Modified cytochromes

Sulfite and S02 Sulfite oxidase- and cytochrome-modified SPCE 4 ppm 50 ppm... 

Although not discussed in detail here, the normal mode analysis method has been used to calculate the electron transfer reorganization spectrum in / M-modified cytochrome c [65,66]. In this application the normal mode analysis fits comfortably into the theory of electron transfer. 

Scheme 10.8 Biosynthesis of epothilone. Individual PKS domains are represented as circles and individual NRPS domains as hexagons. Acyl carrier proteins (ACPs) and thiola-tion domains (T) are posttranslationally modified by a phos-phopantetheinyl group to which the biosynthetic intermediates are covalently bound throughout the chain assembly. The thioesterase domain (TE) cyclizes the fully assembled carbon chain to give the 16-membered lactone. Following dehydration of Cl 2—Cl 3 to give epothilones C and D, the final step in epothilone biosynthesis is the epoxidation of the C12=C13 double bond by the cytochrome P450 enzyme P450epol<. KS ketosyn-thase KS(Y) active-site tyrosine mutant of KS AT acyltransfer-ase C condensation domain A adenylation domain ...

Neurodegeneration. Figure 3 Illustration of synaptic (neuritic) apoptosis. A pyramidal neuron is depicted with cortical afferents synapsing on its dendrites. Localized apoptotic mechanisms lead to the release of cytochrome c from the mitochondria and an increase in the concentration of activated caspase-3 in a presynaptic terminal that is synapsing on a dendritic spine. Increased caspase-3 activity results in a localized breakdown of this nerve terminal and its synapse. Subsequently, the postsynaptic dendritic spine retracts and disappears (Figure modified from Glantz et al. [5] [3]). 

H)2-D3 is a weak agonist and must be modified by hydroxylation at position Cj for full biologic activity. This is accomplished in mitochondria of the renal proximal convoluted tubule by a three-component monooxygenase reaction that requires NADPFl, Mg, molecular oxygen, and at least three enzymes (1) a flavoprotein, renal ferredoxin reductase (2) an iron sulfur protein, renal ferredoxin and (3) cytochrome P450. This system produces l,25(OH)2-D3, which is the most potent namrally occurring metabolite of vitamin D. 

The electron transfer properties of the cytochromes involve cycling of the iron between the +2 and +3 oxidation states (Cytochrome)Fe + e" (Cytochrome)Fe ° = -0.3Vto+ 0.4V Different cytochromes have different side groups attached to the porphyrin ring. These side groups modify the electron density in the delocalized iz system of the porphyrin, which in turn changes the redox potential of the iron cation in the heme. 

Heering HA, Williams KA, de Vries S, Dekker C. 2006. Specific vectorial immobilization of oligonucleotide-modified yeast cytochrome c on carbon nanotubes. Chem Phys Chem 7 1705-1709. 

Porphyrin complexes are particularly suitable cores to construct dendrimers and to investigate how the behavior of an electroactive species is modified when surrounded by dendritic branches. In particular, dendritic porphyrins can be regarded as models for electron-transfer proteins like cytochrome c [42, 43]. Electrochemical investigation on Zn-porphyrins bearing polyether-amide branches has shown that the first reduction and oxidation processes are affected by the electron-rich microenvironment created by the dendritic branches [42]. Furthermore, for the third generation compound all the observed processes become irreversible. 

This chapter describes some of the modified mammalian cell-based systems that have been developed to express intestinal cytochrome P450 enzymes and intestinal transporters. The reader should be aware that other experimental systems, such as transporter expression and drug uptake studies in Xenopus laevis oocytes, have also shown considerable promise [1],... 

A clear priority remains to expand the panel of intestinal efflux transporters that are expressed individually in modified cell lines. These research tools will be instrumental in identifying and validating selective probe transporter substrates and inhibitors. The availability of such probes will allow for a better understanding of the influence of transporters on in vivo pharmacokinetics. A similar set of probes has been instrumental in increasing our understanding of the role that cytochrome P450 plays in human pharmacokinetics and in avoiding issues associated with these enzymes. 

Hu, M., Steimel, D. T., Analysis of transport and metabolism in cell monolayer systems that have been modified by cytochrome P4503A4 cDNA-expression, Eur. J. Pharm. Sci. 2000, 12, 63-68. 

Garcia-Arellano, H. Valderrama, B. Saab-Rincon, G., and Vazquez-Duhalt, R., High Temperature Biocatalysis by Chemically Modified Cytochrome c. Bioconjugate Chem. 2002. 13 pp. 1336-1344. 

Garcia-Arellano, H. Buenrostro-Gonzalez, E. and Vazquez-Duhalt, R., Biocatalytic transformation of petroporphyrins by chemical modified cytochrome, C. Biotechnology and Bioengineering, 2004. 85(7) pp. 790-798. 

Figure 3.89 Cyclic voltammograms of 500 pm cytochrome c at a gold electrode modified by (a) 2-mercaptopyridine, (b> 2-mercaptosuccinic acid, 4,4 -dithiobis(butanoic acid), (d) 4-mercaploaniline. pH 7.0 phosphate buffer +0.1 M NaC104. Scan rale 50mVs . From Allen...

Figure 3.92 shows SERS spectra of adsorbed SSBipy and PySH at 0 V in the absence of the solution species, together with the Raman spectra of PySH in solution and crystalline SSBipy. The activities of the modified electrodes were first confirmed in solution containing cytochrome c. 

Figure 3.96 The effect of increasing time of exposure (as indicated) of a gold electrode once-modified with SSBipy to thiophenol on the cyclic voltammetry of horse heart cytochrome t (0.4mM). 20 mM sodium phosphate/0.1 M NaCI04 pH 7.0. Scan rate 20mVs l. From Hill...

F. Lisdat, B. Ge, E. Ehrentreich-Forster, R. Reszka, and F.W. Scheller, Superoxide dismutase activity measurement using cytochrome c-modified electrode. Anal. Chem. 71,1359—1365 (1999). 

K.V. Gobi and F. Mizutani, Efficient mediatorless superoxide sensors using cytochrome c-modified electrodes. Surface nano-organization for selectivity and controlled peroxidase activity. J. Electroanal. Chem. 484, 172-181 (2000). 

K.D. Gleria, H.A.O. Hill, V.J. Lowe, and D.J. Page, Direct electrochemistry of horse-heart cytochrome c at amino acid-modified gold electrodes. J. Electroanal. Chem. 213, 333-338 (1986). 

J. Wang, M. Li, Z. Shi, N. Li, and Z. Gu, Direct electrochemistry of cytochrome c at a glassy carbon electrode modified with single-wall carbon nanotubes. Anal. Chem. 74, 1993-1997 (2002). 

G.C. Zhao, Z.Z. Yin, L. Zhang, and X.W. Wei, Direct electrochemistry of cytochrome c on a multi-walled carbon nanotube modified electrode and its electrocatalytic activity for the reduction of H2O2. Electrochem. Commun. 7, 256-260 (2005). 

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