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Model Based Analysis for ChIP-Seq data

Project description

Time-stamp: <2014-06-17 16:58:37 Tao Liu>

Introduction

With the improvement of sequencing techniques, chromatin immunoprecipitation followed by high throughput sequencing (ChIP-Seq) is getting popular to study genome-wide protein-DNA interactions. To address the lack of powerful ChIP-Seq analysis method, we present a novel algorithm, named Model-based Analysis of ChIP-Seq (MACS), for identifying transcript factor binding sites. MACS captures the influence of genome complexity to evaluate the significance of enriched ChIP regions, and MACS improves the spatial resolution of binding sites through combining the information of both sequencing tag position and orientation. MACS can be easily used for ChIP-Seq data alone, or with control sample with the increase of specificity.

Install

Please check the file ‘INSTALL’ in the distribution.

Usage of MACS2

macs2 [-h] [--version]
           {callpeak,filterdup,bdgpeakcall,bdgcmp,randsample,bdgdiff,bdgbroadcall}
Example for regular peak calling:

macs2 callpeak -t ChIP.bam -c Control.bam -f BAM -g hs -n test -B -q 0.01

Example for broad peak calling:

macs2 callpeak -t ChIP.bam -c Control.bam --broad -g hs --broad-cutoff 0.1

There are seven major functions available in MACS serving as sub-commands.

callpeak:

Main MACS2 Function to Call peaks from alignment results.

bdgpeakcall:

Call peaks from bedGraph output.

bdgbroadcall:

Call broad peaks from bedGraph output.

bdgcmp:

Deduct noise by comparing two signal tracks in bedGraph.

bdgdiff:

Differential peak detection based on paired four bedgraph files.

filterdup:

Remove duplicate reads at the same position, then convert acceptable format to BED format.

predictd:

Predict d or fragment size from alignment results.

pileup:

Pileup aligned reads with a given extension size (fragment size or d in MACS language). Note there will be no step for duplicate reads filtering or sequencing depth scaling, so you may need to do certain post- processing.

randsample:

Randomly sample number/percentage of total reads.

refinepeak:

(Experimental) Take raw reads alignment, refine peak summits and give scores measuring balance of forward- backward tags. Inspired by SPP.

We only cover ‘callpeak’ module in this document. Please use ‘macs2 COMMAND -h’ to see the detail description for each option of each module.

Call peaks

This is the main function in MACS2. It can be invoked by ‘macs2 callpeak’ command. If you type this command without parameters, you will see a full description of commandline options. Here we only list commonly used ones.

Options

-t/–treatment FILENAME

This is the only REQUIRED parameter for MACS. File can be in any supported format specified by –format option. Check –format for detail. If you have more than one alignment files, you can specify them as `-t A B C`. MACS will pool up all these files together.

-c/–control

The control or mock data file. Please follow the same direction as for -t/–treatment.

-n/–name

The name string of the experiment. MACS will use this string NAME to create output files like ‘NAME_peaks.xls’, ‘NAME_negative_peaks.xls’, ‘NAME_peaks.bed’ , ‘NAME_summits.bed’, ‘NAME_model.r’ and so on. So please avoid any confliction between these filenames and your existing files.

–outdir

MACS2 will save all output files into speficied folder for this option.

-f/–format FORMAT

Format of tag file, can be “ELAND”, “BED”, “ELANDMULTI”, “ELANDEXPORT”, “ELANDMULTIPET” (for pair-end tags), “SAM”, “BAM”, “BOWTIE” or “BAMPE”. Default is “AUTO” which will allow MACS to decide the format automatically. “AUTO” is also usefule when you combine different formats of files.

The BED format can be found at UCSC genome browser website.

If the format is ELAND, the file must be ELAND result output file, each line MUST represents only ONE tag, with fields of:

  1. Sequence name (derived from file name and line number if format is not Fasta)

  2. Sequence

  3. Type of match:

NM:

no match found.

QC:

no matching done: QC failure (too many Ns basically).

RM:

no matching done: repeat masked (may be seen if repeatFile.txt was specified).

U0:

Best match found was a unique exact match.

U1:

Best match found was a unique 1-error match.

U2:

Best match found was a unique 2-error match.

R0:

Multiple exact matches found.

R1:

Multiple 1-error matches found, no exact matches.

R2:

Multiple 2-error matches found, no exact or 1-error matches.

  1. Number of exact matches found.

  2. Number of 1-error matches found.

  3. Number of 2-error matches found. Rest of fields are only seen if a unique best match was found (i.e. the match code in field 3 begins with “U”).

  4. Genome file in which match was found.

  5. Position of match (bases in file are numbered starting at 1).

  6. Direction of match (F=forward strand, R=reverse).

  7. How N characters in read were interpreted: (“.”=not applicable, “D”=deletion, “I”=insertion). Rest of fields are only seen in the case of a unique inexact match (i.e. the match code was U1 or U2).

  8. Position and type of first substitution error (e.g. 12A: base 12 was A, not whatever is was in read).

  9. Position and type of first substitution error, as above.

If the format is ELANDMULTI, the file must be ELAND output file from multiple-match mode, each line MUST represents only ONE tag, with fields of:

  1. Sequence name

  2. Sequence

  3. Either NM, QC, RM (as described above) or the following:

  4. x:y:z where x, y, and z are the number of exact, single-error, and 2-error matches found

  5. Blank, if no matches found or if too many matches found, or the following: BAC_plus_vector.fa:163022R1,170128F2,E_coli.fa:3909847R1 This says there are two matches to BAC_plus_vector.fa: one in the reverse direction starting at position 160322 with one error, one in the forward direction starting at position 170128 with two errors. There is also a single-error match to E_coli.fa.

If the format is BAM/SAM, please check the definition in (http://samtools.sourceforge.net/samtools.shtml). Pair-end mapping results can be saved in a single BAM file, if so, MACS will automatically keep the left mate(5’ end) tag. However, when format BAMPE is specified, MACS will use the real fragments inferred from alignment results for reads pileup.

If the format is BOWTIE, you need to provide the ASCII bowtie output file with the suffix ‘.map’. Please note that, you need to make sure that in the bowtie output, you only keep one location for one read. Check the bowtie manual for detail if you want at (http://bowtie-bio.sourceforge.net/manual.shtml)

Here is the definition for Bowtie output in ASCII characters I copied from the above webpage:

  1. Name of read that aligned

  2. Orientation of read in the alignment, ‘-’ for reverse complement, ‘+’ otherwise

  3. Name of reference sequence where alignment occurs, or ordinal ID if no name was provided

  4. 0-based offset into the forward reference strand where leftmost character of the alignment occurs

  5. Read sequence (reverse-complemented if orientation is -)

  6. ASCII-encoded read qualities (reversed if orientation is -). The encoded quality values are on the Phred scale and the encoding is ASCII-offset by 33 (ASCII char !).

  7. Number of other instances where the same read aligns against the same reference characters as were aligned against in this alignment. This is not the number of other places the read aligns with the same number of mismatches. The number in this column is generally not a good proxy for that number (e.g., the number in this column may be ‘0’ while the number of other alignments with the same number of mismatches might be large). This column was previously described as “Reserved”.

  8. Comma-separated list of mismatch descriptors. If there are no mismatches in the alignment, this field is empty. A single descriptor has the format offset:reference-base>read-base. The offset is expressed as a 0-based offset from the high-quality (5’) end of the read.

Notes:

1) For BED format, the 6th column of strand information is required by MACS. And please pay attention that the coordinates in BED format is zero-based and half-open (http://genome.ucsc.edu/FAQ/FAQtracks#tracks1).

2) For plain ELAND format, only matches with match type U0, U1 or U2 is accepted by MACS, i.e. only the unique match for a sequence with less than 3 errors is involed in calculation. If multiple hits of a single tag are included in your raw ELAND file, please remove the redundancy to keep the best hit for that sequencing tag.

3) For the experiment with several replicates, it is recommended to concatenate several ChIP-seq treatment files into a single file. To do this, under Unix/Mac or Cygwin (for windows OS), type:

`$ cat replicate1.bed replicate2.bed replicate3.bed > all_replicates.bed`

For BAM or SAM files, samtools can be used to combine replicates.

4) ELAND export format support sometimes may not work on your datasets, because people may mislabel the 11th and 12th column. MACS uses 11th column as the sequence name which should be the chromosome names.

5) A special mode will be triggered while format is specified as ‘BAMPE’. In this way, MACS2 will process the BAM files as paired-end data. Instead of building bimodal distribution of plus and minus strand reads to predict fragment size, MACS2 now will use actual insert sizes of pairs of reads to build fragment pileup.

-g/–gsize

PLEASE assign this parameter to fit your needs!

It’s the mappable genome size or effective genome size which is defined as the genome size which can be sequenced. Because of the repetitive features on the chromsomes, the actual mappable genome size will be smaller than the original size, about 90% or 70% of the genome size. The default hs – 2.7e9 is recommended for UCSC human hg18 assembly. Here are all precompiled parameters for effective genome size:

hs:

2.7e9

mm:

1.87e9

ce:

9e7

dm:

1.2e8

-s/–tsize

The size of sequencing tags. If you don’t specify it, MACS will try to use the first 10 sequences from your input treatment file to determine the tag size. Specifying it will override the automatically determined tag size.

–bw

The band width which is used to scan the genome ONLY for model building. You can set this parameter as the sonication fragment size expected from wet experiment. The previous side effect on the peak detection process has been removed. So this parameter only affects the model building.

-q/–qvalue

The qvalue (minimum FDR) cutoff to call significant regions. Default is 0.01. For broad marks, you can try 0.05 as cutoff. Q-values are calculated from p-values using Benjamini-Hochberg procedure.

-p/–pvalue

The pvalue cutoff. If -p is specified, MACS2 will use pvalue instead of qvalue.

-m/–mfold

This parameter is used to select the regions within MFOLD range of high-confidence enrichment ratio against background to build model. The regions must be lower than upper limit, and higher than the lower limit of fold enrichment. DEFAULT:10,30 means using all regions not too low (>10) and not too high (<30) to build paired-peaks model. If MACS can not find more than 100 regions to build model, it will use the –extsize parameter to continue the peak detection ONLY if –fix-bimodal is set.

–nolambda

With this flag on, MACS will use the background lambda as local lambda. This means MACS will not consider the local bias at peak candidate regions.

–slocal, –llocal

These two parameters control which two levels of regions will be checked around the peak regions to calculate the maximum lambda as local lambda. By default, MACS considers 1000bp for small local region(–slocal), and 10000bps for large local region(–llocal) which captures the bias from a long range effect like an open chromatin domain. You can tweak these according to your project. Remember that if the region is set too small, a sharp spike in the input data may kill the significant peak.

–fix-bimodal

Whether turn on the auto paired-peak model process. If it’s set, when MACS failed to build paired model, it will use the nomodel settings, the ‘–extsize’ parameter to extend each tags. If set, MACS will be terminated if paried-peak model is failed.

–nomodel

While on, MACS will bypass building the shifting model.

–extsize

While ‘–nomodel’ is set, MACS uses this parameter to extend reads in 5’->3’ direction to fix-sized fragments. For example, if the size of binding region for your transcription factor is 200 bp, and you want to bypass the model building by MACS, this parameter can be set as 200. This option is only valid when –nomodel is set or when MACS fails to build model and –fix-bimodal is on.

–shift

Note, this is NOT the legacy –shiftsize option which is replaced by –extsize! You can set an arbitrary shift in bp here. Please Use discretion while setting it other than default value (0). When –nomodel is set, MACS will use this value to move cutting ends (5’) then apply –extsize from 5’ to 3’ direction to extend them to fragments. When this value is negative, ends will be moved toward 3’->5’ direction, otherwise 5’->3’ direction. Recommended to keep it as default 0 for ChIP-Seq datasets, or -1 * half of EXTSIZE together with –extsize option for detecting enriched cutting loci such as certain DNAseI-Seq datasets. Note, you can’t set values other than 0 if format is BAMPE for paired-end data. Default is 0.

Here are some examples for combining –shift and –extsize:

1. To find enriched cutting sites such as some DNAse-Seq datasets. In this case, all 5’ ends of sequenced reads should be extended in both direction to smooth the pileup signals. If the wanted smoothing window is 200bps, then use ‘–nomodel –shift -100 –extsize 200’.

2. For certain nucleosome-seq data, we need to pileup the centers of nucleosomes using a half-nucleosome size for wavelet analysis (e.g. NPS algorithm). Since the DNA wrapped on nucleosome is about 147bps, this option can be used: ‘–nomodel –shift 37 –extsize 73’.

–keep-dup

It controls the MACS behavior towards duplicate tags at the exact same location – the same coordination and the same strand. The default ‘auto’ option makes MACS calculate the maximum tags at the exact same location based on binomal distribution using 1e-5 as pvalue cutoff; and the ‘all’ option keeps every tags. If an integer is given, at most this number of tags will be kept at the same location. The default is to keep one tag at the same location. Default: 1

–broad

When this flag is on, MACS will try to composite broad regions in BED12 ( a gene-model-like format ) by putting nearby highly enriched regions into a broad region with loose cutoff. The broad region is controlled by another cutoff through –broad-cutoff. The maximum length of broad region length is 4 times of d from MACS. DEFAULT: False

–broad-cutoff

Cutoff for broad region. This option is not available unless –broad is set. If -p is set, this is a pvalue cutoff, otherwise, it’s a qvalue cutoff. DEFAULT: 0.1

–to-large

When set, linearly scale the smaller dataset to the same depth as larger dataset, by default, the smaller dataset will be scaled towards the larger dataset. Beware, to scale up small data would cause more false positives.

–down-sample

When set, random sampling method will scale down the bigger sample. By default, MACS uses linear scaling. This option will make the results unstable and irreproducible since each time, random reads would be selected, especially the numbers (pileup, pvalue, qvalue) would change. Consider to use ‘randsample’ script before MACS2 runs instead.

-B/–bdg

If this flag is on, MACS will store the fragment pileup, control lambda, -log10pvalue and -log10qvalue scores in bedGraph files. The bedGraph files will be stored in current directory named NAME+’_treat_pileup.bdg’ for treatment data, NAME+’_control_lambda.bdg’ for local lambda values from control, NAME+’_treat_pvalue.bdg’ for Poisson pvalue scores (in -log10(pvalue) form), and NAME+’_treat_qvalue.bdg’ for q-value scores from Benjamini–Hochberg–Yekutieli procedure <http://en.wikipedia.org/wiki/False_discovery_rate#Dependent_tests>

–call-summits

MACS will now reanalyze the shape of signal profile (p or q-score depending on cutoff setting) to deconvolve subpeaks within each peak called from general procedure. It’s highly recommended to detect adjacent binding events. While used, the output subpeaks of a big peak region will have the same peak boundaries, and different scores and peak summit positions.

–verbose

If you don’t want to see any message during the running of MACS, set it to 0. But the CRITICAL messages will never be hidden. If you want to see rich information like how many peaks are called for every chromosome, you can set it to 3 or larger than 3.

Output files

  1. NAME_peaks.xls is a tabular file which contains information about called peaks. You can open it in excel and sort/filter using excel functions. Information include: chromosome name, start position of peak, end position of peak, length of peak region, absolute peak summit position, pileup height at peak summit, -log10(pvalue) for the peak summit (e.g. pvalue =1e-10, then this value should be 10), fold enrichment for this peak summit against random Poisson distribution with local lambda, -log10(qvalue) at peak summit. Coordinates in XLS is 1-based which is different with BED format.

  2. NAME_peaks.narrowPeak is BED6+4 format file which contains the peak locations together with peak summit, pvalue and qvalue. You can load it to UCSC genome browser. Definition of some specific columns are: 5th: integer score for display, 7th: fold-change, 8th: -log10pvalue, 9th: -log10qvalue, 10th: relative summit position to peak start. The file can be loaded directly to UCSC genome browser. Remove the beginning track line if you want to analyze it by other tools.

  3. NAME_summits.bed is in BED format, which contains the peak summits locations for every peaks. The 5th column in this file is -log10pvalue the same as NAME_peaks.bed. If you want to find the motifs at the binding sites, this file is recommended. The file can be loaded directly to UCSC genome browser. Remove the beginning track line if you want to analyze it by other tools.

  4. NAME_peaks.broadPeak is in BED6+3 format which is similar to narrowPeak file, except for missing the 10th column for annotating peak summits.

  1. NAME_peaks.gappedPeak is in BED12+3 format which contains both the broad region and narrow peaks. The 5th column is 10*-log10qvalue, to be more compatible to show grey levels on UCSC browser. Tht 7th is the start of the first narrow peak in the region, and the 8th column is the end. The 9th column should be RGB color key, however, we keep 0 here to use the default color, so change it if you want. The 10th column tells how many blocks including the starting 1bp and ending 1bp of broad regions. The 11th column shows the length of each blocks, and 12th for the starts of each blocks. 13th: fold-change, 14th: -log10pvalue, 15th: -log10qvalue. The file can be loaded directly to UCSC genome browser.

  2. NAME_model.r is an R script which you can use to produce a PDF image about the model based on your data. Load it to R by:

    `$ Rscript NAME_model.r`

    Then a pdf file NAME_model.pdf will be generated in your current directory. Note, R is required to draw this figure.

  3. The .bdg files are in bedGraph format which can be imported to UCSC genome browser or be converted into even smaller bigWig files. There are two kinds of bdg files: treat_pileup, and control_lambda.

Tips of fine-tuning peak calling

Check the three scripts within MACSv2 package:

  1. bdgcmp can be used on `*_treat_pileup.bdg` and `*_control_lambda.bdg` or bedGraph files from other resources to calculate score track.

  2. bdgpeakcall can be used on `*_treat_pvalue.bdg` or the file generated from bdgcmp or bedGraph file from other resources to call peaks with given cutoff, maximum-gap between nearby mergable peaks and minimum length of peak. bdgbroadcall works similarly to bdgpeakcall, however it will output _broad_peaks.bed in BED12 format.

  3. Differential calling tool – bdgdiff, can be used on 4 bedgraph files which are scores between treatment 1 and control 1, treatment 2 and control 2, treatment 1 and treatment 2, treatment 2 and treatment 1. It will output the consistent and unique sites according to parameter settings for minimum length, maximum gap and cutoff.

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