Title data
Martin, Andreas ; Kather, Insa ; Schmid, Franz X.:
Origins of the high stability of an in vitro-selected cold-shock protein.
In: Journal of Molecular Biology.
Vol. 318
(2002)
Issue 5
.
- pp. 1341-1349.
ISSN 0022-2836
DOI: https://doi.org/10.1016/S0022-2836(02)00243-7
Related URLs
Abstract in another language
In previous work, we had identified stabilized forms of the cold-shock protein Bs-CspB from Bacillus subtilis in a combinatorial library by an in vitro selection procedure. In this library, the sequence positions 2, 3, 46, 64, 66, and 67 had been randomized, because Bs-CspB differs from the naturally thermostable homolog Bc-Csp from Bacillus caldolyticus, among others, at these six positions. For the most stable selected variant, the midpoint of thermal unfolding (tM) increased by 28.2 deg. C and the Gibbs free energy of unfolding (deltaG(D)) by 19 kJ/mol. Here, we analyzed by site-directed mutagenesis how the selected residues contribute individually to this strong stabilization. Val3 and Val66, which replace Glu3 and Glu66 of wild-type Bs-CspB, each contribute about 7 kJ/mol to stability, the Thr64Arg substitution contributes 4.5 kJ/mol, and 3.2 kJ/mol originate from the Ala46Leu replacement. Gly67 at the carboxy terminus is unimportant for stability, the Arg selected at position 2 is overall slightly destabilizing but improves the coulombic interactions. The best variant differs from Bc-Csp at all six positions; nevertheless, natural and in vitro selection followed similar principles. In both cases, negatively charged residues at the adjacent positions 3 and 66 are avoided, and a positively charged residue is introduced into this area of the protein surface. Its exact location is unimportant. It can be at position 3, as in the thermophilic Bc-Csp, or at positions 2 or 64, as in the most stable selected variant. These positively charged residues contribute to stability not by engaging in pairwise coulombic interactions with a specific carboxyl group, but by generally improving the charge distribution in this particular region of the protein surface. These coulombic effects contribute significantly to the thermostability of the cold-shock proteins. They are only weakly interdependent and best explained by the presence of a flexible ion network at the protein surface. Our results emphasize that surface positions are very good candidates for optimizing protein stability.
Further data
Item Type: | Article in a journal |
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Refereed: | Yes |
Additional notes: | PubMed-ID: 12083522 |
Institutions of the University: | Faculties > Faculty of Biology, Chemistry and Earth Sciences > Department of Chemistry > Former Professors > Professor Biochemistry - Univ.-Prof. Dr. Franz Xaver Schmid Faculties Faculties > Faculty of Biology, Chemistry and Earth Sciences Faculties > Faculty of Biology, Chemistry and Earth Sciences > Department of Chemistry Faculties > Faculty of Biology, Chemistry and Earth Sciences > Department of Chemistry > Professorship Biochemistry Faculties > Faculty of Biology, Chemistry and Earth Sciences > Department of Chemistry > Former Professors |
Result of work at the UBT: | Yes |
DDC Subjects: | 500 Science > 540 Chemistry |
Date Deposited: | 28 Apr 2015 09:19 |
Last Modified: | 08 Jul 2022 13:42 |
URI: | https://eref.uni-bayreuth.de/id/eprint/10840 |