Combined Mössbauer spectroscopic, multi-edge X-ray absorption spectroscopic, and density functional theoretical study of the radical SAM enzyme spore photoproduct lyase.

Spore photoproduct lyase (SPL), a member of the radical S-adenosyl-L-methionine (SAM) superfamily, catalyzes the direct reversal of the spore photoproduct, a thymine dimer specific to bacterial spores, to two thymines. SPL requires SAM and a redox-active [4Fe-4S] cluster for catalysis. Mössbauer analysis of anaerobically purified SPL indicates the presence of a mixture of cluster states with the majority (40 %) as [2Fe-2S](2+) clusters and a smaller amount (15 %) as [4Fe-4S](2+) clusters. On reduction, the cluster content changes to primarily (60 %) [4Fe-4S](+). The speciation information from Mössbauer data allowed us to deconvolute iron and sulfur K-edge X-ray absorption spectra to uncover electronic (X-ray absorption near-edge structure, XANES) and geometric (extended X-ray absorption fine structure, EXAFS) structural features of the Fe-S clusters, and their interactions with SAM. The iron K-edge EXAFS data provide evidence for elongation of a [2Fe-2S] rhomb of the [4Fe-4S] cluster on binding SAM on the basis of an Fe···Fe scatterer at 3.0 Å. The XANES spectra of reduced SPL in the absence and presence of SAM overlay one another, indicating that SAM is not undergoing reductive cleavage. The X-ray absorption spectroscopy data for SPL samples and data for model complexes from the literature allowed the deconvolution of contributions from [2Fe-2S] and [4Fe-4S] clusters to the sulfur K-edge XANES spectra. The analysis of pre-edge features revealed electronic changes in the Fe-S clusters as a function of the presence of SAM. The spectroscopic findings were further corroborated by density functional theory calculations that provided insights into structural and electronic perturbations that can be correlated by considering the role of SAM as a catalyst or substrate.

Protein delivery of a Ni catalyst to photosystem I for light-driven hydrogen production.

The direct conversion of sunlight into fuel is a promising means for the production of storable renewable energy. Herein, we use Nature's specialized photosynthetic machinery found in the Photosystem I (PSI) protein to drive solar fuel production from a nickel diphosphine molecular catalyst. Upon exposure to visible light, a self-assembled PSI-[Ni(P2(Ph)N2(Ph))2](BF4)2 hybrid generates H2 at a rate 2 orders of magnitude greater than rates reported for photosensitizer/[Ni(P2(Ph)N2(Ph))2](BF4)2 systems. The protein environment enables photocatalysis at pH 6.3 in completely aqueous conditions. In addition, we have developed a strategy for incorporating the Ni molecular catalyst with the native acceptor protein of PSI, flavodoxin. Photocatalysis experiments with this modified flavodoxin demonstrate a new mechanism for biohybrid creation that involves protein-directed delivery of a molecular catalyst to the reducing side of Photosystem I for light-driven catalysis. This work further establishes strategies for constructing functional, inexpensive, earth-abundant solar fuel-producing PSI hybrids that use light to rapidly produce hydrogen directly from water.

Nature-driven photochemistry for catalytic solar hydrogen production: a Photosystem I-transition metal catalyst hybrid.

Solar energy conversion of water into the environmentally clean fuel hydrogen offers one of the best long-term solutions for meeting future energy demands. Nature provides highly evolved, finely tuned molecular machinery for solar energy conversion that exquisitely manages photon capture and conversion processes to drive oxygenic water-splitting and carbon fixation. Herein, we use one of Nature's specialized energy-converters, the Photosystem I (PSI) protein, to drive hydrogen production from a synthetic molecular catalyst comprised of inexpensive, earth-abundant materials. PSI and a cobaloxime catalyst self-assemble, and the resultant complex rapidly produces hydrogen in aqueous solution upon exposure to visible light. This work establishes a strategy for enhancing photosynthetic efficiency for solar fuel production by augmenting natural photosynthetic systems with synthetically tunable abiotic catalysts.

Complete stereospecific repair of a synthetic dinucleotide spore photoproduct by spore photoproduct lyase.

Spore photoproduct lyase (SP lyase), a member of the radical S-adenosylmethionine superfamily of enzymes, catalyzes the repair of 5-thyminyl-5,6-dihydrothymine [spore photoproduct (SP)], a type of UV-induced DNA damage unique to bacterial spores. The anaerobic purification and characterization of Clostridium acetobutylicum SP lyase heterologously expressed in Escherichia coli, and its catalytic activity in repairing stereochemically defined synthetic dinucleotide SPs was investigated. The purified enzyme contains between 2.3 and 3.1 iron atoms per protein. Electron paramagnetic resonance (EPR) spectroscopy reveals an isotropic signal centered at g = 1.99, characteristic of a [3Fe-4S](+) cluster accounting for 3-4% of the iron in the sample. Upon reduction, a nearly axial signal (g = 2.03, 1.93 and 1.92) characteristic of a [4Fe-4S](+) cluster is observed that accounts for 34-45% of total iron. Addition of S-adenosylmethionine to the reduced enzyme produces a rhombic signal (g = 2.02, 1.93, 1.82) unique to the S-adenosyl-L: -methionine complex while decreasing the overall EPR intensity. This reduced enzyme is shown to rapidly and completely repair the 5R diastereomer of a synthetic dinucleotide SP with a specific activity of 7.1 +/- 0.6 nmol min(-1) mg(-1), whereas no repair was observed for the 5S diastereomer.

Control of radical chemistry in the AdoMet radical enzymes.

The radical AdoMet superfamily comprises a diverse set of >2800 enzymes that utilize iron-sulfur clusters and S-adenosylmethionine (SAM or AdoMet) to initiate a diverse set of radical-mediated reactions. The intricate control these enzymes exercise over the radical transformations they catalyze is an amazing feat of elegance and sophistication in biochemistry. This review focuses on the accumulating evidence for how these enzymes control this remarkable chemistry, including controlling the reactivity between the iron-sulfur cluster and AdoMet, and controlling the subsequent radical transformations.

Spore photoproduct lyase catalyzes specific repair of the 5R but not the 5S spore photoproduct.

Bacterial spores are remarkable in their resistance to chemical and physical stresses, including exposure to UV radiation. The unusual UV resistance of bacterial spores is a result of the unique photochemistry of spore DNA, which results in accumulation of 5-thyminyl-5,6-dihydrothymine (spore photoproduct, or SP), coupled with the efficient repair of accumulated damage by the enzyme spore photoproduct lyase (SPL). SPL is a member of the radical AdoMet superfamily of enzymes, and utilizes an iron-sulfur cluster and S-adenosylmethionine to repair SP by a direct reversal mechanism initiated by H atom abstraction from C-6 of the thymine dimer. While two distinct diastereomers of SP (5R or 5S) could in principle be formed upon UV irradiation of bacterial spores, only the 5R configuration is possible for SP formed from adjacent thymines in double helical DNA, due to the constraints imposed by the DNA structure; the 5S configuration is possible in less well-defined DNA structures or as an interstrand cross-link. We report here results from HPLC and MS analysis of in vitro enzymatic assays on stereochemically defined SP substrates demonstrating that SPL specifically repairs only the 5R isomer of SP. The observation that 5R-SP, but not 5S-SP, is a substrate for SPL is consistent with the expectation that 5R is the SP isomer produced in vivo upon UV irradiation of bacterial spore DNA.