Contemporary oncology (Poznan, Poland)

Biomolecular condensates in cancer cell biology: interleukin-6-induced cytoplasmic and nuclear STAT3/PY-STAT3 condensates in hepatoma cells

• Cancer
• Methods
• Physics of Condensates
• Transcription

Proceedings of the National Academy of Sciences of the United States of America

Spontaneous driving forces give rise to protein-RNA condensates with coexisting phases and complex material properties

• Phase Separation
• Physics of Condensates

bioRxiv

Structure of Biomolecular Condensates from Dissipative Particle Dynamics Simulations

• Methods
• Neurodegeneration
• Phase Separation
• Physics of Condensates

bioRxiv

Structure of Biomolecular Condensates from Dissipative Particle Dynamics Simulations

• Neurodegeneration
• Phase Separation
• Physics of Condensates

Nature

Spatiotemporal regulation of liquid-like condensates in epigenetic inheritance

• Imaging
• Metabolism
• Methods
• Physics of Condensates
• Transcription

bioRxiv

Mechanisms of active regulation of biomolecular condensates

• Phase Separation
• Physics of Condensates
• Transcription

bioRxiv

Phosphoregulation provides functional specificity to biomolecular condensates in the cell cycle and cell polarity

• Physics of Condensates
• Transcription

A Composition-Dependent Molecular Clutch Between T Cell Signaling Condensates and Actin

• Phase Separation
• Physics of Condensates

Journal of virology

Human antiviral protein MxA forms novel metastable membrane-less cytoplasmic condensates exhibiting rapid reversible tonicity-driven phase transitions

• Infectious Disease
• Methods
• Phase Separation
• Physics of Condensates

bioRxiv

Human antiviral protein MxA forms novel metastable membrane-less cytoplasmic condensates exhibiting rapid reversible “crowding”-driven phase transitions

• Infectious Disease
• Phase Separation
• Physics of Condensates