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Literature DB >> 24706836

Homolog detection using global sequence properties suggests an alternate view of structural encoding in protein sequences.

Abstract

We show that a Fourier-based sequence distance function is able to identify structural homologs of target sequences with high accuracy. It is shown that Fourier distances correlate very strongly with independently determined structural distances between molecules, a property of the method that is not attainable using conventional representations. It is further shown that the ability of the Fourier approach to identify protein folds is statistically far in excess of random expectation. It is then shown that, in actual searches for structural homologs of selected target sequences, the Fourier approach gives excellent results. On the basis of these results, we suggest that the global information detected by the Fourier representation is an essential feature of structure encoding in protein sequences and a key to structural homology detection.

Keywords: Fourier analysis; sequence homology

Mesh：

Substances：
Proteins

Year: 2014 PMID： 24706836 PMCID： PMC3986189 DOI： 10.1073/pnas.1403599111

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

18 in total

Review 7. My 65 years in protein chemistry.

Authors: Harold A Scheraga
Journal: Q Rev Biophys Date: 2015-04-08 Impact factor: 5.318

Homolog detection using global sequence properties suggests an alternate view of structural encoding in protein sequences.

1. Computational complexity of multiple sequence alignment with SP-score.

2. Remote homology detection: a motif based approach.

3. Global characteristics of protein sequences and their implications.

4. Sequence determinants of protein architecture.

5. Quantitative organization of the known protein x-ray structures. I. Methods and short-length-scale results.

6. Critical assessment of methods of protein structure prediction - Round VIII.

7. A minimal sequence code for switching protein structure and function.

8. Protein structure alignment by incremental combinatorial extension (CE) of the optimal path.

9. Spectral analysis of a protein conformational switch.

10. Computation of structures of homologous proteins. Alpha-lactalbumin from lysozyme.

1. Nonlinearities in protein space limit the utility of informatics in protein biophysics.

2. Global informatics and physical property selection in protein sequences.

3. Alternative approach to protein structure prediction based on sequential similarity of physical properties.

4. Sequence-specific dynamic information in proteins.

5. Sequence-, structure-, and dynamics-based comparisons of structurally homologous CheY-like proteins.

6. The structure of protein dynamic space.

Review 7. My 65 years in protein chemistry.

8. The dynamic basis of structural order in proteins.

9. Dynamic and conformational switching in proteins.

10. 3D representations of amino acids-applications to protein sequence comparison and classification.