Abstract
How cells choose between developmental pathways remains a fundamental biological question. In the case of the p53 protein family, its three transcription factors (p73, p63, and p53) each trigger a gene expression pattern that leads to specific cellular pathways. At the same time, these transcription factors recognize the same response element (RE) consensus sequences, and their transactivation of target genes overlaps. We aimed to understand target gene selectivity at the molecular level by determining the crystal structures of the p73 DNA-binding domain (DBD) in complex with full-site REs that vary in sequence. We report two structures of the p73 DBD bound as a tetramer to 20-bp full-site REs based on two distinct quarter-sites: GAACA and GAACC. Our study confirms that the DNA-binding residues are conserved within the p53 family, whereas the dimerization and tetramerization interfaces diverge. Moreover, a conserved lysine residue in loop L1 of the DBD senses the presence of guanines in positions 2 and 3 of the quarter-site RE, whereas a conserved arginine in loop 3 adapts to changes in position 5. Sequence variations in the RE elicit a p73 conformational response that might explain target gene specificity.
Highlights
Members of the p53 protein family bind to full-site response elements (REs) to trigger specific cellular pathways
Crystal Structures of the p73 DNA-binding domain (DBD) Tetramer Bound to 20-bp Full-site REs—We solved the structures of the p73 DBD bound as a tetramer to two REs (Fig. 1A)
Recent experiments revealed that target gene transcription for the three members often overlaps, and the three factors can act as tumor suppressor genes, triggering cell arrest and apoptosis [13, 14]
Summary
Members of the p53 protein family bind to full-site response elements (REs) to trigger specific cellular pathways. Results: We solved two crystal structures of the p73 DNA-binding domain in complex with full-site REs. Conclusion: Lys-138 in loop L1 distinguishes between consensus REs. Significance: Conformational changes in Lys-138 might explain specificity between cell arrest and apoptosis target genes. In the case of the p53 protein family, its three transcription factors (p73, p63, and p53) each trigger a gene expression pattern that leads to specific cellular pathways. These transcription factors recognize the same response element (RE) consensus sequences, and their transactivation of target genes overlaps. We aimed to understand target gene selectivity at the molecular level by determining the crystal structures of the p73 DNA-binding domain (DBD) in complex with full-site REs that vary in sequence. Sequence variations in the RE elicit a p73 conformational response that might explain target gene specificity
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