--- title: "mitch Workflow" author: "Antony Kaspi & Mark Ziemann" date: "`r Sys.Date()`" output: rmarkdown::html_vignette: toc: true vignette: > %\VignetteIndexEntry{mitch Workflow} %\VignetteEngine{knitr::rmarkdown} \usepackage[utf8]{inputenc} --- ## Background mitch is an R package for multi-contrast enrichment analysis. At it’s heart, it uses a rank-MANOVA based statistical approach to detect sets of genes that exhibit enrichment in the multidimensional space as compared to the background. The rank-MANOVA concept dates to work by Cox and Mann (https://doi.org/10.1186/1471-2105-13-S16-S12). mitch is useful for pathway analysis of profiling studies with one, two or more contrasts, or in studies with multiple omics profiling, for example proteomic, transcriptomic, epigenomic analysis of the same samples. mitch is perfectly suited for pathway level differential analysis of scRNA-seq data. The main strengths of mitch are that it can import datasets easily from many upstream tools and has advanced plotting features to visualise these enrichments. mitch consists of five functions. A typical mitch workflow would consist of: * 1: Import gene sets with `gmt_import()` * 2: Import profiling data with `mitch_import()` * 3: Calculate enrichments with `mitch_calc()` * 4: And generate plots and reports with `mitch_plots()` and `mitch_report()` ```{r, install, eval = FALSE} if(!requireNamespace("BiocManager", quietly = TRUE)) install.packages("BiocManager") BiocManager::install("mitch") ``` ```{r, lib} library("mitch") ``` ## Importing gene sets mitch has a function to import GMT files to R lists (adapted from Yu et al, 2012 in the [clusterProfiler](https://bioconductor.org/packages/release/bioc/html/clusterProfiler.html) package). For example we can grab some gene sets from Reactome.org: ```{r,gsets} download.file("https://reactome.org/download/current/ReactomePathways.gmt.zip", destfile="ReactomePathways.gmt.zip") unzip("ReactomePathways.gmt.zip") genesets<-gmt_import("ReactomePathways.gmt") ``` In this cut down example we will be using a sample of 200 Reactome gene sets: ```{r,genesetsExample} data(genesetsExample) head(genesetsExample,3) ``` ## Importing profiling data mitch accepts pre-ranked data supplied by the user, but also has a function called `mitch_import` for importing tables generated by limma, edgeR, DESeq2, ABSSeq, Sleuth, Seurat, Muscat and several other upstream tools. By default, only the genes that are detected in all contrasts are included, but this behaviour can be modified for sparse data setting `joinType=full`. The below example imports two edgeR tables called "rna" and "k9a" Where gene identifiers are present as row names. Note that if there is more than one profile being imported, they need to be part of a list. ```{r,import11} data(rna,k9a) x<-list("rna"=rna,"k9a"=k9a) y<-mitch_import(x,"edgeR") head(y) ``` mitch can do unidimensional analysis if you provide it a single profile as a dataframe (not in a list). ```{r,import4} y<-mitch_import(rna,DEtype="edger") head(y) ``` If the gene identifiers are not given in the rownames, then the column can be specified with the `geneIDcol` parameter like this: ```{r,import5} # first rearrange cols rna_mod<-rna rna_mod$MyGeneIDs<-rownames(rna_mod) rownames(rna_mod)<-seq(nrow(rna_mod)) head(rna_mod) # now import with geneIDcol y<-mitch_import(rna_mod,DEtype="edgeR",geneIDcol="MyGeneIDs") head(y) ``` By default, differential gene activity is scored using a supplied test statistic or directional p-value (D): D = sgn(logFC) * -log10(p-value) If this is not desired, then users can perform their own custom scoring procedure and import with `DEtype="prescored"`. There are many cases where the gene IDs don't match the gene sets. To overcome this, `mitch_import` also accepts a two-column table (gt here) that relates gene identifiers in the profiling data to those in the gene sets. In this example we can create some fake gene accession numbers to demonstrate this feature. ```{r,import6} library("stringi") # obtain vector of gene names genenames<-rownames(rna) # create fake accession numbers accessions<-paste("Gene0",stri_rand_strings(nrow(rna)*2, 6, pattern = "[0-9]"),sep="") accessions<-head(unique(accessions),nrow(rna)) # create a gene table file that relates gene names to accession numbers gt<-data.frame(genenames,accessions) # now swap gene names for accessions rna2<-merge(rna,gt,by.x=0,by.y="genenames") rownames(rna2)<-rna2$accessions rna2<-rna2[,2:5] k9a2<-merge(k9a,gt,by.x=0,by.y="genenames") rownames(k9a2)<-k9a2$accessions k9a2<-k9a2[,2:5] # now have a peek at the input data before importing head(rna2,3) head(k9a2,3) head(gt,3) x<-list("rna2"=rna2,"k9a2"=k9a2) y<-mitch_import(x,DEtype="edgeR",geneTable=gt) head(y,3) ``` `?mitch_import` provides more instructions on using this feature. ## Calculating enrichment The `mitch_calc` function performs multivariate enrichment analysis of the supplied gene sets in the scored profiling data. At its simpest form `mitch_calc` function accepts the scored data as the first argument and the genesets as the second argument. Users can prioritise enrichments based on small adjusted p-values, by the observed effect size (magnitude of "s", the enrichment score) or the standard deviation of the s scores. Note that the number of parallel cores is set here to cores=2 but the default is to use all but one available cores. ```{r,calc1,results="hide"} # prioritisation by significance res<-mitch_calc(y,genesetsExample,priority="significance",cores=2) ``` ```{r,calc2} # peek at the results head(res$enrichment_result) ``` ```{r,calc3,results="hide"} # prioritisation by effect size res<-mitch_calc(y,genesetsExample,priority="effect",cores=2) ``` ```{r,calc4} head(res$enrichment_result) ``` By default, gene sets with fewer than 10 members present in the profiling data are discarded. This threshold can be modified using the minsetsize option. There is no upper limit of gene set size. ```{r,calc5,results="hide"} res<-mitch_calc(y,genesetsExample,priority="significance",minsetsize=5,cores=2) ``` By default, in downstream visualisation steps, charts are made from the top 50 gene sets, but this can be modified using the resrows option. ```{r,calc6,results="hide"} res<-mitch_calc(y,genesetsExample,priority="significance",resrows=3,cores=2) ``` ## Generate a HTML report The HTML reports contain several plots as raster images and interactive charts which are useful as a first-pass visualisation. These can be generated like this: ```{r,report,results="hide"} mitch_report(res,"myreport.html",overwrite=TRUE) ``` ## Generate high resolution plots In case you want the charts in PDF format, for example for publications, these can be generated as such: ```{r,plots,results="hide"} mitch_plots(res,outfile="mycharts.pdf") ``` ## Session Info ```{r,sessioninfo,message=FALSE} sessionInfo() ```