Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Three-helix-bundle protein in a Ramachandran model.

Literature DB >> 11095708

Three-helix-bundle protein in a Ramachandran model.

Abstract

We study the thermodynamic behavior of a model protein with 54 amino acids that forms a three-helix bundle in its native state. The model contains three types of amino acids and five to six atoms per amino acid and has the Ramachandran torsional angles phi(i), psi(i) as its degrees of freedom. The force field is based on hydrogen bonds and effective hydrophobicity forces. For a suitable choice of the relative strength of these interactions, we find that the three-helix-bundle protein undergoes an abrupt folding transition from an expanded state to the native state. Also shown is that the corresponding one- and two-helix segments are less stable than the three-helix sequence.

Entities: Chemical

Mesh：

Substances：
Proteins

Year: 2000 PMID： 11095708 PMCID： PMC17624 DOI： 10.1073/pnas.240245297

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

24 in total

1. Predicting the structures of 18 peptides using Geocore.

Authors: K Ishikawa; K Yue; K A Dill
Journal: Protein Sci Date: 1999-04 Impact factor: 6.725

2. New Monte Carlo technique for studying phase transitions.

Authors:
Journal: Phys Rev Lett Date: 1988-12-05 Impact factor: 9.161

3. Self-consistently optimized energy functions for protein structure prediction by molecular dynamics.

Authors: K K Koretke; Z Luthey-Schulten; P G Wolynes
Journal: Proc Natl Acad Sci U S A Date: 1998-03-17 Impact factor: 11.205

4. Absence of a stable intermediate on the folding pathway of protein A.

Authors: Y Bai; A Karimi; H J Dyson; P E Wright
Journal: Protein Sci Date: 1997-07 Impact factor: 6.725

5. Exploring the folding free energy surface of a three-helix bundle protein.

Authors: Z Guo; C L Brooks; E M Boczko
Journal: Proc Natl Acad Sci U S A Date: 1997-09-16 Impact factor: 11.205

6. Respective roles of short- and long-range interactions in protein folding.

Authors: N Go; H Taketomi
Journal: Proc Natl Acad Sci U S A Date: 1978-02 Impact factor: 11.205

Review 7. Conformation of polypeptides and proteins.

Authors: G N Ramachandran; V Sasisekharan
Journal: Adv Protein Chem Date: 1968

8. Thermodynamic procedure to synthesize heteropolymers that can renature to recognize a given target molecule.

Authors: V S Pande; A Y Grosberg; T Tanaka
Journal: Proc Natl Acad Sci U S A Date: 1994-12-20 Impact factor: 11.205

9. Kinetics of protein folding. A lattice model study of the requirements for folding to the native state.

Authors: A Sali; E Shakhnovich; M Karplus
Journal: J Mol Biol Date: 1994-02-04 Impact factor: 5.469

10. The stability and unfolding of an IgG binding protein based upon the B domain of protein A from Staphylococcus aureus probed by tryptophan substitution and fluorescence spectroscopy.

Authors: S P Bottomley; A G Popplewell; M Scawen; T Wan; B J Sutton; M G Gore
Journal: Protein Eng Date: 1994-12

25 in total

10. Chevron behavior and isostable enthalpic barriers in protein folding: successes and limitations of simple Gō-like modeling.

Authors: Hüseyin Kaya; Zhirong Liu; Hue Sun Chan
Journal: Biophys J Date: 2005-04-29 Impact factor: 4.033

Three-helix-bundle protein in a Ramachandran model.

1. Predicting the structures of 18 peptides using Geocore.

2. New Monte Carlo technique for studying phase transitions.

3. Self-consistently optimized energy functions for protein structure prediction by molecular dynamics.

4. Absence of a stable intermediate on the folding pathway of protein A.

5. Exploring the folding free energy surface of a three-helix bundle protein.

6. Respective roles of short- and long-range interactions in protein folding.

Review 7. Conformation of polypeptides and proteins.

8. Thermodynamic procedure to synthesize heteropolymers that can renature to recognize a given target molecule.

9. Kinetics of protein folding. A lattice model study of the requirements for folding to the native state.

10. The stability and unfolding of an IgG binding protein based upon the B domain of protein A from Staphylococcus aureus probed by tryptophan substitution and fluorescence spectroscopy.

1. A structure-based method for derivation of all-atom potentials for protein folding.

2. The ensemble folding kinetics of protein G from an all-atom Monte Carlo simulation.

3. Unfolding of globular proteins: monte carlo dynamics of a realistic reduced model.

4. A structural model of polyglutamine determined from a host-guest method combining experiments and landscape theory.

5. Phase diagrams describing fibrillization by polyalanine peptides.

6. Generalized simulated tempering for exploring strong phase transitions.

7. From residue coevolution to protein conformational ensembles and functional dynamics.

8. PRIMO: A Transferable Coarse-grained Force Field for Proteins.

9. A directed essential dynamics simulation of peptide folding.

10. Chevron behavior and isostable enthalpic barriers in protein folding: successes and limitations of simple Gō-like modeling.