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https://doi.org/10.1186/1471-2105-9-S1-S17
Title: | Stability of the core domain of p53: Insights from computer simulations | Authors: | Madhumalar, A Smith, D.J Verma, C |
Keywords: | Computational studies Conformational samplings DNA binding domain Enhanced stability Molecular dynamics simulations Polar interactions Structural perturbation Tumour suppressor protein Amino acids Computer simulation Molecular dynamics Phase space methods Proteins Stability DNA isoleucine phenylalanine protein p53 protein p63 protein p73 threonine tyrosine amino acid substitution article computer model computer simulation controlled study correlation function gene mutation molecular dynamics protein conformation protein DNA binding protein domain protein stability protein structure |
Issue Date: | 2008 | Citation: | Madhumalar, A, Smith, D.J, Verma, C (2008). Stability of the core domain of p53: Insights from computer simulations. BMC Bioinformatics 9 (SUPPL. 1) : S17. ScholarBank@NUS Repository. https://doi.org/10.1186/1471-2105-9-S1-S17 | Rights: | Attribution 4.0 International | Abstract: | Background: The tumour suppressor protein p53 protein has a core domain that binds DNA and is the site for most oncogenic mutations. This domain is quite unstable compared to its homologs p63 and p73. Two key residues in the core domain of p53 (Tyr236, Thr253), have been mutated in-silico, to their equivalent residues in p63 (Phe238 and Ile255) and p73 (Phe238 and Ile255), with subsequent increase in stability of p53. Computational studies have been performed to examine the basis of instability in p53. Results: Molecular dynamics simulations suggest that mutations in p53 lead to increased conformational sampling of the phase space which stabilizes the system entropically. In contrast, reverse mutations, where p63 and p73 were mutated by replacing the Phe238 and Ile255 by Tyr and Thr respectively (as in p53), showed reduced conformational sampling although the change for p63 was much smaller than that for p73. Barriers to the rotation of sidechains containing aromatic rings at the core of the proteins were reduced several-fold when p53 was mutated; in contrast they increased when p73 was mutated and decreased by a small amount in p63. The rate of ring flipping of a Tyrosine residue at the boundary of two domains can be correlated with the change in stability, with implications for possible pathways of entry of agents that induce unfolding. Conclusion: A double mutation at the core of the DNA binding domain of p53 leads to enhanced stability by increasing the softness of the protein. A change from a highly directional polar interaction of the core residues Tyr236 and Thr253 to a non-directional apolar interaction between Phe and Ile respectively may enable the system to adapt more easily and thus increase its robustness to structural perturbations, giving it increased stability. This leads to enhanced conformational sampling which in turn is associated with an increased "softness" of the protein core. However the system seems to become more rigid at the periphery. The success of this methodology in reproducing the experimental trends in the stability of p53 suggests that it has the potential to complement structural studies for rapidly estimating changes in stability upon mutations and could be an additional tool in the design of specific classes of proteins. © 2008 Madhumalar et al; licensee BioMed Central Ltd. | Source Title: | BMC Bioinformatics | URI: | https://scholarbank.nus.edu.sg/handle/10635/177980 | ISSN: | 14712105 | DOI: | 10.1186/1471-2105-9-S1-S17 | Rights: | Attribution 4.0 International |
Appears in Collections: | Elements Staff Publications |
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