Last updated: 2019-02-15
Checks: 6 0
Knit directory: threeprimeseq/analysis/
This reproducible R Markdown analysis was created with workflowr (version 1.2.0). The Report tab describes the reproducibility checks that were applied when the results were created. The Past versions tab lists the development history.
Great! Since the R Markdown file has been committed to the Git repository, you know the exact version of the code that produced these results.
Great job! The global environment was empty. Objects defined in the global environment can affect the analysis in your R Markdown file in unknown ways. For reproduciblity it’s best to always run the code in an empty environment.
The command set.seed(12345) was run prior to running the code in the R Markdown file. Setting a seed ensures that any results that rely on randomness, e.g. subsampling or permutations, are reproducible.
Great job! Recording the operating system, R version, and package versions is critical for reproducibility.
Nice! There were no cached chunks for this analysis, so you can be confident that you successfully produced the results during this run.
Great! You are using Git for version control. Tracking code development and connecting the code version to the results is critical for reproducibility. The version displayed above was the version of the Git repository at the time these results were generated.
Note that you need to be careful to ensure that all relevant files for the analysis have been committed to Git prior to generating the results (you can use wflow_publish or wflow_git_commit). workflowr only checks the R Markdown file, but you know if there are other scripts or data files that it depends on. Below is the status of the Git repository when the results were generated:
Ignored files:
Ignored: .DS_Store
Ignored: .Rhistory
Ignored: .Rproj.user/
Ignored: data/.DS_Store
Ignored: data/perm_QTL_trans_noMP_5percov/
Ignored: output/.DS_Store
Untracked files:
Untracked: KalistoAbundance18486.txt
Untracked: analysis/4suDataIGV.Rmd
Untracked: analysis/DirectionapaQTL.Rmd
Untracked: analysis/EvaleQTLs.Rmd
Untracked: analysis/YL_QTL_test.Rmd
Untracked: analysis/ncbiRefSeq_sm.sort.mRNA.bed
Untracked: analysis/snake.config.notes.Rmd
Untracked: analysis/verifyBAM.Rmd
Untracked: analysis/verifybam_dubs.Rmd
Untracked: code/PeaksToCoverPerReads.py
Untracked: code/strober_pc_pve_heatmap_func.R
Untracked: data/18486.genecov.txt
Untracked: data/APApeaksYL.total.inbrain.bed
Untracked: data/ApaQTLs/
Untracked: data/ChromHmmOverlap/
Untracked: data/DistTXN2Peak_genelocAnno/
Untracked: data/GM12878.chromHMM.bed
Untracked: data/GM12878.chromHMM.txt
Untracked: data/LianoglouLCL/
Untracked: data/LocusZoom/
Untracked: data/NuclearApaQTLs.txt
Untracked: data/PeakCounts/
Untracked: data/PeakCounts_noMP_5perc/
Untracked: data/PeakCounts_noMP_genelocanno/
Untracked: data/PeakUsage/
Untracked: data/PeakUsage_noMP/
Untracked: data/PeakUsage_noMP_GeneLocAnno/
Untracked: data/PeaksUsed/
Untracked: data/PeaksUsed_noMP_5percCov/
Untracked: data/RNAkalisto/
Untracked: data/RefSeq_annotations/
Untracked: data/TotalApaQTLs.txt
Untracked: data/Totalpeaks_filtered_clean.bed
Untracked: data/UnderstandPeaksQC/
Untracked: data/WASP_STAT/
Untracked: data/YL-SP-18486-T-combined-genecov.txt
Untracked: data/YL-SP-18486-T_S9_R1_001-genecov.txt
Untracked: data/YL_QTL_test/
Untracked: data/apaExamp/
Untracked: data/apaQTL_examp_noMP/
Untracked: data/bedgraph_peaks/
Untracked: data/bin200.5.T.nuccov.bed
Untracked: data/bin200.Anuccov.bed
Untracked: data/bin200.nuccov.bed
Untracked: data/clean_peaks/
Untracked: data/comb_map_stats.csv
Untracked: data/comb_map_stats.xlsx
Untracked: data/comb_map_stats_39ind.csv
Untracked: data/combined_reads_mapped_three_prime_seq.csv
Untracked: data/diff_iso_GeneLocAnno/
Untracked: data/diff_iso_proc/
Untracked: data/diff_iso_trans/
Untracked: data/ensemble_to_genename.txt
Untracked: data/example_gene_peakQuant/
Untracked: data/explainProtVar/
Untracked: data/filtPeakOppstrand_cov_noMP_GeneLocAnno_5perc/
Untracked: data/filtered_APApeaks_merged_allchrom_refseqTrans.closest2End.bed
Untracked: data/filtered_APApeaks_merged_allchrom_refseqTrans.closest2End.noties.bed
Untracked: data/first50lines_closest.txt
Untracked: data/gencov.test.csv
Untracked: data/gencov.test.txt
Untracked: data/gencov_zero.test.csv
Untracked: data/gencov_zero.test.txt
Untracked: data/gene_cov/
Untracked: data/joined
Untracked: data/leafcutter/
Untracked: data/merged_combined_YL-SP-threeprimeseq.bg
Untracked: data/molPheno_noMP/
Untracked: data/mol_overlap/
Untracked: data/mol_pheno/
Untracked: data/nom_QTL/
Untracked: data/nom_QTL_opp/
Untracked: data/nom_QTL_trans/
Untracked: data/nuc6up/
Untracked: data/nuc_10up/
Untracked: data/other_qtls/
Untracked: data/pQTL_otherphen/
Untracked: data/peakPerRefSeqGene/
Untracked: data/perm_QTL/
Untracked: data/perm_QTL_GeneLocAnno_noMP_5percov/
Untracked: data/perm_QTL_GeneLocAnno_noMP_5percov_3UTR/
Untracked: data/perm_QTL_opp/
Untracked: data/perm_QTL_trans/
Untracked: data/perm_QTL_trans_filt/
Untracked: data/protAndAPAAndExplmRes.Rda
Untracked: data/protAndAPAlmRes.Rda
Untracked: data/protAndExpressionlmRes.Rda
Untracked: data/reads_mapped_three_prime_seq.csv
Untracked: data/smash.cov.results.bed
Untracked: data/smash.cov.results.csv
Untracked: data/smash.cov.results.txt
Untracked: data/smash_testregion/
Untracked: data/ssFC200.cov.bed
Untracked: data/temp.file1
Untracked: data/temp.file2
Untracked: data/temp.gencov.test.txt
Untracked: data/temp.gencov_zero.test.txt
Untracked: data/threePrimeSeqMetaData.csv
Untracked: data/threePrimeSeqMetaData55Ind.txt
Untracked: data/threePrimeSeqMetaData55Ind.xlsx
Untracked: data/threePrimeSeqMetaData55Ind_noDup.txt
Untracked: data/threePrimeSeqMetaData55Ind_noDup.xlsx
Untracked: data/threePrimeSeqMetaData55Ind_noDup_WASPMAP.txt
Untracked: data/threePrimeSeqMetaData55Ind_noDup_WASPMAP.xlsx
Untracked: output/picard/
Untracked: output/plots/
Untracked: output/qual.fig2.pdf
Unstaged changes:
Modified: analysis/28ind.peak.explore.Rmd
Modified: analysis/CompareLianoglouData.Rmd
Modified: analysis/NewPeakPostMP.Rmd
Modified: analysis/accountMapBias.Rmd
Modified: analysis/apaQTLoverlapGWAS.Rmd
Modified: analysis/cleanupdtseq.internalpriming.Rmd
Modified: analysis/coloc_apaQTLs_protQTLs.Rmd
Modified: analysis/dif.iso.usage.leafcutter.Rmd
Modified: analysis/diff_iso_pipeline.Rmd
Modified: analysis/explainpQTLs.Rmd
Modified: analysis/explore.filters.Rmd
Modified: analysis/flash2mash.Rmd
Modified: analysis/mispriming_approach.Rmd
Modified: analysis/overlapMolQTL.Rmd
Modified: analysis/overlapMolQTL.opposite.Rmd
Modified: analysis/overlap_qtls.Rmd
Modified: analysis/peakOverlap_oppstrand.Rmd
Modified: analysis/peakQCPPlots.Rmd
Modified: analysis/pheno.leaf.comb.Rmd
Modified: analysis/pipeline_55Ind.Rmd
Modified: analysis/swarmPlots_QTLs.Rmd
Modified: analysis/test.max2.Rmd
Modified: analysis/test.smash.Rmd
Modified: analysis/understandPeaks.Rmd
Modified: code/Snakefile
Note that any generated files, e.g. HTML, png, CSS, etc., are not included in this status report because it is ok for generated content to have uncommitted changes.
These are the previous versions of the R Markdown and HTML files. If you’ve configured a remote Git repository (see ?wflow_git_remote), click on the hyperlinks in the table below to view them.
| File | Version | Author | Date | Message |
|---|---|---|---|---|
| html | d6363e1 | Briana Mittleman | 2018-09-24 | Build site. |
| Rmd | ed0a1eb | Briana Mittleman | 2018-09-24 | add fix command to full pipeline |
| html | a0a73b5 | Briana Mittleman | 2018-09-24 | Build site. |
| Rmd | 6242ff6 | Briana Mittleman | 2018-09-24 | add filter command to full pipeline |
| html | 617d032 | brimittleman | 2018-08-08 | Build site. |
| Rmd | 6be219c | brimittleman | 2018-08-08 | add final pipeline |
| html | 5566fd6 | brimittleman | 2018-08-02 | Build site. |
| Rmd | 0f79304 | brimittleman | 2018-08-02 | fix cov to peak file problem |
| html | efad657 | Briana Mittleman | 2018-07-31 | Build site. |
| Rmd | 7c203e4 | Briana Mittleman | 2018-07-31 | format files for yangs peak script |
| html | 7fc2ce7 | Briana Mittleman | 2018-07-30 | Build site. |
| Rmd | 782320d | Briana Mittleman | 2018-07-30 | look at coverage in merged bw |
| html | e5a8da6 | Briana Mittleman | 2018-07-30 | Build site. |
| Rmd | 422a428 | Briana Mittleman | 2018-07-30 | add peak cove pipeline and combined lane qc |
I need to create a processing pipeline that I can run each time I get more individuals that will do the following:
combine all total and nuclear libraries (as a bigwig/genome coverage)
call peaks with Yang’s script
filter peaks with Yang’s script
clean peaks
run feature counts on these peaks for all fo the individuals
I can do this step in my snakefile. First, I added the following to my environemnt.
I want to create bedgraph for each file. I will add a rule to my snakefile that does this and puts them in the bedgraph directory.
I want to add more memory for this rule in the cluster.json
"bedgraph" :
{
"mem": 16000
},
"bedgraph_5" :
{
"mem": 16000
}I will use the bedgraphtobigwig tool.
#add to directory
dir_bedgraph= dir_data + "bedgraph/"
dir_bigwig= dir_data + "bigwig/"
dir_sortbg= dir_data + "bedgraph_sort/"
dir_bedgraph_5= dir_data + "bedgraph_5prime/"
#add to rule_all
expand(dir_bedgraph + "{samples}.split.bg", samples=samples)
expand(dir_sortbg + "{samples}.sort.bg", samples=samples)
expand(dir_bigwig + "{samples}.bw", samples=samples)
expand(dir_bedgraph_5 + "{samples}.5.bg", samples=samples)
#rule
rule bedgraph_5:
input:
bam = dir_sort + "{samples}-sort.bam"
output: dir_bedgraph_5 + "{samples}.5.bg"
shell: "bedtools genomecov -ibam {input.bam} -bg -5 > {output}"
rule bedgraph:
input:
bam = dir_sort + "{samples}-sort.bam"
output: dir_bedgraph + "{samples}.split.bg"
shell: "bedtools genomecov -ibam {input.bam} -bg -split > {output}"
rule sort_bg:
input: dir_bedgraph + "{samples}.split.bg"
output: dir_sortbg + "{samples}.sort.bg"
shell: "sort -k1,1 -k2,2n {input} > {output}"
rule bg_to_bw:
input:
bg=dir_sortbg + "{samples}.sort.bg"
len= chrom_length
output: dir_bigwig + "{samples}.bw"
shell: "bedGraphToBigWig {input.bg} {input.len} {output}"This next step will take all of the files in the bigwig directory and merge them. To do this I will create a script that creates a list of all of the files then uses this list in the merge script.
mergeBW.sh
#!/bin/bash
#SBATCH --job-name=mergeBW
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=mergeBW.out
#SBATCH --error=mergeBW.err
#SBATCH --partition=broadwl
#SBATCH --mem=40G
#SBATCH --mail-type=END
module load Anaconda3
source activate three-prime-env
ls -d -1 /project2/gilad/briana/threeprimeseq/data/bigwig/* | tail -n +2 > /project2/gilad/briana/threeprimeseq/data/list_bw/list_of_bigwig.txt
bigWigMerge -inList /project2/gilad/briana/threeprimeseq/data/list_bw/list_of_bigwig.txt /project2/gilad/briana/threeprimeseq/data/mergedBW/merged_combined_YL-SP-threeprimeseq.bg
The result of this script will be a merged bedgraph of all of the files.
library(workflowr)This is workflowr version 1.2.0
Run ?workflowr for help getting startedlibrary(ggplot2)
library(dplyr)
Attaching package: 'dplyr'The following objects are masked from 'package:stats':
filter, lagThe following objects are masked from 'package:base':
intersect, setdiff, setequal, union#!/usr/bin/env python
main(inFile, outFile):
fout = open(outFile,'w')
for ind,ln in enumerate(open(inFile)):
print(ind)
chrom, start, end, count = ln.split()
i2=int(start)
while i2 < int(end):
fout.write("%s\t%d\t%s\n"%(chrom, i2 + 1, count))
fout.flush()
i2 += 1
fout.close()
if __name__ == "__main__":
import numpy as np
from misc_helper import *
import sys
inFile = sys.argv[1]
outFile = sys.argv[2]
main(inFile, outFile)Create a bash script to run this. I want the input and output files to be arguments in the python script.
#!/bin/bash
#SBATCH --job-name=run_bgtocov
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=run_bgtocov.out
#SBATCH --error=run_bgtocov.err
#SBATCH --partition=broadwl
#SBATCH --mem=12G
#SBATCH --mail-type=END
module load Anaconda3
source activate three-prime-env
python bg_to_cov.py "/project2/gilad/briana/threeprimeseq/data/mergedBW/merged_combined_YL-SP-threeprimeseq.bg" "/project2/gilad/briana/threeprimeseq/data/mergedBW/merged_combined_YL-SP-threeprimeseq.coverage.txt"Sort result with:
sort -k1,1 -k2,2n merged_combined_YL-SP-threeprimeseq.coverage.txt > merged_combined_YL-SP-threeprimeseq.coverage.sort.txt
def main(inFile, outFile, ctarget):
fout = open(outFile,'w')
mincount = 10
ov = 20
current_peak = []
currentChrom = None
prevPos = 0
for ln in open(inFile):
chrom, pos, count = ln.split()
if chrom != ctarget: continue
count = float(count)
if currentChrom == None:
currentChrom = chrom
if count == 0 or currentChrom != chrom or int(pos) > prevPos + 1:
if len(current_peak) > 0:
print (current_peak)
M = max([x[1] for x in current_peak])
if M > mincount:
all_peaks = refine_peak(current_peak, M, M*0.1,M*0.05)
#refined_peaks = [(x[0][0],x[-1][0], np.mean([y[1] for y in x])) for x in all_peaks]
rpeaks = [(int(x[0][0])-ov,int(x[-1][0])+ov, np.mean([y[1] for y in x])) for x in all_peaks]
if len(rpeaks) > 1:
for clu in cluster_intervals(rpeaks)[0]:
M = max([x[2] for x in clu])
merging = []
for x in clu:
if x[2] > M *0.5:
#print x, M
merging.append(x)
c, s,e,mean = chrom, min([x[0] for x in merging])+ov, max([x[1] for x in merging])-ov, np.mean([x[2] for x in merging])
#print c,s,e,mean
fout.write("chr%s\t%d\t%d\t%d\t+\t.\n"%(c,s,e,mean))
fout.flush()
elif len(rpeaks) == 1:
s,e,mean = rpeaks[0]
fout.write("chr%s\t%d\t%d\t%f\t+\t.\n"%(chrom,s+ov,e-ov,mean))
print("chr%s"%chrom+"\t%d\t%d\t%f\t+\t.\n"%rpeaks[0])
#print refined_peaks
current_peak = [(pos,count)]
else:
current_peak.append((pos,count))
currentChrom = chrom
prevPos = int(pos)
def refine_peak(current_peak, M, thresh, noise, minpeaksize=30):
cpeak = []
opeak = []
allcpeaks = []
allopeaks = []
for pos, count in current_peak:
if count > thresh:
cpeak.append((pos,count))
opeak = []
continue
elif count > noise:
opeak.append((pos,count))
else:
if len(opeak) > minpeaksize:
allopeaks.append(opeak)
opeak = []
if len(cpeak) > minpeaksize:
allcpeaks.append(cpeak)
cpeak = []
if len(cpeak) > minpeaksize:
allcpeaks.append(cpeak)
if len(opeak) > minpeaksize:
allopeaks.append(opeak)
allpeaks = allcpeaks
for opeak in allopeaks:
M = max([x[1] for x in opeak])
allpeaks += refine_peak(opeak, M, M*0.3, noise)
#print [(x[0],x[-1]) for x in allcpeaks], [(x[0],x[-1]) for x in allopeaks], [(x[0],x[-1]) for x in allpeaks]
#print '---\n'
return(allpeaks)
if __name__ == "__main__":
import numpy as np
from misc_helper import *
import sys
chrom = sys.argv[1]
inFile = "/project2/gilad/briana/threeprimeseq/data/mergedBW/merged_combined_YL-SP-threeprimeseq.coverage.sort.txt" # "/project2/yangili1/threeprimeseq/gencov/TotalBamFiles.split.genomecov.bed"
outFile = "/project2/gilad/briana/threeprimeseq/data/mergedPeaks/APApeaks_chr%s.bed"%chrom
main(inFile, outFile, chrom)#!/bin/bash
#SBATCH --job-name=w_getpeakYLgen
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=w_getpeakYLgen.out
#SBATCH --error=w_getpeakYLgen.err
#SBATCH --partition=broadwl
#SBATCH --mem=12G
#SBATCH --mail-type=END
module load Anaconda3
source activate three-prime-env
for i in $(seq 1 22); do
python callPeaksYL_GEN.py $i
doneRun the file with : sbatch w_getpeakYLGEN.sh
After I have the peaks I will need to use Yangs filter peak function.
Update each of the following scripts:
cat /project2/gilad/briana/threeprimeseq/data/mergedPeaks/*.bed > /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/APApeaks_merged_allchrom.bedbed2saf.py
fout = file("/project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/APApeaks_merged_allchrom.SAF",'w')
fout.write("GeneID\tChr\tStart\tEnd\tStrand\n")
for ln in open("/project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/APApeaks_merged_allchrom.bed"):
chrom, start, end, score, strand, score2 = ln.split()
ID = "peak_%s_%s_%s"%(chrom,start, end)
fout.write("%s\t%s\t%s\t%s\t+\n"%(ID+"_+", chrom.replace("chr",""), start, end))
fout.write("%s\t%s\t%s\t%s\t-\n"%(ID+"_-", chrom.replace("chr",""), start, end))
fout.close()Run this with run_bed2saf.sh. I did this because I need to load python2 rather than using the environment,
#!/bin/bash
#SBATCH --job-name=peak_fc
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=peak_fc.out
#SBATCH --error=peak_fc.err
#SBATCH --partition=broadwl
#SBATCH --mem=12G
#SBATCH --mail-type=END
module load Anaconda3
source activate three-prime-env
featureCounts -a /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/APApeaks_merged_allchrom.SAF -F SAF -o /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/APAquant.fc /project2/gilad/briana/threeprimeseq/data/sort/*-sort.bam -s 1This script is peak_fc.sh
filter_peaks.py
I should run this in a bash script with python 2 as well.
#!/bin/bash
#SBATCH --job-name=filter_peak
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=filet_peak.out
#SBATCH --error=filter_peak.err
#SBATCH --partition=broadwl
#SBATCH --mem=12G
#SBATCH --mail-type=END
module load python
python filter_peaks.pyName the peaks for the cleanup:
x = wc -l /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/filtered_APApeaks_merged_allchrom.bed
seq 1 x > peak.num.txt
paste /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/filtered_APApeaks_merged_allchrom.bed peak.num.txt | column -s $'\t' -t > temp
awk '{print $1 "\t" $2 "\t" $3 "\t" $7 "\t" $4 "\t" $5 "\t" $6}' temp > /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/filtered_APApeaks_merged_allchrom.named.bed#!/bin/rscripts
# usage: ./cleanupdtseq.R in_bedfile, outfile, cuttoff
#this script takes a putative peak file, and output file name and a cuttoff for classification and outputs the file with all of the seqs classified.
#use optparse for management of input arguments I want to be able to imput the 6up nuc file and write out a filter file
#script needs to run outside of conda env. should module load R in bash script when I submit it
library(optparse)
library(dplyr)
library(tidyr)
library(ggplot2)
library(cleanUpdTSeq)
library(GenomicRanges)
library(BSgenome.Hsapiens.UCSC.hg19)
option_list = list(
make_option(c("-f", "--file"), action="store", default=NA, type='character',
help="input file"),
make_option(c("-o", "--output"), action="store", default=NA, type='character',
help="output file"),
make_option(c("-c", "--cutoff"), action="store", default=NA, type='double',
help="assignment cuttoff")
)
opt_parser <- OptionParser(option_list=option_list)
opt <- parse_args(opt_parser)
#interrupt execution if no file is supplied
if (is.null(opt$file)){
print_help(opt_parser)
stop("Need input file", call.=FALSE)
}
#imput file for test data
testSet <- read.table(file = opt$file, sep="\t", col.names =c("chr", "start", "end", "PeakName", "Cov", "Strand", "score"))
peaks <- BED2GRangesSeq(testSet, withSeq=FALSE)
#build vector with human genome
testSet.NaiveBayes <- buildFeatureVector(peaks, BSgenomeName=Hsapiens,
upstream=40, downstream=30,
wordSize=6, alphabet=c("ACGT"),
sampleType="unknown",
replaceNAdistance=30,
method="NaiveBayes",
ZeroBasedIndex=1, fetchSeq=TRUE)
#classfy sites with built in classsifer
data(classifier)
testResults <- predictTestSet(testSet.NaiveBayes=testSet.NaiveBayes,
classifier=classifier,
outputFile=NULL,
assignmentCutoff=opt$cutoff)
true_peaks=testResults %>% filter(pred.class==1)
#write results
write.table(true_peaks, file=opt$output, quote = F, row.names = F, col.names = T) I will create a bash script to run the cleanupdtseq.R code.
#!/bin/bash
#SBATCH --job-name=cleanup_comb
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=cleanup_comb.out
#SBATCH --error=cleanup_comb.err
#SBATCH --partition=broadwl
#SBATCH --mem=12G
#SBATCH --mail-type=END
module load R
Rscript cleanupdtseq.R -f /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/filtered_APApeaks_merged_allchrom.named.bed -o /project2/gilad/briana/threeprimeseq/data/clean.peaks_comb/truePeaks_clean.bed -c .5
Do this after. filter_peaksClean.R, run with run_filter_peaksClean.sh
library(dplyr)
clean=read.table("/project2/gilad/briana/threeprimeseq/data/clean.peaks_comb/truePeaks_clean.bed", header=F, col.names=c("PeakName", "probFalse", "probTrue", "predClass", "UP", "Down"), skip=1)
peaks=read.table("/project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/filtered_APApeaks_merged_allchrom.named.bed", header=F, col.names=c("Chr", "Start", "End", "PeakName", "Cov", "Strand", "Score"))
true_peaks=clean %>% filter(predClass==1)
true_peak_bed=semi_join(peaks, clean, by="PeakName")
write.table(true_peak_bed, file="/project2/gilad/briana/threeprimeseq/data/clean.peaks_comb/APApeaks_combined_clean.bed", row.names = F, col.names = F, quote = F)#!/bin/bash
#SBATCH --job-name=filter_clean
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=filter_clean.out
#SBATCH --error=filter_clean.err
#SBATCH --partition=broadwl
#SBATCH --mem=12G
#SBATCH --mail-type=END
module load R
Rscript filter_peaksClean.Rmay have to run bed to SAF again. bed2saf.peaks.py
from misc_helper import *
fout = file("/project2/gilad/briana/threeprimeseq/data/clean.peaks_comb/APApeaks_combined_clean.saf",'w')
fout.write("GeneID\tChr\tStart\tEnd\tStrand\n")
for ln in open("/project2/gilad/briana/threeprimeseq/data/clean.peaks_comb/APApeaks_combined_clean.bed"):
chrom, start, end, name, score, strand, score2 = ln.split()
ID = "peak_%s_%s_%s"%(chrom,start, end)
fout.write("%s\t%s\t%s\t%s\t+\n"%(ID+"_+", chrom.replace("chr",""), start, end))
fout.write("%s\t%s\t%s\t%s\t-\n"%(ID+"_-", chrom.replace("chr",""), start, end))
fout.close()#!/bin/bash
#SBATCH --job-name=bed2saf_peaks
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=bed2saf_peak.out
#SBATCH --error=bed2saf_peak.err
#SBATCH --partition=broadwl
#SBATCH --mem=12G
#SBATCH --mail-type=END
module load python
python bed2saf.peaks.py#!/bin/bash
#SBATCH --job-name=clean_peak_fc
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=clean_peak_fc.out
#SBATCH --error=clean_peak_fc.err
#SBATCH --partition=broadwl
#SBATCH --mem=12G
#SBATCH --mail-type=END
module load Anaconda3
source activate three-prime-env
featureCounts -a /project2/gilad/briana/threeprimeseq/data/clean.peaks_comb/APApeaks_combined_clean.saf -F SAF -o /project2/gilad/briana/threeprimeseq/data/clean_peaks_comb_quant/APAquant.fc.cleanpeaks.fc /project2/gilad/briana/threeprimeseq/data/sort/*-sort.bam -s 1Should make this a snake file!!!
mergeBW.sh
run_bgtocov.sh
sort -k1,1 -k2,2n /project2/gilad/briana/threeprimeseq/data/mergedBW/merged_combined_YL-SP-threeprimeseq.coverage.txt > /project2/gilad/briana/threeprimeseq/data/mergedBW/merged_combined_YL-SP-threeprimeseq.coverage.sort.txt
w_getpeakYLGEN.sh
cat /project2/gilad/briana/threeprimeseq/data/mergedPeaks/*.bed > /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/APApeaks_merged_allchrom.bed
run_bed2saf.sh
peak_fc.sh
run_filterPeak.sh
x = wc -l /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/filtered_APApeaks_merged_allchrom.bed
seq 1 x > /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/peak.num.txt
paste /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/filtered_APApeaks_merged_allchrom.bed /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/peak.num.txt | column -s $'\t' -t > /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/temp
awk '{print $1 "\t" $2 "\t" $3 "\t" $7 "\t" $4 "\t" $5 "\t" $6}' /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/temp > /project2/gilad/briana/threeprimeseq/data/mergedPeaks_comb/filtered_APApeaks_merged_allchrom.named.bed
if no cleanning:
cleanup_comb.sh
run_filter_peaksClean.sh
run_bed2saf_peaks.sh
clean_peak_fc.sh
#!/bin/bash
#SBATCH --job-name=comb_gencov
#SBATCH --account=pi-yangili1
#SBATCH --time=24:00:00
#SBATCH --output=comb_gencov.out
#SBATCH --error=comb_gencov.err
#SBATCH --partition=bigmem2
#SBATCH --mem=100G
#SBATCH --mail-type=END
module load Anaconda3
source activate three-prime-env
samtools merge /project2/gilad/briana/threeprimeseq/data/comb_bam/all_total.nuc_comb.bam /project2/gilad/briana/threeprimeseq/data/sort/*.bam
bedtools genomecov -ibam /project2/gilad/briana/threeprimeseq/data/comb_bam/all_total.nuc_comb.bam -d -split > /project2/gilad/briana/threeprimeseq/data/comb_bam/all_total.nuc_comb.split.genomecov.bedWill need to run mergeBW.sh and run_bgtocov.sh then sort with
sort -k1,1 -k2,2n merged_combined_YL-SP-threeprimeseq.coverage.txt > merged_combined_YL-SP-threeprimeseq.coverage.sort.txt then call peaks with the updated callpeaks script from yang (get_APA_peaks.py) I run this with w_getpeakYLGEN.sh.
sessionInfo()R version 3.5.1 (2018-07-02)
Platform: x86_64-apple-darwin15.6.0 (64-bit)
Running under: macOS 10.14.1
Matrix products: default
BLAS: /Library/Frameworks/R.framework/Versions/3.5/Resources/lib/libRblas.0.dylib
LAPACK: /Library/Frameworks/R.framework/Versions/3.5/Resources/lib/libRlapack.dylib
locale:
[1] en_US.UTF-8/en_US.UTF-8/en_US.UTF-8/C/en_US.UTF-8/en_US.UTF-8
attached base packages:
[1] stats graphics grDevices utils datasets methods base
other attached packages:
[1] dplyr_0.7.6 ggplot2_3.0.0 workflowr_1.2.0
loaded via a namespace (and not attached):
[1] Rcpp_0.12.19 bindr_0.1.1 knitr_1.20 whisker_0.3-2
[5] magrittr_1.5 tidyselect_0.2.4 munsell_0.5.0 colorspace_1.3-2
[9] R6_2.3.0 rlang_0.2.2 stringr_1.4.0 plyr_1.8.4
[13] tools_3.5.1 grid_3.5.1 gtable_0.2.0 withr_2.1.2
[17] git2r_0.24.0 htmltools_0.3.6 assertthat_0.2.0 yaml_2.2.0
[21] lazyeval_0.2.1 rprojroot_1.3-2 digest_0.6.17 tibble_1.4.2
[25] crayon_1.3.4 bindrcpp_0.2.2 purrr_0.2.5 fs_1.2.6
[29] glue_1.3.0 evaluate_0.13 rmarkdown_1.11 stringi_1.2.4
[33] pillar_1.3.0 compiler_3.5.1 scales_1.0.0 backports_1.1.2
[37] pkgconfig_2.0.2