Ta-Chau Chang

Three binary molecule conjugates were designed and synthesized by conjugating a chromophore (3, 6-bis-(1-methyl-4-vinylpyridinium)-carbazole diiodide, BMVC) to mono-, bis- and trishydroxyl photosensitizers, respectively. BMVC plays the role of cancer cells recognizer; AIEE (aggregation-induced emission enhancement) generator and FRET (Fluorescence Resonance Energy Transfer) donor. The self assembling properties of these binary conjugates result in different degrees of AIEE and then achieve the formations of FONs (fluorescent organic nanoparticles), which present efficient FRET and singlet oxygen generations. Biologically, FONs-photosensitizers from these compounds were much more phototoxicities to cancer cell than to normal cell without significant dark toxicity. In addition, their intracellular fluorescent colors switching upon photo-excitation are expected to be used for further cell death biomarker applications. This improved photodynamic activity might be due to the aggregation of compounds in the cell that form FONs which can promote PDT (photodynamic therapy) and are observed in cancer cell but not normal cell.

Different cellular accumulations with distinct fluorescence properties of BMVC in cancer cells from normal cells allow us to establish a simple and economic method for the diagnosis of cancer cells. With using a light emitting diode to excite the BMVC molecule, microarray fluorescence analysis of a cell-based glass chip provides an easy method towards the detection of a limited number of cancer cells.

Human 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.

Fluorescence studies of 3,6-bis(1-methyl-4-vinylpyridinium) carbazole diiodide (BMVC) in glycerol/water mixtures allow us to elucidate the photophysical behavior of BMVC upon interaction with different DNA structures. The very weak fluorescence emission of BMVC in highly polar solvents of water is attributed to an increase in nonradiative decay due to the intramolecular twist of the vinyl group induced by charge transfer. Increasing the solvent viscosity and rigidity could lead to large changes in the barrier height and substantial effects on relaxation processes, and result in an enhancement of the fluorescence quantum yield. Similarly, different binding interactions of BMVC with various DNA could perturb the frictions of the reorientation of the vinyl group. We suggest that the intramolecular twist of the vinyl group of BMVC is mainly responsible for the distinct fluorescence emissions under different local environments. (c) 2006 Elsevier B.V. All rights reserved.

ABSTRACT. The importance of guanine-quadruplex (G4) is not only in protecting the ends of chromosomes for human telomeres but also in regulating gene expression for several gene promoters. However, the existence of G4 structures in living cells is still in debate. A fluorescent probe, 3,6-bis(1-methyl-2-vinylpyridinium) carbazole diiodide (o-BMVC), for differentiating G4 structures from duplexes is characterized. o-BMVC has a large contrast in fluorescence decay time, binding affinity, and fluorescent intensity between G4 structures and duplexes, which makes it a good candidate for probing G4 DNA structures. The fluorescence decay time of o-BMVC upon interaction with G4 structures of telomeric G-rich sequences is ∼2.8  ns and that of interaction with the duplex structure of a calf thymus is ∼1.2  ns. By analyzing its fluorescence decay time and histogram, we were able to detect one G4 out of 1000 duplexes in vitro. Furthermore, by using fluorescence lifetime imaging microscopy, we demonstrated an innovative methodology for visualizing the localization of G4 structures as well as mapping the localization of different G4 structures in living cells.

The gel assay, circular dichroism, and differential scanning calorimetry results all demonstrate that a major monomer component of bcl2mid exists at low [K(+)] and an additional dimer component appears at high [K(+)]. This implies that bcl2mid is a good candidate for elucidating the mechanisms of structural conversion between different G-quadruplexes. We further discovered that the conversion between the monomer and dimer forms of bcl2mid does not occur at room temperature but is detected when heated above the melting point. In addition, the use of the lithium cation to keep the same ionic strength in a K(+) solution favors the formation of the bcl2mid dimer. We also found that the bcl2mid dimer is more stable than the monomer. However, after the bcl2mid monomer is formed in a K(+) solution, there is no appreciable structural conversion from the monomer to the dimer detected with addition of Li(+) at room temperature. Furthermore, the spectral changes of bcl2mid when transitioning from sodium form to potassium form take place upon K(+) titration. The absence of the dimer form for bcl2mid after the direct addition of 150 mM [K(+)] at room temperature suggests that the spectral changes are not due to rapid unfolding and refolding. In addition, this work reveals the conditions that would be useful for NMR studies of G-quadruplexes.

The challenge of G-quadruplexes is that the G-rich sequences can adopt various G4 structures and possibly interconvert among them, particularly under the change of environmental conditions. Both NMR and circular dichroism (CD) show the spectral conversion of d[AG3(T2AG3)3] (HT22) from Na-form to K-form after Na+/K+ ion exchange. No appreciable change on the induced CD spectra of BMVC molecule and the single molecule tethered particle motion of HT22 in Na+ solution upon K+ titration suggests that the spectral conversion is unlikely due to the structural conversion via fully unfolded intermediate. Although a number of mechanisms were proposed for the spectral change induced by the Na+/K+ ion exchange, determining the precise structures of HT22 in K+ solution may be essential to unravel the mechanism of the structural conversion. Thus, development of a new method for separating different structures is of critical importance for further individual verification. In the second part of this review, we describe a new approach based on "micelle-enhanced ultrafiltration" method for DNA structural separation. The BMVC, a G-quadruplex ligand, is first modified and then forms a large size of emulsion after ultrasonic emulsification, together with its different binding affinities to various DNA structures; for the first time, we are able to separate different DNA structures after membrane filtration. Verification of the possible structural conversion and investigation of structural diversity among various G4 structures are essential for exploring their potential biological roles and for developing new anticancer drugs.