Abstract 2756: A high-resolution G-quadruplex structure involved in cmyc oncogene regulation

Abstract

Abstract Gene expression needs strict regulation in human cells to prevent tumorigenesis. Among other control mechanisms, guanine-rich sequences which are clustered in promoter regions of oncogenes can form four stranded nucleic acid structures, called G-quadruplexes (G4), and regulate their transcription. The cmyc protein is the most important cellular regulator for proliferation and is often overexpressed in cancer cells. The DNA G-quadruplex formed in the cmyc promoter is a transcriptional silencer element and stabilization of this G4 by small molecules suppresses cmyc transcription, making it a promising target for cancer therapy. High-resolution structures of the highly diverse G4s provide the opportunity to understand their molecular interactions with transcription factors and to design small molecules that specifically bind a particular G4 conformer. Characteristically, multiple G4s can be formed in gene promoter regions because their G-rich sequence generally contains more than the minimum of four G-stretches. While all reported cmyc G4s share the same core with parallel oriented strands, their overall shape is individualized by distinct combinations of varying flanking and loop motifs. In this study, we present a new high-resolution NMR structure of a G4 found to form in the cmyc promoter region. The determined cmyc G4 has a 1:6:1 loop-size arrangement and its conformation is largely defined by its long central loop of 6 nt. We show that this G4 structure is the preferred target of nucleolin protein in comparison to other G4s formed in the cmyc promoter, demonstrating how the polymorphism of a G-rich sequence can modulate the interaction with transcription factors and other regulators. Our NMR structure shows that, despite the length of the 6-nt loop motif and the associated increased flexibility, the folding converges well due to a base pairing between the central loop and the 5’-flanking. Thus, the long loop is pulled towards the 5’-end while analogous loop-flanking interactions are prevented at the opposite 3’-site. In conclusion, the presented new addition to the ensemble of possible cmyc promoter G4 conformations extends the folding landscape for this promoter region, in particular due to the long central loop. This may shed light on how proteins such as nucleolin can target specific G4 and shift the equilibrium of folding to fine-tune gene expression. Finally, this new structure is another promising target for cancer drug development. Citation Format: Jonathan Dickerhoff, Luying Chen, Guanhui Wu, Buket Onel, Clement Lin, Danzhou Yang. A high-resolution G-quadruplex structure involved in cmyc oncogene regulation [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 2756.