DEComplexDisease is designed to find the differential expressed genes (DEGs) for complex diseases, which are characterized by the heterogeneous expression profiles. Different from the established DEG analysis tools, it does not assume the patients of complex diseases to share the common DEGs. By applying a bi-clustering algorithm, DEComplexDisease finds the DEGs shared by many patients. In this way, DEComplexDisease describes the DEGs of complex disease in a novel syntax, e.g. a gene list composed of 200 genes are differentially expressed in 30% percent of studied complex disease patients.
Applying the DEComplexDisease analysis results, users are possible to find the patients affected by the same mechanism based on the shared signatures. This can be achieved by modelling the breakpoints of the bi-clustering analysis and enrichment analysis to the feature patients or genes, e.g. the patient carrying the same mutations. DEComplexDisease also supplies visualization tools for nearly all the output.
if (!requireNamespace("BiocManager", quietly=TRUE))
install.packages("BiocManager")
BiocManager::install("DEComplexDisease")
DEComplexDisease needs huge computing powers to do the whole analysis for the reasons that (1) it is designed for big data, which usually have hundreds of patients; (2) it implements a bi-clustering algorithm in many steps. Therefore, it is highly recommended to use multi-core parallel computing.
In DEComplexDisease
package, we use mclapply
tool of parallel
package to do the multiple process computing. Users just need set “cores = n” in the DEComplexDisease
functions to make use of multi-core hardware, where is “n” is the core number.
Before the analysis, it is better start a new session or run
rm(list=ls())
to clear the current session. Otherwise, the whole session will be copy to each process, which may consume Huge ROM memory. Once the memory is ran out, DEComplexDisease
may report wrong results or other problems.
In this manual, all the examples assume users to have a 4-core computer by setting cores
=4.
DEComplexDisease
takes two mandatory inputs: an expression matrix (exp) and a sample annotation vector (cl). The expression matrix can be the RNA-seq counts data or normalized microarray expression data. The samples annotation vector (cl) is a vector to indicate the disease states of samples. Mandatorily, cl
has the same length and order with the columns of exp
. cl
only has two possible values: 1 and 0. 1 indicates the corresponding samples to be patients and 0 is control or normal samples. The optional input is the clinical annotation data, which can be use for visualization in Plot() function. The clinical annotation should have the row.names
matched by the column names of exp
.
library("DEComplexDisease")
#load RNA-seq counts matrix
data(exp)
#load sample annotation vector
data(cl)
#load sample ER status annotation
data(ann.er)
exp[1:5,1:5]
## TCGA.D8.A27G.01A TCGA.A2.A04N.01A TCGA.A8.A096.01A TCGA.BH.A0BZ.01A
## POLRMTP1 59 5 80 91
## C6orf52 93 59 25 40
## NDUFS6 3356 2160 3529 6269
## KCTD17 761 438 988 972
## CEP126 510 317 1303 497
## TCGA.BH.A0E2.01A
## POLRMTP1 58
## C6orf52 196
## NDUFS6 2684
## KCTD17 437
## CEP126 199
head(cl, 4)
## TCGA.D8.A27G.01A TCGA.A2.A04N.01A TCGA.A8.A096.01A TCGA.BH.A0BZ.01A
## 1 1 1 1
DEComplexDisease applies bi.deg
function to estimate the distribution parameters that describes the gene expression profiles of control samples. The normal samples are collected based on cl
. bi.deg
has three methods to estimate the reference expression profiles of control samples: “edger”, “deseq2” or “normalized”. “edger” or “deseq2” is used for RNA-seq counts data by implementing the algorithms developed by edgeR or DESeq2. The dispersion (disp) and mean (mu) are estimated for each gene. The count number of \(x_{i,j}\) is tested by
p=pnbinom(x, size=1/disp, mu=mu, lower.tail = F)
“normalized” is used for normalized RNA-seq or microarray data. The mean (mu) and standard deviation (sd) is estimated for each gene. The z-score and p-value is calculated by
z=(x-mu)/sd
p=pnorm(z,lower.tail=F)
Using the p-value cutoff defined by the users, bi.deg
assigns 1 or -1 to indicate the up- or down-regulated genes, where 1 is the up-regulated genes and -1 is the down-regulated genes. The other genes are assigned with 0. In this example,
deg=bi.deg(exp, cl, method="edger", cutoff=0.05, cores=4)
## Using classic mode.
bi.deg
returns a deg
object, which is a matrix of 1,0 and -1. Users can use Plot() to view the analysis results.
Plot(deg, ann=ann.er, show.genes=row.names(deg)[1:5])
## All mutation types: Up, Down.
## `alter_fun` is assumed vectorizable. If it does not generate correct
## plot, please set `alter_fun_is_vectorized = FALSE` in `oncoPrint()`.
Here, users can use show.genes
to display the selected genes. Otherwise, the max.n
genes with maximum enrichment will be showed. In this example, we also use a ann
to show the annotation for ER status of the patients.
The DEGs from bi.deg
have noises, e.g. the DEGs not associated with disease, when one sample is tested again references. The idea behind his analysis is that the disease associated DEGs are supposed to be observed in other patients. In another words, when there are enough samples, the patients can be used to cross-validation of high-confident DEGs. deg.specific
implements a bi-clustering analysis algorithm to the binary DEG matrix to find the high-confident disease associated DEGs.
deg.specific
is used to find the cross-validated DEGs. Users only need to choose the proper minimum gene and minimum patient number by setting min.genes
and min.patients
. Please note that min.patients
includes the seed patient itself.
res.deg=deg.specific(deg, min.genes=30, min.patients=5, cores=4)
If users only want to see the results some selected patients, use test.patients
to reduce the computation time.
res.deg.test=deg.specific(deg, test.patients=colnames(deg)[1:10], min.genes=50,
min.patients=8, cores=4)
deg.specific
returns a deg.specific
object, which is a list comprising of the cross-validated DEGs and the support neighbors. If test.patients
is set, a deg.specific.test
object is returned. Users can use Plot() to visualize the deg.specific
and deg.specific.test
object. In Figure 2, we shows the validated DEGs in all used breast cancer patients.
Plot(res.deg, ann=ann.er, max.n=5 )
## All mutation types: Down, Up.
## `alter_fun` is assumed vectorizable. If it does not generate correct
## plot, please set `alter_fun_is_vectorized = FALSE` in `oncoPrint()`.
For res.deg.test
, it can also be plotted :
Plot(res.deg.test, ann=ann.er, max.n=5)
## All mutation types: Up, Down.
## `alter_fun` is assumed vectorizable. If it does not generate correct
## plot, please set `alter_fun_is_vectorized = FALSE` in `oncoPrint()`.
In this work, the DEG modules refer to the DEG list shared by many patients. DEG modules are supposed to be the signatures of patients shared the similar causal mechanism. seed.module
and cluster.module
are designed to find such modules.
Like deg.specific
, seed.module
carries out a bi-clustering analysis to the output of bi.deg
using each patient as a seed. The difference is that this function has more complex setting and steps to predict DEGs modules shared by many patients.
seed.mod1 = seed.module(deg, res.deg=res.deg, min.genes=50, min.patients=20,
overlap=0.85, cores=4)
or
seed.mod2 = seed.module(deg, test.patients=colnames(deg)[1:10], min.genes=50,
min.patients=20, overlap=0.85, cores=4)
No matter whatever the parameter setting is, seed.module
will firstly try to find a modules shared by all the patients, where the final patient number may be less than the min.patients
and gene number may be less than min.genes
. If such module exists, it will named as M0
and the module genes of M0
will be removed from further discovery to module genes. That is to say, module genes of M0
will not be included in other modules.
The bi-clustering analysis is started by a DEG seed, composing of the DEGs of a patient. If res.deg
is set, only the patients with cross-validated DEGs will be used as seeds and the seed will initialized with the cross-validated DEGs. Otherwise, all the patients will be used and all the DEGs are used as seed. The DEGs of patients will be gradually removed to check if the left seed are observed in min.patients
when keeping the similarity is not less than overlap
. seed.module
will record the track of gene-patient number in the bi-clustering analysis, which is stored in a curve
key of output for each patient. If test.patients
is set, only the patients listed in test.patients
are used as seed for bi-clustering analysis.
seed.module
will record the bi-clustering results at three scenarios:
max.genes
records the patient and genes information when the seed is observed in min.patient
. max.patients
stores the patient and gene information when min.genes
are observed, which is also the terminated point of bi-clustering analysis.model
stores the gene/patient information when the gene-patients number curve
has satisfied some modelling criteria defined by 'model.method', which may indicate the inclusion/exclusion of molecular mechanism. In current version, 'model.method' has four possible values: “slope.clustering”, “max.square”, “min.slope” and “min.similarity”, which indicate the different four different modelling methods:
slope.clustering
has maximum slope changes, which may indicate the inclusion/exclusion of molecular mechanism;max.square
is the gene-patients number that has the maximum product;min.slope
has the minimum slope in gene-patient number curve;min.similarity
is the point with minimum similarity scores seed.module
will return a 'seed.module' object. This is a list. It has one key with prefix of “decd”:
It may have one key of “M0”:
Other keys are patient IDs, which are the modules predicted with DEG seed of the patient. Each one have several keys:
curve
;The 'seed.module' object can visualized with Plot().
Plot(seed.mod1, ann=ann.er, type="model", max.n=5)
## All mutation types: >= 0.85.
## `alter_fun` is assumed vectorizable. If it does not generate correct
## plot, please set `alter_fun_is_vectorized = FALSE` in `oncoPrint()`.
For the big data, there are usually many patient samples and DEComplexDisease may predict too many patient-seeded modules. cluster.module
is used to cluster the patient-seeded modules by a modified k-means based on their patient and gene signature similarity. The patients within the same cluster are ranked based on their connecting degrees so that to find the representative patient(s). if vote.seed
is set as false, the bi-clustering analysis results of the representative patient will be used as the final results of the module. Otherwise, a generic seed will be generated by a voting method and the final results is predicted by bi-clustering analysis using the new seed. All the modules will marked as “M1”, “M2”, “M3”…
cluster.mod1 <- cluster.module(seed.mod1, cores=4)
or
cluster.mod2 <- cluster.module(seed.mod1, vote.seed=TRUE, cores=4)
cluster.module
returns a cluster.module
object.
sort(names(cluster.mod1), decreasing=TRUE)
## [1] "decd.input" "decd.clustering" "M4" "M3"
## [5] "M2" "M1" "M0"
names(cluster.mod1[["decd.input"]])
## [1] "overlap" "deg" "test.patients" "min.genes"
## [5] "min.patients" "model.method" "vote.seed"
names(cluster.mod1[["decd.clustering"]])
## [1] "group" "represent"
names(cluster.mod1[["M1"]])
## [1] "max.genes" "max.patients" "genes.removed" "patients.added"
## [5] "curve" "seed" "model"
A cluster.module
has one key with prefix of “decd”:
Other keys has a prefix of “M”, which indicates modules. Each module have several keys:
min.patients
is observed in bi-clustering analysis;min.genes
is reached in bi-clustering analysis";curve
;The deg.module
can be visualized by Plot().
Plot(cluster.mod1, ann=ann.er, type="model", max.n=5)
## All mutation types: >= 0.85.
## `alter_fun` is assumed vectorizable. If it does not generate correct
## plot, please set `alter_fun_is_vectorized = FALSE` in `oncoPrint()`.
The DEG modules may have partial overlaps for either genes or patients. Use “module.overlap” to check the gene and patient overlap among modules. This function is useful to check the relationship of modules and to choose the proper modules during the exploratory discovery steps.
module.overlap(cluster.mod1, max.n=5)
module.compare
is used to compare the modules from different studies, e.g. the different diseases or the different data for the same disease. In following examples, we calculated the modules for both ER+ and ER- breast cancer patients. The modules are compared with module.compare
.
res.mod1 <- seed.module(deg[,1:26], min.genes=50, min.patients=10, overlap=0.85, cores=4)
res.mod1 <- cluster.module(res.mod1)
res.mod2 <- seed.module(deg[,27:52], min.genes=50, min.patients=10, overlap=0.85, cores=4)
res.mod2 <- cluster.module(res.mod2)
module.compare(res.mod1, res.mod2, max.n1=5, max.n2=5)
Please note that, although this function is designed to do module comparison, it does not work to find the modules with distinct composition among conditions.
In the module discovery steps, a bi-clustering algorithm is applied to the binary DEG matrix. The DEGs of seed patients are gradually removed to a number of min.genes
, which may result to a increased patient number from min.patients
. In the output of deg.module
tool, the track of gene-patient number change is recorded as curve
for each module.
names(cluster.mod1[["M1"]][["curve"]])
## [1] "no.gene" "no.patient" "score"
head(cluster.mod1[["M1"]][["curve"]][["no.gene"]])
## [1] 77 76 75 70 64 63
head(cluster.mod1[["M1"]][["curve"]][["no.patient"]])
## [1] 10 11 12 14 15 17
module.curve
can show the patient-gene numbers in a simple way.
module.curve(cluster.mod1, "M1")
In this curve, module.curve
highlights the points of “max.genes”, “model”,“max.patients”.
With the default setting, deg.module
may fail to find the best breakpoints for the model
of some modules. It is possible for users to modify the model
results for all or some modules. module.modelling
provides such a tool. It provides two manners to modify the modelling results by either setting keep.gene.num
or change the model.method
.
Users can change the model
results by manually setting the keep.gene.num
, which is the the gene number where the model
results is select. keep.gene.num
can a integer value or a vector. If it is a integer number, all the modules will have the same keep.gene.num
and this will change the modelling results for all the modules. If it is a vector, its elements should have module names as their names. Otherwise, only the first element will be used and all the modules will be set. When keep.gene.num
is vector, it is not necessary to have the same length as modules. It is possible to only changes some of the modules. And the left modules will use the default setting.
In current version, model.method
has four possible values: “slope.clustering”, “max.square”, “min.slope” and “min.similarity”, which indicate the different four different modelling methods:
slope.clustering
has maximum slope changes, which may indicate the inclusion/exclusion of molecular mechanisms.max.square
is the gene-patients number that has the maximum product;min.slope
is the point with minimum slope in gene-patient number curve;min.similarity
is based on the similarity scores and the point with minimum similarity scores is choosed.x=c(50,40)
names(x)<-c("M1","M3")
new.cluster.mod1=module.modeling(cluster.mod1, keep.gene.num = x, model.method='slope.clustering',
cores=4)
#here, only "M1" and "M3" are modified
new.cluster.mod1=module.modeling(cluster.mod1, keep.gene.num = 50)
# here, all the modules are modified
module.curve(new.cluster.mod1, "M1")
In complex diseases, many patients have the similar clinical trait or carry the same gene mutation. These feature patients are supposed to affected by the common mechanism. model.screen
is used to find the modules that are potentially associated with the feature patients or genes.
module.screen(cluster.mod1, feature.patients=sample(colnames(deg),10))
#search modules
module.screen(seed.mod1, feature.patients=sample(colnames(deg),10),
method="fisher.test")