The de novo design of a rubredoxin-like Fe site.

A redox center similar to that of rubredoxin was designed into the 56 amino acid immunoglobulin binding B1 domain of Streptococcals protein G. The redox center in rubredoxin contains an iron ion tetrahedrally coordinated by four cysteine residues, [Fe(S-Cys)4](-1),(-2). The design criteria for the target site included taking backbone movements into account, tetrahedral metal-binding, and maintaining the structure and stability of the wild-type protein. The optical absorption spectrum of the Co(II) complex of the metal-binding variant is characteristic of tetrahedral chelation by four cysteine residues. Circular dichroism and nuclear magnetic resonance measurements reveal that the metal-free and Cd(II)-bound forms of the variant are folded correctly and are stable. The Fe(III) complex of the metal-binding mutant reproduces the optical and the electron paramagnetic resonance spectra of oxidized rubredoxin. This demonstrates that the engineered protein chelates Fe(III) in a tetrahedral array, and the resulting center is similar to that of oxidized rubredoxin.     

Zn(2+) binding properties of single-point mutants of the C-terminal zinc finger of the HIV-1 nucleocapsid protein: evidence of a critical role of cysteine 49 in Zn(2+) dissociation

The two highly conserved Zn(2+) finger motifs of the HIV-1 nucleocapsid protein, NCp7, strongly bind Zn(2+) through coordination of one His and three Cys residues. To further analyze the role of these residues, we investigated the Zn(2+) binding and acid-base properties of four single-point mutants of a short peptide corresponding to the distal finger motif of NCp7. In each mutant, one Zn(2+)-coordinating residue is substituted with a noncoordinating one. Using the spectroscopic properties of Co(2+), we first establish that the four mutants retain their ability to bind a metal cation through a four- or five-coordinate geometry with the vacant ligand position(s) presumably occupied by water molecule(s). Moreover, the pK(a) values of the three Cys residues of the mutant apopeptide where His44 is substituted with Ala are found by (1)H NMR to be similar to those of the native peptide, suggesting that the mutations do not affect the acid-base properties of the Zn(2+)-coordinating residues. The binding of Zn(2+) was monitored by using the fluorescence of Trp37 as an intrinsic probe. At pH 7.5, the apparent Zn(2+) binding constants (between 1.6 x 10(8) and 1.3 x 10(10) M(-)(1)) of the four mutants are strongly reduced compared to those of the native peptide but are similar to those of various host Zn(2+) binding proteins. As a consequence, the loss of viral infectivity following the mutation of one Zn(2+)-coordinating residue in vivo may not be related to the total loss of Zn(2+) binding. The pH dependence of Zn(2+) binding indicates that the coordinating residues bind Zn(2+) stepwise and that the free energy provided by the binding of a given residue may be modulated by the entropic contribution of the residues already bound to Zn(2+). Finally, the pK(a) of Cys49 in the holopeptide is found to be 5.0, a value that is at least 0.7 unit higher than those for the other Zn(2+)-coordinating residues. This implies that Cys49 may act as a switch for Zn(2+) dissociation in the distal finger motif of NCp7, a feature that may contribute to the high susceptibility of Cys49 to electrophilic attack.     

Metal-binding characteristics of the amino-terminal domain of ZntA: binding of lead is different compared to cadmium and zinc

ZntA from Escherichia coli, a P1-type ATPase, specifically transports Pb(II), Zn(II), and Cd(II). Most P1-type ATPases have an N-terminal domain that contains one or more copies of the conserved metal-binding motif, GXXCXXC. In ZntA, the N-terminal domain has approximately 120 residues with a single GXXCXXC motif, as well as four additional cysteine residues as part of the CCCDGAC motif. The metal-binding specificity and affinity of this domain in ZntA was investigated. Isolated proteins, N1-ZntA and N2-ZntA, containing residues 1-111 and 47-111 of ZntA, respectively, were characterized. N1-ZntA has both the CCCDGAC and GXXCXXC motifs, while N2-ZntA has only the GXXCXXC motif. ICP-MS measurements showed that N1-ZntA can bind both divalent metal ions such as Cd(II), Pb(II), and Zn(II) and monovalent metal ions such as Ag(I), with a stoichiometry of 1. N2-ZntA can bind Zn(II) and Cd(II) with a stoichiometry of 1 but not Pb(II). The affinity of N1-ZntA for Zn(II), Pb(II), and Cd(II) was measured by competition titration with metallochromic indicators. Association constants of approximately 10(8) M(-)(1) were obtained for Zn(II), Pb(II), and Cd(II) binding to N1-ZntA. To investigate whether the CCCDGAC sequence has an important role in binding specifically Pb(II), a mutant of ZntA, which lacked the first 46 residues, was constructed. This mutant, Delta46-ZntA, had the same activity as wtZntA with respect to Cd(II) and Zn(II). However, its activity with Pb(II) was similar to the mutant DeltaN-ZntA, which lacks the entire N-terminal domain (Mitra, B., and Sharma, R. (2001) Biochemistry 40, 7694-7699). Thus, binding of Pb(II) appears to involve different ligands, and possibly geometry, compared to Cd(II) and Zn(II).     

1H, 13C, and 15N chemical shifts assignments for human endothelial monocyte-activating polypeptide EMAP II

Endothelial and monocyte-activating polypeptide II (EMAP II) is a cytokine that plays an important role in inflammation, apoptosis and angiogenesis processes in tumour tissues. Structurally, the EMAP II is a 169 amino acid residues long C-terminal domain (residues 147–312) of auxiliary tRNA binding protein p43. In spite of existence in pdb databank of two X-ray structures there are some important aspects of EMAP II cytokine function which are still not fully understood in detail. To obtain information about 3D structure and backbone dynamic processes in solution we perform structure evaluation of human EMAP II cytokine by NMR spectroscopy. The standard approach to sequence-specific backbone assignment using 3D NMR data sets was not successful in our studies and was supplemented by recently developed 4D NMR experiments with random sampling of evolution time space. Here we report the backbone and side chain ¹H, ¹³C, and ¹⁵N chemical shifts in solution for recombinant EMAP II cytokine together with secondary structure provided by TALOS + software.     

The Metalloregulatory Zinc Site in Streptococcus pneumoniae AdcR, a Zinc-activated MarR Family Repressor

Streptococcus pneumoniae D39 AdcR (adhesin competence repressor) is the first metal-sensing member of the MarR (multiple antibiotic resistance repressor) family to be characterized. Expression profiling with a ΔadcR strain grown in liquid culture (brain-heart infusion) under microaerobic conditions revealed upregulation of 13 genes, including adcR and adcCBA, encoding a high-affinity ABC uptake system for zinc, and genes encoding cell-surface zinc-binding pneumococcal histidine triad (Pht) proteins and AdcAII (Lmb, laminin binding). The ΔadcR, H108Q and H112Q adcR mutant allelic strains grown in 0.2 mM Zn(II) exhibit a slow-growth phenotype and an approximately twofold increase in cell-associated Zn(II). Apo- and Zn(II)-bound AdcR are homodimers in solution and binding to a 28-mer DNA containing an adc operator is strongly stimulated by Zn(II) with K_DNA-Zn = 2.4 × 10⁸ M^- 1 (pH 6.0, 0.2 M NaCl, 25 °C). AdcR binds two Zn(II) per dimer, with stepwise Zn(II) affinities K_Zn1 and K_Zn2 of ≥ 10⁹ M^- 1 at pH 6.0 and ≥ 10¹² M^- 1 at pH 8.0, and one to three lower affinity Zn(II) depending on the pH. X-ray absorption spectroscopy of the high-affinity site reveals a pentacoordinate N/O complex and no cysteine coordination, the latter finding corroborated by wild type-like functional properties of C30A AdcR. Alanine substitution of conserved residues His42 in the DNA-binding domain, and His108 and His112 in the C-terminal regulatory domain, abolish high-affinity Zn(II) binding and greatly reduce Zn(II)-activated binding to DNA. NMR studies reveal that these mutants adopt the same folded conformation as dimeric wild type apo-AdcR, but fail to conformationally switch upon Zn(II) binding. These studies implicate His42, His108 and H112 as metalloregulatory zinc ligands in S. pneumoniae AdcR.     

Solution structure of a type I dockerin domain, a novel prokaryotic, extracellular calcium-binding domain

The type I dockerin domain is responsible for incorporating its associated glycosyl hydrolase into the bacterial cellulosome, a multienzyme cellulolytic complex, via its interaction with a receptor domain (cohesin domain) of the cellulosomal scaffolding subunit. The highly conserved dockerin domain is characterized by two Ca(2+)-binding sites with sequence similarity to the EF-hand motif. Here, we present the three-dimensional solution structure of the 69 residue dockerin domain of Clostridium thermocellum cellobiohydrolase CelS. Torsion angle dynamics calculations utilizing a total of 728 NOE-derived distance constraints and 79 torsion angle restraints yielded an ensemble of 20 structures with an average backbone r.m.s.d. for residues 5 to 29 and 32 to 66 of 0.54 A from the mean structure. The structure consists of two Ca(2+)-binding loop-helix motifs connected by a linker; the E helices entering each loop of the classical EF-hand motif are absent from the dockerin domain. Each dockerin Ca(2+)-binding subdomain is stabilized by a cluster of buried hydrophobic side-chains. Structural comparisons reveal that, in its non-complexed state, the dockerin fold displays a dramatic departure from that of Ca(2+)-bound EF-hand domains. A putative cohesin-binding surface, comprised of conserved hydrophobic and basic residues, is proposed, providing new insight into cellulosome assembly.     

Treponema pallidum TroA is a periplasmic zinc-binding protein with a helical backbone.

The crystal structure of recombinant TroA, a zinc-binding protein component of an ATP-binding cassette transport system in Treponema pallidum, was determined at a resolution of 1.8 A. The organization of the protein is largely similar to other periplasmic ligand-binding proteins (PLBP), in that two independent globular domains interact with each other to create a zinc-binding cleft between them. The structure has one bound zinc pentavalently coordinated to residues from both domains. Unlike previous PLBP structures that have an interdomain hinge composed of beta-strands, the N- and C-domains of TroA are linked by a single long backbone helix. This unique backbone helical conformation was possibly adopted to limit the hinge motion associated with ligand exchange.     

Metal binding Asp-120 in metallo-beta-lactamase L1 from Stenotrophomonas maltophilia plays a crucial role in catalysis

Metallo-beta-lactamase L1 from Stenotrophomonas maltophilia is a dinuclear Zn(II) enzyme that contains a metal-binding aspartic acid in a position to potentially play an important role in catalysis. The presence of this metal-binding aspartic acid appears to be common to most dinuclear, metal-containing, hydrolytic enzymes; particularly those with a beta-lactamase fold. In an effort to probe the catalytic and metal-binding role of Asp-120 in L1, three site-directed mutants (D120C, D120N, and D120S) were prepared and characterized using metal analyses, circular dichroism spectroscopy, and presteady-state and steady-state kinetics. The D120C, D120N, and D120S mutants were shown to bind 1.6 +/- 0.2, 1.8 +/- 0.2, and 1.1 +/- 0.2 mol of Zn(II) per monomer, respectively. The mutants exhibited 10- to 1000-fold drops in kcat values as compared with wild-type L1, and a general trend of activity, wild-type > D120N > D120C and D120S, was observed for all substrates tested. Solvent isotope and pH dependence studies indicate one or more protons in flight, with pKa values outside the range of pH 5-10 (except D120N), during a rate-limiting step for all the enzymes. These data demonstrate that Asp-120 is crucial for L1 to bind its full complement of Zn(II) and subsequently for proper substrate binding to the enzyme. This work also confirms that Asp-120 plays a significant role in catalysis, presumably via hydrogen bonding with water, assisting in formation of the bridging hydroxide/water, and a rate-limiting proton transfer in the hydrolysis reaction.     

Direct insight into insulin aggregation by 2D NMR complemented by PFGSE NMR

The aggregation of Zn(II)-bound and zinc-free human insulin was studied in solution using the H(beta)-CH(3) crosspeaks of threonine residues in 2D COSY, TOCSY, and NOESY NMR spectra which allow viewing of the oligomers in equilibrium. This is complemented by PFGSE measurements of the translational diffusion coefficient, D(i), used for monitoring the changes in equilibrium composition of aggregates on dilution of both insulins in physiological medium. The back calculation of the dilution isotherm allows establishing the association constants for oligomeric equilibria in solution and discussion of the models of association.     

The cysteine-rich amino-terminal domain of ZntA, a Pb(II)/Zn(II)/Cd(II)-translocating ATPase from Escherichia coli, is not essential for its function.

Soft metal-translocating P1-type ATPases have a distinctive amino-terminal domain that contains one to six copies of the conserved metal-binding motif, GXXCXXC. ZntA from Escherichia coli, a Pb(II)-, Zn(II)-, and Cd(II)-transporting ATPase, has an approximately 120 residue amino-terminal domain with one copy of the GXXCXXC motif as well as four additional cysteine residues. The function of this domain was investigated by constructing a mutant of ZntA lacking the first approximately 100 residues. The mutant, DeltaN-ZntA, was able to confer resistance to Pb(II), Zn(II), and Cd(II) salts, in a manner similar to ZntA. The soft metal dependent ATP hydrolysis activity of purified DeltaN-ZntA was characterized. Purified DeltaN-ZntA and ZntA were both inactivated by oxidation. The K(m) for MgATP was unchanged for DeltaN-ZntA relative to ZntA. DeltaN-ZntA displayed the same metal ion specificity as ZntA. Thiolates increased the activities of both ZntA and DeltaN-ZntA. The V(max) values for DeltaN-ZntA were approximately 3-fold lower than for ZntA for all three metal ions. Thus, the amino-terminal domain is not essential for the function of ZntA or for conferring specificity toward particular soft metals. Its function may be to increase the overall catalytic rate by increasing the rate of metal ion binding to the transporter. Residues involved in the ATP-dependent soft metal ion-translocating mechanism as well as those responsible for recognition of specific metal ions must be part of the core structure of the P1-type ATPases.     

Metal binding activity of the Escherichia coli hydrogenase maturation factor HypB

The formation of the [NiFe] metallocenter of Escherichia coli hydrogenase 3 requires the participation of proteins encoded by the hydrogenase pleiotropy operon hypABCDEF. The insertion of Ni(II) into the precursor enzyme follows the incorporation of the iron center and is the function of HypA, a Zn(II)-binding protein, and HypB, a GTPase. The Ni(II) donor and the mechanism of transfer of Ni(II) into the hydrogenase precursor protein are not known. In this study, we demonstrate that HypB is a nickel-binding protein capable of binding 1 equiv of Ni(II) with a K(d) in the sub-picomolar range. In addition, HypB has a weaker metal-binding site that is not specific for Ni(II) over Zn(II). Examination of the isolated C-terminal GTPase domain revealed that the high-affinity metal binding capability was severely abrogated but the low-affinity site was intact. By mutating conserved cysteine and histidine residues in E. coli HypB, we have localized the high-affinity Ni(II)-binding site to an N-terminal CXXCGC motif and the low-affinity metal-binding site to the GTPase domain. A model for the function of HypB during the Ni(II) loading of hydrogenase is proposed.     

Structural probing of a microdomain in the dopamine transporter by engineering of artificial Zn2+ binding sites

Previously, we have identified three Zn(2+) binding residues in an endogenous Zn(2+) binding site in the human dopamine transporter (hDAT): (193)His in extracellular loop 2 (ECL 2), (375)His at the external end of transmembrane segment (TM) 7, and (396)Glu at the external end of TM 8. Here we have generated a series of artificial Zn(2+) binding sites in a domain situated around the external ends of TMs 7 and 8 by taking advantage of the well-defined structural constraints for binding of the zinc(II) ion. Initially, we found that the Zn(2+)-coordinating (193)His in ECL 2 could be substituted with a histidine inserted at the i - 4 position relative to (375)His in TM 7. In this mutant (H193K/M371H), Zn(2+) potently inhibited [(3)H]dopamine uptake with an IC(50) value of 7 microM as compared to a value of 300 microM for the control (H193K). These data are consistent with the presence of an alpha-helical configuration of TM 7. This inference was further corroborated by the observation that no increase in the apparent Zn(2+) affinity was observed following introduction of histidines at the i - 2, i - 3, and i - 5 positions. In contrast, introduction of histidines at positions i + 2, i + 3, and i + 4 all resulted in potent inhibition of [(3)H]dopamine uptake by Zn(2+) (IC(50) = 3-32 microM). These observations are inconsistent with continuation of the helix beyond position 375 and indicate an approximate boundary between the end of the helix and the succeeding loop. In summary, the data presented here provide new insight into the structure of a functionally important domain in the hDAT and illustrate how engineering of Zn(2+) binding sites can be a useful approach for probing both secondary and tertiary structure relationships in membrane proteins of unknown structure.     

Effects of metal ligation and oxygen on the reversibility of the thermal denaturation of Pseudomonas aeruginosa azurin.

Thermodynamic equilibrium transition models in DSC are only applicable to reversible processes, but reversibility of the thermal transitions of proteins is comparatively rare because of intermolecular aggregation of denatured proteins and the degradation that occurs at high temperatures. The cupredoxin azurin from Pseudomonas aeruginosa has previously been found to exhibit irreversible thermal denaturation, both as holo- and apoprotein [Engeseth, H. R., and McMillin, D. R. (1986) Biochemistry 25, 2448-2455]. In this study, however, we demonstrate that this beta-barrel protein of Greek key topology in fact unfolds reversibly in anaerobic solutions when nonreducible metal ions are ligated to the protein. We show that it is the metal-coordinating cysteine residue (C112) that becomes exclusively oxidized in a transition metal catalyzed oxidation reaction with dissolved O(2) at high temperatures. Both Cu(I)- and Zn(II)-coordinating wild-type azurin therefore unfold reversibly in anaerobic solutions, as well as the Zn(II)-coordinating disulfide-deficient C3A/C26A mutant. Correspondingly, apoazurin mutants C112A and C112S unfold reversibly, even in aerobic solutions, and exhibit nearly perfect two-state transitions. Unfolding of Cu(II)-coordinating azurin is, on the other hand, always irreversible due to autoxidation of the thiolate resulting in Cu(I) and a thiyl radical prone to oxidation.     

Metal selectivity of the Escherichia coli nickel metallochaperone, SlyD

SlyD is a Ni(II)-binding protein that contributes to nickel homeostasis in Escherichia coli. The C-terminal domain of SlyD contains a rich variety of metal-binding amino acids, suggesting broader metal binding capabilities, and previous work demonstrated that the protein can coordinate several types of first-row transition metals. However, the binding of SlyD to metals other than Ni(II) has not been previously characterized. To improve our understanding of the in vitro metal-binding activity of SlyD and how it correlates with the in vivo function of this protein, the interactions between SlyD and the series of biologically relevant transition metals [Mn(II), Fe(II), Co(II), Cu(I), and Zn(II)] were examined by using a combination of optical spectroscopy and mass spectrometry. Binding of SlyD to Mn(II) or Fe(II) ions was not detected, but the protein coordinates multiple ions of Co(II), Zn(II), and Cu(I) with appreciable affinity (K(D) values in or below the nanomolar range), highlighting the promiscuous nature of this protein. The order of affinities of SlyD for the metals examined is as follows: Mn(II) and Fe(II) < Co(II) < Ni(II) ~ Zn(II) ? Cu(I). Although the purified protein is unable to overcome the large thermodynamic preference for Cu(I) and exclude Zn(II) chelation in the presence of Ni(II), in vivo studies reveal a Ni(II)-specific function for the protein. Furthermore, these latter experiments support a specific role for SlyD as a [NiFe]-hydrogenase enzyme maturation factor. The implications of the divergence between the metal selectivity of SlyD in vitro and the specific activity in vivo are discussed.     

Characterization of the redox and metal binding activity of BsSco, a protein implicated in the assembly of cytochrome c oxidase

Members of the Sco protein family are implicated in the assembly of the respiratory complex cytochrome c oxidase. Several possible roles have been proposed for Sco: a copper delivery agent, a site-specific thiol reductase, and an indicator of cellular redox status. Two cysteine residues (C45 and C49) in the sequence CXXXCP and a histidine (H135) approximately 90 residues toward the C-terminus are conserved in Sco from bacteria, yeast, and humans. The soluble domain of Sco has a thioredoxin fold that is suggestive of redox activity for this protein. We have characterized the soluble domain of the Sco protein from Bacillus subtilis (i.e., sBsSco) for its redox reactivity and metal binding capacity. In oxidized sBsSco, the cysteines are present as an intramolecular disulfide. Oxidized sBsSco does not bind metal, but can be reduced in vitro to a metal-binding form. Reduction of the disulfide in sBsSco is accompanied by increased intrinsic fluorescence. The reducibility of the cystine is unchanged when the conserved histidine is mutated to alanine. Tight binding by reduced sBsSco is observed for Cu(II) by electronic absorption, intrinsic fluorescence, and EPR spectroscopies, and isothermal titration calorimetry with an observed stoichiometry of one Cu(II) ion per sBsSco and a KD of approximately 50 nM. Tight binding of Cu(I) and Ag(I) is observed by quenching of intrinsic tryptophan fluorescence. Cobalt(II) exhibits weak binding, whereas Ni(II) and Zn(II) do not appear to bind. The high-affinity binding of metals by BsSco is triggered by its redox state, and this property could be important for its function in vivo.     

Effects of metal on the biochemical properties of Helicobacter pylori HypB, a maturation factor of [NiFe]-hydrogenase and urease

The biosyntheses of the [NiFe]-hydrogenase and urease enzymes in Helicobacter pylori require several accessory proteins for proper construction of the nickel-containing metallocenters. The hydrogenase accessory proteins HypA and HypB, a GTPase, have been implicated in the nickel delivery steps of both enzymes. In this study, the metal-binding properties of H. pylori HypB were characterized, and the effects of metal binding on the biochemical behavior of the protein were examined. The protein can bind stoichiometric amounts of Zn(II) or Ni(II), each with nanomolar affinity. Mutation of Cys106 and His107, which are located between two major GTPase motifs, results in undetectable Ni(II) binding, and the Zn(II) affinity is weakened by 2 orders of magnitude. These two residues are also required for the metal-dependent dimerization observed in the presence of Ni(II) but not Zn(II). The addition of metals to the protein has distinct impacts on GTPase activity, with zinc significantly reducing GTP hydrolysis to below detectable levels and nickel only slightly altering the k(cat) and K(m) of the reaction. The regulation of HypB activities by metal binding may contribute to the maturation of the nickel-containing enzymes.