Abstract
In an effort to generate more stable reaction intermediates involved in substrate oxidation by nitric-oxide synthases (NOSs), we have cloned, expressed, and characterized a thermostable NOS homolog from the thermophilic bacterium Geobacillus stearothermophilus (gsNOS). As expected, gsNOS forms nitric oxide (NO) from l-arginine via the stable intermediate N-hydroxy l-arginine (NOHA). The addition of oxygen to ferrous gsNOS results in long-lived heme-oxy complexes in the presence (Soret peak 427 nm) and absence (Soret peak 413 nm) of substrates l-arginine and NOHA. The substrate-induced red shift correlates with hydrogen bonding between substrate and heme-bound oxygen resulting in conversion to a ferric heme-superoxy species. In single turnover experiments with NOHA, NO forms only in the presence of H(4)B. The crystal structure of gsNOS at 3.2 AA of resolution reveals great similarity to other known bacterial NOS structures, with the exception of differences in the distal heme pocket, close to the oxygen binding site. In particular, a Lys-356 (Bacillus subtilis NOS) to Arg-365 (gsNOS) substitution alters the conformation of a conserved Asp carboxylate, resulting in movement of an Ile residue toward the heme. Thus, a more constrained heme pocket may slow ligand dissociation and increase the lifetime of heme-bound oxygen to seconds at 4 degrees C. Similarly, the ferric-heme NO complex is also stabilized in gsNOS. The slow kinetics of gsNOS offer promise for studying downstream intermediates involved in substrate oxidation.
Highlights
Found in a variety of lower eukaryotes including insects, fungi (4 –7), and bacteria [8, 9]
The protein has 65% sequence identity when compared with the nitric-oxide synthases (NOSs) protein from the related mesophile B. subtilis (Supplemental Fig. 1)
We demonstrate that gsNOS produces nitrite from L-arginine and NOHA in the peroxide shunt reaction and an optical signal characteristic of bona fide nitric oxide (NO) in single turnover experiments when only NOHA and H4B are present
Summary
Found in a variety of lower eukaryotes including insects, fungi (4 –7), and bacteria [8, 9]. L-arginine is first hydroxylated at the guanidino nitrogen, and the resultant N-hydroxy-L-arginine (NOHA), an enzyme-bound intermediate [19], is further oxidized to NO and citrulline In both the L-arginine and NOHA reactions, reduction of the Fe(III) heme enables oxygen binding and formation of a heme-dioxygen complex, which is best described as a ferric superoxy species (Fe(III)-O2. In B. subtilis NOS (bsNOS), the release of NO is 20-fold slower than that in mammalian NOSs due to a bacterially conserved Val to Ile switch, which offers more steric hindrance for the heme-bound NO to diffuse away from the heme. The NOS heme pocket can tune the reactivity of heme ligands
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