Search

Your search keyword '"Janin, Joël"' showing total 32 results
Start Over Author "Janin, Joël" Publication Type Electronic Resources
32 results on '"Janin, Joël"'

1. Community-wide evaluation of methods for predicting the effect of mutations on protein-protein interactions

Author

Moretti, Rocco, Fleishman, Sarel J, Agius, Rudi, Torchala, Mieczyslaw, Bates, Paul A, Kastritis, Panagiotis L, Garcia Lopes Maia Rodrigues, João, Trellet, Mikaël, Bonvin, Alexandre M J J, Cui, Meng, Rooman, Marianne, Gillis, Dimitri, Dehouck, Yves, Moal, Iain, Romero-Durana, Miguel, Perez-Cano, Laura, Pallara, Chiara, Jimenez, Brian, Fernandez-Recio, Juan, Flores, Samuel, Pacella, Michael, Praneeth Kilambi, Krishna, Gray, Jeffrey J, Popov, Petr, Grudinin, Sergei, Esquivel-Rodríguez, Juan, Kihara, Daisuke, Zhao, Nan, Korkin, Dmitry, Zhu, Xiaolei, Demerdash, Omar N A, Mitchell, Julie C, Kanamori, Eiji, Tsuchiya, Yuko, Nakamura, Haruki, Lee, Hasup, Park, Hahnbeom, Seok, Chaok, Sarmiento, Jamica, Liang, Shide, Teraguchi, Shusuke, Standley, Daron M, Shimoyama, Hiromitsu, Terashi, Genki, Takeda-Shitaka, Mayuko, Iwadate, Mitsuo, Umeyama, Hideaki, Beglov, Dmitri, Hall, David R, Kozakov, Dima, Vajda, Sandor, Pierce, Brian G, Hwang, Howook, Vreven, Thom, Weng, Zhiping, Huang, Yangyu, Li, Haotian, Yang, Xiufeng, Ji, Xiaofeng, Liu, Shiyong, Xiao, Yi, Zacharias, Martin, Qin, Sanbo, Zhou, Huan-Xiang, Huang, Sheng-You, Zou, Xiaoqin, Velankar, Sameer, Janin, Joël, Wodak, Shoshana J, Baker, David, Moretti, Rocco, Fleishman, Sarel J, Agius, Rudi, Torchala, Mieczyslaw, Bates, Paul A, Kastritis, Panagiotis L, Garcia Lopes Maia Rodrigues, João, Trellet, Mikaël, Bonvin, Alexandre M J J, Cui, Meng, Rooman, Marianne, Gillis, Dimitri, Dehouck, Yves, Moal, Iain, Romero-Durana, Miguel, Perez-Cano, Laura, Pallara, Chiara, Jimenez, Brian, Fernandez-Recio, Juan, Flores, Samuel, Pacella, Michael, Praneeth Kilambi, Krishna, Gray, Jeffrey J, Popov, Petr, Grudinin, Sergei, Esquivel-Rodríguez, Juan, Kihara, Daisuke, Zhao, Nan, Korkin, Dmitry, Zhu, Xiaolei, Demerdash, Omar N A, Mitchell, Julie C, Kanamori, Eiji, Tsuchiya, Yuko, Nakamura, Haruki, Lee, Hasup, Park, Hahnbeom, Seok, Chaok, Sarmiento, Jamica, Liang, Shide, Teraguchi, Shusuke, Standley, Daron M, Shimoyama, Hiromitsu, Terashi, Genki, Takeda-Shitaka, Mayuko, Iwadate, Mitsuo, Umeyama, Hideaki, Beglov, Dmitri, Hall, David R, Kozakov, Dima, Vajda, Sandor, Pierce, Brian G, Hwang, Howook, Vreven, Thom, Weng, Zhiping, Huang, Yangyu, Li, Haotian, Yang, Xiufeng, Ji, Xiaofeng, Liu, Shiyong, Xiao, Yi, Zacharias, Martin, Qin, Sanbo, Zhou, Huan-Xiang, Huang, Sheng-You, Zou, Xiaoqin, Velankar, Sameer, Janin, Joël, Wodak, Shoshana J, and Baker, David

Abstract

Community-wide blind prediction experiments such as CAPRI and CASP provide an objective measure of the current state of predictive methodology. Here we describe a community-wide assessment of methods to predict the effects of mutations on protein-protein interactions. Twenty-two groups predicted the effects of comprehensive saturation mutagenesis for two designed influenza hemagglutinin binders and the results were compared with experimental yeast display enrichment data obtained using deep sequencing. The most successful methods explicitly considered the effects of mutation on monomer stability in addition to binding affinity, carried out explicit side-chain sampling and backbone relaxation, evaluated packing, electrostatic, and solvation effects, and correctly identified around a third of the beneficial mutations. Much room for improvement remains for even the best techniques, and large-scale fitness landscapes should continue to provide an excellent test bed for continued evaluation of both existing and new prediction methodologies.

Published
2013

2. Community-wide evaluation of methods for predicting the effect of mutations on protein-protein interactions

Author

Sub NMR Spectroscopy, NMR Spectroscopy, Moretti, Rocco, Fleishman, Sarel J, Agius, Rudi, Torchala, Mieczyslaw, Bates, Paul A, Kastritis, Panagiotis L, Garcia Lopes Maia Rodrigues, João, Trellet, Mikaël, Bonvin, Alexandre M J J, Cui, Meng, Rooman, Marianne, Gillis, Dimitri, Dehouck, Yves, Moal, Iain, Romero-Durana, Miguel, Perez-Cano, Laura, Pallara, Chiara, Jimenez, Brian, Fernandez-Recio, Juan, Flores, Samuel, Pacella, Michael, Praneeth Kilambi, Krishna, Gray, Jeffrey J, Popov, Petr, Grudinin, Sergei, Esquivel-Rodríguez, Juan, Kihara, Daisuke, Zhao, Nan, Korkin, Dmitry, Zhu, Xiaolei, Demerdash, Omar N A, Mitchell, Julie C, Kanamori, Eiji, Tsuchiya, Yuko, Nakamura, Haruki, Lee, Hasup, Park, Hahnbeom, Seok, Chaok, Sarmiento, Jamica, Liang, Shide, Teraguchi, Shusuke, Standley, Daron M, Shimoyama, Hiromitsu, Terashi, Genki, Takeda-Shitaka, Mayuko, Iwadate, Mitsuo, Umeyama, Hideaki, Beglov, Dmitri, Hall, David R, Kozakov, Dima, Vajda, Sandor, Pierce, Brian G, Hwang, Howook, Vreven, Thom, Weng, Zhiping, Huang, Yangyu, Li, Haotian, Yang, Xiufeng, Ji, Xiaofeng, Liu, Shiyong, Xiao, Yi, Zacharias, Martin, Qin, Sanbo, Zhou, Huan-Xiang, Huang, Sheng-You, Zou, Xiaoqin, Velankar, Sameer, Janin, Joël, Wodak, Shoshana J, Baker, David, Sub NMR Spectroscopy, NMR Spectroscopy, Moretti, Rocco, Fleishman, Sarel J, Agius, Rudi, Torchala, Mieczyslaw, Bates, Paul A, Kastritis, Panagiotis L, Garcia Lopes Maia Rodrigues, João, Trellet, Mikaël, Bonvin, Alexandre M J J, Cui, Meng, Rooman, Marianne, Gillis, Dimitri, Dehouck, Yves, Moal, Iain, Romero-Durana, Miguel, Perez-Cano, Laura, Pallara, Chiara, Jimenez, Brian, Fernandez-Recio, Juan, Flores, Samuel, Pacella, Michael, Praneeth Kilambi, Krishna, Gray, Jeffrey J, Popov, Petr, Grudinin, Sergei, Esquivel-Rodríguez, Juan, Kihara, Daisuke, Zhao, Nan, Korkin, Dmitry, Zhu, Xiaolei, Demerdash, Omar N A, Mitchell, Julie C, Kanamori, Eiji, Tsuchiya, Yuko, Nakamura, Haruki, Lee, Hasup, Park, Hahnbeom, Seok, Chaok, Sarmiento, Jamica, Liang, Shide, Teraguchi, Shusuke, Standley, Daron M, Shimoyama, Hiromitsu, Terashi, Genki, Takeda-Shitaka, Mayuko, Iwadate, Mitsuo, Umeyama, Hideaki, Beglov, Dmitri, Hall, David R, Kozakov, Dima, Vajda, Sandor, Pierce, Brian G, Hwang, Howook, Vreven, Thom, Weng, Zhiping, Huang, Yangyu, Li, Haotian, Yang, Xiufeng, Ji, Xiaofeng, Liu, Shiyong, Xiao, Yi, Zacharias, Martin, Qin, Sanbo, Zhou, Huan-Xiang, Huang, Sheng-You, Zou, Xiaoqin, Velankar, Sameer, Janin, Joël, Wodak, Shoshana J, and Baker, David

Published
2013

3. Community-wide evaluation of methods for predicting the effect of mutations on protein-protein interactions

Author

Sub NMR Spectroscopy, NMR Spectroscopy, Moretti, Rocco, Fleishman, Sarel J, Agius, Rudi, Torchala, Mieczyslaw, Bates, Paul A, Kastritis, Panagiotis L, Garcia Lopes Maia Rodrigues, João, Trellet, Mikaël, Bonvin, Alexandre M J J, Cui, Meng, Rooman, Marianne, Gillis, Dimitri, Dehouck, Yves, Moal, Iain, Romero-Durana, Miguel, Perez-Cano, Laura, Pallara, Chiara, Jimenez, Brian, Fernandez-Recio, Juan, Flores, Samuel, Pacella, Michael, Praneeth Kilambi, Krishna, Gray, Jeffrey J, Popov, Petr, Grudinin, Sergei, Esquivel-Rodríguez, Juan, Kihara, Daisuke, Zhao, Nan, Korkin, Dmitry, Zhu, Xiaolei, Demerdash, Omar N A, Mitchell, Julie C, Kanamori, Eiji, Tsuchiya, Yuko, Nakamura, Haruki, Lee, Hasup, Park, Hahnbeom, Seok, Chaok, Sarmiento, Jamica, Liang, Shide, Teraguchi, Shusuke, Standley, Daron M, Shimoyama, Hiromitsu, Terashi, Genki, Takeda-Shitaka, Mayuko, Iwadate, Mitsuo, Umeyama, Hideaki, Beglov, Dmitri, Hall, David R, Kozakov, Dima, Vajda, Sandor, Pierce, Brian G, Hwang, Howook, Vreven, Thom, Weng, Zhiping, Huang, Yangyu, Li, Haotian, Yang, Xiufeng, Ji, Xiaofeng, Liu, Shiyong, Xiao, Yi, Zacharias, Martin, Qin, Sanbo, Zhou, Huan-Xiang, Huang, Sheng-You, Zou, Xiaoqin, Velankar, Sameer, Janin, Joël, Wodak, Shoshana J, Baker, David, Sub NMR Spectroscopy, NMR Spectroscopy, Moretti, Rocco, Fleishman, Sarel J, Agius, Rudi, Torchala, Mieczyslaw, Bates, Paul A, Kastritis, Panagiotis L, Garcia Lopes Maia Rodrigues, João, Trellet, Mikaël, Bonvin, Alexandre M J J, Cui, Meng, Rooman, Marianne, Gillis, Dimitri, Dehouck, Yves, Moal, Iain, Romero-Durana, Miguel, Perez-Cano, Laura, Pallara, Chiara, Jimenez, Brian, Fernandez-Recio, Juan, Flores, Samuel, Pacella, Michael, Praneeth Kilambi, Krishna, Gray, Jeffrey J, Popov, Petr, Grudinin, Sergei, Esquivel-Rodríguez, Juan, Kihara, Daisuke, Zhao, Nan, Korkin, Dmitry, Zhu, Xiaolei, Demerdash, Omar N A, Mitchell, Julie C, Kanamori, Eiji, Tsuchiya, Yuko, Nakamura, Haruki, Lee, Hasup, Park, Hahnbeom, Seok, Chaok, Sarmiento, Jamica, Liang, Shide, Teraguchi, Shusuke, Standley, Daron M, Shimoyama, Hiromitsu, Terashi, Genki, Takeda-Shitaka, Mayuko, Iwadate, Mitsuo, Umeyama, Hideaki, Beglov, Dmitri, Hall, David R, Kozakov, Dima, Vajda, Sandor, Pierce, Brian G, Hwang, Howook, Vreven, Thom, Weng, Zhiping, Huang, Yangyu, Li, Haotian, Yang, Xiufeng, Ji, Xiaofeng, Liu, Shiyong, Xiao, Yi, Zacharias, Martin, Qin, Sanbo, Zhou, Huan-Xiang, Huang, Sheng-You, Zou, Xiaoqin, Velankar, Sameer, Janin, Joël, Wodak, Shoshana J, and Baker, David

Published
2013

4. Community-wide evaluation of methods for predicting the effect of mutations on protein-protein interactions

Author

Sub NMR Spectroscopy, NMR Spectroscopy, Moretti, Rocco, Fleishman, Sarel J, Agius, Rudi, Torchala, Mieczyslaw, Bates, Paul A, Kastritis, Panagiotis L, Garcia Lopes Maia Rodrigues, João, Trellet, Mikaël, Bonvin, Alexandre M J J, Cui, Meng, Rooman, Marianne, Gillis, Dimitri, Dehouck, Yves, Moal, Iain, Romero-Durana, Miguel, Perez-Cano, Laura, Pallara, Chiara, Jimenez, Brian, Fernandez-Recio, Juan, Flores, Samuel, Pacella, Michael, Praneeth Kilambi, Krishna, Gray, Jeffrey J, Popov, Petr, Grudinin, Sergei, Esquivel-Rodríguez, Juan, Kihara, Daisuke, Zhao, Nan, Korkin, Dmitry, Zhu, Xiaolei, Demerdash, Omar N A, Mitchell, Julie C, Kanamori, Eiji, Tsuchiya, Yuko, Nakamura, Haruki, Lee, Hasup, Park, Hahnbeom, Seok, Chaok, Sarmiento, Jamica, Liang, Shide, Teraguchi, Shusuke, Standley, Daron M, Shimoyama, Hiromitsu, Terashi, Genki, Takeda-Shitaka, Mayuko, Iwadate, Mitsuo, Umeyama, Hideaki, Beglov, Dmitri, Hall, David R, Kozakov, Dima, Vajda, Sandor, Pierce, Brian G, Hwang, Howook, Vreven, Thom, Weng, Zhiping, Huang, Yangyu, Li, Haotian, Yang, Xiufeng, Ji, Xiaofeng, Liu, Shiyong, Xiao, Yi, Zacharias, Martin, Qin, Sanbo, Zhou, Huan-Xiang, Huang, Sheng-You, Zou, Xiaoqin, Velankar, Sameer, Janin, Joël, Wodak, Shoshana J, Baker, David, Sub NMR Spectroscopy, NMR Spectroscopy, Moretti, Rocco, Fleishman, Sarel J, Agius, Rudi, Torchala, Mieczyslaw, Bates, Paul A, Kastritis, Panagiotis L, Garcia Lopes Maia Rodrigues, João, Trellet, Mikaël, Bonvin, Alexandre M J J, Cui, Meng, Rooman, Marianne, Gillis, Dimitri, Dehouck, Yves, Moal, Iain, Romero-Durana, Miguel, Perez-Cano, Laura, Pallara, Chiara, Jimenez, Brian, Fernandez-Recio, Juan, Flores, Samuel, Pacella, Michael, Praneeth Kilambi, Krishna, Gray, Jeffrey J, Popov, Petr, Grudinin, Sergei, Esquivel-Rodríguez, Juan, Kihara, Daisuke, Zhao, Nan, Korkin, Dmitry, Zhu, Xiaolei, Demerdash, Omar N A, Mitchell, Julie C, Kanamori, Eiji, Tsuchiya, Yuko, Nakamura, Haruki, Lee, Hasup, Park, Hahnbeom, Seok, Chaok, Sarmiento, Jamica, Liang, Shide, Teraguchi, Shusuke, Standley, Daron M, Shimoyama, Hiromitsu, Terashi, Genki, Takeda-Shitaka, Mayuko, Iwadate, Mitsuo, Umeyama, Hideaki, Beglov, Dmitri, Hall, David R, Kozakov, Dima, Vajda, Sandor, Pierce, Brian G, Hwang, Howook, Vreven, Thom, Weng, Zhiping, Huang, Yangyu, Li, Haotian, Yang, Xiufeng, Ji, Xiaofeng, Liu, Shiyong, Xiao, Yi, Zacharias, Martin, Qin, Sanbo, Zhou, Huan-Xiang, Huang, Sheng-You, Zou, Xiaoqin, Velankar, Sameer, Janin, Joël, Wodak, Shoshana J, and Baker, David

Published
2013

5. Critical assessment of predicted interactions at atomic resolution

Author

van Helden, Jacques, Wodak, Shoshana, Droogmans, Louis, Prévost, Martine, Janin, Joël, Ledent, Valérie, Raussens, Vincent, Mendez Giraldez, Raul, van Helden, Jacques, Wodak, Shoshana, Droogmans, Louis, Prévost, Martine, Janin, Joël, Ledent, Valérie, Raussens, Vincent, and Mendez Giraldez, Raul

Abstract

Molecular Biology has allowed the characterization and manipulation of the molecules of life in the wet lab. Also the structures of those macromolecules are being continuously elucidated. During the last decades of the past century, there was an increasing interest to study how the different genes are organized into different organisms (‘genomes’) and how those genes are expressed into proteins to achieve their functions. Currently the sequences for many genes over several genomes have been determined. In parallel, the efforts to have the structure of the proteins coded by those genes go on. However it is experimentally much harder to obtain the structure of a protein, rather than just its sequence. For this reason, the number of protein structures available in databases is an order of magnitude or so lower than protein sequences. Furthermore, in order to understand how living organisms work at molecular level we need the information about the interaction of those proteins. Elucidating the structure of protein macromolecular assemblies is still more difficult. To that end, the use of computers to predict the structure of these complexes has gained interest over the last decades.The main subject of this thesis is the evaluation of current available computational methods to predict protein – protein interactions and build an atomic model of the complex. The core of the thesis is the evaluation protocol I have developed at Service de Conformation des Macromolécules Biologiques et de Bioinformatique, Université Libre de Bruxelles, and its computer implementation. This method has been massively used to evaluate the results on blind protein – protein interaction prediction in the context of the world-wide experiment CAPRI, which have been thoroughly reviewed in several publications [1-3]. In this experiment the structure of a protein complex (‘the target’) had to be modeled starting from the coordinates of the isolated molecules, prior to the release of the structure o, Doctorat en Sciences, info:eu-repo/semantics/nonPublished

Published
2007

6. Critical assessment of predicted interactions at atomic resolution

Author

van Helden, Jacques, Wodak, Shoshana, Droogmans, Louis, Prévost, Martine, Janin, Joël, Ledent, Valérie, Raussens, Vincent, Mendez Giraldez, Raul, van Helden, Jacques, Wodak, Shoshana, Droogmans, Louis, Prévost, Martine, Janin, Joël, Ledent, Valérie, Raussens, Vincent, and Mendez Giraldez, Raul

Abstract

Molecular Biology has allowed the characterization and manipulation of the molecules of life in the wet lab. Also the structures of those macromolecules are being continuously elucidated. During the last decades of the past century, there was an increasing interest to study how the different genes are organized into different organisms (‘genomes’) and how those genes are expressed into proteins to achieve their functions. Currently the sequences for many genes over several genomes have been determined. In parallel, the efforts to have the structure of the proteins coded by those genes go on. However it is experimentally much harder to obtain the structure of a protein, rather than just its sequence. For this reason, the number of protein structures available in databases is an order of magnitude or so lower than protein sequences. Furthermore, in order to understand how living organisms work at molecular level we need the information about the interaction of those proteins. Elucidating the structure of protein macromolecular assemblies is still more difficult. To that end, the use of computers to predict the structure of these complexes has gained interest over the last decades.The main subject of this thesis is the evaluation of current available computational methods to predict protein – protein interactions and build an atomic model of the complex. The core of the thesis is the evaluation protocol I have developed at Service de Conformation des Macromolécules Biologiques et de Bioinformatique, Université Libre de Bruxelles, and its computer implementation. This method has been massively used to evaluate the results on blind protein – protein interaction prediction in the context of the world-wide experiment CAPRI, which have been thoroughly reviewed in several publications [1-3]. In this experiment the structure of a protein complex (‘the target’) had to be modeled starting from the coordinates of the isolated molecules, prior to the release of the structure o, Doctorat en Sciences, info:eu-repo/semantics/nonPublished

Published
2007

7. CAPRI: A critical assessment of PRedicted interactions

Author

Janin, Joël, Henrick, Kim, Moult, John, Eyck, Lynn Ten, Sternberg, Michael J.E., Vajda, Sandor, Vakser, Ilya, Wodak, Shoshana, Janin, Joël, Henrick, Kim, Moult, John, Eyck, Lynn Ten, Sternberg, Michael J.E., Vajda, Sandor, Vakser, Ilya, and Wodak, Shoshana

Abstract

SCOPUS: ar.j, FLWIN, info:eu-repo/semantics/published

Published
2003

8. CAPRI: A critical assessment of PRedicted interactions

Author

Janin, Joël, Henrick, Kim, Moult, John, Eyck, Lynn Ten, Sternberg, Michael J.E., Vajda, Sandor, Vakser, Ilya, Wodak, Shoshana, Janin, Joël, Henrick, Kim, Moult, John, Eyck, Lynn Ten, Sternberg, Michael J.E., Vajda, Sandor, Vakser, Ilya, and Wodak, Shoshana

Abstract

SCOPUS: ar.j, FLWIN, info:eu-repo/semantics/published

Published
2003

15. The quaternary structure of carbonmonoxy hemoglobin ypsilanti

Author

Janin, Joël, Wodak, Shoshana, Janin, Joël, and Wodak, Shoshana

Abstract

We present a geometric analysis of the allosteric interface in the new Y state quaternary structure observed in liganded mutant hemoglobin Ypsilanti (β99 Asp → Tyr) by Smith, F.R. Lattman, E.E. Carter, C.W. Jr. (Proteins 10:81–91, 1991). The classical T to R quaternary structure change being a rotation of αβ dimers about an axis which is approximately parallel to the dimer axis of pseudosym‐metry, the new quaternary structure is obtained by applying to R an additional rotation about an axis orthogonal to the first. This suggests that Y is a modified R state rather than an intermediate on the T to R pathway. Computer docking experiments designed to simulate the quaternary structure change support this suggestion. © 1993 Wiley‐Liss, Inc. Copyright © 1993 Wiley‐Liss, Inc., SCOPUS: ar.j, FLWNA, info:eu-repo/semantics/published

Published
1993

16. Protein engineering of xylose (glucose) isomerase from Actinoplanes missouriensis. 2. Site-directed mutagenesis of the xylose binding site

Author

Lambeir, Anne-Marie, Lauwereys, Marc, Stanssens, Patrick, Mrabet, Nadir T., Snauwaert, Johan, Van Tilbeurgh, Herman, Matthyssens, Gaston, Lasters, Ignace, De Maeyer, Marc, Wodak, Shoshana, Jenkins, John, Chiadmi, Mohamed, Janin, Joël, Lambeir, Anne-Marie, Lauwereys, Marc, Stanssens, Patrick, Mrabet, Nadir T., Snauwaert, Johan, Van Tilbeurgh, Herman, Matthyssens, Gaston, Lasters, Ignace, De Maeyer, Marc, Wodak, Shoshana, Jenkins, John, Chiadmi, Mohamed, and Janin, Joël

Abstract

SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1992

17. Protein engineering of xylose (glucose) isomerase from actinoplanes missouriensis. 1. Crystallography and site-directed mutagenesis of metal binding sites

Author

Jenkins, John, Janin, Joël, Rey, Felix, Chiadmi, Mohamed, Van Tilbeurgh, Herman, Lasters, Ignace, De Maeyer, Marc, Chvalun, Sergei, Wodak, Shoshana, Lauwereys, Marc, Stanssens, Patrick, Mrabet, Nadir T., Snauwaert, Johan, Matthyssens, Gaston, Lambeir, Anne-Marie, Jenkins, John, Janin, Joël, Rey, Felix, Chiadmi, Mohamed, Van Tilbeurgh, Herman, Lasters, Ignace, De Maeyer, Marc, Chvalun, Sergei, Wodak, Shoshana, Lauwereys, Marc, Stanssens, Patrick, Mrabet, Nadir T., Snauwaert, Johan, Matthyssens, Gaston, and Lambeir, Anne-Marie

Abstract

SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1992

18. Arginine residues as stabilizing elements in proteins

Author

Mrabet, Nadir T., Van Den Broeck, Annemie, Van Brande, Ilse Den, Stanssens, Patrick, Laroche, Yves, Lambeir, Anne-Marie, Matthijssens, Gaston, Jenkins, John, Chiadmi, Mohamed, Van Tilbeurgh, Herman, Rey, Felix, Janin, Joël, Quax, Wim J., Lasters, Ignace, De Maeyer, Marc, Wodak, Shoshana, Mrabet, Nadir T., Van Den Broeck, Annemie, Van Brande, Ilse Den, Stanssens, Patrick, Laroche, Yves, Lambeir, Anne-Marie, Matthijssens, Gaston, Jenkins, John, Chiadmi, Mohamed, Van Tilbeurgh, Herman, Rey, Felix, Janin, Joël, Quax, Wim J., Lasters, Ignace, De Maeyer, Marc, and Wodak, Shoshana

Abstract

SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1992

19. Protein engineering of xylose (glucose) isomerase from Actinoplanes missouriensis. 2. Site-directed mutagenesis of the xylose binding site

Author

Lambeir, Anne-Marie, Lauwereys, Marc, Stanssens, Patrick, Mrabet, Nadir T., Snauwaert, Johan, Van Tilbeurgh, Herman, Matthyssens, Gaston, Lasters, Ignace, De Maeyer, Marc, Wodak, Shoshana, Jenkins, John, Chiadmi, Mohamed, Janin, Joël, Lambeir, Anne-Marie, Lauwereys, Marc, Stanssens, Patrick, Mrabet, Nadir T., Snauwaert, Johan, Van Tilbeurgh, Herman, Matthyssens, Gaston, Lasters, Ignace, De Maeyer, Marc, Wodak, Shoshana, Jenkins, John, Chiadmi, Mohamed, and Janin, Joël

Abstract

SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1992

20. Protein engineering of xylose (glucose) isomerase from actinoplanes missouriensis. 1. Crystallography and site-directed mutagenesis of metal binding sites

Author

Jenkins, John, Janin, Joël, Rey, Felix, Chiadmi, Mohamed, Van Tilbeurgh, Herman, Lasters, Ignace, De Maeyer, Marc, Chvalun, Sergei, Wodak, Shoshana, Lauwereys, Marc, Stanssens, Patrick, Mrabet, Nadir T., Snauwaert, Johan, Matthyssens, Gaston, Lambeir, Anne-Marie, Jenkins, John, Janin, Joël, Rey, Felix, Chiadmi, Mohamed, Van Tilbeurgh, Herman, Lasters, Ignace, De Maeyer, Marc, Chvalun, Sergei, Wodak, Shoshana, Lauwereys, Marc, Stanssens, Patrick, Mrabet, Nadir T., Snauwaert, Johan, Matthyssens, Gaston, and Lambeir, Anne-Marie

Abstract

SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1992

21. Arginine residues as stabilizing elements in proteins

Author

Mrabet, Nadir T., Van Den Broeck, Annemie, Van Brande, Ilse Den, Stanssens, Patrick, Laroche, Yves, Lambeir, Anne-Marie, Matthijssens, Gaston, Jenkins, John, Chiadmi, Mohamed, Van Tilbeurgh, Herman, Rey, Felix, Janin, Joël, Quax, Wim J., Lasters, Ignace, De Maeyer, Marc, Wodak, Shoshana, Mrabet, Nadir T., Van Den Broeck, Annemie, Van Brande, Ilse Den, Stanssens, Patrick, Laroche, Yves, Lambeir, Anne-Marie, Matthijssens, Gaston, Jenkins, John, Chiadmi, Mohamed, Van Tilbeurgh, Herman, Rey, Felix, Janin, Joël, Quax, Wim J., Lasters, Ignace, De Maeyer, Marc, and Wodak, Shoshana

Abstract

SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1992

22. Structural analysis of the 2.8 Å model of xylose isomerase from Actinoplanes missouriensis

Author

Rey, Felix, Jenkins, John, Janin, Joël, Lasters, Ignace, Alard, Philippe, Classens, Michel, Matthyssens, Gaston, Wodak, Shoshana, Rey, Felix, Jenkins, John, Janin, Joël, Lasters, Ignace, Alard, Philippe, Classens, Michel, Matthyssens, Gaston, and Wodak, Shoshana

Abstract

The structure of Xylose isomerase (X.I.) from Actinoplanes missouriensis has been solved to 2.8 Angstroms resolution. Phases were determined from a single Eu3+ derivative and from the noncrystallographic 22 symmetry of the tetrameric molecule. An atomic model was built and subjected to restrained crystallographic refinement. The resulting model is shown to be closely similar to the recently reported X.I.'s structures from three other bacterial sources. Each monomer is found to be composed of an eight‐stranded α/β “T.I.M.” barrel forming an N‐terminal domain of 328 residues followed by a large loop of 66 residues embracing an adjacent subunit. Analysis of intersubunit packing shows that the X.I. tetramer is an assembly of two tight dimers. The β barrel fits a simple hyperboloid model as other T.I.M. barrels do. The active site, identified as the binding site for the inhibitor xylitol, is located at the carboxyl end of the beta strands in the barrel next to a pair binding site for Eu3+ ions, which are assumed to the sites for the divalent ions involved in catalysis. Active sites in the tetramer are oriented towards the interface between dimmers. It is suggested that subunit interfaces might stabilize the active site region and this might explain the oligomeric nature of the other α/β barrel enzymes. Copyright © 1988 Alan R. Liss, Inc., SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1988

23. Reaction pathway for the quaternary structure change in hemoglobin

Author

Janin, Joël, Wodak, Shoshana, Janin, Joël, and Wodak, Shoshana

Abstract

We perform a computer simulation of the quaternary structure change during the allosteric transition of hemoglobin. The simulation is based on a docking procedure by which αβ dimers of human hemoglobin are associated into tetramers after being rotated in various orientations. The stability of tetramers thus reconstituted is estimated from the values of a simplified energy function describing nonbonded interactions and from the area of the surface buried in dimer–dimer contacts (their interface area), which we take to represent stabilizing interactions and solvent contribution. A systematic analysis of tetramers reconstituted with twofold symmetry reveals that when the dimers have the R tertiary structure, only tetramers having R‐like quaternary structures are stable. When the dimers have the T tertiary structure, they may associate into T‐like tetramers or a variety of quaternary structures ranging from T to near R, thus tracing a plausible reaction pathway for the allosteric transition. We subject intermediates of this pathway to energy refinement with rigid αβ dimers. The refinement demonstrates that symmetrical structures are more stable than non symmetrical ones. A detailed analysis of dimer–dimer contacts in intermediates shows how close packing is maintained over large interfaces throughout the quaternary structure change, especially in the “switch region” of contact between the C helix of α‐chains and the FG corner of β‐chains. Copyright © 1985 John Wiley & Sons, Inc., SCOPUS: ar.j, FLWNA, info:eu-repo/semantics/published

Published
1985

24. Haemoglobin: The surface buried between the α1β1 and α2β2 dimers in the deoxy and oxy structures

Author

Lesk, Arthur A.M., Chothia, Cyrus, Janin, Joël, Wodak, Shoshana, Lesk, Arthur A.M., Chothia, Cyrus, Janin, Joël, and Wodak, Shoshana

Abstract

Using the newly available refined co-ordinates of deoxy and oxyhaemoglobin, we have reexamined and compared the interfaces between the dimers α1β1 and α2β2. The most extensive monomer-monomer contacts are between α1 and β2, and, symmetrically, α2 and β1. In oxyhaemoglobin these interfaces bury 700 Å2less protein surface than in deoxyhaemoglobin. The α1α2 interface involves similar salt bridges in both forms, but in oxyhaemoglobin buries 240 Å2more surface than in deoxyhaemoglobin. There is a loosely packed β1β2 interface burying 320 Å2 of surface in oxyhaemoglobin; there is no β1β2 interface in deoxyhaemoglobin. The greater stability of the deoxy form, in the absence of ligands, can be attributed to a combination of hydrophobic, van der Waals' and electrostatic interactions. © 1985., SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1985

25. Location of structural domains in proteins

Author

Wodak, Shoshana, Janin, Joël, Wodak, Shoshana, and Janin, Joël

Abstract

We use surface area measurements based on atomic positions to give a quantitative definition of structural domains in proteins. Segments of the polypeptide chain making a minimum of interactions with the rest of the protein structure are identified on interface area scans, where the area B of the interface between a N-terminal segment of i residues and the complementary C-terminal segment is plotted as a function of i. Domain boundaries appear as minima of B in the scans. The procedure may be iterated to build a hierarchy of subdomains. It detects only continuous domains made of a single stretch of polypeptide chain but may be extended to detect such domains in the presence of discontinuous ones. Domains defined from interface area scans fit very well with globular structural regions identified by inspection of protein models [Wetlaufer, D. B. (1973) Proc. Natl. Acad. Sci. U.S.A. 70, 697-701]. They do not in general correspond to the repeated structural units observed in some proteins by superposition studies. In hemoglobin and hen lysozyme, the domains do not correspond to the coding sequences separated by introns in the genes. © 1981 American Chemical Society., SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1981

32. Location of structural domains in proteins

Author

Wodak, Shoshana, Janin, Joël, Wodak, Shoshana, and Janin, Joël

Abstract

We use surface area measurements based on atomic positions to give a quantitative definition of structural domains in proteins. Segments of the polypeptide chain making a minimum of interactions with the rest of the protein structure are identified on interface area scans, where the area B of the interface between a N-terminal segment of i residues and the complementary C-terminal segment is plotted as a function of i. Domain boundaries appear as minima of B in the scans. The procedure may be iterated to build a hierarchy of subdomains. It detects only continuous domains made of a single stretch of polypeptide chain but may be extended to detect such domains in the presence of discontinuous ones. Domains defined from interface area scans fit very well with globular structural regions identified by inspection of protein models [Wetlaufer, D. B. (1973) Proc. Natl. Acad. Sci. U.S.A. 70, 697-701]. They do not in general correspond to the repeated structural units observed in some proteins by superposition studies. In hemoglobin and hen lysozyme, the domains do not correspond to the coding sequences separated by introns in the genes. © 1981 American Chemical Society., SCOPUS: ar.j, info:eu-repo/semantics/published

Published
1981

Catalog

Books, media, physical & digital resources
See catalog results