Ultrafast single-molecule imaging reveals focal adhesion nano-architecture and molecular dynamics.
Takahiro K FujiwaraTaka A TsunoyamaShinji TakeuchiZiya KalayYosuke NagaiThomas KalkbrennerYuri L NemotoLimin H ChenAkihiro C E ShibataKokoro IwasawaKen P RitchieKenichi G N SuzukiAkihiro KusumiPublished in: The Journal of cell biology (2023)
Using our newly developed ultrafast camera described in the companion paper, we reduced the data acquisition periods required for photoactivation/photoconversion localization microscopy (PALM, using mEos3.2) and direct stochastic reconstruction microscopy (dSTORM, using HMSiR) by a factor of ≈30 compared with standard methods, for much greater view-fields, with localization precisions of 29 and 19 nm, respectively, thus opening up previously inaccessible spatiotemporal scales to cell biology research. Simultaneous two-color PALM-dSTORM and PALM-ultrafast (10 kHz) single fluorescent-molecule imaging-tracking has been realized. They revealed the dynamic nanoorganization of the focal adhesion (FA), leading to the compartmentalized archipelago FA model, consisting of FA-protein islands with broad diversities in size (13-100 nm; mean island diameter ≈30 nm), protein copy numbers, compositions, and stoichiometries, which dot the partitioned fluid membrane (74-nm compartments in the FA vs. 109-nm compartments outside the FA). Integrins are recruited to these islands by hop diffusion. The FA-protein islands form loose ≈320 nm clusters and function as units for recruiting FA proteins.
Keyphrases
- single molecule
- photodynamic therapy
- molecular dynamics
- high resolution
- living cells
- protein protein
- amino acid
- single cell
- biofilm formation
- high speed
- escherichia coli
- binding protein
- cell therapy
- mesenchymal stem cells
- light emitting
- mass spectrometry
- small molecule
- fluorescence imaging
- electronic health record
- cystic fibrosis
- big data
- cell adhesion