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Literature DB >> 33483232

How Hierarchical Interactions Make Membraneless Organelles Tick Like Clockwork.

Jeremy D Schmit¹, Marina Feric², Miroslav Dundr³.

Abstract

Biomolecular condensates appear throughout the cell, serving many different biochemical functions. We argue that condensate functionality is optimized when the interactions driving condensation vary widely in affinity. Strong interactions provide structural specificity needed to encode functional properties but carry the risk of kinetic arrest, while weak interactions allow the system to remain dynamic but do not restrict the conformational ensemble enough to sustain specific functional features. To support our opinion, we describe illustrative examples of the interplay of strong and weak interactions that are found in the nucleolus, SPOP/DAXX condensates, polySUMO/polySIM condensates, chromatin, and stress granules. The common feature of these systems is a hierarchical assembly motif in which weak, transient interactions condense structurally defined functional units.

Entities: Chemical

Keywords: biomolecular condensates; biophysics; chromatin; liquid-liquid phase separation; membraneless organelles; nucleolus; stress granules

Mesh：

Substances：
Chromatin

Year: 2021 PMID： 33483232 PMCID： PMC8195823 DOI： 10.1016/j.tibs.2020.12.011

Source DB: PubMed Journal: Trends Biochem Sci ISSN： 0968-0004 Impact factor: 14.264

66 in total

1. Phase separation drives heterochromatin domain formation.

Authors: Amy R Strom; Alexander V Emelyanov; Mustafa Mir; Dmitry V Fyodorov; Xavier Darzacq; Gary H Karpen
Journal: Nature Date: 2017-06-21 Impact factor: 49.962

2. Germline P granules are liquid droplets that localize by controlled dissolution/condensation.

Authors: Clifford P Brangwynne; Christian R Eckmann; David S Courson; Agata Rybarska; Carsten Hoege; Jöbin Gharakhani; Frank Jülicher; Anthony A Hyman
Journal: Science Date: 2009-05-21 Impact factor: 47.728

3. Valence and patterning of aromatic residues determine the phase behavior of prion-like domains.

Authors: Erik W Martin; Alex S Holehouse; Ivan Peran; Mina Farag; J Jeremias Incicco; Anne Bremer; Christy R Grace; Andrea Soranno; Rohit V Pappu; Tanja Mittag
Journal: Science Date: 2020-02-07 Impact factor: 47.728

4. Hydrophobic effect in protein folding and other noncovalent processes involving proteins.

Authors: R S Spolar; J H Ha; M T Record
Journal: Proc Natl Acad Sci U S A Date: 1989-11 Impact factor: 11.205

Review 5. Liquid phase condensation in cell physiology and disease.

Authors: Yongdae Shin; Clifford P Brangwynne
Journal: Science Date: 2017-09-22 Impact factor: 47.728

6. Transcription Factors Activate Genes through the Phase-Separation Capacity of Their Activation Domains.

Authors: Ann Boija; Isaac A Klein; Benjamin R Sabari; Alessandra Dall'Agnese; Eliot L Coffey; Alicia V Zamudio; Charles H Li; Krishna Shrinivas; John C Manteiga; Nancy M Hannett; Brian J Abraham; Lena K Afeyan; Yang E Guo; Jenna K Rimel; Charli B Fant; Jurian Schuijers; Tong Ihn Lee; Dylan J Taatjes; Richard A Young
Journal: Cell Date: 2018-11-15 Impact factor: 41.582

7. Composition-dependent thermodynamics of intracellular phase separation.

Authors: Joshua A Riback; Lian Zhu; Mylene C Ferrolino; Michele Tolbert; Diana M Mitrea; David W Sanders; Ming-Tzo Wei; Richard W Kriwacki; Clifford P Brangwynne
Journal: Nature Date: 2020-05-06 Impact factor: 49.962

8. Competing Protein-RNA Interaction Networks Control Multiphase Intracellular Organization.

Authors: David W Sanders; Nancy Kedersha; Daniel S W Lee; Amy R Strom; Victoria Drake; Joshua A Riback; Dan Bracha; Jorine M Eeftens; Allana Iwanicki; Alicia Wang; Ming-Tzo Wei; Gena Whitney; Shawn M Lyons; Paul Anderson; William M Jacobs; Pavel Ivanov; Clifford P Brangwynne
Journal: Cell Date: 2020-04-16 Impact factor: 41.582

9. Compositional adaptability in NPM1-SURF6 scaffolding networks enabled by dynamic switching of phase separation mechanisms.

Authors: Mylene C Ferrolino; Diana M Mitrea; J Robert Michael; Richard W Kriwacki
Journal: Nat Commun Date: 2018-11-29 Impact factor: 14.919

10. RNA self-assembly contributes to stress granule formation and defining the stress granule transcriptome.

Authors: Briana Van Treeck; David S W Protter; Tyler Matheny; Anthony Khong; Christopher D Link; Roy Parker
Journal: Proc Natl Acad Sci U S A Date: 2018-02-26 Impact factor: 11.205

12 in total

1. Assembly of model postsynaptic densities involves interactions auxiliary to stoichiometric binding.

Authors: Yi-Hsuan Lin; Haowei Wu; Bowen Jia; Mingjie Zhang; Hue Sun Chan
Journal: Biophys J Date: 2021-10-09 Impact factor: 4.033

2. An Introduction to the Stickers-and-Spacers Framework as Applied to Biomolecular Condensates.

Authors: Garrett M Ginell; Alex S Holehouse
Journal: Methods Mol Biol Date: 2023

Review 3. A conceptual framework for understanding phase separation and addressing open questions and challenges.

Authors: Tanja Mittag; Rohit V Pappu
Journal: Mol Cell Date: 2022-06-07 Impact factor: 19.328

4. Editorial: Biology of Stress Granules in Plants.

Authors: Monika Chodasiewicz; J C Jang; Emilio Gutierrez-Beltran
Journal: Front Plant Sci Date: 2022-06-09 Impact factor: 6.627

5. Function moves biomolecular condensates in phase space.

Authors: Marina Feric; Tom Misteli
Journal: Bioessays Date: 2022-03-03 Impact factor: 4.653

6. Molecular Coevolution of Nuclear and Nucleolar Localization Signals inside the Basic Domain of HIV-1 Tat.

Authors: Margarita A Kurnaeva; Arthur O Zalevsky; Eugene A Arifulin; Olga M Lisitsyna; Anna V Tvorogova; Maria Y Shubina; Gleb P Bourenkov; Maria A Tikhomirova; Daria M Potashnikova; Anastasia I Kachalova; Yana R Musinova; Andrey V Golovin; Yegor S Vassetzky; Eugene V Sheval
Journal: J Virol Date: 2021-10-06 Impact factor: 6.549