INTEGRIN AND CADHERIN LIGANDS: INTERACTION STUDIES BY COMPUTATIONAL METHODS AND BIOAFFINITY NMR ON INTACT CELLS

On a molecular level protein \u2013 ligand interactions are central to a number of biological processes, but their investigation is inherently difficult due to several problems, especially for membrane proteins. The study of this type of interactions poses a whole set of challenges, including the characterization of the dynamic behaviour and of the conformational properties of the ligands in complex with the target macromolecules. A variety of biophysical methods have been developed to study protein \u2013 ligand interactions and several NMR spectroscopic techniques have emerged as powerful methods to identify and characterize the binding of ligands with receptor proteins. Ligand-based methods do not require labeled protein, since only the ligand NMR signals are detected and only a small amount of protein is required. These techniques are particularly useful in the medium\u2013low affinity range and, therefore they have been adopted to detect ligand interactions in various systems. Among the ligand-based NMR techniques, Saturation Transfer Difference (STD) and transferred-NOE focus on the NMR signals of the ligand and utilize NOE effects between protein and ligand. They are used for: i) the definition of the bioactive conformation of the ligand in the bound state (tr-NOESY), ii) the identification and characterization of the binding mode of the ligand to the receptor with epitope mapping of the ligand itself (STD). The use of the technique is limited to molecules that exhibit a dissociation constant Kd between 10-3 M and 10-7 M. During my PhD, I had the highly qualifying opportunity to grasp these new potent NMR methods, and to apply them for assessing the interactions of cell surface proteins with peptidomimetics. Since membrane proteins, such as integrins, change their conformation if extracted from their environment, it is clear the importance of working in the biophysical neighbourhood of the membrane itself and not in an isotropic extracellular medium. For this reason, when appropriate to the project, I have carried out NMR experiments using intact cells overexpressing the proteins of interest. Specifically, two main topics have been addressed: 1. The first and second year of my PhD have been mainly focused on the conformational study of peptidomimetic integrin ligands and on the investigation of their interaction with platelets and cancer cell overexpressing integrins on their membrane. This study has been developed within the framework of a PRIN project (MIUR-PRIN project 2010NRREPL \u201cSynthesis and Biomedical Applications of Tumor-Targeting Peptidomimetics\u201d) in collaboration with the research groups of Proff. Gennari and Piarulli (University of Insubria) as regards the synthetic activities and with the group of Dr. Belvisi as regards the computational and design studies. 2. The second part of my PhD was mainly focused on cadherins, a class of cell adhesion proteins that promote homophilic interactions. This work is at an early stage and has been developed within the framework of a FIRB project coordinated by Dr. Civera (MIUR-FIRB \u201cFuturo in Ricerca\u201d RBFR088ITV \u201cComputer-aided design, synthesis and biological evaluation of peptidomimetics targeting N-cadherin as anticancer agents\u201d). The NMR study has been aimed at obtaining a thorough understanding of the interaction of peptidomimetic molecules with isolated cadherin constructs containing relevant extracellular domains

Application of NMR methods to the study of the interaction of natural products with biomolecular receptors

8 páginas, 7 figuras -- PAGS nros. 1118-1125In this review, we present applications of NMR spectroscopy as a potent tool for the study of molecular interactions. It is clear that a variety of NMR methods may be employed to deduce key features of ligand–receptor molecular recognition processes, looking at the process from the perspective of the receptor or the ligand. We have not provided an exhaustive review, but we have tried to focus on describing the different aspects within this research topic. We have therefore selected examples accordingly, depending on the particular problem under study or the application/development of protocols to circumvent the technical problems that may be found when working in this fieldWe thank the Ministry of Science and Innovation of Spain for financial support (Grant CTQ2009-08536) and all the colleagues that have collaborated with us over yearsPeer reviewe