Ta-Chau Chang

The mechanism of inhibition of telomerase by drugs is a key factor in an understanding of guanine-quadruplex complex stabilization during human cancer. This study describes a simulated annealing docking and molecular dynamics simulation to investigate a synthesized potent inhibitor, 3,6-bis(1-methyl-4-vinylpyridinium iodine) carbazole (BMVC), which stabilizes the quadruplex structure of the human telomeric DNA sequence d[AG(3)(T(2)AG(3))(3)] and inhibits telomerase activity. The compound was predicted to selectively interact with the quadruplex structure. During our simulation, the binding affinities were calculated and used to predict the best drug-binding sites as well as enhanced selectivity compared with other compounds. Our studies suggest that the simulation results quite coincide with the experimental results. In addition, molecular modeling shows that a 2:1 binding model involving the external binding of BMVC to both ends of the G-quartet of d[AG(3)(T(2)AG(3))(3)] is the most stable binding mode and this agrees with the absorbance titration results that show two binding sites. Of particular interest is that one pyridinium ring and carbazole moiety of the BMVC can stack well at the end of G-quartet. This implies that BMVC is a good human quadruplex stabilizer and also a good telomerase inhibitor.

ABSTRACT. Lipid is an important energy source and essential component for plasma and organelle membranes in all kinds of cells. Coherent anti-Stokes Raman scattering (CARS) microscopy is a label-free and nonlinear optical technique that can be used to monitor the lipid distribution in live organisms. Here, we utilize CARS microscopy to investigate the pattern of lipid droplets in two live Caenorhabditis elegans mutants (fat-2 and fat-3). The CARS images showed a striking decrease in the size, number, and content of lipid droplets in the fat-2 mutant but a slight difference in the fat-3 mutant as compared with the wild-type worm. Moreover, a nondroplet-like structure with enhanced CARS signal was detected for the first time in the uterus of fat-2 and fat-3 mutants. In addition, transgenic fat-2 mutant expressing a GFP fusion protein of vitellogenin-2 (a yolk lipoprotein) revealed that the enhanced CARS signal colocalized with the GFP signal, which suggests that the nondroplet-like structure is primarily due to the accumulation of yolk lipoproteins. Together, this study implies that CARS microscopy is a potential tool to study the distribution of yolk lipoproteins, in addition to lipid droplets, in live animals.