Site-Resolved Observation of Vibrational Energy Transfer Using a Genetically Encoded Ultrafast Heater.
Tobias BaumannMatthias HaufFabian SchildhauerKatharina B EberlPatrick M DurkinErhan DenizJan Gerrit LöfflerCarlos G Acevedo-RochaJelena JaricBerta M MartinsHolger DobbekJens BredenbeckNediljko BudisaPublished in: Angewandte Chemie (International ed. in English) (2019)
Allosteric information transfer in proteins has been linked to distinct vibrational energy transfer (VET) pathways in a number of theoretical studies. Experimental evidence for such pathways, however, is sparse because site-selective injection of vibrational energy into a protein, that is, localized heating, is required for their investigation. Here, we solved this problem by the site-specific incorporation of the non-canonical amino acid β-(1-azulenyl)-l-alanine (AzAla) through genetic code expansion. As an exception to Kasha's rule, AzAla undergoes ultrafast internal conversion and heating after S1 excitation while upon S2 excitation, it serves as a fluorescent label. We equipped PDZ3, a protein interaction domain of postsynaptic density protein 95, with this ultrafast heater at two distinct positions. We indeed observed VET from the incorporation sites in the protein to a bound peptide ligand on the picosecond timescale by ultrafast IR spectroscopy. This approach based on genetically encoded AzAla paves the way for detailed studies of VET and its role in a wide range of proteins.