2017
DOI: 10.1002/ijch.201600136
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Dynamics of the KB Proton Pathway in Cytochrome ba3 from Thermus thermophilus

Abstract: The ba 3 cytochrome c oxidase from Thermus thermophilus is a B-type oxygen-reducing heme-copper oxidase and a proton pump. It uses only one proton pathway for transfer of protons to the catalytic site, the K B pathway. It was previously shown that the ba 3 oxidase has an overall similar reaction sequence to that in mitochondrial-like A-type oxidases. However, the timing of loading the pump site, and formation and decay of catalytic intermediates is different in the two types of oxidases. In the present study, … Show more

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Cited by 7 publications
(8 citation statements)
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References 58 publications
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“…Readers are referred to both primary and recent review articles from key research groups, summarizing a wide variety of observations and results concerning HCO ligand (CO, NO, and O 2 ) binding dynamics and the O 2 -reduction mechanism across a range of HCOs (and see section 4). 879,963,979,991999 Some major conclusions are (i) the widely employed method of studying O 2 -binding kinetics by initially photodissociating CO bound to the heme at the heme–Cu binuclear active site is found to be inhibitory in tT ba 3 CcO but not in bovine aa 3 CcO; in other words, the CO flow-flash method does not accurately reflect the O 2 and NO binding kinetics in tT ba 3 under physiological conditions, namely, in the absence of CO. (ii) tT ba 3 CcO possesses a unique Y- shaped extended hydrophobic tunnel as a very low-barrier passage for O 2 or other ligands entering the heme–Cu active site. Here, in tT ba 3 , the binding of dioxygen (and NO (g) ) is “superfast”; they both occur with rate constants of ~10 9 M −1 s −1 , 912,990 near the diffusion limit (and about 100 times greater than that for myoglobin; also see Table 4).…”
Section: Small Molecule Synthetic Models Of Heme-copper Oxidasesmentioning
confidence: 99%
“…Readers are referred to both primary and recent review articles from key research groups, summarizing a wide variety of observations and results concerning HCO ligand (CO, NO, and O 2 ) binding dynamics and the O 2 -reduction mechanism across a range of HCOs (and see section 4). 879,963,979,991999 Some major conclusions are (i) the widely employed method of studying O 2 -binding kinetics by initially photodissociating CO bound to the heme at the heme–Cu binuclear active site is found to be inhibitory in tT ba 3 CcO but not in bovine aa 3 CcO; in other words, the CO flow-flash method does not accurately reflect the O 2 and NO binding kinetics in tT ba 3 under physiological conditions, namely, in the absence of CO. (ii) tT ba 3 CcO possesses a unique Y- shaped extended hydrophobic tunnel as a very low-barrier passage for O 2 or other ligands entering the heme–Cu active site. Here, in tT ba 3 , the binding of dioxygen (and NO (g) ) is “superfast”; they both occur with rate constants of ~10 9 M −1 s −1 , 912,990 near the diffusion limit (and about 100 times greater than that for myoglobin; also see Table 4).…”
Section: Small Molecule Synthetic Models Of Heme-copper Oxidasesmentioning
confidence: 99%
“…The acidic residue (Asp or Glu) at the entrance of the proton pathway is necessary for fast proton uptake in both the A-family D-pathway as well as in the B- and C-family K-pathway analogues [6, 7, 9, 26, 34, 35]. Interestingly, the effects of alteration of N293, located above the entry point of the K C -pathway, appear to be similar to the N139 Rs of the A-type D-pathway in terms of the linkage to internal proton donors (see [36]), although there is no evolutionary relationship.…”
Section: Discussionmentioning
confidence: 99%
“…This form of ‘convergent evolution’ in HCuOs is observed also for the ‘proton-collecting antenna’ around this Glu [39] and the crosslinked Tyr at the active site which is conserved in space but not in sequence [4, 28]. The relative location of the entry-point Glu is different in K B - and K C -pathways, which means that the region above have to be different as well in order to provide connectivity into the subunit I (or CcoN) part of the pathways (discussed also in [35]). The K B and K C pathways are more similar to each other in composition (lacking the lysine, having mostly Tyr and Thr residues) than they are to the K A -pathway, but the only residue conserved between them is the Y227 (see Fig.…”
Section: Discussionmentioning
confidence: 99%
“…four that are pumped and the remaining two protons used for reduction of O 2 to H 2 O at the catalytic site. In the B-type oxidases all protons are transferred through a single pathway, which approximately overlaps in space with the K pathway in the A-type oxidases 3,6,7 . Hence, there are alternative pathways for transfer of the pumped protons from the n -side in different oxidases.
Figure 1Structural model.
…”
Section: Introductionmentioning
confidence: 99%