The crystal structures of native hydroquinone 1,2-dioxygenase from Sphingomonas sp. TTNP3 and of substrate and inhibitor complexes.

The crystal structure of hydroquinone 1,2-dioxygenase, a Fe(II) ring cleaving dioxygenase from Sphingomonas sp. strain TTNP3, which oxidizes a wide range of hydroquinones to the corresponding 4-hydroxymuconic semialdehydes, has been solved by Molecular Replacement, using the coordinates of PnpCD from Pseudomonas sp. strain WBC-3. The enzyme is a heterotetramer, constituted of two subunits α and two ß of 19 and 38kDa, respectively. Both the two subunits fold as a cupin, but that of the small α subunit lacks a competent metal binding pocket. Two tetramers are present in the asymmetric unit. Each of the four ß subunits in the asymmetric unit binds one Fe(II) ion. The iron ion in each ß subunit is coordinated to three protein residues, His258, Glu264, and His305 and a water molecule. The crystal structures of the complexes with the substrate methylhydroquinone, obtained under anaerobic conditions, and with the inhibitors 4-hydroxybenzoate and 4-nitrophenol were also solved. The structures of the native enzyme and of the complexes present significant differences in the active site region compared to PnpCD, the other hydroquinone 1,2-dioxygenase of known structure, and in particular they show a different coordination at the metal center.

The different catalytic roles of the metal-binding ligands in human 4-hydroxyphenylpyruvate dioxygenase.

4-Hydroxyphenylpyruvate dioxygenase (HPPD) is a non-haem iron(II)-dependent oxygenase that catalyses the conversion of 4-hydroxyphenylpyruvate (HPP) to homogentisate (HG). In the active site, a strictly conserved 2-His-1-Glu facial triad co-ordinates the iron ready for catalysis. Substitution of these residues resulted in about a 10-fold decrease in the metal binding affinity, as measured by isothermal titration calorimetry, and a large reduction in enzyme catalytic efficiencies. The present study revealed the vital role of the ligand Glu(349) in enzyme function. Replacing this residue with alanine resulted in loss of activity. The E349G variant retained 5% activity for the coupled reaction, suggesting that co-ordinating water may be able to support activation of the trans-bound dioxygen upon substrate binding. The reaction catalysed by the H183A variant was fully uncoupled. H183A variant catalytic activity resulted in protein cleavage between Ile(267) and Ala(268) and the production of an N-terminal fragment. The H266A variant was able to produce 4-hydroxyphenylacetate (HPA), demonstrating that decarboxylation had occurred but that there was no subsequent product formation. Structural modelling of the variant enzyme with bound dioxygen revealed the rearrangement of the co-ordination environment and the dynamic behaviour of bound dioxygen in the H266A and H183A variants respectively. These models suggest that the residues regulate the geometry of the reactive oxygen intermediate during the oxidation reaction. The mutagenesis and structural simulation studies demonstrate the critical and unique role of each ligand in the function of HPPD, and which correlates with their respective co-ordination position.

Expression and purification of the natively disordered and redox sensitive metal binding regions of Mycobacterium tuberculosis protein kinase G.

Mycobacterium tuberculosis protein kinase G (PknG) is secreted into host macrophages to block lysosomal degradation. The catalytic domain (∼147-405) is C-terminally flanked by a tetratricopeptide repeat domain (TPRD). The preceding rubredoxin-like metal-binding motif (RD, ∼74-147) mediates PknG redox regulation. The N-terminal ∼75 residues were predicted to show no regulatory secondary structure (NORS) and harbor the only site (T63) phosphorylated in vivo. Deletions or mutations in the NORS or the redox-sensitive RD significantly decrease the survival function. Here, we show that the RD appears only to be present in the folded, metal-bound state if ZnCl2 is added upon induction of protein expression in minimal medium. Since factor Xa cleaves at the end of its recognition site (IEGR), a modified expression plasmid for PknG1-147 was obtained by mutating the N-terminal thrombin to a factor Xa recognition site. This allows preparing PknG1-147 with its native N-terminus. We further present a fast approach to generate expression plasmids for only the NORS or the RD by site-directed mutagenesis of the expression plasmid for His-tagged PknG1-147. An expression plasmid for PknG1-75 was obtained by introducing a stop codon at position 76 and one for PknG74-174 by introducing a factor Xa recognition site before position 74. SDS-PAGE analysis shows that all fragments are highly expressed in E. coli and can be purified to high purity. Thereby, the established preparation protocols pave the route for the NMR structural characterization of PknG regulation by its N-terminal regions, which is demonstrated by the recorded initial (1)H-(15)N-HSQC spectra.

Structure and function of atypically coordinated enzymatic mononuclear non-heme-Fe(II) centers.

Mononuclear, non-heme-Fe(II) centers are key structures in O2 metabolism and catalyze an impressive variety of enzymatic reactions. While most are bound via two histidines and a carboxylate, some show a different organization. A short overview of atypically coordinated O2 dependent mononuclear-non-heme-Fe(II) centers is presented here Enzymes with 2-His, 3-His, 3-His-carboxylate and 4-His bound Fe(II) centers are discussed with a focus on their reactivity, metal ion promiscuity and recent progress in the elucidation of their enzymatic mechanisms. Observations concerning these and classically coordinated Fe(II) centers are used to understand the impact of the metal binding motif on catalysis.

In silico design and construction of metal-binding hybrid proteins for specific removal of cadmium based on CS3 pili display on the surface of Escherichia coli.

In this study, through a combination of bioinformatics and genetic engineering procedures, high-affinity metal-binding peptides were designed and expressed on the surface of Escherichia coli for selective Cd(2+) adsorption. Putative cadmium-binding motifs were identified by searches against the Prosite database and permissive sites in the major subunit (CstH) of the enterotoxigenic E. coli pili were predicted based on the data derived from modeling of 3D structures, secondary structure prediction and assignment, inspection of protein hydropathy and exposed regions, and also protein interaction sites. The metal-binding motifs were inserted into one permissive site of the CstH (amino acid 38) with the aid of the SOEing PCR technique. The capacity and selectivity of the recombinant bacteria displaying hybrid pili to adsorb cadmium were evaluated with the atomic absorption procedure. The levels of Cd(2+) accumulation in the recombinant E. coli strains were 13.9- and 11.33-fold higher than those in the control strain. Cd(2+) was selectively absorbed from a solution containing equal concentrations of four metals, resulting in more than 90% of the total adsorbed metals being Cd(2+) , showing a relatively high affinity for Cd(2+) over other coexisting metal ions.

Crystal structure of a novel RNA motif that allows for precise positioning of a single metal ion.

We have determined a crystal structure of an RNA duplex containing a novel metal-binding motif. The motif is composed of two sheared G○A base pairs, two unpaired A residues and four phosphate groups in close proximity. Four A residues make an A-A-A-A stacking column at the minor groove side and two G bases are highly inclined, thereby forming the pocket-shaped motif at the major groove side. In the present structure, a hydrated Sr2+ ion exists in the pocket and binds to the O6 and N7 atoms of the two G bases and four phosphate groups. According to the previously-reported metal-binding properties to RNA molecules, many of divalent cations, such as Mg2+, Mn2+, Co2+, Zn2+, Ba2+, Pb2+ and Cd2+, may bind to the motif. This metal-binding motif can be used as a modular building block that allows for precise positioning of a single metal ion in functional nucleic acid molecules.

Chemical shift assignment of the intrinsically disordered N-terminus and the rubredoxin domain in the folded metal bound and unfolded oxidized state of mycobacterial protein kinase G.

Mycobacterium tuberculosis protein kinase G (PknG) is a 82 kDa multidomain eukaryotic-like serine/threonine kinase mediating the survival of pathogenic mycobacteria within host macrophages. The N-terminal sequence preceding the catalytic kinase domain contains an approximately 75 residues long tail, which was predicted to show no regulatory secondary structure (1-75 = NORS) but harbors the major in vivo phosphorylation site (T63), and a rubredoxin-like metal binding motif (74-147 = RD). In the reduced rubredoxin motif, four conserved cysteine residues that are present as two C-X-X-C-G motifs coordinate a metal ion. The cysteines are further involved in sensing the redox environment to regulate PknG catalytic activity. Here, we report the (1)H, (13)C, and (15)N resonance assignments of the highly dynamic unstructured N-terminal region NORS and the RD in the reduced, metal bound, presumably folded and the oxidized, presumably unfolded state. Chemical shifts have been deposited at the BioMagResBank under the BMRB accession numbers 26,028 for the His-PknG1-147 with the RD in reduced, metal bound state, 26,027 for His-PknG1-75, and 26,030 and 26,029 for PknG74-147 either in the reduced, metal bound or oxidized state, respectively. The presented chemical shift assignments pave the route for the structural characterization of the regulation of PknG by redox changes and posttranslational modifications (phosphorylation).