Abstract
Colorectal cancers (CRCs) can be divided into four gene expression-based biologically distinct consensus molecular subtypes (CMS). This classification provides a potential framework for stratified treatment, but to identify novel CMS-drug associations, translation of the subtypes to pre-clinical models is essential. The currently available classifier is dependent on gene expression signals from the immune and stromal compartments of tumors and fails to identify the poor-prognostic CMS4-mesenchymal group in immortalized cell lines, patient-derived organoids and xenografts. To address this, we present a novel CMS classifier based on a filtered set of cancer cell-intrinsic, subtype-enriched gene expression markers. This new classifier, referred to as CMScaller, recapitulated the subtypes in both in vitro and in vivo models (551 in total). Importantly, by analyzing public drug response data from patient-derived xenografts and cell lines, we show that the subtypes are predictive of response to standard CRC drugs. CMScaller is available as an R package.
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Introduction
Colorectal cancer (CRC) is the fourth most common cause of cancer deaths worldwide1. Gene expression profiling shows promise to identify clinically important subtypes2,3,4,5,6, including a mesenchymal-like subgroup with high stromal infiltration, poor patient prognosis7 and poor response to standard treatments such as oxaliplatin8 and antibodies against EGFR3,5,9. Based on gene expression profiles from close to 4000 primary tumors, an expert consortium recently proposed a classification scheme reconciling this work and dividing CRCs into four biologically distinct subtypes10. In this consensus system, CMS1-immune comprises most tumors with microsatellite instability (MSI) and is characterized by infiltration of activated immune cells. CMS2-canonical and CMS3-metabolic both show epithelial characteristics, with oncogene amplification and high WNT and MYC signaling predominantly in CMS2 and metabolic reprogramming in CMS3. CMS4 comprises the more mesenchymal-like cancers, with high stromal infiltration and poor patient prognosis10,11. So far, identification of subtype-specific drug responses has only scratched the surface, and CMS classification presents an unexploited basis for stratified treatment and drug repurposing in CRC.
In vitro and in vivo models of CRC recapitulate the molecular profiles of primary cancers12,13,14,15, as well as clinically relevant pharmacogenomic associations and are suitable tools for drug discovery16,17. Publicly available data from pre-clinical drug screen studies represent an invaluable resource, however, analysis of CMS-drug associations is hindered by imprecise subtyping of the models. The original classifier was developed specifically for primary CRCs (pCRC), and it was recently shown that it fails to identify the CMS1-immune and CMS4-mesenchymal groups in cell lines, patient-derived organoids and xenografts (PDX)15,18,19,20, due to the absence of human immune-related signatures, stromal components and extra-cellular matrix in cell cultures and animal models7,10,18,19,20,21,22. However, at least some CRC cell lines are mesenchymal-like5,16,23,24 and both organoids and PDXs can be established with minimal bias in terms of clinical and molecular covariates of the originating tumors14,15,25. This indicates that the apparent lack of CMS4-like models is not a result of biological adaptation to or selection for culturing conditions. We aimed to develop a classifier optimized for pre-clinical models and introduce here CMScaller, an algorithm for CMS classification in the absence of human tumor stroma. We apply CMScaller to in vitro and in vivo models with publicly available gene expression data and show that it enables pre-clinical analysis of CMS-drug associations.
Results
Pre-clinical models require a cancer cell-intrinsic CMS classifier
To illustrate why the original CMS classifier is not applicable to pre-clinical models, the classifyCMS.RF function in the R package CMSclassifier10,26 was applied to gene expression data from CRC cell lines (n = 131)27, organoids (n = 22 + 26)15,16 and PDXs (n = 40 + 37 + 51 + 244)14,20,28,29. Of all 551 samples, 219 (66%) were unclassified using default parameters. Among the classified, 245 (74%) were CMS2, and only 3 samples (0.9%) were identified as CMS4-mesenchymal (Supplementary Table 1). In one PDX dataset predicted to lack the CMS4 subtype, single-sample gene set expression enrichment analysis indicated strong TGFβ response and MSS-like characteristics in two samples, reminiscent of CMS4 characteristics (Fig. 1a).
To identify genes expressed in or induced by the human tumor microenvironment and therefore with reduced levels in xenotransplants, we performed differential gene expression analysis comparing 30 pCRCs against 40 PDX models14. A significant proportion of genes (44/178, 25%) included as features in the original CMS classifier and highly expressed in CMS4 pCRC were reduced or almost completely lost in the PDX samples (log 2fold-change (LFC) > 2, Fig. 1b). Considering all 108 candidate CMS4 genes with reduced expression in the PDXs, the set was significantly enriched for genes involved in biological pathways characteristic of the tumor stroma, including epithelial to mesenchymal transition (EMT), extracellular matrix organization and angiogenesis, which ranked 1st, 2nd and 8th in terms of significance among 2038 unselected gene sets from reactome.org30 and MSigDB Hallmarks31 (hypergeometric test, Supplementary Table 2). Of the 11921 genes overlapping between the pCRC and PDX datasets, 11753 genes showed low differential expression between pCRCs and PDXs (pCRC-PDX LFC < 2, no p-value threshold), 921 (7.8%) of these were identified as differentially expressed between CMS4 and CMS1/2/3 in pCRCs (LFC > 1, false discovery rate adjusted-p < 0.1), indicating that CMS4 cancer cells present intrinsic gene expression signals that can be used for subtyping (Fig. 1c).
Development, application and evaluation of the cancer cell-adapted CMScaller
Accordingly, to construct a classifier useful for pre-clinical models, we set out to identify cancer cell-intrinsic subtype markers by selecting genes that (i) were highly expressed in each CMS group compared with the rest in pCRCs (LFC > 1, adjusted-p < 0.1; representing candidate markers), (ii) had a large range in expression values across a panel of CRC cell lines32 (top-25% 10–90 cross-sample inter-percentile range) and were highly expressed in at least a subset (top-25% within-sample read count in at least three cell lines; representing markers that are informative in cancer cells) and (iii) were not lost upon xenotransplantation14 (pCRC-PDX LFC < 2, no p-value threshold; representing cancer cell-intrinsic markers, Fig. 2a).
The filtered gene set was used as input for nearest template prediction33, resulting in the CMScaller algorithm (Fig. 2b). Although created for pre-clinical models, CMScaller performed well also in pCRCs. Using the original CMS classifications as reference for pCRCs from TCGA, the overall prediction accuracy was 0.83 (95% confidence interval 0.74–0.9, p = 1.5 × 10−13, binomial test for accuracy better than no information rate). Lowest class-wise sensitivity and specificity were found for CMS3 (0.71) and CMS4 (0.91), respectively (Supplementary Table 4). However, gene expression-based principal component analysis showed that most disagreements were at class-boundaries, where the CMS groups are least distinct (Fig. 2c).
Cell lines represent 100% cancer, and the rationale for adding the CRC cell line-filter was to exclude markers of non-carcinoma cell types (genes preferentially expressed by the tumor stroma will not have high expression or expression variation in CRC cell lines). Furthermore, genes with large variation in expression between cell lines are likely to be informative on intrinsic phenotype. To reduce the problem of calling expressed versus non-expressed genes, a dataset based on RNA-sequencing (rather than microarray data) was applied. However, to test how sensitive CMScaller is to thresholds and data sets used during development, we generated four additional prediction template gene sets with the following changes: (i) adjusted-p threshold for differential expression analysis reduced from 0.1 to 10–4 in comparisons among subtypes in pCRC; (ii) selected CRC cell line panel32 replaced with another independent RNA sequencing-based dataset34; (iii) pCRC-PDX LFC threshold reduced from two to one and (iv) any gene independently reported as lost in PDXs by Isella et al. was excluded7 (Supplementary Fig. 1a,b). For the four resulting classifiers, the number of genes overlapping with the original CMScaller template set ranged from 205 to 459 (21–95% overlap in features). These 1 + 4 templates were used to perform five independent classifications on the Gao et al. PDX models29 (Supplementary Fig. 1b,c). The classification concordance ranged from 0.95 to 0.98 and, critically, 47/50 samples (94%) were consistently assigned to a single CMS using all templates (the last sample was consistently unclassified).
We have previously provided CMS classification of widely used, immortalized CRC cell lines, and shown that these in vitro models recapitulate the properties of the CMS groups [Sveen submitted]. Here, we demonstrate that CMScaller can robustly classify also CRC organoids and PDXs, and outperforms the original CMSclassifier in seven publicly available datasets, including 2615 and 22 organoids16, 4014, 3728, 5129 and 24420 PDX models, as well as a dataset of 13127 cell lines. Using the original CMSclassifier, most samples were classified as CMS2, and only 3/551 as CMS4 (Supplementary Table 1). In contrast, using CMScaller, all CMS groups were found to be present in all datasets and CMS4 accounted for 7.5–22% of the samples (Supplementary Table 5). Notably, 46% of the metastatic CRC-derived PDXs were not assigned any CMS, perhaps due to biased representation of individual CMS groups compared to primary CRCs (ref. Discussion).
Gene set expression analyses showed that known CMS group associations were recapitulated in both organoids and PDX models (Fig. 3a,b). Specifically, CMS1 was MSI-like, CMS2 was MSS-like, had activated HNF4A, MYC and WNT target gene sets, CMS3 had up-regulated CDX2 targets and metabolic processes, and CMS4 models showed strong relative activation of TGFβ and EMT. The same pattern was not seen for predictions based on the original CMSclassifier (Supplementary Fig. 2). To further support the validity of our subtyping, we analyzed additional molecular data available in two of the datasets, including MSI-status in organoids from Fujii et al.15 and mutation data in PDXs from Gao et al.29. In the organoids, in line with expectations, 5/6 MSI samples were predicted to be CMS1-immune (CMS1/MSI: p = 1.6 × 10−4, Fisher’s exact test). In the PDXs, both the number of total mutations and BRAF mutations were significantly higher in CMS1 models (Fig. 3c,d, number of mutations: p = 9.9 × 10−4, Mann-Whitney test and BRAF: p = 4× 10−4, Fisher’s exact test), and the median number of copy number aberrations was 216 for CMS2, significantly higher than 112 for non-CMS2 (p = 5.9× 10−3, Mann-Whitney test).
To further evaluate the performance of CMScaller, its prediction accuracy and robustness was compared with the original CMS classifications of pCRCs from TCGA in two ways. First, accuracy was evaluated in relation to sample size by dividing the pCRCs into random subsets (n = 1000) of varying sizes (range 10–80 samples). Accuracy distributions indicated that prediction uncertainties were relatively low when sample sizes exceeded more than approximately 40 samples (Supplementary Fig. 3). Second, robustness was evaluated by analyzing whether the CMScaller classifications were “cycle consistent” across the sample types. In other words, we tested whether the Gao et al. PDX models (n = 51) and assigned CMS groups could be used to derive an independent classifier applicable to the pCRCs (CMSPDX ↔ CMSCRC). Using the same strategy as for development of CMScaller, we performed differential expression analysis among the CMS groups to identify subtype markers, this time in PDX models, and filtered out the genes overlapping with the CMScaller template. Overall subtyping accuracy was 0.83 (95% confidence interval 0.74–0.9, p = 6.3× 10−12, binomial test for accuracy better than no information rate, Supplementary Table 6), indicating that the PDX models and assigned CMS groups represent real biological characteristics of CMS (Supplementary Fig. 4).
Pre-clinical models recapitulate CMS-associations to standard CRC drugs
Pre-clinical analysis of CMS-drug associations is an important application of CMScaller. To illustrate this potential, we analyzed publicly available drug response data for the standard CRC drugs 5-fluorouracil (5-FU) and cetuximab (anti-EGFR) in 51 CRC PDX models29. The Sadanandam et al. transit-amplifying subtype, largely corresponding to CMS2, has previously been shown to be particularly sensitive to EGFR-inhibitors in vitro 5,27, and in vivo response has been shown in PDX models with high WNT signaling18. We confirm strong in vivo response to cetuximab particularly in PDX models predicted to belong to the CMS2 group (p = 0.024, CMS2 versus non-CMS2, Mann-Whitney test, Fig. 3e), independent of KRAS/NRAS/BRAF mutations (p = 0.016, triple wild types only, CMS2 versus non-CMS2, Mann-Whitney test). Importantly, the same association was observed for the dataset of PDXs derived from metastatic CRCs20, representing a clinical setting where anti-EGFR treatment is routinely used (p = 0.01, OR = 2.9, CMS2 versus non-CMS2 independent of KRAS/BRAF/NRAS status, Fisher’s Exact test, Supplementary Fig. 5a). Analysis of CRC cell lines with public gene expression data27 and cetuximab response data35 (only non-duplicated cell lines with assigned CMS, n = 40, Supplementary Fig. 5b) confirmed our previous finding [Sveen submitted] that CMS2 was significantly associated with response to cetuximab also in vitro (p = 3.4× 10−3, OR = 8.3, CMS2 versus non-CMS2, Fisher’s Exact test).
Patients with MSI tumors have been shown to respond poorly to 5-FU36, and consistently, 5-FU had poor anti-tumor activity in CMS1-immune PDXs (Fig. 3f). Furthermore, CMS4 also showed a poor response to 5-FU compared with CMS2/3 PDXs (p = \(0.12\), CMS4 vs CMS2/3 Mann-Whitney test), although the sample number was small (n CMS4 = 4). For validation, and to eliminate the potential effect of MSI, we analyzed in vitro 5-FU response data for a set of MSS CRC cell lines37 (only non-duplicated MSS cell lines with assigned CMS, n = 34, Supplementary Fig. 6). In CMS1-CMS4 cell lines, the median concentrations required for 50% growth inhibition were 1.1, 1.1, 4.1 and 6.8 µM 5-FU respectively, confirming a poor response in CMS4 (p = 7.2 × 10−3, CMS4 vs CMS1/2/3 Mann-Whitney test).
Discussion
Pre-clinical models are invaluable tools for drug discovery, but identification of pharmacogenomic associations depends on accurate molecular subtyping. We report the development and performance of CMScaller, a CMS classifier optimized for pre-clinical model systems of primary colorectal cancer, including cell lines, organoids and xenografts. We illustrate the potential of CMScaller to identify CMS-associated responses to standard CRC drugs, including 5-FU-based chemotherapy, the most widely used oncological treatment regimen in CRC. In patients, treatment is contraindicated in the MSI subtype, but response rates are incomplete also within the MSS group. The PDX and cell line drug response data presented here suggest that the CMS-groups add additional predictive information, indicating a poor response in CMS4. In concordance, previous studies have shown limited benefit from chemotherapy in patients with mesenchymal tumors38, also when adding oxaliplatin8, and there is mounting evidence that stromal cells confer resistance to chemotherapy39. However, these pre-clinical data indicate that the CMS4 group has cancer cell-intrinsic characteristics conferring poor response also in the absence of the tumor microenvironment.
It has been suggested that CMS4 and the related stem-cell/serrated/mesenchymal subtypes mainly reflect tumors dominated by infiltrating stromal cells. Accordingly, novel CRC classifications based on cancer cell-intrinsic gene expression signals were recently proposed20,40. There is an interplay between cancer and stromal cells and we hypothesized that the stromal composition in part is determined by cancer-cell intrinsic features. Thus, analogously to how it is reasonable to assume that CMS1 cancer cell-intrinsic immunogenicity may explain the infiltration of activated immune cells in the tumor microenvironment, particular aspects of CMS4 cancer cells may lead to aggressive growth intimately associated with the formation of tumors with abundant cancer-associated fibroblasts and a poor clinical outcome. In a related work, we showed that undifferentiated CRC cell lines, predominately CMS1 and CMS4, had elevated mRNA expression of TGFB1 and TGFB2, encoding TGFβ cytokines13. It is therefore tempting to speculate that CMS4 cancer cells through such paracrine signaling are actively remodeling their microenvironments.
CMScaller was developed to provide robust classification across gene expression platforms. This is demonstrated by gene set analyses recapitulating the hallmarks of each CMS group in datasets generated on different technological platforms and for different biological sample types. Robustness can in part be ascribed to the fact that gene expression is highly co-regulated and, despite of thousands of features, informationally surprisingly low-dimensional41. Consequently, missing, noisy or erroneous measurements are compensated for by other co-regulated genes in the nearest template prediction algorithm applied33. This may also explain why the tested changes to the template gene set had little impact on the resulting sample classifications.
Although the template genes were selected to enrich for cancer-cell intrinsic signals, they are not exclusively expressed by cancer cells. For example, the CMS4 marker VIM is expressed in fibroblasts, but have higher expression among CMS4 cancer cells than CM2–3 and is therefore a useful template gene. Importantly, stricter gene filtering for stromal expression had limited impact on the resulting classifications. Still, CMScaller in its current implementation is not recommended for use with samples with a different human stromal component than primary CRCs, including e.g. patient biopsies of metastatic CRC. Another inherent limitation to CMScaller is that the input gene expression data should be centered and scaled. The implication is that small datasets inescapably introduce prediction uncertainty, due to the potential for biased representation of either subtype. Our estimations indicate that this is a concern for datasets with fewer than approximately forty samples, but becomes minor when n exceeds this limit. Similarly, caution is warranted in highly selected datasets where molecular distributions are expected, or known, to severely deviate from pCRC cohorts, including metastatic samples42. Importantly, for both organoids and PDXs, it has been shown that the models recapitulate the heterogeneity of their original tumors14,15,25. However, to assess potential bias, we recommend analyzing CMS-associations of additional molecular markers, for instance MSI-status and BRAF mutations. Additionally, CMScaller includes a function for downstream gene set expression analyses, allowing for assessment of CMS hallmarks.
Within its proper context of pCRC-derived cohorts, accuracy assessment of CMScaller indicated that prediction errors were mainly made at the class boundaries, where expression patterns are less distinct. This may be explained by intra-tumor heterogeneity43,44, both from immune/stromal infiltration (tumor cell percentage and stromal composition) and intrinsic to the cancer cells45. The extent of heterogeneity of molecular subtyping has recently been illustrated by single cell RNA-sequencing46. We have tested CMScaller on these data, and fair correspondence in CMS group assignments was obtained for individual cancer cells from the same patient. However, with only ten patients, the number was too low to draw any strong conclusions whether CMScaller is useful with such data inputs. From a technical perspective, single-cell RNA-sequencing data is exceedingly noisy and a classifier should be optimized for and take advantage of the digital nature of such data. We envision implementing this as a future option in the CMScaller package, as well as to further improve the prediction template gene set taking advantage of larger, higher-quality datasets as they become available.
In addition to pre-clinical drug response studies, model systems may also be useful for functional analyses of central CMS-associated characteristics in controlled environments. The CMScaller presented here should enable the matching of patient subtypes with appropriate models, and we hope this will be a useful tool for the research community. CMScaller is platform independent and available as an R package.
Methods
Gene expression and drug response data
Klijn et al. colorectal, liver and stomach cancer cell line mRNA and non-coding RNA-sequencing counts were downloaded from ref.32, non-Entrez features were discarded and pre-processing was performed by conditional quantile normalization and variance stabilization using cqn47 and DESeq248. Gao et al. PDX RNA-sequencing FPKM values were retrieved from Supplementary Table 1 in ref.29. GSE3514428, GSE6439216, GSE7484315 and E-MTAB-99114 PDX/organoid microarray gene expression datasets were downloaded from GEO49/ArrayExpress50 and CEL files were pre-processed using the justRMA function in the R package affy51, with brainarray Entrez v20 CDFs52. Preprocessed cell line and PDX Illumina BeadArray data were downloaded from GSE5985727 and GSE7640220, log 2transformed and quantile normalized. TCGA level 3 RSEM gene-level RNA-sequencing data53 was downloaded from Broad GDAC Firehose [doi:10.7908/C11G0KM9]. For all datasets, non-CRC, neuro-endocrine cancers and same-patient duplicates were discarded prior to analysis. Gao et al. PDX drug response data is from ref.29 Supplementary Table 1. Isella et al. PDX cetuximab response data is from GSE76402. Cell line MSI-status and 5-FU response data were retrieved from Supplementary Tables 1,2 in ref.37 and cetuximab response groups from Fig. 2 in ref.35.
Gene expression analysis
Single sample gene set enrichment analysis was performed with the R package GSVA54. Differential gene expression analysis was performed using limma55. For RNA-sequencing data, voom transformation with quantile normalization was performed prior to the limma modeling56. Principal component analysis was performed using the 1000 genes with the largest 10–90% inter-percentile range in expression values as input. RNA-sequencing data was first log 2- transformed and batch adjusted according to sequencing platform (HiSeq/GAIIx) using the ComBat method implemented in the R package sva57.
Gene set tests
For CMS marker genes down-regulated in the pCRC versus PDX comparison, statistical enrichment among 2038 unselected gene sets retrieved from reactome.org30 and MSigDB Hallmarks31,58 (v5.2) was assessed assuming a hypergeometric distribution using the phyper function in the R package stats26. Camera gene set analysis59 and visualization was performed using the R package limma with default parameters and implemented in the CMScaller function CMSgsa. For the latter analysis, gene sets were pre-selected to be likely CMS-informative based on Guinney et al. and are listed in Supplementary Table 3 10.
CMScaller template feature selection
TCGA primary CRC (COADREAD) CMS labels were retrieved from Sage Bionetworks Synapse (syn4978511)10. TCGA pCRC RNA-sequencing samples53 were randomly assigned to a training (75%) and test set (25%) using the R function sample. Differential expression analysis in the TCGA test set was used to identify candidate markers with higher expression in each subtype compared to the remaining samples (LFC > 1, adjusted-p < 0.1). To generate the final template gene set, these candidates markers were enriched for cancer cell-intrinsic expression signals according to the following criteria. RNA-sequencing data for CRC cell lines32 was used to identify robust and intrinsic markers, genes among the top-25% with (i) highest expression in at least three samples and (ii) largest 10–90% inter-percentile range in expression values. limma differential expression analysis comparing pCRC with PDX models14 was used to further enrich for intrinsic markers defined as genes with LFC < 2. The intersection of candidate, robust and intrinsic markers were used as template features for nearest template prediction33, which is a correlation-based algorithm developed to provide robust class prediction for high-dimensional, noisy gene expression data, and which has been successfully adopted to various similar classification tasks (e.g. ref.27).
CMS classification
CMS classifications were performed using either the original classifyCMS.RF function with default settings in the R package CMSclassfier,10 or the novel CMScaller. With CMScaller, prediction confidence is estimated from gene resampling (n = 1000) and samples with false discovery rate adjusted p-value > 0.05 were “not assigned” (NA). To assess prediction variance, CMScaller was applied on 8 × 1000 random TCGA train subsets (n = {10, 20, …, 80}). To determine whether subtyping is sample-type “cycle consistent”, differential expression analysis of PDXs classified by CMScaller was used to develop new templates for nearest template prediction of the TCGA pCRC test set. Genes used for the PDX classification were not included in this new template.
Additional statistical analysis
For differential gene expression analysis, hypergeometric gene set tests and nearest template predictions, Benjamini-Hochberg false discovery rate adjustment implemented in the R package stats in the function p.adjust was used to account for multiple-testing26,60. All reported accuracy values are overall accuracies (the number of classification agreements divided by the number of cases with those not assigned (NA) excluded).
Data availability
All data analyzed during the current study were retrieved from public sources. In brief, GSE59857, GSE76402, GSE35144, GSE64392 and GSE74843 gene expression datasets were downloaded from Gene Expression Omnibus (GEO). TCGA pCRC gene expression data was downloaded from Broad GDAC Firehose accession doi:10.7908/C11G0KM9. Julien et al. PDX and pCRC gene expression dataset E-MTAB-991 was downloaded from ArrayExpress. Additional data was retrieved as described in the relevant Methods sections.
Code availability
The CMScaller (v0.99.1) R package is available in Supplementary Materials and will be submitted to Bioconductor61. Updates will be available on https://github.com/Lothelab/CMScaller. Instructions for installation and example code are given in Supplementary Tables and Figures.
References
Ferlay, J. et al. Cancer incidence and mortality worldwide: Sources, methods and major patterns in GLOBOCAN 2012. Int J Cancer 136, E359–E386 (2015).
Budinska, E. et al. Gene expression patterns unveil a new level of molecular heterogeneity in colorectal cancer. J Pathol 231, 63–76 (2013).
Melo, F. D. S. E. et al. Poor-prognosis colon cancer is defined by a molecularly distinct subtype and develops from serrated precursor lesions. Nat Med 19, 614–618 (2013).
Marisa, L. et al. Gene Expression Classification of Colon Cancer into Molecular Subtypes: Characterization, Validation, and Prognostic Value. PLoS Med 10, e1001453 (2013).
Sadanandam, A. et al. A colorectal cancer classification system that associates cellular phenotype and responses to therapy. Nat Med 19, 619–625 (2013).
Schlicker, A. et al. Subtypes of primary colorectal tumors correlate with response to targeted treatment in colorectal cell lines. BMC Med Genomics 5, 66 (2012).
Isella, C. et al. Stromal contribution to the colorectal cancer transcriptome. Nat Genet 47, 312–319 (2015).
Song, N. et al. Clinical Outcome From Oxaliplatin Treatment in Stage II/III Colon Cancer According to Intrinsic Subtypes: Secondary Analysis of NSABP C-07/NRG Oncology Randomized Clinical Trial. JAMA Oncol 2, 1162–1169 (2016).
Trinh, A. et al. Practical and Robust Identification of Molecular Subtypes in Colorectal Cancer by Immunohistochemistry. Clin Cancer Res 23, 387–398 (2017).
Guinney, J. et al. The consensus molecular subtypes of colorectal cancer. Nat Med 21, 1350–1356 (2015).
Dienstmann, R. et al. Consensus molecular subtypes and the evolution of precision medicine in colorectal cancer. Nat Rev Cancer 17, 79–92 (2017).
Barretina, J. et al. The Cancer Cell Line Encyclopedia enables predictive modelling of anticancer drug sensitivity. Nature 483, 603–307 (2012).
Berg, K. C. G. et al. Multi-omics of 34 colorectal cancer cell lines - a resource for biomedical studies. Mol Cancer 16, 116 (2017).
Julien, S. et al. Characterization of a Large Panel of Patient-Derived Tumor Xenografts Representing the Clinical Heterogeneity of Human Colorectal Cancer. Clin Cancer Res 18, 5314–5328 (2012).
Fujii, M. et al. A Colorectal Tumor Organoid Library Demonstrates Progressive Loss of Niche Factor Requirements during Tumorigenesis. Cell Stem Cell 18, 827–838 (2016).
Wetering, Mvande et al. Prospective derivation of a living organoid biobank of colorectal cancer patients. Cell 161, 933–945 (2015).
Pauli, C. et al. Personalized In Vitro and In Vivo Cancer Models to Guide Precision Medicine. Cancer Discov 7, 462–477 (2017).
Schütte, M. et al. Molecular dissection of colorectal cancer in pre-clinical models identifies biomarkers predicting sensitivity to EGFR inhibitors. Nat Commun 8, 14262 (2017).
Dunne, P. D. et al. Cancer-cell intrinsic gene expression signatures overcome intratumoural heterogeneity bias in colorectal cancer patient classification. Nat Commun 8, ncomms15657 (2017).
Isella, C. et al. Selective analysis of cancer-cell intrinsic transcriptional traits defines novel clinically relevant subtypes of colorectal cancer. Nat Commun 8, ncomms15107 (2017).
Calon, A. et al. Stromal gene expression defines poor-prognosis subtypes in colorectal cancer. Nat Genet 47, 320–329 (2015).
Becht, E. et al. Immune and Stromal Classification of Colorectal Cancer Is Associated with Molecular Subtypes and Relevant for Precision Immunotherapy. Clin Cancer Res 22, 4057–4066 (2016).
Fessler, E. et al. A multidimensional network approach reveals microRNAs as determinants of the mesenchymal colorectal cancer subtype. Oncogene 35, 6026–6037 (2016).
Sztupinszki, Z. & Győrffy, B. Colon cancer subtypes: Concordance, effect on survival and selection of the most representative preclinical models. Sci Rep 6, 37169 (2016).
Katsiampoura, A. et al. Modeling of Patient-Derived Xenografts in Colorectal Cancer. Mol Cancer Ther 16, 1435–1442 (2017).
R Core Team. R: A Language and Environment for Statistical Computing. (R Foundation for Statistical Computing, 2017).
Medico, E. et al. The molecular landscape of colorectal cancer cell lines unveils clinically actionable kinase targets. Nat Commun 6, (2015).
Uronis, J. M. et al. Histological and Molecular Evaluation of Patient-Derived Colorectal Cancer Explants. PLoS One 7, (2012).
Gao, H. et al. High-throughput screening using patient-derived tumor xenografts to predict clinical trial drug response. Nat Med 21, 1318–1325 (2015).
Croft, D. et al. The Reactome pathway knowledgebase. Nucl Acids Res 42, D472–D477 (2014).
Liberzon, A. et al. The Molecular Signatures Database Hallmark Gene Set Collection. Cell Systems 1, 417–425 (2015).
Klijn, C. et al. A comprehensive transcriptional portrait of human cancer cell lines. Nat Biotech 33, 306–312 (2015).
Hoshida, Y. Nearest Template Prediction: A Single-Sample-Based Flexible Class Prediction with Confidence Assessment. PLoS One 5, e15543 (2010).
Wang, J. et al. Colorectal Cancer Cell Line Proteomes Are Representative of Primary Tumors and Predict Drug Sensitivity. Gastroenterology 153, 1082–1095 (2017).
Ashraf, S. Q. et al. Direct and immune mediated antibody targeting of ERBB receptors in a colorectal cancer cell-line panel. PNAS 109, 21046–21051 (2012).
Sargent, D. J. et al. Defective Mismatch Repair As a Predictive Marker for Lack of Efficacy of Fluorouracil-Based Adjuvant Therapy in ColonCancer. JCO 28, 3219–3226 (2010).
Bracht, K., Nicholls, A. M., Liu, Y. & Bodmer, W. F. 5-Fluorouracil response in a large panel of colorectal cancer cell lines is associated with mismatch repair deficiency. Br J Cancer 103, 340–346 (2010).
Roepman, P. et al. Colorectal cancer intrinsic subtypes predict chemotherapy benefit, deficient mismatch repair and epithelial-to-mesenchymal transition. Int J Cancer 134, 552–562 (2014).
Tauriello, D. V. F., Calon, A., Lonardo, E. & Batlle, E. Determinants of metastatic competency in colorectal cancer. Mol Oncol 11, 97–119 (2017).
Bramsen, J. B. et al. Molecular-Subtype-Specific Biomarkers Improve Prediction of Prognosis in Colorectal Cancer. Cell Reports 19, 1268–1280 (2017).
Heimberg, G., Bhatnagar, R., El-Samad, H. & Thomson, M. Low Dimensionality in Gene Expression Data Enables the Accurate Extraction of Transcriptional Programs from Shallow Sequencing. Cell Systems 2, 239–250 (2016).
Zhao, X., Rødland, E. A., Tibshirani, R. & Plevritis, S. Molecular subtyping for clinically defined breast cancer subgroups. Breast Cancer Res 17, (2015).
Dunne, P. D. et al. Challenging the Cancer Molecular Stratification Dogma: Intratumoral Heterogeneity Undermines Consensus Molecular Subtypes and Potential Diagnostic Value in Colorectal Cancer. Clin Cancer Res 22, 4095–4104 (2016).
Morris, J. S. & Kopetz, S. Tumor Microenvironment in Gene Signatures: Critical Biology or Confounding Noise? Clin Cancer Res 22, 3989–3991 (2016).
Sottoriva, A. et al. A Big Bang model of human colorectal tumor growth. Nat Genet 47, 209–216 (2015).
Li, H. et al. Reference component analysis of single-cell transcriptomes elucidates cellular heterogeneity in human colorectal tumors. Nat Genet 49, 708–718 (2017).
Hansen, K. D., Irizarry, R. A. & Wu, Z. Removing technical variability in RNA-seq data using conditional quantile normalization. Biostat 13, 204–216 (2012).
Love, M. I., Huber, W. & Anders, S. Moderated estimation of fold change and dispersion for RNA-seq data with DESeq. 2. Genome Biol 15, 550 (2014).
Barrett, T. et al. NCBI GEO: Archive for functional genomics data sets—update. Nucl Acids Res 41, D991–D995 (2013).
Kolesnikov, N. et al. ArrayExpress update—simplifying data submissions. Nucl Acids Res 43, D1113–D1116 (2015).
Gautier, L., Cope, L., Bolstad, B. M. & Irizarry, R. A. Affy—analysis of Affymetrix GeneChip data at the probe level. Bioinformatics 20, 307–315 (2004).
Sandberg, R. & Larsson, O. Improved precision and accuracy for microarrays using updated probe set definitions. BMC Bioinformatics 8, 1 (2007).
TCGA. Comprehensive molecular characterization of human colon and rectal cancer. Nature 487, 330–337 (2012).
Hänzelmann, S., Castelo, R. & Guinney, J. GSVA: Gene set variation analysis for microarray and RNA-Seq data. BMC Bioinformatics 14, 7 (2013).
Ritchie, M. E. et al. Limma powers differential expression analyses for RNA-sequencing and microarray studies. Nucl Acids Res 43, e47 (2015).
Law, C. W., Chen, Y., Shi, W. & Smyth, G. K. Voom: Precision weights unlock linear model analysis tools for RNA-seq read counts. Genome Biology 15, R29 (2014).
Leek, J. T. et al. Tackling the widespread and critical impact of batch effects in high-throughput data. Nat Rev Genet 11, 733–739 (2010).
Subramanian, A. et al. Gene set enrichment analysis: A knowledge-based approach for interpreting genome-wide expression profiles. PNAS 102, 15545–15550 (2005).
Wu, D. & Smyth, G. K. Camera: A competitive gene set test accounting for inter-gene correlation. Nucl Acids Res 40, e133 (2012).
Benjamini, Y. & Hochberg, Y. Controlling the False Discovery Rate: A Practical and Powerful Approach to Multiple Testing. J Royal Stat Soc 57, 289–300 (1995).
Huber, W. et al. Orchestrating high-throughput genomic analysis with Bioconductor. Nat Meth 12, 115–121 (2015).
Acknowledgements
This work has been supported by the Norwegian Cancer Society, grant numbers 72190-PR-2006–0442, 182759–2017 and 6824048–2016; the foundation Stiftelsen Kristian Gerhard Jebsen; and the Research Council of Norway through FRIPRO Toppforsk project number 250993.
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P.W.E. and A.S. performed the analyses and drafted the manuscript. All authors contributed to study design, data interpretation and the revision and final approval of the manuscript.
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Eide, P.W., Bruun, J., Lothe, R.A. et al. CMScaller: an R package for consensus molecular subtyping of colorectal cancer pre-clinical models. Sci Rep 7, 16618 (2017). https://doi.org/10.1038/s41598-017-16747-x
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DOI: https://doi.org/10.1038/s41598-017-16747-x
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