Last updated: 2019-01-25
workflowr checks: (Click a bullet for more information) ✔ R Markdown file: up-to-date
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.
✔ Environment: empty
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.
✔ Seed:
set.seed(12345)
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.
✔ Session information: recorded
Great job! Recording the operating system, R version, and package versions is critical for reproducibility.
✔ Repository version: 3789767
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: output/.DS_Store
Untracked files:
Untracked: KalistoAbundance18486.txt
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: code/PeaksToCoverPerReads.py
Untracked: code/strober_pc_pve_heatmap_func.R
Untracked: data/18486.genecov.txt
Untracked: data/APApeaksYL.total.inbrain.bed
Untracked: data/ChromHmmOverlap/
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/PeakUsage/
Untracked: data/PeakUsage_noMP/
Untracked: data/PeaksUsed/
Untracked: data/PeaksUsed_noMP_5percCov/
Untracked: data/RNAkalisto/
Untracked: data/TotalApaQTLs.txt
Untracked: data/Totalpeaks_filtered_clean.bed
Untracked: data/UnderstandPeaksQC/
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_proc/
Untracked: data/diff_iso_trans/
Untracked: data/ensemble_to_genename.txt
Untracked: data/example_gene_peakQuant/
Untracked: data/explainProtVar/
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_opp/
Untracked: data/perm_QTL_trans/
Untracked: data/perm_QTL_trans_filt/
Untracked: data/perm_QTL_trans_noMP_5percov/
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: output/picard/
Untracked: output/plots/
Untracked: output/qual.fig2.pdf
Unstaged changes:
Modified: analysis/28ind.peak.explore.Rmd
Modified: analysis/CompareLianoglouData.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/swarmPlots_QTLs.Rmd
Modified: analysis/test.max2.Rmd
Modified: analysis/understandPeaks.Rmd
Modified: code/Snakefile
There are a few things about the data I need to understand before I can run ash. First I need to find the genes that overlap with protein and RNA. Then I need to pick those with 1 dominant peak.
set.seed(1)
library(workflowr)This is workflowr version 1.1.1
Run ?workflowr for help getting startedlibrary(tidyverse)── Attaching packages ────────────────────────────────────────────────────────────── tidyverse 1.2.1 ──✔ ggplot2 3.0.0 ✔ purrr 0.2.5
✔ tibble 1.4.2 ✔ dplyr 0.7.6
✔ tidyr 0.8.1 ✔ stringr 1.3.1
✔ readr 1.1.1 ✔ forcats 0.3.0── Conflicts ───────────────────────────────────────────────────────────────── tidyverse_conflicts() ──
✖ dplyr::filter() masks stats::filter()
✖ dplyr::lag() masks stats::lag()library(reshape2)
Attaching package: 'reshape2'The following object is masked from 'package:tidyr':
smithslibrary(cowplot)
Attaching package: 'cowplot'The following object is masked from 'package:ggplot2':
ggsaveUpload data:
I want the filtered peak counts. I need to filter the counts file for the total fraction based on the filtered peaks.
Total counts: /project2/gilad/briana/threeprimeseq/data/filtPeakOppstrand_cov_noMP/filtered_APApeaks_merged_allchrom_refseqGenes.TranscriptNoMP_sm_quant.Total_fixed.fc
okPeaks: /project2/gilad/briana/threeprimeseq/data/PeakUsage_noMP/filtered_APApeaks_merged_allchrom_refseqGenes.TranscriptNoMP_sm_quant.Total_fixed.pheno.5percPeaks.txt
filterTotalCounts_noMP_5percCov.py
totalokPeaks5perc_file="/project2/gilad/briana/threeprimeseq/data/PeakUsage_noMP/filtered_APApeaks_merged_allchrom_refseqGenes.TranscriptNoMP_sm_quant.Total_fixed.pheno.5percPeaks.txt"
countFile=open("/project2/gilad/briana/threeprimeseq/data/filtPeakOppstrand_cov_noMP/filtered_APApeaks_merged_allchrom_refseqGenes.TranscriptNoMP_sm_quant.Total_fixed.fc","r")
outFile=open("/project2/gilad/briana/threeprimeseq/data/filtPeakOppstrand_cov_noMP/filtered_APApeaks_merged_allchrom_refseqGenes.TranscriptNoMP_sm_quant.Total_5percCov_fixed.fc", "w")
allPeakOk={}
for ln in open(totalokPeaks5perc_file,"r"):
peakname=ln.split()[5]
peaknum=peakname[4:]
if peaknum not in allPeakOk.keys():
allPeakOk[peaknum]=""
for i,ln in enumerate(countFile):
if i==1:
outFile.write(ln)
if i>1:
ID=ln.split()[0]
peak=ID.split(":")[0]
peaknum=peak[4:]
if peaknum in allPeakOk.keys():
outFile.write(ln)
outFile.close()total_Cov=read.table("../data/PeakCounts_noMP_5perc/filtered_APApeaks_merged_allchrom_refseqGenes.TranscriptNoMP_sm_quant.Total_5percCov_fixed.fc", stringsAsFactors = F,header = T) %>% separate(Geneid, into=c("peak", "chr", "start", "end", "strand", "Name"), sep=":")
total_genes=total_Cov %>% select(Name) %>% arrange(Name) %>% unique()Gene names:
geneNames=read.table("../data/ensemble_to_genename.txt",sep="\t", header=T, stringsAsFactors = F, col.names=c("ID", "Name", "Source"))prot=read.table("../data/mol_pheno/fastqtl_qqnorm_prot.fixed.noChr.txt",header=T,stringsAsFactors = F) %>% inner_join(geneNames, by="ID")Keep the protein genes in APA:
prot_inAPA=prot %>% semi_join(total_genes, by="Name")This shows we have 4209 genes with data for both. Now I can back filter the total peaks for the genes in prot_inAPA
total_Cov_wProt= total_Cov %>% semi_join(prot_inAPA,by="Name")Need to give Stephens lab: unadjusted R-squared, and n and p for each protein, where p is the number of apa s that you are using in the regression and n is the number of samples?
To do this I need to get the overlapping individuals:
protInd=colnames(prot)[5:(dim(prot)[2]-2)]
ApaInd=c()
for (i in colnames(total_Cov)[12:ncol(total_Cov)]){
num=substr(i,2,6)
name=paste("NA", num, sep="")
ApaInd=c(ApaInd, name)
}
IndBoth=intersect(protInd,ApaInd)
length(IndBoth)[1] 29I have 29 individuals in common for these.
I need to make a matrix for each gene. It will have a row for each commmon individual. A column for the protein, and a column for each assocaited peaks. After I have this I will be able to get the R2 value.
First create a function.
get_R2=function(gene, Cov=total_Cov, prot=prot_inAPA, apaName=ApaInd){
gene_un= enexpr(gene)
#deal with APA
genePeaks=total_Cov %>% filter(Name==!!gene_un)
n=nrow(genePeaks)
drop_col=c('chr','Chr', 'start','end','strand','Name', 'Start','End','Strand','Length')
genePeaks_sm= genePeaks %>% select(-one_of(drop_col))
colnames(genePeaks_sm)=c("peak", ApaInd)
genePeakM=genePeaks_sm %>% column_to_rownames(var="peak") %>% t()
genePeakDF=as.data.frame(genePeakM) %>% rownames_to_column(var="Ind")
#deal with prot
drop_col_prot= c("Chr", "start", "end", "ID", "Name", "Source")
geneProt=prot %>% filter(Name==!!gene_un) %>% select(-one_of(drop_col_prot)) %>% t()
colnames(geneProt)="prot"
#print(dim(geneProt))
geneProt_df=as.data.frame(geneProt) %>% rownames_to_column(var="Ind") %>% drop_na(prot)
#print(geneProt_df)
both=geneProt_df %>% inner_join(genePeakDF,by="Ind")
num=seq(1,n)
base="summary(lm(both$prot~"
for (i in 3:dim(both)[2]){
base=paste(base, "+both[,",i,"]",sep="")
}
code=paste(base, "))$r.squared", sep="")
r2=eval(parse(text=code))
final=c(gene, r2,nrow(both),n)
return(final)
}Run this on all genes:
final_matrix=matrix(c("gene","r2","n","p"),1,4)
for (i in prot_inAPA$Name){
final_matrix= rbind(final_matrix,get_R2(i))
}Make this a dataframe:
final_df=as.data.frame(final_matrix)
colnames(final_df)=as.character(unlist(final_df[1,]))
final_df <- final_df[-1 ,]
save(final_df,file="../data/protAndAPAlmRes.Rda")When the stephens lab ran ASH on this, all R2 shrunk to zero. ##Protein and expression
I want to look at the the protein ~ expression model. This is easier because there is always only 1 expression level per gene.
rna=read.table("../data/mol_pheno/fastqtl_qqnorm_RNAseq_phase2.fixed.noChr.txt",header=T,stringsAsFactors = F) %>% separate(ID, into=c("ID", "ver"), sep ="[.]") %>% inner_join(geneNames, by="ID")I want to filter this by genes we have proteinn for.
rnaandProt= rna %>% semi_join(prot, by="Name")These are the gene I want to run the analsis on. I will make a similar function to run the linear model.
get_R2_Protexp=function(gene, exp=rnaandProt, protein=prot){
#gene_un= enexpr(gene)
exp_gene=exp %>% filter(Name ==gene)
#print(exp_gene)
drop_col_exp= c("Chr", "start", "end", "ID", "ver", "Name", "Source")
exp_gene_sm= exp_gene %>% select(-one_of(drop_col_exp)) %>% t()
colnames(exp_gene_sm)="Expression"
exp_gene_df=as.data.frame(exp_gene_sm) %>% rownames_to_column(var="Ind")
#print(exp_gene_df)
drop_col_p= c("Chr", "start", "end", "ID", "Name", "Source")
prot_gene= protein %>% filter(Name ==gene)%>% select(-one_of(drop_col_p)) %>% t()
colnames(prot_gene)= "Protein"
prot_gene_df= as.data.frame(prot_gene) %>% rownames_to_column(var="Ind") %>% drop_na(Protein)
#print(prot_gene_df)
both=prot_gene_df %>% inner_join(exp_gene_df, by="Ind")
#print(both)
r2=summary(lm(both$Protein ~both$Expression))$r.squared
#print(r2)
final=c(gene, r2, nrow(both))
}
test=get_R2_Protexp(gene="ISG15")Run on all genes in rnaandProt
final_matrix_protExp=matrix(c("gene","r2","n"),1,3)
for (i in rnaandProt$Name){
final_matrix_protExp= rbind(final_matrix_protExp,get_R2_Protexp(i))
}Fix as df and save
final_df_protExp=as.data.frame(final_matrix_protExp)
colnames(final_df_protExp)=as.character(unlist(final_df_protExp[1,]))
final_df_protExp <- final_df_protExp[-1 ,]
save(final_df_protExp,file="../data/protAndExpressionlmRes.Rda")I need to subset the protein for genes in apa and expr.
prot_inAPAandExp=prot %>% semi_join(total_genes, by="Name") %>% semi_join(rna,by="Name")get_R2_full=function(gene, Cov=total_Cov, prot=prot_inAPAandExp, apaName=ApaInd,exp=rna){
gene_un= enexpr(gene)
#deal with APA
genePeaks=total_Cov %>% filter(Name==!!gene_un)
n=nrow(genePeaks)
drop_col=c('chr','Chr', 'start','end','strand','Name', 'Start','End','Strand','Length')
genePeaks_sm= genePeaks %>% select(-one_of(drop_col))
colnames(genePeaks_sm)=c("peak", ApaInd)
genePeakM=genePeaks_sm %>% column_to_rownames(var="peak") %>% t()
genePeakDF=as.data.frame(genePeakM) %>% rownames_to_column(var="Ind")
#deal with prot
drop_col_prot= c("Chr", "start", "end", "ID", "Name", "Source")
geneProt=prot %>% filter(Name==!!gene_un) %>% select(-one_of(drop_col_prot)) %>% t()
colnames(geneProt)="prot"
#print(dim(geneProt))
geneProt_df=as.data.frame(geneProt) %>% rownames_to_column(var="Ind") %>% drop_na(prot)
#print(geneProt_df)
#deal with expr
exp_gene=exp %>% filter(Name ==gene)
drop_col_exp= c("Chr", "start", "end", "ID", "ver", "Name", "Source")
exp_gene_sm= exp_gene %>% select(-one_of(drop_col_exp)) %>% t()
colnames(exp_gene_sm)="Expression"
exp_gene_df=as.data.frame(exp_gene_sm) %>% rownames_to_column(var="Ind")
#make full model
both=geneProt_df %>% inner_join(exp_gene_df, by="Ind") %>% inner_join(genePeakDF,by="Ind")
num=seq(1,n)
base="summary(lm(both$prot~ both$Expression"
for (i in 4:dim(both)[2]){
base=paste(base, "+both[,",i,"]",sep="")
}
code=paste(base, "))$r.squared", sep="")
#print(code)
r2=eval(parse(text=code))
final=c(gene, r2,nrow(both),n)
return(final)
}
test_full=get_R2_full("ISG15")Run this on all genes:
final_matrix_full=matrix(c("gene","r2","n","p"),1,4)
for (i in prot_inAPAandExp$Name){
final_matrix_full= rbind(final_matrix_full,get_R2_full(i))
}Make this a dataframe:
final_df_full=as.data.frame(final_matrix_full)
colnames(final_df_full)=as.character(unlist(final_df_full[1,]))
final_df_full <- final_df_full[-1 ,]
save(final_df_full,file="../data/protAndAPAAndExplmRes.Rda")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] bindrcpp_0.2.2 cowplot_0.9.3 reshape2_1.4.3 forcats_0.3.0
[5] stringr_1.3.1 dplyr_0.7.6 purrr_0.2.5 readr_1.1.1
[9] tidyr_0.8.1 tibble_1.4.2 ggplot2_3.0.0 tidyverse_1.2.1
[13] workflowr_1.1.1
loaded via a namespace (and not attached):
[1] tidyselect_0.2.4 haven_1.1.2 lattice_0.20-35
[4] colorspace_1.3-2 htmltools_0.3.6 yaml_2.2.0
[7] rlang_0.2.2 R.oo_1.22.0 pillar_1.3.0
[10] glue_1.3.0 withr_2.1.2 R.utils_2.7.0
[13] modelr_0.1.2 readxl_1.1.0 bindr_0.1.1
[16] plyr_1.8.4 munsell_0.5.0 gtable_0.2.0
[19] cellranger_1.1.0 rvest_0.3.2 R.methodsS3_1.7.1
[22] evaluate_0.11 knitr_1.20 broom_0.5.0
[25] Rcpp_0.12.19 scales_1.0.0 backports_1.1.2
[28] jsonlite_1.5 hms_0.4.2 digest_0.6.17
[31] stringi_1.2.4 grid_3.5.1 rprojroot_1.3-2
[34] cli_1.0.1 tools_3.5.1 magrittr_1.5
[37] lazyeval_0.2.1 crayon_1.3.4 whisker_0.3-2
[40] pkgconfig_2.0.2 xml2_1.2.0 lubridate_1.7.4
[43] assertthat_0.2.0 rmarkdown_1.10 httr_1.3.1
[46] rstudioapi_0.8 R6_2.3.0 nlme_3.1-137
[49] git2r_0.23.0 compiler_3.5.1
This reproducible R Markdown analysis was created with workflowr 1.1.1