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miRPipe: Open source RNA-Seq bioinformatics analysis docker for identification of miRNAs and piRNAs

Graphical Abstract of miRPipe

Figure-1: In the pipeline flowchart, there are 9 steps. In synthetic data experiments, the last step (step-9: differential expression analysis) is not included. However in the CLL data experiments, we have included the last step where both treated and untreated samples are available.

Introduction

miRPipe is the integrated, user-friendly jupyter notebook based RNA-Seq bioinformatics analysis docker. The aim of this docker is to help researchers perform miRNA identification and piRNA identification independently and with much ease.

Project Structure

|----- CLL_results
          |----- diff_exp_miRNAs_expression_counts.csv
          |----- final_diff_exp_miRNAs.csv
          |----- miRNA_expression_counts.csv
          |----- piRNA_raw_counts.csv
          |----- significantly_DE_piRNA.csv
|----- LICENSE
|----- refs
         |----- pirnadb
                   |----- pirnadb.hg19.gff3.gz
                   |----- pirnadb.hg38.gff3.gz     
|----- scripts
         |----- adaptor_trimming.sh
         |----- fastq_split.sh
         |----- FastQC.R
         |----- install_packages.R
         |----- mirdeep_star.sh
         |----- norm_diff_exp.R
         |----- piRNA_pipeline.sh
|----- Dockerfile
|----- geckodriver
|----- geckodriver.log
|----- get-pip.py
|----- miRPipe_Flowchart.png
|----- miRPipe_pipeline.ipynb (complete pipeline)
|----- notebook.sh
|----- README.md
|----- requirements.txt
|----- Tutorial.md

Running the RNA-SEQ Pipeline

We have created a Docker image packaging all the dependencies (command line tools, R and Python packages) for the pipeline, which are publically available. To run the Docker image on your local machine, you need to pull the docker image.

It's very important to check the system requirements before installing the docker image.

System Requirements

Presently, this pipeline is tested only for the Linux OS.

LINUX Operating System:

System Requirements:

• 64bit, 8.00 GB RAM

• OS version used for this pipeline: Ubuntu 18.04.

Prerequisites

Things that needs to be install before running miRPipe.

a) docker

sudo apt-get update
sudo apt-get install docker-ce

Pull miRPipe docker image

After installing the docker, docker build is required to get the docker running.

To build, run the follwing command


docker pull docker.io/vivekruhela/mirpipe

Execution of docker

To run the docker with administration rights, run the following command at terminal.

docker run -p 8880:8888 -e 'PASSWORD=password' -e 'USE_HTTP=1' -v /host_path_to_data/:/miRPipe/data docker.io/vivekruhela/mirpipe

Explanation of execution step-

sudo docker run - Runs the docker with administrative rights.

-p 8880:8888 - Defines the port of the server and the port at which the docker will run.

-e 'PASSWORD=password' - Defines the password as "password", it can be changed as required by the user.

-e 'USE_HTTP=1' - To run in HTTP, we use USE_HTTP environment variable. Setting it to a non-zero value enables HTTP.

-v /host/path/to/data:/miRPipe/data - Mount the host folder which contains raw fastq sequence file to data folder of miRPipe docker

+ Example:

docker run -p 8880:8888 -e 'PASSWORD=password' -e 'USE_HTTP=1' -v /home/vivek/Small_fastq:/miRPipe/data vivekruhela/mirpipe

After successfully running the docker execution command, open firefox browser, and type the follwing in the URL:

localhost:8880/mirpipe

Jupyter Notebook environment will be opened in Firefox browser. Enter the PASSWORD mentioned in above command, by default it is set to- password.

Now you can run the miRPipe from mirpipe_pipeline.ipynb notebook.

Tutorial

We have also developed the tutorial Tutorial.md with screenshots to help users who are running this docker first time.

(A) Synthetic Data Experiments

For demonstration purpose, we are running these experiments only one time for each read depth category while in the figure-5 of the manuscript, we have shown the avaerge performance of mirPipe for 10 runs. The accuracy and F1-score of 1 run is close to the average accuracy and F1-score shown in the table-4 of the main manuscript.

Data Generation for Synthetic Data Experiments

We have used miRSim[1] tool to generate the synthetic data.

For the sake of completion, we have also provided the commands below for synthetic data generation using miRSim tool in case any user would like to generate synthatic data on their own.

- Data generation for 50K Read Depth Synthetic Data Experiments

+ Known miRNA synthetic data generation:

python miRSim.py -i refs/mature_high_conf_hsa.fa -n mirna2.fastq.gz -g mirna2.csv -gff refs/hsa_high_conf.gff3 -t 50000 -st 20 -s 10 -x 10 -b 5 -se 1008 -th 12 -dist uniform -d 20 -rna miRNA

+ Novel miRNA synthetic data generation:

python miRSim.py -i refs/final_novel_seq_filtered.fa -n novel_mirna2.fastq.gz -g novel_mirna2.csv -gff refs/novel_gff.gff3 -t 50000 -st 10 -s 7 -x 7 -b 3.5 -se 1008 -th 12 -rna novel_mirna -dist uniform -d 20

+ Known piRNA synthetic data generation:

python miRSim.py -i refs/piRNAdb.hsa.v1_7_5.fa -n pirna2.fastq.gz -g pirna2.csv -gff refs/pirnadb.hg38.gff3 -t 50000 -st 10 -s 7 -x 7 -b 3.5 -se 1008 -th 12 -rna piRNA -dist uniform -d 20

zcat mirna2.fastq.gz novel_mirna2.fastq.gz pirna2.fastq.gz | gzip > synthetic_data.fastq.gz
- Data generation for 0.1M Read Depth Synthetic Data Experiments

+ Known miRNA synthetic data generation:

python miRSim.py -i refs/mature_high_conf_hsa.fa -n mirna2.fastq.gz -g mirna2.csv -gff refs/hsa_high_conf.gff3 -t 100000 -st 20 -s 10 -x 10 -b 5 -se 108 -th 12 -dist uniform -d 20 -rna miRNA

+ Novel miRNA synthetic data generation:

python miRSim.py -i refs/final_novel_seq_filtered.fa -n novel_mirna2.fastq.gz -g novel_mirna2.csv -gff refs/novel_gff.gff3 -t 100000 -st 10 -s 7 -x 7 -b 3.5 -se 108 -th 12 -rna novel_mirna -dist uniform -d 20

+ Known piRNA synthetic data generation:

python miRSim.py -i refs/piRNAdb.hsa.v1_7_5.fa -n pirna2.fastq.gz -g pirna2.csv -gff refs/pirnadb.hg38.gff3 -t 100000 -st 10 -s 7 -x 7 -b 3.5 -se 108 -th 12 -rna piRNA -dist uniform -d 20


zcat mirna2.fastq.gz novel_mirna2.fastq.gz pirna2.fastq.gz | gzip > synthetic_data.fastq.gz
- Data generation for 1M Read Depth Synthetic Data Experiments

+ Known miRNA synthetic data generation:

python miRSim.py -i refs/mature_high_conf_hsa.fa -n mirna2.fastq.gz -g mirna2.csv -gff refs/hsa_high_conf.gff3 -t 1000000 -st 20 -s 10 -x 10 -b 5 -se 999 -th 12 -dist uniform -d 50 -rna miRNA

+ Novel miRNA synthetic data generation:

python miRSim.py -i refs/final_novel_seq_filtered.fa -n novel_mirna2.fastq.gz -g novel_mirna2.csv -gff refs/novel_gff.gff3 -t 1000000 -st 10 -s 7 -x 7 -b 3.5 -se 999 -th 12 -rna novel_mirna -dist uniform -d 50

+ Known piRNA synthetic data generation:

python miRSim.py -i refs/piRNAdb.hsa.v1_7_5.fa -n pirna2.fastq.gz -g pirna2.csv -gff refs/pirnadb.hg38.gff3 -t 1000000 -st 10 -s 7 -x 7 -b 3.5 -se 999 -th 12 -rna piRNA -dist uniform -d 50


zcat mirna2.fastq.gz novel_mirna2.fastq.gz pirna2.fastq.gz | gzip > synthetic_data.fastq.gz

The miRPipe pipeline performance for 1 run of synthetic data experiments are as follows:

(A) 50K Read Depth (B) 0.1M Read Depth (C) 1M Read Depth

(B) CLL Data Experiments

All the results shown in table-5 and table-6 are generated using miRPipe for the datasets taken from GEO repository GSE123436 [2].

Since the dataset is very huge, to demonstrate the working of miRPipe we have prepared a small subset of treated and untreated samples from the GSE123436 CLL datasets (snapshot shown below). The prepared file sample_list.csv in the data directory in the following format:

sample           file          condition
Sample_A   Sample_A.fastq.gz    treated
Sample_B   Sample_B.fastq.gz    treated
Sample_C   Sample_C.fastq.gz    treated
   .              .                .
   .              .                .
   .              .                .

Please note that, in sample_list.csv, it is absolutely a must to sort all the sample name alphanumerically. This is necessary because the final count file generated at the end of pipeline (and before differential expression analysis) have all the columns sorted in alpha-numerically ascending order. The order of columns in final count matrix generated in the end of pipeline and order in samples in sample_list.csv must be same in order to conduct correct differential expression analysis. The example screenshot sample_list.csv file for CLL data is shown below:

Screenshot for Sample_list csv file

Output Files

The miRPipe pipeline generates total 5 output files in the output directory:

  1. final_diff_exp_miRNAs.csv : This file contains the list of significantly differentially expressed miRNAs along with fold change, new names (in case of novel miRNAs), adjusted p-value, and their genomic locations.

  2. diff_exp_miRNAs_expression_counts.csv : This file contains expression counts of significantly differentially expressed miRNAs.

  3. miRNA_expression_counts.csv : This file contains the raw expression counts of miRNAs in all samples before differential expression analysis.

  4. piRNA_raw_counts.csv : This file contains raw counts of all piRNAs ontained from all samples before differential expression analysis.

  5. significantly_DE_piRNA.csv : This file contains the list of all significantly differentially expressed piRNAs.

Citation

If you use miRPipe for your research, please cite the following paper:

Ruhela, V., Gupta, A., Krishnamachari, S., Ahuja, G., Kaur, G. and Gupta, R., miRPipe: A Unified Computational Framework for a Robust, Reliable, and Reproducible Identification of Novel miRNAs from the RNA Sequencing Data. Frontiers in Bioinformatics, p.71. DOI: https://doi.org/10.3389/fbinf.2022.842051

References

  1. Ruhela, V., Gupta, R., Krishnamachari, S., Ahuja, G., Gupta, A.:vivekruhela/miRSim v1.0.0 (Version v1.0.0). Zenodo (2021)
  2. Kaur, Gurvinder, et al. "RNA-Seq profiling of deregulated miRs in CLL and their impact on clinical outcome." Blood cancer journal 10.1 (2020): 1-9.

8. License

See the LICENSE file for license rights and limitations (Apache2.0).

9. Acknowledgements

  1. Authors would like to gratefully acknowledge the grant from Department of Biotechnology, Govt. of India [Grant: BT/MED/30/SP11006/2015] and Department of Science and Technology, Govt. of India [Grant: DST/ICPS/CPS-Individual/2018/279(G)].

  2. Authors would like to gratefully acknowledge the support of SBILab, Deptt. of ECE & Centre of Excellence in Healthcare, Indraprastha Institute of Information Technology-Delhi (IIIT-D), India for providing guidance in tool methology and development.

  3. Authors would like to gratefully acknowledge the support of Computational Biology Dept., Indraprastha Institute of Information Technology-Delhi (IIIT-D), India for providing resources for tool development.