From sequence and structure of sulfotransferases and dihydropyrimidinases to an understanding of their mechanisms of action and function
- PMID: 20397966
- DOI: 10.1517/17425251003601987
From sequence and structure of sulfotransferases and dihydropyrimidinases to an understanding of their mechanisms of action and function
Abstract
Importance of the field: Most enzymes that catalyze physiologically important reactions are known to be highly efficient and specific to their particular substrates. On the contrary, the enzymes of detoxification are known to catalyze unlimited number of substrates containing similar function groups that may have significant structural variation. This review explores nature's strategy to design enzymes with special properties.
Areas covered in this review: We review articles from 1981 to 2009, with special focus on the relationships of sequence, structure and function of cytosolic sulfotransferases and dihydropyrimidinase (DHP).
What the reader will gain: Specific amino acids responsible for substrate inhibition, substrate binding orientations, substrate specificity, quaternary structures and inactivation of sulfotransferases and DHP related enzymes are elucidated. Susceptibility to some diseases possibly resulted from the mutation of a single amino acid that causes dysfunction of these enzymes. Terminal deletion of amino acid that may affect surface interaction, subunit dissociation, stability alteration and then cause the syndrome of DHP deficiency is discussed.
Take home message: Based on the multiple sequence/structure analysis and with sufficient information from other members of the same enzyme families, the origin and mechanism of specific enzyme actions and proteins assembly can be clarified and predicted.
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