Interactions of neurokinin B with copper(II) ions and their potential biological consequences.

Preeclampsia is a blood pressure disorder associated with significant proteinuria. Hypertensive women have increased levels of neurokinin B (NKB) and Cu(II) ions in blood plasma during pregnancy. NKB bears the ATCUN/NTS N-terminal motif empowering strong Cu(II) binding in a characteristic four-nitrogen (4N) square-planar motif, but an alternative Cu(II)NKB2 geometry was proposed earlier. We studied the coordination of DMHD-NH2, representing the NKB ATCUN/NTS motif, to Cu(II) by potentiometry, electronic absorption and circular dichroism spectroscopy in water and SDS micellar solutions. NKB was studied in SDS micelles. The experiments were aided by density functional theory (DFT) calculations. We found that under all investigated conditions NKB formed solely 1 : 1 complexes. In the absence of SDS, the 4N complex at physiological pH 7.4 has a very low dissociation constant of 3.5 fM, but the interaction with SDS weakened the binding nearly thousand-fold. This interaction may serve as a molecular switch for specific Cu(II) delivery to membrane receptors by NKB. Furthermore, the calculations based on clinical data indicate a potential toxic role of Cu(II)NKB in preeclampsia.

His6, His13, and His14 residues in Aß 1-40 peptide significantly and specifically affect oligomeric equilibria.

Oligomers of Aß peptide are implicated as the most probable causative agent in Alzheimer's disease. However, their structural properties remain elusive due to the dynamic and heterogeneous character of oligomeric species coexisting in solution. Nevertheless, new approaches, mainly based on mass spectrometry, provide unique access to these different structural forms. Using these methods, we previously showed that the N-terminal, non-amyloidogenic region of Aß is involved in the network of interactions specifically stabilizing oligomers. In the present study, we identified three histidine residues as active participants in this network. Detailed knowledge of the structural features that are potentially important for oligomer-mediated neurotoxicity is a prerequisite for the rational design of oligomerization modifiers.

The alcohol-induced conformational changes in casein micelles: a new challenge for the purification of colostrinin.

Recent advances in protein separation technology have allowed for the isolation of whey proteins and peptides of significant biological importance. In this study, we report a novel method for isolation and purification of the neuroprotective proline-rich polypeptides, also known as Colostrinin (CLN). Although CLN was first isolated from ovine colostrum and characterized as a complex of small molecular peptides, its constituents are present also in other mammal colostrums. The previous purification protocols are very tedious, time consuming, and, due to the diverse characteristics of colostrum, also very difficult to validate. Thus, the aim of this study was to develop a simple protocol with a maximum recovery rate for CLN peptides. Here we demonstrate the two-step extraction/purification method that consists of methanol extraction and ammonium sulfate precipitation as the general principles. When compared with the original material, CLN obtained by this method shows (1) similar pattern of peptides in SDS PAGE, (2) identical amino acid analysis, characterized by high content of proline (22%), a high proportion of nonpolar amino acids, a low percentage of glycine, alanine, arginine, histidine, and no tryptophan, methionine, and cysteine residues, (3) similar pattern of HPLC profiles, and (4) its ability to induce IFN gamma and TNF alpha. More importantly, the protocol for the production of high-quality CLN can be accomplished in less than a 48 h timeframe. In addition, avoidance of excessively harsh conditions preserves the structure and biological activity of the peptides.