Pär Nordlund

Crystal structure of human leukotriene A 4 hydrolase, a bifunctional enzyme in inflammation

Leukotriene (LT) A4 hydrolase/aminopeptidase (LTA4H) is a bifunctional zinc enzyme that catalyzes the biosynthesis of LTB4, a potent lipid chemoattractant involved in inflammation, immune responses, host defense against infection, and PAF-induced shock. The high resolution crystal structure of LTA4H in complex with the competitive inhibitor bestatin reveals a protein folded into three domains that together create a deep cleft harboring the catalytic Zn2+ site. A bent and narrow pocket, shaped to accommodate the substrate LTA4, constitutes a highly confined binding region that can be targeted in the design of specific anti-inflammatory agents. Moreover, the structure of the catalytic domain is very similar to that of thermolysin and provides detailed insight into mechanisms of catalysis, in particular the chemical strategy for the unique epoxide hydrolase reaction that generates LTB4.

Geometry of the soluble methane monooxygenase catalytic diiron center in two oxidation states.

BACKGROUND The hydroxylase component of soluble methane monooxygenase (sMMO) contains a dinuclear iron center responsible for the oxidation of methane to methanol. As isolated, the center is in the oxidized, diiron(III) state. The 2.2 A resolution X-ray structure of the oxidized hydroxylase, Hox, from Methylococcus capsulatus (Bath) was previously determined at 4 degrees C. In this structure the two iron atoms are bridged by a glutamate, a hydroxide ion, and an acetate ion, and additionally coordinated to two His residues, three Glu residues, and a water molecule. RESULTS The 1.7 A resolution crystal structures of the sMMO hydroxylase from Methylococcus capsulatus (Bath) in both its oxidized diiron(III), Hox, and dithionite-treated, reduced diiron(II), Hred, oxidation states were determined at -160 degrees C. The structure of the diiron center in Hox differs from that previously reported at 2.2 A resolution and 4 degrees C. Although the hydroxide bridge is retained, the bidentate, bridging ligand assigned as acetate is replaced by a weakly coordinating monoatomic water bridge. In the resulting four-membered Fe(OH)Fe(OH2) ring, the Fe ... Fe distance is shortened from 3.4 A to 3.1 A. In protomer A of Hred, the hydroxide bridge is displaced by an oxygen atom of Glu243, which undergoes a carboxylate shift from its terminal monodentate binding mode in Hox to a mode in which the carboxylate is both monoatomic bridging and bidentate chelating. We therefore conclude that the center has been reduced to the diiron(II) oxidation state. Both iron atoms are coordinated to five ligands and weakly to a sixth water molecule in the resulting structure. The diiron center in protomer B of Hred has the same composition as those in Hox. In both the oxidized and reduced structures, the diiron core is connected through hydrogen bonds involving exogenous species to Thr213 in the active site cavity. CONCLUSIONS The diiron center in Hox can change its exogenous ligand coordination and geometry, a property that could be important in the catalytic cycle of sMMO. In Hred, a carboxylate shift occurs, extruding hydroxide ion and opening coordination sites for reaction with O2 to form the diiron(III) peroxo intermediate, Hperoxo. Residue Thr213 may function in catalysis.

Green fluorescent protein as an indicator to monitor membrane protein overexpression in Escherichia coli

Escherichia coli is one of the most widely used vehicles to overexpress membrane proteins (MPs). Currently, it is not possible to predict if an overexpressed MP will end up in the cytoplasmic membrane or in inclusion bodies. Overexpression of MPs in the cytoplasmic membrane is strongly favoured to overexpression in inclusion bodies, since it is relatively easy to isolate MPs from membranes and usually impossible to isolate them from inclusion bodies. Here we show that green fluorescent protein (GFP), when fused to an overexpressed MP, can be used as an indicator to monitor membrane insertion versus inclusion body formation of overexpressed MPs in E. coli. Furthermore, we show that an overexpressed MP can be recovered from a MP–GFP fusion using a site specific protease. This makes GFP an excellent tool for large‐scale MP target selection in structural genomics projects.

Di-iron—carboxylate proteins

Di-iron centers bridged by carboxylate residues and oxide/hydroxide groups have so far been seen in four classes of proteins involved in dioxygen chemistry or phosphoryl transfer reactions. The dinuclear iron centers in these proteins are coordinated by histidines and additional carboxylate ligands. Recent structural data on some of these enzymes, combined with spectroscopic and kinetic data, can now serve as a base for detailed mechanistic suggestions. The di-iron sites in the major class of hydroxylase-oxidase enzymes, which contains ribonucleotide reductase and methane monooxygenase, show significant flexibility in the geometry of their coordination of three or more carboxylate groups. This flexibility, combined with a relatively low coordination number, and a buried environment suitable for reactive oxygen chemistry, explains their efficient harnessing of the oxidation power of molecular oxygen.

Crystal structure of reduced protein R2 of ribonucleotide reductase: the structural basis for oxygen activation at a dinuclear iron site.

BACKGROUND Ribonucleotide reductases (RNRs) catalyze the formation of the deoxyribonucleotides that are essential for DNA synthesis. The R2 subunit of Escherichia coli RNR is a homodimer containing one dinuclear iron centre per monomer. A tyrosyl radical is essential for catalysis, and is formed via a reaction in which the reduced, diferrous form of the iron centre activates dioxygen. To help understand the mechanism of oxygen activation, we examined the structure of the diferrous form of R2. RESULTS The crystal structures of reduced forms of both wild type R2 and a mutant of R2 (Ser211--> Ala) have been determined at 1.7 A and 2.2 A resolution, respectively. The diferrous iron centre was compared to the previously determined structure of the oxidized, diferric form of R2. In both forms of R2 the iron centre is coordinated by the same carboxylate dominated ligand sphere, but in the reduced form there are clear conformational changes in three of the carboxylate ligands and the bridging mu-oxo group and two water molecules are lost. In the reduced form of R2 the coordination number decreases from six to four for both ferrous ions, explaining their high reactivity towards dioxygen. The structure of the mutant Ser211--> Ala, known to have impaired reduction kinetics, shows a large conformational change in one of the neighbouring helices although the iron coordination is very similar to the wild type protein. CONCLUSIONS Carboxylate shifts are often important for carboxylate coordinated metal clusters; they allow the metals to achieve different coordination modes in redox reactions. In the case of reduced R2 these carboxylate shifts allow the formation of accessible reaction sites for dioxygen. The Ser211--> Ala mutant displays a conformational change in the helix containing the mutation, explaining its altered reduction kinetics.

Crystal structures of the methane monooxygenase hydroxylase from Methylococcus capsulatus (Bath): implications for substrate gating and component interactions.

The crystal structure of the nonheme iron‐containing hydroxylase component of methane monooxygenase hydroxylase (MMOH) from Methylococcus capsulatus (Bath) has been solved in two crystal forms, one of which was refined to 1.7 Å resolution. The enzyme is composed of two copies each of three subunits (α2β2γ2), and all three subunits are almost completely α‐helical, with the exception of two β hairpin structures in the α subunit. The active site of each α subunit contains one dinuclear iron center, housed in a four‐helix bundle. The two iron atoms are octahedrally coordinated by 2 histidine and 4 glutamic acid residues as well as by a bridging hydroxide ion, a terminal water molecule, and at 4°C, a bridging acetate ion, which is replaced at −160°C with a bridging water molecule. Comparison of the results for two crystal forms demonstrates overall conservation and relative orientation of the domain structures. The most prominent structural difference identified between the two crystal forms is in an altered side chain conformation for Leu 110 at the active site cavity. We suggest that this residue serves as one component of a hydrophobic gate controlling access of substrates to and products from the active site. The leucine gate may be responsible for the effect of the B protein component on the reactivity of the reduced hydroxylase with dioxygen. A potential reductase binding site has been assigned based on an analysis of crystal packing in the two forms and corroborated by inhibition studies with a synthetic peptide corresponding to the proposed docking position. Proteins 29:141–152, 1997.

Displacement of the tyrosyl radical cofactor in ribonucleotide reductase obtained by single-crystal high-field EPR and 1.4-Å x-ray data

The R2 protein of class I ribonucleotide reductase generates and stores a tyrosyl radical essential for ribonucleotide reduction and, thus, DNA synthesis. X-ray structures of the protein have enabled detailed mechanistic suggestions, but no structural information has been available for the active radical-containing state of the protein. Here we report on methods to generate the functional tyrosyl radical in single crystals of R2 from Escherichia coli (Y122•). We further report on subsequent high-field EPR experiments on the radical-containing crystals. A full rotational pattern of the spectra was collected and the orientation of the g-tensor axes were determined, which directly reflect the orientation of the radical in the crystal frame. The EPR data are discussed in comparison with a 1.42-Å x-ray structure of the met (oxidized) form of the protein, also presented in this paper. Comparison of the orientation of the radical Y122• obtained from high-field EPR with that of the reduced tyrosine Y122-OH reveals a significant rotation of the tyrosyl side chain, away from the diiron center, in the active radical state. Implications for the radical transfer connecting the diiron site in R2 with the substrate-binding site in R1 are discussed. In addition, the present study demonstrates that structural and functional information about active radical states can be obtained by combined x-ray and high-field EPR crystallography.

An efficient strategy for high-throughput expression screening of recombinant integral membrane proteins.

The recombinant expression of integral membrane proteins is considered a major challenge, and together with the crystallization step, the major hurdle toward routine structure determination of membrane proteins. Basic methodologies for high‐throughput (HTP) expression optimization of soluble proteins have recently emerged, providing statistically significant success rates for producing such proteins. Experimental procedures for handling integral membrane proteins are generally more challenging, and there have been no previous comprehensive reports of HTP technology for membrane protein production.

The structure of Desulfovibrio vulgaris rubrerythrin reveals a unique combination of rubredoxin-like FeS4 and ferritin-like diiron domains.

We have determined the structure of rubrerythrin, a non-haem iron protein from the anaerobic sulphate-reducing bacterium, Desulfovibrio vulgaris (Hildenborough), by X-ray crystallography. The structure reveals a tetramer of two-domain subunits. Each subunit contains a four-helix bundle surrounding a diiron-oxo site and a C-terminal rubredoxin-like FeS4 domain. The diiron-oxo site contains a larger number of carboxylate ligands and a higher degree of solvent exposure than do those in other diiron-oxo proteins. The four-helix bundle of rubrerythrin closely resembles those of the ferritin and bacterioferritin subunits, suggesting a relationship among these proteins—consistent with the recently demonstrated ferroxidase activity of rubrerythrin.

Crystal structure of a human mitochondrial deoxyribonucleotidase

5′ nucleotidases are ubiquitous enzymes that dephosphorylate nucleoside monophosphates and participate in the regulation of nucleotide pools. The mitochondrial 5′-(3′) deoxyribonucleotidase (dNT-2) specifically dephosphorylates dUMP and dTMP, thereby protecting mitochondrial DNA replication from excess dTTP. We have solved the structure of dNT-2, the first of a mammalian 5′ nucleotidase. The structure reveals a relationship to the HAD family, members of which use an aspartyl nucleophile as their common catalytic strategy, with a phosphoserine phosphatase as the most similar neighbor. A structure-based sequence alignment of dNT-2 with other 5′ nucleotidases also suggests a common origin for these enzymes. Here we study the structures of dNT-2 in complex with bound phosphate and beryllium trifluoride plus thymidine as model for a phosphoenzyme–product complex. Based on these structures, determinants for substrate specificity recognition and the catalytic action of dNT-2 are outlined.