Structural features of the Cu(2+)-vancomycin complex

The structure of vancomycin coordinated to Cu(2+) ions is presented and structural aspects upon metal coordination are discussed. The asymmetric part of unit cell comprises two independent molecules of vancomycin-Cu(2+) complex, one of them is partially disordered. The binding site involves one imino nitrogen atom, two amide nitrogen atoms delivered by peptide bonds, and carboxyl oxygen from the peptide moiety. The identical set of donor atoms is not reflected in identical coordination geometry around individual metal ions. The studied complex presents two distinct types of conformation. Additionally, leucinyl side chain in one conformer is disordered leading to another type of conformation. The complex molecules form heterodimer with antiparallel hydrogen bonding.     

Macromolecularization of a tripeptide analogue of the Cu(II) binding site of human serum albumin: 2. Conformational and binding properties towards Cu(II) and Ni(II)ions of Gly-Gly-His derivatives of poly(l-lysine)

The conformational and binding properties towards Cu(II) and Ni(II) ions of Gly-Gly-His derivatives of poly(l-lysine) have been investigated mainly using circular dichroism (c.d.) spectroscopy. These derivatized polymers can be considered macromolecular analogues of the Cu(II) and Ni(II) binding site of human serum albumin. It has been shown that modification up to 53% of the ε-amino groups of lysine side chains by covalent binding of the tripeptide unit Gly-Gly-His does not induce appreciable alteration of the α-helix forming tendency of the polylysine backbone. The derivatized polymers exhibit strong affinity towards Cu(II) and Ni(II) ions. At neutral pH, complexes are formed in which each tripeptide chelating unit is linked to one metal ion. The spectral characteristics in the visible absorption region are consistent with a square planar geometry of the complexes, with deprotonated peptide groups and one imidazole nitrogen in the coordination sphere of the ion. C.d. measurements in the far u.v. indicate that complex formation in the side chains causes an increase of ordered structure of the peptide backbone at neutral pH. This fact is interpreted in terms of a reduced electrostatic repulsion among side chains due to charge neutralization in the tripeptide units linked to metal ions.     

Model studies on the coordination of copper in biological systems. The deprotonated peptide nitrogen as a potential binding site for copper(II)

1. A large number of potentially bidentate and tridentate amides, X-Y-CONH-Z, were used as model ligands to investigate the complex formation of Cu(II) with the deprotonated peptide nitrogen in biological molecules. A combination of potentiometric titration, spectrophotometry and electron paramagnetic resonance was applied to analyse the structure of the Cu(II) chelates formed at neurtal and basic pH. 2. By systematic variation of the primary binding function X, the ring size of the chelate, and the spatial properties of the C-terminal and N-terminal substituents, three classes of amide ligands could be established with reference to their capacity for Cu(II)-induced deprotonation of NHCO and metal binding. 3. Under physiological conditions of pH, peptide (class A) chelates are only formed by those bidentate amide ligands with X being an imidazole (sp2) nitrogen or a terminal (sp3) amino nitrogen. Mercaptide sulfur must also be considered to belong in this group of strong copper(II)-binding sites, but in our low-molecular-weight model ligands the redox equilibrium 2 Cu(II) + 2 RSH in equilibrium or formed from 2 CU(II) + RSSR + 2 H+ interferes, yielding insoluble Cu(I)-S polymers above pH 4. In addition to the unidentate binding strength of X, entropy effects play an important role. Depending on whether X is an imidazole or amino nitrogen, only five-membered or six-membered monocyclic chelate structures respectively cause coordination of the deprotonated peptide function. 4. Biuret (class B) Cu(II) chelates are only formed under non-physiological conditions at pH > 11.5 producing the well known violet chromophores CuIIN4(-). In general these complexes, which also include the Cu(II) biguanides, show a clearly resolved electron paramagnetic resonance spectrum with nitrogen superhyperfine structure. 5. A third class of peptide model ligands (class C) consists of those amides where the CuII-X bond does not provide enough thermodynamic stability. The binding site of these class C amides includes functional groups such as carboxylate (COO-), methionine sulfur (RSR'), aliphatic or aromatic hydroxyl (OH) and amide nitrogen (NHCO) itself. When X is a pyridine (sp2) nitrogen or an amino (sp3) nitrogen, NHCO deprotonation is only promoted in five-membered but not six-membered ring chelates. On the other hand, a combination of COO- and NH2, as in asparagine, will allow deprotonation of NHCO in the presence of Cu(II). And third, despite a pronounced unidentate affinity of the imidazole nitrogen for Cu(II), N-acetylhistamine acts as a class C amine, in contrast to imidazolylacetamide, which forms a stable Cu(II) peptide chelate. This difference in Cu binding is explained on the basis of space-filling models. These clearly demonstrate that in the case of the 2:1 complex of Cu(II) with N-acetylhistamine, the planarity of the ionised peptide function can not be retained in a square planar arrangement of the two amide ligands around the copper center.     

Structure and stability of the CuII complexes with tandem repeats of the chicken prion

Prion protein (PrP) misfolding is one of the pivotal issues in understanding the rudiments of neurodegenerative disorders. The conformational change of mammalian cellular PrP to scrapie PrP is caused by an unknown agent, but there is reasonable evidence supporting the key role of copper ions in this process. The structure of the avian PrP was found to be very similar to the mammalian protein, although there is only 30% homology in the secondary structure. This work shows that copper ions are very effectively bound by hexarepeat fragments of chicken prion protein, although not as effectively as it was found in the case of mammalian protein. By means of potentiometric and spectroscopic techniques (nuclear magnetic resonance, circular dichroism, UV-vis, and electronic paramagnetic resonance), it was shown that Cu(II) ions coordinate to the chicken PrP hexapeptide domain in physiological pH via imidazole nitrogen donors of His residue(s). The binding pattern changes the structure of peptide involved, indicating a possible impact of Cu(II) ions in the biology and pathology of nonmammalian PrP, which could be similar to that found for mammalian PrP. The present study shows that, similar to the human prion octapeptide repeats, chicken prion hexapeptide repeats might bind copper ions in two different ways, depending on the number of repeats and metal/ligand molar ratio: (i) an intra-repeat coordination mode in which copper ion is chelated by His imidazole and deprotonated amide nitrogen in monomeric peptide and (ii) an inter-repeat coordination mode in which a polymeric peptide ligand (dimer and trimer) forms polyimidazole complexes that are very stable at physiological pH. Two proline residues inserted into the hexapeptide unit have a critical impact on the metal-binding ability.     

A circular dichroic study of Cu(II) binding to bovine alpha-lactalbumin.

The visible and ultraviolet circular dichroic spectra resulting from the interaction of bovine alpha-lactalbumin with successive Cu(II) ions have been recorded under a variety of conditions. Analysis of the observed change-transfer and d-d band transitions can be made in terms of two kinds of binding sites: at a histidyl group and at the N-terminal amino group, respectively. At basic pH the amide nitrogens of the peptide backbone progressively take part in the coordination. The occupation of the high affinity calcium binding site by Ca(II) and Mn(II) does not influence the Cu(II) binding process, suggesting that there is no direct interaction between this site and the Cu(II) binding sites.     

On the possible roles of N-terminal His-rich domains of Cu,Zn SODs of some Gram-negative bacteria

The Cu,Zn superoxide dismutases (Cu,Zn SOD) isolated from some Gram-negative bacteria possess a His-rich N-terminal metal binding extension. The N-terminal domain of Haemophilus ducreyi Cu,Zn SOD has been previously proposed to play a copper(II)-, and may be a zinc(II)-chaperoning role under metal ion starvation, and to behave as a temporary (low activity) superoxide dismutating center if copper(II) is available. The N-terminal extension of Cu,Zn SOD from Actinobacillus pleuropneumoniae starts with an analogous sequence (HxDHxH), but contains considerably fewer metal binding sites. In order to study the possibility of the generalization of the above mentioned functions over all Gram-negative bacteria possessing His-rich N-terminal extension, here we report thermodynamic and solution structural analysis of the copper(II) and zinc(II) complexes of a peptide corresponding to the first eight amino acids (HADHDHKK-NH₂, L) of the enzyme isolated from A. pleuropneumoniae. In equimolar solutions of Cu(II)/Zn(II) and the peptide the MH₂L complexes are dominant in the neutral pH-range. L has extraordinary copper(II) sequestering capacity (K_D,Cu = 7.4 × 10^− 13 M at pH 7.4), which is provided only by non-amide (side chain) donors. The central ion in CuH₂L is coordinated by four nitrogens {NH₂,3N_im} in the equatorial plane. In ZnH₂L the peptide binds to zinc(II) through a {NH₂,2N_im,COO⁻} donor set, and its zinc binding affinity is relatively modest (K_D,Zn = 4.8 × 10^− 7 M at pH 7.4). Consequently, the presented data do support a general chaperoning role of the N-terminal His-rich region of Gram-negative bacteria in copper(II) uptake, but do not confirm similar function for zinc(II). Interestingly, the complex CuH₂L has very high SOD-like activity, which may further support the multifunctional role of the copper(II)-bound N-terminal His-rich domain of Cu,Zn SODs of Gram-negative bacteria. The proposed structure for the MH₂L complexes has been verified by semiempirical quantum chemical calculations (PM6), too.     

Transition metal complexes of terminally protected peptides containing histidyl residues

Histidine-containing peptide fragments of prion protein are efficient ligands to bind various transition metal ions and they have high selectivity in metal binding. The metal ion affinity follows the order: Pd(II)>Cu(II)>Ni(II)Zn(II)>Cd(II) approximately Co(II)>Mn(II). The high selectivity of metal binding is connected to the involvement of both imidazole and amide nitrogen atoms in metal binding for Pd(II), Cu(II) and Ni(II), while only the monodentate N(im)-coordination is possible with the other metal ions. The stoichiometry and binding mode of palladium(II) complexes show great variety depending on the metal ion to ligand ratio, pH and especially the presence of coordinating donor atoms in the side chains of peptide fragments. It is also clear from our data that the peptide fragments containing histidine outside the octarepeat (His96, His111 and His187) are more efficient ligands than the monomer peptide fragments of the octarepeat domain.     

Copper binding to octarepeat peptides of the prion protein monitored by mass spectrometry

Electrospray ionization mass spectrometry (ESI-MS) was used to measure the binding of Cu2+ ions to synthetic peptides corresponding to sections of the sequence of the mature prion protein (PrP). ESI-MS demonstrates that Cu2+ is unique among divalent metal ions in binding to PrP and defines the location of the major Cu2+ binding site as the octarepeat region in the N-terminal domain, containing multiple copies of the repeat ProHisGlyGlyGlyTrpGlyGln. The stoichiometries of the complexes measured directly by ESI-MS are pH dependent: a peptide containing four octarepeats chelates two Cu2+ ions at pH 6 but four at pH 7.4. At the higher pH, the binding of multiple Cu2+ ions occurs with a high degree of cooperativity for peptides C-terminally extended to incorporate a fifth histidine. Dissociation constants for each Cu2+ ion binding to the octarepeat peptides, reported here for the first time, are mostly in the low micromolar range; for the addition of the third and fourth Cu2+ ions to the extended peptides at pH 7.4, K(D)'s are <100 nM. N-terminal acetylation of the peptides caused some reduction in the stoichiometry of binding at both pH's. Cu2+ also binds to a peptide corresponding to the extreme N-terminus of PrP that precedes the octarepeats, arguing that this region of the sequence may also make a contribution to the Cu2+ complexation. Although the structure of the four-octarepeat peptide is not affected by pH changes in the absence of Cu2+, as judged by circular dichroism, Cu2+ binding induces a modest change at pH 6 and a major structural perturbation at pH 7.4. It is possible that PrP functions as a Cu2+ transporter by binding Cu2+ ions from the extracellular medium under physiologic conditions and then releasing some or all of this metal upon exposure to acidic pH in endosomes or secondary lysosomes.     

The effect of environment on the recognition and binding of vancomycin to native and resistant forms of lipid II

Molecular dynamics simulations and free energy calculations have been used to examine in detail the mechanism by which a receptor molecule (the glycopeptide antibiotic vancomycin) recognizes and binds to a target molecule (lipid II) embedded within a membrane environment. The simulations show that the direct interaction of vancomycin with lipid II, as opposed to initial binding to the membrane, leads most readily to the formation of a stable complex. The recognition of lipid II by vancomycin occurred via the N-terminal amine group of vancomycin and the C-terminal carboxyl group of lipid II. Despite lying at the membrane-water interface, the interaction of vancomycin with lipid II was found to be essentially identical to that of soluble tripeptide analogs of lipid II (Ac-d-Ala-d-Ala; root mean-square deviation 0.11 nm). Free energy calculations also suggest that the relative binding affinity of vancomycin for native, resistant, and synthetic forms of membrane-bound lipid II was unaffected by the membrane environment. The effect of the dimerization of vancomycin on the binding of lipid II, the position of lipid II within a biological membrane, and the effect of the isoamylene tail of lipid II on membrane fluidity have also been examined.     

Short peptides are not reliable models of thermodynamic and kinetic properties of the N-terminal metal binding site in serum albumin.

A comparative study of thermodynamic and kinetic aspects of Cu(II) and Ni(II) binding at the N-terminal binding site of human and bovine serum albumins (HSA and BSA, respectively) and short peptide analogues was performed using potentiometry and spectroscopic techniques. It was found that while qualitative aspects of interaction (spectra and structures of complexes, order of reactions) could be reproduced, the quantitative parameters (stability and rate constants) could not. The N-terminal site in HSA is much more similar to BSA than to short peptides reproducing the HSA sequence. A very strong influence of phosphate ions on the kinetics of Ni(II) interaction was found. This study demonstrates the limitations of short peptide modelling of Cu(II) and Ni(II) transport by albumins.     

pH-dependence of the specific binding of Cu(II) and Zn(II) ions to the amyloid-β peptide

Metal ions like Cu(II) and Zn(II) are accumulated in Alzheimer's disease amyloid plaques. The amyloid-β (Aβ) peptide involved in the disease interacts with these metal ions at neutral pH via ligands provided by the N-terminal histidines and the N-terminus. The present study uses high-resolution NMR spectroscopy to monitor the residue-specific interactions of Cu(II) and Zn(II) with (15)N- and (13)C,(15)N-labeled Aβ(1-40) peptides at varying pH levels. At pH 7.4 both ions bind to the specific ligands, competing with one another. At pH 5.5 Cu(II) retains its specific histidine ligands, while Zn(II) seems to lack residue-specific interactions. The low pH mimics acidosis which is linked to inflammatory processes in vivo. The results suggest that the cell toxic effects of redox active Cu(II) binding to Aβ may be reversed by the protective activity of non-redox active Zn(II) binding to the same major binding site under non-acidic conditions. Under acidic conditions, the protective effect of Zn(II) may be decreased or changed, since Zn(II) is less able to compete with Cu(II) for the specific binding site on the Aβ peptide under these conditions.     

Macromolecularization of a tripeptide analogue of the Cu(II) binding site of human serum albumin: 2. Conformational and binding properties towards Cu(II) and Ni(II)ions of Gly-Gly-His derivatives of poly(l-lysine)

The conformational and binding properties towards Cu(II) and Ni(II) ions of Gly-Gly-His derivatives of poly(l-lysine) have been investigated mainly using circular dichroism (c.d.) spectroscopy. These derivatized polymers can be considered macromolecular analogues of the Cu(II) and Ni(II) binding site of human serum albumin. It has been shown that modification up to 53% of the ε-amino groups of lysine side chains by covalent binding of the tripeptide unit Gly-Gly-His does not induce appreciable alteration of the α-helix forming tendency of the polylysine backbone. The derivatized polymers exhibit strong affinity towards Cu(II) and Ni(II) ions. At neutral pH, complexes are formed in which each tripeptide chelating unit is linked to one metal ion. The spectral characteristics in the visible absorption region are consistent with a square planar geometry of the complexes, with deprotonated peptide groups and one imidazole nitrogen in the coordination sphere of the ion. C.d. measurements in the far u.v. indicate that complex formation in the side chains causes an increase of ordered structure of the peptide backbone at neutral pH. This fact is interpreted in terms of a reduced electrostatic repulsion among side chains due to charge neutralization in the tripeptide units linked to metal ions.     

The Methylococcus capsulatus (Bath) Secreted Protein, MopE*, Binds Both Reduced and Oxidized Copper

Under copper limiting growth conditions the methanotrophic bacterium Methylococcus capsulatus (Bath) secrets essentially only one protein, MopE*, to the medium. MopE* is a copper-binding protein whose structure has been determined by X-ray crystallography. The structure of MopE* revealed a unique high affinity copper binding site consisting of two histidine imidazoles and one kynurenine, the latter an oxidation product of Trp130. In this study, we demonstrate that the copper ion coordinated by this strong binding site is in the Cu(I) state when MopE* is isolated from the growth medium of M. capsulatus. The conclusion is based on X-ray Near Edge Absorption spectroscopy (XANES), and Electron Paramagnetic Resonance (EPR) studies. EPR analyses demonstrated that MopE*, in addition to the strong copper-binding site, also binds Cu(II) at two weaker binding sites. Both Cu(II) binding sites have properties typical of non-blue type II Cu (II) centres, and the strongest of the two Cu(II) sites is characterised by a relative high hyperfine coupling of copper (A_|| = 20 mT). Immobilized metal affinity chromatography binding studies suggests that residues in the N-terminal part of MopE* are involved in forming binding site(s) for Cu(II) ions. Our results support the hypothesis that MopE plays an important role in copper uptake, possibly making use of both its high (Cu(I) and low Cu(II) affinity properties.     

Bacteriolytic effect of teicoplanin.

The glycopeptide antibiotic teicoplanin belongs to the same group as vancomycin and ristocetin and is a valuable tool for studying the autolytic system of sensitive Gram-positive bacteria. Teicoplanin, at a concentration of 1 microgram ml-1, caused rapid lysis of exponential phase cells of Streptococcus faecalis. Bacillus spp. were most sensitive to the antibiotic; effective lysis occurred at 0.1 microgram teicoplanin ml-1. The bacteriolytic effect depended on the antibiotic concentration, the growth phase and growth rate of the target organism. Antibiotic added to overnight cultures did not cause lysis. Mg2+ (50 mM) was unable to prevent lysis. Mutants with decreased autolytic activity were more resistant to teicoplanin and lysed more slowly than the wild-type. Growth of bacteria in slightly acidic medium protected the cells against the lytic effect of teicoplanin typically observed at pH 7 or 8. This pH-dependent antibiotic tolerance was demonstrated with both bacilli and streptococci. Bacterial lysis was prevented by the presence of Ac-L-Lys(Ac)-D-Ala-D-Ala and normal growth was observed when this peptide was added simultaneously with teicoplanin. Bacteria pretreated with teicoplanin, washed and transferred to fresh medium or buffers behaved as if the antibiotic was still present; in neutral or slightly alkaline conditions strong lysis occurred, whereas in acidic buffer only bacteriostasis was observed. In contrast to vancomycin, teicoplanin induced some lysis of bacteria in hypertonic media, presumably by affecting the integrity of the cell membrane.     

Copper–zinc cross-modulation in prion protein binding

In this paper we report a systematic XAS study of a set of samples in which Cu(II) was progressively added to complexes in which Zn(II) was bound to the tetra-octarepeat portion of the prion protein. This work extends previous EPR and XAS analysis in which, in contrast, the effect of adding Zn(II) to Cu(II)–tetra-octarepeat complexes was investigated. Detailed structural analysis of the XAS spectra taken at both the Cu and Zn K-edge when the two metals are present at different relative concentrations revealed that Zn(II) and Cu(II) ions compete for binding to the tetra-octarepeat peptide by cross-regulating their relative binding modes. We show that the specific metal–peptide coordination mode depends not only, as expected, on the relative metal concentrations, but also on whether Zn(II) or Cu(II) was first bound to the peptide. In particular, it seems that the Zn(II) binding mode in the absence of Cu(II) is able to promote the formation of small peptide clusters in which triplets of tetra-octarepeats are bridged by pairs of Zn ions. When Cu(II) is added, it starts competing with Zn(II) for binding, disrupting the existing peptide cluster arrangement, despite the fact that Cu(II) is unable to completely displace Zn(II). These results may have a bearing on our understanding of peptide-aggregation processes and, with the delicate cross-regulation balancing we have revealed, seem to suggest the existence of an interesting, finely tuned interplay among metal ions affecting protein binding, capable of providing a mechanism for regulation of metal concentration in cells.     

Structural characterization of CYP165D3, a cytochrome P450 involved in phenolic coupling in teicoplanin biosynthesis

Teicoplanin is a glycopeptide antibiotic with activity against Gram-positive bacteria and remains one of the last lines of clinical defense against certain bacterial infections. We have cloned, expressed, and purified the cytochrome P450 OxyE (CYP165D3) from the teicoplanin biosynthetic gene cluster of Actinoplanes teichomyceticus, which is responsible for the phenolic coupling of the aromatic side chains of the first and third peptide residues in the teicoplanin peptide. The crystal structure of OxyE has been determined to 2.5 Å resolution, revealing the probable binding surface for the carrier protein substrate and an extension of the active site into a pocket located above the β-1 sheet. The binding of potential substrates to OxyE shows that peptidyl carrier protein-bound linear peptides bind to OxyE, albeit with low affinity in the absence of a phenolic cross-link that should normally be installed by another Oxy protein in the teicoplanin biosynthetic pathway. This result indicates that the carrier protein alone is not sufficient for tight substrate binding to OxyE and that the Oxy proteins sense the structure of the bound peptide in addition to the presence of the carrier protein, a feature distinct from other carrier protein/P450 systems.     

Metal binding modes of Alzheimer's amyloid beta-peptide in insoluble aggregates and soluble complexes

Aggregation of the amyloid beta-peptide (Abeta) into insoluble fibrils is a key pathological event in Alzheimer's disease. Zn(II) induces the Abeta aggregation at acidic-to-neutral pH, while Cu(II) is an effective inducer only at mildly acidic pH. We have examined Zn(II) and Cu(II) binding modes of Abeta and their pH dependence by Raman spectroscopy. The Raman spectra clearly demonstrate that three histidine residues in the N-terminal hydrophilic region provide primary metal binding sites and the solubility of the metal-Abeta complex is correlated with the metal binding mode. Zn(II) binds to the N(tau) atom of the histidine imidazole ring and the peptide aggregates through intermolecular His(N(tau))-Zn(II)-His(N(tau)) bridges. The N(tau)-metal ligation also occurs in Cu(II)-induced Abeta aggregation at mildly acidic pH. At neutral pH, however, Cu(II) binds to N(pi), the other nitrogen of the histidine imidazole ring, and to deprotonated amide nitrogens of the peptide main chain. The chelation of Cu(II) by histidine and main-chain amide groups results in soluble Cu(II)-Abeta complexes. Under normal physiological conditions, Cu(II) is expected to protect Abeta against Zn(II)-induced aggregation by competing with Zn(II) for histidine residues of Abeta.     

Raman spectroscopic study on the copper(II) binding mode of prion octapeptide and its pH dependence.

The cellular form of prion protein is a precursor of the infectious isoform, which causes fatal neurodegenerative diseases through intermolecular association. One of the characteristics of the prion protein is a high affinity for Cu(II) ions. The site of Cu(II) binding is considered to be the N-terminal region, where the octapeptide sequence PHGGGWGQ repeats 4 times in tandem. We have examined the Cu(II) binding mode of the octapeptide motif and its pH dependence by Raman and absorption spectroscopy. At neutral and basic pH, the single octapeptide PHGGGWGQ forms a 1:1 complex with Cu(II) by coordinating via the imidazole N pi atom of histidine together with two deprotonated main-chain amide nitrogens in the triglycine segment. A similar 1:1 complex is formed by each octapeptide unit in (PHGGGWGQ)2 and (PHGGGWGQ)4. Under weakly acidic conditions (pH approximately 6), however, the Cu(II)-amide- linkages are broken and the metal binding site of histidine switches from N pi to N tau to share a Cu(II) ion between two histidine residues of different peptide chains. The drastic change of the Cu(II) binding mode on going from neutral to weakly acidic conditions suggests that the micro-environmental pH in the brain cell regulates the Cu(II) affinity of the prion protein, which is supposed to undergo pH changes in the pathway from the cell surface to endosomes. The intermolecular His(N tau)-Cu(II)-His(N tau) bridge may be related to the aggregation of prion protein in the pathogenic form.     

Copper(II) complexation by pituitary adenylate cyclase activating polypeptide fragments.

Results are reported from potentiometric and spectroscopic (UV-Vis, CD, and ESR) studies of the protonation constants and Cu2+ complex stability constants of pituitary adenylate cyclase activating polypeptide fragments (HSDGI-NH2, TDSYS-NH2, RKQMAVKKYLAAVL-NH2). With HSDGI-NH2, the formation of a dimeric complex Cu2H-2L2 was found in the pH range 5-8, in which the coordination of copper(II) is glycylglycine-like, while the fourth coordination site is occupied by the imidazole N3 nitrogen atom, forming a bridge between two copper(II) ions. The formation of dimeric species does not prevent the deprotonation and coordination of the amide nitrogen, and in pH above 8 the CuH-2L complex is formed. Aspartic acid in the third position of peptide sequence stabilizes the CuH-2L species and prevents the coordination of a fourth nitrogen donor. Aspartic acid residue in the second position of TDSYS-NH2 stabilizes the CuL (2N) complex but does not prevent deprotonation and binding of the second and third peptide nitrogens to give 3N and 4N complexes at higher pH. The tetradecapeptide amide forms with copper(II) ions unusually stable 3N and 4N complexes compared to pentaalanine amide.     

Synthesis, spectroscopic, structural and complexation studies of a new tetra-naphthylmethylene pendant-armed macrocyclic ligand

A novel emissive tetra-naphthylmethylene pendant-armed macrocyclic ligand and a series of complexes with monovalent and divalent metal ions have been synthesized. Solid compounds have been isolated as mononuclear (Co(II), Cu(II) and Zn(II)) or dinuclear (Co(II), Ni(II), Cu(II), Zn(II), Cd(II) and Ag(I)), complexes, depending on the counterions used. The chemical and photophysical properties of the free ligand, the protonation behavior and its metal complexes have been investigated in solution. UV-Vis spectroscopy has revealed a 1:1 binding stoichiometry for Cu(II), Zn(II), Cd(II), Ni(II) and Co(II), and 2:1 molar ratio for Ag(I). In chloroform, the free ligand presents two emission bands related to the monomer naphthalene emission and a red-shifted band attibutable to an exciplex due to a charge transfer from the nitrogen lone electron pair to the excited chromophore. Upon protonation of the free amines or due to metal complexation, the exciplex band disappears. The crystal structure of [Ag₂L(NO₃)₂] is also reported. The structure reveals that both metal ions are into the macrocyclic cavity in a distorted square plane {AgN₃O} environment. Each Ag(I) atom interacts with two neighbouring amine nitrogen atoms, one pyridine nitrogen and one oxygen atom from a monodentate nitrate ion.