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Protein flexibility of dimers: do symmetric motions play a role in allosteric interactions?

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Protein flexibility of dimers: do symmetric motions play a role in allosteric interactions? / Schulze, Bernd; Sljoka, Adnan; Whiteley, Walter.
AIP Conference Proceedings of Advances in Mathematical and Computational Methods : Addressing Modern Challenges of Science, Technology, and Society 2011. Vol. 1368 American Institute of Physics, 2011. p. 135-138.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

Harvard

Schulze, B, Sljoka, A & Whiteley, W 2011, Protein flexibility of dimers: do symmetric motions play a role in allosteric interactions? in AIP Conference Proceedings of Advances in Mathematical and Computational Methods : Addressing Modern Challenges of Science, Technology, and Society 2011. vol. 1368, American Institute of Physics, pp. 135-138. https://doi.org/10.1063/1.3663478

APA

Schulze, B., Sljoka, A., & Whiteley, W. (2011). Protein flexibility of dimers: do symmetric motions play a role in allosteric interactions? In AIP Conference Proceedings of Advances in Mathematical and Computational Methods : Addressing Modern Challenges of Science, Technology, and Society 2011 (Vol. 1368, pp. 135-138). American Institute of Physics. https://doi.org/10.1063/1.3663478

Vancouver

Schulze B, Sljoka A, Whiteley W. Protein flexibility of dimers: do symmetric motions play a role in allosteric interactions? In AIP Conference Proceedings of Advances in Mathematical and Computational Methods : Addressing Modern Challenges of Science, Technology, and Society 2011. Vol. 1368. American Institute of Physics. 2011. p. 135-138 doi: 10.1063/1.3663478

Author

Schulze, Bernd ; Sljoka, Adnan ; Whiteley, Walter. / Protein flexibility of dimers: do symmetric motions play a role in allosteric interactions?. AIP Conference Proceedings of Advances in Mathematical and Computational Methods : Addressing Modern Challenges of Science, Technology, and Society 2011. Vol. 1368 American Institute of Physics, 2011. pp. 135-138

Bibtex

@inproceedings{a803abbf2a0744dcbaf121ffa0d010cb,
title = "Protein flexibility of dimers: do symmetric motions play a role in allosteric interactions?",
abstract = "How a protein functions depends both on having basic stable forms (tertiary structure) and having some residual flexibility supported within that structure. The modeling of protein flexibility and rigidity in terms imported from physics and engineering has been developed through the theory of generically rigid frameworks and a fast combinatorial algorithm is available in programs such as FIRST. Recent theoretical work on rigidity of frameworks has modified this generic analysis to include the basic symmetry and to predict additional motions. In particular, a framework which would normally count to be combinatorially minimally rigid in generic realizations has been shown to become flexible when realized with 2‐fold rotational symmetry in 3‐space.Protein dimers, formed by two copies of a protein are a good case study for impact of this added flexibility due to 2‐fold rotational symmetry, as dimers generally self‐assemble with a 2‐fold rotational axis, for reasons of minimal energy. We describe an algorithm for predicting possible additional flexibility and consider the question: What is the significance of this for the behavior of dimers, such as tryptophan repressor?",
author = "Bernd Schulze and Adnan Sljoka and Walter Whiteley",
year = "2011",
doi = "10.1063/1.3663478",
language = "English",
volume = "1368",
pages = "135--138",
booktitle = "AIP Conference Proceedings of Advances in Mathematical and Computational Methods : Addressing Modern Challenges of Science, Technology, and Society 2011",
publisher = "American Institute of Physics",

}

RIS

TY - GEN

T1 - Protein flexibility of dimers: do symmetric motions play a role in allosteric interactions?

AU - Schulze, Bernd

AU - Sljoka, Adnan

AU - Whiteley, Walter

PY - 2011

Y1 - 2011

N2 - How a protein functions depends both on having basic stable forms (tertiary structure) and having some residual flexibility supported within that structure. The modeling of protein flexibility and rigidity in terms imported from physics and engineering has been developed through the theory of generically rigid frameworks and a fast combinatorial algorithm is available in programs such as FIRST. Recent theoretical work on rigidity of frameworks has modified this generic analysis to include the basic symmetry and to predict additional motions. In particular, a framework which would normally count to be combinatorially minimally rigid in generic realizations has been shown to become flexible when realized with 2‐fold rotational symmetry in 3‐space.Protein dimers, formed by two copies of a protein are a good case study for impact of this added flexibility due to 2‐fold rotational symmetry, as dimers generally self‐assemble with a 2‐fold rotational axis, for reasons of minimal energy. We describe an algorithm for predicting possible additional flexibility and consider the question: What is the significance of this for the behavior of dimers, such as tryptophan repressor?

AB - How a protein functions depends both on having basic stable forms (tertiary structure) and having some residual flexibility supported within that structure. The modeling of protein flexibility and rigidity in terms imported from physics and engineering has been developed through the theory of generically rigid frameworks and a fast combinatorial algorithm is available in programs such as FIRST. Recent theoretical work on rigidity of frameworks has modified this generic analysis to include the basic symmetry and to predict additional motions. In particular, a framework which would normally count to be combinatorially minimally rigid in generic realizations has been shown to become flexible when realized with 2‐fold rotational symmetry in 3‐space.Protein dimers, formed by two copies of a protein are a good case study for impact of this added flexibility due to 2‐fold rotational symmetry, as dimers generally self‐assemble with a 2‐fold rotational axis, for reasons of minimal energy. We describe an algorithm for predicting possible additional flexibility and consider the question: What is the significance of this for the behavior of dimers, such as tryptophan repressor?

U2 - 10.1063/1.3663478

DO - 10.1063/1.3663478

M3 - Conference contribution/Paper

VL - 1368

SP - 135

EP - 138

BT - AIP Conference Proceedings of Advances in Mathematical and Computational Methods : Addressing Modern Challenges of Science, Technology, and Society 2011

PB - American Institute of Physics

ER -