Main Window
After selecting studies and pressing on
Get Cases and Genetic Profiles
Button, the main window
appears (Figure~@ref(fig:mainWindow.png)) and displays the progress of
loading data of selected studies. The Main Window has a Toolbar with
Menus (see following paragraphs). It is subdivised in two columns. The
first column lists Cases for all selected studies. The first line of
every study indicates its Index and its short description. The remain
lines enumerate Cases with short description of data type and the number
of samples. The second list box shows selected Cases. Similarly, the
second column displays informations of Genetic Profiles. User can select
a single or multiple lines with attention to correspond the Case with
appropriate Genetic Profile.
Gene List
The first step to get genomics data is to specify what are interesting genes for user. The Gene List button browses folders to load Gene list file or displays examples of genes list. The genes could be in text file (.txt) with one gene by line using HUGO gene Symbol. The function removes automatically duplicate genes.
Clinical Data
The Multiple Cases button displays successively selected Cases. Results are returned in a table with row for each case and a column for each clinical attribute (Figure 4B). User could select all or some clinical data by checking dialog box (Figure 4A). For example, we select clinical attributes:
Overall Survival months: Overall survival, in months.
Overall Survival Status: Overall survival status, usually indicated as
LIVING
orDECEASED
.Disease Free Survival months: Disease free survival, in months.
Disease Free Survival status: Disease free survival status, usually indicated as
DiseaseFree
orRecurred/Progressed
.Age at diagnosis: Age at diagnosis.
Mutation
User can search all mutation in gene list of all selected studies. He needs to select All tumors samples in Cases and Mutations in gentics profiles to get mutations (Figure~@ref(fig:Mutation1.png)).
Mutation function allows user to select about 15 informations corresponding to mutations (Figure~@ref(fig:Mutation)A). The results is a table with rows for each sample/case, and columns corresponding to the informations cheched in dialog mutation check box (Figure~@ref(fig:Mutation)B).
User can filter mutation result only for specific amino acid change (Figure~@ref(fig:specificMutation.png)).
Methylation
User can search gene methylation and its correlation with mRNA expression. User needs to select Cases and Genetic Profiles with same methylation assay (HM450 or HM27) for the same study. Multiple Cases selection is allowed for one gene list (Figure~@ref(fig:methylation.png)).
The dialog box of methylation
function allows user to
specify the threshold of the correlation rate
(Figure~@ref(fig:Met_rate)A). cBioportal~Gao et
al. (2013) includes only methylation data from the probe with the
strongest negative correlation between the methylation signal and the
gene’s expression. The result table (Figure~@ref(fig:Met_rate)B) lists
genes with median of rate upper than 0.8.
Profiles
The function get Profile Data depends on gene list, cases, and
genetic profiles. If a Single gene
option is done, dialog
box appears to specify gene symbol (Figure~@ref(fig:singleProfile.png)).
The returned dialog check box allows user to choose some/all profiles
data (Figure~@ref(fig:singleProfile.png)B). The result (table) lists
some/all genetic profiles data in columns (CNA, Met, Mut, mRNA,RPPA) and
all available samples in rows (Figure~@ref(fig:singleProfile.png)C).
Oppositely, if Multiple genes
option is done, the returned
table displays genes expression for gene list (column) for all samples
(rows). In the case of multiple genes, the tables are saved in
Results/ProfilesData
folder
(Figure~@ref(fig:multipleProfiles.png)).
PhenoTest
The function was implemented from package
PhenoTest
~(Planet 2013). The
object of this function is to predict the association between a list of
phenotype variables (Survival, DFS~Status, OS~Status) and the gene
expression. There are two possible formula to get associations:
- Three variables:
Survival
status (event/time as Dead-Living / 30 Months),Categorical
orordinal
description (DSF~STATUS or Tumor stage), andContinuous
value (DFS~MONTHS, Tumor size). - Two variables:
Categorical
orordinal
description (DSF~STATUS or Tumor stage), andContinuous
value (DFS~MONTHS, Tumor size). In this case user does not need to select any variables for survival variable in the phenoTest dialog box (Figure~@ref(fig:prad_broad-2013Results.png)A).
The output of this function does not expect to give systematically a
relevant association between all formula of the chosen variables,
although in some cases it is possible to cluster a list of genes
significantly regulated (gene expression) at a range of tumor size
(continuous) or tumoral stage (ordinal) for recurred or DiseaseFree
cases (survival and categorical). The type of variables could be
explored with Clinical Data tables and selected in the phenoTest dialog
box (Figure~@ref(fig:prad_broad-2013Results.png) A), Dialog Boxused to
select variables; B, Results; C, Only significant pValues}A). The effect
of both continuous
, categorical
and
ordinal
phenotype variables on gene expression levels are
tested via lmFit
from limma
package~(Wettenhall and Smyth 2004). Gene expression
effects on survival
are tested via Cox proportional hazards
model~(Cox 1972), as implemented in
function coxph
from survival
package.
- NB: Continuous or Categories can not have more than 4 classes.
Examples
Study: Prostate Adenocarcinoma (Broad/Cornal, Call 2013)
Cases: All tumor samples (57 samples),
Genetic Profiles: mRNA expression,
Gene list: 1021.txt file
Survival variable: empty
Categorical variable: Pathology Tumor Stage
Numeric variable: Serum PSA level
pVal adjust method: BH
PhenoTest
with Two variables (Figure~@ref(fig:prad_broad-2013Results.png)
After running Pheno/Exp
, PhenoTest
function
returns two tables. The first table ranks gene list by pval
(Figure~@ref(fig:prad_broad-2013Results.png)B). The first part (red
square) displays pValues of the association between gene expression and
Tumor stage. The second part (blue square) displays the fold change (fc)
by PSA level rang.\
Interpretation: Notice that a single pValue is reported for each phenotype variable. For categorical variables these corresponds to the overall null hypothesis that there are no differences between groups.
In the second table, PhenoTest function filters only gene that has significant pval (pval <0.05, Figure~@ref(fig:prad_broad-2013Results.png)C red). Here we see that tumor stage has been categorized into 2 groups (pT2c, pT3c) and PSA level has been ranged into 2 groups (7.3-12.9, 12.9-16.7). This results shows that ANO3 gene is significantly down regulated (negative fold change) for the two pathology tumor stages (pT2c, pT3c).
Heteroneous Clinical Data
In some cases it is possible to have digital (0-9) and character (a-z) data in the same variable. in this case phenoTest function considers it as Categorical variable(Figure@ref(fig:heterogeneous1.jpeg)).
Study: Prostate Adenocarcinoma, Metastatic (Michigan, Nature 2012)
Cases: All tumor samples (61 samples),
Genetic Profiles: mRNA expression
Gene list: 1021.txt file
Survival variable: OS MONTHS, OS STATUS
Categorical variable: OS STATUS
Numeric variable: Serum PSA level
pVal adjust method: BH
PhenoTest
with three variables (Figure~@ref(fig:prad_MichiganResults.png) )
In This test, Overall Survival (OS_STATUS) was used in survival and caterogical variables. The Clinical Data does not have enougth categorical variables. Figure~@ref(fig:prad_MichiganResults.png) B and C shows signicant association between 7 genes and Living Status (OS_STATUS.Living.pval column). The two last columns show opposite regulation of the 7 genes expression in living patient with serum PSA level. The Cox proportion hazard model does not give results with survival variables (OS_STATUS column).
Study:Lung Adenocarcinoma (TCGA, Nature, in press)
Cases: All Samples with mRNA expression data (230 samples),
Genetic Profiles: mRNA expression z-Scores (RNA Seq V2 RSEM)
Gene list: 1021.txt file
Survival variable: empty
Categorical variable: OS STATUS
Numeric variable: OS_MONTHS
pVal adjust method: BH
PhenoTest with two variables.
In this Lung cancer Study, the test shows significant association between living patient and 10 genes expression (Figure~@ref(fig:LungNatureResults.png)).
GSEA-R
Gene Set Enrichment Analysis (GSEA) is computational method that uses expression matrix of thousands of genes with phenotypes data (two biological states) and Molecular Signatures DataBase (MSigDB) to define which biological process or pathway or immune system are significantly different under the phenotypes and which genes are associated~(Subramanian et al. 2005).
Preprocessing of Exprimental Data
getGCT_CLS
function loads Profile and Clinical data of
selected study and saves two files into “gct_cls” folder
(Figure~@ref(fig:gct_cls.png)C).
The GCT file contents genes expression values with genes in the rows and samples in the columns.
The CLS file contents the two biological phenotypes selected from Clincical data. User needs to select clinical phenotype only with two classes.
Molecular Signatures DataBase
The Molecular Signatures DataBase (MSigDB) is a collection of annotated gene sets for use with GSEA computational method. The MSigDB gene sets are divided into 7 collections (positional gene sets, curated gene sets, motif gene sets, computational gene sets, GO gene sets, oncogenic signatures, and immunological signatures). All these collections are available at Broad Institute. Every collections consists in a tab delimited file format (.GMT file) that describes gene sets. Each row shows annotation terme with associated genes. User needs to download .gmt file with genes Symbols and saves them into “workspace/MSigDB/” folder. The MSigDB folder is created with the file menu in the starting windows(Figure@ref(fig:starting.png)).
For more detail about GCT, CLS, GMT
files, see this link.
MSigDB Collection
C1: Positional Gene Sets Gene sets corresponding to each human chromosome and each cytogenetic band that has at least one gene. These gene sets are helpful in identifying effects related to chromosomal deletions or amplification, epigenetic silencing, and other region effects.
C2: Curated Gene Sets into Pathways Gene sets collected from various sources such as online pathway databases.
- CGP: Chemical and Genetic Perturbation - Gene sets represent expression signatures of genetic and chemical perturbations.
- CP: Reactome gene sets - Gene sets derived from the Reactome pathway database.
C3: Motifs Gene Sets Gene sets that contain genes that share:
MIR: microRNA targets A 3’-UTR microRNA binding motif.
TFT: tanscription factor targets A transcription factor binding site defined in the TRANSFAC ([version 7.4(http://www.gene-regulation.com/) database.
C4: Computational Gene Sets Computational gene sets defined by mining large collections of cancer-oriented microarray data.
C5: GO Gene Sets Gene sets are named by GO term (GO and contain genes annotated by that term: Biological Process, Cellular Component, and Molecular Function.
C6: Oncogenic Signatures Gene sets represent signatures of cellular pathways which are often dis-regulated in cancer. The majority of signatures were generated directly from microarray data from NCBI GEO.
C7: Immunologic Signatures Gene sets that represent cell states and perturbations within the immune system. This resource is generated as part of the Human Immunology Project Consortium (HIPC).
Examples
Study: Uterine Corpus Endometrioid Carcinoma (TCGA, Nature 2013)
Cases: All Samples with mRNA, CNA, and sequencing data (232 samples),
Genetic Profiles: mRNA expression (RNA Seq V2 RSEM)
MSigDB: c5.bp.v4.0.symbols
Gene list: 1021.txt file
Nbr of Samples: 100
Phenotype: DFS_STATUS
Based only on Gene list the function getGCT,CLS files
builts the .gct
and .cls
files and save them
under the folder “/gct_cls/”. The Figure~@ref(fig:gct_cls.png) shows the
pre-porcessing steps to get gct
and cls
files.
For enrichment, GSEA
function needs three files. The
gct
file with gene expression, the cls
with
phenotypes and gmt
file with Molecular signature of Gene
Sets. There are two options to load gmt
file, from examples
(Figure~@ref(fig:GSEA-R.png)A, MSigDB.gmt button) available into
canceR
package or from “workspace/MSigDB/” folder
(Figure~@ref(fig:GSEA-R.png)A, browse button) . In the two ways the
gmt
files must be from Broad Institute
and has gene Symbols.
Study: Breast Invasive Carcinoma (TCGA, Provosional)
Cases: All Samples with mRNA expression data (562 samples),
Genetic Profiles: mRNA expression (RNA Seq V2 RSEM)
MSigDB: c5.bp.v4.0.symbols
Gene list: 1021.txt file
Nbr of Samples: 100
Phenotype: OS_STATUS
The Figure~@ref(fig:figbreastGSEA) summarizes the gene sets enrichment analysis of Breast Invasive Carcinoma study using “Deceased/living” phenotypes. The Figure~ef(fig:figbreastGSEA)C shows 4 vs 1 biological process involved respectively into Deceased/Living phenotypes. The size and the genes of appropriate GS are indicated in the second (size) and third (source) columns. The report of significant GS are saved into “/Results/GSEA/name_of_folder/”. Every GS has a report (.txt file) indicating the gene list and which genes (CORE_ENRICHMENT column: YES) are involved in the specific phenotype (DECEASED for RESPONSE_To_STRESS). The plots of significant GS are save with .pdf format file. In a heat map, expression values are represented as colors for every patient, where the range of colors (red, pink, light blue, dark blue) shows the range of expression values (high, moderate, low, lowest). For more details about result interpretation see user guide of GSEA.
GSEA-R Result Interpretation
The primary result of the gene set enrichment analysis is the enrichment score (ES), which reflects the degree to which a gene set is overrepresented at the top or bottom of a ranked list of genes. A positive value indicates correlation with the first phenotype and a negative value indicates correlation with the second phenotype. For continuous phenotypes (time series or PSA level), a positive value indicates correlation with the phenotype profile and a negative value indicates no correlation or inverse correlation with the profile~(Subramanian et al. 2005).
The number of enriched gene sets that are significant, as indicated by a false discovery rate (FDR) of less than 25%. Typically, these are the gene sets most likely to generate interesting hypotheses and drive further research.
The number of enriched gene sets with a nominal p-value of less than 1% and of less than 5%. The nominal p-value is not adjusted for gene set size or multiple hypothesis testing; therefore, it is of limited value for comparing gene sets.
The false discovery rate (FDR) is the estimated probability that a gene set with a given NES represents a false positive finding. For example, an FDR of 25% indicates that the result is likely to be valid 3 out of 4 times. The GSEA analysis report highlights enrichment gene sets with an FDR of less than 25% as those most likely to generate interesting hypotheses and drive further research, but provides analysis results for all analyzed gene sets. In general, given the lack of coherence in most expression datasets and the relatively small number of gene sets being analyzed, an FDR cutoff of 25% is appropriate. However, if you have a small number of samples and use geneset permutation (rather than phenotype permutation) for your analysis, you are using a less stringent assessment of significance and would then want to use a more stringent FDR cutoff, such as 5%~(Subramanian et al. 2005).
Resolved limits
GSEA does not accept negative values from Profile data. In this case the adding of absolute of less negative value to all the matrix is done.
GSEA does not accept missing value in file. The sampling is done only on existing phenotype information.
GSEA needs more than 10000 to be robust but url/gcds-r package accept less that 1000 genes.
The size of samples is between 50 and 100
Removing and cleaning the heterogeneity of the data frames of gene expression: space, character, empty boxes and convert them to readable form by GSEA-R function.
Linear Modeling of GSEA (GSEAlm)
GSEAlm is a function implemented from GSEAlm package~(Oron, Jiang, and Gentleman 2008).
GSEAlm
function is a Linear Model inference and diagnostics
for Gene Set Enrichment Analysis. It uses mRNA expression matrix of gene
list, variable(s) from clinical data (phenotype) and Molecular Signature
Data Base (MSigDB) that groups genes sharing common biological function,
chromosomal location, pathway or regulation~(Subramanian et al. 2005). The result is a
prediction of the most up/down regulated gene sets belonging to one of
MSigDB collections~Liberzon et al.
(2011).
The linear model assumes that the mean of the response variable has a linear relationship with the explanatory variable(s). The data and the model are used to calculate a fitted value for each observation (gene expression). It is strongly recommended to use crude gene expression data and avoid z-score or standardized pre-processing data. we recommend to use the mRNA expression (RNA Seq V2 RSEM).
Two options are available to get linear model. In the first option (phenotypes into disease) the model predicts which gene sets are modulated between patients having the same disease and different phenotypes (OS_STATUS, DFS_STATUS). In the second option (disease vs disease) the model predicts which gene sets are modulated between patient having different disease.
The output is saved in
/Results/GSEAlm/selected-disease-name
folder. The names of
output files describe their content. Three files are saved by model. The
pVal_MSigDB_GeneList_Disease.txt} file lists full results. The
down/upRegulated_MSigDB_GeneList_Disease.txt} files filter only
significant gene sets. The filtered result is merged in one table and
displayed in the screen.
Results interpretation:
NA~~NA: The gene set is unrepresentative in the used gene list
1~~1: No significant different of mRNA expression between the two phenotypes
Limitations:
Use categorical phenotype (not numeric) only with TWO classes
Use crude and not normalised mRNA expression data
The accuracy of the results is better with high number of genes (1000 - 10000) and 1000 permutations. This request takes a while to run. User is recommended to reduce the permutation to 100 instead 1000 and/or reduce the size of gene list.
If two or more phenotypes are checked, only the latter is taken.
Which Molecular Signature Data base (MSigDB) for gene list
This function matches genes list with MSigDB files selected from example or directory (Figure~@ref(fig:whichMSigDB)) and computes the mean of matched Genes by Gene Sets as:
$$ Mean_{(Gene\in GeneSet)} = \frac{ \sum_{1,1}^{I,J} Gene_i \in GeneSet_j}{\sum_{1}^{I} Gene_i} $$
With I is the number of genes in the list and J is the number of Gene Sets in the MSigDB file. \ The returned table indicates the mean of gene number that matched for every Gene Set. For example in the first row (Figure~@ref(fig:whichMSigDB)), there are about 10 genes that mached for every Genes Set in c2.cp.reactome.v4.0.Symbol.gmt.
get SubMSigDb for genes list
The SubMSigDb is a subset of MSigDB generated from gene list in the expression Set (eSet). This specific subsetting reduces the time of GSEA computing. User needs to run before eSet from phenoTest menu.
GSEAlm: Phenotypes into Disease
Disease Free Status (DFS_STATUS) into Prostate Cancer:
Study: Prostate Adenocarcinoma (TCGA, Provisional)
Cases: All Samples with mRNA expression data (246 samples),
Genetic Profiles: mRNA expression (RNA Seq V2 RSEM)
MSigDB: c2.cp.reactome.v4.0.symbols.gmt
Gene list: 73.txt file
Phenotype: DFS_STATUS
Permutation: 1000
pVal: 0.05
This example uses Reactome pathways gene sets (Figure~@ref(fig:pradGSEAlm)A, (http://www.reactome.org/) to compare the gene expression of patients with reccured prostate disease versus patient with free prostate disease. The run was done with 1000 permuattion and pVal 0.05 (Figure~@ref(fig:pradGSEAlm)B). The result (Figure~@ref(fig:pradGSEAlm)C) shows only up regulated gene sets from Reactome pathways were observed in disease free patients.
Copy Number Cluster Level into Stomach Adenocarcinoma:
Study: Stomach Adenocarcinoma (TCGA, Nature 2014)
Cases: All Samples that have mRNA, CNA, and sequencing data (258 samples),
Genetic Profiles: mRNA expression (RNA Seq V2 RSEM)
MSigDB: c5.bp.reactome.v4.0.symbols.gmt
Gene list: 73.txt file
Phenotype: Copy_Number_Cluster (Low, High)
Permutation: 1000
pVal: 0.05
The losses and the gains of DNA can contribute to alterations in the expression of tumor suppressor genes and oncogenes. Therefore, the identification of DNA copy number alterations in tumor genomes may help to discover critical genes associated with cancers and, eventually, to improve therapeutic approaches. In this study we test GSEAlm algorithm with the level of the Copy Number cluster using Biological Process gene sets from Reactome. The Figure~@ref(fig:stadGSEAlm)C shows significant down/up regulated gene sets in patients with low level compared to patients with high level of copy number cluster.
This finding suggests to repeat modeling with copy number alteration profile to predict which biological process (gene set) could be with low level of copy number cluster. The Figure~@ref(fig:stadGSEAlmCNA)D lists gene sets with low level of copy number cluster in the case of stomach adenocarcinoma.
GSEAlm: Disease vs Disease}
Breast vs Prostate Cancers:
In this function, the linear modeling uses the disease type as phenotype for the run. User needs to select two diseases and a gene list.
Studies: Breast Invasive Carcinoma (TCGA, Provisional) versus Prostate Adenocarcinoma (TCGA, Provisional)
Cases: All Samples with mRNA expression data (959/257 samples),
Genetic Profiles: mRNA expression (RNA Seq V2 RSEM)
MSigDB: c2.cp.reactome.v4.0.symbols.gmt
Gene list: 73.txt file
Phenotype: Diseases type
Permutation: 1000
pVal: 0.05
Samples number: 50
The Figure~@ref(fig:brstprstGSEAlm) shows the results of the linear modeling.
Genes Classification using mRNA expression (Classification)
The Classification menu displays two functions to rank genes by phenotypes into- and inter-diseases, depending on mRNA expression data.
Genes vs Diseases (inter-diseases)
The first classifier is implemented from geNetClassifier package~(Aibar et al. 2013). It uses calculateGenesRanking function which based on Parametric Empirical Bayes method included in EBarrays package~(Kendziorski et al. 2003). This method implements an expectation-maximization (EM) algorithm for gene expression mixture models, which compares the patterns of differential expression across multiple conditions and provides a posterior probability. The posterior probability is calculated for each gene-class pair, and represents how much each gene differentiates a class from the other classes; being 1 the best value, and 0 the worst. In this way, the posterior probability allows to find the genes that show significant differential expression when comparing the samples of one class versus all the other samples (One-versus-Rest comparison)~(Aibar et al. 2013).
In the following examples, we would like to predict specific modulated genes by cancer type. The features of the runs are:
Example 1: Breast vs Glioblastoma vs Liver vs Lung Cancers (Figure~@ref(fig:GenesClass)A):}
Studies:
Breast Invasive Carcinoma (TCGA, Provisional)
Glioblastoma Multiforme (TCGA, Provisional)
Liver Hepatocellular Carcinoma (TCGA, Provisional)
*Lung Squamous Cell Carcinoma (TCGA, Provisional)
Cases: All Samples with mRNA expression data,
Genetic Profiles: mRNA expression (RNA Seq V2 RSEM)
Samples: 50
Gene list: 223.txt file
lpThreshold: 0.95
The significant genes (dots) are over the threshold of posterior probability (Figure~@ref(fig:GenesClass)B, B’). Their number are listed in the legend. The details are displayed in table (Figure~@ref(fig:GenesClass)C, C’) and saved in /Results/Classifier folder.
Example 2: Bladder vs Breast vs Glioblastoma vs Lung vs Ovarian vs Prostate Cancers (Figure~A’):}
Studies:
Bladder Urothelial Carcinoma(TCGA, Provisional)
Breast Invasive Carcinoma (TCGA, Provisional)
Glioblastoma Multiforme (TCGA, Provisional)
Lung Adenocarcinoma (TCGA, Provisional)
Ovarian Serous Cystadenocarcinoma (TCGA, Provisional)
Prostate Adenocarcinoma (TCGA, Provisional)
Cases: All Samples with mRNA expression data,
Genetic Profiles: mRNA expression (RNA Seq V2 RSEM)
Samples: 50
Gene list: 73.txt file
lpThreshold: 0.95
Genes vs Phenotypes (intra-disease)
The second function of genes classification is implemented from rpartpackage~(Therneau, Atkinson, and Ripley 2014). The resulting models can be represented as binary trees with gene expression profile threshold (P53 > 2.56) is in node and classes (Living/Deceased) of selected variable in branch. The root of the tree is the best gene divisor of classes. The goal is to pedict which genes combination (P53> 2.56 + CAD < -0.45 + MDM4 > 1.92 lead to 80% Diseased) could be split classes in two or more groups. The tree is built by the following process: first the single variable is found which gene level splits the data into two groups. The data is separated, and then this process is applied separately to each sub-group, and so on recursively until the subgroups either reach a minimum size or until no improvement can be made~(Therneau, Atkinson, and Ripley 2014).
There are 3 methods of splitting rule : classification, anova, and Poisson.
The Classification used either Gini or log-likelihood function rules. It is used when there are only two categories into the selected variable. The dependent variable is nominal (factor). At each splitting step, the rule tries to reduce the total impurity of the two son nodes relative to the parent node.
In the anova, the variable is numeric and it used to predict the closest value to the true one. The method uses splitting criteria SST − (SSL + SSR), where SST = ∑(yi − (̄y)2 is the sum of squares for the node, and SSR, SSL are the sums of squares for the right a,d left son respectively. This is equivalent to choosing the split to maximize the between-groups sum-of-squares in a simple analysis of variance~(Therneau, Atkinson, and Ripley 2014).
The poisson splitting method attempts to extend rpart models to event rate data. The model in this case is λ = f(x), where λ is an event rate and x is some set of predictors.
Genes vs Phenotypes (intra-disease)
The second function of genes classification is implemented from rpart package~(Therneau, Atkinson, and Ripley 2014). The resulting models can be represented as binary trees with gene expression profile threshold (P53 > 2.56) is in node and classes (Living/Deceased) of selected variable in branch. The root of the tree is the best gene divisor of classes. The goal is to pedict which genes combinaison (P53> 2.56 + CAD < -0.45 + MDM4 > 1.92 lead to 80% Diseased) could be split classes in two or more groups. The tree is built by the following process: first the single variable is found which gene level splits the data into two groups. The data is separated, and then this process is applied separately to each sub-group, and so on recursively until the subgroups either reach a minimum size or until no improvement can be made~(Therneau, Atkinson, and Ripley 2014).
There are 3 methods of splitting rule : classification, anova, and Poisson.
The Classification used either Gini or log-likelihood function rules. It is used when there are only two categories into the selected variable. The dependent variable is nominal (factor). At each splitting step, the rule tries to reduce the total impurity of the two son nodes relative to the parent node.
In the anova, the variable is numeric and it used to predict the closest value to the true one. The method uses splitting criteria SST − (SSL + SSR), where SST = ∑(yi − (̄y)2 is the sum of squares for the node, and SSR, SSL are the sums of squares for the right a,d left son respectively. This is equivalent to choosing the split to maximize the between-groups sum-of-squares in a simple analysis of variance~(Therneau, Atkinson, and Ripley 2014).
The poisson splitting method attempts to extend rpart models to event rate data. The model in this case is λ = f(x), where λ is an event rate and x is some set of predictors.
Example 1: Genes classification vs OS_STATUS (Living/Deceased)
Studies: Breast Invasive Carcinoma (TCGA, Provisional)
Cases: All Samples with mRNA expression data (526 samples),
Genetic Profiles: mRNA expression z-score (RNA Seq V2 RSEM)
Gene list: 223.txt file
Variable: OS_STATUS
Split method: class
In this example, the main clinical endpoint of interest is the Living/Deceased Status of patient having breast cancer. We run classification to predict which genes from 223 that make the difference between deceased and living patient having breast cancer. The tree in Figure~@ref(fig:GenePhenoClass1)B indicates that all deceased patients have the following z-score gene expression profile: RAD51<-1.091, HSPA1A>1.424, JUN> -0.4016. All remain patient are living.
Example 2: Genes regression vs OS_STATUS (Living/Deceased)
Studies: Breast Invasive Carcinoma (TCGA, Provisional)
Cases: All Samples with mRNA expression data (526 samples),
Genetic Profiles: mRNA expression z-score (RNA Seq V2 RSEM)
Gene list: 223.txt file
Variable: OS_STATUS
Split method: anova
When we split the same clinical data used in the first example (Living/Deceased) using regression method (anova), we see in the Figure~@ref(fig:GenePhenoClass2)C the same genes and split points with further splitting nodes. For example, the gene HSPA11 has 124 patients with 109 are living. In classification method, all patient have the same predicted value (0.846, Figure~@ref(fig:GenePhenoClass1)C) because the error (misclassification) with and without the split is identical. In the regression context the two predicted values of 16.08 and 1.84 (Figure~@ref(fig:GenePhenoClass2)B) are different. The split has identified a nearly pure subgroup of significant size.
Example 3: Genes classification vs tumor grade (grade1/2/3)
Studies: Uterine Corpus Endometrioid Carcinoma (TCGA, Nature 2013)
Cases: All Samples with mRNA expression data (333 samples),
Genetic Profiles: mRNA expression z-score (RNA Seq V2 RSEM)
Gene list: 223.txt file
Variable: Tumor Grade
Split method:
Classification method could work with phenotype with more than two classes. In this case, the tumor grades are splitted following this order from left to right Grade1/Grade2/Grade3. The nodes are named by the must frequent grade (Figure~@ref(fig:GenePhenoClass3)).
Plots
Their are two plotting functions.The first one (1 Gene/ 2 Gen. Profiles) plots gene data for specified case and two genetic profiles from the same study. It associates between the two selected genetic profiles. The dialog box allows user to specify:
- Layout Skin
- cont: This is the default skin. It treats all data as being continuous
- disc: Repuires a single gene and a single genetic profile. It is not available.
- disc_cont: Requires two genetic profiles. The first datasetin handled as being discrete data, and the function generates a boxplot with distributions for each level of the discrete genetic profile.
- cna_mrna_mut : This skin plots mRNA expression level as function of CNA or DNA methylation status for given gene. Data points are colored respectively by mutation status or CNA and mutation status.
- Correlation Method
- Pearson correlationis is used for parametric distribution (more than 30 samples by genetic profile)
- Spearman correlation is used for non-parametric data.
- Kendall tau is non-parametric test that mesures the rank correlation.
Example: Association of P53 copy number alteration and mRNA exprssion in glioblastoma
- Study: Glioblastoma Multiforme (TCGA, Provisional)
- Cases: All tumor Samples that have mRNA,CNA and sequencing data (135 samples),
- Genetic Profiles 1: Putative copy-number alterations from GISTIC
- Genetic Profiles 2: mRNA expression (RNA Seq V2 RSEM)
- Gene: P53
- Skin: cna_mrna_mut
- correlation method:
No significant pearson correlation was observed between P53 Copy Number Variation (CNV) and P53 mRNA expression (r=0.23, Figure~@ref(fig:plot1)B). The CNV is ranged into 4 levels that derived from the copy-number analysis algorithms GISTIC or RAE, and indicate the copy-number level per gene. “-2” is a deep loss, possibly a homozygous deletion (Homdel), “-1” is a single-copy loss (heterozygous deletion: Hetloss), “0” is Diploid, “1” indicates a low-level gain, and “2” is a high-level amplification. Note that these calls are putative.
The second plot function evaluates the relationship of two genes expression levels in the same study (Figure~@ref(fig:plot2)).
Example: MAP2K2 and ABHD17A mRNA expression (RNA Seq V2 RSEM) levels in Uterine Corpus Endometrioid Carcinoma (TCGA, Nature 2013)
Study: Uterine Corpus Endometrioid Carcinoma (TCGA, Nature 2013)
Cases: All Samples with mRNA expression data (333 samples),
Genetic Profiles: mRNA expression (RNA Seq V2 RSEM)
Genes: MAP2K2 and ABHD17A
Correlation method:
Survival Plots
In medical research is often useful to estimate the survival of patient amount time at tumor stage, or after treatment or particular event. The OS_MONTHS is the overall Survival duration of patient after the first surgery. The OS_STATUS is the event at OS_MONTHS. The survival plot works only with studies that have non empty OS_MONTHS and OS_STATUS.
Kaplan-Meier Curves
The Kaplan-Meier estimator mesures the fraction of patients in life for a certain amount of time after the first surgery. The survival curve can be created assuming various situations. This can be calculated for two groups (DiseaseFree, Recurred) or more of subjects. When the shapes of the curves are similar, the Survival would not be dependent of the groups. The Figure~@ref(fig:KM) shows two plots of survival curves depending, in left, to Tumor stage of patients grouped into 4 stages. The curves show that patients with advanced stage (4) have less survive than early ones (stage 1). in the same way, the right plot shows more survival patients without disease than patients with recurred disease.
Cox proportional Hazards Model
A Cox model is a statistical technique for exploring relationship between the survival of a patient and several explanatory variables. In survival analysis the Cox model is preferred to a logistic model, since the latter one ignores survival times and censoring information. The Figure~@ref(fig:Coxph) shows an example of Cox model of survival patients with 62 years old. If selected variable has NA value (Censoring data), two curves were plotted (censored and variable).
Circos Style
Circular layout is an interesting way to integrate multi-omics heterogeneous and big data of cancer disease in the same plot~(Krzywinski et al. 2009). The goal is to make easy the interpretation and the exploring of the relationships between cancers, genes or dimensions.
There are two R packages (RCircos and Circlize) available for Circular layout but its use remain laborious and needs computational skills.
CanceR package implements getCircos function to facilitate the visualization of cancer disease using Circos style. User needs only to select cancers and check which dimensions will be plotted.
User can select a simple gene list from files or examples or can focus on gene list from gene sets selected from MSigDB.
In the following case, I focus my exploring to two gene lists corresponding to gene set involved in DNA repair and Response to oxidative stres. canceR package allows user to select any gene sets from MSigDB without gene duplication.
I selected mRNA (0.3 threshold), CNA (0.85), Met HM450 (0.3), Mutation (Frequency 101). Only genes with significant rates are plotted with corresponding colors. For example Gold for mutation, Orange (Methylation), Green (CNA), red (mRNA expression) (Figure~@ref(fig:dialogCircos)).
I selected 5 cancers represented with 5 sectors. In the same sector there are 7 tracks (layouts) corresponding respectively (out : in) to: Gene List, Gene Sets, mRNA, CNA, Methylation, Mutation (Figure~@ref(fig:Circos)).