Structures of the Substrate-free and Product-bound Forms of HmuO,a Heme Oxygenase from Corynebacterium diphtheriae: X-RAY CRYSTALLOGRAPHY AND MOLECULAR DYNAMICS INVESTIGATION*?

Heme oxygenase catalyzes the degradation of heme to biliverdin, iron, and carbon monoxide. Here, we present crystal structures of the substrate-free, Fe³⁺-biliverdin-bound, and biliverdin-bound forms of HmuO, a heme oxygenase from Corynebacterium diphtheriae, refined to 1.80, 1.90, and 1.85 Å resolution, respectively. In the substrate-free structure, the proximal and distal helices, which tightly bracket the substrate heme in the substrate-bound heme complex, move apart, and the proximal helix is partially unwound. These features are supported by the molecular dynamic simulations. The structure implies that the heme binding fixes the enzyme active site structure, including the water hydrogen bond network critical for heme degradation. The biliverdin groups assume the helical conformation and are located in the heme pocket in the crystal structures of the Fe³⁺-biliverdin-bound and the biliverdin-bound HmuO, prepared by in situ heme oxygenase reaction from the heme complex crystals. The proximal His serves as the Fe³⁺-biliverdin axial ligand in the former complex and forms a hydrogen bond through a bridging water molecule with the biliverdin pyrrole nitrogen atoms in the latter complex. In both structures, salt bridges between one of the biliverdin propionate groups and the Arg and Lys residues further stabilize biliverdin at the HmuO heme pocket. Additionally, the crystal structure of a mixture of two intermediates between the Fe³⁺-biliverdin and biliverdin complexes has been determined at 1.70 Å resolution, implying a possible route for iron exit.     

Three‐dimensional structure of xylonolactonase from Caulobacter crescentus: A mononuclear iron enzyme of the 6‐bladed β‐propeller hydrolase family

Xylonolactonase Cc XylC from Caulobacter crescentus catalyzes the hydrolysis of the intramolecular ester bond of d‐xylonolactone. We have determined crystal structures of Cc XylC in complex with d‐xylonolactone isomer analogues d‐xylopyranose and (r)‐(+)‐4‐hydroxy‐2‐pyrrolidinone at high resolution. Cc XylC has a 6‐bladed β‐propeller architecture, which contains a central open channel having the active site at one end. According to our previous native mass spectrometry studies, Cc XylC is able to specifically bind Fe²⁺. The crystal structures, presented here, revealed an active site bound metal ion with an octahedral binding geometry. The side chains of three amino acid residues, Glu18, Asn146, and Asp196, which participate in binding of metal ion are located in the same plane. The solved complex structures allowed suggesting a reaction mechanism for intramolecular ester bond hydrolysis in which the major contribution for catalysis arises from the carbonyl oxygen coordination of the xylonolactone substrate to the Fe²⁺. The structure of Cc XylC was compared with eight other ester hydrolases of the β‐propeller hydrolase family. The previously published crystal structures of other β‐propeller hydrolases contain either Ca²⁺, Mg²⁺, or Zn²⁺ and show clear similarities in ligand and metal ion binding geometries to that of Cc XylC. It would be interesting to reinvestigate the metal binding specificity of these enzymes and clarify whether they are also able to use Fe²⁺ as a catalytic metal. This could further expand our understanding of utilization of Fe²⁺ not only in oxidative enzymes but also in hydrolases.     

Identification of the Third Na Site and the Sequence of Extracellular Binding Events in the Glutamate Transporter

The transport cycle in the glutamate transporter (GlT) is catalyzed by the cotransport of three Na⁺ ions. However, the positions of only two of these ions (Na1 and Na2 sites) along with the substrate have been captured in the crystal structures reported for both the outward-facing and the inward-facing states of Glt_ph. Characterizing the third ion binding site (Na3) is necessary for structure-function studies attempting to investigate the mechanism of transport in GlTs at an atomic level, particularly for the determination of the sequence of the binding events during the transport cycle. In this study, we report a series of molecular dynamics simulations performed on various bound states of Glt_ph (the apo state, as well as in the presence of Na⁺, the substrate, or both), which have been used to identify a putative Na3 site. The calculated trajectories have been used to determine the water accessibility of potential ion-binding residues in the protein, as a prerequisite for their ion binding. Combined with conformational analysis of the key regions in the protein in different bound states and several additional independent simulations in which a Na⁺ ion was randomly introduced to the interior of the transporter, we have been able to characterize a putative Na3 site and propose a plausible binding sequence for the substrate and the three Na⁺ ions to the transporter during the extracellular half of the transport cycle. The proposed Na3 site is formed by a set of highly conserved residues, namely, Asp³¹², Thr⁹², and Asn³¹⁰, along with a water molecule. Simulation of a fully bound state, including the substrate and the three Na⁺ ions, reveals a stable structure—showing closer agreement to the crystal structure when compared to previous models lacking an ion in the putative Na3 site. The proposed sequence of binding events is in agreement with recent experimental models suggesting that two Na⁺ ions bind before the substrate, and one after that. Our results, however, provide additional information about the sites involved in these binding events.     

Structural insights into the functional role of the Hcn sub-domain of the receptor-binding domain of the botulinum neurotoxin mosaic serotype C/D

Botulinum neurotoxin (BoNT), the causative agent of the deadly neuroparalytic disease botulism, is the most poisonous protein known for humans. Produced by different strains of the anaerobic bacterium Clostridium botulinum, BoNT effects cellular intoxication via a multistep mechanism executed by the three modules of the activated protein. Endocytosis, the first step of cellular intoxication, is triggered by the ∼50 kDa, heavy-chain receptor-binding domain (HCR) that is specific for a ganglioside and a protein receptor on neuronal cell surfaces. This dual receptor recognition mechanism between BoNT and the host cell's membrane is well documented and occurs via specific intermolecular interactions with the C-terminal sub-domain, Hcc, of BoNT–HCR. The N-terminal sub-domain of BoNT–HCR, Hcn, comprises ∼50% of BoNT–HCR and adopts a β-sheet jelly roll fold. While suspected in assisting cell surface recognition, no unambiguous function for the Hcn sub-domain in BoNT has been identified. To obtain insights into the potential function of the Hcn sub-domain in BoNT, the first crystal structure of a BoNT with an organic ligand bound to the Hcn sub-domain has been obtained. Here, we describe the crystal structure of BoNT/CD–HCR determined at 1.70 Å resolution with a tetraethylene glycol (PG4) moiety bound in a hydrophobic cleft between β-strands in the β-sheet jelly roll fold of the Hcn sub-domain. The PG4 moiety is completely engulfed in the cleft, making numerous hydrophilic (Y932, S959, W966, and D1042) and hydrophobic (S935, W977, L979, N1013, and I1066) contacts with the protein's side chain and backbone that may mimic in vivo interactions with the phospholipid membranes on neuronal cell surfaces. A sulfate ion was also observed bound to residues T1176, D1177, K1196, and R1243 in the Hcc sub-domain of BoNT/CD–HCR. In the crystal structure of a similar protein, BoNT/D–HCR, a sialic acid molecule was observed bound to the equivalent residues suggesting that residues T1176, D1177, K1196, and R1243 in BoNT/CD may play a role in ganglioside binding.     

Metal binding to the tetrathiolate motif of desulforedoxin and related polypeptides

 Desulforedoxin and the N-terminus of desulfoferrodoxin share a 36 amino acid domain containing a (Cys-S)₄ metal binding site. Recombinant forms of desulforedoxin, an N-terminal fragment of desulfoferrodoxin, and two desulforedoxin mutant proteins were reconstituted with Fe³⁺, Cd²⁺, and Zn²⁺ and relative metal ion affinities assessed by proton titrations. Protons compete with metal for protein ligands, a process that can be followed by monitoring the optical spectrum of the metal-protein complex as a function of pH. For all polypeptides, Fe³⁺ bound with the highest affinity, whereas the affinity of Zn²⁺ was greater than Cd²⁺ in desulforedoxin and the N-terminal fragment of desulfoferrodoxin, but this order was reversed in desulforedoxin mutant proteins. Metal binding in both mutants was significantly impaired. Furthermore, the Fe³⁺ complex of both mutants underwent a time-dependent bleaching process which coincided with increased reactivity of cysteine residues to Ellman's reagent and concomitant metal dissociation. It is hypothesized that this results from an autoredox reaction in which Fe³⁺ is reduced to Fe²⁺ with attendant oxidation of ligand thiols. Received: 17 June 1998 / Accepted: 3 September 1998     

Structure of erythrocruorin in different ligand states refined at 1.4 A resolution.

The crystal structure of erythrocruorin has been refined by constrained crystallographic refinement at 1·4 Å resolution in the following ligand states: aquomet (Fe³⁺, high spin), cyanomet (Fe³⁺, low spin), deoxy (Fe²⁺, high spin) and carbonmonoxy (Fe²⁺, low spin). The final R-value at this resolution is better than 0·19 for each of these models. The positional errors of the co-ordinates are less than 0·1 Å.The root-mean-square differences between the deoxygenated and the ligated erythrocruorin are about 0·1 Å, being largest for cyanomet-erythrocruorin. The changes in tertiary structures propagate from the location of primary events and often fade out at the molecular surface. Helix E passing the distal side of the haem group is affected most by the direct contact with the ligand bound to the haem iron.Steric hindrance by the distal residue IleE11 forces the cyanide and carbonmonoxide ligands to bind at an angle to the haem axis. The strain at the ligand is partially relieved by movement of the haem deeper into the haem pocket and rearrangement of neighbouring residues.The differences in iron location with respect to the mean haem plane are spin-dependent but unexpectedly small (the largest value is 0·15 Å between deoxy and carbonmonoxy-erythrocruorin). Spin state changes seem to have little influence on the porphyrin stereochemistry; it is determined primarily by the chemical properties of the ligand and its interaction with the haem and the globin. These non-covalent interactions are largely responsible for the initiation of the structural changes on ligand binding.     

Protein selectivity in immobilized metal affinity chromatography based on the surface accessibility of aspartic and glutamic acid residues

The interaction of different species variants of cytochrome c and myoglobin, as well as hen egg white lysozyme, with the hard Lewis metal ions Al³⁺, Ca²⁺, Fe³⁺, and Yb³⁺ and the borderline metal ion Cu²⁺, immobilized to iminodiacetic acid (IDA)-Sepharose CL-4B, has been investigated over the rangepH 5.5–8.0. With appropriately chosen buffer and metal ion conditions, these proteins can be bound to the immobilized M ⁿ +-IDA adsorbents via negatively charged amino acid residues accessible on the protein surface. For example, tuna heart cytochrome c, which lacks surface-accessible histidine residues, readily bound to the Fe³⁺-IDA adsorbent, while the other proteins also showed affinity toward immobilized Fe³⁺-IDA adsorbents when buffers containing 30 mM of imidazole were used. These studies document that protein selectivity can be achieved with hard-metalion immobilized metal ion affinity chromatography (IMAC) systems through the interaction of surfaceexposed aspartic and glutamic acid residues on the protein with the immobilized M ⁿ +-IDA complex. These investigations have also documented that the so-called soft or borderline immobilized metal ions such as the Cu²⁺-IDA adsorbent can also interact with surface-accessible aspartic and glutamic acid residues in a protein-dependent manner. A relationship is evident between the number and extent of clustering of the surfaceaccessible aspartic and glutamic acid residues and protein selectivity with these IMAC systems. The use of elution buffers which contain organic compound modifiers which replicate the carboxyl group moieties of these amino acids on the surface of proteins is also described.Abbreviations IDA iminodiacetic acid - IDA-Mⁿ⁺ iminodiacetic acid chelated to metal ion - IMAC immobilized metal affinity chromatography - DHCC dog heart cytochrome c - HHCC horse heart cytochrome c, THCC, tuna heart cytochrome c - HMYO horse skeletal muscle myoglobin - SMYO sheep skeletal muscle myoglobin - HEWL hen egg white lysozyme     

Rapid evolution of a bacterial iron acquisition system

Under iron limitation, bacteria scavenge ferric (Fe³⁺) iron bound to siderophores or other chelates from the environment to fulfill their nutritional requirement. In gram‐negative bacteria, the siderophore uptake system prototype consists of an outer membrane transporter, a periplasmic binding protein and a cytoplasmic membrane transporter, each specific for a single ferric siderophore or siderophore family. Here, we show that spontaneous single gain‐of‐function missense mutations in outer membrane transporter genes of Bradyrhizobium japonicum were sufficient to confer on cells the ability to use synthetic or natural iron siderophores, suggesting that selectivity is limited primarily to the outer membrane and can be readily modified. Moreover, growth on natural or synthetic chelators required the cytoplasmic membrane ferrous (Fe²⁺) iron transporter FeoB, suggesting that iron is both dissociated from the chelate and reduced to the ferrous form within the periplasm prior to cytoplasmic entry. The data suggest rapid adaptation to environmental iron by facile mutation of selective outer membrane transporter genes and by non‐selective uptake components that do not require mutation to accommodate new iron sources.     

Fe2+ binding on amyloid β‐peptide promotes aggregation

The metal ions Zn²⁺, Cu²⁺, and Fe²⁺ play a significant role in the aggregation mechanism of Aβ peptides. However, the nature of binding between metal and peptide has remained elusive; the detailed information on this from the experimental study is very difficult. Density functional theory (dft) (M06‐2X/6‐311++G (2df,2pd) +LANL2DZ) has employed to determine the force field resulting due to metal and histidine interaction. We performed 200 ns molecular dynamics (MD) simulation on Aβ_1‐42‐Zn²⁺, Aβ_1‐42‐Cu²⁺, and Aβ_1‐42‐Fe²⁺ systems in explicit water with different combination of coordinating residues including the three Histidine residues in the N‐terminal. The present investigation, the Aβ_1‐42‐Zn²⁺ system possess three turn conformations separated by coil structure. Zn²⁺ binding caused the loss of the helical structure of N‐terminal residues which transformed into the S‐shaped conformation. Zn²⁺ has reduced the coil and increases the turn content of the peptide compared with experimental study. On the other hand, the Cu²⁺ binds with peptide, β sheet formation is observed at the N‐terminal residues of the peptide. Fe²⁺ binding is to promote the formation of Glu22‐Lys28 salt‐bridge which stabilized the turn conformation in the Phe19‐Gly25 residues, subsequently β sheets were observed at His13‐Lys18 and Gly29‐Gly37 residues. The turn conformation facilitates the β sheets are arranged in parallel by enhancing the hydrophobic contact between Gly25 and Met35, Lys16 and Met35, Leu17 and Leu34, Val18 and Leu34 residues. The Fe²⁺ binding reduced the helix structure and increases the β sheet content in the peptide, which suggested, Fe²⁺ promotes the oligomerization by enhancing the peptide‐peptide interaction. Proteins 2016; 84:1257–1274. © 2016 Wiley Periodicals, Inc.     

Coupling of Calcium and Substrate Binding through Loop Alignment in the Outer-Membrane Transporter BtuB

In Gram-negative bacteria, TonB-dependent outer-membrane transporters bind large, scarce organometallic substrates with high affinity preceding active transport. The cobalamin transporter BtuB requires the additional binding of two Ca²⁺ ions before substrate binding can occur, but the underlying molecular mechanism is unknown. Using the crystallographic structures available for different bound states of BtuB, we have carried out extended molecular dynamics simulations of multiple functional states of BtuB to address the role of Ca²⁺ in substrate recruitment. We find that Ca²⁺ binding both stabilizes and repositions key extracellular loops of BtuB, optimizing interactions with the substrate. Interestingly, replacement by Mg²⁺ abolishes this effect, in accordance with experiments. Using a set of new force-field parameters developed for cyanocobalamin, we also simulated the substrate-bound form of BtuB, where we observed interactions not seen in the crystal structure between the substrate and loops previously found to be important for binding and transport. Based on our results, we suggest that the large size of cobalamin compared to other TonB-dependent transporter substrates explains the requirement of Ca²⁺ binding for high-affinity substrate recruitment in BtuB.     

Iron mobilization from ultraviolet-irradiated,iron-saturated,transferrin

SUMMARY

Transferrin is the major iron transport protein of mammalian plasma. The ultraviolet-B irradiation of 1.4 mg/ml iron saturated transferrin solutions (~32 μM Fe³⁺) induces a Fe³⁺ loss accompanied by Fe²⁺ formation. The initial quantum yield of Fe³⁺ loss is wavelength dependent (φ(313 nm)~1.3×10^?3) and oxygen independent suggesting an intramolecular electron transfer from one of the Fe³⁺ ligands. A photolysis of tryptophan residues parallels this photoreduction.     

Role of Nitrosomonas europaea NitABC iron transporter in the uptake of Fe3+-siderophore complexes

Nitrosomonas europaea has a single three-gene operon (nitABC) encoding an iron ABC transporter system (NitABC). Phylogenetic analysis clustered the subunit NitB with Fe³⁺-ABC transporter permease components from other organisms. The N. europaea strain deficient in nitB (nitB::kan) grew well in either Fe-replete or Fe-limited media and in Fe-limited medium containing the catecholate-type siderophore, enterobactin or the citrate-based dihydroxamate-type siderophore, aerobactin. However, the nitB::kan mutant strain was unable to grow in Fe-limited media containing either the hydroxamate-type siderophores, ferrioxamine and ferrichrome or the mixed-chelating type siderophore, pyoverdine. Exposure of N. europaea cells to a ferrichrome analog coupled to the fluorescent moiety naphthalic diimide (Fhu-NI) led to increase in fluorescence in the wild type but not in nitB::kan mutant cells. Spheroplasts prepared from N. europaea wild type exposed to Fhu-NI analog retained the fluorescence, while spheroplasts of the nitB::kan mutant were not fluorescent. NitABC transports intact Fe³⁺-ferrichrome complex into the cytoplasm and is an atypical ABC type iron transporter for Fe³⁺ bound to ferrioxamine, ferrichrome or pyoverdine siderophores into the cytoplasm. The mechanisms to transport iron in either the Fe³⁺ or Fe²⁺ forms or Fe³⁺ associated with enterobactin or aerobactin siderophores into the cell across the cytoplasmic membrane are as yet undetermined.     

Structure and electrostatic property of cytoplasmic domain of ZntB transporter

ZntB is the distant homolog of CorA Mg²⁺ transporter within the metal ion transporter superfamily. It was early reported that the ZntB from Salmonella typhimurium facilitated efflux of Zn²⁺ and Cd²⁺, but not Mg²⁺. Here, we report the 1.90 Å crystal structure of the intracellular domain of ZntB from Vibrio parahemolyticus. The domain forms a funnel-shaped homopentamer that is similar to the full-length CorA from Thermatoga maritima, but differs from two previously reported dimeric structures of truncated CorA intracellular domains. However, no Zn²⁺ or Cd²⁺ binding sites were identified in the high-resolution structure. Instead, 25 well-defined Cl⁻ ions were observed and some of these binding sites are highly conserved within the ZntB family. Continuum electrostatics calculations suggest that the central pore of the funnel is highly attractive for cations, especially divalents. The presence of the bound Cl⁻ ions increases the stability of cations along the pore suggesting they could be important in enhancing cation transport.     

Arginyl residues are involved in the transport of Fe2+ through the plasma membrane of the mammalian reticulocyte

Sealed reticulocyte ghosts were treated with reagents that modify a variety of amino acid residues. Only ninhydrin and phenylglyoxal, both modifiers of arginyl residues, produced inhibition of the initial rate of ⁵⁹Fe²⁺ uptake. The inhibition (i) was dependent on the concentration of ninhydrin or phenylglyoxal, (ii) increased from pH 7 to 9, a feature of the modification of arginine by ninhydrin or phenylglyoxal, and (iii) was blocked when Fe²⁺ was present during the modification step. A23187, an effective membrane Fe²⁺ transporter, diminished the inhibitory effect of ninhydrin and phenylglyoxal, indicative that the transport of iron through the membrane, and not a secondary process, was selectively inhibited. We conclude that the iron transporter from the plasma membrane of erythroid cells has one or more arginyl residues in a segment accessible to ninhydrin or phenylglyoxal, and that this residue is involved in the transmembrane transport of iron.This work was supported by grant 1080-91 from FONDECYT, Chile.     

Vanadyl(IV) conalbumin. II. Mixed metal and anion binding studies

Electron paramagnetic resonance (epr) studies demonstrate that at low levels of conalbumin (CA) saturation with Fe³⁺ or VO²⁺, a ph-dependent preference of the metal exists for different protein binding-site configurations,A, B, and C. The vanadyl ion epr spectra of mixed VO²⁺, Fe³⁺-conalbumin in which Fe³⁺ is preferentially bound to the N- or C-terminal binding site are consistent with all three configurations being formed at both metal sites. At high pH the spectra suggest interaction between binding sites. In the absence of HCO₃^?, VO²⁺ is bound almost exclusively in B configuration; a full binding capacity of 2 VO²⁺ per CA is retained. Stoichiometric amounts of HCO₃^? convert the epr spectrum from B to an A, B, C type. Addition of oxalate to bicarbonate-free preparations converts the B spectrum to an A′, B, C′ type where the B resonances have lost intensity to the A′ and C′ resonances but have not changed position. The data suggest that configuration B is anion independent and that only one equivalent of binding sites at pH 9 responds to the presence of HCO₃^1? or oxalate by changing configuration but not metal binding capability. The form of the bound anion may be HCO₃^? rather than CO₃^2?. The formation rate of the colored ferric conalbumin complex by oxidizing Fe²⁺ to Fe³⁺ in limited HCO₃^? at pH 9 is also consistent with one equivalent of sites having different anion requirements than the remaining sites. Increased NaCl or NaClO₄ concentration or substitution of D₂O for water as solvent affect the environment of bound VO²⁺, but the mechanisms of action are unknown.     

Structural and spectroscopic characterisation of a heme peroxidase from sorghum

A cationic class III peroxidase from Sorghum bicolor was purified to homogeneity. The enzyme contains a high-spin heme, as evidenced by UV–visible spectroscopy and EPR. Steady state oxidation of guaiacol was demonstrated and the enzyme was shown to have higher activity in the presence of calcium ions. A Fe^III/Fe^II reduction potential of ?266 mV vs NHE was determined. Stopped-flow experiments with H₂O₂ showed formation of a typical peroxidase Compound I species, which converts to Compound II in the presence of calcium. A crystal structure of the enzyme is reported, the first for a sorghum peroxidase. The structure reveals an active site that is analogous to those for other class I heme peroxidase, and a substrate binding site (assigned as arising from binding of indole-3-acetic acid) at the γ-heme edge. Metal binding sites are observed in the structure on the distal (assigned as a Na⁺ ion) and proximal (assigned as a Ca²⁺) sides of the heme, which is consistent with the Ca²⁺-dependence of the steady state and pre-steady state kinetics. It is probably the case that the structural integrity (and, thus, the catalytic activity) of the sorghum enzyme is dependent on metal ion incorporation at these positions.     

Ferritin protein nanocage ion channels: gating by N-terminal extensions

Ferritin protein nanocages, self-assembled from four-α-helix bundle subunits, use Fe²⁺ and oxygen to synthesize encapsulated, ferric oxide minerals. Ferritin minerals are iron concentrates stored for cell growth. Ferritins are also antioxidants, scavenging Fenton chemistry reactants. Channels for iron entry and exit consist of helical hairpin segments surrounding the 3-fold symmetry axes of the ferritin nanocages. We now report structural differences caused by amino acid substitutions in the Fe²⁺ ion entry and exit channels and at the cytoplasmic pores, from high resolution (1.3–1.8 Å) protein crystal structures of the eukaryotic model ferritin, frog M. Mutations that eliminate conserved ionic or hydrophobic interactions between Arg-72 and Asp-122 and between Leu-110 and Leu-134 increase flexibility in the ion channels, cytoplasmic pores, and/or the N-terminal extensions of the helix bundles. Decreased ion binding in the channels and changes in ordered water are also observed. Protein structural changes coincide with increased Fe²⁺ exit from dissolved, ferric minerals inside ferritin protein cages; Fe²⁺ exit from ferritin cages depends on a complex, surface-limited process to reduce and dissolve the ferric mineral. High concentrations of bovine serum albumin or lysozyme (protein crowders) to mimic the cytoplasm restored Fe²⁺ exit in the variants to wild type. The data suggest that fluctuations in pore structure control gating. The newly identified role of the ferritin subunit N-terminal extensions in gating Fe²⁺ exit from the cytoplasmic pores strengthens the structural and functional analogies between ferritin ion channels in the water-soluble protein assembly and membrane protein ion channels gated by cytoplasmic N-terminal peptides.     

Selective and sensitive fluorescent turn‐off chemosensors for Fe3+

Two novel chemosensors (2a and 2b) were synthesized by facile condensation of the binding unit (l ‐histidine) and the fluorophores (anthracene and dansyl groups). Both of them displayed high selectivity and sensitivity towards Fe³⁺ over other metal ions in aqueous solution. The sensing mechanism was based on the paramagnetic property of Fe³⁺ that would lead to fluorescence quenching of the fluorophores when Fe³⁺ was bound to the recognition units. The results showed that l ‐histidine was a good coordination motif for Fe³⁺ and both the anthracene and dansyl groups can sensitively report the sensing information. Copyright © 2012 John Wiley & Sons, Ltd.     

Structure and metal binding properties of ZnuA, a periplasmic zinc transporter from Escherichia coli

ZnuA is the periplasmic Zn²⁺-binding protein associated with the high-affinity ATP-binding cassette ZnuABC transporter from Escherichia coli. Although several structures of ZnuA and its homologs have been determined, details regarding metal ion stoichiometry, affinity, and specificity as well as the mechanism of metal uptake and transfer remain unclear. The crystal structures of E. coli ZnuA (Eco-ZnuA) in the apo, Zn²⁺-bound, and Co²⁺-bound forms have been determined. ZnZnuA binds at least two metal ions. The first, observed previously in other structures, is coordinated tetrahedrally by Glu59, His60, His143, and His207. Replacement of Zn²⁺ with Co²⁺ results in almost identical coordination geometry at this site. The second metal binding site involves His224 and several yet to be identified residues from the His-rich loop that is unique to Zn²⁺ periplasmic metal binding receptors. Electron paramagnetic resonance and X-ray absorption spectroscopic data on CoZnuA provide additional insight into possible residues involved in this second site. The second site is also detected by metal analysis and circular dichroism (CD) titrations. Eco-ZnuA binds Zn²⁺ (estimated K _d < 20 nM), Co²⁺, Ni²⁺, Cu²⁺, Cu⁺, and Cd²⁺, but not Mn²⁺. Finally, conformational changes upon metal binding observed in the crystal structures together with fluorescence and CD data indicate that only Zn²⁺ substantially stabilizes ZnuA and might facilitate recognition of ZnuB and subsequent metal transfer. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.