Control of the electron transfer reactions between c-type cytochromes and lipid-modified electrodes

Buildup of polyelectrolyte-protein multilayer assemblies on gold electrodes. Role of the hydrophobic effect

The buildup of layer-by-layer assemblies onto gold surfaces from water-soluble charged polyelectrolytes and proteins is examined using quartz crystal microgravimetry (QCM) and electrochemical techniques. Polyelectrolytes such as poly(styrenesulfonate) and poly(ester sulfonic acid) (Eastman AQ-29D polymer) adsorb spontaneously onto gold, contrary to poly(ethyleneimine). From the modification of the gold surface with a thiol and specific adsorption of polymers under polarization conditions, it is concluded that the hydrophobicity of the gold surface seems to be a determining factor in the adsorption process. Alternate adsorption onto gold resonators first coated with AQ-29D polymer gives stable multilayer films in the case of positively charged lysozyme (pI = 11) or polyheme Desulfovibrio vulgaris Hildenborough cytochrome c3 (pI = 10.5). QCM frequency changes with the number of adsorption steps suggest that a linear increase in film mass occurs. Desulfomicrobium norvegicum polyheme cytochrome c3 (pI = 7), which has a null global charge at neutral pH, is shown to give also stable multilayer AQ-29D/cytochrome c3 films, suggesting that several types of interactions, especially the hydrophobic effect, are involved in the buildup process.

Protein modified- and membrane electrodes: strategies for the development of biomolecular sensors

Different procedures used for constructing protein/enzyme-modified electrodes are examined, in particular adsorption, covalent attachment and film deposition. The performances of such modified electrodes with electroactive proteins or enzymes attached to their active surface are examined, especially in the case of c-type cytochromes, hydrogenases and glucose oxidase. Another strategy presented in this review consists of the use of membrane electrodes with an electroactive protein imprisoned between a dialysis membrane and the electrode surface. The versatility and other advantages of such a procedure are underlined. Applications of membrane electrodes to the bioremediation of soils and effluents and as models for investigating interactions between proteins and soils are described.

Electroactive hemoglobin-surfactant-polymer biomembrane-like films

Polyions complex 2C12N+ PSS- was prepared by reacting poly(sodium styrenesulfonate) (Na+ PSS-) with didodecyldimethylammonium bromide (2Cl2N+ Br-). Stable thin films made from 2C12N+ PSS- with incorporated redox protein hemoglobin (Hb) on pyrolytic graphite (PG) electrodes were then characterized by electrochemistry and other techniques. Cyclic voltammetry (CV) of Hb-2C12N+ PSS- films showed a pair of well-defined and nearly reversible peaks for HbFe(III)/Fe(II) couple at about -0.17 V vs. saturated calomel electrode (SCE) in pH 5.5 buffers. The electron transfer rate between Hb and PG electrode was greatly facilitated in microenvironment of 2C12N+ PSS- films. Positions of Soret absorption band suggest that Hb keeps its secondary structure similar to its native state in 2C12N+ PSS- films at the medium pH. The results of X-ray diffraction and differential scanning calorimetry (DSC) suggest synthesized lipid 2C12N+ PSS- films have an ordered bilayer structure intercalated between PSS- polyion layers, and the incorporated Hb expands the layer spacing of the films. HbFe(I), a highly reduced form of Hb, might also be produced in these films at about -1.09 V, and could be used to catalytically reduce organohalide pollutants.

Salt and pH effects on electrochemistry of myoglobin in thick films of a bilayer-forming surfactant

Salt concentration and pH of external solutions were shown to control the electrochemistry of the heme protein myoglobin (MbFe(III)-H2O) in stable, ordered films of didodecyldimethylammonium bromide (DDAB). Protonation of aquometmyoglobin (MbFe(III)-H2O) in these films precedes electron transfer from electrodes, causing formal potentials to shift negative as pH increases from 5 to 8. At pH > 8, MbFe(III)-H2O dissociates to MbFe(III)-OH, which is reduced directly at the electrode at higher rates than MbFe(III)-H2O. Correlations of voltammetric data with FT-IR spectra suggested that at pH < 4.6, an unfolded form of Mb resides in the films and is reduced directly. The concentration of salt in solution influences electrochemical properties of Mb-DDAB films by its influence on Mb conformation and by effects on interfacial Donnan potentials. NMR indicated strong binding of anions to Mb within DDAB films. Bound anions may neutralize positive charge on Mb's surface so that it can reside in a partly hydrophobic environment, as postulated on the basis of previous ESR and linear dichroism studies.