A protein sequence fitness function for identifying natural and nonnatural proteins

The infinitesimally small sequence space naturally scouted in the millions of years of evolution suggests that the natural proteins are constrained by some functional prerequisites and should differ from randomly generated sequences. We have developed a protein sequence fitness scoring function that...

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Bibliographic Details
Published in:Proteins, structure, function, and bioinformatics structure, function, and bioinformatics, 2020-10, Vol.88 (10), p.1271-1284
Main Authors: Kaushik, Rahul, Zhang, Kam Y. J.
Format: Article
Language:English
Subjects:
amino acid propensity
Amino Acid Sequence
Benchmarking
computational protein design
Datasets as Topic
Fitness
Humans
Mimicry
Models, Statistical
natural proteins
Protein Engineering - methods
protein foldability
Protein Folding
protein sequence space
Protein Structure, Secondary
Proteins
Proteins - chemistry
Reproductive fitness
Research Design
ROC Curve
Sampling
scoring of protein designs
Sequences
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Summary:The infinitesimally small sequence space naturally scouted in the millions of years of evolution suggests that the natural proteins are constrained by some functional prerequisites and should differ from randomly generated sequences. We have developed a protein sequence fitness scoring function that implements sequence and corresponding secondary structural information at tripeptide levels to differentiate natural and nonnatural proteins. The proposed fitness function is extensively validated on a dataset of about 210 000 natural and nonnatural protein sequences and benchmarked with existing methods for differentiating natural and nonnatural proteins. The high sensitivity, specificity, and percentage accuracy (0.81%, 0.95%, and 91% respectively) of the fitness function demonstrates its potential application for sampling the protein sequences with higher probability of mimicking natural proteins. Moreover, the four major classes of proteins (α proteins, β proteins, α/β proteins, and α + β proteins) are separately analyzed and β proteins are found to score slightly lower as compared to other classes. Further, an analysis of about 250 designed proteins (adopted from previously reported cases) helped to define the boundaries for sampling the ideal protein sequences. The protein sequence characterization aided by the proposed fitness function could facilitate the exploration of new perspectives in the design of novel functional proteins.
ISSN:0887-3585
1097-0134
DOI:10.1002/prot.25900