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Literature DB >> 23459639

A Probabilistic Graphical Model for Ab Initio Folding.

Feng Zhao¹, Jian Peng, Joe Debartolo, Karl F Freed, Tobin R Sosnick, Jinbo Xu.

Abstract

Despite significant progress in recent years, ab initio folding is still one of the most challenging problems in structural biology. This paper presents a probabilistic graphical model for ab initio folding, which employs Conditional Random Fields (CRFs) and directional statistics to model the relationship between the primary sequence of a protein and its three-dimensional structure. Different from the widely-used fragment assembly method and the lattice model for protein folding, our graphical model can explore protein conformations in a continuous space according to their probability. The probability of a protein conformation reflects its stability and is estimated from PSI-BLAST sequence profile and predicted secondary structure. Experimental results indicate that this new method compares favorably with the fragment assembly method and the lattice model.

Entities: CellLine Chemical Disease Gene Mutation Species

Keywords: ab initio folding; conditional random fields (CRFs); directional statistics; fragment assembly; lattice model; protein structure prediction

Year: 2009 PMID： 23459639 PMCID： PMC3583211 DOI： 10.1007/978-3-642-02008-7_5

Source DB: PubMed Journal: Res Comput Mol Biol

36 in total

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Journal: J Mol Biol Date: 2006-08-18 Impact factor: 5.469

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Authors: Alexandre V Morozov; Tanja Kortemme; Kiril Tsemekhman; David Baker
Journal: Proc Natl Acad Sci U S A Date: 2004-04-26 Impact factor: 11.205

A Probabilistic Graphical Model for Ab Initio Folding.

1. TOUCHSTONE II: a new approach to ab initio protein structure prediction.

2. Ab initio construction of protein tertiary structures using a hierarchical approach.

3. Database algorithm for generating protein backbone and side-chain co-ordinates from a C alpha trace application to model building and detection of co-ordinate errors.

4. Critical assessment of methods of protein structure prediction (CASP)--round 6.

5. Minimalist representations and the importance of nearest neighbor effects in protein folding simulations.

6. A 3D building blocks approach to analyzing and predicting structure of proteins.

7. Modelling the polypeptide backbone with 'spare parts' from known protein structures.

8. Close agreement between the orientation dependence of hydrogen bonds observed in protein structures and quantum mechanical calculations.

9. Discriminative learning for protein conformation sampling.

10. Using known substructures in protein model building and crystallography.

1. Protein 8-class secondary structure prediction using conditional neural fields.

2. Fragment-free approach to protein folding using conditional neural fields.

3. Template-based and free modeling by RAPTOR++ in CASP8.

4. A conditional random fields method for RNA sequence-structure relationship modeling and conformation sampling.