Insights into graphene oxide interaction with human serum albumin in isolated state and in blood plasma.

The interactions of graphene oxide (GO), a 2-dimensional nanomaterial with hydrophilic edges, hydrophobic basal plane and large flat surfaces, with biological macromolecules, are of key importance for the development of novel nanomaterials for biomedical applications. To gain more insight into the interaction of GO flakes with human serum albumin (HSA), we examined GO binding to HSA in its isolated state and in blood plasma. Calorimetric data reveal that GO strongly stabilizes free isolated HSA against a thermal challenge at low ionic strength, indicating strong binding interactions, confirmed by the drop in ζ-potential of the HSA/GO assemblies compared to bare GO flakes. However, calorimetry also revealed that the HSA-GO molecular interaction is hampered in blood plasma, the ionic strength being particularly important for the interactions. Molecular modelling calculations are in full concert with these experimental findings, indicating a considerably higher binding affinity for HSA to GO in its partially unfolded state, characteristic to low-ionic-strength environment, than for the native protein conformation, observed under physiological conditions. Therefore, for the first time we demonstrate an impeded interaction between HSA and GO nanoflakes in blood plasma, and suggest that the protein is protected from the plausible toxic effects of GO under native conditions.

Characterizing the structural and folding properties of long-sequence hypomurocin B peptides and their analogs.

We studied the folding processes of long-sequence hypomurocin (HM) peptides and their analogs by means of molecular dynamics methods, focusing on the formation of various helical structures and intramolecular H-bonds. The evolution of different helical conformations, such as the 310 -, α-, and left-handed α-helices, was examined, taking into account the entire sequence and each amino acid of peptides. The results indicated that the HM peptides and their analogs possessed a propensity to adopt helical conformations, and they showed a preference for the 310 -helical structure over the α-helical one. The evolution of a variety of the intramolecular H-bonds, including local and non-local interactions, was also investigated. The results pointed out that on the one hand, the appearance of local, helix-stabilizing H-bonds correlated with the presence of helical conformations, and on the other hand, the non-local H-bonds did not affect significantly the formation of helical structures. Additionally, comparing the structural and folding features of HM peptides and their analogs, our study led to the observation that the L-D isomerism of isovaline amino acid induced effects on the folding processes of these long-sequence peptaibol molecules. Accordingly, the HM peptides and their analogs could be characterized by typical structural and folding properties. © 2016 Wiley Periodicals, Inc. Biopolymers (Pept Sci) 106: 645-657, 2016.

Studying the structural and folding features of long-sequence trichobrachin peptides.

In this theoretical study, the folding processes of long-sequence trichobrachin peptides (i.e., TB IIb peptides) were investigated by molecular dynamics methods. The formation of various helical structures (i.e., 310 -, α-, and left-handed α-helices) was studied with regard to the entire sequence of peptides, as well as to each amino acid. The results pointed out that TB IIb molecules showed a propensity to form helical conformations, and they could be characterized by 310 -helical structure rather than by α-helical structure. The formation of local (i.e., i←i+3 and i←i+4) as well as of non-local (i.e., i←i+n, where n>4; and all i→i+n) H-bonds was also examined. The results revealed that the occurrence of local, helix-stabilizing H-bonds was in agreement with the appearance of helical conformations, and the non-local H-bonds did not produce relevant effects on the evolution of helical structures. Based on the data obtained by our structural investigation, differences were observed between the TB IIb peptides, according to the type of amino acid located in the 17th position of their sequences. In summary, the folding processes were explored for TB IIb molecules, and our theoretical study led to the conclusion that these long-sequence peptaibols showed characteristic structural and folding features.

In silico conformational analysis of the short-sequence hypomurocin a peptides.

In this theoretical study, a conformational analysis was performed on short-sequence hypomurocin A peptides, in order to identify their characteristic structural properties. For each hypomurocin A molecule, not only the backbone conformations, but also the side-chain conformations were examined. The results indicated that certain tetrapeptide units could be characterized by types I and III ß-turn structures, and considering the helical conformations, it could be concluded that the hypomurocin A peptides showed a preference for the 310-helical structure over the α-helical structure. Beside the backbone conformations, the side-chain conformations were investigated, and the preferred rotamer states of the side-chains of amino acids were determined. Furthermore, the occurrence of i ← i + 3 and i ← i + 4 intramolecular H-bonds was studied, which could play a role in the structural stabilization of ß-turns and helical conformations. On the whole, our theoretical study supplied a comprehensive characterization of the three-dimensional structure of short-sequence hypomurocin A peptides.

On the Hofmeister effect: fluctuations at the protein-water interface and the surface tension.

We performed molecular dynamics simulations on the tryptophane-cage miniprotein using a nonpolarizable force field, in order to model the effect of concentrated water solutions of neutral salts on protein conformation, which is a manifestation of Hofmeister effects. From the equilibrium values and the fluctuations of the solvent accessible surface area of the miniprotein, the salt-induced changes of the mean value of protein-water interfacial tension were determined. At 300 K, the chaotropic ClO4(-) and NO3(-) decreased the interfacial tension according to their position in the Hofmeister series (by approximately 5 and 2.7 mN/m, respectively), while the kosmotropic F(-) increased it (by 1 mN/m). These values were compared to those obtained from the Gibbs equation using the excess surface adsorption calculated from the probability distribution of the water molecules and ions around the miniprotein, and the two sets were found to be very close to each other. Our results present a direct evidence for the central role of interfacial tension and fluctuations at the protein-water interface in Hofmeister phenomena, and provide a computational method for the determination of the protein-water interfacial tension, establishing a link between the phenomenological and microscopic description of protein-water interfaces.

Structural characterization of the short peptaibols trichobrachins by molecular-dynamics methods.

A structural characterization was carried out by molecular-dynamics methods for eight trichobrachin peptides, to identify the conformational features of these short peptaibols. For all peptides, the backbone and side-chain conformations were investigated, different secondary structures, such as type-I and -III ß-turns as well as ß-bend ribbon spirals, were determined in certain tetrapeptide units of the molecules, and the preferred rotamers of the side chains of amino acids were identified. Furthermore, the end-to-end and residueresidue distances were examined, as well as the fluctuations of backbone atoms were studied. Based on these results, the peptides were compared to one another. Our theoretical study indicated that trichobrachins could be characterized by typical structural properties, and both conformational similarities and dissimilarities were observed between these peptaibols. In summary, this structural investigation supplied a characterization of the various conformational features of eight trichobrachin peptides.