Loss of Electrostatic Interactions Causes Increase of Dynamics within the Plastocyanin–Cytochrome <i>f</i> Complex

Scanu, Sandra; Foerster, Johannes M.; Timmer, Monika; Ullmann, G. Matthias; Ubbink, Marcellus

doi:10.1021/bi400450q

Cited by 13 publications

(22 citation statements)

References 47 publications

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“…The approach was based on measurements of magnetic interactions between spin label (SL) on cytochrome c 2 and a fast-relaxing iron ion of heme c 1 in cytochrome c 1 . These interactions were detected as paramagnetic relaxation enhancement (PRE), 18 a phenomenon that has been exploited to study protein–protein interactions by both EPR and NMR spectroscopy, in systems such as cytochrome c –cytochrome c oxidase, 19 cytochrome c –cytochrome c peroxidase, 20,21 plastocyanin–cytochrome f , 22 and Rieske protein–cytochrome b . 23 Our experiments further support the collisional mechanism in which cytochrome bc 1 does not form long-lived complexes with cytochrome c 2 and ET between the proteins is a product of several collisions between proteins.…”

Section: Introductionmentioning

confidence: 99%

Molecular Organization of Cytochrome c₂ near the Binding Domain of Cytochrome bc₁ Studied by Electron Spin–Lattice Relaxation Enhancement

2014

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Measurements of specific interactions between proteins are challenging. In redox systems, interactions involve surfaces near the attachment sites of cofactors engaged in interprotein electron transfer (ET). Here we analyzed binding of cytochrome c2 to cytochrome bc1 by measuring paramagnetic relaxation enhancement (PRE) of spin label (SL) attached to cytochrome c2. PRE was exclusively induced by the iron atom of heme c1 of cytochrome bc1, which guaranteed that only the configurations with SL to heme c1 distances up to ∼30 Å were detected. Changes in PRE were used to qualitatively and quantitatively characterize the binding. Our data suggest that at low ionic strength and under an excess of cytochrome c2 over cytochrome bc1, several cytochrome c2 molecules gather near the binding domain forming a “cloud” of molecules. When the cytochrome bc1 concentration increases, the cloud disperses to populate additional available binding domains. An increase in ionic strength weakens the attractive forces and the average distance between cytochrome c2 and cytochrome bc1 increases. The spatial arrangement of the protein complex at various ionic strengths is different. Above 150 mM NaCl the lifetime of the complexes becomes so short that they are undetectable. All together the results indicate that cytochrome c2 molecules, over the range of salt concentration encompassing physiological ionic strength, do not form stable, long-lived complexes but rather constantly collide with the surface of cytochrome bc1 and ET takes place coincidentally with one of these collisions.

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Section: Introductionmentioning

confidence: 99%

Molecular Organization of Cytochrome c₂ near the Binding Domain of Cytochrome bc₁ Studied by Electron Spin–Lattice Relaxation Enhancement

2014

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“…In the encounter complex, the proteins assume multiple other orientations, often in equilibrium with the major stereospecific state. In low-affinity complexes with dissociation constant (K d ) values > 10 μM, the encounter complex can represent a sizeable fraction, and in some cases, a well-defined, stereospecific complex may even be absent (10)(11)(12)(13)(14)(15). The presence of encounter states may be a consequence of the chemical nature of proteins.…”

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Identification of productive and futile encounters in an electron transfer protein complex

Andrałojć

Hiruma

Wei-min

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Well-defined, stereospecific states in protein complexes are often in exchange with an ensemble of more dynamic orientations: the encounter states. The structure of the stereospecific complex between cytochrome P450cam and putidaredoxin was solved recently by X-ray diffraction as well as paramagnetic NMR spectroscopy. Other than the stereospecific complex, the NMR data clearly show the presence of additional states in the complex in solution. In these encounter states, populated for a small percentage of the time, putidaredoxin assumes multiple orientations and samples a large part of the surface of cytochrome P450cam. To characterize the nature of the encounter states, an extensive paramagnetic NMR dataset has been analyzed using the Maximum Occurrence of Regions methodology. The analysis reveals the location and maximal spatial extent of the additional states needed to fully explain the NMR data. Under the assumption of sparsity of the size of the conformational ensemble, several minor states can be located quite precisely. The distribution of these minor states correlates with the electrostatic potential map around cytochrome P450cam. Whereas some minor states are on isolated positively charged patches, others are connected to the stereospecific site via positively charged paths. The existence of electrostatically favorable pathways between the stereospecific interaction site and the different minor states or lack thereof suggests a means to discriminate between productive and futile encounter states.paramagnetic NMR | encounter complex | cytochrome P450cam | putidaredoxin | maximum occurrence C rystal structures suggest that proteins assume unique, stereospecific orientations within protein-protein complexes. However, a number of studies in solution have made clear that encounter states are an inherent element of protein complexes (1-8), especially in electron transfer (ET), where the interactions are often extremely fast (9). In the encounter complex, the proteins assume multiple other orientations, often in equilibrium with the major stereospecific state. In low-affinity complexes with dissociation constant (K d ) values > 10 μM, the encounter complex can represent a sizeable fraction, and in some cases, a well-defined, stereospecific complex may even be absent (10-15). The presence of encounter states may be a consequence of the chemical nature of proteins. In nonobligate stereospecific complexes, the interface represents a small fraction of the total protein surface, and therefore, it is reasonable to assume that weak interactions also occur elsewhere. In the case in which protein pairs have evolved to exhibit a high association rate by using electrostatic preorientation, electrostatic patches seem to enhance the presence of encounter states (16,17). On the one hand, the preorientation reduces the surface area that is visited by the partner, thus enhancing the number of productive encounters, but on the other hand, highly charged patches can bind the oppositely charged protein in many orientations with a...

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“…Previous experiments suggest that the initial stage of the formation of the encounter complex is governed mostly by long‐range electrostatic interactions, but hydrophobic interactions can in some cases be relevant . Guiding the proteins through these interactions, the encounter complex can enhance the formation of the stereo‐specific complex by reducing the search area.…”

Section: Introductionmentioning

confidence: 99%

The Transient Complex of Cytochrome c and Cytochrome c Peroxidase: Insights into the Encounter Complex from Multifrequency EPR and NMR Spectroscopy

et al. 2020

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We present a novel approach to study transient protein-protein complexes with standard, 9 GHz, and high-field, 95 GHz, electron paramagnetic resonance (EPR) and paramagnetic NMR at ambient temperatures and in solution. We apply it to the complex of yeast mitochondrial iso-1-cytochrome c (Cc) with cytochrome c peroxidase (CcP) with the spin label [1-oxyl-2,2,5,5-tetramethyl-Δ3-pyrroline-3-methyl)-methanethiosulfo-nate] attached at position 81 of Cc (SLÀ Cc). A dissociation constant K D of 20 � 4 × 10 À 6 M (EPR and NMR) and an equal amount of stereo-specific and encounter complex (NMR) are found. The EPR spectrum of the fully bound complex reveals that the encounter complex has a significant population (60 %) that shares important features, such as the Cc-interaction surface, with the stereo-specific complex.

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Loss of Electrostatic Interactions Causes Increase of Dynamics within the Plastocyanin–Cytochrome f Complex

Cited by 13 publications

References 47 publications

Molecular Organization of Cytochrome c₂ near the Binding Domain of Cytochrome bc₁ Studied by Electron Spin–Lattice Relaxation Enhancement

Molecular Organization of Cytochrome c₂ near the Binding Domain of Cytochrome bc₁ Studied by Electron Spin–Lattice Relaxation Enhancement

Identification of productive and futile encounters in an electron transfer protein complex

The Transient Complex of Cytochrome c and Cytochrome c Peroxidase: Insights into the Encounter Complex from Multifrequency EPR and NMR Spectroscopy

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Loss of Electrostatic Interactions Causes Increase of Dynamics within the Plastocyanin–Cytochrome f Complex

Cited by 13 publications

References 47 publications

Molecular Organization of Cytochrome c2 near the Binding Domain of Cytochrome bc1 Studied by Electron Spin–Lattice Relaxation Enhancement

Molecular Organization of Cytochrome c2 near the Binding Domain of Cytochrome bc1 Studied by Electron Spin–Lattice Relaxation Enhancement

Identification of productive and futile encounters in an electron transfer protein complex

The Transient Complex of Cytochrome c and Cytochrome c Peroxidase: Insights into the Encounter Complex from Multifrequency EPR and NMR Spectroscopy

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Molecular Organization of Cytochrome c₂ near the Binding Domain of Cytochrome bc₁ Studied by Electron Spin–Lattice Relaxation Enhancement

Molecular Organization of Cytochrome c₂ near the Binding Domain of Cytochrome bc₁ Studied by Electron Spin–Lattice Relaxation Enhancement