Electrophoresis and Biosensor-Based DNA Interaction Analysis of the First Paraben Derivatives of Spermine-Bridged Cyclotriphosphazenes.

Cancer is the uncontrolled growth of abnormal cells via malignant cell division and rapid DNA replication. While DNA damaging molecules can cause cancer, their role as anticancer drugs are very significant. For this purpose, the novel series of paraben substituted spermine bridged(dispirobino) cyclotriphosphazene compounds 2-6 were synthesized for the first time, and their structures were characterized by various spectroscopic techniques. The solid-state structures and geometries of compounds 2-6 were determined using single-crystal X-ray structural analysis. In addition, it was confirmed by TGA that all compounds 1-6 showed high thermal stability. Two methods were used in order to investigate DNA interaction properties of the targeted molecules. While biosensor-based screening test that measures DNA hybridization efficiency on a biochip surface, the agarose gel electrophoresis method examines the effect of compounds on plasmid DNA structure. The results collected from the automated biosensor device and agarose gel electrophoresis have indicated that compounds 1, 5, and 6 showed higher DNA damage than the compounds 2-4. According to the biosensor results, compounds 1, 5, and 6 showed 85%, 69%, and 77% activity, respectively.

Functional effects of active site mutations in NAD+-dependent formate dehydrogenases on transformation of hydrogen carbonate to formate.

Conversion of hydrogen carbonate to formate by mutants of Candida methylica (CmFDH) and Chaetomium thermophilum (CtFDH) formate dehydrogenases (FDHs) was studied. Hydrogen carbonate is not the primary substrate for the hydride transfer reaction in FDHs. The chosen mutations were selected so that enzyme activity could remain at an adequate level. In CtFDH, the mutation Asn120Cys in the active site inactivated the enzyme for formate (oxidation) but increased the specific activity for hydrogen carbonate (reduction) as a function of substrate concentration. The mutation Asn120Cys in CtFDH increased 6.5-fold the KM, indicating that substrate binding was weakened. A 6.5-fold increase of kcat compensated the lower affinity suggesting that product release was improved. The corresponding mutation Asn119Cys in CmFDH inactivated the enzyme for both substrates. Molecular dynamics simulations indicated that the active site dimensions change differently with different substrates after mutations, and in the mutant Asn120Cys of CtFDH, hydrogen carbonate adopted better reactive position than formate. With hydrogen carbonate, the active site enlarged enough for two hydrogen carbonate molecules to be placed there. The change of Asn119 to bulky Tyr or His in CmFDH requires changes in the active site to accommodate the substrate; activity with formate was retained but not with hydrogen carbonate. This study showed that the active site of FDHs can be modified radically, which gives possibilities for further enzyme engineering to improve the reaction with hydrogen carbonate or carbon dioxide for enzymatic fixing of carbon dioxide.