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author | mingchen0919 |
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date | Tue, 08 Aug 2017 10:40:22 -0400 |
parents | 0374e090e38e |
children | 2efa46ce2c4c |
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--- title: "Fastqc report: short reads quality evaluation" author: "Ming Chen" output: html_document --- ```{r setup, include=FALSE} knitr::opts_chunk$set(echo=ECHO, warning=FALSE, message=FALSE) library(plyr) library(stringr) library(dplyr) library(highcharter) library(DT) library(reshape2) library(plotly) library(formattable) library(htmltools) ``` ```{bash 'create output directory', echo=FALSE} # create extra files directory. very important! mkdir REPORT_OUTPUT_DIR ``` # Fastqc analysis ```{bash 'copy data to working directory', echo=FALSE} # Copy uploaded data to the working directory for f in $(echo READS | sed "s/,/ /g") do cp $f ./ done ``` ```{bash 'run fastqc', echo=FALSE} for r in $(ls *.dat) do fastqc -o REPORT_OUTPUT_DIR $r > /dev/null 2>&1 done ``` ## Fastqc html reports Below are links to ***Fastqc*** original html reports. ```{r 'html report links'} html_report_list = list() html_files = list.files('REPORT_OUTPUT_DIR', pattern = '.*html') for (i in html_files) { html_report_list[[i]] = tags$li(tags$a(href=i, i)) } tags$ul(html_report_list) ``` ## Parsing fastqc data ```{bash echo=FALSE} ##==== copy fastqc generated zip files from report output directory to job work directory == cp -r REPORT_OUTPUT_DIR/*zip ./ # create a file to store data file paths echo "sample_id,file_path" > PWF_file_paths.txt # Pass, Warning, Fail echo "sample_id,file_path" > PBQS_file_paths.txt # Per Base Quality Score echo "sample_id,file_path" > PSQS_file_paths.txt # Per Sequence Quality Score echo "sample_id,file_path" > PSGC_file_paths.txt # Per Sequence GC Content echo "sample_id,file_path" > PBSC_file_paths.txt # Per Base Sequence Content echo "sample_id,file_path" > PBNC_file_paths.txt # Per Base N Content echo "sample_id,file_path" > SDL_file_paths.txt # Sequence Duplication Level echo "sample_id,file_path" > SLD_file_paths.txt # Sequence Length Distribution echo "sample_id,file_path" > KMC_file_paths.txt # Kmer Content for i in $(ls *.zip) do BASE=$(echo $i | sed 's/\(.*\)\.zip/\1/g') echo $BASE unzip ${BASE}.zip > /dev/null 2>&1 ##====== pass,warning,fail (WSF) ============= awk '/^>>/ {print}' "$BASE"/fastqc_data.txt | grep -v 'END_MODULE' | sed 's/>>//' > "$BASE"-PWF.txt echo "${BASE},${BASE}-PWF.txt" >> PWF_file_paths.txt ##====== per base quality scores (PBQS) ====== awk '/^>>Per base sequence quality/ {flag=1; next} /END_MODULE/ {flag=0} flag' "$BASE"/fastqc_data.txt >"$BASE"-PBQS.txt echo "${BASE},${BASE}-PBQS.txt" >> PBQS_file_paths.txt ##====== per sequence quality scores (PSQS) awk '/^>>Per sequence quality scores/ {flag=1; next} /END_MODULE/ {flag=0} flag' "$BASE"/fastqc_data.txt >"$BASE"-PSQS.txt echo "${BASE},${BASE}-PSQS.txt" >> PSQS_file_paths.txt ##====== Per sequence GC content (PSGC) awk '/^>>Per sequence GC content/ {flag=1; next} /END_MODULE/ {flag=0} flag' "$BASE"/fastqc_data.txt >"$BASE"-PSGC.txt echo "${BASE},${BASE}-PSGC.txt" >> PSGC_file_paths.txt ##====== Per Base Sequence Content (PBSC) awk '/^>>Per base sequence content/ {flag=1; next} /END_MODULE/ {flag=0} flag' "$BASE"/fastqc_data.txt >"$BASE"-PBSC.txt echo "${BASE},${BASE}-PBSC.txt" >> PBSC_file_paths.txt ##====== Per Base N Content (PBNC) awk '/^>>Per base N content/ {flag=1; next} /END_MODULE/ {flag=0} flag' "$BASE"/fastqc_data.txt >"$BASE"-PBNC.txt echo "${BASE},${BASE}-PBNC.txt" >> PBNC_file_paths.txt ##====== Sequence Duplication Level (SDL) awk '/^>>Sequence Duplication Levels/ {flag=1; next} /END_MODULE/ {flag=0} flag' "$BASE"/fastqc_data.txt >"$BASE"-SDL.txt echo "${BASE},${BASE}-SDL.txt" >> SDL_file_paths.txt ##====== Sequence Length Distribution (SLD) awk '/^>>Sequence Length Distribution/ {flag=1; next} /END_MODULE/ {flag=0} flag' "$BASE"/fastqc_data.txt >"$BASE"-SLD.txt echo "${BASE},${BASE}-SLD.txt" >> SLD_file_paths.txt ##====== Kmer Content ============ awk '/^>>Kmer Content/ {flag=1; next} /END_MODULE/ {flag=0} flag' "$BASE"/fastqc_data.txt >"$BASE"-KMC.txt echo "${BASE},${BASE}-KMC.txt" >> KMC_file_paths.txt done ``` ## Evaluation Overview ```{r 'overview'} PWF_file_paths = read.csv('PWF_file_paths.txt', header = TRUE, stringsAsFactors = FALSE) rm('PWF_df') for(i in 1:nrow(PWF_file_paths)) { file_path = PWF_file_paths[i,2] pwf_df = read.csv(file_path, sep='\t', header=FALSE, stringsAsFactors = FALSE) colnames(pwf_df) = c('item', PWF_file_paths[i,1]) if (!exists('PWF_df')) { PWF_df = pwf_df } else { PWF_df = cbind(PWF_df, pwf_df[,2,drop=FALSE]) } } ``` ```{r} my_icon = c('ok', 'remove', 'star') names(my_icon) = c('pass', 'fail', 'warn') evaluate_list = list() for (i in colnames(PWF_df)[-1]) { evaluate_list[[i]] = formatter( "span", style = x ~ style("background-color" = ifelse(x =='pass', '#9CD027', ifelse(x == 'fail', '#CC0000', '#FF4E00')), "color" = "white", "width" = "50px", "float" = "left", "padding-right" = "5px") ) } formattable(PWF_df, evaluate_list) ``` ## Per Base Quality Scores ```{r} PBQS_df = data.frame() PBQS_file_paths = read.csv('PBQS_file_paths.txt', header = TRUE, stringsAsFactors = FALSE) for(i in 1:nrow(PBQS_file_paths)) { # file_path = paste0('REPORT_OUTPUT_DIR/', PBQS_file_paths[i,2]) file_path = PBQS_file_paths[i,2] pbqs_df = read.csv(file_path, sep='\t', header=TRUE, stringsAsFactors = FALSE) %>% mutate(Base1=as.numeric(str_split_fixed(X.Base, '-', 2)[,1]), Base2=as.numeric(str_split_fixed(X.Base, '-', 2)[,2])) %>% (function (df) { df1 = select(df, -Base2) df2 = select(df, -Base1) %>% filter(Base2 != '') colnames(df1) = c(colnames(df1)[1:7], 'Base') colnames(df2) = c(colnames(df2)[1:7], 'Base') res = rbind(df1, df2) %>% arrange(Base) return(res) }) pbqs_df$sample_id = rep(PBQS_file_paths[i,1], nrow(pbqs_df)) PBQS_df = rbind(PBQS_df, pbqs_df) } ``` ```{r} # datatable(PBQS_df) max_phred = max(PBQS_df$Mean) + 10 hchart(PBQS_df, "line", hcaes(x = Base, y = Mean, group = sample_id)) %>% hc_title( text = "Per Base Quality Score" ) %>% hc_yAxis( title = list(text = "Mean Base Quality Score"), min = 0, max = max_phred, plotLines = list( list(label = list(text = "Phred Score = 27"), width = 2, dashStyle = "dash", color = "green", value = 27), list(label = list(text = "Phred Score = 20"), width = 2, color = "red", value = 20) ) ) %>% hc_exporting(enabled = TRUE) ``` ## Per Base N Content ```{r} PBNC_df = data.frame() PBNC_file_paths = read.csv('PBNC_file_paths.txt', header = TRUE, stringsAsFactors = FALSE) for(i in 1:nrow(PBNC_file_paths)) { # file_path = paste0('REPORT_OUTPUT_DIR/', PBNC_file_paths[i,2]) file_path = PBNC_file_paths[i,2] pbnc_df = read.csv(file_path, sep='\t', header=TRUE, stringsAsFactors = FALSE) %>% mutate(Base1=as.numeric(str_split_fixed(X.Base, '-', 2)[,1]), Base2=as.numeric(str_split_fixed(X.Base, '-', 2)[,2])) %>% (function (df) { df1 = select(df, -Base2) df2 = select(df, -Base1) %>% filter(Base2 != '') colnames(df1) = c(colnames(df1)[1:2], 'Base') colnames(df2) = c(colnames(df2)[1:2], 'Base') res = rbind(df1, df2) %>% arrange(Base) return(res) }) pbnc_df$sample_id = rep(PBNC_file_paths[i,1], nrow(pbnc_df)) PBNC_df = rbind(PBNC_df, pbnc_df) } ``` ```{r} PBNC_df$N.Count = PBNC_df$N.Count * 100 max_phred = max(PBNC_df$N.Count) + 5 hchart(PBNC_df, "line", hcaes(x = as.character(Base), y = N.Count, group = sample_id)) %>% hc_title( text = "Per Base N Content" ) %>% hc_xAxis( title = list(text = "Base Position") ) %>% hc_yAxis( title = list(text = "N %"), plotLines = list( list(label = list(text = "N = 5%"), width = 2, dashStyle = "dash", color = "red", value = 5) ) ) %>% hc_exporting(enabled = TRUE) ``` ## Per Sequence Quality Scores ```{r} PSQS_df = data.frame() PSQS_file_paths = read.csv('PSQS_file_paths.txt', header = TRUE, stringsAsFactors = FALSE) for(i in 1:nrow(PSQS_file_paths)) { # file_path = paste0('REPORT_OUTPUT_DIR/', PSQS_file_paths[i,2]) file_path = PSQS_file_paths[i,2] psqs_df = read.csv(file_path, sep='\t', header=TRUE, stringsAsFactors = FALSE) psqs_df$sample_id = rep(PSQS_file_paths[i,1], nrow(psqs_df)) PSQS_df = rbind(PSQS_df, psqs_df) } ``` ```{r} max_phred = max(PSQS_df$X.Quality) + 5 hchart(PSQS_df, "line", hcaes(x = X.Quality, y = Count, group = sample_id)) %>% hc_title( text = "Per Sequence Quality Score" ) %>% hc_xAxis( title = list(text = "Mean Sequence Quality Score"), min = 0, max = max_phred, plotLines = list( list(label = list(text = "Phred Score = 27"), width = 2, dashStyle = "dash", color = "green", value = 27), list(label = list(text = "Phred Score = 20"), width = 2, color = "red", value = 20) ) ) %>% hc_exporting(enabled = TRUE) ``` ## Per Sequence GC Content ```{r} PSGC_df = data.frame() PSGC_file_paths = read.csv('PSGC_file_paths.txt', header = TRUE, stringsAsFactors = FALSE) for(i in 1:nrow(PSGC_file_paths)) { # file_path = paste0('REPORT_OUTPUT_DIR/', PSGC_file_paths[i,2]) file_path = PSGC_file_paths[i,2] psgc_df = read.csv(file_path, sep='\t', header=TRUE, stringsAsFactors = FALSE) psgc_df$sample_id = rep(PSGC_file_paths[i,1], nrow(psgc_df)) PSGC_df = rbind(PSGC_df, psgc_df) } ``` ```{r} max_phred = max(PSGC_df$Count) + 5 hchart(PSGC_df, "line", hcaes(x = X.GC.Content, y = Count, group = sample_id)) %>% hc_title( text = "Per Sequence GC Content" ) %>% hc_xAxis( title = list(text = "% GC") ) %>% hc_exporting(enabled = TRUE) ``` ## Per Base Sequence Content ```{r} PBSC_df = data.frame() PBSC_file_paths = read.csv('PBSC_file_paths.txt', header = TRUE, stringsAsFactors = FALSE) for(i in 1:nrow(PBSC_file_paths)) { # file_path = paste0('REPORT_OUTPUT_DIR/', PBSC_file_paths[i,2]) file_path = PBSC_file_paths[i,2] pbsc_df = read.csv(file_path, sep='\t', header=TRUE, stringsAsFactors = FALSE) %>% mutate(Base1=as.numeric(str_split_fixed(X.Base, '-', 2)[,1]), Base2=as.numeric(str_split_fixed(X.Base, '-', 2)[,2])) %>% (function (df) { df1 = select(df, -Base2) df2 = select(df, -Base1) %>% filter(Base2 != '') colnames(df1) = c(colnames(df1)[1:5], 'Base') colnames(df2) = c(colnames(df2)[1:5], 'Base') res = rbind(df1, df2) %>% arrange(Base) return(res) }) pbsc_df$sample_id = rep(PBSC_file_paths[i,1], nrow(pbsc_df)) PBSC_df = rbind(PBSC_df, pbsc_df) } ``` ```{r out.width="100%"} PBSC_df_2 = select(PBSC_df, -X.Base) %>% melt(id = c('Base', 'sample_id'), value.name = 'base_percentage') p = ggplot(data = PBSC_df_2, aes(x = Base, y = base_percentage, group = variable, color = variable)) + geom_line() + facet_wrap(~ sample_id) ggplotly(p) ``` ## References * Andrews, Simon. "FastQC: a quality control tool for high throughput sequence data." (2010): 175-176. * Goecks, Jeremy, Anton Nekrutenko, and James Taylor. "Galaxy: a comprehensive approach for supporting accessible, reproducible, and transparent computational research in the life sciences." Genome biology 11.8 (2010): R86. * Afgan, Enis, et al. "The Galaxy platform for accessible, reproducible and collaborative biomedical analyses: 2016 update." Nucleic acids research (2016): gkw343. * Highcharts. https://www.highcharts.com/. (access by May 26, 2017). * R Core Team (2017). R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL https://www.R-project.org/. * Joshua Kunst (2017). highcharter: A Wrapper for the 'Highcharts' Library. R package version 0.5.0. https://CRAN.R-project.org/package=highcharter * Carson Sievert, Chris Parmer, Toby Hocking, Scott Chamberlain, Karthik Ram, Marianne Corvellec and Pedro Despouy (2017). plotly: Create Interactive Web Graphics via 'plotly.js'. R package version 4.6.0. https://CRAN.R-project.org/package=plotly