Bacillus subtilis mprF

Accession ARO:3003324
CARD Short NameBsub_mprF
DefinitionMprF is a integral membrane protein that modifies the negatively-charged phosphatidylglycerol on the membrane surface. This confers resistance to cationic peptides that disrupt the cell membrane, including defensins. Additionally, large-scale mutations causing loss of function of the gene result in increased susceptibility to daptomycin.
AMR Gene Familydefensin resistant mprF
Drug Classpeptide antibiotic
Resistance Mechanismantibiotic target alteration
Resistomes with Perfect MatchesBacillus subtilisg+wgs
Resistomes with Sequence VariantsBacillus subtilisg+wgs
Classification10 ontology terms | Show
Parent Term(s)2 ontology terms | Show
+ confers_resistance_to_antibiotic defensin [Antibiotic]
+ defensin resistant mprF [AMR Gene Family]
Publications

Hachmann AB, et al. 2011. Antimicrob Agents Chemother 55(9): 4326-4337. Reduction in membrane phosphatidylglycerol content leads to daptomycin resistance in Bacillus subtilis. (PMID 21709092)

Hachmann AB, et al. 2009. Antimicrob Agents Chemother 53(4): 1598-1609. Genetic analysis of factors affecting susceptibility of Bacillus subtilis to daptomycin. (PMID 19164152)

Ernst CM, et al. 2009. PLoS Pathog 5(11): E1000660. The bacterial defensin resistance protein MprF consists of separable domains for lipid lysinylation and antimicrobial peptide repulsion. (PMID 19915718)

Resistomes

Prevalence of Bacillus subtilis mprF among the sequenced genomes, plasmids, and whole-genome shotgun assemblies available at NCBI or IslandViewer for 413 important pathogens (see methodological details and complete list of analyzed pathogens). Values reflect percentage of genomes, plasmids, genome islands, or whole-genome shotgun assemblies that have at least one hit to the AMR detection model. Default view includes percentages calculated based on Perfect plus Strict RGI hits. Select the checkbox to view percentages based on only Perfect matches to AMR reference sequences curated in CARD (note: this excludes resistance via mutation as references in protein variant models are often wild-type, sensitive sequences).

Prevalence: protein homolog model (view sequences)

SpeciesNCBI ChromosomeNCBI PlasmidNCBI WGSNCBI GI
Bacillus subtilis31.18%0%16.18%0%
Show Perfect Only


Detection Models

Model Type: protein homolog model

Model Definition: Protein Homolog Models (PHM) detect protein sequences based on their similarity to a curated reference sequence, using curated BLASTP bitscore cut-offs. Protein Homolog Models apply to all genes that confer resistance through their presence in an organism, such as the presence of a beta-lactamase gene on a plasmid. PHMs include a reference sequence and a bitscore cut-off for detection using BLASTP. A Perfect RGI match is 100% identical to the reference protein sequence along its entire length, a Strict RGI match is not identical but the bit-score of the matched sequence is greater than the curated BLASTP bit-score cutoff, Loose RGI matches have a bit-score less than the curated BLASTP bit-score cut-off.

Bit-score Cut-off (blastP): 1650


>gb|CAX52582.1|+|Bacillus subtilis mprF [Bacillus subtilis subsp. subtilis str. 168]
MLIKKNALSILKIVFPIAVLLFVIYQSKKELTNLSFKRTLMVINGLERTDLFMLVLIGLLAVAAMSLYDYVLKYSLRLSITNGKVFRVSW
IANSFNNVLGFGGLAGVGLRMMFYKEHTKDHKALVKGIAWLTSSMLLGLSVFSIFVAARVLPVDEVIHEKPWLWAVVIGFALILPLSLAV
SKIKDRKAGDEENADKVKNPIFAYIGASVVEWLMAGTVIYFALFAMGIHADIRYVFGVFVIAAIGGMISLVPGGFGSFDLLFLLGMEQLG
YHQEAIVTSIVLYRLAYSFIPFILGLFFAAGDLTENTMKRLETNPRIAPAIETTNVLLVVQRAVLVRILQGSLSLIVFVAGLIVLASVSL
PIDRLTVIPHIPRPALLLFNGLSLSSALILLILPIELYKRTKRSYTMAITALVGGFVFSFLKGLNISAIFVLPMIIVLLVLLKKQFVREQ
ASYTLGQLIFAVALFTVALFNYNLIAGFIWDRMKKVLRHEYFVHSTSHITHATIMAIIIVPLFFLIFTVVYHKRTKPIGEKADPERLAAF
LNEKGGNALSHLGFLGDKRFYFSSDGNALLLFGKIARRLVVLGDPSGQRESFPLVLEEFLNEAHQKGFSVLFYQIEREDMALYHDFGYNF
FKLGEEAYVDLNTFTLTGKKKAGLRAINNRFEREEYTFHVDHPPFSDAFLEELKQISDEWLGSKKEKGFSLGFFDPSYLQKAPIAYMKNA
EGEIVAFANVMPMYQEGEISVDLMRYRGDAPNGIMDALFIRMFLWAKEEGCTSFNMGMAPLANVGTAFTSFWSERFAAVIFNNVRYMYSF
SGLRAFKEKYKPEWRGKYLAYRKNRSLSVTMFLVTRLIGKSKKDSV


>gb|AL009126.3|+|916778-919348|Bacillus subtilis mprF [Bacillus subtilis subsp. subtilis str. 168]
TTGCTGATTAAAAAGAATGCTTTATCAATATTAAAAATCGTTTTTCCTATTGCTGTTTTGCTATTTGTTATTTATCAATCGAAAAAAGAA
CTGACAAATCTGTCATTCAAACGTACGCTCATGGTCATCAACGGACTGGAACGAACGGATTTATTCATGCTTGTGTTGATCGGCTTGCTG
GCTGTTGCGGCTATGTCGCTGTATGATTACGTCCTGAAGTACTCACTGCGCCTATCGATCACAAACGGAAAAGTTTTCAGGGTTTCCTGG
ATCGCCAATTCATTTAATAATGTGTTGGGATTCGGCGGTTTAGCCGGAGTCGGGTTAAGAATGATGTTCTATAAGGAGCATACGAAAGAC
CATAAGGCACTCGTGAAAGGAATCGCCTGGCTCACATCATCTATGCTGCTCGGATTATCTGTTTTCAGCATTTTCGTTGCTGCGAGAGTG
CTGCCAGTTGATGAAGTGATTCATGAGAAGCCTTGGCTGTGGGCGGTCGTTATCGGTTTTGCACTGATATTGCCGTTATCTTTAGCGGTG
TCCAAAATAAAAGACCGCAAAGCTGGGGACGAAGAGAATGCGGATAAAGTGAAAAATCCGATTTTCGCATATATTGGAGCTTCAGTTGTT
GAATGGCTCATGGCCGGGACCGTCATCTATTTTGCTTTGTTCGCTATGGGCATTCATGCAGATATCAGGTATGTGTTCGGGGTGTTCGTC
ATTGCGGCGATCGGAGGAATGATCAGCCTCGTGCCGGGCGGCTTCGGCTCGTTTGACCTTTTATTTTTGCTGGGGATGGAGCAGCTTGGC
TATCATCAAGAGGCCATCGTTACTTCTATTGTGTTGTACAGGCTCGCCTACTCATTTATCCCATTTATCTTGGGACTGTTCTTTGCCGCC
GGCGACCTGACGGAAAATACAATGAAGCGGCTCGAAACGAACCCGCGCATCGCACCGGCAATTGAGACGACAAACGTTCTGCTTGTTGTT
CAGCGTGCGGTATTAGTGAGAATTTTGCAAGGCTCGCTTTCCCTTATTGTGTTCGTAGCAGGTCTGATTGTCTTGGCCTCAGTTTCCTTG
CCGATTGACAGGCTGACGGTTATACCGCACATTCCGCGCCCGGCGCTTTTGCTGTTCAACGGCCTGTCCTTAAGCTCAGCGCTCATTCTG
CTCATTTTGCCGATCGAGCTTTATAAACGGACAAAACGTTCCTACACGATGGCCATTACAGCGCTTGTCGGCGGCTTTGTGTTCAGCTTT
TTAAAAGGGCTTAACATCAGCGCGATATTCGTACTGCCGATGATTATCGTATTGCTTGTGCTATTGAAAAAACAATTTGTCCGCGAACAG
GCATCCTATACACTGGGACAATTGATATTCGCTGTGGCGCTGTTTACTGTGGCGCTCTTTAACTACAATCTGATCGCGGGCTTTATTTGG
GACCGGATGAAGAAGGTGCTGCGTCACGAATATTTCGTCCACAGCACCTCGCATATTACACATGCAACCATCATGGCGATCATCATTGTG
CCGCTGTTCTTCTTGATATTTACAGTGGTCTATCATAAGAGAACGAAACCGATCGGAGAGAAAGCTGACCCTGAGCGTCTTGCTGCGTTT
CTCAATGAAAAAGGCGGCAACGCGCTGAGCCATCTTGGTTTTCTTGGAGATAAGCGGTTTTATTTTTCTAGCGATGGAAATGCACTGCTT
CTGTTTGGGAAAATCGCCAGAAGGCTGGTCGTGCTCGGCGATCCATCTGGCCAAAGAGAATCATTCCCGCTCGTGCTGGAAGAATTTCTG
AACGAAGCGCATCAGAAGGGATTCAGTGTTTTGTTCTATCAAATTGAACGAGAGGACATGGCGCTGTATCACGATTTTGGCTACAACTTC
TTTAAATTGGGTGAGGAAGCATATGTAGATTTAAATACATTTACCTTGACTGGGAAGAAAAAAGCCGGCCTTCGGGCAATCAATAACCGC
TTTGAGCGGGAGGAGTATACTTTCCATGTGGATCATCCCCCATTTTCTGATGCGTTTTTGGAGGAGCTGAAGCAAATCTCAGACGAATGG
CTCGGCTCGAAAAAAGAGAAGGGATTCTCGCTCGGATTTTTTGATCCTTCCTATTTACAGAAAGCGCCGATCGCCTATATGAAAAATGCA
GAAGGAGAGATCGTTGCATTCGCAAATGTCATGCCGATGTACCAGGAAGGAGAGATATCGGTCGATCTGATGCGCTATCGCGGCGACGCT
CCAAATGGCATTATGGACGCATTGTTTATCCGTATGTTTTTATGGGCAAAGGAAGAGGGCTGTACGTCATTTAATATGGGGATGGCACCC
TTGGCCAATGTCGGCACTGCCTTTACATCCTTCTGGTCCGAAAGGTTTGCCGCTGTCATTTTTAATAATGTCAGATACATGTACAGTTTC
AGCGGCCTAAGAGCCTTTAAAGAAAAATATAAACCGGAGTGGCGAGGGAAATACTTAGCGTATCGGAAAAACAGATCTCTTTCTGTCACC
ATGTTCCTCGTTACACGTCTGATTGGCAAAAGCAAAAAAGACTCCGTCTAA