Detail Information for IndEnz0010001618
IED ID IndEnz0010001618
Enzyme Type ID esterase001618
Protein Name Cytochrome P450 monooxygenase claJ
EC 1.-.-.-
Clavatol biosynthesis cluster protein J
Gene Name claJ
Organism Penicillium crustosum (Blue mold fungus)
Taxonomic Lineage cellular organisms Eukaryota Opisthokonta Fungi Dikarya Ascomycota saccharomyceta Pezizomycotina leotiomyceta Eurotiomycetes Eurotiomycetidae Eurotiales (green and blue molds) Aspergillaceae Penicillium Penicillium crustosum (Blue mold fungus)
Enzyme Sequence MKGPIVRITPNELHIKDASFYDEIYAGSGRIRNKDERFVKTFSAPHAMVSITDHAYHRVRRGLLGEFFSQRSVIKMEPIINGAIEKLSQRLHEACQTGAVINMDAAFAAMTADVITRHAWGQSGNYLDHGNFNKQWKDAVAGTMASRVLFRHFPYMLHILMAVPLPILLKLDPGVADILKIEGLVRRLSVENVNRGIVEKQEGKTIFDALNNVSVPPEQRTAKHLIDEGHILLLAGTETTAKALSTCLCYLLLAENKNVLLALQSELRQAFPNVSTWPKWTEAQKLPYLTAVINECLRLSHGLSTRLPRTAPKESLQYKQWHIPAATPVSQTAYFVHMDPSIFPDPERFEPERWIRASKEGLHLERYIVSFSKGSRQCLGINMAYAEIFLALTHIMRNFEFQLHDTSVDDVRLFRDRFFGAAQDGSVGVRVLVNEVKY
Enzyme Length 438
Uniprot Accession Number A0A481WPJ6
Absorption
Active Site
Activity Regulation
Binding Site
Calcium Binding
catalytic Activity
DNA Binding
EC Number 1.-.-.-
Enzyme Function FUNCTION: Cytochrome P450 monooxygenase; part of the cla gene cluster that produces clavatol and ortho-quinone methide (PubMed:30811183). The clavatol biosynthesis cluster cla and the terrestric acid cluster tra are both involved in the production of peniphenones and penilactones (PubMed:30811183). The non-reducing PKS claF is responsible for the formation of clavatol from successive condensations of 3 malonyl-CoA units, presumably with a simple acetyl-CoA starter unit, and 2 methylation steps (PubMed:30811183). The esterase claE probably collaborates with claF by catalyzing the hydrolysis of ACP-bound acyl intermediates to free the ACP from stalled intermediates (By similarity). The clavatol oxidase claD then converts clavatol to hydroxyclavatol (PubMed:30811183). Spontaneous dehydration of hydroxyclavatol leads to the accumulation of the highly active ortho-quinone methide (PubMed:30811183, PubMed:31860310). On the other hand, the PKS-NRPS hybrid traA is involved in the formation of crustosic acid, with the help of traB and traD (PubMed:30811183). The polyketide synthase module (PKS) of traA is responsible for the synthesis of the polyketide backbone via the condensation of an acetyl-CoA starter unit with 3 malonyl-CoA units (PubMed:30811183). The downstream nonribosomal peptide synthetase (NRPS) module then amidates the carboxyl end of the polyketide with L-malic acid (PubMed:30811183). Because traA lacks a designated enoylreductase (ER) domain, the required activity is provided the enoyl reductase traG (By similarity). Crustosic acid undergoes decarboxylation and isomerization to the terrestric acid, catalyzed by the 2-oxoglutarate-dependent dioxygenase traH (PubMed:30811183). Both acids are further converted to the 2 gamma-butyrolactones (R)-5-methyltetronic acid and (S)-5-carboxylmethyltetronic acid, with involvement of the cytochrome P450 monooxygenase claJ (PubMed:30811183). Spontaneous addition of the methide to these gamma-butyrolactones leads to peniphenone D and penilactone D, which undergo again stereospecific attacking by methide to give penilactones A and B (PubMed:30811183, PubMed:31860310). {ECO:0000250|UniProtKB:A0A0E0RXA7, ECO:0000250|UniProtKB:A0A161CKG1, ECO:0000269|PubMed:30811183, ECO:0000269|PubMed:31860310}.
Temperature Dependency
PH Dependency
Pathway PATHWAY: Secondary metabolite biosynthesis. {ECO:0000269|PubMed:30811183}.
nucleotide Binding
Features Chain (1); Metal binding (1)
Keywords Heme;Iron;Metal-binding;Monooxygenase;Oxidoreductase
Interact With
Induction
Subcellular Location
Modified Residue
Post Translational Modification
Signal Peptide
Structure 3D
Cross Reference PDB -
Mapped Pubmed ID -
Motif
Gene Encoded By
Mass 49,573
Kinetics
Metal Binding METAL 378; /note=Iron (heme axial ligand); /evidence=ECO:0000250|UniProtKB:P04798
Rhea ID
Cross Reference Brenda