Stability and structural recovery of the tetramerization domain of p53-R337H mutant induced by a designed templating ligand

Gordo, Susana; Martos, Vera; Santos, Eva; Menéndez, Margarita; Bo, Carles; Giralt, Ernest; Mendoza, Javier de

doi:10.1073/pnas.0805658105

Cited by 82 publications

(66 citation statements)

References 55 publications

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“…Once attention is focused on a predicted amino acid/metal-ion interaction destabilized by a dSNP, the metal binding site might be targetable by compounds designed to stabilize the protein and to mimic its native conformation. For example, this general approach has been shown to restore tetramer integrity to the monomers of a variant p53 protein using a compound designed to stabilize the tetrameric structure [Gordo et al, 2008]. Other examples are restabilization of protein structure similar to the function of proenzyme small-molecule activators [Wolan et al, 2009], or engineering conformational changes mimicking those occurring upon metal binding [Axelrod et al, 2010].…”

Section: Discussionmentioning

confidence: 98%

First- and second-shell metal binding residues in human proteins are disproportionately associated with disease-related SNPs

2011

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Protein structure serves as a key determinant for revealing the molecular basis of human disease. Metal ions are among the most frequently bound heterogroups in proteins affecting structure and function. We analyzed the relationship between single nucleotide polymorphisms (SNPs) associated with human disease and metal binding sites in proteins on a database scale, using structural models and predictive tools. A match was identified for 586 disease-associated SNPs (dSNPs) located at 135 predicted metal binding sites and associated with 126 diverse diseases. For 104 diseases, a metal is known to bind at the predicted site in the homologue; for 22, the analysis gives a first indication for metal involvement in the disease. As second-shell residues play an important part in metal ion binding, our analysis included protein space up to 4.5 Å from metal binding sites. The ratio of disease-associated versus nondisease-associated SNPs (dSNP/ndSNP) for first-shell residues is 7.4 and for second-shell residues, 3.1. In addition, over 13% of all dSNPs were found to be associated with first- and second-shell residues, although these residues occupy only about 3% of protein space. These results show a disproportionate association of dSNPs and metal binding sites over a wide variety of diseases.

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Section: Discussionmentioning

confidence: 98%

First- and second-shell metal binding residues in human proteins are disproportionately associated with disease-related SNPs

2011

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“…Approximately 20% of p53 germline mutations have a mutation at codon 337, whereas the relative frequency of somatic cancer mutations at this site is low (see release R13 of the IARC TP53 Mutation Database at www-p53.iarc.fr) (Petitjean et al 2007). A recent study shows that the structural integrity of the R337H tetramer can be restored by a designed tetraguanidiniomethylcalix[4]arene ligand, which serves as a template for holding together the four monomers of the mutated tetramerization domain (Gordo et al 2008).…”

Section: Structural Basis Of Tetramer Formationmentioning

confidence: 99%

The Tumor Suppressor p53: From Structures to Drug Discovery

Joerger

Fersht²

2010

Cold Spring Harbor Perspectives in Biology

288

272

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Even 30 years after its discovery, the tumor suppressor protein p53 is still somewhat of an enigma. p53's intimate and multifaceted role in the cell cycle is mirrored in its equally complex structural biology that is being unraveled only slowly. Here, we discuss key structural aspects of p53 function and its inactivation by oncogenic mutations. Concerted action of folded and intrinsically disordered domains of the highly dynamic p53 protein provides binding promiscuity and specificity, allowing p53 to process a myriad of cellular signals to maintain the integrity of the human genome. Importantly, progress in elucidating the structural biology of p53 and its partner proteins has opened various avenues for structure-guided rescue of p53 function in tumors. These emerging anticancer strategies include targeting mutant-specific lesions on the surface of destabilized cancer mutants with small molecules and selective inhibition of p53's degradative pathways.

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“…[101][102][103][104] MD conformational analyses were also performed for the N-terminal recognition α helix, [105][106][107][108] and for C-terminal fragments. 109,110 In order to study the entire monomeric protein behavior and its inter domain interactions, we have built a model for the full-length p53 (residues 1-393). The structure of unresolved fragments (10%) and disordered links between the domains have been predicted and merged with the experimental data.…”

Section: Introductionmentioning

confidence: 99%

Molecular dynamics of the full-length p53 monomer

Chillemi¹,

Davidovich

D’Abramo³

et al. 2013

Cell Cycle

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The p53 protein is frequently mutated in a very large proportion of human tumors, where it seems to acquire gain-of-function activity that facilitates tumor onset and progression. A possible mechanism is the ability of mutant p53 proteins to physically interact with other proteins, including members of the same family, namely p63 and p73, inactivating their function. Assuming that this interaction might occurs at the level of the monomer, to investigate the molecular basis for this interaction, here, we sample the structural flexibility of the wild-type p53 monomeric protein. The results show a strong stability up to 850 ns in the DNA binding domain, with major flexibility in the N-terminal transactivations domains (TAD1 and TAD2) as well as in the C-terminal region (tetramerization domain). Several stable hydrogen bonds have been detected between N-terminal or C-terminal and DNA binding domain, and also between N-terminal and C-terminal. Essential dynamics analysis highlights strongly correlated movements involving TAD1 and the proline-rich region in the N-terminal domain, the tetramerization region in the C-terminal domain; Lys120 in the DNA binding region. The herein presented model is a starting point for further investigation of the whole protein tetramer as well as of its mutants

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Stability and structural recovery of the tetramerization domain of p53-R337H mutant induced by a designed templating ligand

Cited by 82 publications

References 55 publications

First- and second-shell metal binding residues in human proteins are disproportionately associated with disease-related SNPs

First- and second-shell metal binding residues in human proteins are disproportionately associated with disease-related SNPs

The Tumor Suppressor p53: From Structures to Drug Discovery

Molecular dynamics of the full-length p53 monomer

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