (SVZ) of young adult mice10. Transformation in this setting was characterized by gains and losses of whole chromosomes and arms of chromosomes in neural progenitor cells and by their evolution to a PDGFA-independent proliferative phenotype with the capacity to generate infiltrating GBM-like cancers in the brains of immune-competent mice. Furthermore, amplification of a segment of chromosome 7 containing the PDGFA locus, which was only seen in IDH WT LGAs, emerged as a putative mechanism for the high expression of PDGFA and was associated with worse prognosis. Also consistent with worse patient outcomes was the finding that overexpression of PDGFA in IDH WT LGAs was associated with high aneuploidy scores and markers of immune evasion.
In contrast, PDGFA was expressed at low levels in mutant cases in association with promoter methylation. Low expression was also associated with lesser degrees of genomic instability and lower levels of expression of genes linked to immune evasion, characteristics that might contribute to slower rates of malignant progression and a more favorable prognosis. In addition, we observed that the PDGFRA receptor was overexpressed in mutant tumors, perhaps as a compensatory response to downregulation of its key ligand, PDGFA. Such dramatic differences in the expression of ligands and receptors from the same growth factor family suggest that genes in this pathway play important but different roles in the pathogenesis of mutant and WT LGAs.
A second insight that emerged from this analysis pertains to perturbations of the p53 pathway in LGA. Although p53 alterations were essentially universal among the LGAs evaluated here, the nature and ‘staging’ of these alterations differed between IDH WT and IDH mutant LGAs in a way that may bear on their different clinical behaviors. As noted previously, point mutations of TP53 (i.e., SNVs), primarily located in the DNA binding domain of the gene, were an early and constant feature of IDH mutant LGAs. They were found in virtually all IDH mutant grade II, grade III, and high-grade (i.e., grade IV) lesions. In contrast, TP53 SNVs were not detected in IDH WT grade 2 LGAs and were less commonly observed than other types of p53 pathway alterations in grade 3 WT tumors and in GBMs. Instead, in IDH WT LGAs the p53 pathway was inactivated by a variety of different mechanisms including deletion of the p53-positive regulator CDKN2A and overexpression of the p53-negative regulators, MDM2 and MDM4. These qualitative differences in p53 alterations between IDH WT and mutant LGAs have not been highlighted previously.
These analyses illustrate the scope of genomic reprogramming that occurs in the diffuse astrocytic gliomas in association with the presence or absence of an IDH mutation and signal potentially important roles of the PDGF and p53 pathways in mediating their different behaviors. Finally, these data generate hypotheses that can be explored in models of LGA and GBM.
Methods
Data analysis and statistical tests
Data processing and analyses were performed on R version 4.0.0. All statistical tests were two-sided.
Datasets used
TCGA clinical data for LGG and GBM cases was downloaded from Supplementary Table 1 in Ceccarelli et al.22. This dataset was utilized for annotated information on the grade, IDH status, and 1p/19q codeletion status of TCGA gliomas. IDH status included mutations of both the IDH1 and IDH2 genes22. Pan-cancer (including TCGA-GBM/LGG) survival data was downloaded from Supplementary Table 1 in Liu et al.23. P53 pathway genes (TP53, MDM2, MDM4, and CDKN2A) were queried for mutations and CNVs in the TCGA-GBMLGG dataset on the cBio Cancer Genomics Portal (cbioportal.org)24. The corresponding raw dataset for the OncoPrint generated by cBioPortal was downloaded for analysis on a third-party platform. Aneuploidy Scores (AS) for TCGA-GBM/LGG samples were acquired from Supplementary Table 2 provided in the study by Taylor et al.17 Three hundred forty-four out of 347 LGA cases had mutation, methylation and transcriptome data available for analysis. Of note, these datasets were built before the new WHO nomenclature for central nervous system tumors were published25 and IDH WT diffuse astrocytomas with TERT promoter mutations, EGFR amplification, and/or +7/−10 were renamed GBM.
Gene expression, copy number, and methylation datasets
Normalized level 3 RSEM RNA-seq data, segmented copy number data from SNP6 arrays, and Infinium 450k methylation array data for TCGA-GBMLGG samples was downloaded from the Broad GDAC Firehose (https://gdac.broadinstitute.org). For copy number analysis, probes were filtered to those overlapping the region containing the PDGFA gene (chromosome 7 between 536897 bp and 559481 bp) or the PDGFD gene (chromosome 11 between 103777914 bp and 104035027 bp). Absolute copy number values were computed by transforming segment means (absolute copy # = 2 × 2(segment mean)). Methylation probes cg15454385 and cg03145963 were used as the representative probes to study PDGFA and PDGFD promoter methylation status, respectively.
Filtering of gliomas, and classification of LGAs
Depending on the analysis requirements, filters were utilized to select glioma samples based on their grade or molecular alteration status (IDH status, 1p/19q codeletion, or p53 pathway alterations). For the purposes of this analysis, LGAs were defined as WHO grade II and grade III gliomas without 1p/19 codeletions.
Differential expression analysis of IDH WT LGAs vs. IDH mutant LGAs in TCGA
Level 3 RNA-Seq by Expectation-Maximization (RSEM) data was downloaded for TCGA-GBM/LGG samples from GDAC Firehose (https://gdac.broadinstitute.org). Samples were filtered for tumors and subsequently for LGAs, as per the criteria described above. Samples classified as NA for IDH status in the clinical dataset were not considered further. Differential expression analysis was performed between IDH WT and IDH mutant LGAs using the DESeq2 package26. A differentially expressed gene (DEG) list was generated with an adjusted P value threshold of 0.001 and log2(fold change) threshold of +1. P value adjustment was performed with the application of the Benjamini-Hochberg method.
Pathway enrichment analysis of DEGs between IDH WT and IDH mutant LGAs
Pathway enrichment analysis was performed on a smaller DEG list (with an adjusted P value threshold of 0.001 and log2(fold change) threshold of +2) using the ReactomePA package27. As per the differential expression analysis, P value adjustment was performed using the Benjamini-Hochberg method. Since there were multiple changes related to collagen, scavenger receptors, and acetylcholine receptors, these alterations were collapsed into one pathway hit each.
Gene set enrichment analyses
p53 pathway genes were identified from the Molecular Signature Database (MSigDB v6.2, C2 collection; https://www.gsea-msigdb.org/gsea/msigdb/genesets.jsp? collection = C2). The list of TGF-β upregulated genes and cancer-associated ECM (C-ECM) genes were downloaded from the supplementary material in the study by Chakravarthy et al.20. These genesets were used to compute single sample gene enrichment analysis (ssGSEA) scores using the gene set variation analysis (GSVA) R package28,29. For a pre-defined gene set, ssGSEA calculates an enrichment score based on enriched and depleted gene expression for each case. Gene set enrichment analysis (GSEA) was performed with the Broad GSEA 4.0.1 software. GSEA permutation type was set to “phenotype” and 1000 permutations were performed.
Survival analyses and Kaplan–Meier visualizations
Cox proportional hazards models were fit on R with the survival package. Prior to visualization, all survival associations were confirmed to be significant in univariate Cox proportional hazards models with the continuous variables as covariates. Differences in surviving fractions between groups were visualized via Kaplan–Meier curves generated using the survminer R package. Cut-points for continuous variables were identified by the method reported by Contal and O’Quigley30.
Validation cohorts
Gene expression and clinical data from two additional glioma datasets were obtained (GSE16011 and REMBRANDT). For both datasets, gliomas were filtered to contain only LGAs (i.e., WHO Grade II or Grade III tumors that were non-1p/19q co-deleted).
Statistical visualizations
Graphs with statistical information and bar plots were generated using the ggstatsplot R package.
Data availability
TCGA clinical data for LGG and GBM cases was downloaded from Supplementary Table 1 in Ceccarelli et al. Pan-cancer (including TCGA-GBM/LGG) survival data was downloaded from Supplementary Table 1 in Liu et al. p53 pathway genes (TP53, MDM2, MDM4, and CDKN2A) were queried for mutations and CNVs in the TCGA-GBMLGG dataset on the cBio Cancer Genomics Portal (cbioportal.org). The corresponding raw dataset for the OncoPrint generated by cBioPortal was downloaded for analysis on a third-party platform. Aneuploidy Scores (AS) for TCGA-GBM/LGG samples were acquired from Supplementary Table 2 provided in the study by Taylor et al. Normalized level 3 RSEM RNA-seq data, segmented copy number data from SNP6 arrays, and Infinium 450k methylation array data for TCGA-GBMLGG samples was downloaded from the Broad GDAC Firehose (https://gdac.broadinstitute.org). RNA-Seq by Expectation-Maximization (RSEM) data was downloaded for TCGA-GBM/LGG samples from GDAC Firehose (https://gdac.broadinstitute.org). p53 pathway genes were identified from the Molecular Signature Database (MSigDB v6.2, C2 collection; https://www.gsea-msigdb.org/gsea/msigdb/genesets.jsp? collection = C2). The list of TGF-β upregulated genes and cancer-associated ECM (C-ECM) genes were downloaded from the supplementary material in the study by Chakravarthy et al. Gene expression and clinical data from two additional glioma datasets were obtained (GSE16011 and REMBRANDT). For both datasets, gliomas were filtered to contain only LGAs (i.e., WHO Grade II or Grade III tumors that were non-1p/19q co-deleted).
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Acknowledgements
This study was generously supported by funds from the Precision Oncology and Experimental Therapeutics (POET) Program to P.B. M.K. is funded through a Data-Enabled Innovation Graduate Studentship from Alberta Innovates. The Terry Fox Research Institute and Foundation, the Alberta Cancer Foundation, Genome Canada, Alberta Innovates, and Jane Smith.
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Conception and design: M.B., G.C., and P.B. Development of methodology: M.K., M.M., M.B., and P.N. Analysis and interpretation of data (e.g., statistical analysis, biostatistics, computational analysis): M.K., M.M., and P.B. Writing, review, and/or revision of the paper: All Authors. Study supervision: M.B., G.C., and P.B.
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P.B. is the co-founder and V.P. Management at OncoHelix Inc. The authors declare no competing interests.
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Kumar, M., Meode, M., Blough, M. et al. PDGF gene expression and p53 alterations contribute to the biology of diffuse astrocytic gliomas. npj Genom. Med. 8, 6 (2023). https://doi.org/10.1038/s41525-023-00351-2
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DOI: https://doi.org/10.1038/s41525-023-00351-2
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