Attraction or Repulsion? London Dispersion Forces Control Azobenzene Switches.

Large substituents are commonly seen as entirely repulsive through steric hindrance. Such groups have additional attractive effects arising from weak London dispersion forces between the neutral atoms. Steric interactions are recognized to have a strong influence on isomerization processes, such as in azobenzene-based molecular switches.

Phage selection of photoswitchable peptide ligands.

Photoswitchable ligands are powerful tools to control biological processes at high spatial and temporal resolution. Unfortunately, such ligands exist only for a limited number of proteins and their development by rational design is not trivial. We have developed an in vitro evolution strategy to generate light-activatable peptide ligands to targets of choice.

Measuring net protease activities in biological samples using selective peptidic inhibitors.

The measurement of activities from individual proteases in biological samples is difficult because of the numerous proteases, their overlapping activities, and the lack of specific substrates. We applied selective protease inhibitors based on bicyclic peptides (>2000-fold selective over related proteases) to block individual proteases, allowing the quantification of their net activities. In protease mixtures, activity contributions of the serine proteases plasma kallikrein and urokinase-type plasminogen activator (uPA) were accurately quantified.

Synthesis and photochemical properties of oligo-ortho-azobenzenes.

Azobenzenes have attracted great interest in recent years because of their ability to change conformation upon irradiation. This property has been featured in several applications not only in organic chemistry but also in biology. Even though monoazobenzenes have been extensively studied and documented in the literature, only a few methods are available for the synthesis of oligo-ortho-azobenzenes.