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No matter the source of compounds, drug discovery campaigns focused directly on the target are entirely dependent on a consistent stream of reliable data that reports on how a putative ligand interacts with the protein of interest. The data will derive from many sources including enzyme assays and many types of biophysical binding assays such as TR-FRET, SPR, thermophoresis and many others. Each method has its strengths and weaknesses, but none is as information rich and broadly applicable as NMR. Here we provide a number of examples of the utility of NMR for enabling and providing ongoing support for the early pre-clinical phase of small molecule drug discovery efforts. The examples have been selected for their usefulness in a commercial setting, with full understanding of the need for speed, cost-effectiveness and ease of implementation.

The topology of the GCAP-2 homodimer was investigated by chemical cross-linking and high resolution mass spectrometry. Complementary conducted size-exclusion chromatography and analytical ultracentrifugation studies indicated that GCAP-2 forms a homodimer both in the absence and in the presence of Ca 2+ . In-depth MS and MS/MS analysis of the cross-linked products was aided by 15   N -labeled GCAP-2. The use of isotope-labeled protein delivered reliable structural information on the GCAP-2 homodimer, enabling an unambiguous discrimination between cross-links within one monomer (intramolecular) or between two subunits (intermolecular). The limited number of cross-links obtained in the Ca 2+ -bound state allowed us to deduce a defined homodimeric GCAP-2 structure by a docking and molecular dynamics approach. In the Ca 2+ -free state, GCAP-2 is more flexible as indicated by the higher number of cross-links. We consider stable isotope-labeling to be indispensable for deriving reliable structural information from chemical cross-linking data of multi-subunit protein assemblies. Figure ᇵ

Glycosaminoglycans (GAGs) play an important role in many biological processes in the extracellular matrix. In a theoretical approach, structures of monosaccharide building blocks of natural GAGs and their sulfated derivatives were optimized by a B3LYP6311ppdd//B3LYP/6-31+G(d) method. The dependence of the observed conformational properties on the applied methodology is described. NMR chemical shifts and proton-proton spin-spin coupling constants were calculated using the GIAO approach and analyzed in terms of the method's accuracy and sensitivity towards the influence of sulfation, O1-methylation, conformations of sugar ring, and ω dihedral angle. The net sulfation of the monosaccharides was found to be correlated with the 1H chemical shifts in the methyl group of the N-acetylated saccharides both theoretically and experimentally. The ω dihedral angle conformation populations of free monosaccharides and monosaccharide blocks within polymeric GAG molecules were calculated by a molecular dynamics approach using the GLYCAM06 force field and compared with the available NMR and quantum mechanical data. Qualitative trends for the impact of sulfation and ring conformation on the chemical shifts and proton-proton spin-spin coupling constants were obtained and discussed in terms of the potential and limitations of the computational methodology used to be complementary to NMR experiments and to assist in experimental data assignment.

Almost complete assignment of backbone ^sup 1^H, ^sup 13^C, ^sup 15^N and side chain ^sup 13^C[beta] resonances for the immune-regulatory cytokine IL-10 is reported. The protein was overexpressed in Escherichia coli and was refolded from inclusion bodies. The point mutation C149Y was introduced to suppress incorrect disulfide bond formation and to improve protein refolding.[PUBLICATION ABSTRACT]

Almost complete assignment of backbone 1 H, 13 C, 15 N and side chain 13 Cβ resonances for the immune-regulatory cytokine IL-10 is reported. The protein was overexpressed in Escherichia coli and was refolded from inclusion bodies. The point mutation C149Y was introduced to suppress incorrect disulfide bond formation and to improve protein refolding.

Guanylate cyclase-activating proteins (GCAPs) are neuronal Ca 2+ sensors that play a central role in shaping the photoreceptor light response and in light adaptation through the Ca 2+ -dependent regulation of the transmembrane retinal guanylate cyclase. GCAPs are N-terminally myristoylated, and the role of the myristoyl moiety is not yet fully understood. While protein lipid chains typically represent membrane anchors, the crystal structure of GCAP-1 showed that the myristoyl chain of the protein is completely buried within a hydrophobic pocket of the protein, which stabilizes the protein structure. Therefore, we address the question of the localization of the myristoyl group of GCAP-2 in the absence and in the presence of lipid membranes as well as DPC detergents (as a membrane substitute amenable to solution state NMR). We investigate membrane binding of both myristoylated and nonmyristoylated GCAP-2 and study the structure and dynamics of the myristoyl moiety of GCAP-2 in the presence of POPC membranes. Further, we address structural alterations within the myristoylated N-terminus of GCAP-2 in the presence of membrane mimetics. Our results suggest that upon membrane binding the myristoyl group is released from the protein interior and inserts into the lipid bilayer.