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A supervised learning framework for chromatin loop detection in genome-wide contact maps.

Project description

NOTE: Peakachu (version>=1.1.2) now supports both .hic and .cool formats.

Introduction

Accurately predicting chromatin loops from genome-wide interaction matrices such as Hi-C data is critical to deepening our understanding of proper gene regulation. Current approaches are mainly focused on searching for statistically enriched dots on a genome-wide map. However, given the availability of orthogonal data types such as ChIA-PET, HiChIP, Capture Hi-C, and high-throughput imaging, a supervised learning approach could facilitate the discovery of a comprehensive set of chromatin interactions. Here, we present Peakachu, a Random Forest classification framework that predicts chromatin loops from genome-wide contact maps. We compare Peakachu with current enrichment-based approaches, and find that Peakachu identifies a unique set of short-range interactions. We show that our models perform well in different platforms, across different sequencing depths, and across different species. We apply this framework to predict chromatin loops in 56 Hi-C datasets, and release the results at the 3D Genome Browser.

Citation

Salameh, T.J., Wang, X., Song, F. et al. A supervised learning framework for chromatin loop detection in genome-wide contact maps. Nat Commun 11, 3428 (2020). https://doi.org/10.1038/s41467-020-17239-9

Installation

Peakachu requires Python3 and several scientific packages to run. It is best to first set up the environment using conda and then install Peakachu from PyPI:

conda config --add channels defaults
conda config --add channels bioconda
conda config --add channels conda-forge
conda create -n peakachu cooler numba scikit-learn=1.1.2 joblib=1.1.0
conda activate peakachu
pip install -U peakachu hic-straw==0.0.6 

Peakachu should now be installed as a command-line tool within the new environment. Options for all peakachu commands and sub-commands can be accessed with the -h option.

peakachu -h
usage: peakachu [-h] {train,score_chromosome,score_genome,depth,pool} ...

Unveil Hi-C Anchors and Peaks.

positional arguments:
  {train,score_chromosome,score_genome,depth,pool}
    train               Train RandomForest model per chromosome
    score_chromosome    Calculate interaction probability per pixel for a chromosome
    score_genome        Calculate interaction probability per pixel for the whole genome
    depth               Calculate the total number of intra-chromosomal chromatin contacts and select the most appropriate pre-trained model
                        for you.
    pool                Print centroid loci from score_genome/score_chromosome output

options:
  -h, --help            show this help message and exit

Example: predicting loops in GM12878 Hi-C

The following example will download an example cooler file containing the GM12878 Hi-C data at the 10kb resolution, train a series of models using H3K27ac HiChIP interactions, and then predict loops using the trained models.

Data preparation

Peakachu requires the contact map to be a .cool file or a .hic file and any training input to be a text file in bedpe format. Example training data can be found at the training-sets subfolder. Cooler files may be found at the 4DN data portal.

wget http://3dgenome.fsm.northwestern.edu/peakachu/test_file/Rao2014-GM12878-MboI-allreps-filtered.10kb.cool

Train a model and predict loops

It is always a good idea to call the help function immediately before entering a command:

peakachu train -h
usage: peakachu train [-h] [-r RESOLUTION] [-p PATH] [--balance] [-b BEDPE] [-w WIDTH] [--nproc NPROC] [-O OUTPUT]

options:
  -h, --help            show this help message and exit
  -r RESOLUTION, --resolution RESOLUTION
                        Resolution in bp (default 10000)
  -p PATH, --path PATH  Path to a .cool URI string or a .hic file.
  --balance             Whether or not using the ICE/KR-balanced matrix.
  -b BEDPE, --bedpe BEDPE
                        Path to the bedpe file containing positive training set.
  -w WIDTH, --width WIDTH
                        Number of bins added to center of window. default width=5 corresponds to 11x11 windows
  --nproc NPROC         Number of worker processes that will be allocated for training. (default 4)
  -O OUTPUT, --output OUTPUT
                        Folder path to store trained models.
peakachu train -r 10000 -p Rao2014-GM12878-MboI-allreps-filtered.10kb.cool --balance -O models -b gm12878.mumbach.h3k27ac-hichip.hg19.bedpe

This will train 23 random forest models, each labeled by a chromosome. The model for every chromosome was trained using interactions from all the other 22 chromosomes in the provided bedpe file. The purpose of this is to avoid Peakachu to predict loops from the same map it used for training, without overfitting. To use these models, you may either use the score_chromosome function to predict loops in only one chromosome, or the score_genome function to perform a genome-wide prediction.

peakachu score_chromosome -h
usage: peakachu score_chromosome [-h] [-r RESOLUTION] [-p PATH] [--balance] [-C CHROM] [-m MODEL] [-l LOWER] [-u UPPER]
                             [--minimum-prob MINIMUM_PROB] [-O OUTPUT]

options:
  -h, --help            show this help message and exit
  -r RESOLUTION, --resolution RESOLUTION
                        Resolution in bp (default 10000)
  -p PATH, --path PATH  Path to a .cool URI string or a .hic file.
  --balance             Whether or not using the ICE/KR-balanced matrix.
  -C CHROM, --chrom CHROM
                        Chromosome label. Only contact data within the specified chromosome will be considered.
  -m MODEL, --model MODEL
                        Path to pickled model file.
  -l LOWER, --lower LOWER
                        Lower bound of distance between loci in bins (default 6).
  -u UPPER, --upper UPPER
                        Upper bound of distance between loci in bins (default 300).
  --minimum-prob MINIMUM_PROB
                        Only output pixels with probability score greater than this value (default 0.5)
  -O OUTPUT, --output OUTPUT
                        Output file name.
peakachu score_chromosome -r 10000 -p Rao2014-GM12878-MboI-allreps-filtered.10kb.cool --balance -O GM12878-chr2-scores.bedpe -C chr2 -m models/chr2.pkl 
peakachu pool -r 10000 -i GM12878-chr2-scores.bedpe -o GM12878-chr2-loops.bedpe -t .9

The pool function serves to select the most significant non-redundant results from per-pixel probabilities calculated by the score functions. It is recommended to try different probability thresholds to achieve the best sensitivity-specificity tradeoff. The output is a standard bedpe file with the 7th and the final column containing the predicted probability from the random forest model and the interaction frequency extracted from the contact matrix, respectively, to support further filtering. The results can be visualized in juicebox or higlass by loading as 2D annotations. Here is an example screenshot of predicted GM12878 loops in juicer: Predicted loops from model trained on H3K27ac HiChIP interactions

Using Peakachu as a standard loop caller

Models for predicting loops in Hi-C have been trained using CTCF ChIA-PET interactions, H3K27ac HiChIP interactions, and a high-confidence loop set (loops that can be detected by at least two orthogonal methods from CTCF ChIA-PET, Pol2 ChIA-PET, Hi-C, CTCF HiChIP, H3K27ac HiChIP, SMC1A HiChIP, H3K4me3 PLAC-Seq, and TrAC-Loop) as positive training samples, at a variety of read depths. Simply download the appropriate model file and directly run the score_genome/score_chromosome function if you want to detect chromatin loops on your own Hi-C or Micro-C maps.

If you are using Peakachu>=2.0, please select a model from the following table:

Total intra reads high-confidence (5kb) high-confidence (10kb) high-confidence (25kb)
2 billion total 5kb total 10kb total 25kb
1.8 billion 90% 5kb 90% 10kb 90% 25kb
1.6 billion 80% 5kb 80% 10kb 80% 25kb
1.4 billion 70% 5kb 70% 10kb 70% 25kb
1.2 billion 60% 5kb 60% 10kb 60% 25kb
1 billion 50% 5kb 50% 10kb 50% 25kb
900 million 45% 5kb 45% 10kb 45% 25kb
850 million 42.5% 5kb 42.5% 10kb 42.5% 25kb
800 million 40% 5kb 40% 10kb 40% 25kb
750 million 37.5% 5kb 37.5% 10kb 37.5% 25kb
700 million 35% 5kb 35% 10kb 35% 25kb
650 million 32.5% 5kb 32.5% 10kb 32.5% 25kb
600 million 30% 5kb 30% 10kb 30% 25kb
550 million 27.5% 5kb 27.5% 10kb 27.5% 25kb
500 million 25% 5kb 25% 10kb 25% 25kb
450 million 22.5% 5kb 22.5% 10kb 22.5% 25kb
400 million 20% 5kb 20% 10kb 20% 25kb
350 million 17.5% 5kb 17.5% 10kb 17.5% 25kb
300 million 15% 5kb 15% 10kb 15% 25kb
250 million 12.5% 5kb 12.5% 10kb 12.5% 25kb
200 million 10% 5kb 10% 10kb 10% 25kb
150 million 7.5% 5kb 7.5% 10kb 7.5% 25kb
100 million 5% 5kb 5% 10kb 5% 25kb
50 million 2.5% 5kb 2.5% 10kb 2.5% 25kb
30 million 1.5% 5kb 1.5% 10kb 1.5% 25kb
10 million 0.5% 5kb 0.5% 10kb 0.5% 25kb
5 million 0.25% 5kb 0.25% 10kb 0.25% 25kb

Instead, if you are using an older Peakachu version (<2.0), please select a model from this table:

Total intra reads high-confidence (5kb) high-confidence (10kb) high-confidence (25kb) CTCF Models (10kb) H3K27ac Model (10kb)
2 billion total 5kb total 10kb total 25kb CTCF total H3K27ac total
1.8 billion 90% 5kb 90% 10kb 90% 25kb CTCF 90% H3K27ac 90%
1.6 billion 80% 5kb 80% 10kb 80% 10kb CTCF 80% H3K27ac 80%
1.4 billion 70% 5kb 70% 10kb 70% 25kb CTCF 70% H3K27ac 70%
1.2 billion 60% 5kb 60% 10kb 60% 25kb CTCF 60% H3K27ac 60%
1 billion 50% 5kb 50% 10kb 50% 25kb CTCF 50% H3K27ac 50%
900 million 45% 5kb 45% 10kb 45% 25kb
850 million 42.5% 5kb 42.5% 10kb 42.5% 25kb
800 million 40% 5kb 40% 10kb 40% 25kb CTCF 40% H3K27ac 40%
750 million 37.5% 5kb 37.5% 10kb 37.5% 25kb
700 million 35% 5kb 35% 10kb 35% 25kb
650 million 32.5% 5kb 32.5% 10kb 32.5% 25kb
600 million 30% 5kb 30% 10kb 30% 25kb CTCF 30% H3K27ac 30%
550 million 27.5% 5kb 27.5% 10kb 27.5% 25kb
500 million 25% 5kb 25% 10kb 25% 25kb
450 million 22.5% 5kb 22.5% 10kb 22.5% 25kb
400 million 20% 5kb 20% 10kb 20% 25kb CTCF 20% H3K27ac 20%
350 million 17.5% 5kb 17.5% 10kb 17.5% 25kb
300 million 15% 5kb 15% 10kb 15% 25kb
250 million 12.5% 5kb 12.5% 10kb 12.5% 25kb
200 million 10% 5kb 10% 10kb 10% 25kb CTCF 10% H3K27ac 10%
150 million 7.5% 5kb 7.5% 10kb 7.5% 25kb
100 million 5% 5kb 5% 10kb 5% 25kb
50 million 2.5% 5kb 2.5% 10kb 2.5% 25kb
30 million 1.5% 5kb 1.5% 10kb 1.5% 25kb CTCF 1.5% H3K27ac 1.5%
10 million 0.5% 25kb
5 million 0.25% 25kb

To make it clear, let's download another Hi-C dataset:

wget -O SKNAS-MboI-allReps-filtered.mcool -L https://www.dropbox.com/s/f80bgn11d7wfgq8/SKNAS-MboI-allReps-filtered.mcool?dl=0

Peakachu provides a handy function peakachu depth to extract the total number of intra-chromosomal pairs in your data and help you select the most appropriate pre-trained model:

peakachu depth -p SKNAS-MboI-allReps-filtered.mcool::resolutions/1000000

The output of above command will be:

num of intra reads in your data: 141955751
num of intra reads in a human with matched sequencing coverage: 139325229
suggested model: 150 million

Therefore, we recommend using the 7.5% models (trained with ~150 million intra reads) to predict loops on this data.

peakachu score_genome -r 10000 --balance -p SKNAS-MboI-allReps-filtered.mcool::resolutions/10000 -O SKNAS-peakachu-10kb-scores.bedpe -m high-confidence.150million.10kb.w6.pkl
peakachu pool -r 10000 -i SKNAS-peakachu-10kb-scores.bedpe -o SKNAS-peakachu-10kb-loops.0.95.bedpe -t 0.95

Not just Hi-C

Peakachu has been tested on Hi-C, Micrco-C, and DNA SPRITE contact maps with good results. For training sets, ChIA-PET, HiChIP, and PLAC-Seq have been tested. The purpose of this software is ultimately to facilitate the interpretation of results from multiple types of experiments, and the user is encouraged to apply Peakachu's training framework to newer approaches as they become available.

Release Notes

Version 2.0 (09/06/2022)

  1. Re-trained the models using the latest scikit-learn v1.1.2
  2. Used the distance-normalized signals instead of original contact signals
  3. Added a 2D Gaussian filter followed by min-max scaling to pre-process each training image
  4. Optimized the computation efficiency using numba and matrix operations.

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