Electron hopping through proteins

Biological redox machines require efficient transfer of electrons and holes for function. Reactions involving multiple tunneling steps, termed “hopping,” often promote charge separation within and between proteins that is essential for energy storage and conversion. Here we show how semiclassical electron transfer theory can be extended to include hopping reactions: graphical representations (called hopping maps) of the dependence of calculated two-step reaction rate constants on driving force are employed to account for flow in a rhenium-labeled azurin mutant as well as in two structurally characterized redox enzymes, DNA photolyase and MauG. Analysis of the 35 Å radical propagation in ribonucleotide reductases using hopping maps shows that all tyrosines and tryptophans on the radical pathway likely are involved in function. We suggest that hopping maps can facilitate the design and construction of artificial photosynthetic systems for the production of fuels and other chemicals

Hole Hopping through Tryptophan in Cytochrome P450

Electron-transfer kinetics have been measured in four conjugates of cytochrome P450 with surface-bound Ru-photosensitizers. The conjugates are constructed with enzymes from Bacillus megaterium (CYP102A1) and Sulfolobus acidocaldarius (CYP119). A W96 residue lies in the path between Ru and the heme in CYP102A1, whereas H76 is present at the analogous location in CYP119. Two additional conjugates have been prepared with (CYP102A1)W96H and (CYP119)H76W mutant enzymes. Heme oxidation by photochemically generated Ru^(3+) leads to P450 compound II formation when a tryptophan residue is in the path between Ru and the heme; no heme oxidation is observed when histidine occupies this position. The data indicate that heme oxidation proceeds via two-step tunneling through a tryptophan radical intermediate. In contrast, heme reduction by photochemically generated Ru+ proceeds in a single electron tunneling step with closely similar rate constants for all four conjugates

Symmetry-Breaking Charge Transfer of Visible Light Absorbing Systems: Zinc Dipyrrins

Zinc dipyrrin complexes with two identical dipyrrin ligands absorb strongly at 450–550 nm and exhibit high fluorescence quantum yields in nonpolar solvents (e.g., 0.16–0.66 in cyclohexane) and weak to nonexistent emission in polar solvents (i.e., <10^(–3), in acetonitrile). The low quantum efficiencies in polar solvents are attributed to the formation of a nonemissive symmetry-breaking charge transfer (SBCT) state, which is not formed in nonpolar solvents. Analysis using ultrafast spectroscopy shows that in polar solvents the singlet excited state relaxes to the SBCT state in 1.0–5.5 ps and then decays via recombination to the triplet or ground states in 0.9–3.3 ns. In the weakly polar solvent toluene, the equilibrium between a localized excited state and the charge transfer state is established in 11–22 ps

Computational design of a homotrimeric metalloprotein with a trisbipyridyl core

Metal-chelating heteroaryl small molecules have found widespread use as building blocks for coordination-driven, self-assembling nanostructures. The metal-chelating noncanonical amino acid (2,2'-bipyridin-5yl)alanine (Bpy-ala) could, in principle, be used to nucleate specific metalloprotein assemblies if introduced into proteins such that one assembly had much lower free energy than all alternatives. Here we describe the use of the Rosetta computational methodology to design a self-assembling homotrimeric protein with [Fe(Bpy-ala)3]2+ complexes at the interface between monomers. X-ray crystallographic analysis of the homotrimer showed that the design process had near-atomic-level accuracy: The all-atom rmsd between the design model and crystal structure for the residues at the protein interface is ∼1.4 Å. These results demonstrate that computational protein design together with genetically encoded noncanonical amino acids can be used to drive formation of precisely specified metal-mediated protein assemblies that could find use in a wide range of photophysical applications.</p

Generation of Powerful Tungsten Reductants by Visible Light Excitation

The homoleptic arylisocyanide tungsten complexes, W(CNXy)_6 and W(CNIph)_6 (Xy = 2,6-dimethylphenyl, Iph = 2,6-diisopropylphenyl), display intense metal to ligand charge transfer (MLCT) absorptions in the visible region (400–550 nm). MLCT emission (λ_max ≈ 580 nm) in tetrahydrofuran (THF) solution at rt is observed for W(CNXy)6 and W(CNIph)_6 with lifetimes of 17 and 73 ns, respectively. Diffusion-controlled energy transfer from electronically excited W(CNIph)_6 (*W) to the lowest energy triplet excited state of anthracene (anth) is the dominant quenching pathway in THF solution. Introduction of tetrabutylammonium hexafluorophosphate, [Bun4N][PF_6], to the THF solution promotes formation of electron transfer (ET) quenching products, [W(CNIph)6]+ and [anth]^•–. ET from *W to benzophenone and cobalticenium also is observed in [Bun4N][PF6]/THF solutions. The estimated reduction potential for the [W(CNIph)6]^(+)/*W couple is −2.8 V vs Cp_(2)Fe^(+/0), establishing W(CNIph)_6 as one of the most powerful photoreductants that has been generated with visible light

A serine-substituted P450 catalyzes highly efficient carbene transfer to olefins in vivo

Whole-cell catalysts for non-natural chemical reactions will open new routes to sustainable production of chemicals. We designed a cytochrome 'P411' with unique serine-heme ligation that catalyzes efficient and selective olefin cyclopropanation in intact Escherichia coli cells. The mutation C400S in cytochrome P450_(BM3) gives a signature ferrous CO Soret peak at 411 nm, abolishes monooxygenation activity, raises the resting-state FeIII-to-FeII reduction potential and substantially improves NAD(P)H-driven activity

Multiple-Step Electron Flow in Proteins

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Pt(pop-BF2) as a photosensitizer in photocatalytic carbon-chlorine bond formation

Palladium complexes perform regioselective C-H functionalizations, which are essential for many syntheses. We are interested in halogenation of C-H bonds using [(benzo[h]quinoline)PdII(μ-OAc)]2 catalysts. Bulk electrolysis expts. show that we can chlorinate C-H bonds using chloride and Pd catalysts, eliminating the need for harsh chlorinating agents. To improve the speed and energetic cost of C-H transformations we are exploring reactions with photooxidants. Electronically excited fluoroborated tetrakis(μ-pyrophosphito)diplatinate(II) (Pt(pop-BF2)) undergoes facile electron transfer reactions. Electrochem. (E°(PtII-PtII/PtIPtII) = 1.3 V vs. SCE in MeCN) and fluorescence data were used to calc. E°(*PtII-PtII/PtII-PtI) = 1.4 V vs. SCE, suggesting that electronically excited Pt(pop-BF2) can oxidize Pd catalysts. Absorbance spectra of the transiently reduced Pt complexes were recorded. Time-resolved laser expts. in the presence of Pd catalyst suggest that *Pt(pop-BF2) generates catalytically active Pd intermediates, making it a viable sensitizer for photocatalyic C-H functionalizations

Symmetry breaking charge transfer processes of zinc dipyrrin complexes

Photoinduced charge transfer (CT) via symmetry breaking (SB) processes plays a crucial role in photosynthetic reaction center of biol. systems. In such systems, which contain two or more identical and sym. chromophores, CT process from one to another chromophore occurs upon photo-excitation, thus breaking the symmetry. It is of great interest to apply SBCT processes in org. photovoltaics (OPV) and related systems. For application to OPVs, it is desirable for compds. that undergo SB processes to have absorption in the visible spectrum. The most well-documented compds. for SB phenomenon, such as bianthryl derivs., do not absorb visible light. Herein we present study on Zinc Dipyrrin complexes, which contain two identical dipyrrin ligands and absorb strongly at 450-550 nm. These compds. undergo efficient SBCT processes in polar solvents; the photoinduced CT state from the singlet excited state occurs in 4-7 ps, and then recombines back to the triplet state in 1-4 ns