Protein Model Discrimination Using Mutational Sensitivity Derived from Deep Sequencing

A major bottleneck in protein structure prediction is the selection of correct models from a pool of decoys. Relative activities of ∼1,200 individual single-site mutants in a saturation library of the bacterial toxin CcdB were estimated by determining their relative populations using deep sequencing...

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Bibliographic Details
Published inStructure (London) Vol. 20; no. 2; pp. 371 - 381
Main Authors Adkar, Bharat V., Tripathi, Arti, Sahoo, Anusmita, Bajaj, Kanika, Goswami, Devrishi, Chakrabarti, Purbani, Swarnkar, Mohit K., Gokhale, Rajesh S., Varadarajan, Raghavan
Format Journal Article
LanguageEnglish
Published United States Elsevier Ltd 08.02.2012
Subjects
Amino Acid Sequence
Amino Acid Substitution
Bacteria
Bacterial Proteins - chemistry
Bacterial Proteins - genetics
Catalytic Domain
Cluster Analysis
Computer Simulation
Decoys
Escherichia coli - genetics
Escherichia coli - growth & development
Escherichia coli Proteins - chemistry
Escherichia coli Proteins - genetics
High-Throughput Nucleotide Sequencing
Mathematical models
Methodology
Models, Molecular
Mutagenesis, Site-Directed
Mutation
Phenotype
Pools
Protein Conformation
Proteins
Residues
Sequencing
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Summary:A major bottleneck in protein structure prediction is the selection of correct models from a pool of decoys. Relative activities of ∼1,200 individual single-site mutants in a saturation library of the bacterial toxin CcdB were estimated by determining their relative populations using deep sequencing. This phenotypic information was used to define an empirical score for each residue (RankScore), which correlated with the residue depth, and identify active-site residues. Using these correlations, ∼98% of correct models of CcdB (RMSD ≤ 4Å) were identified from a large set of decoys. The model-discrimination methodology was further validated on eleven different monomeric proteins using simulated RankScore values. The methodology is also a rapid, accurate way to obtain relative activities of each mutant in a large pool and derive sequence-structure-function relationships without protein isolation or characterization. It can be applied to any system in which mutational effects can be monitored by a phenotypic readout. [Display omitted] ► Individual mutant phenotypes in a saturation library derived via deep sequencing ► Residue depth and active-site residue derivation from mutant phenotypes ► Mutant-phenotype-derived parameters used for protein model discrimination ► Derivation of sequence-structure-function relationships without protein isolation
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ISSN:0969-2126
1878-4186
DOI:10.1016/j.str.2011.11.021