Nitric oxide synthesis heme role

Recent investigations have shed light on peculiarities of the NOS action mechanism the role of the H4B cofactor and CaM, and cooperativity in kinetic and thermodynamic properties of different components of the nitric oxide synthesis system. Stop flow experiments with eNOS (Abu-Soud et al., 2000) showed that calmodulin binding caused an increase in NADH-dependent flavin reduction from 0.13 to 86 s 1 at 10 °C. Under such conditions, in the presence of Arg, heme is reduced very slowly (0.005 s 1). Heme complex formation requires a relatively high concentration ofNO (>50 nM) and inhibits the entire process NADH oxidation and citrulline synthesis decreases 3-fold and Km increases 3-fold. NOS reactions were monitored at subzero temperatures in the presence of 50% ethylene glycol as an anti-freeze solvent (Bee et al., 1998). 

FIGURE I Role for calmodulin (CaM) in triggering interdomain electron transfer to the nitric oxide synthase (NOS) heme iron. Electrons derived from NADPH can transfer only into the flavin centers of CaM-free neuronal NOS (A). CaM binding to NOS occurs in response to elevated Ca concentrations, and this enables electrons to transfer from the flavins to the heme iron. Heme iron reduction is associated with increased NADPH oxidation and results in (B) superoxide (O2) production in the absence of L-arginine or (C) nitric oxide (NO) synthesis in the presence of L-arginine. FAD, Flavin-adenine dinucleotide FMN, flavin mononucleotide. 

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