Chu, JF, Chang TC, Li HW.
2010.
Single-Molecule TPM Studies on the Conversion of Human Telomeric DNA, Apr 21. Biophysical Journal. 98:1608-1616., Number 8
AbstractHuman telomere contains guanine-rich (G-rich) tandem repeats of single-stranded DNA sequences at its 3' tail. The G-rich sequences can be folded into various secondary structures, termed G-quadruplexes (G4s), by Hoogsteen basepairing in the presence of monovalent cations (such as Na(+) and K(+)). We developed a single-molecule tethered particle motion (TPM) method to investigate the unfolding process of G4s in the human telomeric sequence AGGG(TTAGGG)3 in real time. The TPM method monitors the DNA tether length change caused by formation of the G4, thus allowing the unfolding process and structural conversion to be monitored at the single-molecule level. In the presence of its antisense sequence, the folded G4 structure can be disrupted and converted to the unfolded conformation, with apparent unfolding time constants of 82 s and 3152 s. We also observed that the stability of the G4 is greatly affected by different monovalent cations. The folding equilibrium constant of G4 is strongly dependent on the salt concentration, ranging from 1.75 at 5 mM Na(+) to 3.40 at 15 mM Na(+). Earlier spectral studies of Na(+)- and K(+)-folded states suggested that the spectral conversion between these two different folded structures may go through a structurally unfolded intermediate state. However, our single-molecule TPM experiments did not detect any totally unfolded intermediate within our experimental resolution when sodium-folded G4 DNA molecules were titrated with high-concentration, excess potassium ions. This observation suggests that a totally unfolding pathway is likely not the major pathway for spectral conversion on the timescale of minutes, and that interconversion among folded states can be achieved by the loop rearrangement. This study also demonstrates that TPM experiments can be used to study conformational changes in single-stranded DNA molecules.
Chang, TC, Chang CC.
2010.
Detection of G-quadruplexes in cells and investigation of G-quadruplex structure of d(T2AG3)4 in K+ solution by a carbazole derivative: BMVC. Methods Mol Biol. 608:183-206.
AbstractVerification of the existence of quadruplex structure in native human telomeres and determination of the major structure of d(T(2)AG(3))(4) (H24) in K(+) solution are the major questions regarding the structure of human telomeres. We have synthesized a fluorescent probe of 3,6-bis(1-methyl-4-vinylpyridinium)carbazole diiodide (BMVC) that has a very high binding affinity for G-quadruplex H24. BMVC stabilizes quadruplex structures and acts as a sensitive probe to the local environment. Although the circular dichroism patterns of H24 are different in Na(+) and K(+) solutions, similar binding behaviors of BMVC to H24 in these solutions led us to suggest that the major G-quadruplex structure of H24 in K(+) solution is very likely similar to that in Na(+) solution. Of particular interest is the fluorescent band detected at -575 nm in quadruplex H24 and at -545 nm in duplex DNA. In addition, the intensity of BMVC fluorescence increases by two orders of magnitudes upon interaction with either duplex or G-quadruplex DNA. BMVC has a greater binding preference for G-quadruplex H24 than for duplex DNA. Analyzing the BMVC fluorescence at the ends of metaphase chromosomes and other regions of chromosomes allowed us to verify the presence of G-quadruplex structure in human telomeres for the first time. Using fluorescence lifetime imaging microscopy, the longer decay time of BMVC in G-quadruplex H24 than in duplex DNA allowed us to map the G-quadruplex structure in human metaphase chromosomes.