Chemistry, asked by yogiiii7512, 1 year ago

Why desaturase enzyme not changing the double to triple bond?

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Answered by neethupuppy
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Desaturases and related enzymes perform O2-dependent dehydrogenations initiated at unactivated C-H groups with the use of a diiron active site. Determination of the long-sought oxidized desaturase crystal structure facilitated structural comparison of the active sites of disparate diiron enzymes. Experiments on the castor desaturase are discussed that provide experimental support for a hypothesized ancestral oxidase enzyme in the context of the evolution of the diiron enzyme diverse functionality. We also summarize recent analysis of a castor mutant desaturase that provides valuable insights into the relationship of proposed substrate-binding modes with respect to a range of catalytic outcomes.

Desaturase enzymes perform dehydrogenation reactions that result in the introduction of double bonds into fatty acids that are initiated by the energy-demanding abstraction of a hydrogen from a methylene group (1⇓–3). To achieve this, desaturase enzymes recruit and activate molecular oxygen with the use of an active-site diiron cluster (4). The diiron center is common to a variety of proteins, including methane monooxygenase, ribonucleotide reductase, rubrerythrins, and a variety of oxidase enzymes (5). Valuable insights regarding the tuning of diiron centers with respect to diverse chemical reactivity (6) have been made via comparisons of the diiron centers of diiron-containing enzymes (7); however, differences in amino acid sequence, multiple protein-protein interactions, and reaction outcomes complicate the analysis. The study of fatty-acid desaturases and related enzymes presents a unique opportunity for performing enzyme structure-function studies because relatively close homologs perform diverse reactions on similar substrates (8, 9).

Desaturase enzymes have evolved independently twice (10); the acyl-ACP2 desaturases are soluble enzymes found in the plastids of higher plants, whereas the more widespread class of integral membrane desaturases is found in endomembrane systems in prokaryotes and eukaryotes (9). In addition to forming distinct homology groups, their diiron centers possess distinct primary ligation spheres (11). The availability of crystal structures for acyl-ACP desaturases (12) makes this system amenable to detailed structure-function studies. Crystal structures are available for the 18:0 Δ9-desaturase3 (12, 13) from Ricinus communis (castor) and a bifunctional desaturase from Hedera helix (ivy) (14, 15). These desaturases are homodimeric proteins, with each monomer folded into a compact single domain composed of nine helices. The diiron active site of these enzymes is buried within a core four-helix bundle and is positioned alongside a deep, bent, narrow hydrophobic cavity in which the substrate is bound during catalysis. It is a textbook example of a lock-and-key type of binding site in which the bound fatty acid moiety is poised for formation of the cis-fatty acid product.

Nobel Laureate Konrad Bloch observed, “The stereospecific removal of hydrogen in the formation of oleate, although predictable on principle grounds would seem to approach the limits of the discriminatory power of enzymes” (16). Bloch's statement underscores that desaturase enzymes perform highly regio- and stereo-selective reactions on long-chain fatty acids composed of essentially equivalent methylene chains that lack distinguishing landmarks close to the site of desaturation. We will review structural features of the diiron active site of the acyl-ACP desaturases in the context of those of other diiron enzymes, discuss recent insights into the evolution of acyl-ACP desaturases, and summarize recent discoveries relating to the evolution of selectivity and functional diversity within desaturase enzyme families.

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