Nucleation landscape of biomolecular condensates

Shimobayashi, Shunsuke F.; Ronceray, Pierre; Sanders, David W.; Haataja, Mikko; Brangwynne, Clifford P.

doi:10.1038/s41586-021-03905-5

Cited by 153 publications

(144 citation statements)

References 25 publications

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“…However, in more typical rapidly dividing mammalian cells, nuclear bodies, such as nucleoli and speckles 8,17 , tend to appear following mitosis and coalesce 18 , but then maintain relatively stable sizes until the next cell division, likely in part due to strong mechanical constraints from chromatin [19][20][21][22] . This picture is consistent with other recent work that has taken advantage of synthetic nuclear condensates, which form quickly 23 but grow and coalesce slowly due to their constrained, subdiffusive motion 20 .…”

Section: Introductionsupporting

confidence: 92%

“…Here, we have shown that both native nuclear speckles and synthetic condensates form via a quench-then-coalesce mechanism, which may present a common mechanism for size control of condensates. Indeed, several native organelles within the nucleus, including nuclear speckles 8 but also nucleoli 23 , Cajal bodies 23 , histone locus bodies, paraspeckles, and PML bodies, all disassemble or scatter into the cytoplasm during mitosis 18 , likely due to a combination of dilution and post–translational modifications 19,41 , and then nucleate and regrow in the resulting daughter nuclei. Our results show that a relatively narrow, exponentially decaying size distribution will be attained for simple regrowth driven by coalescence.…”

Section: Discussionmentioning

confidence: 99%

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A rich get richer effect governs intracellular condensate size distributions

Lee

Choi

Sanders

et al. 2022

Preprint

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Phase separation of biomolecules into condensates has emerged as a ubiquitous mechanism for intracellular organization and impacts many intracellular processes, including reaction pathways through clustering of enzymes and their intermediates. Precise and rapid spatiotemporal control of reactions by condensates requires tuning of their sizes. However, the physical processes that govern the distribution of condensate sizes remain unclear. Here, we utilize a combination of synthetic and native condensates to probe the underlying physical mechanisms determining condensate size. We find that both native nuclear speckles and FUS condensates formed with the synthetic Corelet system obey an exponential size distribution, which can be recapitulated in Monte Carlo simulations of fast nucleation followed by coalescence. By contrast, pathological aggregation of cytoplasmic Huntingtin polyQ protein exhibits a power-law size distribution, with an exponent of -1.41±0.02. These distinct behaviors reflect the relative importance of nucleation and coalescence kinetics: introducing continuous condensate nucleation into the Monte Carlo coarsening simulations gives rise to polyQ-like power-law behavior. We demonstrate that the emergence of power-law distributions under continuous nucleation reflects a ''rich get richer'' effect, whose extent may play a general role in the determination of condensate size distributions.

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Section: Introductionsupporting

confidence: 92%

Section: Discussionmentioning

confidence: 99%

A rich get richer effect governs intracellular condensate size distributions

Lee

Choi

Sanders

et al. 2022

Preprint

Self Cite

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“…Recent progresses in multiple loci (Zhou et al 2017) and in super-resolution (Alexander et al 2019;Chen et al 2018;Brandão et al 2020;Barth et al 2020) live imaging would make it possible to test quantitatively the relations between mobility, coherent motion and compaction predicted by our polymer models and the role of basic mechanisms such as phase separation or loop extrusion in regulating chromosome dynamics. For example, live-imaging the coupled structural and dynamical responses of chromatin after rapid in vivo perturbations of the amount of key chromatin-binding complexes using the auxin-inducible-degron system (Schwarzer et al 2017;Dobrinić et al 2021) or after modifications of their self-interacting capacities using optogenetics (Shin et al 2019;Shimobayashi et al 2021) would allow to directly investigate how chromatin dynamics respond to changes in chromatin compaction.…”

Section: Discussionmentioning

confidence: 99%

Spatial organization of chromosomes leads to heterogeneous chromatin motion and drives the liquid- or gel-like dynamical behavior of chromatin

Salari

Stefano

Jost

2021

Preprint

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Chromosome organization and dynamics are involved in the regulation of many fundamental processes such as gene transcription and DNA repair. Experiments unveiled that inside cell nuclei chromatin motion is highly heterogeneous ranging from a liquid-like, mobile state to a gel-like, rigid state. Using polymer modeling, we investigated how these different physical states and dynamical heterogeneities may emerge from the same structural mechanisms. We found that the formation of topologically-associating domains (TADs) is a key driver of chromatin motion heterogeneity. In particular, we demonstrated that the local degree of compaction of the TAD regulates the transition from a weakly compact, fluid state of chromatin to a more compact, gel state exhibiting anomalous diffusion and coherent motion. Our work provides a comprehensive study of chromosome dynamics and offers a unified view of chromatin motion allowing to interpret the wide variety of dynamical behaviors observed experimentally across different biological conditions.

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“…Above a critical radius a * , the free energy of cluster formation overcomes the interfacial penalty, and the new dense phase grows in a thermodynamically downhill fashion. Recently, these ideas from classical nucleation theory were applied to analyze and interpret the dynamics of phase separation in supersaturated solutions in cells (12, 13, 15).…”

Section: Introductionmentioning

confidence: 99%

Phase separating RNA binding proteins form heterogeneous distributions of clusters in subsaturated solutions

Kar

Dar

Welsh

et al. 2022

Preprint

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Macromolecular phase separation is thought to be one of the processes that drive the formation of membraneless biomolecular condensates in cells. The dynamics of phase separation, especially at low endogenous concentrations found in cells, are thought to follow the tenets of classical nucleation theory describing a sharp transition between a dense phase and a dilute phase by dispersed monomers. Here, we used in vitro biophysical studies to study subsaturated solutions of phase separating RNA binding proteins with intrinsically disordered prion like domains (PLDs) and RNA binding domains (RBDs). Surprisingly, we find that subsaturated solutions are characterized by heterogeneous distributions of clusters comprising tens to hundreds of molecules. These clusters also include low abundance mesoscale species that are several hundreds of nanometers in diameter. Our results show that cluster formation in subsaturated solutions and phase separation in supersaturated solutions are strongly coupled via sequence-encoded interactions. Interestingly, however, cluster formation and phase separation can be decoupled from one another using solutes that impact the solubilities of phase separating proteins. They can also be decoupled by specific types of mutations. Overall, our findings implicate the presence of distinct, sequence-specific energy scales that contribute to the overall phase behaviors of RNA binding proteins. We discuss our findings in the context of theories of associative polymers.

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Nucleation landscape of biomolecular condensates

Cited by 153 publications

References 25 publications

A rich get richer effect governs intracellular condensate size distributions

A rich get richer effect governs intracellular condensate size distributions

Spatial organization of chromosomes leads to heterogeneous chromatin motion and drives the liquid- or gel-like dynamical behavior of chromatin

Phase separating RNA binding proteins form heterogeneous distributions of clusters in subsaturated solutions

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