1. Introduction

EpiMix is a comprehensive tool for the integrative analysis of DNA methylation data and gene expression data (Figure 1). EpiMix enables automated data downloading (from TCGA or GEO), pre-processing, methylation modeling, interactive visualization and functional annotation. To identify hypo- or hypermethylated genes, EpiMix uses a beta mixture model to identify the methylation states of each CpG site and compares the DNA methylation of an experimental group to a control group. The output from EpiMix is the functional changes in DNA methylation that is associated with gene expression.

EpiMix incorporates specialized algorithms to identify functional DNA methylation at various genetic elements, including proximal cis-regulatory elements within or surrounding protein-coding genes, distal enhancers, and genes encoding microRNAs (miRNAs) or lncRNAs. There are four alternative analytic modes for modeling DNA methylation at different genetic elements:

  • Regular: cis-regulatory elements within or surrounding protein-coding genes.
  • Enhancer: distal enhancers.
  • miRNA: miRNA-coding genes.
  • lncRNA: lncRNA-coding genes.

Figure 1. Overview of EpiMix’s workflow. EpiMix incorporates four functional modules: downloading, preprocessing, methylation modeling and functional analysis. The methylation modeling module enables four alternative analytic modes, including “Regular”, “Enhancer”, “miRNA” and “lncRNA”. These analytic modes target DNA methylation analysis on different genetic elements.

2. Installation

2.1 Bioconductor

if (!require("BiocManager", quietly = TRUE))
    install.packages("BiocManager")

BiocManager::install(version='devel')

BiocManager::install("EpiMix")

2.2 Github

devtools::install_github("gevaertlab/EpiMix.data")
devtools::install_github("gevaertlab/EpiMix")

To load the EpiMix package in your R session, type library(EpiMix)

Help files. Detailed information on each function of the EpiMix package can be obtained in the help files. For example, to view the help file for the function EpiMix, use ?EpiMix.


3. Data input

The EpiMix function requires three data matricies as input:

  • DNA methylation data: a matrix of the DNA methylation data (beta values) with CpG sites in rows and samples in columns.
data(MET.data)
TCGA-05-4384-01 TCGA-05-4390-01 TCGA-05-4396-01 TCGA-05-4405-01 TCGA-05-4410-01
cg14029001 0.5137112 0.7590496 0.7344551 0.3842839 0.7792050
cg00374492 0.0819639 0.1277514 0.1730193 0.1037328 0.1079144
cg21462428 0.1397001 0.5207123 0.0738277 0.4853540 0.3803233
cg03987115 0.3346637 0.4516052 0.5916153 0.1713237 0.2410597
cg19351701 0.2816598 0.4035316 0.4949594 0.2380439 0.2139926
  • (Optional) Gene expression data: a matrix of the matched gene expression data with genes in rows and samples in columns. If gene expression data are not provided, no comparision for gene expression will be made beteween the differentially methylated groups. Gene expression data can be normalized values from any methods: TPM, RPKM, FPKM, etc.
data(mRNA.data)
TCGA-05-4244-01 TCGA-05-4249-01 TCGA-05-4250-01 TCGA-05-4382-01 TCGA-05-4384-01
CCND2 8.453134 9.740521 8.732788 10.00435 8.772762
CCND3 10.891247 11.427828 10.853533 10.30242 11.863776
HOXA9 1.481609 2.757258 1.992442 1.93693 2.096296
MANBAL 10.548016 10.548264 10.558500 10.18544 10.080922
SRC 11.182247 11.940123 11.198035 11.54182 10.154679
  • Sample annotation: a dataframe that maps each sample in the DNA methylation data to a study group. Should contain two columns: the first column (named “primary”) indicating the sample names, and the second column (named “sample.type”) indicating which study group each sample belongs to (e.g.,“Cancer” vs. “Normal”, “Experiment” vs. “Control”).
data(LUAD.sample.annotation)
primary sample.type
TCGA-05-4384-01 Cancer
TCGA-05-4390-01 Cancer
TCGA-05-4396-01 Cancer
TCGA-05-4405-01 Cancer
TCGA-50-6592-11 Normal
TCGA-50-6593-11 Normal
TCGA-50-6594-11 Normal
TCGA-73-4658-11 Normal
TCGA-73-4676-11 Normal


4. Methylation modeling


4.1 Regular mode

# Specify the output directory
outputDirectory = tempdir()

# We compare the DNA methylation in cancer (group.1) to the normal (group.2) tissues
EpiMixResults_Regular <- EpiMix(methylation.data = MET.data,
                                 gene.expression.data = mRNA.data,
                                 sample.info = LUAD.sample.annotation,
                                 group.1 = "Cancer",
                                 group.2 = "Normal",
                                 met.platform = "HM450",
                                 OutputRoot =  outputDirectory)

One of the major outputs of EpiMix is a $FunctionalPairs matrix, indicating the differentially methylated CpG sites that are signficantly associated with gene expression:

datatable(EpiMixResults_Regular$FunctionalPairs[1:5, ],
          options = list(scrollX = TRUE, 
                         autoWidth = TRUE,
                         keys = TRUE, 
                         pageLength = 5, 
                         rownames= FALSE,
                         digits = 3), 
                         rownames = FALSE)

4.2 Enhancer mode

The Enhancer mode targets DNA methylation analysis on distal enhancers of protein-coding genes.

# First, we need to set the analytic mode to enhancer
mode <- "Enhancer"

# Since enhancers are cell or tissue-type specific, EpiMix needs 
# to know the reference cell type or tissue to select proper enhancers.
# Available ids for tissue or cell types can be 
# obtained from Figure 2 of the RoadmapEpigenomic
# paper: https://www.nature.com/articles/nature14248. 
# Alternatively, they can also be retrieved from the 
# built-in function `list.epigenomes()`.

roadmap.epigenome.ids = "E096"   

# Specify the output directory
outputDirectory = tempdir()

# Third, run EpiMix
EpiMixResults_Enhancer <- EpiMix(methylation.data = MET.data, 
                                gene.expression.data = mRNA.data,
                                mode = mode,
                                roadmap.epigenome.ids = roadmap.epigenome.ids,
                                sample.info = LUAD.sample.annotation,
                                group.1 = "Cancer",
                                group.2 = "Normal",
                                met.platform = "HM450",
                                OutputRoot =  outputDirectory)
datatable(EpiMixResults_Enhancer$FunctionalPairs[1:5, ],
          options = list(scrollX = TRUE, 
                         autoWidth = TRUE,
                         keys = TRUE, 
                         pageLength = 5, 
                         rownames= FALSE,
                         digits = 3), 
                         rownames = FALSE)

4.3 miRNA mode

The miRNA mode targets DNA methylation analysis on miRNA-coding genes.

# Note that running the methylation analysis for miRNA genes need gene expression data for miRNAs
data(microRNA.data)

mode <- "miRNA"

# Specify the output directory
outputDirectory = tempdir()

EpiMixResults_miRNA <- EpiMix(methylation.data = MET.data, 
                        gene.expression.data = microRNA.data,
                        mode = mode,
                        sample.info = LUAD.sample.annotation,
                        group.1 = "Cancer",
                        group.2 = "Normal",
                        met.platform = "HM450",
                        OutputRoot = outputDirectory)
# View the EpiMix results
datatable(EpiMixResults_miRNA$FunctionalPairs[1:5, ],
          options = list(scrollX = TRUE, 
                         autoWidth = TRUE,
                         keys = TRUE, 
                         pageLength = 5, 
                         rownames= FALSE,
                         digits = 3), 
                         rownames = FALSE)

4.4 lncRNA mode

The lncRNA mode targets DNA methylation analysis on lncRNA-coding genes.

# Note: standard RNA-seq processing method can not detect sufficient amount of lncRNAs. 
# To maximize the capture of lncRNA expression, please use the pipeline propoased 
# in our previous study: PMID: 31808800

data(lncRNA.data)

mode <- "lncRNA"

# Specify the output directory
outputDirectory =  tempdir()

EpiMixResults_lncRNA <- EpiMix(methylation.data = MET.data, 
                        gene.expression.data = lncRNA.data,
                        mode = mode,
                        sample.info = LUAD.sample.annotation,
                        group.1 = "Cancer",
                        group.2 = "Normal",
                        met.platform = "HM450",
                        OutputRoot = outputDirectory)
datatable(EpiMixResults_lncRNA$FunctionalPairs[1:5, ],
          options = list(scrollX = TRUE, 
                         autoWidth = TRUE,
                         keys = TRUE,
                         pageLength = 5, 
                         rownames= FALSE,
                         digits = 3), 
                         rownames = FALSE)


5. One-step functions for TCGA data

EpiMix enables automated DNA methylation analysis for cancer data from the TCGA project with a single-function TCGA_GetData. This function wraps the functions for (1) data downloading, (2) pre-processing and (3) DNA methylation analysis. By default, EpiMix compares the DNA methylation in tumors to normal tissues.

# Set up the TCGA cancer site. "OV" stands for ovarian cancer.  
CancerSite <- "OV"     

# Specify the analytic mode.
mode <- "Regular"

# Set the file path for saving the output.
outputDirectory <- tempdir()

# Only required if mode == "Enhancer".
roadmap.epigenome.ids = "E097"  

# Run EpiMix

# We highly encourage to use multiple (>=10) CPU cores to 
# speed up the computational process for large datasets

EpiMixResults <- TCGA_GetData(CancerSite = CancerSite, 
                              mode = mode, 
                              roadmap.epigenome.ids = roadmap.epigenome.ids, 
                              outputDirectory = outputDirectory,
                              cores = 10)


6. Step-by-step functions for TCGA data

The above one-step functions in Section can be executed in a step-by-step manner in case users want to inspect the output from each individual step.

6.1 Download and preprocess DNA methylation data from TCGA

  • Download DNA methylation data
METdirectories <- TCGA_Download_DNAmethylation(CancerSite = "OV", 
                                               TargetDirectory = outputDirectory)
cat("HM27k directory:", METdirectories$METdirectory27k, "\n")
#> HM27k directory: /tmp/Rtmp2wFUXz/gdac_20160128/gdac.broadinstitute.org_OV.Merge_methylation__humanmethylation27__jhu_usc_edu__Level_3__within_bioassay_data_set_function__data.Level_3.2016012800.0.0/
cat("HM450k directory:", METdirectories$METdirectory450k, "\n")
#> HM450k directory: /tmp/Rtmp2wFUXz/gdac_20160128/gdac.broadinstitute.org_OV.Merge_methylation__humanmethylation450__jhu_usc_edu__Level_3__within_bioassay_data_set_function__data.Level_3.2016012800.0.0/
  • Preprocess DNA methylation data

Preprocessing includes eliminating samples and genes with too many missing values (default: 20%), imputing remaining missing values, removing single-nucleotide polymorphism (SNP) probes.

METProcessedData <- TCGA_Preprocess_DNAmethylation(CancerSite = "OV", METdirectories)

The pre-processed DNA methylation data is a matrix with CpG probes in rows and patient in columns. The values in the matrix represent beta values of DNA methylation:

knitr::kable(METProcessedData[1:5,1:5])
TCGA-04-1331-01 TCGA-04-1332-01 TCGA-04-1335-01 TCGA-04-1336-01 TCGA-04-1337-01
cg00000292 0.9221302 0.4648186 0.9042943 0.7567368 0.8791313
cg00002426 0.1486593 0.0562675 0.2632028 0.2009483 0.0726626
cg00003994 0.0293567 0.0344792 0.0552332 0.0840847 0.0209836
cg00005847 0.8248150 0.4201426 0.6690116 0.7688814 0.7630715
cg00007981 0.0177981 0.0122320 0.0410097 0.0276765 0.0110274

Optional. Since TCGA data were collected in technical batches, systematic differences may exist between technical batches. Users can optionally correct the batch effect using thedoBatchCorrection parameter. EpiMix provides two alternative methods for batch effect correction: Seurat and Combat. The Seurat method (PMID: 31178118) is much more time efficient compared to the Combat (PMID: 16632515). If using the Combat method, users are encouraged to use multiple CPU cores by tuning the cores parameter.


6.2 Download and preprocess gene expression data

# If use the Regular or the Enhancer mode: 
GEdirectories <- TCGA_Download_GeneExpression(CancerSite = "OV", 
                                              TargetDirectory = outputDirectory)
                                              

# If use the miRNA mode, download miRNA expression data:
mode <- "miRNA"
GEdirectories <- TCGA_Download_GeneExpression(CancerSite = "OV", 
                                              TargetDirectory = outputDirectory, 
                                              mode = mode)

# If use the lncRNA mode, download lncRNA expression data:
mode <- "lncRNA"
GEdirectories <- TCGA_Download_GeneExpression(CancerSite = "OV", 
                                              TargetDirectory = outputDirectory, 
                                              mode = mode)
  • Preprocess gene expression data
GEProcessedData <- TCGA_Preprocess_GeneExpression(CancerSite = "OV", 
                                                  MAdirectories = GEdirectories, 
                                                  mode = mode
                                                  )

The pre-processed gene expression data is a matrix with gene in rows and patients in columns.

Example of gene expression data:

TCGA-04-1331-01 TCGA-04-1332-01 TCGA-04-1335-01 TCGA-04-1336-01 TCGA-04-1337-01
ELMO2 -0.6204167 0.184750 -0.6716667 -1.105500 0.7858333
CREB3L1 -0.0032500 1.008500 1.2210000 -0.623000 1.1265000
RPS11 0.5672500 0.967625 -0.2337500 0.555375 0.6608750
PNMA1 1.2940000 1.159000 -0.8425000 0.476750 0.6160000
MMP2 -0.3280000 0.416500 -1.1091667 -1.716333 0.9626667
  • Generate the sample annotation

To identify the hypo- or hyper-methylated genes, EpiMix compares the DNA methylation in tumors to normal tissues. Therefore, EpiMix needs to know which samples in the DNA methylation and gene expression data are tumors (group.1), and which are normal tissues (group.2). The TCGA_GetSampleInfo function can be used to generate a dataframe of sample information.

sample.info = TCGA_GetSampleInfo(METProcessedData = METProcessedData,
                                 CancerSite = "OV", 
                                 TargetDirectory = outputDirectory)

The sample.info is a dataframe with two columns: the primary column indicates the sample identifiers and the sample.type column indicates which group each sample belongs to:

knitr::kable(sample.info[1:4,])
primary sample.type
TCGA-04-1331-01 Cancer
TCGA-04-1332-01 Cancer
TCGA-04-1335-01 Cancer
TCGA-04-1336-01 Cancer


7. Visualization

EpiMix enables diverse types of visualization.

7.1 Mixture model and gene expression

data(Sample_EpiMixResults_Regular)

plots <- EpiMix_PlotModel(
                 EpiMixResults = Sample_EpiMixResults_Regular, 
                 Probe = "cg14029001", 
                 methylation.data = MET.data, 
                 gene.expression.data = mRNA.data,
                 GeneName = "CCND3"
                 )
# Mixture model of the DNA methylation of the CCND3 gene at cg14029001
plots$MixtureModelPlot

# Violin plot of the gene expression levels of the CCND3 gene in different mixtures
plots$ViolinPlot

# Correlation between DNA methylation and gene expression of CCND3
plots$CorrelationPlot


7.2 Genome-browser style visualization

7.2.1 Integrative visualization of the chromatin state, DNA methylation, and transcript structure of a specific gene

library(karyoploteR)
library(TxDb.Hsapiens.UCSC.hg19.knownGene)
library(org.Hs.eg.db)
library(regioneR)

data(Sample_EpiMixResults_Regular)

gene.name = "CCND2"
met.platform = "HM450"

# Since the chromatin states are cell-type specific, we need to specify a reference cell or 
# tissue type for plotting. Available cell or tissue type can be found in
# Figure 2 of the Roadmap Epigenomics paper (nature, PMID: 25693563): 
# https://www.nature.com/articles/nature14248 

roadmap.epigenome.id = "E096"
  
EpiMix_PlotGene(gene.name = gene.name,
                EpiMixResults = Sample_EpiMixResults_Regular, 
                met.platform = met.platform,
                roadmap.epigenome.id = roadmap.epigenome.id
               )
Integrative visualization of the chromatin state, DM values and the transcript structure of the CCND2 gene. The differential methylation (DM) value represents the mean difference in beta values between the hypermethylated samples versus the normally methylated samples.
Integrative visualization of the chromatin state, DM values and the transcript structure of the CCND2 gene. The differential methylation (DM) value represents the mean difference in beta values between the hypermethylated samples versus the normally methylated samples.


7.2.2 Plot the chromatin state of a CpG site and the expression of its nearby genes

This plot is used for visualization of a differentially methylated enhancer. The genes shown in red are the genes whose transcription was negatively associated with the DNA methylation of an enhancer.

# The CpG site to plot
probe.name = "cg00374492"

# The number of adjacent genes to be plotted
# Warnings: setting the gene number to a high value (>20 genes) may blow the internal memory
numFlankingGenes = 10

# Set up the reference cell/tissue type
roadmap.epigenome.id = "E096"

# Generate the plot
EpiMix_PlotProbe(probe.name, 
                 EpiMixResults = Sample_EpiMixResults_Regular, 
                 met.platform = "HM450", 
                 numFlankingGenes = numFlankingGenes, 
                 roadmap.epigenome.id = roadmap.epigenome.id,
                 left.gene.margin = 10000,  # left graph margin in nucleotide base pairs
                 right.gene.margin = 10000  # right graph margin in nucleotide base pairs
                 )

Integrative visualization of the chromatin state and the nearby genes of a differentially methylated CpG site.

8. Pathway enrichment analysis

EpiMix integrates the clusterProfiler R package to perform the function enrichment analysis of the differentially methylated genes. Enrichment results can be visualized in both tabular format and in graphic format. See this paper for more details.

8.1 Gene ontology (GO) analysis

library(clusterProfiler)
library(org.Hs.eg.db)

# We want to check the functions of both the hypo- and hypermethylated genes. 
methylation.state = "all"

# Use the gene ontology for functional analysis.
enrich.method = "GO"

# Use the "biological process" subterm
selected.pathways = "BP"

# Perform enrichment analysis 
enrich.results <- functionEnrich(EpiMixResults = Sample_EpiMixResults_Regular,
                                  methylation.state = methylation.state,
                                  enrich.method = enrich.method,
                                  ont = selected.pathways,
                                  simplify = TRUE,
                                  save.dir = "" 
                                  )
knitr::kable(head(enrich.results), row.names = FALSE)
ID Description GeneRatio BgRatio RichFactor FoldEnrichment zScore pvalue p.adjust qvalue geneID Count
GO:0045737 positive regulation of cyclin-dependent protein serine/threonine kinase activity 2/5 34/18986 0.0588235 223.36471 21.06243 0.0000310 0.0020550 0.0004766 CCND2/CCND3 2
GO:1904031 positive regulation of cyclin-dependent protein kinase activity 2/5 36/18986 0.0555556 210.95556 20.46467 0.0000348 0.0020550 0.0004766 CCND2/CCND3 2
GO:1900087 positive regulation of G1/S transition of mitotic cell cycle 2/5 56/18986 0.0357143 135.61429 16.37347 0.0000850 0.0033419 0.0007751 CCND2/CCND3 2
GO:1902808 positive regulation of cell cycle G1/S phase transition 2/5 71/18986 0.0281690 106.96338 14.51819 0.0001369 0.0040381 0.0009366 CCND2/CCND3 2
GO:0048704 embryonic skeletal system morphogenesis 2/5 95/18986 0.0210526 79.94105 12.51895 0.0002453 0.0041355 0.0009592 HOXA9/HOXB7 2
GO:0048706 embryonic skeletal system development 2/5 134/18986 0.0149254 56.67463 10.49692 0.0004876 0.0053820 0.0012483 HOXA9/HOXB7 2

8.2 KEGG pathway enrichment analysis

enrich.results <- functionEnrich(EpiMixResults = Sample_EpiMixResults_Regular,
                                  methylation.state = "all",
                                  enrich.method = "KEGG",
                                  simplify = TRUE,
                                  save.dir = "")
knitr::kable(head(enrich.results), row.names = FALSE)
category subcategory ID Description GeneRatio BgRatio RichFactor FoldEnrichment zScore pvalue p.adjust qvalue geneID Count
Cellular Processes Cell growth and death hsa04115 p53 signaling pathway 2/3 75/8850 0.0266667 78.66667 12.438026 0.0002114 0.0028682 0.0004529 894/896 2
Human Diseases Infectious disease: viral hsa05162 Measles 2/3 139/8850 0.0143885 42.44604 9.069142 0.0007272 0.0028682 0.0004529 894/896 2
Cellular Processes Cell growth and death hsa04218 Cellular senescence 2/3 157/8850 0.0127389 37.57962 8.515573 0.0009273 0.0028682 0.0004529 894/896 2
Environmental Information Processing Signal transduction hsa04390 Hippo signaling pathway 2/3 157/8850 0.0127389 37.57962 8.515573 0.0009273 0.0028682 0.0004529 894/896 2
Cellular Processes Cell growth and death hsa04110 Cell cycle 2/3 158/8850 0.0126582 37.34177 8.487592 0.0009391 0.0028682 0.0004529 894/896 2
Environmental Information Processing Signal transduction hsa04630 JAK-STAT signaling pathway 2/3 168/8850 0.0119048 35.11905 8.221506 0.0010613 0.0028682 0.0004529 894/896 2


9. Biomarker identification

After the differentially methylated genes were identified, we look for the genes whose methylation states are associated with patient survival. For each differentially methylated CpG, we compare the survival of the abnormally methylated patients to the normally methylated patients. The GetSurvivalProbe function generates all the survival associated CpGs.

library(survival)

# We use a sample result from running the EpiMix's miRNA mode on the 
# lung adenocarcinomas (LUAD) data from TCGA
data("Sample_EpiMixResults_miRNA")

# Set the TCGA cancer site. 
CancerSite = "LUAD"

# Find survival-associated CpGs/genes
survival.CpGs <- GetSurvivalProbe (EpiMixResults = Sample_EpiMixResults_miRNA, TCGA_CancerSite = CancerSite)
                                    
knitr::kable(survival.CpGs, row.names = FALSE)
Probe Genes State HR lower.Cl higher.Cl p.value adjusted.p.value
cg00909706 hsa-mir-34a Hyper 1.8164322924391 1.17176293780833 2.8157796825242 0.0067882646557248 0.0067883

Plot the Kaplan-Meier survival curve for the normally and the abnormally methylated patients.

library(survminer)

# Select the target CpG site whose methylation states will be evaluated
Probe = "cg00909706"

# If using data from TCGA, just input the cancer site 
CancerSite = "LUAD"

EpiMix_PlotSurvival(EpiMixResults = Sample_EpiMixResults_miRNA, 
                                     plot.probe = Probe,
                                     TCGA_CancerSite = CancerSite)
Survival curve for patients showing different methylation states at the CpG cg00909706

Survival curve for patients showing different methylation states at the CpG cg00909706

10. Find potential miRNA targets

Find miRNA targets whose transcription levels are associated with the differential methylation of miRNAs: 1. Hyper-methylation miRNA -> upregulation of targets 2. Hypo-methylation miRNA -> downregulation of targets

library(multiMiR)
library(miRBaseConverter)

miRNA_targets <- find_miRNA_targets(
 EpiMixResults = Sample_EpiMixResults_miRNA,
 geneExprData = mRNA.data
)
datatable(miRNA_targets[1:5, ],
          options = list(scrollX = TRUE, 
                         autoWidth = TRUE,
                         keys = TRUE, 
                         pageLength = 5, 
                         rownames= FALSE,
                         digits = 3), 
                         rownames = FALSE)

Now, the Fold change of gene expression column indicates the change of gene expression for the miRNA targets, where the comparisions were made between patients with different methylation states for the corresponding miRNAs.

11. Session Information

sessionInfo()
#> R Under development (unstable) (2024-10-21 r87258)
#> Platform: x86_64-pc-linux-gnu
#> Running under: Ubuntu 24.04.1 LTS
#> 
#> Matrix products: default
#> BLAS:   /home/biocbuild/bbs-3.21-bioc/R/lib/libRblas.so 
#> LAPACK: /usr/lib/x86_64-linux-gnu/lapack/liblapack.so.3.12.0
#> 
#> locale:
#>  [1] LC_CTYPE=en_US.UTF-8       LC_NUMERIC=C              
#>  [3] LC_TIME=en_GB              LC_COLLATE=C              
#>  [5] LC_MONETARY=en_US.UTF-8    LC_MESSAGES=en_US.UTF-8   
#>  [7] LC_PAPER=en_US.UTF-8       LC_NAME=C                 
#>  [9] LC_ADDRESS=C               LC_TELEPHONE=C            
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#> 
#> time zone: America/New_York
#> tzcode source: system (glibc)
#> 
#> attached base packages:
#> [1] stats4    stats     graphics  grDevices utils     datasets  methods  
#> [8] base     
#> 
#> other attached packages:
#>  [1] miRBaseConverter_1.31.0 multiMiR_1.29.0         survminer_0.4.9        
#>  [4] ggpubr_0.6.0            ggplot2_3.5.1           survival_3.7-0         
#>  [7] org.Hs.eg.db_3.20.0     AnnotationDbi_1.69.0    Biobase_2.67.0         
#> [10] clusterProfiler_4.15.0  GenomicRanges_1.59.0    GenomeInfoDb_1.43.0    
#> [13] IRanges_2.41.0          S4Vectors_0.45.0        sesameData_1.23.0      
#> [16] DT_0.33                 EpiMix_1.9.0            EpiMix.data_1.7.0      
#> [19] ExperimentHub_2.15.0    AnnotationHub_3.15.0    BiocFileCache_2.15.0   
#> [22] dbplyr_2.5.0            BiocGenerics_0.53.0    
#> 
#> loaded via a namespace (and not attached):
#>   [1] splines_4.5.0               BiocIO_1.17.0              
#>   [3] bitops_1.0-9                ggplotify_0.1.2            
#>   [5] filelock_1.0.3              tibble_3.2.1               
#>   [7] R.oo_1.26.0                 XML_3.99-0.17              
#>   [9] lifecycle_1.0.4             httr2_1.0.5                
#>  [11] rstatix_0.7.2               doParallel_1.0.17          
#>  [13] lattice_0.22-6              crosstalk_1.2.1            
#>  [15] backports_1.5.0             magrittr_2.0.3             
#>  [17] limma_3.63.0                sass_0.4.9                 
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#>  [21] yaml_2.3.10                 ggtangle_0.0.3             
#>  [23] cowplot_1.1.3               DBI_1.2.3                  
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#>  [27] zlibbioc_1.53.0             purrr_1.0.2                
#>  [29] R.utils_2.12.3              RCurl_1.98-1.16            
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#>  [33] GenomeInfoDbData_1.2.13     KMsurv_0.1-5               
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#>  [37] tidytree_0.4.6              codetools_0.2-20           
#>  [39] DelayedArray_0.33.0         DOSE_4.1.0                 
#>  [41] xml2_1.3.6                  tidyselect_1.2.1           
#>  [43] aplot_0.2.3                 UCSC.utils_1.3.0           
#>  [45] farver_2.1.2                matrixStats_1.4.1          
#>  [47] GenomicAlignments_1.43.0    jsonlite_1.8.9             
#>  [49] Formula_1.2-5               iterators_1.0.14           
#>  [51] foreach_1.5.2               tools_4.5.0                
#>  [53] progress_1.2.3              treeio_1.31.0              
#>  [55] snow_0.4-4                  Rcpp_1.0.13                
#>  [57] glue_1.8.0                  gridExtra_2.3              
#>  [59] SparseArray_1.7.0           xfun_0.48                  
#>  [61] mgcv_1.9-1                  qvalue_2.39.0              
#>  [63] MatrixGenerics_1.19.0       dplyr_1.1.4                
#>  [65] withr_3.0.2                 BiocManager_1.30.25        
#>  [67] fastmap_1.2.0               fansi_1.0.6                
#>  [69] digest_0.6.37               R6_2.5.1                   
#>  [71] mime_0.12                   gridGraphics_0.5-1         
#>  [73] colorspace_2.1-1            GO.db_3.20.0               
#>  [75] RPMM_1.25                   biomaRt_2.63.0             
#>  [77] RSQLite_2.3.7               R.methodsS3_1.8.2          
#>  [79] utf8_1.2.4                  tidyr_1.3.1                
#>  [81] generics_0.1.3              data.table_1.16.2          
#>  [83] rtracklayer_1.67.0          prettyunits_1.2.0          
#>  [85] httr_1.4.7                  htmlwidgets_1.6.4          
#>  [87] S4Arrays_1.7.0              pkgconfig_2.0.3            
#>  [89] gtable_0.3.6                blob_1.2.4                 
#>  [91] impute_1.81.0               XVector_0.47.0             
#>  [93] survMisc_0.5.6              htmltools_0.5.8.1          
#>  [95] carData_3.0-5               fgsea_1.33.0               
#>  [97] scales_1.3.0                png_0.1-8                  
#>  [99] doSNOW_1.0.20               ggfun_0.1.7                
#> [101] km.ci_0.5-6                 knitr_1.48                 
#> [103] tzdb_0.4.0                  reshape2_1.4.4             
#> [105] rjson_0.2.23                nlme_3.1-166               
#> [107] curl_5.2.3                  zoo_1.8-12                 
#> [109] cachem_1.1.0                stringr_1.5.1              
#> [111] BiocVersion_3.21.1          parallel_4.5.0             
#> [113] restfulr_0.0.15             pillar_1.9.0               
#> [115] grid_4.5.0                  vctrs_0.6.5                
#> [117] car_3.1-3                   xtable_1.8-4               
#> [119] cluster_2.1.6               evaluate_1.0.1             
#> [121] readr_2.1.5                 GenomicFeatures_1.59.0     
#> [123] cli_3.6.3                   compiler_4.5.0             
#> [125] Rsamtools_2.23.0            rlang_1.1.4                
#> [127] crayon_1.5.3                ggsignif_0.6.4             
#> [129] labeling_0.4.3              plyr_1.8.9                 
#> [131] fs_1.6.4                    stringi_1.8.4              
#> [133] BiocParallel_1.41.0         munsell_0.5.1              
#> [135] Biostrings_2.75.0           lazyeval_0.2.2             
#> [137] GOSemSim_2.33.0             Matrix_1.7-1               
#> [139] hms_1.1.3                   patchwork_1.3.0            
#> [141] bit64_4.5.2                 KEGGREST_1.47.0            
#> [143] statmod_1.5.0               SummarizedExperiment_1.37.0
#> [145] highr_0.11                  broom_1.0.7                
#> [147] igraph_2.1.1                memoise_2.0.1              
#> [149] bslib_0.8.0                 ggtree_3.15.0              
#> [151] fastmatch_1.1-4             bit_4.5.0                  
#> [153] ELMER.data_2.29.0           downloader_0.4             
#> [155] gson_0.1.0                  ape_5.8