Uncompetitive substrate inhibition and noncompetitive inhibition by 5- n-undecyl-6-hydroxy-4,7-dioxobenzothiazole (UHDBT) and 2-n-nonyl-4- hydroxyquinoline-N-oxide (NQNO) is observed for the cytochrome bo3 complex

Implications for a Q(H2)-loop proton translocation mechanism

S. M. Musser, M. H.B. Stowell, Kay Lee Hung Kay Lee, J. N. Rumbley, S. I. Chan

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Abstract

The cytochrome bo3 ubiquinol oxidase complex from Escherichia coli contains two binding sites for ubiquinone(ol) (UQ(H2)). One of these binding sites, the ubiquinol oxidation site, is clearly in dynamic equilibrium with the UQ(H2) pool in the membrane. The second site has a high affinity for ubiquinone (UQ), stabilizes a semiquinone species, and is located physically close to the low-spin heme b component of the enzyme. The UQ molecule in this site has been proposed to remain strongly bound to the enzyme during enzyme turnover and to act as a cofactor facilitating the transfer of electrons from the substrate ubiquinol to heme b [Sato-Watanabe et al. (1994) J. Biol. Chem. 269, 28908-28912]. In this paper, the steady-state turnover of the enzyme is examined in the presence and absence of inhibitors (UHDBT and NQNO) that appear to be recognized as ubisemiquinone analogs. It is found that the kinetics are accounted for best by a noncompetitive inhibitor binding model. Furthermore, at high concentrations, the substrates ubiquinol-1 and ubiquinol-2 inhibit turnover in an uncompetitive fashion. Together, these observations strongly suggest that there must be at least two UQ(H2) binding sites that are in rapid equilibrium with the UQ(H2) pool under turnover conditions. Although these data do not rule out the possibility that a strongly bound UQ molecule functions to facilitate electron transfer to heme b, they are more consistent with the behavior expected if the two UQ(H2) binding sites were to function in a Q(H2)loop mechanism (similar to that of the cytochrome bc1 complex) as originally proposed by Musser and co-workers [(1993) FEBS Lett. 327, 131-136]. In this model, ubiquinol is oxidized at one site and ubiquinone is reduced at the second site. While the structural similarities of the heme-copper ubiquinol and cytochrome c oxidase complexes suggest the possibility that these two families of enzymes translocate protons by similar mechanisms, the current observations indicate that the Q(H2)-loop proton translocation mechanism for the heme-copper ubiquinol oxidase complexes should be further investigated and experimentally tested.

Original languageEnglish (US)
Pages (from-to)894-902
Number of pages9
JournalBiochemistry
Volume36
Issue number4
DOIs
StatePublished - Mar 20 1997

Fingerprint

Ubiquinone
Cytochromes
Protons
Substrates
Heme
Binding Sites
Enzymes
coenzyme Q10
Copper
nonyl-4-hydroxyquinoline-N-oxide
5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole
2-nonyl-4-hydroxyquinoline
Electrons
Molecules
Electron Transport Complex III
Electron Transport Complex IV
Escherichia coli
ubiquinol
Membranes
Oxidation

Cite this

@article{23835ab4cf004966a3ab26405201d16c,
title = "Uncompetitive substrate inhibition and noncompetitive inhibition by 5- n-undecyl-6-hydroxy-4,7-dioxobenzothiazole (UHDBT) and 2-n-nonyl-4- hydroxyquinoline-N-oxide (NQNO) is observed for the cytochrome bo3 complex: Implications for a Q(H2)-loop proton translocation mechanism",
abstract = "The cytochrome bo3 ubiquinol oxidase complex from Escherichia coli contains two binding sites for ubiquinone(ol) (UQ(H2)). One of these binding sites, the ubiquinol oxidation site, is clearly in dynamic equilibrium with the UQ(H2) pool in the membrane. The second site has a high affinity for ubiquinone (UQ), stabilizes a semiquinone species, and is located physically close to the low-spin heme b component of the enzyme. The UQ molecule in this site has been proposed to remain strongly bound to the enzyme during enzyme turnover and to act as a cofactor facilitating the transfer of electrons from the substrate ubiquinol to heme b [Sato-Watanabe et al. (1994) J. Biol. Chem. 269, 28908-28912]. In this paper, the steady-state turnover of the enzyme is examined in the presence and absence of inhibitors (UHDBT and NQNO) that appear to be recognized as ubisemiquinone analogs. It is found that the kinetics are accounted for best by a noncompetitive inhibitor binding model. Furthermore, at high concentrations, the substrates ubiquinol-1 and ubiquinol-2 inhibit turnover in an uncompetitive fashion. Together, these observations strongly suggest that there must be at least two UQ(H2) binding sites that are in rapid equilibrium with the UQ(H2) pool under turnover conditions. Although these data do not rule out the possibility that a strongly bound UQ molecule functions to facilitate electron transfer to heme b, they are more consistent with the behavior expected if the two UQ(H2) binding sites were to function in a Q(H2)loop mechanism (similar to that of the cytochrome bc1 complex) as originally proposed by Musser and co-workers [(1993) FEBS Lett. 327, 131-136]. In this model, ubiquinol is oxidized at one site and ubiquinone is reduced at the second site. While the structural similarities of the heme-copper ubiquinol and cytochrome c oxidase complexes suggest the possibility that these two families of enzymes translocate protons by similar mechanisms, the current observations indicate that the Q(H2)-loop proton translocation mechanism for the heme-copper ubiquinol oxidase complexes should be further investigated and experimentally tested.",
author = "Musser, {S. M.} and Stowell, {M. H.B.} and {Hung Kay Lee}, {Kay Lee} and Rumbley, {J. N.} and Chan, {S. I.}",
year = "1997",
month = "3",
day = "20",
doi = "10.1021/bi961723r",
language = "English (US)",
volume = "36",
pages = "894--902",
journal = "Biochemistry",
issn = "0006-2960",
publisher = "American Chemical Society",
number = "4",

}

TY - JOUR

T1 - Uncompetitive substrate inhibition and noncompetitive inhibition by 5- n-undecyl-6-hydroxy-4,7-dioxobenzothiazole (UHDBT) and 2-n-nonyl-4- hydroxyquinoline-N-oxide (NQNO) is observed for the cytochrome bo3 complex

T2 - Implications for a Q(H2)-loop proton translocation mechanism

AU - Musser, S. M.

AU - Stowell, M. H.B.

AU - Hung Kay Lee, Kay Lee

AU - Rumbley, J. N.

AU - Chan, S. I.

PY - 1997/3/20

Y1 - 1997/3/20

N2 - The cytochrome bo3 ubiquinol oxidase complex from Escherichia coli contains two binding sites for ubiquinone(ol) (UQ(H2)). One of these binding sites, the ubiquinol oxidation site, is clearly in dynamic equilibrium with the UQ(H2) pool in the membrane. The second site has a high affinity for ubiquinone (UQ), stabilizes a semiquinone species, and is located physically close to the low-spin heme b component of the enzyme. The UQ molecule in this site has been proposed to remain strongly bound to the enzyme during enzyme turnover and to act as a cofactor facilitating the transfer of electrons from the substrate ubiquinol to heme b [Sato-Watanabe et al. (1994) J. Biol. Chem. 269, 28908-28912]. In this paper, the steady-state turnover of the enzyme is examined in the presence and absence of inhibitors (UHDBT and NQNO) that appear to be recognized as ubisemiquinone analogs. It is found that the kinetics are accounted for best by a noncompetitive inhibitor binding model. Furthermore, at high concentrations, the substrates ubiquinol-1 and ubiquinol-2 inhibit turnover in an uncompetitive fashion. Together, these observations strongly suggest that there must be at least two UQ(H2) binding sites that are in rapid equilibrium with the UQ(H2) pool under turnover conditions. Although these data do not rule out the possibility that a strongly bound UQ molecule functions to facilitate electron transfer to heme b, they are more consistent with the behavior expected if the two UQ(H2) binding sites were to function in a Q(H2)loop mechanism (similar to that of the cytochrome bc1 complex) as originally proposed by Musser and co-workers [(1993) FEBS Lett. 327, 131-136]. In this model, ubiquinol is oxidized at one site and ubiquinone is reduced at the second site. While the structural similarities of the heme-copper ubiquinol and cytochrome c oxidase complexes suggest the possibility that these two families of enzymes translocate protons by similar mechanisms, the current observations indicate that the Q(H2)-loop proton translocation mechanism for the heme-copper ubiquinol oxidase complexes should be further investigated and experimentally tested.

AB - The cytochrome bo3 ubiquinol oxidase complex from Escherichia coli contains two binding sites for ubiquinone(ol) (UQ(H2)). One of these binding sites, the ubiquinol oxidation site, is clearly in dynamic equilibrium with the UQ(H2) pool in the membrane. The second site has a high affinity for ubiquinone (UQ), stabilizes a semiquinone species, and is located physically close to the low-spin heme b component of the enzyme. The UQ molecule in this site has been proposed to remain strongly bound to the enzyme during enzyme turnover and to act as a cofactor facilitating the transfer of electrons from the substrate ubiquinol to heme b [Sato-Watanabe et al. (1994) J. Biol. Chem. 269, 28908-28912]. In this paper, the steady-state turnover of the enzyme is examined in the presence and absence of inhibitors (UHDBT and NQNO) that appear to be recognized as ubisemiquinone analogs. It is found that the kinetics are accounted for best by a noncompetitive inhibitor binding model. Furthermore, at high concentrations, the substrates ubiquinol-1 and ubiquinol-2 inhibit turnover in an uncompetitive fashion. Together, these observations strongly suggest that there must be at least two UQ(H2) binding sites that are in rapid equilibrium with the UQ(H2) pool under turnover conditions. Although these data do not rule out the possibility that a strongly bound UQ molecule functions to facilitate electron transfer to heme b, they are more consistent with the behavior expected if the two UQ(H2) binding sites were to function in a Q(H2)loop mechanism (similar to that of the cytochrome bc1 complex) as originally proposed by Musser and co-workers [(1993) FEBS Lett. 327, 131-136]. In this model, ubiquinol is oxidized at one site and ubiquinone is reduced at the second site. While the structural similarities of the heme-copper ubiquinol and cytochrome c oxidase complexes suggest the possibility that these two families of enzymes translocate protons by similar mechanisms, the current observations indicate that the Q(H2)-loop proton translocation mechanism for the heme-copper ubiquinol oxidase complexes should be further investigated and experimentally tested.

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U2 - 10.1021/bi961723r

DO - 10.1021/bi961723r

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VL - 36

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JF - Biochemistry

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