Propargylamine-selective dual fluorescence turn-on method for post-synthetic labeling of DNA

Propargylamine: an important moiety in drug discovery

Propargylamine is a chemical moiety whose properties have made it a widely distributed group within the fields of medicinal chemistry and chemical biology. Its particular reactivity has traditionally popularized the preparation of propargylamine derivatives using a large variety of synthetic strategies, which have facilitated the access to these compounds for the study of their biomedical potential. This review comprehensively covers and analyzes the applications that propargylamine-based derivatives have achieved in the drug discovery field, both from a medicinal chemistry perspective and from a chemical biology-oriented approach. The principal therapeutic fields where propargylamine-based compounds have made an impact are identified, and a discussion of their influence and growing potential is included.

RNA Polymerase-Mediated Stepwise RNA-Primed RNA Polymerization for Site-Specific Multiple Labeling into RNA: A Fluorescence Resonance Energy Transfer Probe Detects the Structural Change of an RNA G-Quadruplex

In this paper, we report a stepwise RNA-primed RNA polymerization method for the site-specific incorporation of multiple fluorescent moieties into RNA, mediated by an RNA polymerase. A screen of several RNA polymerases revealed that T7 RNA polymerase was the only one that functioned in the RNA-primed RNA polymerization. In the first fluorescence labeling step, a fluorescent rU_thioTP residue was incorporated directly into the RNA using T7 RNA polymerase; the second fluorescence labeling step was performed using a post-labeling strategy: directly introducing an rU_amiTP residue into RNA, using T7 RNA polymerase, and then reacting with ylidenemalononitrile enamine (P3). The whole process for the site-specific introduction of the multiple labeled moieties was performed through stepwise RNA-primed RNA polymerization. Interestingly, the resulting multiple-labeled RNA exhibited fluorescence resonance energy transfer (FRET) between the two fluorescent labels in the RNA. We optimized the FRET-breaking point in the RNA by changing of distance between the two fluorescent labels and then used this property for the detection of the structural change of the RNA. The FRET signal increased in intensity upon the transformation of the RNA from a single-strand structure to the G-quadruplex. This approach for site-specific FRET labeling into RNA using RNA polymerase suggests the possibility of performing other diverse site-specific modifications at predefined positions in RNA.

Polymerase-mediated synthesis of p-vinylaniline-coupled fluorescent DNA for the sensing of nucleolin protein-c-myc G-quadruplex interactions

In this paper we report the synthesis of two deoxyuridine derivatives (dUCN2, dUPy)-featuring p-vinylaniline-based fluorophores linked through a propargyl unit at the 5' position-that function as molecular rotors. This probing system proved to be useful for the sensing of gene regulation arising from interactions between this G-quadruplex and nucleolin.