Abstract
The tp53 gene is found to be mutated in 50% of all the cancers. The p53 protein, a product of tp53 gene, is a multi-domain protein. It consists of a core DNA binding domain (DBD) which is responsible for its binding and transcription of downstream target genes. The mutations in p53 protein are responsible for creating cancerous conditions and are found to be occurring at a high frequency in the DBD region of p53. Some of these mutations are also known to be temperature sensitive (ts) in nature. They are known to exhibit partial or strong binding with DNA in the temperature range (298–306 K). Whereas, at 310 K and above they show complete loss in binding. We have analyzed the changes in binding and conformational behavior at 300 K and 310 K for three of the ts-mutants viz., V143A, R249S and R175H. QM-MM simulations have been performed on the wild type and the above mentioned ts-mutants for 30 ns each. The optimal estimate of free energy of binding for a particular number of interface hydrogen bonds was calculated using the maximum likelihood method as described by Chodera et. al (2007). This parameter has been observed to be able to mimic the binding affinity of the p53 ts-mutants at 300 K and 310 K. Thus the correlation between MM-GBSA free energy of binding and hydrogen bonds formed by the interface residues between p53 and DNA has revealed the temperature dependent nature of these mutants. The role of main chain dihedrals was obtained by performing dihedral principal component analysis (PCA). This analysis, suggests that the conformational variations in the main chain dihedrals (ϕ and ψ) of the p53 ts-mutants may have caused reduction in the overall stability of the protein. The solvent exposure of the side chains of the interface residues were found to hamper the binding of the p53 to the DNA. Solvent Accessible Surface Area (SASA) also proved to be a crucial property in distinguishing the conformers obtained at 300 K and 310 K for the three ts-mutants from the wild type at 300 K.
Highlights
The p53 pathway plays a crucial role for effective tumor suppression which activates genes in response to cellular stress [1, 2]
As an attempt this paper presents the quantum mechanics (QM)-molecular mechanics (MM) simulation study on temperature dependent p53 mutants
ΔEgas, is the molecular mechanics energy and ΔGsol(com, rec, lig) is the solvation energy calculated by Generalised Born (GB) solvation model for the complex, receptor and ligand respectively
Summary
The p53 pathway plays a crucial role for effective tumor suppression which activates genes in response to cellular stress [1, 2]. In almost 50% of human cancers, mutations are observed in the p53 protein [4, 5], [6] Majority of these mutations are found in the sequence specific DNA binding core domain (DBD) of p53 [7,8,9,10]. These mutations are known to affect the thermodynamic stability of DBD and the whole protein as well. The DNA binding activity of p53 involves the association of zinc ion, which is known to form a tetrahedral co-ordination complex with CYS 176, CYS 238, CYS 242 and HIS 179 residues of the protein. Most of the residues in DNA binding domain of p53 are highly doi:10.1371/journal.pone.0143065.g001
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