Summary
Lamellipodia are sheet-like protrusions essential for migration and endocytosis, yet the ultrastructure of the actin cytoskeleton during lamellipodia formation remains underexplored. Here, we combined the optogenetic tool PA-Rac1 with cryo-ET to enable ultrastructural analysis of newly formed lamellipodia. We successfully visualized lamellipodia at various extension stages, representing phases of their formation. In minor extensions, several unbundled actin filaments formed “Minor protrusions” at the leading edge. For moderately extended lamellipodia, cross-linked actin filaments formed small filopodia-like structures, termed “mini filopodia.” In fully extended lamellipodia, filopodia matured at multiple points, and cross-linked actin filaments running nearly parallel to the leading edge increased throughout the lamellipodia. These observations suggest that actin polymerization begins in specific plasma membrane regions, forming mini filopodia that either mature into full filopodia or detach from the leading edge to form parallel filaments. This actin turnover likely drives lamellipodial protrusion, providing new insights into actin dynamics and cell migration.
Competing Interest Statement
Kazuhiro Aoyama is affiliated with Thermo Fisher Scientific.
Footnotes
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Abbreviations
- Cryo-EM
- cryogenic transmission microscopy
- Cryo-ET
- cryogenic electron tomography
- CLEM
- correlative light and electron microscopy
- ECM
- extracellular matrix
- EM
- electron microscopy
- PA-Rac1
- photoactivatable Rac1
- LM
- light microscopy
- LLPS
- liquid-liquid phase separation
- MTs
- microtubules