Improved prognostication of glioblastoma beyond molecular subtyping by transcriptional profiling of the tumor microenvironment

The study included 67 glioma samples, which were grouped according to the 2016 revision of the WHO classification of tumors of the central nervous system (Louis et al., 2016). It comprised 36 pGBMs, 5 sGBMs, 18 AIIs, and 8 OIIs from glioma patients who underwent surgery at the Department of Neurosurgery (Oslo University Hospital) between June 2006 and April 2010. Patients were included following written informed consent. Permission to include deceased patients was obtained from The National Health Authorities. The study was approved by the Regional Ethics Committee (S‐06046) as well as the Institutional Study Board. All experiments were performed in accordance with the standards set by the Declaration of Helsinki. Histological diagnoses were reviewed by an expert neuropathologist (author D.S.). Four commercially available normal brain total RNA samples were also included (BioChain, Newark, CA, USA), B209031, pool of five male donors; B306103, one male donor; Takara Bio USA (Mountain View, CA, USA), 1004311A, one male donor; Invitrogen (Waltham, MA, USA), First Choice Human Brain – 105P055201A, pool of 23 donors). The preliminary results showed that one of the normal brain samples, with material from just one donor (BioChain B306103), did not cluster with the other normal samples. As this outlier sample came from one person only, whereas the other three normal samples represented a total of 29 donors, the outlier was excluded from further analyses. The clinical characteristics of the patients and samples are summarized in Table S1.

IDH1/IDH2 mutation analysis had previously been performed for the majority of samples (Håvik et al., 2014). All IDH mutated samples (n = 29) included in our series had mutation in the IDH1 gene, not in IDH2. From three samples not previously analyzed, DNA was extracted from the TRIzol left over from the RNA extraction using a standard protocol (Invitrogen). Sanger sequencing of IDH1 and IDH2 mutations was performed as described in the previous study from Håvik et al. (2014). Combined loss of 1p and 19q was examined for by loss of heterozygosity–polymerase chain reaction (LOH‐PCR) or multiplex ligation‐dependent probe amplification (MLPA) as previously described (Håvik et al., 2014).

Tumor tissue samples were collected on RNAlater (Qiagen, Hilden, Germany), and total RNA was extracted using a standard TRIzol protocol. Quantity and quality of RNA was assessed by NanoDrop ND‐1000 Spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA) and Agilent BioAnalyzer 2100 (Agilent Technologies, Santa Clara, CA, USA), respectively. All samples were analyzed for global gene expression using Affymetrix Human Exon 1.0. ST Array (Thermo Fisher Scientific). Total RNA (250 ng) was used as input and processed according to the manufacturer's instructions, using the Ambion WT Expression Kit protocol (Invitrogen), Affymetrix GeneChip WT terminal labeling, and Hybridization User Manual (Affymetrix, Santa Clara, CA, USA).

Normalized gene expression profiles from Affymetrix H133A arrays and matching clinical information were downloaded for n = 441 glioblastoma samples from TCGA using the TCGA2STAT r package version 1.2 (Brennan et al., 2013; Wan et al., 2015). CpG island methylator phenotype (G‐CIMP) annotations were provided for each tumor. Since G‐CIMP, promoted by mutations in IDH (Turcan et al., 2012), is associated with better outcome and younger age at diagnosis, these tumors were discarded from the dataset, as previously suggested in Klopfenstein et al. (2019). It resulted in n = 393 pGBM expression profiles. Survival data were available for all except one patient (n = 392), and the following treatment groups were considered for the analyses: (a) temozolomide (TMZ) chemoradiation followed by TMZ (n = 147), (b) radiation and TMZ (n = 69), or (c) radiotherapy alone (n = 118). Data from the Rembrandt study were included for validation purposes (Madhavan et al., 2009, GEO accession number http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE68848↗). In this dataset, gene expression profiles were generated using the H133Plus2 Affymetrix platform. The 124 grade IV GBM samples were kept for the analysis, and matching clinical data were downloaded from Klopfenstein et al. (2019).

Statistical analyses were conducted with r version 3.2.2 and default packages from r environment. Differential analyses of expression and infiltration profiles were performed using the moderated t‐test approach implemented in the limma r package, version 3.30.13 (Ritchie et al., 2015). All plots were created using the ggplot2 r package, version 3.0.0 (Wickham, 2016).

For each sample, a CEL file storing intensity measures was generated by the affymetrix genechip command console software (version 1.0). These files were further background corrected, quantile normalized, and summarized at the gene level via median polish, by the robust multi‐array average (RMA) approach using the r package oligo, version 1.34.2 (Carvalho and Irizarry, 2010). Affymetrix identifiers were converted to gene symbols from NetAffx annotation files provided by IPA (release 36).

The batch effect between the three datasets was corrected using ComBat, an empirical Bayes‐based method implemented in the SVA package (Leek et al., 2012). The in‐house generated data and the TCGA expression profiles were merged to constitute the exploratory dataset (n = 463, among which 429 were pGBM). The third cohort was used for validation (n = 124). The analyses were performed on the set of 13 265 genes common to the three platforms.

Tumor infiltration by immune and other stromal cells was estimated from expression data using the MCPcounter approach, implemented in the MCPcounter r package (version 1.1.0) (Becht and de Reynies, 2016). MCPcounter provides abundance estimates for eight immune cell populations, namely CD3⁺ T cells, CD8⁺ T cells, natural killer (NK) cells, B lymphocytes, cells originating from monocytes, myeloid dendritic cells, neutrophils, and cytotoxic lymphocytes (including both CD8⁺ T cells and cytotoxic innate lymphoid NK cells). The abundance of two nonimmune stromal cell populations, that is, fibroblastic and endothelial cells, is also computed by the method. Primary GBMs were clustered based on MCPcounter abundance estimates, using a partitioning around medoids algorithm (PAM), available in the cluster r package version 2.0.3 (Maechler et al., 2017). The silhouette values were computed for every sample and averaged over all data points to determine the optimal number of pGBM infiltration clusters.

A list of 63 key immune effector and suppressive genes, compiled by Doucette et al. (2013), was investigated for differential expression in the pGBM infiltration clusters and against the normal samples (see Tables S2 and S3). An FDR < 0.05 was used as the threshold for statistical significance in the various contrasts. Five representative immune gene sets, described in Thorsson et al. (2018), were downloaded from the paper supplementary materials. Sample‐based enrichment scores were computed using Gene Set Variation Analysis (GSVA) as implemented in the GSVA r package, for each of the five gene sets (Hänzelmann et al., 2013). The clusters were also tested for association with the Verhaak's molecular subtypes (Verhaak et al., 2010). The four gene sets, that is, classical, mesenchymal, neural, and proneural, were downloaded from MSigDB (Subramanian et al., 2005). Primary GBM samples of the exploratory and validation cohorts were assigned a Verhaak's molecular subtype based on their highest enrichment score.

Survival analyses were conducted with Cox's proportional hazards regression implemented in the r survival package (version 2.40‐1), with calculation of P‐values from Wald's tests for predictive potential (Therneau, 2015). Hazard ratios (HR) and 95% confidence intervals were derived from the model. Kaplan–Meier method was used to estimate the survival curves. Overall survival was censored at 24 months.

A random forest approach was implemented in order to assess the reproducibility of the clusters identified from infiltration profiles in the validation cohort, and to confirm their prognostic value. The model was trained on the MCPcounter estimates of the pGBM exploratory samples and applied to classify patients of the validation cohort. All figures included in the main paper refer to the exploratory data, and results from the validation cohort are presented in the supplementary material.

In silico analyses of individual immune and stromal cell populations in the exploratory dataset underlined a higher variability in the composition of the microenvironment of pGBMs compared to AII and other subtypes (Fig. 1A). Using unsupervised partitioning, we conducted further investigations into the infiltration profiles of pGBMs and identified two distinct infiltration clusters of samples – denoted pGBM‐I1 (n = 192) and pGBM‐I2 (n = 237) (Fig. S1). Tumors of the pGBM‐I1 cluster showed a consistent high infiltration in fibroblasts, and moderate‐to‐high infiltration in the eight immune cell populations and endothelial cells (Fig. S2A,B). In comparison, pGBM‐I2 samples had overall lower infiltration in all immune and stromal cell populations (Fig. S2A,C). Further differential analyses established that the pGBM‐I1 cluster had significant increased infiltration in nine out of ten cell populations (B lineage, CD8 T cells, endothelial cells, fibroblasts, monocytic lineage and myeloid dendritic cells, neutrophils, NK cells, and T cells; Fig. 1B). CD45, a pan‐hematopoietic marker, was also considered as an alternative strategy to measure the general immune infiltration in GBMs. Its expression was highly associated with abundance of cells of monocytic origin. However, CD45 expression poorly correlated with other immune cell populations such as NK cells or T cells (data not shown), highlighting the relevance of investigating immune cell populations individually. In the validation cohort, the random forest model trained on these nine cell populations classified the samples into pGBM‐I1 and pGBM‐I2, with significant differences in abundances between the two clusters for the same cell populations, except NK cells (Fig. S3).

Analyzing pGBM‐I1 vs. pGBM‐I2 samples for differential gene expression in the exploratory dataset revealed that > 80% of the selected immune effector and suppressor genes were significantly upregulated in pGBM‐I1 (Tables S2 and S3). When tested against normal samples, pGBM‐I1 had significantly increased expression in about 35% of the suppressor genes and 32% of the effectors. The percentage of upregulated immune effectors and suppressors in pGBM‐I2 samples was comparable to AII and lower than in pGBM‐I1 (Fig. 2A). To further characterize the immune microenvironment according to the six pan‐cancer immune subtypes defined by Thorsson et al. (2018), we derived sample‐based enrichment scores from the five representative gene sets described in the paper: (a) activation of macrophages/monocytes, (b) overall lymphocyte infiltration, (c) TGF‐β response, (d) IFN‐γ response, and (e) wound healing (Fig. 2B). Enrichment scores were significantly higher in pGBM‐I1 for the lymphocyte, the macrophage, and the TGF‐β response signatures and to a lesser extent, significantly lower for the wound healing signature (FDR < 0.05).

The pGBM samples were classified according to Verhaak's molecular subtypes. The exploratory cohort included a majority of mesenchymal tumors (32%), similar rates of classical and proneural (26% and 25%) and fewer neural tumors (17%), as reported in TCGA data by Verhaak et al. (2010). The mesenchymal tumors displayed a significantly lower expression of NF1 (Fig. S4), in line with the frequent number of mutations in the NF1 tumor suppressor gene reported in the mesenchymal subtype (Verhaak et al., 2010). High expressions of CHI3L1, CD44, SERPINE1, and CTGF, typical of mesenchymal tumors, were also observed (Parker et al., 2016). Compared to other pGBM molecular subtypes, mesenchymal samples had increased infiltration in monocytic lineage cells (FDR = 0.0060) and a tendency toward higher infiltration in fibroblasts (FDR = 0.12) (Fig. S5).

We found a significant association between the molecular classification and the pGBM infiltration clusters, with pGBM‐I1 being enriched in tumors of the mesenchymal subtype both in the exploratory (Fisher's exact test P‐value < 2e‐16, Fig. 3) and in the validation datasets (Fisher's exact test P‐value = 3.0e‐05, Fig. S6). The infiltration patterns observed in pGBM‐I1 and pGBM‐I2 were similar across molecular subtypes; there was a trend toward low infiltration in most cell populations in pGBM‐I2, while tumors of pGBM‐I1 had high expression in fibroblast markers and moderate‐to‐high abundance of immune cell populations and endothelial cells (Figs S7–S10).

We tested the overall significance of several univariable Cox's regression models to predict patient survival in the exploratory cohort. The regression model including the Verhaak's molecular classification alone as a factor did not reach the significance level (Wald's test P‐value = 0.086, Fig. 4A, Table S4). In comparison, the univariable model accounting for the infiltration clusters was overall significant, with pGBM‐I2 being associated with worse prognosis compared to pGBM‐I1 [Wald's test P‐value = 0.032, HR = 1.3 (1.0–1.6), Fig. 4B]. We found no association between the pGBM infiltration clusters and the type of treatment received after surgery (Fisher's exact test P‐value = 0.36). A multivariable Cox's regression model, including the molecular subtypes and the infiltration cluster annotation as covariates, was fitted to the data. Comparing the uni‐ and multivariable models using deviance and chi‐square statistic revealed that adding the infiltration clusters significantly improved our ability to predict survival compared to the molecular subtypes alone (P‐value = 0.0034). We also tested whether we should account for potential differences in survival in our own series and the TCGA series, but no significant effect was observed. The molecular subtypes and infiltration clusters had independent prognostic values in the multivariable model (Table S4). When controlling for the molecular subtype, pGBM‐I2 was significantly associated with inferior survival compared to pGBM‐I1 [HR = 1.5 (1.1–2.0), P‐value = 0.0037]. Mesenchymal tumors showed significantly worse outcome among pGBM patients when adjusting for immune and stromal infiltration [HR = 1.7 (1.2–2.4), P‐value = 0.0016]. Patient with mesenchymal pGBM‐I2 tumors had the worst prognosis, with a median survival < 10 months and an HR = 3.0 (1.7–5.4) (P‐value = 2.5e‐4) when compared to classical pGBM‐I1, which had the best outcome (median survival = 18 months).

In the validation cohort, the proneural subtype was significantly associated with a better outcome [P‐value = 0.018, HR = 0.42 (0.21–0.86), Fig. S11 and Table S5]. The survival between pGBM‐I1 and pGBM‐I2 patients was not significantly different in the univariable model [P‐value = 0.47 and HR = 1.2 (0.75–1.9), Fig. S12 and Table S5]. Including the immune and stromal infiltration as a covariate, in addition to the molecular subtype, significantly improved the fit of the Cox's regression. We confirmed the independent prognostic value of the molecular subtype and infiltration cluster in the multivariable model; patients with pGBM‐I2 tumors were found to have a significantly worse outcome compared to pGBM‐I1 [P‐value = 0.048, HR = 1.7 (1.0–2.8), Table S5]. Mesenchymal pGBM‐I2 had again the shortest median survival (11 months).

Combining survival data from the exploratory and validation cohorts strengthened our finding and confirmed the independent prognostic value of the infiltration clusters (Table). In stratified analyses, the mesenchymal subtype showed consistently significantly worse outcome among patients with high (pGBM‐I1) or low (pGBM‐I2) tumor infiltration (Tableand Fig.). S6 S7 S13

The in‐house generated dataset is available in the GEO repository (GEO: http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE111260↗).