One-Pot Dual Protein Labelling for Simultaneous Mechanical and Fluorescent Readouts in Optical Tweezers

Optical tweezers are widely used in the study of biological macromolecules but are limited by their one-directional probing capability, potentially missing critical conformational changes. Combining fluorescence microscopy with optical tweezers, employing Förster resonance energy transfer (FRET) pairs, addresses this issue. Moreover, attaching one FRET probe to a tethered protein and the other to a protein in solution allows precise localisation of interaction sites, while probing mechanical properties. When integrating fluorescence microscopy with optical tweezers, orthogonal protein conjugation methods are needed to enable simultaneous, site-specific attachment of fluorophores and DNA handles, commonly used to apply force to molecules of interest. In this study, we utilized commercially available reagents for dual site-specific labelling of the homodimeric heat shock protein 90 (Hsp90) using thiol-maleimide and inverse electron demand Diels–Alder cycloaddition (IEDDAC) bioorthogonal reactions. In a one-pot approach, Hsp90 modified with a cysteine mutation and the non-canonical amino acid cyclopropene-L-lysine (CpK) was labelled with the FRET pair maleimide-Atto550 and maleimide-Atto647N, alongside single- stranded methyltetrazine-modified DNA oligonucleotide. Optical tweezers experiments with this labelled Hsp90 construct revealed structural transitions consistent with previous studies, validating the approach. Fluorescence measurements confirmed the proximity of FRET pairs in the N-terminally closed state of Hsp90 in this experimental setup. This integrative method provides a powerful tool for probing protein conformational dynamics and protein interactions beyond the limitations of traditional optical tweezers.