Ureohydrolase domain <p>The ureohydrolase superfamily includes arginase (<db_xref db="EC" dbkey="3.5.3.1"/>), agmatinase (<db_xref db="EC" dbkey="3.5.3.11"/>), formiminoglutamase (<db_xref db="EC" dbkey="3.5.3.8"/>) and proclavaminate amidinohydrolase (<db_xref db="EC" dbkey="3.5.3.22"/>) [<cite idref="PUB00028086"/>]. These enzymes share a 3-layer alpha-beta-alpha structure [<cite idref="PUB00028086"/>, <cite idref="PUB00028087"/>, <cite idref="PUB00025337"/>], and play important roles in arginine/agmatine metabolism, the urea cycle, histidine degradation, and other pathways. </p><p>Arginase, which catalyses the conversion of arginine to urea and ornithine,is one of the five members of the urea cycle enzymes that convert ammoniato urea as the principal product of nitrogen excretion [<cite idref="PUB00001437"/>]. There are several arginase isozymes that differ in catalytic, molecular and immunological properties. Deficiency in the liver isozyme leads to argininemia, which is usually associated with hyperammonemia.</p><p>Agmatinase hydrolyses agmatine to putrescine, the precursor for the biosynthesis of higher polyamines, spermidine and spermine. In addition, agmatine may play an important regulatory role in mammals. </p><p> Formiminoglutamase catalyses the fourth step in histidine degradation, acting to hydrolyse N-formimidoyl-L-glutamate to L-glutamate and formamide.</p><p> Proclavaminate amidinohydrolase is involved in clavulanic acid biosynthesis. Clavulanic acid acts as an inhibitor of a wide range of beta-lactamase enzymes that are used by various microorganisms to resist beta-lactam antibiotics. As a result, this enzyme improves the effectiveness of beta-lactamase antibiotics [<cite idref="PUB00025337"/>].</p><p>This entry represents the 3-layer alpha-beta-alpha domain which characterises the ureohydrolase superfamily. </p>