Structure and Stability Insights into Tumour Suppressor p53 Evolutionary Related Proteins

Bruno Pagano,Penka V Nikolova,Alex F Drake,Franca Fraternali,Abdullah Jama,Ester Akanho,Pierre Martinez,Tam T T Bui,Klaus Roemer

doi:10.1371/journal.pone.0076014

Bruno Pagano, Penka V Nikolova + Show 7 more

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https://doi.org/10.1371/journal.pone.0076014

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Abstract

The p53 family of genes and their protein products, namely, p53, p63 and p73, have over one billion years of evolutionary history. Advances in computational biology and genomics are enabling studies of the complexities of the molecular evolution of p53 protein family to decipher the underpinnings of key biological conditions spanning from cancer through to various metabolic and developmental disorders and facilitate the design of personalised medicines. However, a complete understanding of the inherent nature of the thermodynamic and structural stability of the p53 protein family is still lacking. This is due, to a degree, to the lack of comprehensive structural information for a large number of homologous proteins and to an incomplete knowledge of the intrinsic factors responsible for their stability and how these might influence function. Here we investigate the thermal stability, secondary structure and folding properties of the DNA-binding domains (DBDs) of a range of proteins from the p53 family using biophysical methods. While the N- and the C-terminal domains of the p53 family show sequence diversity and are normally targets for post-translational modifications and alternative splicing, the central DBD is highly conserved. Together with data obtained from Molecular Dynamics simulations in solution and with structure based homology modelling, our results provide further insights into the molecular properties of evolutionary related p53 proteins. We identify some marked structural differences within the p53 family, which could account for the divergence in biological functions as well as the subtleties manifested in the oligomerization properties of this family.

Highlights

The p53 protein family plays a key role in many different biological functions spanning different aspects of health and disease [1,2]
It is well known that the p53 human protein is unstable when compared to homologs within the same evolutionary family; it has been reported that stability and aggregation have at least as great a role in protein evolution as in cellular and organismal function [10]
We set out to investigate the molecular basis of thermal stability of the p53 protein family

Summary

Introduction

The p53 protein family plays a key role in many different biological functions spanning different aspects of health and disease [1,2]. Transcriptional profiling data from C. elegans suggests that the DNA damage dependent apoptosis is an ancient function of the p53 family [4]. This interplay of intrinsic p53 functions contributes to the increased complexity of the network of genes implicated in its regulation. The ability of the p53 protein family to elicit cell cycle arrest and apoptosis is clearly one of the most dynamic of functions as it has a direct link to tumour suppression and cancer biology [5,6]. A genomewide study showed that p63 and p73 regulate a range of unique target genes involved in multitude of biological functions including DNA repair [7]. The Drosophila melanogaster (p53_fly) gene codes for a single p53-like protein, which stands as an ancestor of the mammalian p53

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