Goychuk Lab

@article{goh_rna_2025,

title = {RNA gradients can guide condensates toward promoters: Implications for enhancer–promoter contacts and condensate-promoter kissing},

author = {David Goh and Deepti Kannan and Pradeep Natarajan and Andriy Goychuk and Arup K. Chakraborty},

url = {https://pubs.aip.org/jcp/article/163/10/104905/3362007/RNA-gradients-can-guide-condensates-toward},

doi = {10.1063/5.0277838},

issn = {0021-9606, 1089-7690},

year  = {2025},

date = {2025-09-01},

urldate = {2026-05-29},

journal = {The Journal of Chemical Physics},

volume = {163},

number = {10},

pages = {104905},

abstract = {We study how protein condensates respond to a site of active RNA transcription (i.e., a gene promoter) due to electrostatic protein–RNA interactions. Our results indicate that condensates can show directed motion toward the promoter, driven by gradients in the RNA concentration. Analytical theory, consistent with simulations, predicts that the droplet velocity has a non-monotonic dependence on the distance to the promoter. We explore the consequences of this gradient-sensing mechanism for enhancer–promoter (E–P) communication using polymer simulations of the intervening chromatin chain. Directed motion of enhancer-bound condensates can, together with loop extrusion by cohesin, collaboratively increase the enhancer–promoter contact probability. Finally, we investigate under which conditions condensates can exhibit oscillations in their morphology and in the distance to the promoter. Oscillatory dynamics are caused by a delayed response of transcription to condensate-promoter contact and negative feedback from the accumulation of RNA at the promoter, which results in charge repulsion.},

keywords = {Biological Physics, Biomolecular Interactions, Chromatin, Gene transcription, Phase transitions, Polymers, Protein-Protein-Interactions, Reentrant, Ribonucleic Acid, Simulation},

pubstate = {published},

tppubtype = {article}

}

@article{goychuk_polymer_2023,

title = {Polymer folding through active processes recreates features of genome organization},

author = {Andriy Goychuk and Deepti Kannan and Arup K. Chakraborty and Mehran Kardar},

url = {https://pnas.org/doi/10.1073/pnas.2221726120},

doi = {10.1073/pnas.2221726120},

issn = {0027-8424, 1091-6490},

year  = {2023},

date = {2023-05-01},

urldate = {2026-05-29},

journal = {Proceedings of the National Academy of Sciences},

volume = {120},

number = {20},

pages = {e2221726120},

abstract = {From proteins to chromosomes, polymers fold into specific conformations that control their biological function. Polymer folding has long been studied with equilibrium thermodynamics, yet intracellular organization and regulation involve energy-consuming, active processes. Signatures of activity have been measured in the context of chromatin motion, which shows spatial correlations and enhanced subdiffusion only in the presence of adenosine triphosphate. Moreover, chromatin motion varies with genomic coordinate, pointing toward a heterogeneous pattern of active processes along the sequence. How do such patterns of activity affect the conformation of a polymer such as chromatin? We address this question by combining analytical theory and simulations to study a polymer subjected to sequence-dependent correlated active forces. Our analysis shows that a local increase in activity (larger active forces) can cause the polymer backbone to bend and expand, while less active segments straighten out and condense. Our simulations further predict that modest activity differences can drive compartmentalization of the polymer consistent with the patterns observed in chromosome conformation capture experiments. Moreover, segments of the polymer that show correlated active (sub)diffusion attract each other through effective long-ranged harmonic interactions, whereas anticorrelations lead to effective repulsions. Thus, our theory offers nonequilibrium mechanisms for forming genomic compartments, which cannot be distinguished from affinity-based folding using structural data alone. As a first step toward exploring whether active mechanisms contribute to shaping genome conformations, we discuss a data-driven approach.},

keywords = {Active Processes, Analytical Theory, Genome Organization, Polymer Mechanics, Simulation, Stochastic Processes},

pubstate = {published},

tppubtype = {article}

}

@article{demarchi_enzyme-enriched_2023,

title = {Enzyme-Enriched Condensates Show Self-Propulsion, Positioning, and Coexistence},

author = {Leonardo Demarchi and Andriy Goychuk and Ivan Maryshev and Erwin Frey},

url = {https://link.aps.org/doi/10.1103/PhysRevLett.130.128401},

doi = {10.1103/PhysRevLett.130.128401},

issn = {0031-9007, 1079-7114},

year  = {2023},

date = {2023-03-01},

urldate = {2026-05-29},

journal = {Physical Review Letters},

volume = {130},

number = {12},

pages = {128401},

abstract = {Enzyme-enriched condensates can organize the spatial distribution of their substrates by catalyzing nonequilibrium reactions. Conversely, an inhomogeneous substrate distribution induces enzyme fluxes through substrate-enzyme interactions. We find that condensates move toward the center of a confining domain when this feedback is weak. Above a feedback threshold, they exhibit self-propulsion, leading to oscillatory dynamics. Moreover, catalysis-driven enzyme fluxes can lead to interrupted coarsening, resulting in equidistant condensate positioning, and to condensate division.},

keywords = {Analytical Theory, Biomolecular Dynamics, Enzymes, Liquid-Liquid Phase Transition, Nonequilibrium Systems, Pattern Formation, Protein-Protein Interactions, Simulation, Traveling Waves},

pubstate = {published},

tppubtype = {article}

}

@article{zhou_quasi-periodic_2020,

title = {Quasi-periodic migration of single cells on short microlanes},

author = {Fang Zhou and Sophia A. Schaffer and Christoph Schreiber and Felix J. Segerer and Andriy Goychuk and Erwin Frey and Joachim O. Rädler},

editor = {Jordi Garcia-Ojalvo},

url = {https://dx.plos.org/10.1371/journal.pone.0230679},

doi = {10.1371/journal.pone.0230679},

issn = {1932-6203},

year  = {2020},

date = {2020-04-01},

urldate = {2026-05-29},

journal = {PLOS ONE},

volume = {15},

number = {4},

pages = {e0230679},

abstract = {Cell migration on microlanes represents a suitable and simple platform for the exploration of the molecular mechanisms underlying cell cytoskeleton dynamics. Here, we report on the quasi-periodic movement of cells confined in stripe-shaped microlanes. We observe persistent polarized cell shapes and directed pole-to-pole motion within the microlanes. Cells depolarize at one end of a given microlane, followed by delayed repolarization towards the opposite end. We analyze cell motility via the spatial velocity distribution, the velocity frequency spectrum and the reversal time as a measure for depolarization and spontaneous repolarization of cells at the microlane ends. The frequent encounters of a boundary in the stripe geometry provides a robust framework for quantitative investigations of the cytoskeleton protrusion and repolarization dynamics. In a first advance to rigorously test physical models of cell migration, we find that the statistics of the cell migration is recapitulated by a Cellular Potts model with a minimal description of cytoskeleton dynamics. Using LifeAct-GFP transfected cells and microlanes with differently shaped ends, we show that the local deformation of the leading cell edge in response to the tip geometry can locally either amplify or quench actin polymerization, while leaving the average reversal times unaffected.},

keywords = {Actin Polymerization, Actins, Cell Migration, Cellular Potts Model, Cytoskeleton, Depolarization, Directed Cell Migration, Simulation, Transfection, Velocity},

pubstate = {published},

tppubtype = {article}

}

@article{thuroff_bridging_2019,

title = {Bridging the gap between single-cell migration and collective dynamics},

author = {Florian Thüroff and Andriy Goychuk and Matthias Reiter and Erwin Frey},

url = {https://elifesciences.org/articles/46842},

doi = {10.7554/eLife.46842},

issn = {2050-084X},

year  = {2019},

date = {2019-12-01},

urldate = {2026-05-29},

journal = {eLife},

volume = {8},

pages = {e46842},

abstract = {Motivated by the wealth of experimental data recently available, we present a cellular-automaton-based modeling framework focussing on high-level cell functions and their concerted effect on cellular migration patterns. Specifically, we formulate a coarse-grained description of cell polarity through self-regulated actin organization and its response to mechanical cues. Furthermore, we address the impact of cell adhesion on collective migration in cell cohorts. The model faithfully reproduces typical cell shapes and movements down to the level of single cells, yet allows for the efficient simulation of confluent tissues. In confined circular geometries, we find that specific properties of individual cells (polarizability; contractility) influence the emerging collective motion of small cell cohorts. Finally, we study the properties of expanding cellular monolayers (front morphology; stress and velocity distributions) at the level of extended tissues.},

keywords = {Cell Migration, Cell Polarization, Cellular Potts Model, Collective Dynamics, Simulation, Wound Healing},

pubstate = {published},

tppubtype = {article}

}