Glutathione combined reduced thiol

However, the reaction of NP with thiols may be a necessary but not sufficient cause for the release of NO from the ion as there are many thiols in frog heart tissue and NP is a vasodilator only under illumination. Furthermore Sogo et al. [50] could not detect NO generation from NP in human plasma containing cysteine, glutathione, homocysteine and reduced cysteine residues. Therefore, there must be a unique component of mammalian tissues which is involved in the release of NO from NP, and this reaction comes after reaction with thiol. Kowaluk et al. [51] report that NP is readily metabolised to NO in subcellular fractions of bovine coronary arterial smooth muscle and that the dominant site of metabolism is in the membrane fraction. This led to the isolation of a small membrane-bound protein or enzyme that can convert NP into NO. The mechanism shown in Scheme 8.2 combines the thiol reaction and that with an enzyme. 

Copper reduces glutathione, which is necessary for normal cell viability. The amino acid transferases are inhibited in the presence of excess copper lipid peroxidation also occurs. Copper combines with thiol groups, which reduces the oxidation state II to I in copper and oxidizes the thiol groups to disulfides, especially in the cell membrane. 

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