This paper deals with the engineering multicomponent nanofunctionalization process considering fundamental physicochemical features of nanostructures such as surface energy, chemical bonds, and electrostatic interactions. It is pursued by modeling the surface nanopatterning and evaluating the proposed technique and the models. To this end, the effects of surface modifications of nanoclay on surface interactions, orientations, and final features of TiO2/Mt nanocolloidal textiles functionalization have been investigated. Various properties of cross-linkable polysiloxanes (XPs) treated samples as well as untreated samples with XPs have been compared to one another. The complete series of samples have been examined in terms of bioactivity and some physical properties, given to provide indirect evidence on the surface nanopatterning. The results disclosed a key role of the selected factors on the final features of treated surfaces. The effects have been thoroughly explained and modeled according to the fundamental physicochemical features. The developed models and associated hypotheses interestingly demonstrated a full agreement with all measured properties and were appreciably confirmed by FESEM evidence (direct evidence). Accordingly, a guideline has been developed to facilitate engineering and optimizing the pre-, main, and post-multicomponent nanofunctionalization procedures in terms of fundamental features of nanostructures and substrates for biomedical applications and other approaches.

The number of publications in the field of chemical cross-linking/mass spectrometry (MS) for deriving protein 3D structures and for probing protein/protein interactions has largely increased during the last years. MS analysis of the large cross-linking data sets requires an automated data analysis by dedicated software tools, but applying scoring procedures with statistical methods does not eliminate the fundamental problems of a misassignment of cross-linked products. In fact, we have observed a significant rate of misassigned cross-links in a number of publications, mainly due to the presence of isobaric cross-linked species, an incomplete fragmentation of cross-linked products, and low-mass accuracy fragment ion data. These false assignments will eventually lead to wrong conclusions on the structural information derived from chemical cross-linking/MS experiments. In this contribution, we examine the most common sources for misassigning cross-linked products. We propose and discuss rational criteria and suggest five guidelines that might be followed for a reliable and unambiguous identification of cross-links, independent of the software used for data analysis. In the interest of the cross-linking/MS approach, it should be ensured that only high-quality data enter the structural biology literature. Clearly, there is an urgent need to define common standards for data analysis and reporting formats of cross-linked products.

P-selectin (GMP-140, CD62P) is a member of the selectin family of cell adhesion molecules expressed on the cell surface of platelets and endothelial cells, which mediates leukocyte adhesion via carbohydrate ligands. We now report that a monoclonal antibody (mAb), recognizing the ninth consensus repeat domain of the human P-selectin molecule, enhanced the adhesion activity of neutrophils to platelets, whereas the monovalent Fab fragment of the mAb did not exert this effect. The enhancement by the mAb was thought to result from cross-linking of the P-selectin molecules. The results indicated that cross-linking adjacent to the transmembrane domain of P-selectin enhanced the cell adhesion activity.

The amino acid sequence motifs of human c-H-ras p21 involved in the interaction with guanosine nucleotides were cross-linked to in situ periodate-oxidized [alpha-32P]GDP or [alpha-32P]GTP. Site-specific reaction was achieved by cross-linking conserved lysine residues close to the G-nucleotide binding site of p21 with the 2\',3\'-dialdehyde derivatives of GDP or GTP under kinetically controlled conditions. After endoproteinase Asp-N digestion, HPLC separation of 32P-labeled peptides and N-terminal microsequence analysis, two single lysine residues, namely, K117 and K147, which are parts of the N-K-X-D and S-A-K/L consensus elements of ras proteins, respectively, were identified. No significant divergences in the position and extent of covalent modification could be detected between p21.GDP and p21.GTP. This is in contrast to Thermus thermophilus EF-Tu.GDP and EF-Tu.GTP, which were investigated with the same technique [Peter, M. E., Wittmann-Liebold, B. & Sprinzl, M. (1988) Biochemistry 27, 9132-9139] and which exhibited considerable differences in cross-linking efficiency in the GTP form as compared to the GDP form of the protein. The described affinity labeling technique of cross-linking [alpha-32P]GTP with GTP-binding proteins can be used as a general analytical method for the detection and identification of consensus elements in GTPases from different organisms.