Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Drug
Enzyme
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Target Concepts:
Gene/Protein
Disease
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Enzyme
Compound
Query: EC:1.16.3.1 (
ceruloplasmin
)
5,074
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The phenoxazinone chromophore occurs in a variety of biological systems, including numerous pigments and certain antibiotics. It also appears to form as part of a mechanism to protect mammalian tissue from oxidative damage. During cultivation of the basidiomycete, Pycnoporus cinnabarinus, a red pigment was observed to accumulate in the culture medium. It was identified as the phenoxazinone derivative, cinnabarinic acid (CA). Laccase was the predominant extracellular phenoloxidase activity in P. cinnabarinus cultures. In vitro studies showed that CA was formed after oxidation of the precursor,
3-hydroxyanthranilic acid
(3-HAA), by laccases. Moreover, oxidative coupling of 3-HAA to form CA was also demonstrated for the mammalian counterpart of laccase, the blue copper oxidase,
ceruloplasmin
.
...
PMID:Laccase-mediated formation of the phenoxazinone derivative, cinnabarinic acid. 749 42
Almost all iron uptake by fungi involves reduction from Fe(III) to Fe(II) in order to facilitate ligand exchange. This leads to two mechanisms: uptake before reduction, or reduction before uptake. Many fungi secrete specific hydroxamate siderophores when short of iron. The mechanism with uptake before reduction is described in the context of siderophore synthesis and usage, since it applies to many (but not all) siderophores. The hydroxamate functional group is synthesized from ornithine by N5 hydroxylation and acylation. In most fungal siderophores, two or three modified ornithines are joined together by a non-ribosomal peptide synthetase. The transcription of these genes is regulated by an iron activated repressor. There is evidence that the iron-free siderophore may be stored in intracellular vesicles until secretion is required. After loading with iron, re-entry is likely to be via a proton symport. In some fungi, siderophores are used for iron storage. The iron is liberated by an NADPH-linked reductase. The second mechanism starts with Fe(III) reduction. In yeast, this is catalysed by an NADPH-linked transmembrane reductase, which has homology with the NADPH oxidase of neutrophils. There are two closely similar reductases with overlapping roles in Fe(III) and Cu(II) reduction, while the substrates for reduction include Fe(III)-siderophores. External reductants, which may be important in certain fungi, include
3-hydroxyanthranilic acid
, melanin, cellobiose dehydrogenase and 2,5-dimethylhydroquinone. In yeast, a high-affinity iron uptake pathway involves reoxidation of Fe(II) to Fe(III), probably to confer specificity for iron. This is catalysed by a copper protein which has homology with
ceruloplasmin
, and is closely coupled to Fe(III) transport. The transcription of these genes is regulated by an iron-inhibited activator. Because of its copper requirement, the high-affinity pathway is blocked by disruption of genes for copper metabolism. A low-affinity uptake transports Fe(II) directly and is important in anoxic growth. In many fungi, mechanisms with internal or external reduction are both important. The external reduction is applicable to almost any Fe(III) complex, while internal reduction is more efficient at low iron but requires a siderophore permease through which toxins might enter. Both mechanisms require close coupling of Fe(III) reduction and Fe(II) utilization in order to minimize production of active oxygen.
...
PMID:Iron uptake by fungi: contrasted mechanisms with internal or external reduction. 1090 54
A gene (yacK) encoding a putative multicopper oxidase (MCO) was cloned from Escherichia coli, and the expressed enzyme was demonstrated to exhibit phenoloxidase and
ferroxidase
activities. The purified protein contained six copper atoms per polypeptide chain and displayed optical and electron paramagnetic resonance (EPR) spectra consistent with the presence of type 1, type 2, and type 3 copper centers. The strong optical A(610) (E(610) = 10,890 M(-1) cm(-1)) and copper stoichiometry were taken as evidence that, similar to
ceruloplasmin
, the enzyme likely contains multiple type 1 copper centers. The addition of copper led to immediate and reversible changes in the optical and EPR spectra of the protein, as well as decreased thermal stability of the enzyme. Copper addition also stimulated both the phenoloxidase and
ferroxidase
activities of the enzyme, but the other metals tested had no effect. In the presence of added copper, the enzyme displayed significant activity against two of the phenolate siderophores utilized by E. coli for iron uptake, 2,3-dihydroxybenzoate and enterobactin, as well as
3-hydroxyanthranilate
, an iron siderophore utilized by Saccharomyces cerevisiae. Oxidation of enterobactin produced a colored precipitate suggestive of the polymerization reactions that characterize microbial melanization processes. As oxidation should render the phenolate siderophores incapable of binding iron, yacK MCO activity could influence levels of free iron in the periplasm in response to copper concentration. This mechanism may explain, in part, how yacK MCO moderates the sensitivity of E. coli to copper.
...
PMID:Oxidation of phenolate siderophores by the multicopper oxidase encoded by the Escherichia coli yacK gene. 1146 90
