rphA

Download Sequences

Accession	ARO:3000444
CARD Short Name	rphA
Definition	The enzymatic inactivation of rifampin by phosphorylation at the 21-OH position.
AMR Gene Family	rifampin phosphotransferase
Drug Class	rifamycin antibiotic
Resistance Mechanism	antibiotic inactivation
Classification	9 ontology terms \| Show + process or component of antibiotic biology or chemistry + mechanism of antibiotic resistance + determinant of antibiotic resistance + antibiotic inactivation [Resistance Mechanism] + antibiotic molecule + antibiotic inactivation enzyme + rifamycin antibiotic [Drug Class] + phosphorylation of antibiotic conferring resistance + rifampin inactivation enzyme
Parent Term(s)	5 ontology terms \| Show + rifampin phosphotransferase [AMR Gene Family] + confers_resistance_to_antibiotic rifabutin [Antibiotic] + confers_resistance_to_antibiotic rifampin [Antibiotic] + confers_resistance_to_antibiotic rifaximin [Antibiotic] + confers_resistance_to_antibiotic rifapentine [Antibiotic]
Publications	Yazawa K, et al. 1994. J Antimicrob Chemother 33(6): 1127-1135. Phosphorylative inactivation of rifampicin by Nocardia otitidiscaviarum. (PMID 7928806) Spanogiannopoulos P, et al. 2014. Proc Natl Acad Sci U S A 111(19): 7102-7107. A rifamycin inactivating phosphotransferase family shared by environmental and pathogenic bacteria. (PMID 24778229) Stogios PJ, et al. 2016. Nat Commun 7:11343 Rifampin phosphotransferase is an unusual antibiotic resistance kinase. (PMID 27103605)

Resistomes

Prevalence of rphA 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

Species	NCBI Chromosome	NCBI Plasmid	NCBI WGS	NCBI GI
No prevalence data

Detection Models

protein homolog model

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): 1500

Protein
DNA

>gb|AIA08936.1|+|rphA [Streptomyces sp. WAC4747]
MSGRLVVDLQDVDAAGLAEVGGKGAHLGELSRIDGVRVPSGFCVTTHAFRRIMAEAPESGELLDRLSRVDEGDQEAVRSLAARLRQVVGA
TPLPDEVAAAVTGALARHGERSAYAVRSSATAEDLPTASFAGQQDTYLNVVGTEEILRHVSRCWASLFTERAVTYRGRQGVDHRTVHMGV
VVQRMVVPRASGILFTADPVTGDRRTATVDAGFGLGEALVSGLVDPDVLTVRHGEVVARTIAAKRRALHAVQGGGTRETPIEERRQREPV
LTDDQAVELVALGRRIEAHFGSPQDIEWCLDDDGFHIVQSRPITTLFPVPERDDDVFRVYLSVGHQQMMTDAMKPLGLSMWRLTALAPMY
EAGGRLFVDATARLAVPGSRATLLDVVGRGDPLTRDALETVLENGEFEPTPAETDGGAPPAGDGAEPDEADPSIVTELIERSRRSLAELE
REIGTKSGPALFAFLREAFEEHKRVVGDPLNIRAIMAGMEATWWLNDRLEEWLGEKNAADTLTLSAPDNVTSEMGLELLDVADVVRTHPE
VVAFLEGVEDDGFLDELPKVPGGAEARDAFEAYLDRYGMRCVGEIDITXPPVRERPSALVPVVLDHVRAFGPGAAARRFEDGRRRALAKE
REVLERLRDLPDGERRADAARRMIRQVRAFAGYREYPKYAIVSRSFVYRQALLREADELVRAGVLADREDVHYLTFDEFEEAVRVRRVDE
RLVRRRKDAFRSYQALTPPRVLTSEGVALSGAYRRDDVPEGALAGLAVSAGTVEGRARVVLDMAEADLEAGDILVTRFTDPSWSPLFVGI
AGLVTEVGGLMTHGAVIAREYGLAAVVGVERATRLIRDGQRIRVHGTEGYIELLS

>gb|KJ151292.1|+|295-2892|rphA [Streptomyces sp. WAC4747]
ATGAGCGGGCGTCTGGTCGTGGATCTTCAGGACGTCGACGCGGCGGGGCTCGCCGAGGTCGGCGGCAAGGGCGCCCACCTGGGCGAGCTG
TCCCGGATCGACGGGGTCCGGGTGCCGTCCGGGTTCTGTGTGACGACGCACGCCTTCCGGCGGATCATGGCGGAGGCACCCGAGAGCGGG
GAACTCCTCGACCGGCTGTCCCGCGTGGACGAGGGCGACCAGGAGGCGGTCCGATCCCTCGCCGCCCGTCTACGGCAGGTCGTCGGGGCG
ACGCCCCTCCCGGACGAGGTGGCGGCGGCCGTCACCGGGGCGCTCGCCCGGCACGGTGAGCGGTCCGCGTACGCCGTACGGTCCAGCGCG
ACGGCCGAGGACCTGCCGACCGCGTCGTTCGCCGGCCAGCAGGACACGTACCTGAACGTCGTCGGCACCGAGGAGATCCTCCGGCACGTC
AGCCGGTGCTGGGCCTCCCTGTTCACCGAGCGGGCGGTGACCTACCGCGGGCGTCAGGGCGTCGACCACCGTACGGTCCACATGGGCGTG
GTCGTGCAGCGGATGGTCGTGCCGCGGGCGTCCGGCATCCTGTTCACCGCCGACCCGGTGACGGGAGACCGCCGCACGGCGACCGTGGAC
GCCGGTTTCGGTCTCGGCGAGGCCCTGGTGTCGGGGCTGGTCGACCCGGACGTCCTCACGGTGCGGCACGGCGAGGTCGTCGCGCGGACG
ATCGCCGCGAAGCGGCGCGCCCTGCACGCCGTGCAGGGCGGTGGGACGCGCGAGACCCCGATCGAGGAACGGCGGCAGCGCGAACCGGTA
CTGACGGACGATCAGGCCGTGGAGCTGGTCGCGCTCGGGCGGCGGATCGAGGCGCACTTCGGCAGCCCGCAGGACATCGAGTGGTGCCTG
GACGACGACGGCTTCCACATCGTGCAGAGCCGGCCGATCACCACGCTGTTCCCCGTGCCCGAGCGGGACGACGACGTCTTCCGCGTCTAT
CTCTCGGTCGGCCACCAGCAGATGATGACCGACGCCATGAAGCCCCTGGGCCTCTCGATGTGGCGGCTGACGGCCCTGGCACCGATGTAC
GAGGCCGGCGGGCGGCTGTTCGTCGACGCCACCGCCCGGCTGGCGGTGCCCGGGAGCCGTGCCACTCTCCTGGACGTCGTCGGCCGTGGC
GACCCGCTGACCCGGGACGCGCTCGAAACGGTCCTGGAGAACGGCGAGTTCGAGCCGACGCCGGCGGAGACGGACGGAGGCGCGCCGCCC
GCCGGTGACGGGGCCGAACCGGACGAGGCCGATCCTTCCATCGTCACCGAGCTGATCGAGCGCAGCCGGCGCTCCCTCGCCGAGCTGGAG
CGGGAGATCGGCACGAAGAGCGGTCCCGCCCTGTTCGCGTTCCTGCGGGAGGCGTTCGAGGAGCACAAGCGGGTGGTCGGCGATCCGCTG
AACATCCGCGCGATCATGGCGGGCATGGAGGCCACCTGGTGGCTGAACGACCGGCTGGAGGAGTGGCTCGGCGAGAAGAACGCCGCCGAC
ACGCTCACGCTGTCCGCCCCCGACAACGTGACCTCGGAGATGGGGCTGGAGCTGCTCGACGTCGCCGACGTGGTCCGCACGCACCCGGAG
GTGGTGGCCTTCCTGGAGGGCGTCGAGGACGACGGCTTCCTGGACGAGCTGCCCAAGGTCCCCGGTGGCGCCGAGGCCCGGGACGCCTTC
GAGGCATACCTGGACCGGTACGGCATGCGCTGCGTCGGCGAGATCGACATCACGNGGCCCCCGGTGCGGGAACGGCCCAGCGCGCTCGTG
CCGGTCGTCCTCGACCACGTGCGCGCCTTCGGGCCCGGCGCCGCCGCGCGCCGCTTCGAGGACGGCCGGCGCAGGGCGCTCGCGAAGGAG
CGTGAGGTGCTGGAGCGGCTGCGGGACCTGCCGGACGGGGAGCGCAGGGCCGACGCGGCGCGCCGGATGATCCGGCAGGTCCGCGCGTTC
GCCGGCTACCGGGAGTACCCGAAGTACGCGATCGTCAGCCGCTCCTTCGTCTACCGTCAGGCCCTGCTGCGGGAGGCCGACGAGCTGGTG
CGGGCCGGCGTCCTCGCCGACCGGGAGGACGTCCACTACCTGACGTTCGACGAGTTCGAGGAGGCCGTCCGCGTGCGCCGGGTGGACGAG
CGGCTGGTGCGGCGCCGCAAGGACGCCTTCCGTTCGTACCAGGCGCTGACCCCGCCCCGCGTCCTCACCTCGGAGGGTGTGGCCCTCTCC
GGGGCGTACCGGCGCGACGACGTGCCGGAAGGGGCGCTGGCGGGTCTCGCGGTGTCCGCGGGGACCGTGGAGGGCCGGGCCCGGGTGGTC
CTCGACATGGCGGAGGCCGATCTGGAGGCGGGCGACATCCTGGTCACGCGGTTCACGGACCCCAGCTGGTCACCGCTGTTCGTCGGGATC
GCGGGCCTGGTGACGGAGGTGGGCGGTCTGATGACCCATGGCGCGGTGATCGCCCGCGAGTACGGTCTGGCGGCCGTGGTCGGGGTGGAG
CGGGCCACCCGGCTGATCCGGGACGGGCAGCGCATCCGGGTGCACGGGACGGAGGGCTATATCGAGCTTCTGTCCTGA

>gb|KJ151292.1|+|295-2892|rphA [Streptomyces sp. WAC4747] ATGAGCGGGCGTCTGGTCGTGGATCTTCAGGACGTCGACGCGGCGGGGCTCGCCGAGGTCGGCGGCAAGGGCGCCCACCTGGGCGAGCTGTCCCGGATCGACGGGGTCCGGGTGCCGTCCGGGTTCTGTGTGACGACGCACGCCTTCCGGCGGATCATGGCGGAGGCACCCGAGAGCGGGGAACTCCTCGACCGGCTGTCCCGCGTGGACGAGGGCGACCAGGAGGCGGTCCGATCCCTCGCCGCCCGTCTACGGCAGGTCGTCGGGGCGACGCCCCTCCCGGACGAGGTGGCGGCGGCCGTCACCGGGGCGCTCGCCCGGCACGGTGAGCGGTCCGCGTACGCCGTACGGTCCAGCGCGACGGCCGAGGACCTGCCGACCGCGTCGTTCGCCGGCCAGCAGGACACGTACCTGAACGTCGTCGGCACCGAGGAGATCCTCCGGCACGTCAGCCGGTGCTGGGCCTCCCTGTTCACCGAGCGGGCGGTGACCTACCGCGGGCGTCAGGGCGTCGACCACCGTACGGTCCACATGGGCGTGGTCGTGCAGCGGATGGTCGTGCCGCGGGCGTCCGGCATCCTGTTCACCGCCGACCCGGTGACGGGAGACCGCCGCACGGCGACCGTGGACGCCGGTTTCGGTCTCGGCGAGGCCCTGGTGTCGGGGCTGGTCGACCCGGACGTCCTCACGGTGCGGCACGGCGAGGTCGTCGCGCGGACGATCGCCGCGAAGCGGCGCGCCCTGCACGCCGTGCAGGGCGGTGGGACGCGCGAGACCCCGATCGAGGAACGGCGGCAGCGCGAACCGGTACTGACGGACGATCAGGCCGTGGAGCTGGTCGCGCTCGGGCGGCGGATCGAGGCGCACTTCGGCAGCCCGCAGGACATCGAGTGGTGCCTGGACGACGACGGCTTCCACATCGTGCAGAGCCGGCCGATCACCACGCTGTTCCCCGTGCCCGAGCGGGACGACGACGTCTTCCGCGTCTATCTCTCGGTCGGCCACCAGCAGATGATGACCGACGCCATGAAGCCCCTGGGCCTCTCGATGTGGCGGCTGACGGCCCTGGCACCGATGTACGAGGCCGGCGGGCGGCTGTTCGTCGACGCCACCGCCCGGCTGGCGGTGCCCGGGAGCCGTGCCACTCTCCTGGACGTCGTCGGCCGTGGCGACCCGCTGACCCGGGACGCGCTCGAAACGGTCCTGGAGAACGGCGAGTTCGAGCCGACGCCGGCGGAGACGGACGGAGGCGCGCCGCCCGCCGGTGACGGGGCCGAACCGGACGAGGCCGATCCTTCCATCGTCACCGAGCTGATCGAGCGCAGCCGGCGCTCCCTCGCCGAGCTGGAGCGGGAGATCGGCACGAAGAGCGGTCCCGCCCTGTTCGCGTTCCTGCGGGAGGCGTTCGAGGAGCACAAGCGGGTGGTCGGCGATCCGCTGAACATCCGCGCGATCATGGCGGGCATGGAGGCCACCTGGTGGCTGAACGACCGGCTGGAGGAGTGGCTCGGCGAGAAGAACGCCGCCGACACGCTCACGCTGTCCGCCCCCGACAACGTGACCTCGGAGATGGGGCTGGAGCTGCTCGACGTCGCCGACGTGGTCCGCACGCACCCGGAGGTGGTGGCCTTCCTGGAGGGCGTCGAGGACGACGGCTTCCTGGACGAGCTGCCCAAGGTCCCCGGTGGCGCCGAGGCCCGGGACGCCTTCGAGGCATACCTGGACCGGTACGGCATGCGCTGCGTCGGCGAGATCGACATCACGNGGCCCCCGGTGCGGGAACGGCCCAGCGCGCTCGTGCCGGTCGTCCTCGACCACGTGCGCGCCTTCGGGCCCGGCGCCGCCGCGCGCCGCTTCGAGGACGGCCGGCGCAGGGCGCTCGCGAAGGAGCGTGAGGTGCTGGAGCGGCTGCGGGACCTGCCGGACGGGGAGCGCAGGGCCGACGCGGCGCGCCGGATGATCCGGCAGGTCCGCGCGTTCGCCGGCTACCGGGAGTACCCGAAGTACGCGATCGTCAGCCGCTCCTTCGTCTACCGTCAGGCCCTGCTGCGGGAGGCCGACGAGCTGGTGCGGGCCGGCGTCCTCGCCGACCGGGAGGACGTCCACTACCTGACGTTCGACGAGTTCGAGGAGGCCGTCCGCGTGCGCCGGGTGGACGAGCGGCTGGTGCGGCGCCGCAAGGACGCCTTCCGTTCGTACCAGGCGCTGACCCCGCCCCGCGTCCTCACCTCGGAGGGTGTGGCCCTCTCCGGGGCGTACCGGCGCGACGACGTGCCGGAAGGGGCGCTGGCGGGTCTCGCGGTGTCCGCGGGGACCGTGGAGGGCCGGGCCCGGGTGGTCCTCGACATGGCGGAGGCCGATCTGGAGGCGGGCGACATCCTGGTCACGCGGTTCACGGACCCCAGCTGGTCACCGCTGTTCGTCGGGATCGCGGGCCTGGTGACGGAGGTGGGCGGTCTGATGACCCATGGCGCGGTGATCGCCCGCGAGTACGGTCTGGCGGCCGTGGTCGGGGTGGAGCGGGCCACCCGGCTGATCCGGGACGGGCAGCGCATCCGGGTGCACGGGACGGAGGGCTATATCGAGCTTCTGTCCTGA

rphA

Prevalence: protein homolog model

Graph