| IED ID | IndEnz0018001120 |
| Enzyme Type ID | peroxidase001120 |
| Protein Name |
Catalase easC EC 1.11.-.- Catalase 2 Ergot alkaloid synthesis protein C |
| Gene Name | easC cpcat2 CPUR_04081 |
| Organism | Claviceps purpurea (strain 20.1) (Ergot fungus) (Sphacelia segetum) |
| Taxonomic Lineage | cellular organisms Eukaryota Opisthokonta Fungi Dikarya Ascomycota saccharomyceta Pezizomycotina leotiomyceta sordariomyceta Sordariomycetes Hypocreomycetidae Hypocreales Clavicipitaceae Claviceps Claviceps purpurea (Ergot fungus) (Sphacelia segetum) Claviceps purpurea (strain 20.1) (Ergot fungus) (Sphacelia segetum) |
| Enzyme Sequence | MASEVSVASSGSEHSGAQKCPFQDPGLSSMDQDSRLRDILSRFNREKIPERAVHARGAGAYGEFEVTHDVSDICDIDMLLGVGKKTPCVVRFSTTTLERGSAESVRDVKGMAIKHFTQDGNWDWVCLNIPMFFIRDPSKFPDMVHAQRPDPTTNVANPSRWWEFVCNNHETLHMVMFQFSDFGTMFDYRSMSGYAAHAYKWVMPDGSWKYVHWFLASDQGPNFETGHQAKQIGADDAESATRDLYQSLERGEYPSWTVKVQVVDPEDAPKLPFNILDVTKHWNLGNYPPDIDVIPGRTLGKLTLKKGPQDYFEEIEQLAFSPSRLVHGVEASEDPMLQARLFAYPDAQKHRLGPNNLDLPANRTKKLADGSRPEKAEMAPQKVPSQEHADWVSQVKSSSWSEPNETDYKFPREFWKALPRLRGEAFQNSLVVNMAKSVSQVPADMRQKVYSTLALIADDLADRVRTMTEEIVE |
| Enzyme Length | 473 |
| Uniprot Accession Number | M1WA44 |
| Absorption | |
| Active Site | ACT_SITE 54; /evidence=ECO:0000250|UniProtKB:P15202 |
| Activity Regulation | |
| Binding Site | |
| Calcium Binding | |
| catalytic Activity | |
| DNA Binding | |
| EC Number | 1.11.-.- |
| Enzyme Function | FUNCTION: Catalase; part of the gene cluster that mediates the biosynthesis of fungal ergot alkaloid (PubMed:14732265, PubMed:14700635, PubMed:15904941, PubMed:17308187, PubMed:17720822). DmaW catalyzes the first step of ergot alkaloid biosynthesis by condensing dimethylallyl diphosphate (DMAP) and tryptophan to form 4-dimethylallyl-L-tryptophan (PubMed:14732265). The second step is catalyzed by the methyltransferase easF that methylates 4-dimethylallyl-L-tryptophan in the presence of S-adenosyl-L-methionine, resulting in the formation of 4-dimethylallyl-L-abrine (By similarity). The catalase easC and the FAD-dependent oxidoreductase easE then transform 4-dimethylallyl-L-abrine to chanoclavine-I which is further oxidized by easD in the presence of NAD(+), resulting in the formation of chanoclavine-I aldehyde (PubMed:20118373, PubMed:21409592). Agroclavine dehydrogenase easG then mediates the conversion of chanoclavine-I aldehyde to agroclavine via a non-enzymatic adduct reaction: the substrate is an iminium intermediate that is formed spontaneously from chanoclavine-I aldehyde in the presence of glutathione (PubMed:20735127, PubMed:21494745). The presence of easA is not required to complete this reaction (PubMed:21494745). Further conversion of agroclavine to paspalic acid is a two-step process involving oxidation of agroclavine to elymoclavine and of elymoclavine to paspalic acid, the second step being performed by the elymoclavine oxidase cloA (PubMed:16538694, PubMed:17720822). Paspalic acid is then further converted to D-lysergic acid (PubMed:15904941). Ergopeptines are assembled from D-lysergic acid and three different amino acids by the D-lysergyl-peptide-synthetases composed each of a monomudular and a trimodular nonribosomal peptide synthetase subunit (PubMed:14700635, PubMed:15904941). LpsB and lpsC encode the monomodular subunits responsible for D-lysergic acid activation and incorporation into the ergopeptine backbone (PubMed:14700635). LpsA1 and A2 subunits encode the trimodular nonribosomal peptide synthetase assembling the tripeptide portion of ergopeptines (PubMed:14700635). LpsA1 is responsible for formation of the major ergopeptine, ergotamine, and lpsA2 for alpha-ergocryptine, the minor ergopeptine of the total alkaloid mixture elaborated by C.purpurea (PubMed:17560817, PubMed:19139103). D-lysergyl-tripeptides are assembled by the nonribosomal peptide synthetases and released as N-(D-lysergyl-aminoacyl)-lactams (PubMed:24361048). Cyclolization of the D-lysergyl-tripeptides is performed by the Fe(2+)/2-ketoglutarate-dependent dioxygenase easH which introduces a hydroxyl group into N-(D-lysergyl-aminoacyl)-lactam at alpha-C of the aminoacyl residue followed by spontaneous condensation with the terminal lactam carbonyl group (PubMed:24361048). {ECO:0000250|UniProtKB:Q50EL0, ECO:0000269|PubMed:14700635, ECO:0000269|PubMed:14732265, ECO:0000269|PubMed:15904941, ECO:0000269|PubMed:16538694, ECO:0000269|PubMed:17560817, ECO:0000269|PubMed:19139103, ECO:0000269|PubMed:20118373, ECO:0000269|PubMed:20735127, ECO:0000269|PubMed:21409592, ECO:0000269|PubMed:21494745, ECO:0000269|PubMed:24361048, ECO:0000305|PubMed:17308187, ECO:0000305|PubMed:17720822}. |
| Temperature Dependency | |
| PH Dependency | |
| Pathway | PATHWAY: Alkaloid biosynthesis; ergot alkaloid biosynthesis. {ECO:0000305|PubMed:15904941}. |
| nucleotide Binding | |
| Features | Active site (1); Chain (1); Compositional bias (1); Metal binding (1); Region (2) |
| Keywords | Alkaloid metabolism;Heme;Hydrogen peroxide;Iron;Metal-binding;Oxidoreductase;Peroxidase;Reference proteome |
| 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 | 53,510 |
| Kinetics | |
| Metal Binding | METAL 344; /note=Iron (heme axial ligand); /evidence=ECO:0000250|UniProtKB:P15202 |
| Rhea ID | |
| Cross Reference Brenda |