Structural characterization of a mutant peptide derived from ubiquitin: Implications for protein folding

ROSA ZERELLA; PEI-YEH CHEN; PHILIP A. EVANS; ANDREW RAINE; DUDLEY H. WILLIAMS

doi:10.1110/ps.9.11.2142

Abstract

The formation of the N-terminal β-hairpin of ubiquitin is thought to be an early event in the folding of this small protein. Previously, we have shown that a peptide corresponding to residues 1–17 of ubiquitin folds autonomously and is likely to have a native-like hairpin register. To investigate the causes of the stability of this fold, we have made mutations in the amino acids at the apex of the turn. We find that in a peptide where Thr9 is replaced by Asp, U(1–17)T9D, the native conformation is stabilized with respect to the wild-type sequence, so much so that we are able to characterize the structure of the mutant peptide fully by NMR spectroscopy. The data indicate that U(1–17)T9D peptide does indeed form a hairpin with a native-like register and a type I turn with a G1 β-bulge, as in the full-length protein. The reason for the greater stability of the U(1–17)T9D mutant remains uncertain, but there are nuclear Overhauser effects between the side chains of Asp9 and Lys11, which may indicate that a charge–charge interaction between these residues is responsible.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Cochran, Andrea G. Skelton, Nicholas J. and Starovasnik, Melissa A. 2001. Tryptophan zippers: Stable, monomeric β-hairpins. Proceedings of the National Academy of Sciences, Vol. 98, Issue. 10, p. 5578.

Chen, Pei‐Yeh Lin, Chih‐Kai Lee, Chung‐Tien Jan, Howard and Chan, Sunney I. 2001. Effects of turn residues in directing the formation of the β‐sheet and in the stability of the β‐sheet. Protein Science, Vol. 10, Issue. 9, p. 1794.

Bolton, David Evans, Philip A Stott, Katherine and Broadhurst, R.William 2001. Structure and properties of a dimeric N-terminal fragment of human ubiquitin 1 1Edited by R. Huber. Journal of Molecular Biology, Vol. 314, Issue. 4, p. 773.

Jang, Soonmin Shin, Seokmin and Pak, Youngshang 2002. Molecular Dynamics Study of Peptides in Implicit Water: Ab Initio Folding of β-Hairpin, β-Sheet, and ββα-motif. Journal of the American Chemical Society, Vol. 124, Issue. 18, p. 4976.

Gao, F Li, Y Sha, Y Lai, L Wang, Y Wu, H and Qiu, Y 2002. β‐turn formation by a six‐residue linear peptide in solution. The Journal of Peptide Research, Vol. 60, Issue. 2, p. 75.

Lei, Hongxing and Smith, Paul E. 2003. The Role of the Unfolded State in Hairpin Stability. Biophysical Journal, Vol. 85, Issue. 6, p. 3513.

Blandl, Tamas Cochran, Andrea G. and Skelton, Nicholas J. 2003. Turn stability in β‐hairpin peptides: Investigation of peptides containing 3:5 type I G1 bulge turns. Protein Science, Vol. 12, Issue. 2, p. 237.

Santiveri, C.M. Rico, M. Jiménez, M.A. Pastor, M.T. and Pérez‐Payá, E. 2003. Insights into the determinants of β‐sheet stability: 1H and 13C NMR conformational investigation of three‐stranded antiparallel β‐sheet‐forming peptides. The Journal of Peptide Research, Vol. 61, Issue. 4, p. 177.

Krantz, Bryan A. Dothager, Robin S. and Sosnick, Tobin R. 2004. Discerning the Structure and Energy of Multiple Transition States in Protein Folding using ψ-Analysis. Journal of Molecular Biology, Vol. 337, Issue. 2, p. 463.

Dhanasekaran, Muthu Prakash, Om Xi Gong, Yu and Baures, Paul W. 2004. Expected and unexpected results from combined β-hairpin design elements. Org. Biomol. Chem., Vol. 2, Issue. 14, p. 2071.

Chen, Rita P.-Y. Huang, Joseph J.-T. Chen, Hsin-Liang Jan, Howard Velusamy, Marappan Lee, Chung-Tien Fann, Wunshain Larsen, Randy W. and Chan, Sunney I. 2004. Measuring the refolding of β-sheets with different turn sequences on a nanosecond time scale. Proceedings of the National Academy of Sciences, Vol. 101, Issue. 19, p. 7305.

Steinbach, Peter J. 2004. Exploring peptide energy landscapes: A test of force fields and implicit solvent models. Proteins: Structure, Function, and Bioinformatics, Vol. 57, Issue. 4, p. 665.

Ulmschneider, Jakob P. and Jorgensen, William L. 2004. Polypeptide Folding Using Monte Carlo Sampling, Concerted Rotation, and Continuum Solvation. Journal of the American Chemical Society, Vol. 126, Issue. 6, p. 1849.

Simpson, Emma R. Meldrum, Jill K. Bofill, Roger Crespo, Maria D. Holmes, Elizabeth and Searle, Mark S. 2005. Engineering Enhanced Protein Stability through β‐Turn Optimization: Insights for the Design of Stable Peptide β‐Hairpin Systems. Angewandte Chemie International Edition, Vol. 44, Issue. 31, p. 4939.

Searle, Mark S. 2005. Protein Folding Handbook. p. 314.

Went, Heather M. and Jackson, Sophie E. 2005. Ubiquitin folds through a highly polarized transition state. Protein Engineering, Design and Selection, Vol. 18, Issue. 5, p. 229.

Tyka, Michael D. Clarke, Anthony R. and Sessions, Richard B. 2006. An Efficient, Path-Independent Method for Free-Energy Calculations. The Journal of Physical Chemistry B, Vol. 110, Issue. 34, p. 17212.

Jackson, Sophie E. 2006. Ubiquitin: a small protein folding paradigm. Organic & Biomolecular Chemistry, Vol. 4, Issue. 10, p. 1845.

Jäger, Marcus Zhang, Yan Bieschke, Jan Nguyen, Houbi Dendle, Maria Bowman, Marianne E. Noel, Joseph P. Gruebele, Martin and Kelly, Jeffery W. 2006. Structure–function–folding relationship in a WW domain. Proceedings of the National Academy of Sciences, Vol. 103, Issue. 28, p. 10648.

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Structural characterization of a mutant peptide derived from ubiquitin: Implications for protein folding

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Structural characterization of a mutant peptide derived from ubiquitin: Implications for protein folding

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