Molecule of the Month: p53 Tumor Suppressor

p53 tumor suppressor protects the body from DNA damage and cancer

p53 tumor supressor. Flexible portions of the molecule that are not included in the structures are shown schematically.
p53 tumor supressor. Flexible portions of the molecule that are not included in the structures are shown schematically.
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Guardian of the Cell

Our cells face many dangers, including chemicals, viruses, and ionizing radiation. If cells are damaged in sensitive places by these attackers, the effects can be disastrous. For instance, if key regulatory elements are damaged, the normal controls on cell growth may be blocked and the cell will rapidly multiply and grow into a tumor. p53 tumor suppressor is one of our defenses against this type of damage. p53 tumor suppressor is normally found at low levels, but when DNA damage is sensed, p53 levels rise and initiate protective measures. p53 binds to many regulatory sites in the genome and begins production of proteins that halt cell division until the damage is repaired. Or, if the damage is too severe, p53 initiates the process of programmed cell death, or apoptosis, which directs the cell to commit suicide, permanently removing the damage.

Structures by Parts

p53 tumor suppressor is a flexible molecule composed of four identical protein chains. Flexible molecules are difficult to study by x-ray crystallography because they do not form orderly crystals, and if they do crystallize, the experimental images are often blurry. So, p53 has been studied in parts, by removing the flexible regions and solving structures of the pieces that form stable structures. Three of these compact, globular portions, termed "domains", have been studied. At the center of p53 is a tetramerization domain (PDB entry 1olg ) that ties the four chains together. A long flexible region in each chain then connects to the second stable domain: a large DNA-binding domain (PDB entry 1tup ) that is rich in arginine residues that interact with DNA. This domain recognizes specific regulatory sites on the DNA. The third stable domain studied thus far is the transactivation domain (PDB entry 1ycq ), found near the end of each arm, that activates the DNA-reading machinery.

p53 and Cancer

As you might guess from its name, p53 tumor suppressor plays a central role in the protection of your body from cancer. Cancer cells typically contain two types of mutations: mutations that cause uncontrolled growth and multiplication of cells, and other mutations that block the normal defenses that protect against unnatural growth. p53 is in this second category and mutations in the p53 gene contribute to about half of the cases of human cancer. Most of these are missense mutations, changing the information in the DNA at one position and causing the cell to build p53 with an error, swapping an incorrect amino acid at one point in the protein chain. In these mutants, the normal function of p53 is blocked and the protein is unable to stop multiplication in the damaged cell. If the cell has other mutations that cause uncontrolled growth, the cell will develop into a tumor.

Model of p53 tumor suppressor bound to DNA.
Model of p53 tumor suppressor bound to DNA.
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Embracing DNA

p53 tumor suppressor binds to DNA using all four of its arms. The typical binding site for the whole molecule is composed of three parts: a specific binding site for two p53 domains, a variable stretch of 0 to 13 base pairs, and a second specific binding site for the other two p53 domains. In the picture shown here (constructed from PDB entries 1tup , 1olg and 1ycq ), two p53 domains are bound near the top of the DNA strand and two are bound at an identical site near the bottom. The tetramerization domain is behind the helix, tying all four chains together, and the four transactivation domains extend along the DNA helix, ready to activate neighboring proteins involved in reading the DNA. The flexible chains that connect all four arms together allow p53 to bind to many different variants of this binding site, allowing it to regulate transcription at many places in the genome.

Exploring the Structure

Leading cancer-causing mutations in p53 disrupt its ability to bind to DNA. PDB entry 3ts8 shows a tetramer of human p53 bound to a DNA substrate. The most common mutations occur in arginine 248 (shown in red). This key amino acid stabilizes DNA by binding to nucleotides within DNA’s minor groove. Additional mutations can be found in arginines 175, 249, 273, 282, and glycine 245. These amino acids (shown in pink) either interact directly with DNA, or help position other DNA-interacting residues.

Select the JSmol tab to explore these structures in an interactive view.

This JSmol was designed and illustrated by Ryan Nini.

References

  1. B. Vogelstein, D. Lane, A.J. Levine (2000): Surfing the p53 network. Nature 408, pp. 307-310.

July 2002, David Goodsell

http://doi.org/10.2210/rcsb_pdb/mom_2002_7
About Molecule of the Month
The RCSB PDB Molecule of the Month by David S. Goodsell (The Scripps Research Institute and the RCSB PDB) presents short accounts on selected molecules from the Protein Data Bank. Each installment includes an introduction to the structure and function of the molecule, a discussion of the relevance of the molecule to human health and welfare, and suggestions for how visitors might view these structures and access further details.More
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