Chang, CC, Chien CW, Lin YH, Kang CC, Chang TC.
2007.
Investigation of spectral conversion of d(TTAGGG)(4) and d(TTAGGG)(13) upon potassium titration by a G-quadruplex recognizer BMVC molecule, May. Nucleic Acids Research. 35:2846-2860., Number 9
AbstractWe have introduced a G- quadruplex- binding ligand, 3,6- bis( 1- methyl- 4- vinylpyridinium) carbazole diiodide ( BMVC), to verify the major structure of d( T(2)AG(3))(4) ( H24) in potassium solution and examine the structural conversion of H24 in sodium solution upon potassium titration. The studies of circular dichroism, induced circular dichroism, spectral titration and gel competition have allowed us to determine the binding mode and binding ratio of BMVC to the H24 in solution and eliminate the parallel form as the major G- quadruplex structure. Although the mixed- type form could not be eliminated as a main component, the basket and chair forms are more likely the main components of H24 in potassium solution. In addition, the circular dichroism spectra and the job plots reveal that a longer telomeric sequence d( T(2)AG(3))(13) ( H78) could form two units of G4 structure both in sodium or potassium solutions. Of particular interest is that no appreciable change on the induced circular dichroism spectra of BMVC is found during the change of the circular dichroism patterns of H24 upon potassium titration. Considering similar spectral conversion detected for H24 and a long sequence H78 together with the G4 structure stabilized by BMVC, it is therefore unlikely that the rapid spectral conversion of H24 and H78 is due to structural change between different types of the G4 structures. With reference to the circular dichroism spectra of d( GAA)(7) and d( GAAA)(5), we suggest that the spectral conversion of H24 upon potassium titration is attributed to fast ion exchange resulting in different loop base interaction and various hydrogen bonding effects.
Chang, CC, Chien CW, Lin YH, Kang CC, Chang TC.
2007.
Investigation of spectral conversion of d(TTAGGG)4 and d(TTAGGG)13 upon potassium titration by a G-quadruplex recognizer BMVC molecule. Nucleic Acids Res. 35:2846-60., Number 9
AbstractWe have introduced a G-quadruplex-binding ligand, 3,6-bis(1-methyl-4-vinylpyridinium)carbazole diiodide (BMVC), to verify the major structure of d(T2AG3)4 (H24) in potassium solution and examine the structural conversion of H24 in sodium solution upon potassium titration. The studies of circular dichroism, induced circular dichroism, spectral titration and gel competition have allowed us to determine the binding mode and binding ratio of BMVC to the H24 in solution and eliminate the parallel form as the major G-quadruplex structure. Although the mixed-type form could not be eliminated as a main component, the basket and chair forms are more likely the main components of H24 in potassium solution. In addition, the circular dichroism spectra and the job plots reveal that a longer telomeric sequence d(T2AG3)13 (H78) could form two units of G4 structure both in sodium or potassium solutions. Of particular interest is that no appreciable change on the induced circular dichroism spectra of BMVC is found during the change of the circular dichroism patterns of H24 upon potassium titration. Considering similar spectral conversion detected for H24 and a long sequence H78 together with the G4 structure stabilized by BMVC, it is therefore unlikely that the rapid spectral conversion of H24 and H78 is due to structural change between different types of the G4 structures. With reference to the circular dichroism spectra of d(GAA)7 and d(GAAA)5, we suggest that the spectral conversion of H24 upon potassium titration is attributed to fast ion exchange resulting in different loop base interaction and various hydrogen bonding effects.
Chang, TC, Yang YP, Huang KH, Chang CC, Hecht C.
2005.
Investigation of thionin-DNA interaction by satellite hole spectroscopy, May. Optics and Spectroscopy. 98:655-660., Number 5
AbstractThe interactions of the two tautomers of thionin dye with DNA have been investigated by using satellite hole burning spectroscopy. Similar features in the absorption and satellite hole spectra of thionin in the presence of calf thymus (CT) DNA and polynucleotides [d(GC)(6)](2) (GC) suggested that thionin preferentially binds to GC rather than polynucleotides [d(AT)(6)](2) (AT). Different binding effects of the two tautomers to DNA could be observed. While the imino form fully intercalates into the DNA base pairs, the amino form is only partially intercalated. In addition, a broad hole associated with an antihole appeared in the presence of DNA, particularly in GC base pairs. The coincidence of the antihole with the absorption band of the amino form showed that the amino form is the photoproduct of the imino form. An increase in intensity of the broad hole and its antihole and the loss of nonresonant hole intensity upon interaction with CT DNA could be described by rapid ground state recovery resulting from fast charge transfer between the intercalated thionin and a guanine base quenching the internal conversion. (c) 2005 Pleiades Publishing, Inc.
Chien, CH, Chen WW, Wu JT, Chang TC.
2012.
Investigation of lipid homeostasis in living Drosophila by coherent anti-Stokes Raman scattering microscopy, Dec. J Biomed Opt. 17:126001., Number 12
AbstractTo improve our understanding of lipid metabolism, Drosophila is used as a model animal, and its lipid homeostasis is monitored by coherent anti-Stokes Raman scattering microscopy. We are able to achieve in vivo imaging of larval fat body (analogous to adipose tissue in mammals) and oenocytes (analogous to hepatocytes) in Drosophila larvae at subcellular level without any labeling. By overexpressing two lipid regulatory proteins--Brummer lipase (Bmm) and lipid storage droplet-2 (Lsd-2)--we found different phenotypes and responses under fed and starved conditions. Comparing with the control larva, we observed more lipid droplet accumulation by approximately twofold in oenocytes of fat-body-Bmm-overexpressing (FB-Bmm-overexpressing) mutant under fed condition, and less lipid by approximately fourfold in oenocytes of fat-body-Lsd-2-overexpressing (FB-Lsd-2-overexpressing) mutant under starved condition. Moreover, together with reduced size of lipid droplets, the lipid content in the fat body of FB-Bmm-overexpressing mutant decreases much faster than that of the control and FB-Lsd-2-overexpressing mutant during starvation. From long-term starvation assay, we found FB-Bmm-overexpressing mutant has a shorter lifespan, which can be attributed to faster consumption of lipid in its fat body. Our results demonstrate in vivo observations of direct influences of Bmm and Lsd-2 on lipid homeostasis in Drosophila larvae.