---

RNAflow - An effective and simple RNA-Seq differential gene expression pipeline using Nextflow

Figure 1. Workflow. The user can decide after preprocessing to run a differential gene expression (DEG) analysis or a transcriptome assembly. Circles symbolize input data and download icons symbolize automated download of resources. Steps marked by asterisks are currently only available for some species. See here for a list of references for the used tools and please consider to cite them as well.

Table of Contents

• Quick installation
• Quick start
  • Start a test run
  • Call help
  • Update the pipeline
  • Use a certain release
• Usage
  • Input files
    • Read files (required)
    • Genomes and annotation
    • Build-in species
    • Comparisons for DEG analysis
  • Resume your run
• Workflow control
  • Preprocessing
  • DEG analysis
  • Transcriptome assembly
• Profiles/configuration options
  • Executor options...
  • Engine options...
• Monitoring
• Output
  • DESeq2 results
• Working offline
• Help message
• Known bugs and issues
  • [Problems with SortMeRNA/ HISAT2 error (#141, #116)](#problems-with-sortmerna-hisat2-error-141-116)
    • Description
    • Workaround
  • Latency problems on HPCs, issue (#79)
    • Description
    • Workaround
• Citation

Quick installation

The pipeline is written in Nextflow, which can be used on any POSIX compatible system (Linux, OS X, etc). Windows system is supported through WSL. You need Nextflow installed and either conda, Docker, or Singularity to run the steps of the pipeline:

1. Install Nextflow

   click here for a bash one-liner

   wget -qO- https://get.nextflow.io | bash
   # In the case you don’t have wget
   # curl -s https://get.nextflow.io | bash

2. Install conda

   click here for a bash two-liner for Miniconda3 Linux 64-bit

   wget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh
   bash Miniconda3-latest-Linux-x86_64.sh

OR

1. Install conda

   click here for a bash two-liner for Miniconda3 Linux 64-bit

   wget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh
   bash Miniconda3-latest-Linux-x86_64.sh

2. Install Nextflow via conda

   click here to see how to do that

   conda create -n nextflow -c bioconda nextflow
   conda active nextflow

For transcriptome assembly you have to install also Docker or Singularity.

1. You can try to simply install Singularity via conda as well

   click for an example command

   conda create -n singularity -c conda-forge singularity
   conda active singularity

   or if you already have a conda environment for nextflow:

   conda activate nextflow
   conda install -c conda-forge singularity

A system admin-configured Singularity installation should be preferred in comparison to an own local conda installation. Please ask your sys admin!

All other dependencies and tools will be installed within the pipeline via conda, Docker or Singularity depending on the profile you run (see below).

Quick start

Start a test run

# conda active nextflow
nextflow run hoelzer-lab/rnaflow -profile test,conda,local

... performs

• a differential gene expression analysis with sub-sampled human read data,
• on a reduced human genome and annotation (chromosome 1, 10 and 11),
• comparing two conditions (MAQCA, MAQCB),
• with a local execution (uses max. 4 cores in total and 8GB) and
• conda dependency management.

Resource usage

For a local test run (with 30 cores in total at maximum):

nextflow run hoelzer-lab/rnaflow -profile test,conda,local -w work \
--max_cores 30 --cores 10 --softlink_results -r master

we observed the following resource usage including downloads and conda environment creation for each process:

Total runtime

25m 56s

Physical memory (RAM), max.

3.015 GB at process hisat2index

Virtual memory (RAM + Disk swap), max.

10.16 GB at process hisat2

A detailed HTML report automatically produced the pipeline can be found here.

Call help

nextflow run hoelzer-lab/rnaflow --help

Update the pipeline

nextflow pull hoelzer-lab/rnaflow

Use a certain release

We recommend to use a stable release of the pipeline:

nextflow pull hoelzer-lab/rnaflow -r <RELEASE>

Usage

nextflow run hoelzer-lab/rnaflow --reads input.csv --autodownload hsa --pathway hsa --max_cores 6 --cores 2

with --autodownload <hsa|mmu|ssc|mau|eco> build-in species, or define your own genome reference and annotation files in CSV files:

nextflow run hoelzer-lab/rnaflow --reads input.csv --genome fastas.csv --annotation gtfs.csv --max_cores 6 --cores 2

Genomes and annotations from --autodownload, --genome and --annotation are concatenated.

By default, all possible comparisons are performed. Use --deg to change this.

--pathway <hsa|mmu|mau|ssc> performs downstream pathway analysis. Available are WebGestalt set enrichment analysis (GSEA) for hsa, mmu and ssc, piano GSEA with different settings and consensus scoring for hsa, mmu, mau, and ssc.

Input files

Read files (required)

Specify your read files in FASTQ format with --reads input.csv. The file input.csv has to look like this for single-end reads:

Sample,R1,R2,Condition,Source,Strandedness
mock_rep1,/path/to/reads/mock1.fastq.gz,,mock,,0
mock_rep2,/path/to/reads/mock2.fastq.gz,,mock,,0
mock_rep3,/path/to/reads/mock3.fastq.gz,,mock,,0
treated_rep1,/path/to/reads/treat1.fastq.gz,,treated,,0
treated_rep2,/path/to/reads/treat2.fastq.gz,,treated,,0
treated_rep3,/path/to/reads/treat3.fastq.gz,,treated,,0

and for paired-end reads, like this:

Sample,R1,R2,Condition,Source,Strandedness
mock_rep1,/path/to/reads/mock1_1.fastq,/path/to/reads/mock1_2.fastq,mock,A,0
mock_rep2,/path/to/reads/mock2_1.fastq,/path/to/reads/mock2_2.fastq,mock,B,0
mock_rep3,/path/to/reads/mock3_1.fastq,/path/to/reads/mock3_2.fastq,mock,C,0
treated_rep1,/path/to/reads/treat1_1.fastq,/path/to/reads/treat1_2.fastq,treated,A,0
treated_rep2,/path/to/reads/treat2_1.fastq,/path/to/reads/treat2_2.fastq,treated,B,0
treated_rep3,/path/to/reads/treat3_1.fastq,/path/to/reads/treat3_2.fastq,treated,C,0

The first line is a required header. Read files can be compressed (.gz). You need at least two replicates for each condition to run the pipeline. Source labels are optional - the header is still required, the value can be empty as in the single-end example above. Source labels can be used to define the corresponding experiment even more precisely for improved differential expression testing, e.g. if RNA-Seq samples come from different Conditions (e.g. tissues) but the same Sources (e.g. patients). Still, the comparison will be performed between the Conditions but the Source information is additionally used in designing the DESeq2 experiment. Source labels also extend the heatmap sample annotation. Strandedness for the samples can optionally be defined directly in the csv or via the commandline parameter --strand. Where the strandedness column can be any value from: 0 = unstranded, 1 = stranded, 2 = reversely stranded, [default: 0]. Note that if strandedness is provided via the input CSV and the commandline parameter, the value from the command line will be used for the run.

Genomes and annotation

If you don't use one of the build-in species, specify your genomes via --genome fastas.csv, with fastas.csv looking like this:

/path/to/reference_genome1.fasta
/path/to/reference_genome2.fasta

and --annotation gtfs.csv with gtfs.csv looking like this:

/path/to/reference_annotation_1.gtf
/path/to/reference_annotation_2.gtf

You can add a build-in species to your defined genomes and annotation with --autodownload xxx.

Build-in species

We provide a small set of build-in species for which the genome and annotation files are automatically downloaded from Ensembl with --autodownload xxx. Please let us know, we can easily add other species.

Species	three-letter shortcut	Annotation	Genome
Homo sapiens	hsa *	Homo_sapiens.GRCh38.98	Homo_sapiens.GRCh38.dna.primary_assembly
Mus musculus	mmu *	Mus_musculus.GRCm38.99	Mus_musculus.GRCm38.dna.primary_assembly
Sus scrofa	ssc *	Sus_scrofa.Sscrofa11.1.111	Sus_scrofa.Sscrofa11.1.dna.toplevel
Mesocricetus auratus	mau *	Mesocricetus_auratus.MesAur1.0.100	Mesocricetus_auratus.MesAur1.0.dna.toplevel
Escherichia coli	eco	Escherichia_coli_k_12.ASM80076v1.45	Escherichia_coli_k_12.ASM80076v1.dna.toplevel

^* Downstream pathway analysis availible via --pathway xxx.

Multiple-mapped reads

To adjust the handling of multiple-mapped reads during the feature counting process you can use: --featurecounts_additional_params '-t exon -g gene_id -M' The default handling is to only count uniquely mapped reads via featureCounts. With the above flag set featureCounts will also count multi-mapped reads.

Comparisons for DEG analysis

Per default, all possible pairwise comparisons in one direction are performed. Thus, when A is compared against B the pipeline will not automatically compare B vs. A which will anyway only change the direction of the finally resulting fold changes. To change this, please define the needed comparison with --deg comparisons.csv, where each line contains a pairwise comparison:

Condition1,Condition2
conditionX,conditionY
conditionA,conditionB
conditionB,conditionA

The first line is a required header.

Resume your run

You can easily resume your run in case of changes to the parameters or inputs. Nextflow will try to not recalculate steps that are already done:

nextflow run hoelzer-lab/rnaflow -profile test,conda,local -resume

Nextflow will need access to the working directory where temporary calculations are stored. Per default, this is set to work but can be adjusted via -w /path/to/any/workdir. In addition, the .nextflow.log file is needed to resume a run, thus, this will only work if you resume the run from the same folder where you started it.

Workflow control

Preprocessing

--skip_sortmerna                       # skip rRNA removal via SortMeRNA [default false]
--skip_read_preprocessing              # skip preprocessing with fastp [default: false]
--fastp_additional_params              # additional parameters for fastp [default '-5 -3 -W 4 -M 20 -l 15 -x -n 5 -z 6']
--hisat2_additional_params             # additional parameters for HISAT2
--featurecounts_additional_params      # additional parameters for FeatureCounts [default: -t gene -g gene_id]

DEG analysis

--strand                        # strandness for counting with featureCounts: 0 (unstranded), 1 (stranded) and 2 (reversely stranded) [default 0]
--tpm                           # threshold for TPM (transcripts per million) filter [default 1]
--deg                           # a CSV file following the pattern: conditionX,conditionY
--pathway                       # perform different downstream pathway analysis for the species hsa|mmu|mau|ssc
--feature_id_type               # ID type for downstream analysis [default: ensembl_gene_id]

Transcriptome assembly

--assembly                      # switch to transcriptome assembly
--busco_db                      # BUSCO database ['euarchontoglires' or path to existing DB]
--dammit_uniref90               # add UniRef90 to dammit databases, takes long [false]
--rna                           # activate directRNA mode for ONT transcriptome assembly [default: false (cDNA)]

Profiles/configuration options

Per default, the pipeline is locally executed with conda dependency management (corresponds to -profile local,conda). Adjust this setting by combining an executer option with an engine option, e.g. -profile local,conda or -profile slurm,conda. We also provide container support, see below.

Executor options...

... or how to schedule your workload.

Currently implemented are local, slurm and lsf executions.

You can customize local with this parameters:

--cores                         # cores for one process [default 1]
--max_cores                     # max. cores used in total [default allAvailable]
--memory                        # max. memory in GB for local use [default 8 GB]

Engine options...

... or in which environment to run the tools.

Currently implemented are conda, Docker and Singularity. For transcriptome assembly some tools need to be run with Docker or Singularity.

You can switch between different engines via -profile, for example:

nextflow run hoelzer-lab/rnaflow -profile test,local,conda
nextflow run hoelzer-lab/rnaflow -profile test,local,docker
nextflow run hoelzer-lab/rnaflow -profile test,slurm,singularity

As a best practice for a local execution, we recommend to run the pipeline with --cores 1 --max_cores 1 the first time you use Singularity, because we experienced issues when generating the Singularity images in parallel the first time the pipeline is executed with this engine option. It is also possible to run the pipeline once with --setup set. In setup mode all the necessary files (DBs, reference files and images) are being downloaded and set up.

You can customize where conda environments are stored using

--condaCacheDir /path/to/dir

and where Singularity images are stored via

--singularityCacheDir /path/to/dir

Docker images are stored based on your system configuration.

Monitoring

To monitor your computations the pipeline can be connected to Nextflow Tower. You need an user access token to connect your Tower account with the pipeline. Simply generate a login using your email and then click the link send to this address.

"Nextflow Tower does not require a password or registration procedure. Just provide your email address and we'll send you an authentication link to login. That's all!"

Once logged in, click on your avatar on the top right corner and select "Your tokens". Generate a token or copy the default one and set the environment variable:

export TOWER_ACCESS_TOKEN=<YOUR_COPIED_TOKEN>
export NXF_VER=20.10.0

You can save this command to your .bashrc or .profile to not need to enter it again.

Now run:

nextflow run hoelzer-lab/rnaflow -profile test,local,conda -with-tower

Alternatively, you can also activate the Tower connection within the nextflow.config file located in the root GitHub directory:

tower {
    accessToken = ''
    enabled = true
} 

You can also directly enter your access token here instead of generating the above environment variable.

Output

The result folder is structured by each step and tool (results/step/tool) as follows:

results/
├── 01-Trimming
│   └── fastp                   trimmed reads
├── 02-rRNARemoval
│   └── SortMeRNA               rRNA-free (and trimmed) reads
├── 03-Mapping
│   └── HISAT2                  mapping results in BAM format with index files (BAI)
├── 04-Counting
│   └── featureCounts           counting table
├── 05-CountingFilter
│   └── TPM                     counting table with additional TPM value; formatted counting table filtered by TPM
├── 06-Annotation               filtered annotation; gene id, name and bio type mapping
├── 07-DifferentialExpression
│   └── DESeq2                  see below
├── 08-Assembly
│   └── de_novo
│      └── Trinity              Trinity assembly  (with --assembly)
├── 09-RNA-Seq_Annotation       BUSCO, dammit and StringTie2 results (with --assembly)
├── Logs                        Nextflow execution timeline and workflow report
└── Summary                     MultiQC report

Please note, that 08-Assembly and 09-RNA-Seq_Annotation are part of the transcriptome assembly branch (--assembly). Here, steps 04 to 07 are currently not applicable.

DESeq2 results

The DESeq2 result is structured as follows:

07-DifferentialExpression/
└── DESeq2
   ├── data                         
   │   ├── counts                   normalized, transformed counts; size factors table
   │   └── input                    DESeq2 input summary
   ├── deseq2.Rout                  R log file
   ├── MAQCA_vs_MAQCB               results for pairwise comparison (here exemplarily for the -profile test data set)
   │   ├── downstream_analysis  
   │   │   ├── piano                piano results
   │   │   └── WebGestalt           WebGestalt results
   │   ├── input                    DESeq2 input summary
   │   ├── plots
   │   │   ├── heatmaps
   │   │   ├── MA
   │   │   ├── PCA
   │   │   ├── sample2sample
   │   │   └── volcano
   │   ├── reports                  DESeq2 result HTML table; summary report
   │   └── results                  raw and filtered DESeq2 result in CSV and XLSX format; DEG analysis summary
   └── plots                        heatmaps and PCA of all samples

We provide DESeq2 normalized, regularized log (rlog), variance stabilized (vsd) and log2(n+1) (ntd) transformed count tables (DESeq2/data/counts).

For each comparison (specified with --deg or, per default, all possible pairwise comparisons in one direction), a new folder X_vs_Y is created. This also describes the direction of the comparison, e.g., the log2FoldChange describes the change of a gene A under condition Y with respect to the gene under condition X. For example, a log2FoldChange of +2 for gene A would tell you that this gene is 2-fold upregulated when we compare condition X vs. condition Y. The gene A is higher expressed in samples belonging to condition X.

Downstream analysis (--pathway xxx) are currently provided for some species: GSEA consensus scoring with piano for Homo sapiens (hsa), Mus musculus (mmu), Mesocricetus auratus (mau), and Sus scofa (ssc); and WebGestalt GSEA for Homo sapiens, Mus musculus, and Sus scrofa.

Working offline

In case you don't have an internet connection, here is a workaround to this issue for manual download and copying of external recourses:

• Genomes and annotation can also be specified via --genome and --annotation, see here.
• For BUSCO it is a simple download, see here with busco_db = 'euarchontoglires_odb9' as default.
• For SortMeRNA and dammit the tools must be installed. Version specifications can be found here and there, the code to create the databases here and there with busco_db = 'euarchontoglires_odb9' dammit_uniref90 = false as default.
• Downstream analysis with piano and WebGestalt currently need an internet connection in any case. If no connection is available piano and WebGestalt are skipped.

RNAflow looks up the files here:

nextflow-autodownload-databases     # default: `permanentCacheDir = 'nextflow-autodownload-databases'`
└── databases
    └── busco
        └── <busco_db>.tar.gz
    └── dammit
        └── <busco_db>.tar.gz
        └── uniref90                # in case of `dammit_uniref90 = true`
            └── <busco_db>.tar.gz
    └── sortmerna
        └── data
            └── rRNA_databases

Help message

click here to see the complete help message

Usage examples:
nextflow run hoelzer-lab/rnaflow -profile test,local,conda
nextflow run hoelzer-lab/rnaflow --cores 4 --reads input.csv --autodownload mmu --pathway mmu
nextflow run hoelzer-lab/rnaflow --cores 4 --reads input.csv --autodownload eco --assembly
nextflow run hoelzer-lab/rnaflow --cores 4 --reads input.csv --genome fasta_virus.csv --annotation gtf_virus.csv --autodownload hsa --pathway hsa
Genomes and annotations from --autodownload, --genome and --annotation are concatenated.

Input:
--reads                  A CSV file following the pattern: Sample,R1,R2,Condition,Source,Strandedness - read mode is detected automatically
                                    (check terminal output if correctly assigned)
                                    Per default, all possible comparisons of conditions in one direction are made. Use --deg to change.
--autodownload           Specifies the species identifier for automated download [default: ]
                                    Currently supported are:
                                    - hsa [Ensembl: Homo_sapiens.GRCh38.dna.primary_assembly | Homo_sapiens.GRCh38.98]
                                    - eco [Ensembl: Escherichia_coli_k_12.ASM80076v1.dna.toplevel | Escherichia_coli_k_12.ASM80076v1.45]
                                    - mmu [Ensembl: Mus_musculus.GRCm38.dna.primary_assembly | Mus_musculus.GRCm38.99.gtf]
                                    - ssc [Ensembl: Sus_scrofa.Sscrofa11.1.dna.toplevel | Sus_scrofa.Sscrofa11.1.111 ]
                                    - mau [Ensembl: Mesocricetus_auratus.MesAur1.0.dna.toplevel | Mesocricetus_auratus.MesAur1.0.100]
--species                Specifies the species identifier for downstream path analysis. (DEPRECATED)
                         If `--include_species` is set, reference genome and annotation are added and automatically downloaded. [default: ]
                                    Currently supported are:
                                    - hsa [Ensembl: Homo_sapiens.GRCh38.dna.primary_assembly | Homo_sapiens.GRCh38.98]
                                    - eco [Ensembl: Escherichia_coli_k_12.ASM80076v1.dna.toplevel | Escherichia_coli_k_12.ASM80076v1.45]
                                    - mmu [Ensembl: Mus_musculus.GRCm38.dna.primary_assembly | Mus_musculus.GRCm38.99.gtf]
                                    - mau [Ensembl: Mesocricetus_auratus.MesAur1.0.dna.toplevel | Mesocricetus_auratus.MesAur1.0.100]
--genome                 CSV file with genome reference FASTA files (one path in each line)
                                    If set, --annotation must also be set.
--annotation             CSV file with genome annotation GTF files (one path in each line)
--include_species        Either --species or --genome/--annotation need to be used. Both input seetings can be also combined to use genome and annotation of 
                         supported species in addition to --genome and --annotation [default: false]

Preprocessing options:
--fastp_additional_params          additional parameters for fastp [default: -5 -3 -W 4 -M 20 -l 15 -x -n 5 -z 6]
--skip_sortmerna                   skip rRNA removal via SortMeRNA [default: false] 
--skip_read_preprocessing          skip preprocessing with fastp [default: false]
--hisat2_additional_params         additional parameters for HISAT2 [default: ]
--featurecounts_additional_params  additional parameters for FeatureCounts [default: -t gene -g gene_id]

DEG analysis options:
--strand                 0 (unstranded), 1 (stranded) and 2 (reversely stranded) [default: 0]
                         This will overwrite the optional strandedness defined in the input CSV file.
--tpm                    Threshold for TPM (transcripts per million) filter. A feature is discared, if for all conditions the mean TPM value of all 
                         corresponding samples in this condition is below the threshold. [default: 1]
--deg                    A CSV file following the pattern: conditionX,conditionY
                         Each line stands for one differential gene expression comparison.  
                         Must match the 'Condition' labels defined in the CSV file provided via --reads.  
--pathway                Perform different downstream pathway analysis for the species. [default: ]
                         Currently supported are:
                             - hsa | Homo sapiens
                             - mmu | Mus musculus
                             - mau | Mesocricetus auratus
                             - ssc | Sus scrofa
--feature_id_type        ID type for downstream analysis [default: ensembl_gene_id]                            

Transcriptome assembly options:
--assembly               Perform de novo and reference-based transcriptome assembly instead of DEG analysis [default: false]
--busco_db               The database used with BUSCO [default: euarchontoglires_odb9]
                         Full list of available data sets at https://busco-data.ezlab.org/v5/data/lineages/ 
--dammit_uniref90        Add UniRef90 to the dammit databases (time consuming!) [default: false]
--rna                    Activate directRNA mode for ONT transcriptome assembly [default: false (cDNA)]

Computing options:
--cores                  Max cores per process for local use [default: 1]
--max_cores              Max cores used on the machine for local use [default: 4]
--memory                 Max memory in GB for local use [default: 8 GB]
--output                 Name of the result folder [default: results]

Caching:
--permanentCacheDir      Location for auto-download data like databases [default: nextflow-autodownload-databases]
--condaCacheDir          Location for storing the conda environments [default: conda]
--singularityCacheDir    Location for storing the singularity images [default: singularity]
--workdir                Working directory for all intermediate results [default: null] (DEPRECATED: use `-w your/workdir` instead)
--softlink_results       Softlink result files instead of copying.
--setup                  Download all necessary DB, reference and image files without running the pipeline. [default: false]

Nextflow options:
-with-tower              Activate monitoring via Nextflow Tower (needs TOWER_ACCESS_TOKEN set).
-with-report rep.html    CPU / RAM usage (may cause errors).
-with-dag chart.html     Generates a flowchart for the process tree.
-with-timeline time.html Timeline (may cause errors).

Execution/Engine profiles:
The pipeline supports profiles to run via different Executers and Engines e.g.: -profile local,conda

Executer (choose one):
  local
  slurm
  lsf
  latency

Engines (choose one):
  conda
  mamba
  docker
  singularity

Per default: -profile local,conda is executed. 

For a test run (~ 15 min), add "test" to the profile, e.g. -profile test,local,conda.
The command will create all conda environments and download and run test data.

We also provide some pre-configured profiles for certain HPC environments:    
  ara (slurm, conda and parameter customization)

Known bugs and issues

Problems with SortMeRNA/ HISAT2 error (#141, #116)

Description

The pipeline fails with something like

this

Error executing process > 'preprocess:hisat2 (2)'

Caused by:
  Missing output file(s) `22_rep4_summary.log` expected by process `preprocess:hisat2 (2)`

Command executed:

  hisat2 -x reference -1 22_rep4.R1.other.fastq.gz -2 22_rep4.R2.other.fastq.gz -p 60 --new-summary --summary-file 22_rep4_summary.log  | samtools view -bS | samtools sort -o 22_rep4.sorted.bam -T tmp --threads 60

Command exit status:
  0

Command output:
  (empty)

Command error:
  Error: Read AFFFJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJJ has more quality values than read characters.
  terminate called after throwing an instance of 'int'
  Aborted (core dumped)
  (ERR): hisat2-align exited with value 134
  [bam_sort_core] merging from 0 files and 60 in-memory blocks...
  grep: warning: GREP_OPTIONS is deprecated; please use an alias or script
  
Work dir:
  /tmp/nextflow-work-as11798/2f/4a5b7060530705c2697bdf3eec73a4

Tip: when you have fixed the problem you can continue the execution adding the option `-resume` to the run command line

• Often encountered when running in screen or tmux
• Nextflow's -bg option does not help

Workaround

• Skip SortMeRNA with --skip_sortmerna
• Reads can be cleand beforhand e.g. with CLEAN

Latency problems on HPCs, issue (#79)

Description

Latency related problems with Nextflow might occur when running on HPC systems, where Nextflow expects files to be available before they are fully written to the file system. In these cases Nextflow might get stuck or report missing output or input files to some processes:

ERROR ~ Error executing process > 'some_process'

Caused by:
 Missing output file(s) `some_process.out` expected by process `some_process`

• Often encountered when running on HPC systems

Workaround

Please try running the pipeline with the latency profile activated, just add it to the profiles you already defined:

-profile slurm,conda,latency

Citation

If you use RNAflow please cite:

• RNAflow

Marie Lataretu and Martin Hölzer. "RNAflow: An effective and simple RNA-Seq differential gene expression pipeline using Nextflow". Genes 2020, 11(12), 1487; https://doi.org/10.3390/genes11121487