Enzymatic Synthesis of 7′,5′‐Bicyclo‐DNA Oligonucleotides

The selection of artificial genetic polymers with tailor‐made properties for their application in synthetic biology requires the exploration of new nucleosidic scaffolds that can be used in selection experiments. Herein, we describe the synthesis of a bicyclo‐DNA triphosphate (i.e., 7′,5′‐bc‐TTP) and show its potential to serve for the generation of new xenonucleic acids (XNAs) based on this scaffold. 7′,5′‐bc‐TTP is a good substrate for Therminator DNA polymerase, and up to seven modified units can be incorporated into a growing DNA chain. In addition, this scaffold sustains XNA‐dependent DNA synthesis and potentially also XNA‐dependent XNA synthesis. However, DNA‐dependent XNA synthesis on longer templates is hampered by competitive misincorporation of deoxyadenosine triphosphate (dATP) caused by the slow rate of incorporation of 7′,5′‐bc‐TTP.     

1‐Alkynyltriazenes as Functional Analogues of Ynamides

The chemical reactivity of 1‐alkynyltriazenes has been investigated and is found to parallel the reactivity of ynamides. The similarity in reactivity of these two classes of compounds is demonstrated by addition reactions with acids, by cycloaddition reactions with ketenes, tetracyanoethene, and cyclopropanes, as well as by intramolecular cyclization reactions. The presence of reactive triazene groups in the products enables subsequent transformations. Overall, our results suggest that 1‐alkynyltriazenes should become valuable reagents in synthetic organic chemistry.