MOTIVATION: Enzyme catalysis is involved in numerous biological processes and the disruption of enzymatic activity has been implicated in human disease. Despite this, various aspects of catalytic reactions are not completely understood, such as the mechanics of reaction chemistry and the geometry of catalytic residues within active sites. As a result, the computational prediction of catalytic residues has the potential to identify novel catalytic pockets, aid in the design of more efficient enzymes and also predict the molecular basis of disease. RESULTS: We propose a new kernel-based algorithm for the prediction of catalytic residues based on protein sequence, structure and evolutionary information. The method relies upon explicit modeling of similarity between residue-centered neighborhoods in protein structures. We present evidence that this algorithm evaluates favorably against established approaches, and also provides insights into the relative importance of the geometry, physicochemical properties and evolutionary conservation of catalytic residue activity. The new algorithm was used to identify known mutations associated with inherited disease whose molecular mechanism might be predicted to operate specifically though the loss or gain of catalytic residues. It should, therefore, provide a viable approach to identifying the molecular basis of disease in which the loss or gain of function is not caused solely by the disruption of protein stability. Our analysis suggests that both mechanisms are actively involved in human inherited disease. AVAILABILITY AND IMPLEMENTATION: Source code for the structural kernel is available at www.informatics.indiana.edu/predrag/.
MOTIVATION: Enzyme catalysis is involved in numerous biological processes and the disruption of enzymatic activity has been implicated in human disease. Despite this, various aspects of catalytic reactions are not completely understood, such as the mechanics of reaction chemistry and the geometry of catalytic residues within active sites. As a result, the computational prediction of catalytic residues has the potential to identify novel catalytic pockets, aid in the design of more efficient enzymes and also predict the molecular basis of disease. RESULTS: We propose a new kernel-based algorithm for the prediction of catalytic residues based on protein sequence, structure and evolutionary information. The method relies upon explicit modeling of similarity between residue-centered neighborhoods in protein structures. We present evidence that this algorithm evaluates favorably against established approaches, and also provides insights into the relative importance of the geometry, physicochemical properties and evolutionary conservation of catalytic residue activity. The new algorithm was used to identify known mutations associated with inherited disease whose molecular mechanism might be predicted to operate specifically though the loss or gain of catalytic residues. It should, therefore, provide a viable approach to identifying the molecular basis of disease in which the loss or gain of function is not caused solely by the disruption of protein stability. Our analysis suggests that both mechanisms are actively involved in humaninherited disease. AVAILABILITY AND IMPLEMENTATION: Source code for the structural kernel is available at www.informatics.indiana.edu/predrag/.
Authors: Thomas A Lagace; David E Curtis; Rita Garuti; Markey C McNutt; Sahng Wook Park; Heidi B Prather; Norma N Anderson; Y K Ho; Robert E Hammer; Jay D Horton Journal: J Clin Invest Date: 2006-11 Impact factor: 14.808
Authors: Matthew Mort; Uday S Evani; Vidhya G Krishnan; Kishore K Kamati; Peter H Baenziger; Angshuman Bagchi; Brandon J Peters; Rakesh Sathyesh; Biao Li; Yanan Sun; Bin Xue; Nigam H Shah; Maricel G Kann; David N Cooper; Predrag Radivojac; Sean D Mooney Journal: Hum Mutat Date: 2010-03 Impact factor: 4.878
Authors: Predrag Radivojac; Peter H Baenziger; Maricel G Kann; Matthew E Mort; Matthew W Hahn; Sean D Mooney Journal: Bioinformatics Date: 2008-08-15 Impact factor: 6.937
Authors: Peter D Stenson; Matthew Mort; Edward V Ball; Katy Howells; Andrew D Phillips; Nick St Thomas; David N Cooper Journal: Genome Med Date: 2009-01-22 Impact factor: 11.117
Authors: Biao Li; Chet Seligman; Janita Thusberg; Jackson L Miller; Jim Auer; Michelle Whirl-Carrillo; Emidio Capriotti; Teri E Klein; Sean D Mooney Journal: BMC Genomics Date: 2014-05-20 Impact factor: 3.969
Authors: Jose Lugo-Martinez; Vikas Pejaver; Kymberleigh A Pagel; Shantanu Jain; Matthew Mort; David N Cooper; Sean D Mooney; Predrag Radivojac Journal: PLoS Comput Biol Date: 2016-08-26 Impact factor: 4.475