Small molecule inhibitor of myogenic microRNAs leads to a discovery of miR-221/222-myoD-myomiRs regulatory pathway.

Myogenic microRNAs (myomiRs) that are specifically expressed in cardiac and skeletal muscle are highly relevant to myogenic development and diseases. Discovery and elucidation of unknown myomiRs-involved regulatory pathways in muscle cells are important, but challenging due to the lack of proper molecular tools. We report here a miR-221/222-myoD-myomiRs regulatory pathway revealed by using a small-molecule probe that selectively inhibits myomiRs including miR-1, miR-133a, and miR-206.

Small molecular inhibitors of miR-1 identified from photocycloadducts of acetylenes with 2-methoxy-1,4-naphthalenequinone.

Small molecules which can modulate endogenous microRNAs are important chemical tools to study microRNA regulational network. In this Letter we screened the [2+2] photocycloadducts of 2-methoxy-1,4-naphthalenequinone with a series of aryl acetylenes on their activity to modulate endogenous microRNAs. A potent inhibitor of the muscle-specific miR-1 which is closely related with cardiac development and disease was identified.

Microphotochemistry: a reactor comparison study using the photosensitized addition of isopropanol to furanones as a model reaction.

Three types of micro-photoreactor setups were investigated using DMBP-sensitized additions of isopropanol to furanones as model reactions. The results were compared to experiments using a conventional batch reactor. Based on conversion rates, reactor geometries and energy efficiency calculations the microsystems showed superior performances over the batch process.