Conformational changes of DNA by photoirradiation of DNA-bis(Zn(II)-cyclen)-azobenzene complex

Bis(Zn(II)-cyclen)-azobenzene derivative, which has two Zn(II)-macrocyclic tetraamine complexes connected through azobenzene spacer, has been synthesized as a cross-linking agent fordoublestranded DNA in aqueous solution. The Zn(II)-cyclen derivative selectively binds to A-T base pairs producing complexes between the Zn(II)-cyclen moiety and the imide-deprotonated thymine with breaking A-T base pairs. The azobenzene spacer undergoes cis/trans photoisomerization in the complex between the Zn(II)-cyclen derivative and the DNA duplex. The conformation of the DNA remarkably changed by photoisomerization of the azobenzene linker, when the Zn(II)-cyclen derivative binds to the DNA duplex with an interstrand cross-linking manner     

A heteroduplex-preferential Tm depressor for the specificity-enhanced DNA polymerase chain reactions

A macrocyclic tetraamine zinc(II) complex appended with two quinoline groups, Zn(2+)-1,7-bis(4-quinolylmethyl)-1,4,7,10- tetraazacyclododecane (Zn(2+)-Q2-cyclen), was successfully used as a novel additive to suppress nonspecific products in DNA polymerase chain reaction (PCR). In the presence of Zn(2+)-Q2-cyclen, the Tm drop of 20-bp heteroduplexes containing a noncomplementary basepair was greater than that of the corresponding homoduplex (i.e., primer DNA). Here, we applied such preferential DNA melting to a specificity-enhanced PCR using micromolar concentrations of Zn(2+)-Q2-cyclen. We demonstrated the selective amplification of target DNA fragments (i.e., the human heart sodium channel Nav1.5 gene) from genomic DNA or a cDNA library. The optimum condition for the specificity-enhanced PCR could be determined in the concentration range of 1-50muM of Zn(2+)-Q2-cyclen.     

Recent progress in artificial receptors for phosphate anions in aqueous solution

Phosphate esters exist ubiquitously in nature in the form of nucleoside phosphates (nucleotides) as components of RNA (or DNA), sugar nucleotides for glycosylation of oligosaccharides or proteins, activated form of proteins responding to extracellular signals, and chemical mediators playing central roles in intracellular signaling signals. Phosphorylation of anti-viral nucleoside analogues by intracellular kinases yields nucleoside phosphates (nucleotide) as biologically active forms as anti-viral agents. Development of artificial phosphate receptors would afford new methodologies for detection, separation, or transport of biologically important phosphates. Herein, a recent progress of artificial phosphate receptors is reviewed with special focus on macrocyclic polyamines and their metal complexes as a new prototype. In comparison to most of the previous artificial receptors (most of them are organic molecules), our system characteristically works in aqueous solution at neutral pH with extremely strong affinities with phosphate anions. Moreover, zinc(II)-macrocyclic tetraamine (cyclen) complexes were discovered to selectively bind thymine and uracil, so that nucleotides of these bases are specifically recognized by the bis(Zn2+-cyclen) complexes.