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Super-resolution imaging reveals nucleolar encapsulation by single-stranded DNA.

Koichiro MakiJumpei FukuteTaiji Adachi
Published in: Journal of cell science (2024)
In eukaryotic cell nuclei, specific sets of proteins gather in nuclear bodies and facilitate distinct genomic processes. The nucleolus, a nuclear body, functions as a factory for ribosome biogenesis by accumulating constitutive proteins, such as RNA polymerase I and nucleophosmin 1 (NPM1). Although in vitro assays have suggested the importance of liquid-liquid phase separation (LLPS) of constitutive proteins in nucleolar formation, how the nucleolus is structurally maintained with intranuclear architecture remains unknown. This study revealed that the nucleolus is encapsulated by single-stranded (ss) DNA-based molecular complex inside the cell nucleus. Super-resolution lattice-structured illumination microscopy (lattice-SIM) showed high abundance of ssDNA beyond the "outer shell" of the nucleolus. Nucleolar disruption and the release of NPM1 were caused by in situ digestion of ssDNA, suggesting that ssDNA has a structural role in nucleolar encapsulation. Furthermore, we identified that ssDNA forms molecular complex with histone H1 for nucleolar encapsulation. Thus, this study illustrates how ssDNA-based molecular complex uphold the structural integrity of nuclear bodies to coordinate genomic processes such as gene transcription and replication.
Keyphrases
  • single molecule
  • single cell
  • high resolution
  • cell therapy
  • high throughput
  • gene expression
  • transcription factor
  • genome wide
  • mass spectrometry
  • microbial community
  • high speed
  • fluorescence imaging