Evolution and functional classification of mammalian copper amine oxidases.

Mammalian copper-containing amine oxidases (CAOs), encoded by four genes (AOC1-4) and catalyzing the oxidation of primary amines to aldehydes, regulate many biological processes and are linked to various diseases including inflammatory conditions and histamine intolerance. Despite the known differences in their substrate preferences, CAOs are currently classified based on their preference for either primary monoamines (EC 1.4.3.21) or diamines (EC 1.4.3.22). Here, we present the first extensive phylogenetic study of CAOs that, combined with structural analyses of the CAO active sites, provides in-depth knowledge of their relationships and guidelines for classification of mammalian CAOs into AOC1-4 sub-families. The phylogenetic results show that CAOs can be classified based on two residues, X1 and X2, from the active site motif: T/S-X1-X2-N-Y-D. Residue X2 discriminates among the AOC1 (Tyr), AOC2 (Gly), and AOC3/AOC4 (Leu) proteins, while residue X1 further classifies the AOC3 (Leu) and AOC4 (Met) proteins that so far have been poorly identified and annotated. Residues X1 and X2 conserved within each sub-family and located in the catalytic site seem to be the key determinants for the unique substrate preference of each CAO sub-family. Furthermore, one residue located at 10 Šdistance from the catalytic site is different between the sub-families but highly conserved within each sub-family (Asp in AOC1, His in AOC2, Thr in AOC3 and Asn in AOC4) and likely contributes to substrate selectivity. Altogether, our results will benefit the design of new sub-family specific inhibitors and the design of in vitro tests to detect individual CAO levels for diagnostic purposes.

Cell surface monoamine oxidases: enzymes in search of a function.

Ectoenzymes with a catalytically active domain outside the cell surface have the potential to regulate multiple biological processes. A distinct class of copper-containing semicarbazide-sensitive monoamine oxidases, expressed on the cell surface and in soluble forms, oxidatively deaminate primary amines. Via transient covalent enzyme-substrate intermediates, this reaction results in production of aldehydes, hydrogen peroxide and ammonium, which are all biologically active substances. The physiological functions of these enzymes have remained unknown, although they have been suggested to be involved in the metabolism of biogenic amines. Recently, new roles have been proposed for these enzymes in regulation of glucose uptake and, even more surprisingly, in leukocyte-endothelial cell interactions. The emerging functions of ectoenzymes in signalling and cell-cell adhesion suggest a novel mode of molecular control of these complex processes.

Variation in semicarbazide-sensitive amine oxidase activity in plasma and tissues of mammals.

Semicarbazide-sensitive amine oxidase (SSAO) (E.C. 1.4.3.6) is a group of enzymes with as yet poorly understood function which is widely present in nature. The variation in methodology for determination of activity, differences in substrates used and in nomenclature have made it difficult to compare SSAO in different species and tissues. Since SSAO is implicated in the pathophysiology of diabetes mellitus and congestive heart failure, our aim was to analyse the importance and abundance of SSAO in human plasma and tissues compared to other mammals. In plasma of ten different mammals, Vmax values were found to vary more than 10,000-fold, while KM differed much less; in human plasma SSAO activity is relatively low. In some species more than one SSAO entity was present in plasma. SSAO activity was ubiquitous in tissues of human, rat and pig, but varied considerably, both between species and between tissues. In human tissues, SSAO activity is higher than in tissues from rat and pig. Relative to monoamine oxidase-B there is also wide variation in SSAO, with much higher relative activities in human than in rat and pig tissues. We conclude that in plasma, SSAO activity is highest in ruminants, while in tissues, SSAO activity is more prominently present in human than in rat and pig.