An EPR study of the interactions between heme and flavin in yeast flavocytochrome b2

Flavocytochrome b2-Mediated Electroactive Nanoparticles for Developing Amperometric L-Lactate Biosensors

L-Lactate is an indicator of food quality, so its monitoring is essential. Enzymes of L-Lactate metabolism are promising tools for this aim. We describe here some highly sensitive biosensors for L-Lactate determination which were developed using flavocytochrome b₂ (Fcb₂) as a bio-recognition element, and electroactive nanoparticles (NPs) for enzyme immobilization. The enzyme was isolated from cells of the thermotolerant yeast Ogataea polymorpha. The possibility of direct electron transfer from the reduced form of Fcb₂ to graphite electrodes has been confirmed, and the amplification of the electrochemical communication between the immobilized Fcb₂ and the electrode surface was demonstrated to be achieved using redox nanomediators, both bound and freely diffusing. The fabricated biosensors exhibited high sensitivity (up to 1436 A·M^-1·m^-2), fast responses, and low limits of detection. One of the most effective biosensors, which contained co-immobilized Fcb₂ and the hexacyanoferrate of gold, having a sensitivity of 253 A·M^-1·m^-2 without freely diffusing redox mediators, was used for L-Lactate analysis in samples of yogurts. A high correlation was observed between the values of analyte content determined using the biosensor and referenced enzymatic-chemical photometric methods. The developed biosensors based on Fcb₂-mediated electroactive nanoparticles can be promising for applications in laboratories of food control.

Biochemical and biophysical methods for studying mitochondrial iron metabolism

Iron is a heavily utilized element in organisms and numerous mechanisms accordingly regulate the trafficking, metabolism, and storage of iron. Despite the high regulation of iron homeostasis, several diseases and mutations can lead to the misregulation and often accumulation of iron in the cytosol or mitochondria of tissues. To understand the genesis of iron overload, it is necessary to employ various techniques to quantify iron in organisms and mitochondria. This chapter discusses techniques for determining the total iron content of tissue samples, ranging from colorimetric determination of iron concentrations, atomic absorption spectroscopy, inductively coupled plasma-optical emission spectroscopy, and inductively coupled plasma-mass spectrometry. In addition, we discuss in situ techniques for analyzing iron including electron microscopic nonheme iron histochemistry, electron energy loss spectroscopy, synchrotron X-ray fluorescence imaging, and confocal Raman microscopy. Finally, we discuss biophysical methods for studying iron in isolated mitochondria, including ultraviolet-visible, electron paramagnetic resonance, X-ray absorbance, and Mössbauer spectroscopies. This chapter should aid researchers to select and interpret mitochondrial iron quantifications.

Further characterization of the two tetraheme cytochromes c3 from Desulfovibiro africanus: nucleotide sequences, EPR spectroscopy and biological activity

The genes encoding the basic and acidic tetraheme cytochromes c3 from Desulfovibrio africanus have been sequenced. The corresponding amino acid sequences of the basic and acidic cytochromes c3 indicate that the mature proteins consist of a single polypeptide chain of 117 and 103 residues, respectively. Their molecular masses, 15102 and 13742 Da, respectively, determined by mass spectrometry, are in perfect agreement with those calculated from their amino acid sequences. Both D. africanus cytochromes c3 are synthesized as precursor proteins with signal peptides of 23 and 24 residues for the basic and acidic cytochromes, respectively. These cytochromes c3 exhibit the main structural features of the cytochrome c3 family and contain the 16 strictly conserved cysteine + histidine residues directly involved in the heme binding sites. The D. africanus acidic cytochrome c3 differs from all the other homologous cytochromes by its low content of basic residues and its distribution of charged residues in the amino acid sequence. The presence of four hemes per molecule was confirmed by EPR spectroscopy in both cytochromes c3. The g-value analysis suggests that in both cytochromes, the angle between imidazole planes of the axial histidine ligands is close to 90 degrees for one heme and much lower for the three others. Moreover, an unusually high exchange interaction (approximately 10[-2] cm[-1]) was evidenced between the highest potential heme (-90 mV) and one of the low potential hemes in the basic cytochrome c3. The reactivity of D. africanus cytochromes c3 with heterologous [NiFe] and [Fe] hydrogenases was investigated. Only the basic one interacts with the two types of hydrogenase to achieve efficient electron transfer, whereas the acidic cytochrome c3 exchanges electrons specifically with the basic cytochrome c3. The difference in the specificity of the two D. africanus cytochromes c3 has been correlated with their highly different content of basic and acidic residues.

Individual redox characteristics and kinetic properties of the hemes in cytochromes c3: new methods of investigation

The elucidation of the role of the four hemes in cytochromes c3 requires several complementary approaches. The measurements and the assignment of the redox potentials resort to magnetic spectroscopies, EPR and NMR, which are able to discriminate the hemes. The origin of the differences between the redox properties of the hemes can be studied by comparing their thermodynamic parameters delta S and delta H, as measured by the temperature dependence of their individual potentials. Lastly, the available data concerning the electron exchange between cytochromes c3 and their redox partners can be analysed through a detailed kinetic model which provides important information on the role of the different hemes.

Comparison of the spin-lattice relaxation properties of the two classes of [2Fe-2S] clusters in proteins

Two classes of [2Fe-2S] proteins have been defined according to the mean value gav of their g tensor components (Bertrand, P., Guigliarelli, B., Gayda, J.P., Beardwood, P. and Gibson, J.F. (1985) Biochim. Biophys. Acta 831, 261-266). To characterize their magnetic properties better, we have compared the spin-lattice relaxation behavior of typical proteins which belong to these two classes, namely Spirulina maxima and adrenal ferredoxin for the gav approximately 1.96 class, Thermus thermophilus Rieske protein and Pseudomonas putida benzene dioxygenase for the gav approximately 1.91 class. For all these proteins, the data support the existence of an efficient Orbach process in the highest temperature range, which allows the determination of the exchange coupling parameter, J. From the comparison of the J values obtained in each class, it is concluded that the structural factors which determine the value of the g tensor and the strength of the antiferromagnetic exchange interactions are different.