BGCFlow is a systematic workflow for the analysis of biosynthetic gene clusters across large collections of genomes (pangenomes) from internal & public datasets.
At present, BGCFlow is only tested and confirmed to work on Linux systems with conda / mamba package manager.
Matin Nuhamunada, Omkar S Mohite, Patrick V Phaneuf, Bernhard O Palsson, Tilmann Weber, BGCFlow: systematic pangenome workflow for the analysis of biosynthetic gene clusters across large genomic datasets, Nucleic Acids Research, 2024;, gkae314, https://doi.org/10.1093/nar/gkae314
BGCFlow requires gcc and the conda/mamba package manager. See installation instruction for details.
Please use the latest version of BGCFlow available.
A quick and easy way to use BGCFlow using the command line interface wrapper:
- Create a conda environment and install the
BGCFlowpython wrapper :
# create and activate a new conda environment
mamba create -n bgcflow -c conda-forge python=3.11 pip openjdk -y # also install java for metabase
conda activate bgcflow
# install `BGCFlow` wrapper
pip install bgcflow_wrapper
# make sure to use bgcflow_wrapper version >= 0.2.7
bgcflow --version- Additional pre-requisites: With the environment activated, install or setup this configurations:
- Set
condachannel priorities toflexible
conda config --set channel_priority disabled
conda config --describe channel_priority- Deploy and run BGCFlow, change
your_bgcflow_directoryvariable accordingly:
# Deploy and run BGCFlow
bgcflow clone bgcflow # clone `BGCFlow` a directory named bgcflow
cd bgcflow # move to bgcflow directory
bgcflow init # initiate `BGCFlow` config and examples from template
bgcflow run -n # do a dry run, remove the flag "-n" to run the example dataset-
Build and serve interactive report (after
bgcflow runfinished). The report will be served in http://localhost:8001/. A demo of the report is available here:
# build a report
bgcflow build report
# show available projects
bgcflow serve
# serve interactive report
bgcflow serve --project Lactobacillus_delbrueckii-
For detailed usage and configurations, have a look at the WIKI:
-
Read more about
bgcflow_wrapperfor a detailed overview of the command line interface.
The main Snakefile workflow comprises various pipelines for data selection, functional annotation, phylogenetic analysis, genome mining, and comparative genomics for Prokaryotic datasets.
Available pipelines in the main Snakefile can be checked using the following command:
bgcflow pipelinesHere you can find pipeline keywords that you can run using the main Snakefile of BGCflow.
| Keyword | Description | Links | |
|---|---|---|---|
| 0 | eggnog | Annotate samples with eggNOG database (http://eggnog5.embl.de) | eggnog-mapper |
| 1 | mash | Calculate distance estimation for all samples using MinHash. | Mash |
| 2 | fastani | Do pairwise Average Nucleotide Identity (ANI) calculation across all samples. | FastANI |
| 3 | automlst-wrapper | Simplified Tree building using autoMLST | automlst-simplified-wrapper |
| 4 | roary | Build pangenome using Roary. | Roary |
| 5 | eggnog-roary | Annotate Roary output using eggNOG mapper | eggnog-mapper |
| 6 | seqfu | Calculate sequence statistics using SeqFu. | seqfu2 |
| 7 | bigslice | Cluster BGCs using BiG-SLiCE (https://github.com/medema-group/bigslice) | bigslice |
| 8 | query-bigslice | Map BGCs to BiG-FAM database (https://bigfam.bioinformatics.nl/) | bigfam.bioinformatics.nl |
| 9 | checkm | Assess genome quality with CheckM. | CheckM |
| 10 | gtdbtk | Taxonomic placement with GTDB-Tk | GTDBTk |
| 11 | prokka-gbk | Copy annotated genbank results. | prokka |
| 12 | antismash | Summarizes antiSMASH result. | antismash |
| 13 | arts | Run Antibiotic Resistant Target Seeker (ARTS) on samples. | arts |
| 14 | deeptfactor | Use deep learning to find Transcription Factors. | deeptfactor |
| 15 | deeptfactor-roary | Use DeepTFactor on Roary outputs. | Roary |
| 16 | cblaster-genome | Build diamond database of genomes for cblaster search. | cblaster |
| 17 | cblaster-bgc | Build diamond database of BGCs for cblaster search. | cblaster |
| 18 | bigscape | Cluster BGCs using BiG-SCAPE | BiG-SCAPE |
| 19 | gecco | GEne Cluster prediction with COnditional random fields. | GECCO |
The development of BGCFlow commenced within the Natural Products Genome Mining research group at the Novo Nordisk Foundation Center for Biosustainability, Technical University of Denmark (DTU Biosustain). BGCFlow development was/is made possible through the generous support of various funding organizations:
-
Novo Nordisk Foundation: BGCFlow development was supported by grants from the Novo Nordisk Foundation, specifically [NNF20CC0035580] and [NNF16OC0021746]. Matin Nuhamunada received support from the NNF Copenhagen Bioscience PhD Program: , grant [NNF20SA0035588].
-
Danish National Research Foundation: Additional funding was provided by the Danish National Research Foundation for the Center for Microbial Secondary Metabolites (CeMiSt), under the grant [DNRF137].
- Mash: fast genome and metagenome distance estimation using MinHash. Ondov BD, Treangen TJ, Melsted P, Mallonee AB, Bergman NH, Koren S, Phillippy AM. Genome Biol. 2016 Jun 20;17(1):132. doi: 10.1186/s13059-016-0997-x.
- Mash Screen: high-throughput sequence containment estimation for genome discovery. Ondov BD, Starrett GJ, Sappington A, Kostic A, Koren S, Buck CB, Phillippy AM. Genome Biol. 2019 Nov 5;20(1):232. doi: 10.1186/s13059-019-1841-x.
- Jain, C., Rodriguez-R, L.M., Phillippy, A.M. et al. High throughput ANI analysis of 90K prokaryotic genomes reveals clear species boundaries. Nat Commun 9, 5114 (2018). https://doi.org/10.1038/s41467-018-07641-9
- Mohammad Alanjary, Katharina Steinke, Nadine Ziemert, AutoMLST: an automated web server for generating multi-locus species trees highlighting natural product potential,Nucleic Acids Research, Volume 47, Issue W1, 02 July 2019, Pages W276–W282
- Andrew J. Page, Carla A. Cummins, Martin Hunt, Vanessa K. Wong, Sandra Reuter, Matthew T. G. Holden, Maria Fookes, Daniel Falush, Jacqueline A. Keane, Julian Parkhill, 'Roary: Rapid large-scale prokaryote pan genome analysis', Bioinformatics, 2015;31(22):3691-3693 doi:10.1093/bioinformatics/btv421
- eggNOG-mapper v2: functional annotation, orthology assignments, and domain prediction at the metagenomic scale. Carlos P. Cantalapiedra, Ana Hernandez-Plaza, Ivica Letunic, Peer Bork, Jaime Huerta-Cepas. 2021. Molecular Biology and Evolution, msab293
- eggNOG 5.0: a hierarchical, functionally and phylogenetically annotated orthology resource based on 5090 organisms and 2502 viruses. Jaime Huerta-Cepas, Damian Szklarczyk, Davide Heller, Ana Hernández-Plaza, Sofia K Forslund, Helen Cook, Daniel R Mende, Ivica Letunic, Thomas Rattei, Lars J Jensen, Christian von Mering, Peer Bork Nucleic Acids Res. 2019 Jan 8; 47(Database issue): D309–D314. doi: 10.1093/nar/gky1085
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- Satria A Kautsar, Kai Blin, Simon Shaw, Tilmann Weber, Marnix H Medema, BiG-FAM: the biosynthetic gene cluster families database, Nucleic Acids Research, gkaa812, https://doi.org/10.1093/nar/gkaa812
- Satria A Kautsar, Justin J J van der Hooft, Dick de Ridder, Marnix H Medema, BiG-SLiCE: A highly scalable tool maps the diversity of 1.2 million biosynthetic gene clusters, GigaScience, Volume 10, Issue 1, January 2021, giaa154.
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- Mungan,M.D., Alanjary,M., Blin,K., Weber,T., Medema,M.H. and Ziemert,N. (2020) ARTS 2.0: feature updates and expansion of the Antibiotic Resistant Target Seeker for comparative genome mining. Nucleic Acids Res.,10.1093/nar/gkaa374
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- Kim G.B., Gao Y., Palsson B.O., Lee S.Y. 2020. DeepTFactor: A deep learning-based tool for the prediction of transcription factors. PNAS. doi: 10.1073/pnas.2021171118
- Andrew J. Page, Carla A. Cummins, Martin Hunt, Vanessa K. Wong, Sandra Reuter, Matthew T. G. Holden, Maria Fookes, Daniel Falush, Jacqueline A. Keane, Julian Parkhill, 'Roary: Rapid large-scale prokaryote pan genome analysis', Bioinformatics, 2015;31(22):3691-3693 doi:10.1093/bioinformatics/btv421
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- Laura M Carroll, Martin Larralde, Jonas Simon Fleck, Ruby Ponnudurai, Alessio Milanese, Elisa Cappio Barazzone, Georg Zeller. 2021. Accurate de novo identification of biosynthetic gene clusters with GECCO. bioRxiv 2021.05.03.442509; doi:10.1101/2021.05.03.442509