Mechanical detection of interactions between proteins related to intermediate filament and transcriptional regulation in living cells.

Intermediate filaments (IF) bind to various proteins and regulate cell function in the cytoplasm. Recently, IFs were found to regulate gene expression by acting as capture scaffolds for transcription-related proteins and preventing their translocation into the nucleus. To reveal such transcriptional regulatory mechanisms controlled by IFs, a method to analyze the interaction between IFs and transcription-related proteins is necessary. Although there are many methods to observe interactions in living cells, it is still challenging to measure protein-protein interactions in living cells in their unmodified and native state. In this study, we utilized a nanoneedle that can access the cytosol by insertion into the cell. Modification of antibody recognizing transcription-related proteins allows the needle to detect mechanical force required to unbind the interaction between antibody and target proteins interacting with IFs during retraction of the needle from the cell. We focused on IF vimentin, a marker of epithelial-mesenchymal transition, to mechanically detect transcription-related proteins trapped by vimentin filaments. Prohibitin 2 (PHB2), a transcription-related factor, was selected as the candidate vimentin-binding protein. We conducted mechanical detection of PHB2 using atomic force microscopy and anti-PHB2 antibody-modified nanoneedles in vimentin-expressing mouse breast cancer and vimentin-knockout (VKO) cells. Significantly larger unbinding forces were detected in the vimentin-expressing cells than in the VKO cells. The results demonstrate that this method is useful for in-cell mechanical detection of IF-binding proteins.