p10 single-stranded nucleic acid binding protein from murine leukemia virus binds metal ions via the peptide sequence Cys26-X2-Cys29-X4-His34-X4-Cys39

The RNA binding protein of 56 residues encoded by the extreme 3' region of the gag gene of Rauscher murine leukemia virus (MuLV) has been chemically synthesized by a solid-phase synthesis approach. Since the peptide contains a Cys26-X2-Cys29-X4-His34-X2-Cys39 sequence that is shared by all retroviral gag polyproteins which has been proposed to be a metal binding region, it was of considerable interest to examine the metal binding properties of the complete p10 protein. As postulated, p10 binds the metal ions Cd(II), Co(II), and Zn(II). The Co(II) protein shows a set of d-d absorption bands typical of a tetrahedral Co(II) complex at 695 (epsilon = 565 M-1 cm-1), 642 (epsilon = 655 M-1 cm-1), and 615 nm (epsilon = 510 M-1 cm-1) and two intense bands at 349 (epsilon = 2460 M-1 cm-1) and 314 nm (epsilon = 4240 M-1 cm-1) typical of Co(II)----(-)S- charge transfer. The ultraviolet absorption spectrum also indicates Cd(II) binding by the appearance of a Cd(II)----(-)S- charge-transfer band at 255 nm. The 113Cd NMR spectrum of 113Cd(II)-p10 reveals one signal at delta = 648 ppm. This chemical shift correlates well with that predicted for ligation of 113Cd(II) to three -S- from the three Cys residues of p10. The chemical shift of 113Cd(II)-p10 changes by only 4 ppm upon binding of d(pA)6, indicating that the chelate complex is little changed by oligonucleotide binding.(ABSTRACT TRUNCATED AT 250 WORDS)     

Manganese (II) electron spin resonance and cadmium-113 nuclear magnetic resonance evidence for the nature of the calcium binding site in alpha-lactalbumins

Bovine and goat alpha-lactalbumins were substituted with 113Cd(II) or Mn(II) at the strong calcium site [Murakami, K., Andree, P.J., & Berliner, L.J. (1982) Biochemistry 21, 5488-5494] and studied by 113 Cd NMR and electron spin resonance. The 113Cd chemical shifts were in the -80 to -85 ppm range vs. Cd(ClO4)2, which was almost identical with that found for several nearly octahedral (oxygen-coordinated) calcium binding proteins such as calmodulin, parvalbumin, and troponin C. The electron spin resonance spectra of bound Mn(II)-alpha-lactalbumin complexes at 9 or 35 GHz were also confirmatory of a highly symmetric (cubic) environment around the Mn(II) with only slight distortions. The near identity of this site in alpha-lactalbumin to those of calcium binding proteins containing an "EF hand domain" was remarkable despite the absence of such a domain sequence in the alpha-lactalbumin structure.     

Effect of the two conserved prolines of human growth inhibitory factor (metallothionein-3) on its biological activity and structure fluctuation: comparison with a mutant protein

Human neuronal growth inhibitory factor, a metalloprotein classified as metallothionein-3 (MT-3), impairs the survival and the neurite formation of cultured neurons. In these studies the double P7S/P9A mutant (mutMT-3) and single mutants P7S and P9A of human Zn(7)-MT-3 were generated, and their effects on the biological activity and the structure of the protein were examined. The biological results clearly established the necessity of both proline residues for the inhibitory activity, as even single mutants were found to be inactive. Using electronic absorption, circular dichroism (CD), magnetic CD (MCD), and (113)Cd NMR spectroscopy, the structural features of the metal-thiolate clusters in the double mutant Cd(7)-mutMT-3 were investigated and compared with those of wild-type Cd(7)-MT-3 [Faller, P., Hasler, D. W., Zerbe, O., Klauser, S., Winge, D. R., and Vasák, M. (1999) Biochemistry 38, 10158] and the well characterized Cd(7)-MT-2a from rabbit liver. Similarly to (113)Cd(7)-MT-3 the (113)Cd NMR spectrum of (113)Cd(7)-mutMT-3 at 298 K revealed four major and three minor resonances (approximately 20% of the major ones) between 590 and 680 ppm, originating from a Cd(4)S(11) cluster in the alpha-domain and a Cd(3)S(9) cluster in the beta-domain, respectively. Due to the presence of dynamic processes in the structure of MT-3 and mutMT-3, all resonances showed the absence of resolved homonuclear [(113)Cd-(113)Cd] couplings and large apparent line widths (between 140 and 350 Hz). However, whereas in (113)Cd(7)-mutMT-3 the temperature rise to 323 K resulted in a major recovery of the originally NMR nondetectable population of the Cd(3)S(9) cluster resonances, no such temperature effect was observed in (113)Cd(7)-MT-3. To account for the observed NMR features, a dynamic structural model for the beta-domain is proposed, which involves a folded and a partially unfolded state. It is suggested that in the partially unfolded state a slow cis/trans isomerization of Cys-Pro(7) or Cys-Pro(9) amide bonds in (113)Cd(7)-MT-3 takes place and that this process represents a rate-limiting step in a correct domain refolding. In addition, closely similar apparent stability constants of human MT-3, mutMT-3, and rabbit MT-2a with Cd(II) and Zn(II) ions were found. These results suggest that specific structural features dictated by the repetitive (Cys-Pro)(2) sequence in the beta-domain of MT-3 and not its altered metal binding affinity compared to MT-1/MT-2 isoforms are responsible for the biological activity of this protein.     

Physicochemical properties of cloned nucleocapsid protein from HIV. Interactions with metal ions

The nucleocapsid (NC) protein (p15) of the human immunodeficiency virus (HIV) has been cloned and overproduced (under the control of a phage T7 promoter) in soluble form in an Escherichia coli host. The soluble NC protein is a fusion protein containing 15 amino acids from the T7 gene 10 and 7 amino acids from the HIV p24 protein at the N-terminus to make a protein of 171 amino acids. The plasmid containing the fusion gene is designated p15DF. A homogeneous product has been isolated from the induced cells and, when isolated under aerobic conditions, contains 0.3-0.5 mol of Zn/mol of protein and has only 2 titratable SH groups. Reduction and refolding in the presence of Zn(II) yields a protein containing 2.0 mol of Zn/mol of protein and 6 titratable SH groups. On the other hand, if the cells are sonicated in 2 mM CdCl2 and purified at pH 5.0, an unoxidized protein containing 2 mol of Cd/mol of protein is obtained. The Cd(II) ions can be exchanged with Zn(II), Co(II), or 113Cd(II). The Co(II)2 NC protein shows d-d electronic transitions at 695 nm [epsilon = 675 M-1 cm-1 per Co(II)] and 640 nm [epsilon = 825 M-1 cm-1 per Co(II)] compatible with regular tetrahedral geometry around both Co(II) ions. The Co(II)2 and Cd(II)2 NC proteins show intense charge-transfer bands in the near-UV, at 355 nm (epsilon = approximately 4000 M-1 cm-1) and 310 nm (epsilon = approximately 8000 M-1 cm-1) for the Co(II) protein and 255 nm (epsilon = approximately 10(4) M-1 cm-1) for the Cd(II)2 NC protein, compatible with -S- coordination. 113Cd NMR of the 113Cd(II)2 NC protein shows two 113Cd NMR signals at 659 and 640 ppm, respectively, each integrating to approximately 1 Cd(II) ion. The downfield chemical shifts suggest coordination of each 113Cd(II) ion to 3 sulfur donor atoms. The spectroscopic data fully support the prediction that the NC protein binds metal ions to each of the tandem repeats of the -Cys-X2-Cys-X4-His-X4-Cys- sequence contained in the N-terminal half of the molecule. 113Cd NMR shows, however, that the sites are not identical. Isolation of the NC protein under standard aerobic conditions results in oxidation of the sulfhydryl groups and loss of the coordinated Zn(II) ions, while preparation of the NC protein as the Cd(II) derivative at low pH protects the sulfhydryl groups from oxidation.     

NMR spectroscopy of 113Cd(II)-substituted gene 32 protein

Gene 32 protein (g32P), the single-stranded DNA binding protein from bacteriophage T4, contains 1 mol of Zn(II)/mol of protein. This intrinsic zinc is retained within the DNA-binding core fragment, g32P-(A+B) (residues 22-253), obtained by limited proteolysis of the intact protein. Ultraviolet circular dichroism provides evidence that Zn(II) binding causes significant changes in the conformation of the peptide chain coupled with alterations in the microenvironments of tryptophan and tyrosine side chains. NMR spectroscopy of the 113Cd(II) derivative of g32P-(A+B) at both 44.4 and 110.9 MHz shows a single 113Cd resonance, delta 637, a chemical shift consistent with coordination to three of the four sulfhydryl groups in the protein. In vitro mutagenesis of Cys166 to Ser166 creates a mutant g32P that still contains 1 Zn(II)/molecule. This mutant protein when substituted with 113Cd(II) shows a 113Cd signal with a delta and a line width the same as those observed for the wild-type protein. Thus, the S-ligands to the metal ion appear to be contributed by Cys77, Cys87, and Cys90. Relaxation data suggest that chemical shift anisotropy is the dominant, but not exclusive, mechanism of relaxation of the 113Cd nucleus in g32P, since a dipolar modulation from ligand protons is observed at 44.4 MHz but not at 110.9 MHz. Complexation of core 113Cd g32P with d(pA)6 or Co(II) g32P with poly(dT) shows only minor perturbation of the NMR signal or d-d electronic transitions, respectively, suggesting that the metal ion in g32P does not add a ligand from the bound DNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

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).     

113Cd-NMR investigation of a cadmium-substituted copper, zinc-containing superoxide dismutase from yeast

113Cd nuclear magnetic resonance spectroscopy has been used to investigate the metal binding sites of cadmium-substituted copper, zinc-containing superoxide dismutase from baker's yeast. NMR signals were obtained for 113Cd(II) at the Cu site as well as for 113Cd(II) at the Zn site. The two subunits in the dimeric enzyme were found to have identical coordination properties towards 113Cd(II) at the Zn site when no copper is coordinated at the Cu site, and when Cu(I) or Cd(II) is coordinated, were found to be very small indicating that 113Cd(II) must be bound to the same number and type of ligands in both cases. Furthermore, the spectra show that the rate of exchange of protein-bound 113Cd(II) and free 113Cd2+ is slow on the NMR time scale also at the Cu site. The present study suggests an explanation for the discrepancy in the literature regarding 113Cd-NMR investigations of bovine superoxide dismutase.     

1H NMR studies of T4 gene 32 protein: effects of zinc removal and reconstitution

Gene 32 protein (g32P), the single-stranded DNA binding protein from bacteriophage T4, contains 1 mol of Zn(II)/mol bound in a tetrahedral ligand field. 113Cd NMR studies of Cd-substituted wild-type and mutant (Cys166----Ser166) g32Ps show Cys77, Cys87, and Cys90 to provide three sulfur donor atoms as ligands to the metal ion [Giedroc, D. P., Johnson, B. A., Armitage, I. M., & Coleman, J. E. (1989) Biochemistry 28, 2410]. Proton NMR signals from the His and Trp side chains of the protein have been followed as a function of pH and metal ion removal by biosynthesizing the protein with amino acids carrying protons at specific positions in a background of perdeuteriated aromatic amino acids. Only one of the two pairs of His resonances (from His64 and His81) titrates over the pH range 8.0-5.9. The nontitrating His side chain is most likely ligated to the metal ion. Upon Zn(II) removal, 1H NMR spectra of the fully protonated g32P-(A + B) exhibit substantial signal broadening in several regions of the spectrum, while the His 2,4-1H resonances are broadened beyond detection. The 1H NMR spectral characteristics of the original protein are restored by reconstitution with stoichiometric Zn(II). The broadening of the 1H NMR signals is not due to oligomerization of the protein, since small-angle X-ray scattering experiments show that the average radius of gyration of the apo-g32P-(A + B) is 25.0 A and that of the reconstituted Zn(II)-g32P-(A + B) is 31.2 A.(ABSTRACT TRUNCATED AT 250 WORDS)     

1H NMR studies of DNA recognition by the glucocorticoid receptor: complex of the DNA binding domain with a half-site response element.

The complex of the rat glucocorticoid receptor (GR) DNA binding domain (DBD) and half-site sequence of the consensus glucocorticoid response element (GRE) has been studied by two-dimensional 1H NMR spectroscopy. The DNA fragment is a 10 base-pair oligonucleotide, 5'd(GCTGTTCTGC)3'.5'd-(GCAGAACAGC)3', containing the stronger binding GRE half-site hexamer, with GC base pairs at each end. The 93-residue GR-DBD contains an 86-residue segment corresponding to residues 440-525 of the rat GR. Eleven NOE cross peaks between the protein and DNA have been identified, and changes in the chemical shift of the DNA protons upon complex formation have been analyzed. Using these protein-DNA contact points, it can be concluded that (i) the "recognition helix" formed by residues C460-E469 lies in the major groove of the DNA; (ii) the GR-DBD is oriented on the GRE half-site such that residues A477-D481, forming the so-called D-loop, are available for protein-protein interaction in the GR-DBD dimer on the intact consensus GRE; and (iii) the 5-methyl of the second thymine in the half-site and valine 462 interact, confirming indirect evidence [Truss et al. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 7180-7184; Mader et al. (1989) Nature 338, 271-274] that both play an important role in GR-DBD DNA binding. These findings are consistent with the model proposed by H?rd et al. [(1990) Science 249, 157-160] and the X-ray crystallographic complex structure determined by Luisi et al. [(1991) Nature 352, 497-505].     

1H NMR (500 MHz) identification of aromatic residues of gene 32 protein involved in DNA binding by use of protein containing perdeuterated aromatic residues and by site-directed mutagenesis

Preparation of gene 32 protein containing perdeuterated tyrosyl and phenylalanyl residues has allowed the resolution of separate 1H NMR signals for the Tyr and Phe residues of the protein by NMR difference spectra. Upfield shifts in the chemical shifts of a number of aromatic protons previously observed to accompany deoxyoligonucleotide complex formation with gene 32 protein [Prigodich, R. V., Casas-Finet, J., Williams, K. R., Konigsberg, W., & Coleman, J. E. (1984) Biochemistry 23, 522-529] can be assigned to five Tyr and two Phe residues that must form part of the DNA binding domain. Site-directed mutation of Tyr-115 to Ser-115 results in the disappearance of a set of 2,6 and 3,5 tyrosyl protons that are among those moved upfield by oligonucleotide complex formation. These findings suggest that the amino acid sequence from Tyr-73 to Tyr-115 which contains six of the eight Tyr residues of the protein forms part of the DNA binding surface.     

Zn(II) coordination domain mutants of T4 gene 32 protein.

Gene 32 protein (g32P), the replication accessory single-stranded nucleic acid binding protein from bacteriophage T4, contains 1 mol of Zn(II)/mol of protein. Zinc coordination provides structural stability to the DNA-binding core domain of the molecule, termed g32P-(A+B) (residues 22-253). Optical absorption studies with the Co(II)-substituted protein and 113Cd NMR spectroscopy of 113Cd(II)-substituted g32P-(A+B) show that the metal coordination sphere in g32P is characterized by approximately tetrahedral ligand symmetry and ligation by the Cys-S- atoms of Cys77, Cys87, and Cys90. These studies predicted the involvement of a fourth protein-derived non-thiol ligand to complete the tetrahedral complex, postulated to be His81 on the basis of primary structure prediction and modeling [Giedroc, D.P., Johnson, B.A., Armitage, I.M., & Coleman, J.E. (1989) Biochemistry 28, 2410-2418]. To test this model, we have employed site-directed mutagenesis to substitute each of the two histidine residues in g32P (His64 and His81), accompanied by purification and structural characterization of these single-site mutant proteins. We show that g32P's containing any of three substitutions at residue 64 (H64Q, H64N, and H64L) are isolated from Escherichia coli in a Zn(II)-free form [less than or equal to 0.03 g.atom Zn(II)]. All derivatives show extremely weak affinity for the ssDNA homopolymer poly(dT). All are characterized by a far-UV-CD spectrum reduced in negative intensity relative to the wild-type protein. These structural features parallel those found for the known metal ligand mutant Cys87----Ser87 (C87S) g32P. In contrast, g32P-(A+B) containing a substitution of His81 with glutamine (H81Q), alanine (H81A) or cysteine (H81C), contains stoichiometric Zn(II) as isolated and binds to polynucleotides with an affinity comparable to the wild-type g32P-(A+B). Spin-echo 1H NMR spectra recorded for wild-type and H81Q g32P-(A+B) as a function of pH allow the assignment of His81 ring proteins to delta = 6.81 and 6.57 ppm, respectively, at pH 7.8, corresponding to the C and D histidyl protons of 1H-His-g32P-(A+B) [Pan, T., Giedroc, D.P., & Coleman, J.E. (1989) Biochemistry 28, 8828-8832]. These resonances shift downfield as the pH is reduced from 7.8 to 6.6 without metal dissociation, a result incompatible with His81 donating a ligand to the Zn(II) in wild-type g32P. Likewise, Cys81 in Zn(II) H81C g32P is readily reactive with 5,5'-dithiobis(2-nitrobenzoic acid), unlike metal ligands Cys77, Cys87, and Cys90.(ABSTRACT TRUNCATED AT 400 WORDS)     

113Cd NMR studies on metal-thiolate cluster formation in rabbit Cd(II)-metallothionein: evidence for a pH dependence

The formation of two metal-thiolate clusters in rabbit liver metallothionein 2 (MT) has been examined by 113Cd NMR spectroscopy at pH 7.2 and 8.6. The chemical shifts of the 113Cd resonances developing in the course of apoMT titration with 113Cd(II) ions have been compared with those of fully metal occupied 113Cd7-MT. At pH 7.2 and at low metal occupancy (less than 4), a cooperative formation of the four-metal cluster (cluster A) occurs. Further addition of 113Cd(II) ions generates all the resonances of the three-metal cluster (cluster B) in succession, suggesting cooperative metal binding to this cluster also. In contrast, similar studies at pH 8.6, at low metal occupancy (less than 4), reveal a broad NMR signal centered at 688 ppm. This observation indicates that an entirely different protein structure exists. When exactly 4 equiv of 113Cd(II) are bound to apoMT, the 113Cd NMR spectrum changes to the characteristic spectrum of cluster A. Further addition of 113Cd(II) ions again leads to the cooperative formation of cluster B. These results stress the determining role of the cluster A domain on the overall protein fold. The observed pH dependence of the cluster formation in MT can be rationalized by the different degree of deprotonation of the cysteine residues (pKa approximately 8.9), i.e., by the difference in the Gibbs free energy required to bind Cd(II) ions to the thiolate ligands at both pH values.     

Zinc finger motif for single-stranded nucleic acids? investigations by nuclear magnetic resonance

Nuclear magnetic resonance (NMR) methods have been used to address issues regarding the relevance and feasibility of zinc binding to "zinc finger-like" sequences of the type C-X2-C-X4-H-X4-C [referred to as CCHC or retroviral-type (RT) zinc finger sequences]. One-dimensional (1D) NMR experiments with an 18-residue synthetic peptide containing the amino acid sequence of an HIV-1 RT-zinc finger domain (HIV1-F1) indicate that the sequences are capable of binding zinc tightly and stoichiometrically. 1H-113Cd spin echo difference NMR data confirm that the Cys and His amino acids are coordinated to metal in the 113Cd adduct. The 3D structure of the zinc adduct [Zn(HIV1-F1)] was determined to high atomic resolution by a new NMR-based approach that utilizes 2D-NOESY back-calculations as a measure of the consistency between the structures and the experimental data. Several interesting structural features were observed, including (1) the presence of extensive internal hydrogen bonding, and (2) the similarity of the folding of the first six residues to the folding observed by X-ray crystallography for related residues in the iron domain of rubredoxin. Structural constraints associated with conservatively substituted glycines provide further rationale for the physiological relevance of the zinc adduct. Similar NMR and structural results have been obtained for the second HIV-1 RT-zinc finger peptide, Zn(HIV1-F2). NMR studies of the zinc adduct with the NCP isolated directly from HIV-1 particles provide solid evidence that zinc finger domains are formed that are conformationally similar (if not identical) to the peptide structures.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding of cadmium(II) and zinc(II) to human and dog serum albumins. An equilibrium dialysis and 113Cd-NMR study.

The binding of Cd(II) and Zn(II) to human serum albumin (HSA) and dog serum albumin (DSA) has been studied by equilibrium dialysis and 113Cd(II)-NMR techniques at physiological pH. Scatchard analysis of the equilibrium dialysis data indicate the presence of at least two classes of binding sites for Cd(II) and Zn(II). On analysis of the high-affinity class of sites, HSA is shown to bind 2.08 +/- 0.09 (log K = 5.3 +/- 0.6) and 1.07 +/- 0.12 (log K = 6.4 +/- 0.8) moles of Cd(II) and Zn(II) per mole of protein, respectively. DSA bound 2.02 +/- 0.19 (log K = 5.1 +/- 0.8), and 1.06 +/- 0.15 (log K = 6.0 +/- 0.2) moles of Cd(II) and Zn(II) per mole of protein, respectively. Competition studies indicate the presence of one high-affinity Cd(II) site on both HSA and DSA that is not affected by Zn(II) or Cu(II), and one high-affinity Zn(II) site on both HSA and DSA that is not affected by Cd(II) or Cu(II). 113Cadmium-HSA spectra display three resonances corresponding to three different sites of complexation. In site I, Cd(II) is most probably coordinated to two or three histidyl residues, site II to one histidyl residue and three oxygen ligands (carboxylate), while for the most upfield site III, four oxygens are likely to be involved in the binding of the metal ion. The 113Cd(II)-DSA spectra display only two resonances corresponding to two different sites of complexation. The environment around Cd(II) at sites I and II on DSA is similar to sites I and II, respectively, on HSA. No additional resonances are observed in any of these experiments and in particular in the low field region where sulfur coordination occurs. Overall, our results are consistent with the proposal that the physiologically important high-affinity Zn(II) and Cd(II) binding sites of albumins are located not at the Cu(II)-specific NH2-terminal site, but at internal sites, involving mostly nitrogen and oxygen ligands and no sulphur ligand.