Identification of Ligand Binding Site and Protein-Protein Interaction Area
Identification of Ligand Binding Site and Protein-Protein Interaction Area [electronic resource] /
edited by Irena Roterman-Konieczna.
- X, 170 p. online resource.
- Focus on Structural Biology, 8 1571-4853 ; .
- Focus on Structural Biology, 8 .
Contributors -- Foreword -- Chapter 1 SuMo, J-A. Chemelle, E. Bettler, CH. Combet, R. Terreux, CH. Geourjon, G. Deleage -- Chapter 2 Identification of pockets on protein surface to predict protein–ligand binding sites, Binding Huang -- Chapter 3 Can the structure of the hydrophobic core determine the complexation site?, M. Banach, L. Konieczny, I. Roterman -- Chapter 4 Comparative analysis of techniques oriented on the recognition of ligand binding area in proteins, P. Alejster, M. Banach, W. Jurkowski, D. Marchewka, I. Roterman -- Chapter 5 Docking predictions of protein-protein interactions and their assessment, Joel Janin -- Chapter 6 Prediction of protein-protein binding interfaces, D. Marchewka, W. Jurkowski, M. Banach, I. Roterman -- Chapter 7 Support for Cooperative Experiments in e-Science: From Scientific Workflows to Knowledge Sharing, A. Belloum, R. Cushing, S. Koulouzis, V. Korkhov, D. Vasunin, V. Guevara-Masis, Z. Zhao, M. Bubak -- Index.
This volume presents a review of the latest numerical techniques used to identify ligand binding and protein complexation sites. It should be noted that there are many other theoretical studies devoted to predicting the activity of specific proteins and that useful protein data can be found in numerous databases. The aim of advanced computational techniques is to identify the active sites in specific proteins and moreover to suggest a generalized mechanism by which such protein-ligand (or protein-protein) interactions can be effected. Developing such tools is not an easy task – it requires extensive expertise in the area of molecular biology as well as a firm grasp of numerical modeling methods. Thus, it is often viewed as a prime candidate for interdisciplinary research.
9789400752856
10.1007/978-94-007-5285-6 doi
Medicine.
Biomedicine.
Biomedicine general.
R-RZ
610
Contributors -- Foreword -- Chapter 1 SuMo, J-A. Chemelle, E. Bettler, CH. Combet, R. Terreux, CH. Geourjon, G. Deleage -- Chapter 2 Identification of pockets on protein surface to predict protein–ligand binding sites, Binding Huang -- Chapter 3 Can the structure of the hydrophobic core determine the complexation site?, M. Banach, L. Konieczny, I. Roterman -- Chapter 4 Comparative analysis of techniques oriented on the recognition of ligand binding area in proteins, P. Alejster, M. Banach, W. Jurkowski, D. Marchewka, I. Roterman -- Chapter 5 Docking predictions of protein-protein interactions and their assessment, Joel Janin -- Chapter 6 Prediction of protein-protein binding interfaces, D. Marchewka, W. Jurkowski, M. Banach, I. Roterman -- Chapter 7 Support for Cooperative Experiments in e-Science: From Scientific Workflows to Knowledge Sharing, A. Belloum, R. Cushing, S. Koulouzis, V. Korkhov, D. Vasunin, V. Guevara-Masis, Z. Zhao, M. Bubak -- Index.
This volume presents a review of the latest numerical techniques used to identify ligand binding and protein complexation sites. It should be noted that there are many other theoretical studies devoted to predicting the activity of specific proteins and that useful protein data can be found in numerous databases. The aim of advanced computational techniques is to identify the active sites in specific proteins and moreover to suggest a generalized mechanism by which such protein-ligand (or protein-protein) interactions can be effected. Developing such tools is not an easy task – it requires extensive expertise in the area of molecular biology as well as a firm grasp of numerical modeling methods. Thus, it is often viewed as a prime candidate for interdisciplinary research.
9789400752856
10.1007/978-94-007-5285-6 doi
Medicine.
Biomedicine.
Biomedicine general.
R-RZ
610