Saccharose complexes of manganese in different oxidation states

The interaction between saccharose and manganese in different oxidation states was studied in alkaline media by polarographic, potentiometric, ESR spectroscopic and UV-Vis spectrophotometric methods. The results showed that stable manganese(II) and manganese(III) complexes and a complex of manganese(II,III) in a mixed oxidation state were formed with the composition [Mn^IIL(OH)₂], [Mn₂^IIIL₂(OH)₈]²⁻ and [Mn^IIMn^IIIL₂(OH)₆]⁻, respectively. The manganese(II)-saccharose complex was shown to dimerize in alkaline media. The stability constants of the Mn(II,III) and Mn(III) complexes were determined. The oxidation of the manganese(II)-saccharose complex by a stoichiometric amount of K₃ [FeCN]₆ resulted in the formation of the manganese(III) and manganese(IV) complexes. However, oxidation by molecular oxygen only yielded the manganese(III) complex which reduced spontaneously in inert atmosphere to the mixed valence Mn(II,III) complex. The latter was able to be oxidized again by oxygen to the Mn(III) complex. This process proved to be reversible and could be repeated several times.     

Redox potential changes during ATP‐dependent corrinoid reduction determined by redox titrations with europium(II)–DTPA

Corrinoids are essential cofactors of enzymes involved in the C₁ metabolism of anaerobes. The active, super‐reduced [Co^I] state of the corrinoid cofactor is highly sensitive to autoxidation. In O‐demethylases, the oxidation to inactive [Co^II] is reversed by an ATP‐dependent electron transfer catalyzed by the activating enzyme (AE). The redox potential changes of the corrinoid cofactor, which occur during this reaction, were studied by potentiometric titration coupled to UV/visible spectroscopy. By applying europium(II)–diethylenetriaminepentaacetic acid (DTPA) as a reductant, we were able to determine the midpoint potential of the [Co^II]/[Co^I] couple of the protein‐bound corrinoid cofactor in the absence and presence of AE and/or ATP. The data revealed that the transfer of electrons from a physiological donor to the corrinoid as the electron‐accepting site is achieved by increasing the potential of the corrinoid cofactor from ?530 ± 15 mV to ?250 ± 10 mV (E_SHE, pH 7.5). The first 50 to 100 mV of the shift of the redox potential seem to be caused by the interaction of nucleotide‐bound AE with the corrinoid protein or its cofactor. The remaining 150–200 mV had to be overcome by the chemical energy of ATP hydrolysis. The experiments revealed that Eu(II)–DTPA, which was already known as a powerful reducing agent, is a suitable electron donor for titration experiments of low‐potential redox centers. Furthermore, the results of this study will contribute to the understanding of thermodynamically unfavorable electron transfer processes driven by the power of ATP hydrolysis.     

The redox properties of (1,6-bis(benzimidazol-2-yl)-2,5-dithiahexane) chloro-copper(II) chloride as studied by cyclic voltammetry

Cyclic voltammetry in acetonitrile has been used to study the redox properties of the compound [Cu-(BBDH)Cl] Cl under various conditions. The nature of the species in solution was studied with the aid of ligand-field spectra and ESR spectra. It appears that in CH₃CN solution two Cu(II) species are predominating, viz. [Cu(BBDH)(CH₃CN)_x]²⁺ and Cu(BBDH)-Cl⁺. Minor species are dimeric in nature, such as [(BBDH)CuCl₂Cu(BBDH)]²⁺, as easily seen from ESR. The relative amount of the two major species was varied using added LiCl, allowing us to determine the nature of both species. The redox potential of the species [Cu(BBDH)Cl]⁺ appeared to be 0.62 V (against a normal hydrogen electrode), which is very high for a Cu(II) compound and in the same area as found for the blue copper proteins. Re-oxidation of Cu(BBDH)⁺ in the presence of LiCl shows that C$\text{l}$ slowly recoordinates after reoxidation.     

Synthesis, structural and corrosion inhibition studies on cobalt(II), nickel(II), copper(II) and zinc(II) complexes with 2-acetylthiophene benzoylhydrazone

Cobalt(II), nickel(II), copper(II) and zinc(II) complexes with 2-acetylthiophene benzoylhydrazone have been synthesized and characterized by elemental analyses, magnetic susceptibility measurements, electronic, IR, NMR and ESR spectral techniques. The molecular structures of ligand and its copper(II) complex have been determined by single crystal X-ray diffraction technique. The Cu(II) complex possesses a CuN₂O₂ chromophore with a considerable delocalization of charge. The structure of the complex is stabilized by intermolecular π–π stacking and C–H?π interactions. Hatbh acts as a monobasic bidentate ligand in all the complexes bonding through a deprotonated C–O⁻ and >CN groups. Electronic spectral studies indicate an octahedral geometry for the Ni(II) complex while square planar geometry for the Co(II) and Cu(II) complexes. ESR spectrum of the Cu(II) complex exhibits a square planar geometry in solid and in DMSO solution. The trend g_|| > g_⊥ > 2.0023 indicates the presence of an unpaired electron in the d_x²-y² orbital of Cu(II). The electro-chemical study of Cu(II) complex reveals a metal based reversible redox behavior. The Ni(II) complex shows exothermic multi-step decomposition pattern of the bonded ligand. The ligand and its most of the metal complexes show appreciable corrosion inhibition properties for mild steel in 1 M HCl medium. [Co(atbh)₂] complex exhibited the greatest impact on corrosion inhibition among the other compounds.     

Redox behavior of copper in particulate methane monooxygenase from Methylosinus trichosporium OB3b

The redox properties of the copper in particulate methane monooxygenase from Methylosinus trichosporium OB3b were investigated. The ESR spectrum of the pMMO-containing membranes from M. trichosporium OB3b indicated a typical type II copper (II) signal (g = 2.24, A = 18.4 mT, g = 2.06, ₂= 0.84). By anaerobic addition of excess amounts of duroquinol, an optimum reductant of pMMO, the ESR spectra indicated that the copper cluster in membranes was reduced and successively oxidized by dioxygen, a substrate of pMMO. The result suggests that the copper is the active site of pMMO or an electron carrier. During the titration, the intensity of the type II copper signal decreased with decreasing potential and the multiple hyperfine structure at g = 2.06 appeared clearly. Although the copper signal did not change by treatment of the EDTA-treated membranes with duroquinol and dioxygen, the copper signal intensity decreased with decreasing potential in the redox titration. These results suggest that some redox mediators play a role as an electron carrier between the active site and a reductant, and the presence of at least two types of copper sites in pMMO- containing membranes. On the basis of the ESR spectra of the EDTA-treated membranes and the as-isolated membranes, it is concluded that one type of the copper sites functions as the active site of pMMO (A-site), and the other type of copper sites plays a role as an electron carrier (E-site)     

Interaction of Cu(II)with His-Val-Gly-Asp and of Zn(II) with His-Val-His,Two Peptides at the Active Site of Cu,Zn-Superoxide Dismutase

His-Val-His and His-Val-Gly-Asp are two naturally occurring peptide sequences, present at the active site of Cu,Zn-superoxide dismutase (Cu,Zn-SOD). We have already studied the interaction of His-Val-His=A (copper binding site) with Cu(II) and of His-Val-Gly-Asp=B (zinc binding site) with Zn(II). As a continuation of this work and for comparison purposes we have also studied the interaction of Zn(II) with His-Val-His and Cu(II) with His-Val-Gly-Asp using both potentiometric and spectroscopic methods (visible, EPR, NMR). The stoichiometry, stability constants and solution structure of the complexes formed have been determined. Histamine type of coordination is observed for/ZnAH/²⁺, /ZnA/⁺, /ZnA²H/⁺ and/ZnA²/ in acidic pH while deprotonation of coordinated water molecules is observed at higher pH. /CUB/ species is characterized by the formation of a macrochelate and histamine type coordination. Its stability results in the suppression of amide deprotonation which occurs at high pH resulting in the formation of the highly distorted from square planar geometry 4N complex/CuBH_-3/³.     

Ligand chirality-controlled selective formation of mono- and dinuclear copper complexes

Reaction of copper(II) acetate with the (S)-enantiomer of a tridentate binaphthyl Schiff base ligand, 2-(3,5-dichloro-2-hydroxybenzylideneamino)-2′-hydroxy-1,1′-binaphthyl (H₂L), in methanol afforded mononuclear copper(II) complex [Cu^II(HL)₂] ((S,S)-1) in 52% isolated yield. The same reaction gave dinuclear copper(II) complex [Cu^II₂(L)₂] ((R,S)-2) in 73% isolated yield when racemic-H₂L was used instead of (S)-H₂L. Both complexes (S,S)-1 and (R,S)-2 were characterized by elemental analysis, mass spectrometry, and X-ray crystallography. The present work highlights the functioning of ligand chirality as a ‘switch’ for selective formation of mono- and dinuclear metal complexes.     

The complex formation of zinc(II) with GHL and related peptides

The formation constants for complexes of Zn(II) with GHL and related peptides have been determined by means of potentiometric titration and ¹H NMR spectroscopy in aqueous solution. GHL has a high affinity for Zn(II) but this somewhat higher affinity compared to the related peptides AH, LH and HL is not a sufficient explanation for its biological role.¹H NMR spectroscopy allows structural assignment of the relative chemical shifts to complex structures and the method, therefore, is a powerful tool for the determination of complex structures when the metal ion is diamagnetic and the ESR method previously applied to the GHLCu(II) system (see ref. 4) cannot be used.     

Tautomeric changes in guanfacine and its copper(II) complex as revealed by X-ray crystallography; synthesis and EPR

Obtention and crystal structure of guanfacine (guaH) together with synthesis and crystal structure of its copper complex [Cu^II(gua)₂] · DMF were reported. The free molecule guaH exhibits one tautomeric form (B) in contrast to the form (A) which was reported in the Merck index. In the copper(II) complex, the anionic form gua⁻ exhibits the third tautomeric form (C). This complex is characterized by a CuN₂O₂ coordination. The EPR spectrum is in agreement with a Cu(II) ion in a square planar configuration.     

Metal binding by pyridine-2,6-bis(monothiocarboxylic acid), a biochelator produced by Pseudomonas stutzeri and Pseudomonas putida

Pyridine-2,6-bis(monothiocarboxylic acid) (pdtc),a natural metal chelator produced by Pseudomonas stutzeri and Pseudomonas putidathat promotes the degradation of carbon tetrachloride, was synthesized and studiedby potentiometric and spectrophotometric techniques. The first two stepwise protonationconstants (pK) for successive proton addition to pdtc were found to be 5.48 and2.58. The third stepwise protonation constant was estimated to be 1.3. The stability (affinity)constants for iron(III), nickel(II), and cobalt(III) were determined by potentiometric orspectrophotometric titration. The results show that pdtc has strong affinity for Fe(III)and comparable affinities for various other metals. The stability constants (log K) are 33.93 for Co(pdtc)₂ ^1-; 33.36 for Fe(pdtc)₂ ^1-; and 33.28 for Ni(pdtc)₂ ^2-. These protonationconstants and high affinity constants show that over a physiological pH range theferric pdtc complex has one of the highest effective stability constants for ironbinding among known bacterial chelators.     

On the generation of OH<Superscript>·</Superscript> radical species from H<Subscript>2</Subscript>O<Subscript>2</Subscript> by Cu(I) amyloid beta peptide model complexes: a DFT investigation

According to different studies, the interaction between amyloid β-peptide (Aβ) and copper ions could yield radical oxygen species production, in particular the highly toxic hydroxyl radical OH^· that is suspected to contribute to Alzheimer’s disease pathogenesis. Despite intensive experimental and computational studies, the nature of the interaction between copper and Aβ peptide, as well as the redox reactivity of the system, are still matter of debate. It was proposed that in Cu(II) → Cu(I) reduction the complex Cu(II)–Aβ could follow a multi-step conformational change with redox active intermediates that may be responsible for OH^· radical production from H₂O₂ through a Fenton-like process. The purpose of this work is to evaluate, using ab initio Density Functional Theory computations, the reactivity of different Cu(I)–Aβ coordination modes proposed in the literature, in terms of OH^· production. For each coordination model, we considered the corresponding H₂O₂ adduct and performed a potential energy surface scan along the reaction coordinate of O–O bond dissociation of the peroxide, resulting in the production of OH^· radical, obtaining reaction profiles for the evaluation of the energetic of the process. This procedure allowed us to confirm the hypothesis according to which the most populated Cu(I)–Aβ two-histidine coordination is not able to perform efficiently H₂O₂ reduction, while a less populated three-coordinated form would be responsible for the OH^· production. We show that coordination modes featuring a third nitrogen containing electron-donor ligand (an imidazole ring of an histidine residue is slightly favored over the N-terminal amine group) are more active towards H₂O₂ reduction.     

Disproportionation of pentaammineruthenium(III)–nucleoside complexes leads to two-electron oxidation of nucleosides without involving oxygen molecules

Pentaammineruthenium(III) complexes of deoxyinosine (dIno) and xanthosine (Xao) ([Ru^III(NH₃)₅(L)], L?is?dIno, Xao) in basic solution were studied by UV?Cvis spectroscopy, liquid chromatography/electrospray ionization mass spectrometry, and high-performance liquid chromatography. Both Ru^III complexes disproportionate to Ru^II and Ru^IV. Disproportionation followed the rate law d[Ru^II]/dt?=?(k _o?+?k ₁[OH^?])[Ru^III]. k _o and k ₁ of disproportionation at 25?°C were 2.1 (±0.1)?×?10^?3?s^?1 and 21.4?±?3.2?M^?1 s^?1, respectively, for [Ru^III(NH₃)₅(dIno)], and 3.5 (±0.7)?×?10^?4?s^?1 and 59.7?±?3.6?M^?1?s^?1, respectively, for [Ru^III(NH₃)₅(Xao)]. The [Ru^III(NH₃)₅(Xao)] complex disproportionates at a faster rate than [Ru^III(NH₃)₅(dIno)] owing to the stronger electron-withdrawing effect of exocyclic oxygen in Xao. The activation parameters ??H ^? and ??S ^? for k ₁ of [Ru^III(NH₃)₅(dIno)] were 80.2?±?15.2?kJ?mol^?1 and 47.6?±?9.8?J?K^?1 mol^?1, respectively, indicating that the disproportionation of Ru^III to Ru^II and Ru^IV is favored owing to the positive entropy of activation. The final products of both complexes in basic solution under Ar were compared with those under O₂. Under both conditions [Ru(NH₃)₅(8-oxo-L)] was produced, but via different mechanisms. In both aerobic and anaerobic conditions, the deprotonation of highly positively polarized C8-H of Ru-L by OH^? initiates a two-electron redox reaction. For the next step, we propose a one-step two-electron redox reaction between L and Ru^IV under anaerobic conditions, which differentiates from Clarke??s mechanism of two consecutive one-electron redox reactions between L, Ru^III, and O₂.     

Copper(II) complexation by D-glucosamine. Spectroscopic and potentiometric studies

The Cu(II) complex formation equilibria of D- glucosamine were studied in aqueous solution by potentiometric and spectroscopic (ESR, CD, absorption spectra) techniques. All data agree that two major species are formed in the pH region 6–9 involving two D-glucosamine ligand molecules bound to the cupric ion via NH₂(CuL₂) or NH₂ and O^? (CuH_?2L₂). In the latter case deprotonated hydroxyls were found to be very effective coordination sites for Cu(II) giving rise to chelate complexes. On the contrary, no complex formation was observed for the Cu(II) N-acetyl-D-glucosamine system.     

Solution properties of Cu(II)-L-α-alaninehydroxamic acid

In the aqueous solution of copper(II) ions, bidentate L-α-alaninehydroxamic acid (CH₃CH(NH₂)-CONHOHHL) binds cupric ion forming of monodimeric and bis(L-α-alaninehydroxamato)copper(II) complexes. These complexes were studied by potentiometric, ESR and spectrophotometric methods.The ESR studies provide important evidence for the formation of different Cu(II) complexes with L-α-alaninehydroxamic acid, depending on pH. The ESR spectra can be used to follow the appearance of the individual complexes, to estimate the coordination sphere around Cu(II) and to observe the equilibria between different complexes.The solution electronic spectra are reported. The experimental curve was resolved into precise- positioned absorption bands by Gaussian analysis for the bis(L-α-alaninehydroxamato)copper(II) species. These data were used in a weak tetragonal ligand field model to calculate ligand field parameters.The distribution and the relevant stability constants of species present in aqueous solutions were obtained by analytical potentiometry.     

Synthesis, characterization and structure of a new zinc(II) complex containing the hexadentate N,N′,N,N′-bis[(2-hydroxy-3,5-di-tert-butylbenzyl)(2-pyridylmethyl)]-ethylenediamine ligand: Generation of phenoxyl radical species

This work summarizes the results of our studies on the structural, spectral and redox properties of a mononuclear zinc(II) complex with the new H₂L ligand (H₂L = N,N′,N,N′-bis[(2-hydroxy-3,5-di-tert-butylbenzyl)(2-pyridylmethyl)]-ethylene diamine). The crystal structure of the complex [Zn^II(HL)] · ClO₄ (1) was determined by X-ray crystallographic analysis. The structure of this complex consists of a discrete mononuclear cation [Zn^II(HL)]⁺, in a strongly distorted geometry with a slight tendency toward a distorted square pyramidal geometry, as reflected by the structural index parameter τ of 0.44. The zinc(II) cation is coordinated to one oxygen and four nitrogen atoms: the pyridine nitrogen atoms (N22 and N32), tertiary amine nitrogen atoms (N1 and N4) and phenolate oxygen atom (O10). ¹H and ¹³C NMR spectral data show a rigid solution structure for 1 in agreement with X-ray structure. Potentiometric studies of complex 1 were also performed and revealed three titratable protons which are attributed to the protonation/deprotonation of two phenol groups (p[K]_a1 = 4.04 and p[K]_a3 = 11.34) and dissociation of a metal-bound water molecule (p[K]_a2 = 7.8). The phenolate groups in complex 1 are suitably protected by bulky substituents (tert-butyl) in the ortho- and para-positions, which through electrochemical oxidation generate a one-electron oxidized phenoxyl species in solution. This radical species was characterized by UV-Vis, EPR and electrochemical studies. The Zn(II)-phenoxyl radical species is of bioinorganic relevance, since its spectroscopic, redox and reactivity properties can be used to establish the role of phenoxyl radicals in biological and catalytical systems.     

Two macrocyclic pentaaza compounds containing pyridine evaluated as novel chelating agents in copper(II) and nickel(II) overload

Two pentaaza macrocycles containing pyridine in the backbone, namely 3,6,9,12,18-pentaazabicyclo[12.3.1]octadeca-1(18),14,16-triene ([15]pyN₅), and 3,6,10,13,19-pentaazabicyclo[13.3.1]nonadeca-1(19),15,17-triene ([16]pyN₅), were synthesized in good yields. The acid-base behaviour of these compounds was studied by potentiometry at 298.2 K in aqueous solution and ionic strength 0.10 M in KNO₃. The protonation sequence of [15]pyN₅ was investigated by ¹H NMR titration that also allowed the determination of protonation constants in D₂O. Binding studies of the two ligands with Ca²⁺, Ni²⁺, Cu²⁺, Zn²⁺, Cd²⁺, and Pb²⁺ metal ions were performed under the same experimental conditions. The results showed that all the complexes formed with the 15-membered ligand, particularly those of Cu²⁺ and especially Ni²⁺, are thermodynamically more stable than with the larger macrocycle. Cyclic voltammetric data showed that the copper(II) complexes of the two macrocycles exhibited analogous behaviour, with a single quasi-reversible one-electron transfer reduction process assigned to the Cu(II)/Cu(I) couple. The UV-visible-near IR spectroscopic and magnetic moment data of the nickel(II) complexes in solution indicated a tetragonal distorted coordination geometry for the metal centre. X-band EPR spectra of the copper(II) complexes are consistent with distorted square pyramidal geometries. The crystal structure of [Cu([15]pyN₅)]²⁺ determined by X-ray diffraction showed the copper(II) centre coordinated to all five macrocyclic nitrogen donors in a distorted square pyramidal environment.     

Tris-ruthenium(II)/copper(II) multimetallic porphyrin: Synthesis, characterization, DNA binding and supercoiled DNA photocleavage studies

The porphyrin, meso-5-(pentafluorophenyl)-10, 15, 20-tris(4-pyridyl)porphyrin has been used to synthesize two new metalloporphyrin complexes. Insertion of copper(II) into the porphyrin center gives the copper(II) porphyrin. Coordination of three [Ru(bipy)₂Cl]⁺ moieties (where bipy = 2,2′-bipyridine) to the pyridyl nitrogens of the copper(II) porphyrin gives the target complex. Electronic transitions associated with the copper(II) porphyrin and the triruthenium copper(II) porphyrin include an intense Soret band and a less intense Q-band in the visible region of the spectrum. An intense π-π∗ transition in the UV region associated with the bipyridyl groups and a metal to ligand charge transfer (MLCT) band appearing as a shoulder to the Soret band are observed for the ruthenated copper(II) porphyrin. Electrochemical properties associated with the multimetallic complex include a redox couple in the cathodic region with E_1/2 = −0.86 V versus Ag/AgCl attributed to the porphyrin and a redox couple in the anodic region E_1/2 = 0.88 V versus Ag/AgCl due to the Ru^III/II couple. DNA titrations indicate the triruthenium copper(II) porphyrin interacts with DNA potentially through a groove binding mechanism. Irradiation of aqueous solutions of the target complex and supercoiled DNA at a 10:1 base pair to complex ratio with visible light above 400 nm indicates that the complex causes nicking of the DNA helix.     

Nickel(II) complexes of the multihistidine peptide fragments of human prion protein

Nickel(II) complexes of the peptide fragments of human prion protein containing histidyl residues both inside and outside the octarepeat domain have been studied by the combined application of potentiometric, UV-visible and circular dichroism spectroscopic methods. The imidazole-N donor atoms of histidyl residues are the exclusive metal binding sites below pH 7.5, but the formation of stable macrochelates was characteristic only for the peptide HuPrP(76-114) containing four histidyl residues. Yellow colored square planar complexes were obtained above pH 7.5-8 with the cooperative deprotonation of three amide nitrogens in the [N_im,N⁻,N⁻,N⁻] coordination mode. It was found that the peptides can bind as many nickel(II) ions as the number of independent histidyl residues. All data supported that the complex formation processes of nickel(II) are very similar to those of copper(II), but with a significantly reduced stability for nickel(II), which shifts the complex formation reactions into the slightly alkaline pH range. The formation of coordination isomers was characteristic of the mononuclear complexes with a significant preference for the nickel(II) binding at the histidyl sites outside the octarepeat domain. The results obtained for the two-histidine fragments of the protein, HuPrP(91-115), HuPrP(76-114)H85A and HuPrP(84-114)H96A, made it possible to compare the binding ability of the His96 and His111 sites. These data reveal a significant difference in the nickel(II) and copper(II) binding sites of the peptides: His96 was found to predominate almost completely for nickel(II) ions, while the opposite order, but with comparable concentrations, was reported for copper(II).     

Synthesis of palladium(II) 3d-metal(II) paddlewheel acetate-bridged heterodimetallic complexes: Unexpected catalysis by water molecules

A study of the reaction kinetics between the trinuclear palladium(II) acetate Pd₃(μ-OOCMe)₆ (1) and the mononuclear 3d-metal (Ni^II, Co^II, Cu^II) acetates in acetic acid under water-specified conditions revealed a fairly complicated reaction mechanism triggered by the primary hydrolytic cleavage of an acetate bridge in molecule 1. The isolated reaction products, as established by X-ray diffraction study, are 1D polymeric complexes {Pd(μ-OOCMe)₄M(OH₂)(HOOCMe)₂}_n (M = Ni^II, Co^II, Cu^II, Mn^II, Zn^II) built of the Pd^II-based paddlewheel units [Pd(μ-OOCMe)₄M] and linked trough the H-bonded H₂O and MeCOOH molecules.     

Mononuclear copper(II) complexes of alloferons 1 and 2: a combined potentiometric and spectroscopic studies

Mononuclear copper(II) complexes of the alloferon 1 His-Gly-Val-Ser-Gly-His-Gly-Gln-His-Gly-Val-His-Gly, alloferon 2 Gly-Val-Ser-Gly-His-Gly-Gln-His-Gly-Val-His-Gly, Ac-alloferon 1 Ac-His-Gly-Val-Ser-Gly-His-Gly-Gln-His-Gly-Val-His-Gly and Ac-alloferon 2 Ac-Gly-Val-Ser-Gly-His-Gly-Gln-His-Gly-Val-His-Gly have been studied by potentiometric, UV-vis, CD and EPR spectroscopic methods. The potentiometric and spectroscopic data shows that acetylation of the amino terminal group induces significant changes in the coordination properties of the Ac-alloferons 1 and 2 compared to the alloferons 1 and 2, respectively. The presence of four (Ac-alloferon 1) or three (Ac-alloferon 2) histidyl residues provides a high possibility for the formation of macrochelates via the exclusive binding of imidazole-N donor atoms. The macrochelation suppresses, but cannot preclude the deprotonation and metal ion coordination of amide functions and the CuH₋₃L species with {N_Im, 3N⁻} bonding mode at pH above 8 are formed. The N-terminal amino group of the alloferons 1 and 2 takes part in the coordination of the metal ion and the 4N complex with {NH₂, 3N_Im} coordination mode dominates at physiological pH 7.4 for alloferon 1 and the 3N {NH₂, CO, 2N_Im} binding mode for alloferon 2. However, at higher pH values sequential amide nitrogens are deprotonated and coordinated to copper(II) ions.