Disparity of Cytochrome Utilization in Anodic and Cathodic Extracellular Electron Transfer Pathways of Geobacter sulfurreducens Biofilms.

Extracellular electron transfer (EET) in microorganisms is prevalent in nature and has been utilized in functional bioelectrochemical systems. EET of Geobacter sulfurreducens has been extensively studied and has been revealed to be facilitated through c-type cytochromes, which mediate charge between the electrode and G. sulfurreducens in anodic mode. However, the EET pathway of cathodic conversion of fumarate to succinate is still under debate. Here, we apply a variety of analytical methods, including electrochemistry, UV-vis absorption and resonance Raman spectroscopy, quartz crystal microbalance with dissipation, and electron microscopy, to understand the involvement of cytochromes and other possible electron-mediating species in the switching between anodic and cathodic reaction modes. By switching the applied bias for a G. sulfurreducens biofilm coupled to investigating the quantity and function of cytochromes, as well as the emergence of Fe-containing particles on the cell membrane, we provide evidence of a diminished role of cytochromes in cathodic EET. This work sheds light on the mechanisms of G. sulfurreducens biofilm growth and suggests the possible existence of a nonheme, iron-involving EET process in cathodic mode.

Molecular dynamics at constant pH and reduction potential: application to cytochrome c(3).

Here we present a new implementation and extension of the stochastic titration method which makes it possible to perform MD simulations at constant pH and reduction potential. The method was applied to the redox titration of cytochrome c(3) from Desulfovibrio vulgaris Hildenborough, and a major finding of this study was that the method showed a better performance when the protein region is assigned a high dielectric constant. This dependence on the value of the protein dielectric constant was not found in previous constant-pH MD simulations and is attributed to excessively high heme-heme interactions at low dielectric constants. The simulations revealed strong coupling between hemes in close proximity, and we also showed how these couplings can be used to estimate the sensibility of the heme reductions to small pH changes.

Studies of the reduction and protonation behavior of tetraheme cytochromes using atomic detail.

A comparative study of tetraheme cytochrome c3 molecules from several species was carried out using recently developed theoretical methods based on continuum electrostatics. The binding joint equilibrium of electrons and protons was simulated, revealing the complete thermodynamic aspects of electron-proton coupling in these molecules. The method yields excellent accuracy in terms of midpoint potentials, giving the correct reduction orders in all molecules examined, except for one heme site. The coupling between electrons and protons is shown to be present and significant at physiological pH in all cases. This phenomenon, known as the redox-Bohr effect, though of thermodynamic nature, is shown to have an intrinsic "dynamic" character at the molecular level (in the sense of the empty/occupied fluctuations at the microscopic level), with the binding states of redox and protonatable sites displaying both correlated averages and correlated fluctuations. The protonatable sites more directly involved in the redox-Bohr effect are identified using, among other properties, the statistical correlation between pairs of sites, which automatically reflects indirect effects mediated by other sites. Several sites are identified in this analysis. Propionate D of heme I seems to be the most interesting, generally showing a high correlation not only with its own heme, but also with heme II, corresponding to an indirect stabilization of the reduced forms of both hemes. Other interesting sites are the free histidines of two of the cytochromes and propionate D of heme IV, the latter being potentially associated with redox-induced structural changes. Among the set of cytochromes c3 analyzed in this study, significant differences are observed for several properties of the acidic cytochrome included in the set, from Desulfovibrio africanus, supporting the hypothesis of a different functional role.

Simulation of electron-proton coupling with a Monte Carlo method: application to cytochrome c3 using continuum electrostatics.

A new method is presented for simulating the simultaneous binding equilibrium of electrons and protons on protein molecules, which makes it possible to study the full equilibrium thermodynamics of redox and protonation processes, including electron-proton coupling. The simulations using this method reflect directly the pH and electrostatic potential of the environment, thus providing a much closer and realistic connection with experimental parameters than do usual methods. By ignoring the full binding equilibrium, calculations usually overlook the twofold effect that binding fluctuations have on the behavior of redox proteins: first, they affect the energy of the system by creating partially occupied sites; second, they affect its entropy by introducing an additional empty/occupied site disorder (here named occupational entropy). The proposed method is applied to cytochrome c3 of Desulfovibrio vulgaris Hildenborough to study its redox properties and electron-proton coupling (redox-Bohr effect), using a continuum electrostatic method based on the linear Poisson-Boltzmann equation. Unlike previous studies using other methods, the full reduction order of the four hemes at physiological pH is successfully predicted. The sites more strongly involved in the redox-Bohr effect are identified by analysis of their titration curves/surfaces and the shifts of their midpoint redox potentials and pKa values. Site-site couplings are analyzed using statistical correlations, a method much more realistic than the usual analysis based on direct interactions. The site found to be more strongly involved in the redox-Bohr effect is propionate D of heme I, in agreement with previous studies; other likely candidates are His67, the N-terminus, and propionate D of heme IV. Even though the present study is limited to equilibrium conditions, the possible role of binding fluctuations in the concerted transfer of protons and electrons under nonequilibrium conditions is also discussed. The occupational entropy contributions to midpoint redox potentials and pKa values are computed and shown to be significant.

Assessment of ferrocytochrome C oxidation by hydrogen peroxide.

The reduction of ferricytochrome C is commonly employed for the quantitation of O2-.H2O2 arising from the dismutation of O2- is capable of oxidizing ferrocytochrome C. In order to assess whether this may interfere with O2- quantitation, the amount of H2O2 required for the oxidation of ferrocytochrome C was determined. While H2O2 concentrations below 10(-5) M were ineffective, one half of the reduced cytochrome was oxidized by 5 x 10(-5) M H2O2 within 15 min. H2O2 in the concentration range at which ferrocytochrome C is oxidized is generated upon interaction of hypoxanthine with xanthine oxidase and upon stimulation of human polymorphonuclear neutrophilic granulocytes by phorbol myristate acetate or the phagocytosis of opsonized zymosan. It is suggested that O2- quantitation by cytochrome C reduction is routinely performed in the presence of catalase.

The random collision model and a critical assessment of diffusion and collision in mitochondrial electron transport.

This review focuses on our studies over the past ten years which reveal that the mitochondrial inner membrane is a fluid-state rather than a solid-state membrane and that all membrane proteins and redox components which catalyze electron transport and ATP synthesis are in constant and independent diffusional motion. The studies reviewed represent the experimental basis for the random collision model of electron transport. We present five fundamental postulates upon which the random collision model of mitochondrial electron transport is founded: All redox components are independent lateral diffusants; Cytochrome c diffuses primarily in three dimensions; Electron transport is a diffusion-coupled kinetic process; Electron transport is a multicollisional, obstructed, long-range diffusional process; The rates of diffusion of the redox components have a direct influence on the overall kinetic process of electron transport and can be rate limiting, as in diffusion control. The experimental rationales and the results obtained in testing each of the five postulates of the random collision model are presented. In addition, we offer the basic concepts, criteria and experimental strategies that we believe are essential in considering the significance of the relationship between diffusion and electron transport. Finally, we critically explore and assess other contemporary studies on the diffusion of inner membrane components related to electron transport including studies on: rotational diffusion, immobile fractions, complex formation, dynamic aggregates, and rates of diffusion. Review of all available data confirms the random collision model and no data appear to exist that contravene it. It is concluded that mitochondrial electron transport is a diffusion-based random collision process and that diffusion has an integral and controlling affect on electron transport.

Exchange transfusion with Fluosol 43: in vivo assessment of cerebral cytochrome c oxidase redox state.

Rats were serially exchange transfused to hematocrits less than 2% (50-cc exchange) with either Krebs-Henseleit-albumin (KHA) solution or Fluosol-43 (F-43). Reflectance spectrophotometry was employed to monitor cerebral cytochrome c oxidase redox states. Determination of mean arterial pressure (MAP), arterial and venous oxygen content difference (A-VO2), and cerebral cortical ATP and lactate concentrations were also made. As hemodilution progressed, neither solution provided normal quantities of oxygen as evaluated by the cytochrome c oxidase redox state and a decrease in A-VO2 difference, although F-43 was significantly (p less than 0.01) better than KHA in terms of cytochrome c oxidase redox state as well as maintenance of MAP. There was no significant difference between the two test solutions in terms of cortical ATP and lactate.