A new method for high throughput screening has been developed based upon the inclusion of the target receptors, transmembrane receptors (cellular, nuclear or mitochondrial) in a flowing chromatographic system. In this approach, the target protein is immobilized on a solid support and the support packed into a small column. The test chemicals are passed through the column, over the immobilized target, and the time that it takes for the compounds to pass from the beginning of the column to its end is directly related to the strength of interaction between the target and the compound, i.e. the binding affinity of the ligand-receptor complex. Using this method, complex chemical and biological mixtures can be rapidly sorted between compounds that interact and do not interact with the disease-related target. At the same time, the compounds that bind to the target are themselves rapidly sorted between low, medium and high affinity binders. Thus, the method quickly provides a large amount of data with high information content. We have developed columns containing various subtypes of the nicotinic receptor. The nicotinic receptor-based columns have been used to screen tobacco smoke condensates and initial results indicate that previously unknown compounds have been identified. These compounds are being assessed for their pharmacological activity as competitive agonists and antagonists and non-competitive inhibitors. A study using non-competitive inhibitors and non-linear chromatography was conducted and demonstrated that the method can be used to identify and characterize the non-competitive inhibitors which bind in the central lumen of the receptor as well as at an extra-receptor site identified as the quinacrine binding site. Chemometric analysis was used to develop quantitative structure-activity relationships (QSAR) and the resulting equations can be used to predict the pharmacological activity of a compound. Molecular modeling studies were used to describe and predict the interactions between the nicotinic receptors and non-competitive inhibitors. The general approach has been expanded through the immobilization of SIRT6 protein onto the surface of an open tubular capillary and on the surface of magnetic beads. The SIRT6-MBs were used to extract small molecules that bind to SIRT6 from chemical and botanical mixtures. Additional SIRT6 activity assays were developed and optimized for the identification of SIRT6 activators and SIRT6 inhibitors. Using this approach, several novel SIRT6 activators have been identified from complex matrixes. The identified compounds will be tested for activity in vivo.
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