MOTIVATION: Membrane proteins are clinically relevant, yet their crystal structures are rare. Models of membrane proteins are typically built from template structures with low sequence identity to the target sequence, using a sequence-structure alignment as a blueprint. This alignment is usually made with programs designed for use on soluble proteins. Biological membranes have layers of varying hydrophobicity, and membrane proteins have different amino-acid substitution preferences from their soluble counterparts. Here we include these factors into an alignment method to improve alignments and consequently improve membrane protein models. RESULTS: We developed Membrane Protein Threader (MP-T), a sequence-structure alignment tool for membrane proteins based on multiple sequence alignment. Alignment accuracy is tested against seven other alignment methods over 165 non-redundant alignments of membrane proteins. MP-T produces more accurate alignments than all other methods tested (δF(M) from +0.9 to +5.5%). Alignments generated by MP-T also lead to significantly better models than those of the best alternative alignment tool (one-fourth of models see an increase in GDT_TS of ≥4%). AVAILABILITY: All source code, alignments and models are available at http://www.stats.ox.ac.uk/proteins/resources
MOTIVATION: Membrane proteins are clinically relevant, yet their crystal structures are rare. Models of membrane proteins are typically built from template structures with low sequence identity to the target sequence, using a sequence-structure alignment as a blueprint. This alignment is usually made with programs designed for use on soluble proteins. Biological membranes have layers of varying hydrophobicity, and membrane proteins have different amino-acid substitution preferences from their soluble counterparts. Here we include these factors into an alignment method to improve alignments and consequently improve membrane protein models. RESULTS: We developed Membrane Protein Threader (MP-T), a sequence-structure alignment tool for membrane proteins based on multiple sequence alignment. Alignment accuracy is tested against seven other alignment methods over 165 non-redundant alignments of membrane proteins. MP-T produces more accurate alignments than all other methods tested (δF(M) from +0.9 to +5.5%). Alignments generated by MP-T also lead to significantly better models than those of the best alternative alignment tool (one-fourth of models see an increase in GDT_TS of ≥4%). AVAILABILITY: All source code, alignments and models are available at http://www.stats.ox.ac.uk/proteins/resources
Authors: Kriti Arora; Bernardo Ochoa-Montaño; Patricia S Tsang; Tom L Blundell; Stephanie S Dawes; Valerie Mizrahi; Tracy Bayliss; Claire J Mackenzie; Laura A T Cleghorn; Peter C Ray; Paul G Wyatt; Eugene Uh; Jinwoo Lee; Clifton E Barry; Helena I Boshoff Journal: Antimicrob Agents Chemother Date: 2014-08-25 Impact factor: 5.191
Authors: René Staritzbichler; Emily Yaklich; Edoardo Sarti; Nikola Ristic; Peter W Hildebrand; Lucy R Forrest Journal: Nucleic Acids Res Date: 2022-05-24 Impact factor: 19.160