Predicting protein functional sites with phylogenetic motifs

David, Lawrence A.; Sutch, Brian T.; Livesay, Dennis R.

doi:10.1002/prot.20321

Cited by 71 publications

(70 citation statements)

References 48 publications

(64 reference statements)

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“…A variety of approaches are being applied that include aligning structures to match a few consensus or enzymatic catalytic residues, [14][15][16][17][18][19][20][21][22][23] identifi cation of cavities consistent with shapes of known ligands, 24 a sequence independent force fi eld to extract common active site features, 25 theoretical prediction of titration curves, 26 using chemical properties and electrostatic potentials of amino acid residues consistent with active site characteristics, 27,28 neural network analysis of spatial clustering of residues, 29 and conserved residues from multiple sequence alignments (phylogenetic motifs). 20,30 Nevertheless, direct experimental observation of protein-ligand interactions are a more reliable mechanism for the proper and accurate identifi cation of protein active sites. LigBase is an online database that aligns only active sites present in the protein data bank (PDB) that bind the identical ligand, using structure and sequence alignments.…”

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confidence: 99%

Comparison of protein active site structures for functional annotation of proteins and drug design

et al. 2006

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Rapid and accurate functional assignment of novel proteins is increasing in importance, given the completion of numerous genome sequencing projects and the vastly expanding list of unannotated proteins. Traditionally, global primary‐sequence and structure comparisons have been used to determine putative function. These approaches, however, do not emphasize similarities in active site configurations that are fundamental to a protein's activity and highly conserved relative to the global and more variable structural features. The Comparison of Protein Active Site Structures (CPASS) database and software enable the comparison of experimentally identified ligand‐binding sites to infer biological function and aid in drug discovery. The CPASS database comprises the ligand‐defined active sites identified in the protein data bank, where the CPASS program compares these ligand‐defined active sites to determine sequence and structural similarity without maintaining sequence connectivity. CPASS will compare any set of ligand‐defined protein active sites, irrespective of the identity of the bound ligand. Proteins 2006. © 2006 Wiley‐Liss, Inc.

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confidence: 99%

Comparison of protein active site structures for functional annotation of proteins and drug design

et al. 2006

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“…Recently, we demonstrated that sequence fragments conserving the overall phylogeny, termed phylogenetic motifs (PMs), are very likely to correspond to protein functional sites [12]. We briefly highlight the key results of our previous report here (see Implementation for a technical description of the approach).…”

Section: Introductionmentioning

confidence: 93%

Predicting functional sites with an automated algorithm suitable for heterogeneous datasets

David

Livesay

2005

BMC Bioinformatics

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Background: In a previous report (La et al., Proteins, 2005), we have demonstrated that the identification of phylogenetic motifs, protein sequence fragments conserving the overall familial phylogeny, represent a promising approach for sequence/function annotation. Across a structurally and functionally heterogeneous dataset, phylogenetic motifs have been demonstrated to correspond to a wide variety of functional site archetypes, including those defined by surface loops, active site clefts, and less exposed regions. However, in our original demonstration of the technique, phylogenetic motif identification is dependent upon a manually determined similarity threshold, prohibiting large-scale application of the technique.

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“…Derivatives of the ET method have been recently proposed demonstrating that motifs taken from regions known to be functionally important a priori conserve the overall phylogeny of the family [256]. These Phylogenetic Motifs (PM) frequently correspond to key protein functional sites and recently a web based application has been developed [257]. Due to its nature, ET analysis is limited by the availability of a sufficiently large and diverse set of related proteins.…”

Section: Functional Descriptors From Structurementioning

confidence: 99%

Large-Scale Prediction of Protein Structure and Function from Sequence

Tosatto

Toppo²

2006

CPD

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The identification of novel drug targets from genomic data involves the large-scale analysis of many protein sequences. Methods for automated structure and function prediction are an essential tool for this purpose. In this review we concentrate on the recent developments in the field of protein structure prediction and how these can be used to gain hints about the function of proteins. The current state-of-the-art is highlighted through recent community-wide experiments aimed at comparing different approaches. For structure prediction this allows the identification of key improvements to increase the crucial sequence to structure alignment needed for accurate models. Function prediction is a rapidly maturing field that is still being benchmarked. Definitions for protein function are presented and available methods, mostly concentrating on functional site descriptors and structural motifs, presented.

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Predicting protein functional sites with phylogenetic motifs

Cited by 71 publications

References 48 publications

Comparison of protein active site structures for functional annotation of proteins and drug design

Comparison of protein active site structures for functional annotation of proteins and drug design

Predicting functional sites with an automated algorithm suitable for heterogeneous datasets

Large-Scale Prediction of Protein Structure and Function from Sequence

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