Topology of Gemini-shaped Hexagonal Heterojunction for Efficient Stereoconvergent Transformation via Dynamic Kinetic Resolution.

Despite recent advances in the combination of kinetic resolution and racemization for efficient stereoconvergent transformation, the poor stability and limited reaction activities of the products restrict their wide application in industrial production. To overcome these problems, Gemini-shaped hexagons with para-heterojunctions for one-dimensional and two-dimensional supramolecular polymers were designed via hydrogen-bonding adhesion by racemization catalyst 1 and kinetic resolution 2 in this work. The polymers from the assembly of Gemini-shaped hexagons exhibit rapid catalytic behaviour with efficient selectivity for the desired configuration in the synthesis of tertiary alcohols with contiguous stereocenters through dynamic kinetic resolution for the nanoscale heterojunctions of dissimilar catalysts.

Hydrogen Evolution of a Unique DNAzyme Composed of Cobalt-Protoporphyrin IX and G-Quadruplex DNA.

Molecular hydrogen (H ) is a clean and renewable fuel that has garnered significant interest in the search for alternatives to fossil fuels. Here, we constructed an artificial DNAzyme composed of cobalt-protoporphyrin IX (CoPP) and G-quadruplex DNA, possessing a unique H O ligand between the CoPP and G-quartet planes. We show for the first time that CoPP-DNAzyme catalyzes photo-induced H production under anaerobic conditions with a turnover number (TON) of 1229 ± 51 over 12 h at pH 6.

Construction of "peptide-hemin/DNA" hybrid-complexes and their peroxidase activities.

-Acetylated microperoxidase-11 and G-quadruplex DNA are shown to form a stable "peptide-hemin/DNA" hybrid-complex, in which the peroxidase activity at the interface between hemin and the G-quartet planes exponentially increases with increasing value.

Resonance Raman Studies on Heme Ligand Stretching Modes in Methionine80-Depleted Cytochrome : Fe-His, Fe-O, and O-O Stretching Modes.

The peroxidase activity of cytochrome (cyt) increases when Met80 dissociates from the heme iron, which is related to the initial cyt membrane permeation step of apoptosis. Met80-dissociated cyt can form an oxygenated species. Herein, resonance Raman spectra of Met80-depleted horse cyt (M80A cyt ) were analyzed to elucidate the heme ligand properties of Met80-dissociated cyt .

Structural and spectroscopic characterization of CO inhibition of [NiFe]-hydrogenase from Citrobacter sp. S-77.

Hydrogenases catalyze the reversible oxidation of H. Carbon monoxide (CO) is known to be a competitive inhibitor of O-sensitive [NiFe]-hydrogenases. Although the activities of some O-tolerant [NiFe]-hydrogenases are unaffected by CO, the partially O-tolerant [NiFe]-hydrogenase from Citrobacter sp.

Proton Transfer Mechanisms in Bimetallic Hydrogenases.

Hydrogenases are metalloenzymes that catalyze proton reduction and H oxidation with outstanding efficiency. They are model systems for bioinorganic chemistry, including low-valent transition metals, hydride chemistry, and proton-coupled electron transfer. In this Account, we describe how photochemistry and infrared difference spectroscopy can be used to identify the dynamic hydrogen-bonding changes that facilitate proton transfer in [NiFe]- and [FeFe]-hydrogenase.

Mechanism and Application of the Catalytic Reaction of [NiFe] Hydrogenase: Recent Developments.

Hydrogenases (H ase) catalyze the oxidation of dihydrogen and the reduction of protons with remarkable efficiency, thereby attracting considerable attention in the energy field due to their biotechnological potential. For this simple reaction, [NiFe] H ase has developed a sophisticated but intricate mechanism with the heterolytic cleavage of dihydrogen, where its Ni-Fe active site exhibits various redox states. Recently, new spectroscopic and crystal structure studies of [NiFe] H ases have been reported, providing significant insights into the catalytic reaction mechanism, hydrophobic gas-access tunnel, proton-transfer pathway, and electron-transfer pathway of [NiFe] H ases.

Cysteine SH and Glutamate COOH Contributions to [NiFe] Hydrogenase Proton Transfer Revealed by Highly Sensitive FTIR Spectroscopy.

A [NiFe] hydrogenase (H ase) is a proton-coupled electron transfer enzyme that catalyses reversible H oxidation; however, its fundamental proton transfer pathway remains unknown. Herein, we observed the protonation of Cys546-SH and Glu34-COOH near the Ni-Fe site with high-sensitivity infrared difference spectra by utilizing Ni-C-to-Ni-L and Ni-C-to-Ni-SI photoconversions. Protonated Cys546-SH in the Ni-L state was verified by the observed SH stretching frequency (2505 cm ), whereas Cys546 was deprotonated in the Ni-C and Ni-SI states.

Redox-dependent conformational changes of a proximal [4Fe-4S] cluster in Hyb-type [NiFe]-hydrogenase to protect the active site from O.

Citrobacter sp. S-77 [NiFe]-hydrogenase harbors a standard [4Fe-4S] cluster proximal to the Ni-Fe active site. The presence of relocatable water molecules and a flexible aspartate enables the [4Fe-4S] to display redox-dependent conformational changes.

Comprehensive reaction mechanisms at and near the Ni-Fe active sites of [NiFe] hydrogenases.

[NiFe] hydrogenase (H2ase) catalyzes the oxidation of dihydrogen to two protons and two electrons and/or its reverse reaction. For this simple reaction, the enzyme has developed a sophisticated but intricate mechanism with heterolytic cleavage of dihydrogen (or a combination of a hydride and a proton), where its Ni-Fe active site exhibits various redox states. Recently, thermodynamic parameters of the acid-base equilibrium for activation-inactivation, a new intermediate in the catalytic reaction, and new crystal structures of [NiFe] H2ases have been reported, providing significant insights into the activation-inactivation and catalytic reaction mechanisms of [NiFe] H2ases.

Activation Mechanism of the Streptomyces Tyrosinase Assisted by the Caddie Protein.

Tyrosinase (EC 1.14.18.

Equilibrium between inactive ready Ni-SI and active Ni-SI states of [NiFe] hydrogenase studied by utilizing Ni-SI-to-Ni-SI photoactivation.

Previously, the Ni-SI state of [NiFe] hydrogenase was found to convert to the Ni-SI state by light irradiation. Herein, large activation energies and a large kinetic isotope effect were obtained for the reconversion of the Ni-SI state to the Ni-SI state after the Ni-SI-to-Ni-SI photoactivation, suggesting that the Ni-SI state reacts with HO and leaves a bridging hydroxo ligand for the Ni-SI state.

Characterization of the interaction between heme and a parallel G-quadruplex DNA formed from d(TTGAGG).

Structure-function relationships of complexes between heme and G-quadruplex DNAs have attracted interest from researchers in related fields. A carbon monoxide adduct of a complex between heme and a parallel G-quadruplex DNA formed from hexanucleotide d(TTGAGG) (heme-[d(TTGAGG)] complex) has been characterized using H NMR spectroscopy, and the obtained results were compared with those for the heme-[d(TTAGGG)] complex previously studied in order to elucidate the effect of the incorporation of an A-quartet into stacked G-quartets in the 3'-terminal region of the DNA on the structure of the heme-DNA complex. We found that a π-π stacking interaction between the porphyrin moiety of the heme and the 3'-terminal G-quartet of the DNA is affected by the nature of the stacked G-quartets.

Characterization of Heme-DNA Complexes Composed of Some Chemically Modified Hemes and Parallel G-Quadruplex DNAs.

Heme {Fe(II)- or Fe(III)-protoporphyrin IX complex [heme(Fe(2+)) or heme(Fe(3+)), respectively]} binds selectively to the 3'-terminal G-quartet of a parallel G-quadruplex DNA formed from a single repeat sequence of the human telomere, d(TTAGGG), through a π-π stacking interaction between the porphyrin moiety of the heme and the G-quartet. The binding affinities of some chemically modified hemes(Fe(3+)) for DNA and the structures of complexes between the modified hemes(Fe(2+)) and DNA, with carbon monoxide (CO) coordinated to the heme Fe atom on the side of the heme opposite the G6 G-quartet, have been characterized to elucidate the interaction between the heme and G-quartet in the complexes through analysis of the effects of the heme modification on the structural properties of the complex. The study revealed that the binding affinities and structures of the complexes were barely affected by the heme modification performed in the study.

FT-IR Characterization of the Light-Induced Ni-L2 and Ni-L3 States of [NiFe] Hydrogenase from Desulfovibrio vulgaris Miyazaki F.

Different light-induced Ni-L states of [NiFe] hydrogenase from its Ni-C state have previously been observed by EPR spectroscopy. Herein, we succeeded in detecting simultaneously two Ni-L states of [NiFe] hydrogenase from Desulfovibrio vulgaris Miyazaki F by FT-IR spectroscopy. A new light-induced νCO band at 1890 cm(-1) and νCN bands at 2034 and 2047 cm(-1) were detected in the FT-IR spectra of the H2-activated enzyme under N2 atmosphere at basic conditions, in addition to the 1910 cm(-1) νCO band and 2047 and 2061 cm(-1) νCN bands of the Ni-L2 state.

Control of the transition between Ni-C and Ni-SI(a) states by the redox state of the proximal Fe-S cluster in the catalytic cycle of [NiFe] hydrogenase.

[NiFe] hydrogenase catalyzes the reversible cleavage of H2. The electrons produced by the H2 cleavage pass through three Fe-S clusters in [NiFe] hydrogenase to its redox partner. It has been reported that the Ni-SI(a), Ni-C, and Ni-R states of [NiFe] hydrogenase are involved in the catalytic cycle, although the mechanism and regulation of the transition between the Ni-C and Ni-SI(a) states remain unrevealed.

Electronic control of ligand-binding preference of a myoglobin mutant.

The L29F mutant of sperm whale myoglobin (Mb), where the leucine 29 residue was replaced by phenylalanine (Phe), was shown to exhibit remarkably high affinity to oxygen (O2), possibly due to stabilization of the heme Fe atom-bound O2 in the mutant protein through a proposed unique electrostatic interaction with the introduced Phe29, in addition to well-known hydrogen bonding with His64 [Carver, T. E.; Brantley, R.

Electronic control of discrimination between O2 and CO in myoglobin lacking the distal histidine residue.

We analyzed the oxygen (O2) and carbon monoxide (CO) binding properties of the H64L mutant of myoglobin reconstituted with chemically modified heme cofactors possessing a heme Fe atom with a variety of electron densities, in order to elucidate the effect of the removal of the distal His64 on the control of both the O2 affinity and discrimination between O2 and CO of the protein by the intrinsic heme Fe reactivity through the electron density of the heme Fe atom (ρFe). The study revealed that, as in the case of the native protein, the O2 affinity of the H64L mutant protein is regulated by the ρFe value in such a manner that the O2 affinity of the protein decreases, due to an increase in the O2 dissociation rate constant, with a decrease in the ρFe value, and that the O2 affinities of the mutant and native proteins are affected comparably by a given change in the ρFe value. On the other hand, the CO affinity of the H64L mutant protein was found to increase, due to a decrease in the CO dissociation rate constant, with a decrease in the ρFe value, whereas that of the native protein was essentially independent of a change in the ρFe value.

Inversion of the stereochemistry around the sulfur atom of the axial methionine side chain through alteration of amino acid side chain packing in Hydrogenobacter thermophilus cytochrome C552 and its functional consequences.

In cytochrome c, the coordination of the axial Met Sδ atom to the heme Fe atom occurs in one of two distinctly different stereochemical manners, i.e., R and S configurations, depending upon which of the two lone pairs of the Sδ atom is involved in the bond; hence, the Fe-coordinated Sδ atom becomes a chiral center.

Relationship between the electron density of the heme Fe atom and the vibrational frequencies of the Fe-bound carbon monoxide in myoglobin.

We analyzed the vibrational frequencies of the Fe-bound carbon monoxide (CO) of myoglobin reconstituted with a series of chemically modified heme cofactors possessing a heme Fe atom with a variety of electron densities. The study revealed that the stretching frequency of Fe-bound CO (ν(CO)) increases with decreasing electron density of the heme Fe atom (ρ(Fe)). This finding demonstrated that the ν(CO) value can be used as a sensitive measure of the ρ(Fe) value and that the π back-donation of the heme Fe atom to CO is affected by the heme π-system perturbation induced through peripheral side chain modifications.

Relationship between oxygen affinity and autoxidation of myoglobin.

Studies using myoglobins reconstituted with a variety of chemically modified heme cofactors revealed that the oxygen affinity and autoxidation reaction rate of the proteins are highly correlated to each other, both decreasing with decreasing the electron density of the heme iron atom. An Fe(3+)-O(2)(-)-like species has been expected for the Fe(2+)-O(2) bond in the protein, and the electron density of the heme iron atom influences the resonance process between the two forms. A shift of the resonance toward the Fe(2+)-O(2) form results in lowering of the O(2) affinity due to an increase in the O(2) dissociation rate.

Interaction between the heme and a G-quartet in a heme-DNA complex.

The structure of a complex between heme(Fe(3+)) and a parallel G-quadruplex DNA formed from a single repeat sequence of the human telomere, d(TTAGGG), has been characterized by (1)H NMR. The study demonstrated that the heme(Fe(3+)) is sandwiched between the 3'-terminal G-quartets of the G-quadruplex DNA. Hence, the net +1 charge of the heme(Fe(3+)) in the complex is surrounded by the eight carbonyl oxygen atoms of the G-quartets.

Structural characterization of a carbon monoxide adduct of a heme-DNA complex.

The structure of a carbon monoxide (CO) adduct of a complex between heme and a parallel G-quadruplex DNA formed from a single repeat sequence of the human telomere, d(TTAGGG), has been characterized using ¹H and ¹³C NMR spectroscopy and density function theory calculations. The study revealed that the heme binds to the 3'-terminal G-quartet of the DNA though a π-π stacking interaction between the porphyrin moiety of the heme and the G-quartet. The π-π stacking interaction between the pseudo-C₂-symmetric heme and the C₄-symmetric G-quartet in the complex resulted in the formation of two isomers possessing heme orientations differing by 180° rotation about the pseudo-C₂ axis with respect to the DNA.