Keiichi Fukuyama

Crystal structure of the fungal peroxidase from Arthromyces ramosus at 1.9 A resolution. Structural comparisons with the lignin and cytochrome c peroxidases.

The crystal structure of the peroxidase (donor: H2O2 oxidoreductase, EC 1.11.1.7) from the hyphomycete Arthromyces ramosus (ARP) has been determined by the multiple isomorphous replacement method and refined by the simulated annealing method to a crystallographic R-factor of 17.4% for the 19,191 reflections with F > 2 sigma F between 7.0 and 1.9 A resolution. The model includes residues 9 to 344, the heme group, two N-acetylglucosamine residues, two calcium ions and 246 water molecules. The root-mean-square deviation of bond lengths from the ideal values is 0.02 A. The mean coordinate error is estimated as 0.2 A. The electron density of the glycine-rich region of the amino-terminal eight residues was invisible. ARP has ten major and two short alpha-helices and a few short beta-strands. The overall tertiary structure of ARP is similar to that of yeast cytochrome c peroxidase (CCP) and is particularly similar to that of the lignin peroxidase (LiP) from Phanerochaete chrysosporium. Relative to CCP, ARP and LiP each have an extension of approximately 40 residues at the carboxy terminus. All eight cysteine residues in ARP form disulfide bonds (C12:C24, C23:C293, C43:C129 and C257:C322). Two calcium sites are inaccessible to solvent. The four disulfide bonds and two calcium sites, which are lacking in CCP, are conserved in ARP and LiP. The bond from Asn304C to Ala305N in ARP is the site sensitive to proteases. An Asx turn present in the Asn303 to Ala305 segment appears to orient the side-chain of Asn304 to outward from the molecule, rendering it easily trappable by pockets of proteases. The proximal heme ligand is His184 in helix F (distance of N epsilon 2 ... Fe, 2.10 A), and one of several water molecules in the distal pocket of the heme bridges the iron atom and the N epsilon 2 of His56. The orientation of the imidazole ring of the distal histidine residue relative to the heme group in ARP differs significantly from that in LiP. The access channel to the distal side of the heme of ARP is markedly wider along the heme plane than that of LiP. Many of the amino acid residues that comprise the entrance of this channel differ for ARP and LiP. This may account for the differences in substrate specificity.

Solvent Tuning of Electrochemical Potentials in the Active Sites of HiPIP Versus Ferredoxin

A persistent puzzle in the field of biological electron transfer is the conserved iron-sulfur cluster motif in both high potential iron-sulfur protein (HiPIP) and ferredoxin (Fd) active sites. Despite this structural similarity, HiPIPs react oxidatively at physiological potentials, whereas Fds are reduced. Sulfur K-edge x-ray absorption spectroscopy uncovers the substantial influence of hydration on this variation in reactivity. Fe-S covalency is much lower in natively hydrated Fd active sites than in HiPIPs but increases upon water removal; similarly, HiPIP covalency decreases when unfolding exposes an otherwise hydrophobically shielded active site to water. Studies on model compounds and accompanying density functional theory calculations support a correlation of Fe-S covalency with ease of oxidation and therefore suggest that hydration accounts for most of the difference between Fd and HiPIP reduction potentials.

Crystal structure of a repair enzyme of oxidatively damaged DNA. MutM (FPG), from an extreme thermophile, Thermus thermophilus HB8

The MutM [formamidopyrimidine DNA glycosylase (Fpg)] protein is a trifunctional DNA base excision repair enzyme that removes a wide range of oxidatively damaged bases (N‐glycosylase activity) and cleaves both the 3′‐ and 5′‐phosphodiester bonds of the resulting apurinic/apyrimidinic site (AP lyase activity). The crystal structure of MutM from an extreme thermophile, Thermus thermophilus HB8, was determined at 1.9 Å resolution with multiwavelength anomalous diffraction phasing using the intrinsic Zn2+ ion of the zinc finger. MutM is composed of two distinct and novel domains connected by a flexible hinge. There is a large, electrostatically positive cleft lined by highly conserved residues between the domains. On the basis of the three‐dimensional structure and taking account of previous biochemical experiments, we propose a DNA‐binding mode and reaction mechanism for MutM. The locations of the putative catalytic residues and the two DNA‐binding motifs (the zinc finger and the helix–two‐turns–helix motifs) suggest that the oxidized base is flipped out from double‐stranded DNA in the binding mode and excised by a catalytic mechanism similar to that of bifunctional base excision repair enzymes.

Crystal structure of rat heme oxygenase-1 in complex with heme

Heme oxygenase catalyzes the oxidative cleavage of protoheme to biliverdin, the first step of heme metabolism utilizing O2 and NADPH. We determined the crystal structures of rat heme oxygenase‐1 (HO‐1)–heme and selenomethionyl HO‐1–heme complexes. Heme is sandwiched between two helices with the δ‐meso edge of the heme being exposed to the surface. Gly143N forms a hydrogen bond to the distal ligand of heme, OH−. The distance between Gly143N and the ligand is shorter than that in the human HO‐1–heme complex. This difference may be related to a pH‐dependent change of the distal ligand of heme. Flexibility of the distal helix may control the stability of the coordination of the distal ligand to heme iron. The possible role of Gly143 in the heme oxygenase reaction is discussed.

Structure and function of plant-type ferredoxins.

The plant-type ferredoxins (Fds) are the [2Fe–2S] proteins that function primarily in photosynthesis; they transfer electrons from photoreduced Photosystem I to ferredoxin NADP+ reductase in which NADPH is produced for CO2 assimilation. In addition, Fds partition electrons to various ferredoxin-dependent enzymes not only for assimilations of inorganic nitrogen and sulfur and N2 fixation but also for regulation of CO2 assimilation cycle. Although Fds are small iron–sulfur proteins with molecular weight of 11 KDa, they are expected to interact with surprisingly many enzymes. Several Fd isoforms were found in non-photosynthetic cells as well as Fds in photosynthetic cells, leading to the recognition that they have differentiated physiological roles. In a quarter of century, X-ray crystallography and NMR spectroscopy provided wealth of structural data, which shed light on the structure–function relationship of the plant-type Fds and gave structural basis for the biochemical and spectroscopic properties so far accumulated. Thus the structural studies of Fds have come to a new era in which different roles of Fds and interactions with various enzymes are clarified on the basis of the tertiary and quaternary structures, although they are premature at present. This article reviews briefly the structures of the plant-type Fds together with their functions, properties, and interactions with Fd related enzymes. Lastly the folding motif of Fd, that has grown to be a large family by including many functionally unrelated proteins, is noted.

Tertiary structure of Bacillus thermoproteolyticus [4Fe-4S] ferredoxin: Evolutionary implications for bacterial ferredoxins

The structure of a low-potential [4Fe-4S] ferredoxin from Bacillus thermoproteolyticus has been solved using anomalous scattering data from iron atoms in the diffraction data of native crystals and refined partially to a crystallographic R-factor of 0.33, with 2.3 A (1 A = 0.1 nm) resolution data. The least-squares refinement based on the Bijvoet differences has determined that the four iron atoms in the cluster are an equal distance, approximately 2.8 A, apart. The NH ... S hydrogen bonds between polypeptide nitrogen atoms, and both cysteine and inorganic sulfur atoms, are present, as in ferrodoxin from Peptococcus aerogenes. The polypeptide chain of the B. thermoproteolyticus ferredoxin has a fold closely similar to that of 2[4Fe-4S] ferredoxin from P. aerogenes. The structural correspondence indicates strongly that both types of ferredoxin evolved from a common ancestor. The second cluster-binding region in P. aerogenes ferredoxin corresponds to the alpha-helix in B. thermoproteolyticus ferredoxin. The secondary-structure predictions strongly suggest that the alpha-helix is generally present in the monocluster-type ferredoxins. The conformational change to alpha-helix, insertions of a loop and a protrusion, as well as the absence of the second cluster in B. thermoproteolyticus ferredoxin, result in the lack of 2-fold symmetry present in P. aerogenes ferredoxin. So, the track of gene duplication is no longer detectable in the tertiary structure alone. The evolutionary events that may have occurred in the ferredoxins with the [4Fe-4S] cluster are discussed.

Structure of the [2Fe-2S] ferredoxin I from the blue-green alga Aphanothece sacrum at 2.2 A resolution.

Crystals of a [2Fe-2S] ferredoxin (Fd) I with a relative molecular mass of 10,480 were obtained from the blue-green alga Aphanothece sacrum. Each asymmetric unit of the crystal contains four molecules. An electron density map calculated by the single isomorphous replacement method with the anomalous dispersion at 2.5 A resolution was refined by averaging the four molecules in the asymmetric unit. Positional and isotropic thermal parameters for the non-hydrogen atoms of the four molecules and 158 water molecules were refined to an R-factor (R = sigma[Fo-Fc[/sigma Fo) of 0.23 by the restrained least-squares method. The estimated root-mean-square (r.m.s.) error for the atomic positions is 0.3 A. The r.m.s. deviations of equivalent C alpha atoms of the asymmetric-unit molecules superposed by the least-squares method average 0.35 A. The Fd molecule has a structure like the beta-barrel in the molecule of the [2Fe-2S] Fd from Spirulina platensis. A [2Fe-2S] cluster is bonded covalently to the protein molecule by four Fe-S, in which three of the Fe-S bonds are in a loop segment from position 38 to 47. The hydrophobic core inside the beta-barrel is formed by seven conservative residues: Val15, Val18, Ile24, Leu51, Ile74, Ala79 and Ile87. The molecular surface around Tyr23, Tyr80 and the active center may interact with ferredoxin-NADP+ reductase. One of the two iron atoms of the [2Fe-2S] cluster should be more easily reduced than the other because of differences in the hydrogen-bonding scheme and the hydrophobicity around the atoms.

The Asymmetric Trimeric Architecture of [2Fe-2S] IscU : Implications for Its Scaffolding during Iron-Sulfur Cluster Biosynthesis

IscU is a key component of the ISC machinery and is involved in the biogenesis of iron-sulfur (Fe-S) proteins. IscU serves as a scaffold for assembly of a nascent Fe-S cluster prior to its delivery to an apo protein. Here, we report the first crystal structure of IscU with a bound [2Fe-2S] cluster from the hyperthermophilic bacterium Aquifex aeolicus, determined at a resolution of 2.3 A, using multiwavelength anomalous diffraction of the cluster. The holo IscU formed a novel asymmetric trimer that harbored only one [2Fe-2S] cluster. One iron atom of the cluster was coordinated by the S(gamma) atom of Cys36 and the N(epsilon) atom of His106, and the other was coordinated by the S(gamma) atoms of Cys63 and Cys107 on the surface of just one of the protomers. However, the cluster was buried inside the trimer between the neighboring protomers. The three protomers were conformationally distinct from one another and associated around a noncrystallographic pseudo-3-fold axis. The three flexible loop regions carrying the ligand-binding residues (Cys36, Cys63, His106 and Cys107) and the N-terminal alpha1 helices were positioned at the interfaces and underwent substantial conformational rearrangement, which stabilized the association of the asymmetric trimer. This unique trimeric A. aeolicus holo-IscU architecture was clearly distinct from other known monomeric apo-IscU/SufU structures, indicating that asymmetric trimer organization, as well as its association/dissociation, would be involved in the scaffolding function of IscU.

The crystal structure of exonuclease RecJ bound to Mn2+ ion suggests how its characteristic motifs are involved in exonuclease activity

RecJ, a 5′ to 3′ exonuclease specific for single-stranded DNA, functions in DNA repair and recombination systems. We determined the crystal structure of RecJ bound to Mn2+ ion essential for its activity. RecJ has a novel fold in which two domains are interconnected by a long helix, forming a central groove. Mn2+ is located on the wall of the groove and is coordinated by conserved residues characteristic of a family of phosphoesterases that includes RecJ proteins. The groove is composed of residues conserved among RecJ proteins and is positively charged. These findings and the narrow width of the groove indicate that the groove binds single- instead of double-stranded DNA.

Structure of [4Fe-4S] ferredoxin from Bacillus thermoproteolyticus refined at 2.3 Å resolution: Structural comparisons of bacterial ferredoxins

The structure of a low-potential ferredoxin isolated from Bacillus thermoproteolyticus has been refined by a restrained least-squares method. The final crystallographic R factor is 0.204 for 2906 reflections with F greater than 3 sigma F in the 6.0 to 2.3 A resolution range. The model contains 81 amino acid residues, one [4Fe-4S] cluster, and 59 water molecules. The root-mean-square deviation from ideal values for bond lengths is 0.018 A, and the mean coordinate error is estimated to be 0.25 A. The present ferredoxin is similar in the topology of the polypeptide backbone to the dicluster-type ferredoxins from Peptococcus aerogenes and Azotobacter vinelandii, but has considerable insertions and deletions of the peptide segments as well as different secondary structures. Although all but the C-terminal C zeta atoms of P. aerogenes ferredoxin superpose on the C alpha atoms of A. vinelandii ferredoxin, only 60% superpose on the C alpha atoms of B. thermoproteolyticus ferredoxin, with a root-mean-square distance of 0.82 A for each pair. The conformations of the peptide segments surrounding the [4Fe-4S] clusters in these three ferredoxins are all conserved. Moreover, the schemes for the NH...S hydrogen bonds in these ferredoxins are nearly identical. The site of the aromatic ring of Tyr27 in B. thermoproteolyticus ferredoxin is close spatially to that of Tyr28 in P. aerogenes ferredoxin with reference to the cluster, but these residues do not correspond in the spatial alignment of their polypeptide backbones. We infer that in monocluster-type ferredoxins, the side-chain at the 27th residue has a crucial effect on the stability of the cluster. Of the four cysteine residues that bind to the second Fe-S cluster in the dicluster-type ferredoxins, two are conserved in the monocluster-type ferredoxins from Desulfovibrio gigas. D. desulfuricans Norway, and Clostridium thermoaceticum. The tertiary structure of B. thermoproteolyticus ferredoxin suggests that in such monocluster-type ferredoxins these two cysteine residues, which in it correspond to Ala21 and Asp53, form a disulfide bridge.