Nucleic acid sequences containing guanine tracts are able to adopt noncanonical four-stranded nucleic acid structures called G-quadruplexes (G4s). These structures are based on the stacking of two or more G-tetrads; each tetrad is a planar association of four guanines held together by eight hydrogen bonds. In this study, we analyzed a conserved G-rich region from HIV-1 promoter that is known to regulate the transcription of the HIV-1 provirus. Strikingly, our analysis of an alignment of 1684 HIV-1 sequences from this region showed a high conservation of the ability to form G4 structures despite a lower conservation of the nucleotide primary sequence. Using NMR spectroscopy, we determined the G4 topology adopted by a DNA sequence from this region (HIV-PRO1: 5' TGGCCTGGGCGGGACTGGG 3'). This DNA fragment formed a stable two G-tetrad antiparallel G4 with an additional Watson-Crick CG base pair. This hybrid structure may be critical for HIV-1 gene expression and is potentially a novel target for anti-HIV-1 drug development.
Non-canonical base pairing within guanine-rich DNA and RNA sequences can produce G-quartets, whose stacking leads to the formation of a G-quadruplex (G4). G4s can coexist with canonical duplex DNA in the human genome and have been suggested to suppress gene transcription, and much attention has therefore focused on studying G4s in promotor regions of disease-related genes. For example, the human proto-oncogene contains a nuclease-hypersensitive element located upstream of the major transcription start site. The KRAS nuclease-hypersensitive element (NHE) region contains a G-rich element (22RT; 5'-AGGGCGGTGTGGGAATAGGGAA-3') and encompasses a Myc-associated zinc finger-binding site that regulates transcription. The NEH region therefore has been proposed as a target for new drugs that control transcription, which requires detailed knowledge of the NHE structure. In this study, we report a high-resolution NMR structure of the G-rich element within the KRAS NHE. We found that the G-rich element forms a parallel structure with three G-quartets connected by a four-nucleotide loop and two short one-nucleotide double-chain reversal loops. In addition, a thymine bulge is found between G8 and G9. The loops of different lengths and the presence of a bulge between the G-quartets are structural elements that potentially can be targeted by small chemical ligands that would further stabilize the structure and interfere or block transcriptional regulators such as Myc-associated zinc finger from accessing their binding sites on the KRAS promoter. In conclusion, our work suggests a possible new route for the development of anticancer agents that could suppress KRAS expression.
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