The domain within your query sequence starts at position 147 and ends at position 692; the E-value for the An_peroxidase domain shown below is 4.2e-183.

YRTITGHCNNRRSPTLGASNRAFVRWLPAEYEDGVSMPFGWTPGVNRNGFKVPLARQVSN
AIVRFPNDQLTKDQERALMFMQWGQFLDHDITLTPEPATRFSFFTGLNCETSCLQQPPCF
PLKIPPNDPRIKNQKDCIPFFRSCPACTRNNITIRNQINALTSFVDASGVYGSEDPLARK
LRNLTNQLGLLAINTRFQDNGRALMPFDSLHDDPCLLTNRSARIPCFLAGDMRSSEMPEL
TSMHTLFVREHNRLATQLKRLNPRWNGEKLYQEARKIVGAMVQIITYRDYLPLVLGPAAM
KKYLPQYRSYNDSVDPRIANVFTNAFRYGHTLIQPFMFRLNNQYRPTGPNPRVPLSKVFF
ASWRVVLEGGIDPILRGLMATPAKLNRQNQIVVDEIRERLFEQVMRIGLDLPALNMQRSR
DHGLPGYNAWRRFCGLPQPSTVGELGTVLKNLELARKLMAQYGTPNNIDIWMGGVSEPLE
PNGRVGQLLACLIGTQFRKLRDGDRFWWENPGVFSKQQRQALASISLPRIICDNTGITTV
SKNNIF

An_peroxidase

An_peroxidase
PFAM accession number:PF03098
Interpro abstract (IPR019791):

Peroxidases are haem-containing enzymes that use hydrogen peroxide as the electron acceptor to catalyse a number of oxidative reactions.

Peroxidases are found in bacteria, fungi, plants and animals. On the basis of sequence similarity, a number of animal haem peroxidases can be categorised as members of a superfamily: myeloperoxidase (MPO); eosinophil peroxidase (EPO); lactoperoxidase (LPO); thyroid peroxidase (TPO); prostaglandin H synthase (PGHS); and peroxidasin [ (PUBMED:8062820) (PUBMED:7922023) (PUBMED:2840655) ].

MPO plays a major role in the oxygen-dependent microbicidal system of neutrophils. EPO from eosinophilic granulocytes participates in immunological reactions, and potentiates tumor necrosis factor (TNF) production and hydrogen peroxide release by human monocyte-derived macrophages [ (PUBMED:2548579) (PUBMED:7774640) ]. In the main, MPO (and possibly EPO) utilises Cl - ions and H 2 O 2 to form hypochlorous acid (HOCl), which can effectively kill bacteria or parasites. In secreted fluids, LPO catalyses the oxidation of thiocyanate ions (SCN - ) by H 2 O 2 producing the weak oxidising agent hypothiocyanite (OSCN - ), which has bacteriostatic activity [ (PUBMED:6295491) ]. TPO uses I - ions and H 2 O 2 to generate iodine, and plays a central role in the biosynthesis of thyroid hormones T(3) and T(4).

To date, the 3D structures of MPO and PGHS have been reported. MPO is a homodimer: each monomer consists of a light (A or B) and a heavy (C or D) chain resulting from post-translational excision of 6 residues from the common precursor. Monomers are linked by a single inter-chain disulphide. Each monomer includes a bound calcium ion [ (PUBMED:1320128) ]. PGHS exists as a symmetric dimer, each monomer of which consists of 3 domains: an N-terminal epidermal growth factor (EGF) like module; a membrane-binding domain; and a large C-terminal catalytic domain containing the cyclooxygenase and the peroxidase active sites. The catalytic domain shows striking structural similarity to MPO. The cyclooxygenase active site, which catalyses the formation of prostaglandin G2 (PGG2) from arachidonic acid, resides at the apex of a long hydrophobic channel, extending from the membrane-binding domain to the centre of the molecule. The peroxidase active site, which catalyses the reduction of PGG2 to PGH2, is located on the other side of the molecule, at the haem binding site [ (PUBMED:8121489) ]. Both MPO and the catalytic domain of PGHS are mainly alpha-helical, 19 helices being identified as topologically and spatially equivalent; PGHS contains 5 additional N-terminal helices that have no equivalent in MPO. In both proteins, three Asn residues in each monomer are glycosylated.

This is a PFAM domain. For full annotation and more information, please see the PFAM entry An_peroxidase