Peptide-based chemical models for lytic polysaccharide monooxygenases.

Copper(II) complexes of HPH-NH2 (L1) and HPHPY-NH2 (L2) peptides have been studied as small molecular models of lytic polysaccharide monooxygenases by pH-potentiometry and UV-vis, CD and EPR spectroscopy. The coordination properties of these ligands are fundamentally different from those of other non-protected N-terminal HXH-sequences concerning the metal binding ability of amide nitrogens. The proline units prevent the formation of fused chelates with the participation of amide nitrogens; therefore, instead of ATCUN-type {NH2,2N-,Nim} coordination, dimer complexes (Cu2HxL2, where x = -1, -2, and -3 for L1 and 1, 0, and -1 for L2) are formed in equimolar systems above pH 5. Using H2O2 as the oxidant and PNPG as the activated substrate, these dimer complexes were proved to be relevant functional models of LPMOs, even at neutral pH. Although the tyrosine residue in L2 participates in the coordination at pH 7-9.6, it does not seem to play a role in the oxidation process. In the presence of H2O2, the dimer complexes partially dissociate to form mononuclear hydroperoxo complexes, which are stable for 1-2 hours in equimolar concentrations of H2O2. On the other hand, with excess H2O2 both their formation and their decomposition are faster. The decay of (hydro)peroxo complexes, after longer reaction times, results in the evolution of dioxygen bubbles and the formation of Cu(I) (probably through catalytic disproportionation). However, in the presence of PNPG, the formation of dioxygen bubbles was not observed. Therefore, we assumed that the formed Cu(I) complexes bind H2O2 and enter into a similar catalytic cycle as suggested recently for native LPMOs.

Characterization of copper(II) specific pyridine containing ligands: Potential metallophores for Alzheimer's disease therapy.

Two amide group containing pyridine derivatives, N-(pyridin-2-ylmethyl)picolinamide (PMPA) and N-(pyridin-2-ylmethyl)-2-((pyridin-2-ylmethyl)amino)acetamide (DPMGA), have been investigated as potential metallo-phores in the therapy of Alzheimer's disease. Their complex formation with Cu(II) and Zn(II) were characterized in details. Unexpectedly not only the Cu(II) but also the Zn(II) was able to induce deprotonation of the amide-NH, however, it occurred only at higher pH or at higher metal ion concentrations than the biological conditions. At µM concentration level mono complexes (MLH-1) dominate with both ligands. Direct fluorescence and reactive oxygen species (ROS) producing measurements prove that both ligands are able to remove Cu(II) from its amyloid-ß complexes (CuAß). Correlation was also established between the conditional stability constant of the Cu(II) complexes with different ligands and their ability of inhibition of ROS production by CuAß.

The interaction of half-sandwich (η5-Cp*)Rh(III) cation with histidine containing peptides and their ternary species with (N,N) bidentate ligands.

Our goal was to explore the possible interactions of the potential metallodrug (η5-Cp*)Rh(III) complexes with histidine containing biomolecules (peptides/proteins) in order to understand the most important thermodynamic factors influencing the biospeciation and biotransformation of (η5-Cp*)Rh(III) complexes. To this end, here we report systematic solution thermodynamic and solution structural study on the interaction of (η5-Cp*)Rh(III) cation with histidine containing peptides and their constituents ((N-methyl)imidazole, GGA-OH, GGH-OH, histidine-amide, HGG-OH, GHG-NH2), based on extensive 1H NMR, ESI-MS and potentiometric investigations. The comparative evaluation of our data indicated that (η5-Cp*)Rh(III) cation is able to induce the deprotonation of amide nitrogen well below pH 7. Consequently, at physiological pH the peptides are coordinated to Rh(III) by tridentate manner, with the participation of amide nitrogen. At pH 7.4 the (η5-Cp*)Rh(III) binding affinity of peptides follow the order GGA-OH < < GGH-OH < < histidine-amide < HGG-OH < GHG-NH2, i.e. the observed binding strength essentially depends on the presence and position of histidine within the peptide sequence. We also performed computational study on the possible solution structures of complexes present at near physiological pH. At pH 7.4 all histidine containing peptides form ternary complexes with strongly coordinating (N,N) bidentate ligands (ethylenediamine or bipyridyl), in which the peptides are monodentately coordinated to Rh(III) through their imidazole N1­nitrogens. In addition, the strongest chelators histidine-amide, HGG-OH and GHG-NH2 are also able to displace these powerful bidentate ligands from the coordination sphere of Rh(III).