The binding of advanced glycation end products to cell surfaces can be measured using bead-reconstituted cellular membrane proteins.

Advanced glycation end products (AGEs) that arise from the reaction of sugars with protein side chains are supposed to be involved in the pathogenesis of several diseases and therefore the effects of AGEs on cells are the objective of numerous investigations. Although different cellular responses to AGEs can be measured in cell culture studies, knowledge about the nature of AGE-binding and the involved cell surface receptors is poor. The measurement of AGE-binding to cell surfaces bears the potential to gain a deeper understanding about the nature of AGE-binding to cell surface proteins and could be applied as a preliminary test before performing cell culture studies on AGE effects. Herein, a new material and method for the detection of AGE-binding to cell surfaces is introduced, which has the potential to facilitate the detection of binding. In the present paper, the detection of AGE-binding to cell surface proteins using an artificial system of cellular membrane proteins reconstituted on beads (TRANSIL CaCo-2) is described. The binding of a BSA-AGE derived from a 37 degrees C incubation with 500 mM Glc (BSA-Glc 500) and the corresponding control to this artificial system was compared with the binding to intact cells and was found to be in good agreement. Additionally, the K(d) for the binding of the BSA-Glc 500 used in the study to CaCo-2 surfaces was determined using FITC-labelled samples in a flow cytometric approach. Competitive binding studies were performed using a set of non-labelled BSA-AGEs to compete with FITC-labelled BSA-Glc 500 for the cell surface binding sites. The binding was found to be inhibited to different extends, virtually depending on the degree of arginine modifications within the modified protein used for competition. Additionally, the effects of all AGEs used in the study on CaCo-2 cells was measured using the detection of reactive oxygen species (ROS), which are known to be induced as a primary result of AGE-receptor binding. The induction of ROS was found to linearly correlate to the capacity of the individual AGE to displace FITC-labelled BSA-Glc 500 in competitive binding studies. Therefore, the data indicate, that at least in case of CaCo-2 cells the detection of cell surface binding can serve as a reliable preliminary test for a potential cell-damaging effect of AGEs.

ADME related profiling in 96 and 384 well plate format--a novel and robust HT-assay for the determination of lipophilicity and serum albumin binding.

The failure of about half of the drug candidates is associated with poor pharmacokinetic properties leading to a huge loss of time and money [1]. Early profiling of drug like properties provides important information in order to screen out insoluble, poorly absorbed and toxic compounds. Today, large compound libraries have to be screened, and of course the total number of compounds will rise over the next years leading to a growing demand for fully automated assays. A balance between quality, speed, throughput, cost and information content can be accomplished by the careful selection of assays and experimental conditions. Here we describe a novel 384 well format assay for two important ADME related descriptors (lipophilicity and serum protein binding) as input parameters for a precise prediction of fraction absorbed, blood/organ distribution coefficients and permeability, in order to maximize the information about a compound at an early stage of discovery.

Two analytical methods to study the interaction of AGEs with cell surface proteins.

Advanced glycation end products (AGEs) are sugar-modified proteins that are known to appear in vivo and are suspected to be involved in the pathogenesis of several diseases. Although different cellular responses to AGEs can be measured in cell culture studies, knowledge about the nature of AGE-binding and their cell surface receptors is poor. In the present paper a method for the purification of AGE-binding proteins from membrane fractions derived from different rat organs as well as a method for assaying the binding of fluorescein labelled AGEs to the surface of cells of different cell lines are described. The presence of more than 10 proteins interacting with AGEs could be shown in membrane fractions obtained from rat organs. Additionally, binding of AGE-modified BSA to different cells could be shown using fluorescence-labelled ligands in a flow cytometric approach. The presented methods provide an option to isolate AGE-interacting proteins which is a precondition for the identification of these proteins. Furthermore, the measurement of AGE-binding to cell surfaces bears the potential to gain a deeper understanding about the nature of AGE-binding to cell surface proteins and might be applied as a preliminary test before performing cell culture studies about AGE effects.