1 Introduction

We guide you through the individual steps of the BEclear package in their own chapters. They will follow in the logical order of an example of correcting some batch affected DNA methylation data. This article should only give a small tutorial, more details about the individual methods can always be found in the help sections of the BEclear package, e.g. through typing calcBatchEffects in the R environment with the package loaded. To work with the methods contained in the BEclear package, a matrix or data.frame with genes as row-names and samples as column names as well as a samples data.frame with the first column named “sample_id” and the second column named “batch_id” is needed as input.

2 Installation

BEclear is available on Bioconductor. To install it you can therefore use the BiocManager:

if (!requireNamespace("BiocManager", quietly = TRUE)) {
  install.packages("BiocManager")
}
BiocManager::install("BEclear")

Otherwise you can also install BEclear from its Github repository by the following command:

if (!requireNamespace("devtools", quietly = TRUE)) {
  install.packages("devtools")
}
devtools::install_github("David-J-R/MoDentify")

We however recommend installing it through Bioconductor, as this takes care of installing the dependencies and furthermore you can refer to the release of Bioconductor, when using our package, which enables you to reproduce the exact conditions of your run.

During the compilation of the code, many parts of the software will be automatically tested for correct execution and reproduction of expected results. This is implemented in form of unit tests with the help of the testthat package.

When done with the installation you can simply load the package by typing:

library(BEclear)
#> Loading required package: BiocParallel

3 Data

The beta values stored in the ex.data matrix were obtained from level 3 BRCA data from the TCGA portal (Cancer Genome Atlas Research Network et al. 2013). Generally, beta values are calculated by dividing the methylated signal by the sum of the unmethylated and methylated signals from a DNA methylation microrarray. In the level 3 TCGA data, this calculation has already been done. The sample data used here contains averaged beta values of probes that belong to promoter regions of single genes. Another possibility would be to use beta values of single probes, whereby the probe names should then be used instead of the gene names as rownames of the matrix.

You can load our sample data via the following command:

data("BEclearData")

It contains one matrix with the beta values:

knitr::kable(ex.data[1:10,1:5], caption = 'Some entries from the example data-set')

Table 1: Some entries from the example data-set
s20 s21 s22 s23 s24
ACSM3 0.2297873 0.2162873 0.2071987 0.2329269 0.2120593
ADAM28 0.3435064 0.4579607 0.3749625 0.4205235 0.3933762
ADCK1 0.2176142 0.2120385 0.2130803 0.2171312 0.2143814
AFTPH 0.0314942 0.0306752 0.0303586 0.0293008 0.0236312
AKAP7 0.1265222 0.0898430 0.1638099 0.1087261 0.1150119
ANKRD24 0.0516417 0.0427307 0.0371261 0.0434301 0.0430231
ANKRD44 0.3431776 0.3256014 0.2781775 0.3132249 0.2984070
ANKS4B 0.5712550 0.5467739 0.5209191 0.6075328 0.5419098
APCDD1 0.4861491 0.4201033 0.4405887 0.5275998 0.4438821
APOBEC3G 0.3636649 0.3301716 0.3749334 0.3509543 0.4406087

And one data.frame containing the assignment of samples to batches:

knitr::kable(ex.samples[1:10,], caption = 'Some entries from the example sample annotation')

Table 2: Some entries from the example sample annotation
sample_id batch_id
s20 b109
s21 b109
s22 b109
s23 b109
s24 b117
s25 b117
s26 b117
s27 b117
s28 b117
s29 b117

4 Detection of batch effects

For the detection of batch effects we calculate the median difference between the beta values of a gene in a batch and the values of this gene in all other batches. Furthermore we use a non-parametric Kolmogorov-Smirnov test (ks.test) to compare the distribution of the beta value for this gene in the batch and the other batches.

If one gene in a batch has a p-value determined by the ks.test of less or equal 0.01 and a median difference of greater or equal 0.05 it is considered batch effected.

4.1 Detection

For the calculation of the batch effects you just use the calcBatchEffects function. It calculates both median difference and p-value. By default we correct the p-values by the false discovery rate developed by Benjamini and Hochberg (1995), but you can use all adjustment methods covered by p.adjust.methods.

batchEffect <- calcBatchEffects(
  data = ex.data, samples = ex.samples,
  adjusted = TRUE, method = "fdr"
)
#> INFO [2019-05-02 21:27:50] Transforming matrix to data.table
#> INFO [2019-05-02 21:27:50] Calculate the batch effects for 10 batches
#> INFO [2019-05-02 21:27:51] Adjusting p-values
mdifs <- batchEffect$med
pvals <- batchEffect$pval

4.2 Summary

To see which genes in which batches are effected you use the calcSummary function as follows:

summary <- calcSummary(medians = mdifs, pvalues = pvals)
#> INFO [2019-05-02 21:27:51] Generating a summary table
knitr::kable(head(summary), caption = 'Summary over the batch affected gene-sample combination of the example data set')

Table 3: Summary over the batch affected gene-sample combination of the example data set
gene batch median pvalue
ADAM28 b136 0.2539018 0.0003223
AKAP7 b136 0.2236255 0.0000298
ANKRD44 b136 0.2578482 0.0024103
APCDD1 b136 0.2078392 0.0000016
AREG b136 0.3659073 0.0001033
BCL2L14 b136 0.2356189 0.0058860

4.3 Scoring

Furthermore you can calculate a batch score for a whole batch to determine the severeness how it is affected.

score <- calcScore(ex.data, ex.samples, summary, dir = getwd())
#> INFO [2019-05-02 21:27:51] Calculating the scores for 10 batches
knitr::kable(score, caption = 'Batch scores of the example data-set')

Table 4: Batch scores of the example data-set
batch 0.05 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 BEscore
b109 0 0 0 0 0 0 0 0 0 0 0.000
b117 0 0 0 0 0 0 0 0 0 0 0.000
b120 0 0 0 0 0 0 0 0 0 0 0.000
b124 0 0 0 0 0 0 0 0 0 0 0.000
b136 10 2 31 7 1 0 0 0 0 0 0.752
b142 0 0 0 0 0 0 0 0 0 0 0.000
b155 0 0 0 0 0 0 0 0 0 0 0.000
b72 0 0 0 0 0 0 0 0 0 0 0.000
b185 0 0 0 0 0 0 0 0 0 0 0.000
b61 0 0 0 0 0 0 0 0 0 0 0.000

5 Imputation of missing values

For the imputation of missing values we use a slightly modified version of the stochastic gradient descent method described by Koren, Bell, and Volinsky (2009). In this section we will describe our implementation of this method and how to use it.

We assume that our complete data matrix \(D_{ij}\) can be described by the effects of a matrix \(L_i\), which represents the effect of the features (genes in our case) and a matrix \(R_j\) describing the effect of the samples in the following way:

\[\begin{equation} D_{ij} = L_{i}^{T} \times R_{j} \tag{1} \end{equation}\]

The method can either be run on the complete data set or the data set can be divided into blocks on which the method is applied. This division into blocks allows for parallelisation of the method, which can be useful to speed up the process. We have found that a block-size of 60x60 works well(Akulenko, Merl, and Helms 2016).

\[\begin{equation} errorMatrix_{ij} = Block_{ij} - L_{i}^{T} \times R_{j} \tag{2} \end{equation}\]

We try to minimalise the following loss function through a gradient descent:

\[\begin{equation} min_{L, R} \sum_{ij \in K}(errorMatrix_{ij}^2) + \lambda \times (\left\lVert L_{i}\right\rVert_{F}^{2} + \left\lVert R_{j}\right\rVert_{F}^{2} ) \tag{3} \end{equation}\]

Where \(K\) is the set of tuples \((i,j)\) for which the value is present. \(\lambda\) is the penalty coefficient, which controls how restrictive the selection of variables should be. The default of \(\lambda\) is 1.

Another coefficient \(\gamma\) controls the size of the step by which the two matrices \(L_i\) and \(R_j\) are modified. It is initialized by default with 0.01 and its value changes during the iterations (epochs).

For the first iteration the matrices \(L_i\) and \(R_j\) are filled with random values generated by the rnorm function from the stats package and the initial loss and error matrix are calculated.

Then for each iteration the following is done:

  • \(L_i\) and \(R_j\) are modified proportional by \(\gamma\) through the following calculation:

    • \[\begin{equation} L_i = L_i + 2 \times \gamma \times (errorMatrix_{ij} \times R_j - \lambda \times L_i) \tag{4} \end{equation}\]
    • \[\begin{equation} R_j = R_j + 2 \times \gamma \times (errorMatrix_{ij} \times L_i - \lambda \times R_j) \tag{5} \end{equation}\]
  • Then the new error matrix and loss are calculated.
  • If the old loss is smaller than the new one:
    • \(\gamma = \gamma \div 2\)
  • Else:
    • \(\gamma = \gamma \times 1.05\)

The \(L_i\) and \(R_j\) matrices at the end of the last iteration are then used to impute the missing data. The default number of iterations is 50.

5.1 Usage

First you have to set the found batch effect values to NAs. You can do this by using the clearBEgenes function:

cleared.data <- clearBEgenes(ex.data, ex.samples, summary)
#> INFO [2019-05-02 21:27:51] Removing values with batch effect:
#> INFO [2019-05-02 21:27:51] 510 values ( 5.1 % of the data) set to NA

In case you’re using BEclear not for correcting batch effects, but just for the data imputation, you would have to set the values you want to impute to NA, if they not already are.

For the data imputation you use the imputeMissingData function:

corrected.data <- imputeMissingData(cleared.data,
  rowBlockSize = 60,
  colBlockSize = 60, epochs = 50,
  outputFormat = "", dir = getwd()
)
#> INFO [2019-05-02 21:27:51] Starting the imputation of missing values.
#> INFO [2019-05-02 21:27:51] This might take a while.
#> INFO [2019-05-02 21:27:51] BEclear imputation is started:
#> INFO [2019-05-02 21:27:51] block size: 60  x  60
#> INFO [2019-05-02 21:27:51] Impute missing data for block 1 of 4
#> INFO [2019-05-02 21:27:51] Impute missing data for block 2 of 4
#> INFO [2019-05-02 21:27:51] Impute missing data for block 3 of 4
#> INFO [2019-05-02 21:27:51] Impute missing data for block 4 of 4

If you set rowBlockSize and colBlockSize to 0 the matrix won’t be divided into block and the gradient descent will be applied to the matrix as a whole.

5.2 Replacing values outside the boundaries

Note that sometimes during the prediction, it can happen that values beyond the boundaries of beta values are returned, that means values smaller than zero or greater than one. findWrongValues simply returns a list of these values, together with the position in the output matrix, replaceOutsideValues corrects these by simply setting the wrong values to zero or one, respectively. Note that these methods are especially designed for the prediction of beta values from DNA methylation data, which only take on values between 0 and 1.

corrected.data.valid<-replaceOutsideValues(corrected.data)
#> INFO [2019-05-02 21:27:51] Replacing values below 0 or above 1:
#> INFO [2019-05-02 21:27:51] 0 values replaced

In this case there were no values to be replaced.

6 Overall correction

Besides the individual methods BEclear also offers an overall method, which executes all the described previous steps in one call. It also applies some preprocessing to your data set if necessary.

result <- correctBatchEffect(data = ex.data, samples = ex.samples)
#> INFO [2019-05-02 21:27:51] Transforming matrix to data.table
#> INFO [2019-05-02 21:27:51] Calculate the batch effects for 10 batches
#> INFO [2019-05-02 21:27:52] Adjusting p-values
#> INFO [2019-05-02 21:27:52] Generating a summary table
#> INFO [2019-05-02 21:27:52] Calculating the scores for 10 batches
#> INFO [2019-05-02 21:27:52] Removing values with batch effect:
#> INFO [2019-05-02 21:27:52] 510 values ( 5.1 % of the data) set to NA
#> INFO [2019-05-02 21:27:52] Starting the imputation of missing values.
#> INFO [2019-05-02 21:27:52] This might take a while.
#> INFO [2019-05-02 21:27:52] BEclear imputation is started:
#> INFO [2019-05-02 21:27:52] block size: 60  x  60
#> INFO [2019-05-02 21:27:52] Impute missing data for block 1 of 4
#> INFO [2019-05-02 21:27:53] Impute missing data for block 2 of 4
#> INFO [2019-05-02 21:27:53] Impute missing data for block 3 of 4
#> INFO [2019-05-02 21:27:53] Impute missing data for block 4 of 4
#> INFO [2019-05-02 21:27:53] Replacing values below 0 or above 1:
#> INFO [2019-05-02 21:27:53] 0 values replaced

Returned is a list containing all results from the executed functions.

7 Parallelization

For parallelization we use the BiocParellel package. However by default all methods are executed in serial mode. The methods CalcBatchEffect, imputeMissingData and correctBatchEffect support parallelization through there parameter BPPARAM, which takes a BiocParallel::BiocParallelParam class as an argument.

Type the following to get an overview over the supported evaluation environments:

?BiocParallel::BiocParallelParam

8 Plotting

Additionally BEclear also includes a method for plotting the batch effects. Let us now use the makeBoxplot to compare the distributions of the values in the different samples before and after the batch effect correction:

makeBoxplot(ex.data, ex.samples, score,
  bySamples = TRUE,
  col = "standard", main = "Example data", xlab = "Batch",
  ylab = "Beta value", scoreCol = TRUE)
Distribution of the example beta values grouped by sample

Figure 1: Distribution of the example beta values grouped by sample

makeBoxplot(corrected.data, ex.samples, score,
  bySamples = TRUE,
  col = "standard", main = "Corrected example data",
  xlab = "Batch", ylab = "Beta value", scoreCol = FALSE)
Distribution of the corrected beta values grouped by sample

Figure 2: Distribution of the corrected beta values grouped by sample

Session info

Here is the output of sessionInfo() on the system on which this document was compiled running pandoc 2.1:

R version 3.6.0 (2019-04-26)

Platform: x86_64-pc-linux-gnu (64-bit)

locale: LC_CTYPE=en_US.UTF-8, LC_NUMERIC=C, LC_TIME=en_US.UTF-8, LC_COLLATE=C, LC_MONETARY=en_US.UTF-8, LC_MESSAGES=en_US.UTF-8, LC_PAPER=en_US.UTF-8, LC_NAME=C, LC_ADDRESS=C, LC_TELEPHONE=C, LC_MEASUREMENT=en_US.UTF-8 and LC_IDENTIFICATION=C

attached base packages: stats, graphics, grDevices, utils, datasets, methods and base

other attached packages: BEclear(v.2.0.0), BiocParallel(v.1.18.0), pander(v.0.6.3) and BiocStyle(v.2.12.0)

loaded via a namespace (and not attached): Rcpp(v.1.0.1), knitr(v.1.22), magrittr(v.1.5), lattice(v.0.20-38), bibtex(v.0.4.2), highr(v.0.8), stringr(v.1.4.0), tools(v.3.6.0), parallel(v.3.6.0), grid(v.3.6.0), data.table(v.1.12.2), xfun(v.0.6), lambda.r(v.1.2.3), futile.logger(v.1.4.3), htmltools(v.0.3.6), yaml(v.2.2.0), digest(v.0.6.18), bookdown(v.0.9), Matrix(v.1.2-17), formatR(v.1.6), BiocManager(v.1.30.4), codetools(v.0.2-16), Rdpack(v.0.11-0), futile.options(v.1.0.1), gbRd(v.0.4-11), evaluate(v.0.13), rmarkdown(v.1.12), stringi(v.1.4.3) and compiler(v.3.6.0)

References

Akulenko, Ruslan, Markus Merl, and Volkhard Helms. 2016. “BEclear: Batch effect detection and adjustment in DNA methylation data.” PLoS ONE 11 (8):1–17. https://doi.org/10.1371/journal.pone.0159921.

Benjamini, Yoav, and Yosef Hochberg. 1995. “Controlling the False Discovery Rate: A Practical and Powerful Approach to Multiple Testing.” Journal of the Royal Statistical Society. Series B (Methodological) 57 (1). [Royal Statistical Society, Wiley]:289–300. http://www.jstor.org/stable/2346101.

Cancer Genome Atlas Research Network, John N Weinstein, Eric A Collisson, Gordon B Mills, Kenna R Mills Shaw, Brad A Ozenberger, Kyle Ellrott, Ilya Shmulevich, Chris Sander, and Joshua M Stuart. 2013. “The Cancer Genome Atlas Pan-Cancer analysis project.” Nature Genetics 45 (10):1113–20. https://doi.org/10.1038/ng.2764.

Candès, Emmanuel J., and Benjamin Recht. 2009. “Exact Matrix Completion via Convex Optimization.” Foundations of Computational Mathematics 9 (6):717–72. https://doi.org/10.1007/s10208-009-9045-5.

Koren, Yehuda, Robert Bell, and Chris Volinsky. 2009. “Matrix Factorization Techniques for Recommender Systems.” Computer 42 (8):30–37. https://doi.org/10.1109/MC.2009.263.