Crystallographic study of wild-type carbonic anhydrase alpha CA1 from Chlamydomonas reinhardtii.

Carbonic anhydrases (CAs) are ubiquitously distributed and are grouped into three structurally independent classes (alphaCA, betaCA and gammaCA). Most alphaCA enzymes are monomeric, but alphaCA1 from Chlamydomonas reinhardtii is a dimer that is uniquely stabilized by disulfide bonds. In addition, during maturation an internal peptide of 35 residues is removed and three asparagine residues are glycosylated. In order to obtain insight into the effects of these structural features on CA function, wild-type C. reinhardtii alphaCA1 has been crystallized in space group P6(5), with unit-cell parameters a=b=134.3, c=120.2 A. The crystal diffracted to 1.88 A resolution and a preliminary solution of its crystal structure has been obtained by the MAD method.

Two complementary enzymes for threonylation of tRNA in crenarchaeota: crystal structure of Aeropyrum pernix threonyl-tRNA synthetase lacking a cis-editing domain.

In protein synthesis, threonyl-tRNA synthetase (ThrRS) must recognize threonine (Thr) from the 20 kinds of amino acids and the cognate tRNA(Thr) from different tRNAs in order to generate Thr-tRNA(Thr). In general, an organism possesses one kind of gene corresponding to ThrRS. However, it has been recently found that some organisms have two different genes for ThrRS in the genome, suggesting that their proteins ThrRS-1 and ThrRS-2 function separately and complement each other in the threonylation of tRNA(Thr), one for catalysis and the other for trans-editing of misacylated Ser-tRNA(Thr). In order to clarify their three-dimensional structures, we performed X-ray analyses of two putatively assigned ThrRSs from Aeropyrum pernix (ApThrRS-1 and ApThrRS-2). These proteins were overexpressed in Escherichia coli, purified, and crystallized. The crystal structure of ApThrRS-1 has been successfully determined at 2.3 A resolution. ApThrRS-1 is a dimeric enzyme composed of two identical subunits, each containing two domains for the catalytic reaction and for anticodon binding. The essential editing domain is completely missing as expected. These structural features reveal that ThrRS-1 catalyzes only the aminoacylation of the cognate tRNA, suggesting the necessity of the second enzyme ThrRS-2 for trans-editing. Since the N-terminal sequence of ApThrRS-2 is similar to the sequence of the editing domain of ThrRS from Pyrococcus abyssi, ApThrRS-2 has been expected to catalyze deaminoacylation of a misacylated serine moiety at the CCA terminus.

Structure of D-3-hydroxybutyrate dehydrogenase prepared in the presence of the substrate D-3-hydroxybutyrate and NAD+.

D-3-hydroxybutyrate dehydrogenase from Alcaligenes faecalis catalyzes the reversible conversion between D-3-hydroxybutyrate and acetoacetate. The enzyme was crystallized in the presence of the substrate D-3-hydroxybutyrate and the cofactor NAD(+) at the optimum pH for the catalytic reaction. The structure, which was solved by X-ray crystallography, is isomorphous to that of the complex with the substrate analogue acetate. The product as well as the substrate molecule are accommodated well in the catalytic site. Their binding geometries suggest that the reversible reactions occur by shuttle movements of a hydrogen negative ion from the C3 atom of the substrate to the C4 atom of NAD(+) and from the C4 atom of NADH to the C3 atom of the product. The reaction might be further coupled to the withdrawal of a proton from the hydroxyl group of the substrate by the ionized Tyr155 residue. These structural features strongly support the previously proposed reaction mechanism of D-3-hydroxybutyrate dehydrogenase, which was based on the acetate-bound complex structure.

Crystallization and preliminary crystallographic studies of putative threonyl-tRNA synthetases from Aeropyrum pernix and Sulfolobus tokodaii.

Threonyl-tRNA synthetase (ThrRS) plays an essential role in protein synthesis by catalyzing the aminoacylation of tRNA(Thr) and editing misacylation. ThrRS generally contains an N-terminal editing domain, a catalytic domain and an anticodon-binding domain. The sequences of the editing domain in ThrRSs from archaea differ from those in bacteria and eukaryotes. Furthermore, several creanarchaea including Aeropyrum pernix K1 and Sulfolobus tokodaii strain 7 contain two genes encoding either the catalytic or the editing domain of ThrRS. To reveal the structural basis for this evolutionary divergence, the two types of ThrRS from the crenarchaea A. pernix and S. tokodaii have been overexpressed in Eschericha coli, purified and crystallized by the hanging-drop vapour-diffusion method. Diffraction data were collected and the structure of a selenomethionine-labelled A. pernix type-1 ThrRS crystal has been solved using the MAD method.

Crystal structures of DNA duplexes stabilized by bicyclic-C residues.

Chemical modification of nucleic acids is being studied extensively as an approach for the development of nucleic acid-based therapies. We found that a nucleotide carrying 7,8-dihydropyrido[2,3-d]pyrimidin-2-one (bicyclic-C or X), which is a cytosine derivative with a propene attached at the N4 and C5 atoms, increases the stability of DNA duplexes. To establish the conformational effects of X on DNA and to obtain insight into the correlation between the structure and stability of X-containing DNA duplexes, the crystal structures of [d(CGCGAATT-X-GCG)](2) and [d(CGCGAAT-X-CGCG)](2) have been determined at 2.9 A resolutions. In both duplexes, the bicyclic-C bases form pairs with the counter bases through hydrogen bonds, and stabilize the duplex formation in part by stacking interactions between X and the subsequent thymine base of the same strand.

Structures of Arthrobacter globiformis urate oxidase-ligand complexes.

The enzyme urate oxidase catalyzes the conversion of uric acid to 5-hydroxyisourate, one of the steps in the ureide pathway. Arthrobacter globiformis urate oxidase (AgUOX) was crystallized and structures of crystals soaked in the substrate uric acid, the inhibitor 8-azaxanthin and allantoin have been determined at 1.9-2.2 A resolution. The biological unit is a homotetramer and two homotetramers comprise the asymmetric crystallographic unit. Each subunit contains two T-fold domains of betabetaalphaalphabetabeta topology, which are usually found in purine- and pterin-binding enzymes. The uric acid substrate is bound tightly to the enzyme by interactions with Arg180, Leu222 and Gln223 from one subunit and with Thr67 and Asp68 of the neighbouring subunit in the tetramer. In the other crystal structures, lithium borate, 8-azaxanthin and allantoate are bound to the enzyme in a similar manner as uric acid. Based on these AgUOX structures, the enzymatic reaction mechanism of UOX has been proposed.

The structures of pyruvate oxidase from Aerococcus viridans with cofactors and with a reaction intermediate reveal the flexibility of the active-site tunnel for catalysis.

The crystal structures of pyruvate oxidase from Aerococcus viridans (AvPOX) complexed with flavin adenine dinucleotide (FAD), with FAD and thiamine diphosphate (ThDP) and with FAD and the 2-acetyl-ThDP intermediate (AcThDP) have been determined at 1.6, 1.8 and 1.9 A resolution, respectively. Each subunit of the homotetrameric AvPOX enzyme consists of three domains, as observed in other ThDP-dependent enzymes. FAD is bound within one subunit in the elongated conformation and with the flavin moiety being planar in the oxidized form, while ThDP is bound in a conserved V-conformation at the subunit-subunit interface. The structures reveal flexible regions in the active-site tunnel which may undergo conformational changes to allow the entrance of the substrates and the exit of the reaction products. Of particular interest is the role of Lys478, the side chain of which may be bent or extended depending on the stage of catalysis. The structures also provide insight into the routes for electron transfer to FAD and the involvement of active-site residues in the catalysis of pyruvate to its products.

Crystal structures of DNA:DNA and DNA:RNA duplexes containing 5-(N-aminohexyl)carbamoyl-modified uracils reveal the basis for properties as antigene and antisense molecules.

Oligonucleotides containing 5-(N-aminohexyl)carbamoyl-modified uracils have promising features for applications as antigene and antisense therapies. Relative to unmodified DNA, oligonucleotides containing 5-(N-aminohexyl)carbamoyl-2'-deoxyuridine ((N)U) or 5-(N-aminohexyl)carbamoyl-2'-O-methyluridine ((N)U(m)), respectively exhibit increased binding affinity for DNA and RNA, and enhanced nuclease resistance. To understand the structural implications of (N)U and (N)U(m) substitutions, we have determined the X-ray crystal structures of DNA:DNA duplexes containing either (N)U or (N)U(m) and of DNA:RNA hybrid duplexes containing (N)U(m). The aminohexyl chains are fixed in the major groove through hydrogen bonds between the carbamoyl amino groups and the uracil O4 atoms. The terminal ammonium cations on these chains could interact with the phosphate oxygen anions of the residues in the target strands. These interactions partly account for the increased target binding affinity and nuclease resistance. In contrast to (N)U, (N)U(m) decreases DNA binding affinity. This could be explained by the drastic changes in sugar puckering and in the minor groove widths and hydration structures seen in the (N)U(m) containing DNA:DNA duplex structure. The conformation of (N)U(m), however, is compatible with the preferred conformation in DNA:RNA hybrid duplexes. Furthermore, the ability of (N)U(m) to render the duplexes with altered minor grooves may increase nuclease resistance and elicit RNase H activity.

Crystallization of auto-regulatory A-rich repeats found in the 5'-UTR of human PABP mRNA.

Eukaryotic poly(A)-binding protein (PABP) binds not only to the 3' poly(A) tail of most mRNAs, but also to the 5'-untranslated region (UTR). The latter form of binding leads to auto-regulation of PABP expression. The 5'-UTR sequence contains A-rich repeats different from that in 3'-UTR. The role of these A-rich repeats in auto-regulation, however, remains unknown. To confirm that the 5'-UTR sequence has a specific structure before or after PABP binding, and to determine the function of such structure, several RNA/DNA fragments containing A-rich repeats were examined by crystallization, fluorescence microscopy and X-ray diffraction. Crystals were obtained for several of these fragments. In particular, single crystals were obtained for the DNA fragment with four repeats, suggesting that such fragment is folded into a regular structure through A:A interactions.

Crystal structure of d(gcGXGAgc) with X=G: a mutation at X is possible to occur in a base-intercalated duplex for multiplex formation.

DNA fragments with the sequences d(gcGX[Y]n Agc) (n=1, X=A, and Y=A, T, or G)form base-intercalated duplexes, which is a basic unit for formation of multiplexes such as octaplex and hexaplex. To examine the stability of multiplexes, a DNA with X=Y=G and n=1 was crystallized under conditions different from those of the previously determined sequences, and its crystal structure has been determined. The two strands are coupled in an anti-parallel fashion to form a base-intercalated duplex, in which the first and second residues form Watson-Crick type G:C pairs and the third and sixth residues form a sheared G:A pairs at both ends of the duplex. The G4 and G5 bases are stacked alternatively on those of the counter strand to form a long G column of G3-G4-G5*-G5-G4*-G3*, the central four Gs being protruded. In addition, the three duplexes are associated to form a hexaplex around a mixture of calcium and sodium cations on the crystallographic threefold axis. These structural features are similar to those of the previous crystals, though slightly different in detail. The present study indicates that mutation at the 4th position is possible to occur in a base-intercalated duplex for multiplex formations, suggesting that DNA fragments with any sequence sandwiched between the two triplets gcG and Agc can form a multiplex.

X-ray analyses of hybrid duplexes between antisense oligonucleotides containing 5-(N-aminohexyl)carbamoyl-2'-O-methyluridine and their target RNAs.

Incorporation of 5-(N-aminohexyl)carbamoyl-2'-O-methyluridine ((N)Um) into oligonucleotides increases antisense properties such as RNA binding affinity, nuclease resistance and RNase H activity. The present X-ray studies on hybrid duplexes formed between antisense oligonucleotides containing (N)Um and their target RNAs have revealed the structural basis for such properties. The terminal ammonium groups of the aminohexyl chains interact with the phosphate oxygen anions. The 2'-O-methyl modification induces the ribose group to adopt the C3'-endo conformation. Comparisons with the structure of unmodified duplex show that the (N)Um incorporation narrows the minor grooves and alters their hydration structures. These structural changes are well correlated to the favorable properties for useful antisense molecules.

X-ray analyses of DNA duplexes containing 5-(N-aminohexyl)carbamoyl modifications.

Oligonucleotides containing polyamines are currently being evaluated as potential antigene compounds for therapeutic purposes. Among them, 5-(N-aminohexyl) carbamoyl-2'-deoxyuridine ((N)U) and 5-(N-aminohexyl) carbamoyl-2'-O-methyluridine ((N)Um) substituted oligonucleotides have higher resistance against nuclease degradation compared to native DNA. Furthermore, oligonucleotides containing (N)U stabilizes duplex formation with the complementary DNA. To elucidate the mechanisms behind these improved antigene properties, we synthesized and crystallized two Dickerson-Drew-type DNA duplexes containing (N)U and (N)Um. The 2'-O-methyl modification in (N)Um was found to induce the ribose ring to adopt the C3'-endo conformation. Electron density maps show possible interactions of the terminal ammonium ion of the aminohexyl groups with the phosphate oxygen anions.