Phase Separation in Living Cells
portes grátis
Phase Separation in Living Cells
Benefits and Risks
Kurokawa, Riki
Springer Verlag, Singapore
10/2023
318
Dura
Inglês
9789819948857
15 a 20 dias
Descrição não disponível.
Chapter 1. FUS aggregation by shear stress on pipetting and its suppression by non-coding RNA.- Chapter 2. Basics and recent advances in computational and theoretical methods for understanding the liquid-liquid phase separation.- Chapter 3.Promotion of liquid-liquid phase separation by G-quadruplex DNA and RNA.- Chapter 4. Phase regulation by chaperons.- Chapter 5. Regulation of aggregation of intrinsically disordered protein through phase separation: Risk management of phase separation.- Chapter 6. Molecular mechanisms of phase transition/separation of protein low-complexity sequences.- Chapter 7. Winding and Tangling. An Initial Phase of Membrane-less Organelle Formation (from a viewpoint of Cajal Bodies).- Chapter 8. Formation and function of phase separated nuclear bodies directed by architectural noncoding RNA.- Chapter 9. Force-dependent remodeling of cell-to-cell adhesion through the regulation of phase separation.- Chapter 10. Neuronal RNA granules: Phase separation, dynamics, and higher brain functions.- Chapter 11. Liquid-liquid phase separation in structure and function of nuclear pore complex.- Chapter 12. Phase Separation Orchestrates Cancer Signaling: Biomolecular condensates as a promising target for cancer therapy.- Chapter 13. Regulatory interaction of intrinsically disordered regions of pathogenic proteins in neurodegenerative diseases.- Chapter 14. Functional properties of phase separation and intranuclear complex of FUS in the pathogenesis of ALS/FTLD.- Chapter 15. Functional responses of microglia to amyloid plaques.- Chapter 16. Emerging role of phage separation in COVID-19.
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Phase separation;Aggregation;intrinsically disordered protein;membrane-less organelle;nuclear pore complex;liquid-liquid phase separation;low complexity domain;noncoding RNA;brain;neurodegenerative disease
Chapter 1. FUS aggregation by shear stress on pipetting and its suppression by non-coding RNA.- Chapter 2. Basics and recent advances in computational and theoretical methods for understanding the liquid-liquid phase separation.- Chapter 3.Promotion of liquid-liquid phase separation by G-quadruplex DNA and RNA.- Chapter 4. Phase regulation by chaperons.- Chapter 5. Regulation of aggregation of intrinsically disordered protein through phase separation: Risk management of phase separation.- Chapter 6. Molecular mechanisms of phase transition/separation of protein low-complexity sequences.- Chapter 7. Winding and Tangling. An Initial Phase of Membrane-less Organelle Formation (from a viewpoint of Cajal Bodies).- Chapter 8. Formation and function of phase separated nuclear bodies directed by architectural noncoding RNA.- Chapter 9. Force-dependent remodeling of cell-to-cell adhesion through the regulation of phase separation.- Chapter 10. Neuronal RNA granules: Phase separation, dynamics, and higher brain functions.- Chapter 11. Liquid-liquid phase separation in structure and function of nuclear pore complex.- Chapter 12. Phase Separation Orchestrates Cancer Signaling: Biomolecular condensates as a promising target for cancer therapy.- Chapter 13. Regulatory interaction of intrinsically disordered regions of pathogenic proteins in neurodegenerative diseases.- Chapter 14. Functional properties of phase separation and intranuclear complex of FUS in the pathogenesis of ALS/FTLD.- Chapter 15. Functional responses of microglia to amyloid plaques.- Chapter 16. Emerging role of phage separation in COVID-19.
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
