MOTIVATION: Two major bottlenecks in advancing comparative protein structure modeling are the efficient combination of multiple template structures and the generation of a correct input target-template alignment. RESULTS: A novel method, Multiple Mapping Method with Multiple Templates (M4T) is introduced that implements an algorithm to automatically select and combine Multiple Template structures (MT) and an alignment optimization protocol (Multiple Mapping Method, MMM). The MT module of M4T selects and combines multiple template structures through an iterative clustering approach that takes into account the 'unique' contribution of each template, their sequence similarity among themselves and to the target sequence, and their experimental resolution. MMM is a sequence-to-structure alignment method that optimally combines alternatively aligned regions according to their fit in the structural environment of the template structure. The resulting M4T alignment is used as input to a comparative modeling module. The performance of M4T has been benchmarked on CASP6 comparative modeling target sequences and on a larger independent test set, and showed favorable performance to current state of the art methods.
MOTIVATION: Two major bottlenecks in advancing comparative protein structure modeling are the efficient combination of multiple template structures and the generation of a correct input target-template alignment. RESULTS: A novel method, Multiple Mapping Method with Multiple Templates (M4T) is introduced that implements an algorithm to automatically select and combine Multiple Template structures (MT) and an alignment optimization protocol (Multiple Mapping Method, MMM). The MT module of M4T selects and combines multiple template structures through an iterative clustering approach that takes into account the 'unique' contribution of each template, their sequence similarity among themselves and to the target sequence, and their experimental resolution. MMM is a sequence-to-structure alignment method that optimally combines alternatively aligned regions according to their fit in the structural environment of the template structure. The resulting M4T alignment is used as input to a comparative modeling module. The performance of M4T has been benchmarked on CASP6 comparative modeling target sequences and on a larger independent test set, and showed favorable performance to current state of the art methods.
Authors: Rajesh Nair; Jinfeng Liu; Ta-Tsen Soong; Thomas B Acton; John K Everett; Andrei Kouranov; Andras Fiser; Adam Godzik; Lukasz Jaroszewski; Christine Orengo; Gaetano T Montelione; Burkhard Rost Journal: J Struct Funct Genomics Date: 2009-02-05
Authors: M S Madhusudhan; Benjamin M Webb; Marc A Marti-Renom; Narayanan Eswar; Andrej Sali Journal: Protein Eng Des Sel Date: 2009-07-08 Impact factor: 1.650
Authors: Ben Webb; Andrej Sali; Narayanan Eswar; Marc A Marti-Renom; M S Madhusudhan; David Eramian; Min-Yi Shen; Ursula Pieper Journal: Curr Protoc Bioinformatics Date: 2006-10
Authors: Manir Ali; Beatriz Buentello-Volante; Martin McKibbin; J Alberto Rocha-Medina; Narcis Fernandez-Fuentes; Wilson Koga-Nakamura; Aruna Ashiq; Kamron Khan; Adam P Booth; Grange Williams; Yasmin Raashid; Hussain Jafri; Aine Rice; Chris F Inglehearn; Juan Carlos Zenteno Journal: Mol Vis Date: 2010-06-23 Impact factor: 2.367