Stabilized flavin radical in chloroplast NADP+ reductase

Biohybrid photosynthetic charge accumulation detected by flavin semiquinone formation in ferredoxin-NADP+ reductase

Flavin chemistry is ubiquitous in biological systems with flavoproteins engaged in important redox reactions. In photosynthesis, flavin cofactors are used as electron donors/acceptors to facilitate charge transfer and accumulation for ultimate use in carbon fixation. Following light-induced charge separation in the photosynthetic transmembrane reaction center photosystem I (PSI), an electron is transferred to one of two small soluble shuttle proteins, a ferredoxin (Fd) or a flavodoxin (Fld) (the latter in the condition of Fe-deficiency), followed by electron transfer to the ferredoxin-NADP⁺ reductase (FNR) enzyme. FNR accepts two of these sequential one electron transfers, with its flavin adenine dinucleotide (FAD) cofactor becoming doubly reduced, forming a hydride which is then passed onto the substrate NADP⁺ to form NADPH. The two one-electron potentials (oxidized/semiquinone and semiquinone/hydroquinone) are similar to each other with the FNR protein stabilizing the hydroquinone, making spectroscopic detection of the intermediate semiquinone state difficult. We employed a new biohybrid-based strategy that involved truncating the native three-protein electron transfer cascade PSI → Fd → FNR to a two-protein cascade by replacing PSI with a molecular Ru(ii) photosensitizer (RuPS) which is covalently bound to Fd and Fld to form biohybrid complexes that successfully mimic PSI in light-driven NADPH formation. RuFd → FNR and RuFld → FNR electron transfer experiments revealed a notable distinction in photosynthetic charge accumulation that we attribute to the different protein cofactors [2Fe2S] and flavin. After freeze quenching the two-protein systems under illumination, an intermediate semiquinone state of FNR was readily observed with cw X-band EPR spectroscopy. The increased spectral resolution from selective deuteration allowed EPR detection of inter-flavoprotein electron transfer. This work establishes a biohybrid experimental approach for further studies of photosynthetic light-driven electron transfer chain that culminates at FNR and highlights nature's mechanisms that couple single electron transfer chemistry to charge accumulation, providing important insight for the development of photon-to-fuel schemes.

Genome mining in Sorangium cellulosum So ce56: identification and characterization of the homologous electron transfer proteins of a myxobacterial cytochrome P450

Myxobacteria, especially members of the genus Sorangium, are known for their biotechnological potential as producers of pharmaceutically valuable secondary metabolites. The biosynthesis of several of those myxobacterial compounds includes cytochrome P450 activity. Although class I cytochrome P450 enzymes occur wide-spread in bacteria and rely on ferredoxins and ferredoxin reductases as essential electron mediators, the study of these proteins is often neglected. Therefore, we decided to search in the Sorangium cellulosum So ce56 genome for putative interaction partners of cytochromes P450. In this work we report the investigation of eight myxobacterial ferredoxins and two ferredoxin reductases with respect to their activity in cytochrome P450 systems. Intriguingly, we found not only one, but two ferredoxins whose ability to sustain an endogenous So ce56 cytochrome P450 was demonstrated by CYP260A1-dependent conversion of nootkatone. Moreover, we could demonstrate that the two ferredoxins were able to receive electrons from both ferredoxin reductases. These findings indicate that S. cellulosum can alternate between different electron transport pathways to sustain cytochrome P450 activity.

Electron spin resonance and electron nuclear double resonance studies of flavoproteins involved in the photosynthetic electron transport in the cyanobacterium Anabaena sp. PCC 7119

The flavins of ferredoxin-NADP+ reductase (FNR) and flavodoxin from the cyanobacterium Anabaena PCC 7119 were obtained in their semiquinone states at pH 7 by photoreduction of the pure proteins in the presence of EDTA and 5-deazariboflavin. For FNR, the ESR signal of the FAD semiquinone was centred at g = 2.005 with linewidths 2.0 mT in H2O and 1.48 mT in D2O. These data are in agreement with those reported for other neutral flavin semiquinones. The linewidths were the same when measured either at X-band (9.35 GHz) or at S-band (4 GHz), indicating that line broadening is due to unresolved nuclear hyperfine couplings, caused in part by exchangeable protons. When the substrate, NADP+, was added to the semiquinone form of the protein no changes in the linewidth or shape of the spectra were detected, but a decrease in the ESR signal due to the FNR semiquinone was observed, consistent with the reduction of NADP+ to NADPH by reduced FNR and, subsequent displacement of the equilibrium. No changes in the shape or linewidth of the FNR ESR signals were observed when photoreduction of FNR was performed in the presence of either flavodoxin or ferredoxin. Electron nuclear double resonance (ENDOR) spectroscopy of FNR semiquinone from Anabaena PCC 7119 provided further information about the interactions of the flavin radical with protons. A group of signals, with couplings of 5-9.5 MHz, is attributed to protons on C6 and on 8-CH3 of the flavin ring. No change in these hyperfine couplings was detected when the protein was studied in D2O, but the coupling Aiso attributed to protons on 8-CH3 decreased from 8.12 MHz to 7.72 MHz in the presence of NADP+. The decrease in the electron spin density distribution on this part of the flavin ring system was attributed to binding of the substrate, polarising the electron density distribution of the flavin towards the pyrimidine ring. A second group of signals was observed, with hyperfine couplings less than 3 MHz, some of which disappeared when the protein was transferred into D2O. Effects of NADP+ binding to the protein were also observed in these weak couplings. These signals are attributed to displaced water protons, or to exchangeable protons from amino acid residues on the protein near the flavin-binding site, involved in substrate stabilization.(ABSTRACT TRUNCATED AT 400 WORDS)