Human telomere double G-quadruplex recognition by berberine-bisquinolinium imaging conjugates in vitro and cells.

Molecular tools of double or multimeric G-quadruplexes have been given higher requirements on detection sensitivity, thermal stabilization and cell imaging to establish functions of these G-quadruplex aggregates and biological mechanisms as anticancer reagents. Here, two smart berberine-bisquinolinium conjugates (Ber-360A and Ber-PDS) by linking the berberine fluorophore ligand and an established G-quadruplex binder (i.e. bisquinolinium scaffold), have been designed and evaluated their activities and mechanisms for G-quadruplex aggregation. Two conjugates, especially Ber-PDS, are two highly selective, sensitive and fluorescent sensors which can distinguish human telomere double G-quadruplexes from other type G-quadruplexes and ds DNA. These two ligands could be the first example to stack two adjacent G-quadruplex units and fluorescently recognize human telomere double G-quadruplexes. Furthermore, conjugate Ber-PDS could enter the nucleoli and target G-quadruplex DNA through microscopy experiments, and also display strong telomerase inhibition and antitumor activities.

Dimers formed with the mixed-type G-quadruplex binder pyridostatin specifically recognize human telomere G-quadruplex dimers.

By choosing pyridostatin (PDS) with high thermal stabilization towards mixed-type G-quadruplexes as the monomer in dimers, three novel polyether-tethered PDS dimers (1a-c) were first synthesized and their interaction with human telomere G-quadruplex dimers (G2T1) was studied. Through the regulation of the linker length in PDS dimers, the dimer with a medium-length polyether linker (1b) showed higher binding selectivity and thermal stabilization (ΔTm = 29.5 °C) towards antiparallel G2T1 over G-quadruplex monomers (G1). Furthermore, the dimer with the longest-length polyether linker (1c) showed higher binding selectivity and thermal stabilization towards mixed-type G2T1 over mixed-type G1, c-kit 1, c-kit 2, c-myc and ds DNA. This work provides new insights into the development of G2T1 binders, especially mixed-type G2T1 binders, which could be promoted by a polymer formed with a mixed-type G-quadruplex binder. In addition, dimer 1c exhibited stronger telomerase inhibition than dimers 1a and 1b.

A Comparative Study on High Selectivities of Human Telomeric Dimeric G-Quadruplexes by Dimeric G-Quadruplex Binders.

Three new polyether-tethered bisquinolinium dimers (3 a-c) were synthesized, and their binding affinities, selectivities, and thermal stabilization towards dimeric G-quadruplex DNA (G2T1) in human telomeric regions were studied. The bisquinolinium dimer with a medium-length polyether linker (3 b) showed 30-425-fold higher binding affinity and selectivity towards antiparallel G2T1 than towards monomeric quadruplexes, which included human telomeric monomeric G-quadruplexes (G1), c-kit 1, c-kit 2, and c-myc. In addition, compound 3 b induced the formation of quadruplexes and displayed the highest level of thermal stabilization (ΔTm >28.1 °C) among all reported multimeric G-quadruplex binders. Compound 3 b also displayed a higher selectivity towards antiparallel G2T1 than monomer 360 A and bisquinolinium dimers 3 a and c. In contrast with our recent research on the analogous berberine dimer 1 b and dinickel-salphen complex 2 c, polyether linkers and their monomeric G-quadruplex binders in these dimeric G-quadruplex binders play a crucial role in regulating the binding affinities, selectivities, and thermal stabilization towards G2T1. More interestingly, these dimeric G-quadruplex compounds bind through end-stacking with the two adjacent G-quadruplex units in G2T1, and they showed high selectivity towards antiparallel G2T1 rather than mixed-type G2T1. In addition, compound 3 b, which displayed high selectivity towards antiparallel G2T1, showed strong telomerase inhibition and potent anticancer activities against HeLa and MCF-7 cells.

A novel square-planar Pt(ii) complex as a monomeric and dimeric G-quadruplex DNA binder.

A novel phenanthroimidazole ethylenediamine Pt(ii) complex with coumarin derivative (1) was synthesized and showed higher affinity, selectivity and thermal stabilization for mixed-type dimeric G-quadruplexes (G2T1) over monomeric G-quadruplexes (G1) and duplex DNA. Complex 1 could bind to G-quadruplexes via end-stacking and external-binding modes.

Specifically targeting mixed-type dimeric G-quadruplexes using berberine dimers.

Three polyether-tethered berberine dimers (1a-c) were studied for their binding affinity, selectivity and thermal stabilization towards human telomeric dimeric quadruplex DNA (G2T1). Compound 1a with the shortest polyether linker showed the highest affinity (Ka > 108 M-1) and 76-508-fold higher selectivity for mixed-type G2T1 over antiparallel G2T1 and three monomeric G-quadruplexes, which are human telomeric monomeric quadruplex G1, c-kit 1 and c-kit 2. Compound 1a induced the formation of quadruplex structures and showed higher thermal stabilization for mixed-type G2T1 than for anti-parallel G2T1, G1 and ds DNA. Spectroscopic studies suggest that compound 1a could bind to mixed-type G2T1 via end-stacking and external binding modes. These results suggest that the polyether linkers in these compounds play an important role in regulating the binding affinity and selectivity towards mixed-type G2T1 and that compound 1a could target mixed-type G2T1 at other genome regions with antiparallel G2T1 and monomeric G-quadruplexes. These results may provide useful guidance for the rational design of selective multimeric G-quadruplex binders and potential anticancer agents.

Dinickel-Salphen Complexes as Binders of Human Telomeric Dimeric G-Quadruplexes.

Three new polyether-tethered dinickel-salphen complexes (2 a-c) have been synthesized and fully characterized by NMR spectroscopy, mass spectrometry, and elemental analyses. The binding affinity and selectivity of these complexes and of the parent mono-nickel complex (1) towards dimeric quadruplex DNA have been determined by UV/Vis titrations, fluorescence spectroscopy, CD spectroscopy, and electrophoresis. These studies have shown that the dinickel-salphen complex with the longest polyether linker (2 c) has higher binding affinity and selectivity towards dimeric quadruplexes (over monomeric quadruplexes) than the dinickel-salphen complexes with the shorter polyether linkers (2 a and 2 b). Complex 2 c also has higher selectivity towards human telomeric dimeric quadruplexes with one TTA linker than the monometallic complex 1. Based on the spectroscopic data, a possible binding mode between complex 2 c and the dimeric G-quadruplex DNA under study is proposed.