Detect translated ORFs using ribosome-profiling data
RiboCode is a very simple but high-quality computational algorithm to identify genome-wide translated ORFs using ribosome-profiling data.
Dependencies:
- pysam
- pyfasta
- h5py
- Biopython
- Numpy
- Scipy
- statsmodels
- matplotlib
- HTSeq
- minepy
Installation
RiboCode can be installed like any other Python packages. Here are some popular ways:
- Install via pypi:
pip install ribocode- Install via conda:
conda install -c bioconda ribocode- Install from source:
git clone https://www.github.com/xzt41/RiboCode
cd RiboCode
python setup.py install- Install from local:
pip install RiboCode-*.tar.gzIf you have not administrator permission, you need to install RiboCode locally in you own directory by adding the
option --user in the above command. Then, you need to define ~/.local/bin/ in PATH variable,
and ~/.local/lib/ in PYTHONPATH variable. For example, if you are using the bash shell, you should add the following lines to your ~/.bashrc file:
export PATH=$PATH:$HOME/.local/bin/
export PYTHONPATH=$HOME/.local/lib/python2.7then, source your ~/.bashrc file using this command:
source ~/.bashrcUsers can also update or uninstall package through one of the following commands:
pip install --upgrade RiboCode # upgrade
pip uninstall RiboCode # uninstall
conda update -c bioconda ribocode # upgrade
conda remove ribocode # uninstallTutorial to analyze ribosome-profiling data and run RiboCode
Here, we use the HEK293 dataset as an example to illustrate the use of RiboCode and demonstrate typical workflow. Please make sure the path and file name are correct.
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Required files
The genome FASTA file, GTF file for annotation can be downloaded from:
or from:
http://asia.ensembl.org/info/data/ftp/index.html
http://useast.ensembl.org/info/data/ftp/index.html
For example, the required files in this tutorial can be downloaded from following URL:
GTF: ftp://ftp.sanger.ac.uk/pub/gencode/Gencode_human/release_19/gencode.v19.annotation.gtf.gz
FASTA: ftp://ftp.sanger.ac.uk/pub/gencode/Gencode_human/release_19/GRCh37.p13.genome.fa.gz
The GTF file required by RiboCode should include three-level hierarchy annotations: genes,transcripts and exons. Some GTF files may lack the gene and transcript annotations, users can added these annotations using the "GTFupdate" command in RiboCode. Please refer to GTF_update.rst for more information.
The raw Ribo-seq FASTQ file can be downloaded using fastq-dump tool from SRA_Toolkit:
fastq-dump -A <SRR1630831>
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Trimming adapter sequence for ribo-seq data
Using cutadapt program https://cutadapt.readthedocs.io/en/stable/installation.html
Example:
cutadapt -m 20 --match-read-wildcards -a (Adapter sequence) -o <Trimmed fastq file> <Input fastq file>
Here, the adapter sequences for this data had already been trimmed off, so we can skip this step.
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Removing ribosomal RNA(rRNA) derived reads
Removing rRNA contamination by aligning the trimmed reads to rRNA sequences using Bowtie, then keeping the unaligned reads for the next step.
rRNA sequences are provided in rRNA.fa file.
Example:
bowtie-build <rRNA.fa> rRNA bowtie -p 8 -norc --un <un_aligned.fastq> -q <SRR1630831.fastq> rRNA <HEK293_rRNA.align>
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Aligning the clean reads to reference genome
Using STAR program: https://github.com/alexdobin/STAR
Example:
(1). Build index
STAR --runThreadN 8 --runMode genomeGenerate --genomeDir <hg19_STARindex> --genomeFastaFiles <hg19_genome.fa> --sjdbGTFfile <gencode.v19.annotation.gtf>
(2). Alignment:
STAR --outFilterType BySJout --runThreadN 8 --outFilterMismatchNmax 2 --genomeDir <hg19_STARindex> --readFilesIn <un_aligned.fastq> --outFileNamePrefix <HEK293> --outSAMtype BAM SortedByCoordinate --quantMode TranscriptomeSAM GeneCounts --outFilterMultimapNmax 1 --outFilterMatchNmin 16 --alignEndsType EndToEnd
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Running RiboCode to identify translated ORFs
(1). Preparing the transcripts annotation files:
prepare_transcripts -g <gencode.v19.annotation.gtf> -f <hg19_genome.fa> -o <RiboCode_annot>
(2). Selecting the length range of the RPF reads and identify the P-site locations:
metaplots -a <RiboCode_annot> -r <HEK293Aligned.toTranscriptome.out.bam>
This step will generate two files: a PDF file plots the aggregate profiles of the distance from the 5'-end of reads to the annotated start codons (or stop codons), which is used for examining the P-site periodicity of RPF reads on CDS regions. The P-site config file, which defines the read lengths with strong 3-nt periodicity and the associated P-site locations for each length. In some cases, user may have multiple bam files to predict ORFs together in next step, they can use "-i" argument to specify a text file which contains the names of these bam files ( one file per line)
(3). Detecting translated ORFs using the ribosome-profiling data:
RiboCode -a <RiboCode_annot> -c <config.txt> -l no -g -o <RiboCode_ORFs_result>
Using the config file generated by last step to specify the information of the bam file and P-site parameters, please refer to the example file config.txt in data folder. The "gtf" or "bed" format file of predicted ORFs can be obtained by adding the "-g" or "-b" argument to this command.
Explanation of final result files
The RiboCode generates two text files: The "(output file name).txt" contains the information of all predicted ORFs in each transcript. The "(output file name)_collapsed.txt" file combines the ORFs having the same stop codon in different transcript isoforms: the one harboring the most upstream in-frame ATG will be kept.
Some column names of the result file:
- ORF_ID: The identifier of predicated ORF. - ORF_type: The type of predicted ORF, which is annotated according to its location to associated CDS. The following ORF categories are reported: "annotated" (overlapping with annotated CDS, have the same stop codon with annotated CDS) "uORF" (upstream of annotated CDS, not overlapping with annotated CDS) "dORF" (downstream of annotated CDS, not overlapping with annotated CDS) "Overlap_uORF" (upstream of annotated CDS and overlapping annotated with CDS) "Overlap_dORF" (downstream of annotated CDS and overlapping annotated CDS" "Internal" (internal ORF of annotated CDS, but in a different reading frame) "novel" (from non-coding genes or non-coding transcripts of the coding genes). - alt_ORF_type: only shown in "_collapsed.txt" file for reporting alternative annotations of each ORF based on its relative location in those transcripts other than the longest one - ORF_tstart, ORF_tstop: the start and end position of ORF relative to its transcript (1-based coordinate) - ORF_gstart, ORF_gstop: the start and end position of ORF in the genome (1-based coordinate) - pval_frame0_vs_frame1: significance levels of P-site densities of frame0 greater than of frame1 - pval_frame0_vs_frame2: significance levels of P-site densities of frame0 greater than of frame2 - pval_combined: integrated P-value by combining pval_frame0_vs_frame1 and pval_frame0_vs_frame2 - adjusted_pval: adjusted p-value for multiple testing correction.
All above three steps can also be easily run by a single command "RiboCode_onestep":
RiboCode_onestep -g <gencode.v19.annotation.gtf> -f <hg19_genome.fa> -r <HEK293Aligned.toTranscriptome.out.bam> -l no -o <RiboCode_ORFs_result>
(4). (optional) Plotting the P-sites densities of predicted ORFs
Using the "plot_orf_density" command, for example:
plot_orf_density -a <RiboCode_annot> -c <config.txt> -t (transcript_id) -s (ORF_gstart) -e (ORF_gstop)
The generated PDF plots can be edited by Adobe Illustrator.
(5). (optional) Counting the number of RPF reads aligned to ORFs
The number of reads aligned on each ORF can be counted by the "ORFcount" command which will call the HTSeq-count program. Only the reads of a given length will be counted. For those ORF with length longer than a specified value (set by "-e"), the RPF reads located in first few and last few codons can be excluded by adjusting the parameters "-f" and "-l". For example, the reads with length between 26-34 nt aligned on predicted ORF can be obtained by using below command:
ORFcount -g <RiboCode_ORFs_result.gtf> -r <ribo-seq genomic mapping file> -f 15 -l 5 -e 100 -m 26 -M 34 -o <ORF.counts>
The reads aligned to first 15 codons and last 5 codons of ORFs and had the length longer than 100 nt will be excluded. The "RiboCode_ORFs_result.gtf" file can be generated by RiboCode command. The "ribo-seq genomic mapping file" is the genome-wide mapping file produced by STAR mapping.
Recipes (FAQ):
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I have a BAM/SAM file aligned to genome, how do I convert it to transcriptome-based mapping file ?
You can use STAR aligner to generate the transcriptome-based alignment file by specifying the "--quantMode TranscriptomeSAM" parameters, or use the "sam-xlate" command from UNC Bioinformatics Utilities .
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How to use multiple BAM/SAM files to identify ORFs?
You can select the read lengths which show strong 3-nt periodicity and the corresponding P-site locations for each BAM/SAM file, then list each file and their information in config.txt file. RiboCode will combine the P-site densities at each nucleotides of these BAM/SAM files together to predict ORFs.
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Generating figures with matplotlib when DISPLAY variable is undefined or invalid
When running the "metaplots" or "plot_orf_density" command, some users received errors similar to the following:
raise RuntimeError('Invalid DISPLAY variable')_tkinter.TclError: no display name and no $DISPLAY environment variableThe main problem is that default backend of matplotlib is unavailable. The solution is to modify the backend in matplotlibrc file. A very simple solution is to set the MPLBACKEND environment variable, either for your current shell or for a single script:
export MPLBACKEND="module:Agg"
Giving below are non-interactive backends, capable of writing to a file:
Agg PS PDF SVG Cairo GDK
See also:
http://matplotlib.org/faq/usage_faq.html#what-is-a-backend
http://matplotlib.org/users/customizing.html#the-matplotlibrc-file
For any questions, please contact:
Xuerui Yang (yangxuerui[at]tsinghua.edu.cn); Zhengtao Xiao (zhengtao.xiao[at]xjtu.edu.cn)
