Solution structure of Desulfovibrio vulgaris (Hildenborough) ferrocytochrome c 3 : structural basis for functional cooperativity 1 1Edited by P. E. Wright

Messias, Ana C.; Kastrau, Dieter H. W.; Costa, H.S.; LeGall, Jean; Turner, David L.; Santos, Helena; Xavier, António V.

doi:10.1006/jmbi.1998.1974

Cited by 53 publications

(60 citation statements)

References 65 publications

(79 reference statements)

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“…The detailed thermodynamic properties that favor a coupled two-electron step modulated by a redox-Bohr effect in Ddc3, i.e. a proton-assisted two-electron step, are different from those reported for other structurally homologous cytochromes c 3 (2,3,24,32). Thus, the study of these various proteins yields information on the variety of strategies that Nature can employ to achieve a common function using the same structural arrangement of the redox active sites.…”

Section: Discussioncontrasting

confidence: 56%

“…The structural analysis of bacteriorhodopsin trapped in the M photointermediate state (1), the structures in the oxidized and reduced forms of cytochromes c 3 that perform a coupled two-electron step associated with proton transfer (2,3), and the establishment of the coupled transfer of electrons and protons to the 3Fe-4S cluster of Azotobacter vinelandii ferredoxin (4) are just a few recent examples where results from different techniques are integrated in a description at the atomic level of the energy-transducing events. The phenomenon of energy transduction relies on coupled events (5), whether they involve only electrostatic interactions or structural rearrangements of the active sites or its surroundings (mechano-chemical coupling), which may be more important than the electrostatic component of the overall coupling (6).…”

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confidence: 99%

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Conformational Component in the Coupled Transfer of Multiple Electrons and Protons in a Monomeric Tetraheme Cytochrome

Louro¹,

Bento²,

Matías³

et al. 2001

Journal of Biological Chemistry

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Cell metabolism relies on energy transduction usually performed by complex membrane-spanning proteins that couple different chemical processes, e.g. electron and proton transfer in proton-pumps. There is great interest in determining at the molecular level the structural details that control these energy transduction events, particularly those involving multiple electrons and protons, because tight control is required to avoid the production of dangerous reactive intermediates. Tetraheme cytochrome c 3 is a small soluble and monomeric protein that performs a central step in the bioenergetic metabolism of sulfate reducing bacteria, termed "proton-thrusting," linking the oxidation of molecular hydrogen with the reduction of sulfate. The mechanochemical coupling involved in the transfer of multiple electrons and protons in cytochrome c 3 from Desulfovibrio desulfuricans ATCC 27774 is described using results derived from the microscopic thermodynamic characterization of the redox and acid-base centers involved, crystallographic studies in the oxidized and reduced states of the cytochrome, and theoretical studies of the redox and acid-base transitions. This proton-assisted two-electron step involves very small, localized structural changes that are sufficient to generate the complex network of functional cooperativities leading to energy transduction, while using molecular mechanisms distinct from those established for other Desulfovibrio sp. cytochromes from the same structural family.Recent developments in techniques of structural biology have opened the way for probing the mechanisms used by biological macromolecules involved in energy transduction at the molecular level. The structural analysis of bacteriorhodopsin trapped in the M photointermediate state (1), the structures in the oxidized and reduced forms of cytochromes c 3 that perform a coupled two-electron step associated with proton transfer (2, 3), and the establishment of the coupled transfer of electrons and protons to the 3Fe-4S cluster of Azotobacter vinelandii ferredoxin (4) are just a few recent examples where results from different techniques are integrated in a description at the atomic level of the energy-transducing events. The phenomenon of energy transduction relies on coupled events (5), whether they involve only electrostatic interactions or structural rearrangements of the active sites or its surroundings (mechano-chemical coupling), which may be more important than the electrostatic component of the overall coupling (6). The pumping of proton(s) at the beginning of re-reduction of cytochrome c oxidase (7) can be described using a model in which the electrostatic attraction of electrons and protons is overcome (8), a situation that requires structural changes involving charged residues. Small proteins capable of performing energy transduction provide easier access to the structural bases for the underlying mechanisms, as the recent advances in the understanding of the proton pumping by the 26-kDa bacteriorhodopsin demonstrate (1, 9).This wo...

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Section: Discussioncontrasting

confidence: 56%

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confidence: 99%

Conformational Component in the Coupled Transfer of Multiple Electrons and Protons in a Monomeric Tetraheme Cytochrome

Louro¹,

Bento²,

Matías³

et al. 2001

Journal of Biological Chemistry

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“…This is consistent with a relative destabilization of the oxidized state of the protein since the replacement of T24 by valine prevents the formation of a network of hydrogen bonds that stabilizes the oxidized state of the wild type (28).…”

Section: (281)supporting

confidence: 76%

“…In T24VDVHc 3 , differences caused near heme III by the mutation could be responsible for this small variation, through the modulation of the dielectric constant or movement of the ionizable group. Previous work showed that the redox-Bohr effect in DVHc 3 is controlled by heme I propionates and neighboring residues (11,27,28), and since the residue mutated is not located close to heme I, the four macroscopic reduction potentials have a similar pH dependence in both cytochromes, although it is shifted to significantly higher values in T24VDVHc 3 ( Figure 5).…”

Section: (281)mentioning

confidence: 80%

Effect of Hydrogen-Bond Networks in Controlling Reduction Potentials in Desulfovibrio vulgaris (Hildenborough) Cytochrome c₃ Probed by Site-Specific Mutagenesis

et al. 2001

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Cytochromes c 3 isolated from DesulfoVibrio spp. are periplasmic proteins that play a central role in energy transduction by coupling the transfer of electrons and protons from hydrogenase. Comparison between the oxidized and reduced structures of cytochrome c 3 isolated from DesulfoVibrio Vulgaris (Hildenborough) show that the residue threonine 24, located in the vicinity of heme III, reorients between these two states [Messias, A. C., Kastrau, D. H. W., Costa, H. S., LeGall, J., Turner, D. L., Santos, H., and Xavier, A. V. (1998) J. Mol. Biol. 281,. Threonine 24 was replaced with valine by sitedirected mutagenesis to elucidate its effect on the redox properties of the protein. The NMR spectra of the mutated protein are very similar to those of the wild type, showing that the general folding and heme core architecture are not affected by the mutation. However, thermodynamic analysis of the mutated cytochrome reveals a large alteration in the microscopic reduction potential of heme III (75 and 106 mV for the protonated forms of the fully reduced and oxidized states, respectively). The redox interactions involving this heme are also modified, while the remaining heme-heme interactions and the redoxBohr interactions are less strongly affected. Hence, the order of oxidation of the hemes in the mutated cytochrome is different from that in the wild type, and it has a higher overall affinity for electrons. This is consistent with the replacement of threonine 24 by valine preventing the formation of a network of hydrogen bonds, which stabilizes the oxidized state. The mutated protein is unable to perform a concerted two-electron step between the intermediate oxidation stages, 1 and 3, which can occur in the wild-type protein. Thus, replacing a single residue unbalances the global network of cooperativities tuned to control thermodynamically the directionality of the stepwise electron transfer and may affect the functionality of the protein.

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“…Recent studies allowed the identification of the key residues involved in homotropic and/or heterotropic cooperativities in type I cytochromes c 3 from Desulfovibrio gigas (Dg) (9) and Desulfovibrio vulgaris Hildenborough (DvH) (10,11). Site-directed mutagenesis studies were used to further probe the role of some specific residues in the modulation of the redox properties of these proteins (12)(13)(14).…”

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Proton-assisted Two-electron Transfer in Natural Variants of Tetraheme Cytochromes from Desulfomicrobium Sp.

Correia

Paquete

Coelho

et al. 2004

Journal of Biological Chemistry

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The tetraheme cytochrome c 3 isolated from Desulfomicrobium baculatum (DSM 1743) (Dsmb) was cloned, and the sequence analysis showed that this cytochrome differs in just three amino acid residues from the cytochrome c 3 isolated from Desulfomicrobium norvegicum (Dsmn): (DsmnXXDsmb) Thr-37 3 Ser, Val-45 3 Ala, and Phe-88 3 Tyr. X-ray crystallography was used to determine the structure of cytochrome c 3 from Dsmb, showing that it is very similar to the published structure of cytochrome c 3 from Dsmn. A detailed thermodynamic and kinetic characterization of these two tetraheme cytochromes c 3 was performed by using NMR and visible spectroscopy. The results obtained show that the network of cooperativities between the redox and protonic centers is consistent with a synergetic process to stimulate the hydrogen uptake activity of hydrogenase. This is achieved by increasing the affinity of the cytochrome for protons through binding electrons and, reciprocally, by favoring a concerted two-electron transfer assisted by the binding of proton(s). The data were analyzed within the framework of the differences in the primary and tertiary structures of the two proteins, showing that residue 88, close to heme I, is the main cause for the differences in the microscopic thermodynamic parameters obtained for these two cytochromes c 3 . This comparison reveals how replacement of a single amino acid can tune the functional properties of energy-transducing proteins, so that they can be optimized to suit the bioenergetic constraints of specific habitats.

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Solution structure of Desulfovibrio vulgaris (Hildenborough) ferrocytochrome c 3 : structural basis for functional cooperativity 1 1Edited by P. E. Wright

Cited by 53 publications

References 65 publications

Conformational Component in the Coupled Transfer of Multiple Electrons and Protons in a Monomeric Tetraheme Cytochrome

Conformational Component in the Coupled Transfer of Multiple Electrons and Protons in a Monomeric Tetraheme Cytochrome

Effect of Hydrogen-Bond Networks in Controlling Reduction Potentials in Desulfovibrio vulgaris (Hildenborough) Cytochrome c₃ Probed by Site-Specific Mutagenesis

Proton-assisted Two-electron Transfer in Natural Variants of Tetraheme Cytochromes from Desulfomicrobium Sp.

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Solution structure of Desulfovibrio vulgaris (Hildenborough) ferrocytochrome c 3 : structural basis for functional cooperativity 1 1Edited by P. E. Wright

Cited by 53 publications

References 65 publications

Conformational Component in the Coupled Transfer of Multiple Electrons and Protons in a Monomeric Tetraheme Cytochrome

Conformational Component in the Coupled Transfer of Multiple Electrons and Protons in a Monomeric Tetraheme Cytochrome

Effect of Hydrogen-Bond Networks in Controlling Reduction Potentials in Desulfovibrio vulgaris (Hildenborough) Cytochrome c3 Probed by Site-Specific Mutagenesis

Proton-assisted Two-electron Transfer in Natural Variants of Tetraheme Cytochromes from Desulfomicrobium Sp.

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Effect of Hydrogen-Bond Networks in Controlling Reduction Potentials in Desulfovibrio vulgaris (Hildenborough) Cytochrome c₃ Probed by Site-Specific Mutagenesis