SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2526391010> ?p ?o ?g. }

Showing items 1 to 100 of ±154 with 100 items per page.

W2526391010 endingPage "5725" @default.
W2526391010 startingPage "5714" @default.
W2526391010 abstract "The respiratory cytochrome bo3 ubiquinol oxidase from Escherichia coli has a high-affinity ubiquinone binding site that stabilizes the one-electron reduced ubisemiquinone (SQH), which is a transient intermediate during the electron-mediated reduction of O2 to water. It is known that SQH is stabilized by two strong hydrogen bonds from R71 and D75 to ubiquinone carbonyl oxygen O1 and weak hydrogen bonds from H98 and Q101 to O4. In this work, SQH was investigated with orientation-selective Q-band (∼34 GHz) pulsed 1H electron-nuclear double resonance (ENDOR) spectroscopy on fully deuterated cytochrome (cyt) bo3 in a H2O solvent so that only exchangeable protons contribute to the observed ENDOR spectra. Simulations of the experimental ENDOR spectra provided the principal values and directions of the hyperfine (hfi) tensors for the two strongly coupled H-bond protons (H1 and H2). For H1, the largest principal component of the proton anisotropic hfi tensor Tz' = 11.8 MHz, whereas for H2, Tz' = 8.6 MHz. Remarkably, the data show that the direction of the H1 H-bond is nearly perpendicular to the quinone plane (∼70° out of plane). The orientation of the second strong hydrogen bond, H2, is out of plane by ∼25°. Equilibrium molecular dynamics simulations on a membrane-embedded model of the cyt bo3 QH site show that these H-bond orientations are plausible but do not distinguish which H-bond, from R71 or D75, is nearly perpendicular to the quinone ring. Density functional theory calculations support the idea that the distances and geometries of the H-bonds to the ubiquinone carbonyl oxygens, along with the measured proton anisotropic hfi couplings, are most compatible with an anionic (deprotonated) ubisemiquinone." @default.
W2526391010 created "2016-10-07" @default.
W2526391010 creator A5002187628 @default.
W2526391010 creator A5008855880 @default.
W2526391010 creator A5011336390 @default.
W2526391010 creator A5015276426 @default.
W2526391010 creator A5024866318 @default.
W2526391010 creator A5048778417 @default.
W2526391010 creator A5067485627 @default.
W2526391010 creator A5087810793 @default.
W2526391010 date "2016-09-28" @default.
W2526391010 modified "2023-10-15" @default.
W2526391010 title "Q-Band Electron-Nuclear Double Resonance Reveals Out-of-Plane Hydrogen Bonds Stabilize an Anionic Ubisemiquinone in Cytochrome bo3 from Escherichia coli" @default.
W2526391010 cites W1492994354 @default.
W2526391010 cites W1523705478 @default.
W2526391010 cites W1548394531 @default.
W2526391010 cites W1810331649 @default.
W2526391010 cites W1850742102 @default.
W2526391010 cites W1898563571 @default.
W2526391010 cites W1964647308 @default.
W2526391010 cites W1965594444 @default.
W2526391010 cites W1966286780 @default.
W2526391010 cites W1968816829 @default.
W2526391010 cites W1972996979 @default.
W2526391010 cites W1973255798 @default.
W2526391010 cites W1976499671 @default.
W2526391010 cites W1983312132 @default.
W2526391010 cites W1984370423 @default.
W2526391010 cites W1988072095 @default.
W2526391010 cites W1989678178 @default.
W2526391010 cites W1990771438 @default.
W2526391010 cites W1991937519 @default.
W2526391010 cites W2010011345 @default.
W2526391010 cites W2013436866 @default.
W2526391010 cites W2023271753 @default.
W2526391010 cites W2024943035 @default.
W2526391010 cites W2028585191 @default.
W2526391010 cites W2029667189 @default.
W2526391010 cites W2031724257 @default.
W2526391010 cites W2033738528 @default.
W2526391010 cites W2033920637 @default.
W2526391010 cites W2035638488 @default.
W2526391010 cites W2035687084 @default.
W2526391010 cites W2037339914 @default.
W2526391010 cites W2038758364 @default.
W2526391010 cites W2039943976 @default.
W2526391010 cites W2040937743 @default.
W2526391010 cites W2042987383 @default.
W2526391010 cites W2047628604 @default.
W2526391010 cites W2052721805 @default.
W2526391010 cites W2055563809 @default.
W2526391010 cites W2060872117 @default.
W2526391010 cites W2064193203 @default.
W2526391010 cites W2066414494 @default.
W2526391010 cites W2067039368 @default.
W2526391010 cites W2067174909 @default.
W2526391010 cites W2067718414 @default.
W2526391010 cites W2092157292 @default.
W2526391010 cites W2093884442 @default.
W2526391010 cites W2094879588 @default.
W2526391010 cites W2096747776 @default.
W2526391010 cites W2109606373 @default.
W2526391010 cites W2110176312 @default.
W2526391010 cites W2124373056 @default.
W2526391010 cites W2133623225 @default.
W2526391010 cites W2143981217 @default.
W2526391010 cites W2150981663 @default.
W2526391010 cites W2152490783 @default.
W2526391010 cites W2154158126 @default.
W2526391010 cites W2163749104 @default.
W2526391010 cites W2166258960 @default.
W2526391010 cites W2168269595 @default.
W2526391010 cites W2170929465 @default.
W2526391010 cites W2171074980 @default.
W2526391010 cites W2175483238 @default.
W2526391010 cites W2327829412 @default.
W2526391010 cites W2950548959 @default.
W2526391010 cites W4238652547 @default.
W2526391010 cites W4245255344 @default.
W2526391010 doi "https://doi.org/10.1021/acs.biochem.6b00669" @default.
W2526391010 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/5558440" @default.
W2526391010 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/27622672" @default.
W2526391010 hasPublicationYear "2016" @default.
W2526391010 type Work @default.
W2526391010 sameAs 2526391010 @default.
W2526391010 citedByCount "8" @default.
W2526391010 countsByYear W25263910102017 @default.
W2526391010 countsByYear W25263910102018 @default.
W2526391010 countsByYear W25263910102019 @default.
W2526391010 countsByYear W25263910102021 @default.
W2526391010 crossrefType "journal-article" @default.
W2526391010 hasAuthorship W2526391010A5002187628 @default.
W2526391010 hasAuthorship W2526391010A5008855880 @default.
W2526391010 hasAuthorship W2526391010A5011336390 @default.
W2526391010 hasAuthorship W2526391010A5015276426 @default.
W2526391010 hasAuthorship W2526391010A5024866318 @default.
W2526391010 hasAuthorship W2526391010A5048778417 @default.
W2526391010 hasAuthorship W2526391010A5067485627 @default.