Integrated proteogenomics database

Bacteria iconB. producta DSM2950_Asp-N

The extended simplified human intestinal microbiota (SIHUMIx) consists of eight bacterial members (Anaerostipes caccae (DSMZ 14662); Bacteroides thetaiotaomicron (DSMZ 2079); Bifidobacterium longum (NCC 2705); Blautia producta (DSMZ 2950); Clostridium butyricum (DSMZ 10702); Clostridium ramosum (DSMZ 1402); Escherichia coli K-12 (MG1655); Lactobacillus plantarum (DSMZ 20174)) of the human intestine and thus represents a model community to analyze such microbial interactions [1].

An Asp-N iPtgxDB of Blautia producta (DSM 2950) was created by hierarchically integrating protein coding sequences from the following annotation resources:

Hierarchy Resource Link
1 NCBI RefSeq CP039126.1 from 10-APR-2019 (NCBI Prokaryotic Genome Annotation Pipeline (PGAP v.4.7)
2 Prodigal [2] ab initio gene predictions from Prodigal (v2.6)
3 ChemGenome [3] ab initio gene predictions from ChemGenome (v2.0, http://www.scfbio-iitd.res.in/chemgenome/chemgenomenew.jsp; with parameters: method, Swissprot space; length threshold, 70 nt; initiation codons, ATG, CTG, TTG, GTG)
4 in silico ORFs in silico ORF annotations were generated as described by Omasits and Varadarajan et al., 2017 (v2.0, Only ORFs above a selectable length threshold (here 18 aa) were considered.)

The iPtgxDB was created using the hierarchy RefSeq > Prodigal > ChemGenome > in silico. Files were parsed to extract the identifier, coordinates and sequences of bona fide protein-coding sequences (CDS) and pseudogene entries.

References

  1. Becker, N., Kunath, J., Loh, G. & Blaut, M. Human intestinal microbiota: Characterization of a simplified and stable gnotobiotic rat model. Gut Microbes 2, 25-33, doi:10.4161/gmic.2.1.14651 (2011).
  2. Hyatt, D., Chen, G.L., Locascio, P.F., Land, M.L., Larimer, F.W., and Hauser, L.J. 2010. Prodigal: prokaryotic gene recognition and translation initiation site identification. BMC Bioinformatics 11: 119.
  3. Singhal, P., Jayaram, B., Dixit, S.B., and Beveridge, D.L. 2008. Prokaryotic gene finding based on physicochemical characteristics of codons calculated from molecular dynamics simulations. Biophys J 94: 4173-4183.
  4. Omasits, U., Varadarajan, A. R., Schmid, M., Goetze, S., Melidis, D., Bourqui, M., Nikolayeva, O., Quebatte, M., Patrignani, A., Dehio, C., Frey, J. E., Robinson, M. D., Wollscheid, B., and Ahrens., C. H. An integrative strategy to identify the entire protein coding potential of prokaryotic genomes by proteogenomics. bioRxiv, Cold Spring Harbor Labs Journals, 2017.
iPtgxDB Release Info
Versions
Version
1
Versions
Date
10.08.2020

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TAR.GZ

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Size
10.6 MB
Data icon
MD5
b84f82ce33603b0ad270e12406ad58ba
Data icon
SHA1
f3e0bbd97dd5fc764be4d21ca602c6da9a85bff2
Compression icon

ZIP

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Size
10.9 MB
Data icon
MD5
99ad3681b04d46e2f54d3d36899d8532
Data icon
SHA1
18175ea21567d97047c470e36366a25150f68755