Site-directed mutants of cytochrome P-450cam (the cytochrome P-450 that acts as the terminal monooxygenase in the d-camphor monooxygenase system), in which threonine-252 had been changed to alanine, valine, or serine, were employed to study the role of the hydroxy amino acid in the monooxygenase reaction. The mutant enzymes were expressed in Escherichia coli and were purified by a conventional method. All the mutant enzymes in the presence of d-camphor exhibited optical absorption spectra almost indistinguishable from those of the wild-type enzyme in their ferric, ferrous, oxygenated, and carbon monoxide ferrous forms. In a reconstituted system with putidaredoxin and its reductase, the alanine enzyme consumed O2 at a rate (1100 per min per heme) comparable to that of the wild-type enzyme (1330 per min per heme), whereas the amount of exo-5-hydroxycamphor formed was less than 10% of that formed by the wild-type enzyme. About 85% of the O2 consumed was recovered as H2O2. The valine enzyme also exhibited an oxidase activity to yield H2O2 accompanied by a relative decrease in the monooxygenase activity. On the other hand, the serine enzyme exhibited essentially the same monooxygenase activity as that of the wild-type enzyme. Thus, uncoupling of O2 consumption from the monooxygenase function was produced by the substitution of an amino acid without a hydroxyl group. When binding of O2 to the ferrous forms was examined, the alanine and valine enzymes formed instantaneously an oxygenated form, which slowly decomposed to the ferric form with rates of 5.5 and 3.2 x 10(-3) sec-1 for the former and latter enzymes, respectively. Since these rates were too slow to account for the overall rates of O2 consumption, the formation of H2O2 was considered to proceed not by way of this route but through the decomposition of a peroxide complex formed by reduction of the oxygenated form by reduced putidaredoxin. Based on these findings, a possible mechanism for oxygen activation in this monooxygenase reaction has been discussed.
Cytochrome P450cam (CYP101) of Pseudomonas
putida PpGl in which Arg112 is substituted by Cys was isolated by in vitro random mutagenesis of the camC gene DNA coding for P450cam. The absorption spectra of the purified mutant enzyme were similar to those of the wild type enzyme, but its substrate‐dependent NADH oxidation activity in the presence of putidaredoxin (Pd) and putidaredoxin reductase (PdR) was extremely low. The rate constant of electron transfer from reduced Pd to the heme of the mutant P450cam, measured on an anaerobic stopped flow apparatus, was 1/400 of that of the wild type enzyme and the dissociation constant of the mutant P450cam for oxidized Pd was several fold higher than that of the wild type enzyme. A considerable decrease in mid‐point potential of the mutant enzyme was also noted. We conclude that Arg112, which is located on the surface of the P450cam molecule and hydrogen‐bonded to one of the heme propionate chains, plays an essential role in the electron transfer from Pd.
When gold is deposited as nanoparticles (NPs) with mean diameters of 2-5 nm or clusters with mean diameters below 2 nm onto a variety of supports such as metal oxides, carbons, polymers, etc., the supported Au NPs exhibit unique catalytic properties, while bulk Au is almost inert as a catalyst. A lot of research works indicate that the key factors of the catalysis by supported Au NPs are the selection of the supports, the control of the Au NP size, the shape of the Au NPs, and the strong junction between Au NPs and the supports, because the perimeter zone around Au NPs acts as the active site for many reactions. In order to elucidate the origin of catalysis by supported Au NPs, the interplay between physicochemical analysis, computational studies, and rational experiments for catalysis by supported Au NPs is becoming more and more important. This article summarizes our experiences and progress in such interplay.
Pseudomonas putida PpGl, which carries the CAM plasmid encoding enzymes involved in the degradation pathway of D-camphor, can utilize D-camphor as a sole carbon source. Cytochrome P-450cam and related enzymes participate in the early oxidation steps of D-camphor degradation metabolism. We cloned from a HindIII DNA library of PpGl a 2.9 kbp CAM segment which carries the major part of camA gene encoding NADH-putidaredoxin reductase and the entire camB gene encoding putidaredoxin. The 2.9 kbp CAM segment was adjacent to the 4.27 kbp HindIII CAM segment which has been previously cloned (Koga et al. (1986) J. Bacteriol. 166, 1089-1095). Thus, the total 7.17 kbp HindIII CAM directed all the genes responsible for early steps of D-camphor degradation, i.e. 5-exo-hydroxycamphor dehydrogenase (camD gene), cytochrome P-450cam (camC), NADH-putidaredoxin reductase (camA), and putidaredoxin (camB). These cam genes form an operon, camDCAB, and are under negative control by the gene camR located immediately upstream from the camD gene. The total number of amino acids deduced from the nucleotide sequence is 422 for putidaredoxin reductase, and 106 for putidaredoxin.
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