Youssef El Khoury

New Insights into the Coordination of Cu(II) by the Amyloid-B 16 Peptide from Fourier Transform IR Spectroscopy and Isotopic Labeling

Alzheimers disease is a neurodegenerative disorder in which the formation of amyloid-β (Aβ) aggregates plays a causative role. There is ample evidence that Cu(II) can bind to Aβ and modulate its aggregation. Moreover, Cu(II) bound to Aβ might be involved in the production of reactive oxygen species, a process supposed to be involved in the Alzheimers disease. The native Aβ40 contains a high affinity binding site for Cu(II), which is comprised in the N-terminal portion. Thus, Aβ16 (amino acid 1-16 of Aβ) has often been used as a model for Cu(II)-binding to monomeric Aβ. The Cu(II)-binding to Aβ is pH dependent and at pH 7.4, two different type of Cu(II) coordinations exist in equilibrium. These two forms are predominant at pH 6.5 and pH 9.0. In either form, a variety of studies show that the N-terminal Asp and the three His play a key role in the coordination, although the exact binding of these amino acids has not been addressed. Therefore, we studied the coordination modes of Cu(II) at pH 6.5 and 9.0 with the help of Fourier transform infrared (FTIR) spectroscopy. Combined with isotopic labeling of the amino acids involved in the coordination sphere, the data points toward the coordination of Cu(II) via the carboxylate of Asp1 at both pH values in a pseudobridging monovalent fashion. At low pH, His6 binds copper via Nτ, while His13 and His14 are bound via Nπ. At high pH, direct evidence is given on the coordination of Cu(II) via the Nτ atom of His6. Additionally, this study clearly shows the effect of Cu(II) binding on the protonation state of the His residues where a proton displacement takes places on the nitrogen atoms of the imidazole ring.

Zinc Inhibition of Bacterial Cytochrome bc1 Reveals the Role of Cytochrome b E295 in Proton Release at the Qo Site

The cytochrome (cyt) bc(1) complex (cyt bc(1)) plays a major role in the electrogenic extrusion of protons across the membrane responsible for the proton motive force to produce ATP. Proton-coupled electron transfer underlying the catalysis of cyt bc(1) is generally accepted, but the molecular basis of coupling and associated proton efflux pathway(s) remains unclear. Herein we studied Zn(2+)-induced inhibition of Rhodobacter capsulatus cyt bc(1) using enzyme kinetics, isothermal titration calorimetry (ITC), and electrochemically induced Fourier transform infrared (FTIR) difference spectroscopy with the purpose of understanding the Zn(2+) binding mechanism and its inhibitory effect on cyt bc(1) function. Analogous studies were conducted with a mutant of cyt b, E295, a residue previously proposed to bind Zn(2+) on the basis of extended X-ray absorption fine-structure spectroscopy. ITC analysis indicated that mutation of E295 to valine, a noncoordinating residue, results in a decrease in Zn(2+) binding affinity. The kinetic study showed that wild-type cyt bc(1) and its E295V mutant have similar levels of apparent K(m) values for decylbenzohydroquinone as a substrate (4.9 ± 0.2 and 3.1 ± 0.4 μM, respectively), whereas their K(I) values for Zn(2+) are 8.3 and 38.5 μM, respectively. The calorimetry-based K(D) values for the high-affinity site of cyt bc(1) are on the same order of magnitude as the K(I) values derived from the kinetic analysis. Furthermore, the FTIR signal of protonated acidic residues was perturbed in the presence of Zn(2+), whereas the E295V mutant exhibited no significant change in electrochemically induced FTIR difference spectra measured in the presence and absence of Zn(2+). Our overall results indicate that the proton-active E295 residue near the Q(o) site of cyt bc(1) can bind directly to Zn(2+), resulting in a decrease in the electron transferring activity without changing drastically the redox potentials of the cofactors of the enzyme. We conclude that E295 is involved in proton efflux coupled to electron transfer at the Q(o) site of cyt bc(1).

Probing the Hydrogen Bonding Structure in the Rieske Protein

The use of the far-infrared spectral range presents a novel approach for analysis of the hydrogen bonding in proteins. Here it is presented for the analysis of Fe--S vibrations (500-200 cm(-1)) and of the intra- and intermolecular hydrogen bonding signature (300-50 cm(-1)) in the Rieske protein from Thermus thermophilus as a function of temperature and pH. Three pH values were adequately chosen in order to study all the possible protonation states of the coordinating histidines. The Fe--S vibrations showed pH-dependent shifts in the FIR spectra in line with the change of protonation state of the histidines coordinating the [2Fe--2S] cluster. Measurements of the low-frequency signals between 300 and 30 K demonstrated the presence of a distinct overall hydrogen bonding network and a more rigid structure for a pH higher than 10. To further support the analysis, the redox-dependent shifts of the secondary structure were investigated by means of an electrochemically induced FTIR difference spectroscopic approach in the mid infrared. The results confirmed a clear pH dependency and an influence of the immediate environment of the cluster on the secondary structure. The results support the hypothesis that structure-mediated changes in the environment of iron--sulfur centers play a critical role in regulating enzymatic catalysis. The data point towards the role of the overall internal hydrogen bonding organization for the geometry and the electronic properties of the cluster.

A Combined Far‐Infrared Spectroscopic and Electrochemical Approach for the Study of Iron–Sulfur Proteins

Herein, we present the development of a far-infrared spectroscopic approach for studying metalloenzyme active sites in a redox-dependent manner. An electrochemical cell with 5 mm path and based on silicon windows was found to be appropriate for the measurement of aqueous solutions down to 200 cm(-1) . The cell was probed with the infrared redox signature of the metal-ligand vibrations of different iron-sulfur proteins. Each Fe-S cluster type was found to show a specific spectral signature. As a common feature, a downshift of the frequency of the Fe-S vibrations was seen upon reduction, in line with the increase of the Fe-S bond. This downshift was found to be fully reversible. Electrochemically induced FTIR difference spectroscopy in the far infrared is now possible, opening new perspectives on the understanding of metalloproteins in function of the redox state.

Similarities and differences of copper and zinc cations binding to biologically relevant peptides studied by vibrational spectroscopies

GHK and DAHK are biological peptides that bind both copper and zinc cations. Here we used infrared and Raman spectroscopies to study the coordination modes of both copper and zinc ions, at pH 6.8 and 8.9, correlating the data with the crystal structures that are only available for the copper-bound form. We found that Cu(II) binds to deprotonated backbone (amidate), the N-terminus and Nπ of the histidine side chain, in both GHK and DAHK, at pH 6.8 and 8.9. The data for the coordination of zinc at pH 6.8 points to two conformers including both nitrogens of a histidine residue. At pH 8.9, vibrational spectra of the ZnGHK complexes show that equilibria between monomers, oligomers exist, where deprotonated histidine residues as well as deprotonated amide nitrogen are involved in the coordination. A common feature is found: zinc cations coordinate to Nτ and/or Nπ of the His leading to the formation of GHK and DAHK multimers. In contrast, Cu(II) binds His via Nπ regardless of the peptide, in a pH-independent manner.

Temperature Dependence of the Far Infrared Signature of Internal Hydrogen Bonds in Proteins as Probed for Integrins

The basic motions and the conformational flexibility of a protein have a strong impact on its molecular recognition properties and ultimately on its function. In the far infrared (or THz) spectral range the breathing of the hydrogen bonds can be monitored, providing essential information on local dynamics and mechanism. The use of this spectral range is rapidly evolving and a number of IR synchrotron beamlines are available for this research. Here we present a study on the I‐domain of the integrin LFA‐1, an allosteric receptor that transmits signals across the plasma membrane in a bidirectional way. The I‐domain contains the principal binding site for extracellular ligands and thus crucial for the signaling and the integrin‐mediated cell adhesion. We measured the temperature dependence of the conformational dynamics of the I‐domain bound to four different divalent metal ions (Mg2+, Ca2+, Mn2+ and Fe2+) in the range 10–300 K. The H‐bonding vibrations show distinct temperature dependences for the different ...

Cu(II) Binding to the Peptide Ala-His-His, a Chimera of the Canonical Cu(II)-Binding Motifs Xxx-His and Xxx-Zzz-His

Peptides and proteins with the N-terminal motifs NH2-Xxx-His and NH2-Xxx-Zzz-His form well-established Cu(II) complexes. The canonical peptides are Gly-His-Lys and Asp-Ala-His-Lys (from the wound healing factor and human serum albumin, respectively). Cu(II) is bound to NH2-Xxx-His via three nitrogens from the peptide and an external ligand in the equatorial plane (called 3N form here). In contrast, Cu(II) is bound to NH2-Xxx-Zzz-His via four nitrogens from the peptide in the equatorial plane (called 4N form here). These two motifs are not mutually exclusive, as the peptides with the sequence NH2-Xxx-His-His contain both of them. However, this chimera has never been fully explored. In this work, we use a multispectroscopic approach to analyze the Cu(II) binding to the chimeric peptide Ala-His-His (AHH). AHH is capable of forming the 3N- and 4N-type complexes in a pH dependent manner. The 3N form predominates at pH ∼ 4-6.5 and the 4N form at ∼ pH 6.5-10. NMR experiments showed that at pH 8.5, where Cu(II) is almost exclusively bound in the 4N form, the Cu(II)-exchange between AHH or the amidated AHH-NH2 is fast, in comparison to the nonchimeric 4N form (AAH). Together, the results show that the chimeric AHH can access both Cu(II) coordination types, that minor changes in the second (or further) coordination sphere can impact considerably the equilibrium between the forms, and that Cu kinetic exchange is fast even when Cu-AHH is mainly in the 4N form.

Study on hydrogen bonding patterns in biological molecules by reaction induced far infrared spectroscopy

The use of the far IR spectral range presents a novel approach for analysis of proteins. Here it is presented for the analysis of Fe-S vibrations (500–200 cm⁻¹) and of the intra-and intermolecular H-bonding signature (300–50 cm⁻¹) in Rieske proteins and lipids in function of T, redox state and pH.