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Repository for building experimental enhancer locus definitions for chipenrich

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Overview

This repository allows one to repeat much of the analysis that I did in my rotation in the Sartor lab in May/June 2016.

It includes the following:

  • Create new enhancers lists using ENCODE ChromHMM tracks, ENCODE DNase-seq data for 125 cell lines, FANTOM5 permissive enhancers, and Thurman et al DHSs from ~75 cell lines.
  • Process ENCODE ChIA-PET data using Mango / download other processed ChIA-PET data from other sources. Heming has added code to find particular orientations of CTCF motifs.
  • Use processed ChIA-PET data, FANTOM5 associations, or THurman et al associations to link enhancers to genes
  • Evaluate how well different enhancer lists capture ENCODE ChIP-seq peaks
  • Run chipenrich using different enhancer lists and compare the resulting p-values

I've set it up so that everything can be run using a series of make commands. The make commands are running the commands listed in commands files in the respective directories. I've also added --help messages to most or all of the R scripts that are used (in the scripts directory), so hopefully by looking at the commands files and the options for the R scripts it will be clear how any desired modifications can be made. I've tried to scatter comments throughout the commands files and R scripts as well.

If something doesn't seem to work as it's supposed to, if something's unclear, etc., my email is [email protected].

I've also included some jupyter notebooks and my rotation wrap-up powerpoint in the "other_materials" directory.

Relevant file formats

The instructions below mention a number of file formats that I used. They are described here. There also files named commands or *.commands throughout the directories; these are the files called by the Makefiles, listing the commands to be run.

Pairs file

A pairs file name ends in *.pairs. It has two columns. The first column represents a gene ID, the second column represents an enhancer that has been assigned to the gene (the enhancer is represented in the format "chrom:start:end", e.g. "chr2:20000:22000").

My scripts assume that there are no headers in these files.

Interactions file

An interactions file ends in *.interactions and lists interacting genomic regions based on e.g. a ChIA-PET experiment. Each line in the file symbolizes an interaction between two genomic regions. The first three columns are the chromosome, start, and end of the first of the two regions, and the second three columns are the chromosome, start, and end of the second of the two interacting regions. This can be used to associate genes with enhancers.

My scripts assume that there are no headers in these files.

Instructions

Download public data

You'll need to start by downloading some public datasets (ENCODE ChIP-seq, ChromHMM tracks, and master DNase). You can do this from this directory by running:

	# Gets data from UCSC Genome Browser (DHSs, chromHMM), Thurman et al, FANTOM5,
	# and chipenrich.data. Data are deposited in the data/ folder
	make download_data

Some notes:

  • chromHMM files are concatenated into a single file and the individual ones are deleted
  • FANTOM5 files have their initial rows (as needed) removed
  • The 5kb locus definition is extracted from chipenrich.data with version at least 1.99.8.

Generate enhancer lists

Once these have been downloaded, you can generate enhancer lists:

cd enhancer_lists
make
cd ..

You'll likely need to change the path at the top of the commands file in order for this to work, as I've set it for my own home path. This will be the case in every commands file in other directories as well.

As it is now, this will generate the following enhancer lists in enhancer_lists for no extension, and another for 1000bp extension:

    Var1     Var2   Var3    Var4
2  dnase     <NA>   <NA>    <NA>
3   <NA> chromhmm   <NA>    <NA>
4  dnase chromhmm   <NA>    <NA>
5   <NA>     <NA> fantom    <NA>
6  dnase     <NA> fantom    <NA>
7   <NA> chromhmm fantom    <NA>
8  dnase chromhmm fantom    <NA>
9   <NA>     <NA>   <NA> thurman
11  <NA> chromhmm   <NA> thurman
13  <NA>     <NA> fantom thurman
15  <NA> chromhmm fantom thurman

Enhancers overlapping with the 5kb locus definition from chipenrich.data (data/genes/chipenrich_5kb_locusdef.txt) are removed.

Generate interaction lists

ChIA-PET interaction data

Next you need to make sure that you have ChIA-PET interaction lists (simple text files listing the significantly interacting regions based on ChIA-PET data). I've included all of the ones I've used in the interaction_lists directory (all files ending with *interactions), so if you don't want to change anything then you can skip this step. If you'd like to add new interactions files, just add them to this directory (with the file name following the format 'experiment_name.interactions') and they'll be included in the downstream processing (also make sure to add the experiment(s) to the experiment_info.txt file in the pair_lists directory -- explained later).

The files in the interaction_lists directory are from three sources:

  • The files starting with "EN" (e.g., ENCSR000CAD.interactions) are from ENCODE ChIA-PET data and have been processed with Mango (v. 1.1.7). To recreate the processing pipelines for these files, go into the mango_pipelines directory and run:
make prepare_workspace
make ENCODE_pipelines

then you can run the resulting *.pipeline files individually with bash.

  • The files ruan_2015*.interactions are from this publication. I've simply downloaded their supplementary data; you can download the data again using the script interaction_lists/ruan_2015_data.sh. This data was not processed using Mango, but rather with another method that (by the look of it) isn't as statistically stringent as Mango would be.
  • The files naive_hesc.interactions and primed_hesc.interactions are from this publication. They ran an earlier version of Mango on their data and the results are included in their supplementary files (as Excel files). I downloaded these, converted them to text files, and included them in this repository. It should be noted that although these were processed by the authors using Mango, it was an earlier version that I believe wasn't yet optimized for the protocol that they used; therefore, processing them with a newer version of Mango will give different results.

The number of interactions per experiment are in the spreadsheet here

Once the ChIA-PET pipelines are finished, various .interactions files will be created.

Checking for convergent CTCF motifs in ChIA-PET

cd mango_pipelines
cd interaction_lists
make motifs

Thurman

cd interaction_lists
make thurman

FANTOM

cd interaction_lists
make fantom

Link enhancers to genes

Once the ChIA-PET data is all there, and you've generated the enhancer lists, you can link enhancers to genes. To do this, cd into the pair_lists directory and run:

make pipelines

This will create a number of *.pipeline files which you can simply run using bash. When these are finished there will be files ending with ".all.E.pairs" or ".all.P2P.pairs" (described below).

This part of the pipeline links enhancers to genes in two different ways. One is the "point-to-point" method (P2P). This just means that if there are any enhancer(s) at one end of the interaction, and gene(s) at the other end, then these enhancers are assigned to these genes. The second is the "encompassing" method (E). This is something that I tried based on the CTCF-looping model of genome organization; if CTCF molecules interact to form loops, and genes and enhancers in these loops interact, then in CTCF/cohesin ChIA-PET data we may wish to take not only the ends of the interactions but everything in between. At the moment I have it set up so that the within a CTCF loop, if there is only one gene then this gene will be linked to all the enhancers in the loop. If there is more than one gene present, then no assignments are made based on that loop (this is the --max_genes_per_region argument for the link_genes_and_enhancers.R script, as indicated by the --help menu for that script).

In order to use the 'E' method on just the CTCF/cohesin experiments, the scripts obviously need to know which proteins were pulled down in which experiments. The experiment_info.txt file in this directory lists this information. The first column lists the experiments (this should correspond to the experiment's interactions file name (in the interaction_lists directory), with the ".interactions" suffix removed); the second column lists the protein that was pulled down in the experiment. Naturally this assumes that it's a ChIA-PET experiment. If it's a HiC experiment or something like that and you'd like to use the experiment to create the locus definitions, just treat it like a ChIA-PET experiment and put "CTCF" in the second column of the experiment_info.txt file.

The output files at this step (using bash to run the *.pipeline files) are *.pairs files (one for each enhancer list and experiment, corresponding to the "E" and the "P2P" methods. If it's not a CTCF/cohesin ChIA-PET experiment, the "E" and "P2P" files will actually be the same; I just make one of each because I concatenate the *pairs files for each enhancer list and each method (P2P/E) together to create the final locus definitions for that enhancer list and that method, and creating an "E" file even for the non-CTCF/cohesin experiments (equivalent to a P2P file for these experiments) allows me to have a consistent naming scheme for concatenating the files that belong together). The .pairs files for a given enhancer list can be concatenated together to get the locus definition corresponding to that enhancer list; the .pipeline files do this concatenation to create the ".all.E.pairs" and ".all.P2P.pairs" files mentioned earlier in this section.

Evaluation of locus definitions

Next, there are a variety of ways in which the new locus definitions can be compared to the old locus definitions (note: the old locus definitions are included in the current_definitions file; these are the "TSS +/- 5kb and 2kb enhancers based on FANTOM5" definitions. If you wish to run my analyses using a different set of locus definitions, you can do so. Just take the locus list of interest, make sure it's in the same format as shown in the current.ldef file, and change the name to current.ldef so that it's compatible with all my scripts. Also, you'll need to include a list of the regions in this locus definition that correspond to genes (format: chrom, start, end, geneid; tab-separated, no header; see genes.txt) and to enhancers (format: chrom, start, end; tab-separated, no header; see enhancers.txt). For the gene file and the enhancer file, change the names to genes.txt and enhancers.txt; essentially, you're just replacing the files currently in the current_definitions directory).

Plot the overlap between the old and the new enhancer lists

The first comparison that can be done is checking how many of the old enhancers overlap with the new enhancers (i.e., what fraction of the old enhancers overlap with at least one enhancer from the new enhancer list, and what fraction of base pairs from the old enhancers are covered in the new enhacers). You can make these plots by changing into the overlap_old_enhancers_with_new directory and running:

make plot

Overlap all the ENCODE ChIP-seq peaks with the locus lists

To compare the fraction of ChIP-seq peaks caught by the new lists with the fraction caught by the old lists, cd into the peak_catching directory and run:

make pipeline
make run

This will overlap each ChIP-seq experiment's peaks with the locus definitions and print out a few basic statistics. You can run

make master_list

to concatenate the results into a single file that can be used to plot things in R

Compare chipenrich p values using different locus lists

You can additionally run chipenrich using the different locus lists and plot negative log10 p values against each other. To do this, cd into the chipenrich directory and run:

make pipeline
make run
make pairs_plots

The make run can take a long time to complete since it's running chipenrich on many different ChIP-seq experiments and locus lists; therefore you'll probably want to do this step with nohup.

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