Chinese Journal of Magnetic Resonance ›› 2021, Vol. 38 ›› Issue (4): 503-513.doi: 10.11938/cjmr20212928
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Xiao-dong HU,Wen-xian LAN,Chun-xi WANG,Chun-yang CAO*(
)
Received:2021-06-29
Online:2021-12-05
Published:2021-09-16
Contact:
Chun-yang CAO
E-mail:ccao@mail.sioc.ac.cn
CLC Number:
Xiao-dong HU,Wen-xian LAN,Chun-xi WANG,Chun-yang CAO. Research Advance and NMR Studies of Anti-Cancer Small Molecules Targeting c-MYC G4-DNA[J]. Chinese Journal of Magnetic Resonance, 2021, 38(4): 503-513.
Fig.1
The structural composition of G-quadruplex. (a) G-tetrad formed by Hoogsteen hydrogen-bond; (b) The central structure of G-quadruplex is stabilized by monovalent cation
Fig.2
Structural diversity of G4 structures. (a) Four orientation of chains in G-tetrads; (b) Main three connection modes of loops; (c) Monomer or dimer G4 structure. The red arrow indicates the orientation from 5'-end to 3'-end[3]
Fig.3
Reported G4 structures in the c-MYC gene promoter. (a) The promoter structure of the MYC gene and different related elements; (b) Schematic demonstration of MYC-1245, MYC-1234, MYC-2345, and Pu22(4/14/23T) G4-DNA structures. The arrowheads indicate 5'-to-3' direction of DNA strands; guanines are shown by circles, and adenines and thymines are shown by boxes
Fig.4
Transcriptional regulation of G-quadruplex structure formed in c-MYC promoter NHE Ⅲ1[10, 11]
Fig.5
Binding modes of the proteins interacting with c-MYC G4. Binding modes that promotes (a) and stabilizes (b) the G4 structural stability; (c) Binding mode that unwinds G4 structure
Fig.6
Four binding models of the ligands with G4-DNA. (a) Ligands stack to the 5'-end, 3'-end, or both termini; (b) Ligands insert into G-tetrads; (c) Ligands bind to the groove and loop regions; (d) Ligands stay in the center of G4 structure
Fig.7
Structures of the compounds that directly or indirectly interact with c-MYC G4-DNA
Fig.8
(a) Imino proton region of one-dimensional 1H NMR spectra in H2O (down) and D2O (upper, exchanged from H2O sample 1 h later), respectively. (b) RET G4-DNA structure[57]
Fig.9
Solution structure of vegfr-2 17T G4-DNA displayed in ribbon mode (a) and cartoon mode (b), respectively, in which syn-G bases are shown in purple, anti-G bases are shown in cyan, G-C base-pairs are shown in yellow[59]
Fig.10
NMR structure of DC-34 complex with c-MYC G4. (PDB: 5W77). All molecules are shown as sticks. Two DC-34 molecules are shown in green and yellow, and K+ cations are shown as purple spheres[60]
Fig.11
Structure of RET G4-DNA in complex with colchicine (in orange). (a) The ensemble of 20 structures with the lowest energy. Base G14 is flexible; (b) One conformer of the complex. An angle 27.5° was formed between aromatic seven-membered ring and phenyl ring; (c) The structure of free RET G4-DNA; (d) The position of colchicine (in orange) relative to G14 (in green) above G3-G9-G13-G19 tetrad (in cyan) at 3'-end in the complex structure, compared to structure of free RET G4-DNA (in line mode, except the base G14 which was termed as G14 free and displayed in blue stick). In (a)~(c), the G-tetrad composed by four syn guanines was in magenta line and cartoon modes, respectively. The G-tetrads composed by anti- guanines were shown in cyan lines and cartoon modes, respectively. In all figures, base G14 was in deep-gray lines and cartoon modes. Bases G16 and T20 were in green lines and cartoon modes, respectively. Bases G4, C5, G6 and C10 in loops were in wheat lines or cartoon modes. All nonpolar protons were not displayed[61]
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