Gregory Way and Casey Greene
A transcriptome can describe the total state of a tumor at a snapshot in time. In this repository, we use cancer transcriptomes from The Cancer Genome Atlas PanCancerAtlas project to interrogate gene expression states induced by deleterious mutations and copy number alterations.
The code in this repository is flexible and can build a Pan-Cancer classifier for any combination of genes and cancer-types using gene expression, mutation, and copy number data. In this repository, we provide examples for building classifiers to detect aberration in TP53 and Ras signalling.
The Ras signalling pathway is a major player in cancer development and treatment resistance. We observed that nearly 60% of all tumors in TCGA have mutations or copy number alterations in at least one of 38 core pathway genes (Sanchez-Vega et al. 2018).
We applied our approach to detect Ras pathway activation using KRAS, HRAS, and NRAS gain of function mutations and copy number gains to define our gold standard Ras hyperactivation events. We train a supervised classifier to detect when a tumor has activated Ras.
For more details about the approach, see our paper published in Cell Reports. The paper should be cited as:
Way, GP, Sanchez-Vega, F, La, K, Armenia, J, Chatila, WK, Luna, A, Sander, A, Cherniack, AD, Mina, M, Ciriello, G, Schultz, N., The Cancer Genome Atlas Research Network, Sanchez, Y, Greene, CS. 2018. Machine Learning Detects Pan-cancer Ras Pathway Activation in The Cancer Genome Atlas. Cell Reports 23(1):172-180.e3 doi:10.1016/j.celrep.2018.03.046
We have previously described the ability of a machine learning classifier to detect an NF1 inactivation signature using Glioblastoma data (Way et al. 2016). There, we applied an ensemble of logistic regression classifiers to the problem, but the solutions were unstable and overfit. To address these issues, we posited that we could leverage data from diverse cancer types to build a pancancer NF1 classifier. We also hypothesized that a Ras classifier would be able to detect tumors with NF1 inactivation since NF1 directly inhibits RAS activity.
We are also interested in building a classifier to detect TP53 inactivation.
TP53 is the most highly mutated gene in cancer and regulates several important oncogenic processes such as apoptosis and DNA damage response (DDR).
We include a pipeline to build and evaluate a machine learning TP53 classifier.
See tp53_analysis.sh
for more details.
The description for this analysis can be viewed in the following publication:
Knijnenburg, TA, Wang, L, Zimmermann, MT, Chambwe, N, Gao, GF, Cherniack AD, Fan, H, Shen, H, Way, GP, Greene, CS, Liu, Y, Akbani, R, Feng, B, Donehower, LA, Miller, C, Shen, Y, Karimi, M, Chen, H, Kim, P, Jia, P, Shinbrot, E, Zhang, S, Liu, J, Hu, H, Bailey, MH, Yau, C, Wolf, D, Zhao, Z, Weinstein, J, Li, L, Ding, L, Mills, GB, Laird, PW, Wheeler, DA, Shmulevich, I, The Cancer Genome Atlas Research Network, Monnat Jr, RJ, Xiao, Y, Wang, C. 2018. Genomic and Molecular Landscape of DNA Damage Repair Deficiency across The Cancer Genome Atlas. Cell Reports 23(1):239-254.e3 doi:10.1016/j.celrep.2018.03.076
All data was released by the TCGA PanCancerAtlas project. The compendium of papers is described here. Supplementary data from these papers can be downloaded from the NCI. The specific data used in the analyses presented here are archived on Zenodo Gene expression) and copy number data can be accessed here.
See scripts/initialize/download_data.sh
for more details.
Also note that the definitions for all TCGA cancer-type acronyms is stored in data/tcga_dictionary.tsv
.
The repository must be cloned onto local machine before analyses can proceed.
# Make sure git-lfs (https://git-lfs.github.com/) is installed before cloning
# If not, run `git lfs install`
git clone [email protected]:greenelab/pancancer.git
cd pancancer
We provide two distinct example pipelines for predicting TP53 and NF1/RAS loss of function.
- TP53 loss of function (see
tp53_analysis.sh
) - Ras signaling hyperactivation (see
ras_analysis.sh
)
For custom analyses, use the scripts/pancancer_classifier.py
script with command line arguments.
python scripts/pancancer_classifier.py ...
Flag | Required/Default | Description |
---|---|---|
--genes |
Required | Build a classifier for the input gene symbols |
--diseases |
Auto |
The disease types to use in building the classifier |
--folds |
5 |
Number of cross validation folds |
--drop |
False |
Decision to drop input genes from expression matrix |
--copy_number |
False |
Integrate copy number data to gene event |
--filter_count |
15 |
Default options to filter diseases if none are specified |
--filter_prop |
0.05 |
Default options to filter diseases if none are specified |
--num_features |
8000 |
Number of MAD genes used to build classifier |
--alphas |
0.1,0.15,0.2,0.5,0.8,1 |
The alpha grid to search over in parameter sweep |
--l1_ratios |
0,0.1,0.15,0.18,0.2,0.3 |
The l1 ratio grid to search over in parameter sweep |
--alt_genes |
None |
Alternative genes to test classifier performance |
--alt_diseases |
Auto |
Alternative diseases to test classifier performance |
--alt_filter_count |
15 |
Filtering used for alternative disease classification |
--alt_filter_prop |
0.05 |
Filtering used for alternative disease classification |
--alt_folder |
Auto |
Location to save all classifier figures |
--remove_hyper |
False |
Decision to remove hyper mutated tumors |
--keep_intermediate |
False |
Decision to keep intermediate ROC curve metrics |
--x_matrix |
raw |
if not "raw", then the filename storing the features |
--shuffled |
False |
Shuffle the X matrix for better training |
--shuffled_before_training |
False |
Remove correlational structure in the data |
--no_mutation |
True |
Decision to remove mutation data from the input matrix |
--drop_rasopathy |
False |
Decision to drop all rasopathy genes from the X matrix |
--drop_covariates |
False |
Decision to drop all covariate information from the X matrix |