Journal
BIOPHYSICAL JOURNAL
Volume 97, Issue 5, Pages 1288-1294Publisher
CELL PRESS
DOI: 10.1016/j.bpj.2009.06.024
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Funding
- Ministry of Education. Culture, Sports, Science and Technology of Japan
- New Energy and Industrial Technology Development Organization
- Human Frontier Science Program
- Global COE Program Evolving Education and Research Center for Spatio-Temporal Biological Network
- Molecular Ensemble Program at RIKEN
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The nuclear envelope (NE) defines the nuclear compartment, and nuclear pore complexes (NPCs) on the NE form aqueous passages through which small water-soluble molecules can passively diffuse. It is well known that proteins smaller than 50 kDa can diffuse though NPCs, whereas proteins larger than 60 kDa rarely enter by passive diffusion. Little, however, is known about how this size cutoff develops as the NE reassembles and the nucleus expands. In 1987, a well-known study identified an efficient mechanism by which large diffusing proteins (>60 kDa) were excluded from the reassembling nucleus after mitosis. Since then, it has been generally accepted that after mitosis, newly formed nuclei completely exclude all proteins except those that are initially bound to the mitotic chromosomes and those that are selectively imported through NPCs. Here, the tetrameric complex of the photoconvertible fluorescent protein KikGR (similar to 103 kDa) was optically highlighted in the cytoplasm and followed to examine its entry into nuclei. Remarkably, highlighted complexes efficiently entered newly assembled nuclei during an similar to 20-min period after the completion of cytokinesis. Because KikGR contains no known nuclear-localization or chromosome-binding sequences, our results indicate the diffusion barrier is less restrictive during nuclear reassembly.
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