Phase Separation: A New Dimension to Understanding Tumor Biology and Therapy

Xingwen Wang; Minqiao Lu; Yi Zhang; Jiangwen Ma; Ying Hu

doi:10.1002/mog2.70018

MEDCOMM - Oncology ›› 2025, Vol. 4 ›› Issue (2) : e70018 DOI: 10.1002/mog2.70018

REVIEW ARTICLE

Phase Separation: A New Dimension to Understanding Tumor Biology and Therapy

Xingwen Wang ¹^,²
, Minqiao Lu ¹^,²
, Yi Zhang ¹^,²
, Jiangwen Ma ¹^,²
, Ying Hu ¹^,²

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Abstract

Liquid–liquid phase separation (LLPS) plays a critical role in orchestrating various cellular processes, such as gene expression, signal transduction, and protein synthesis, by compartmentalizing cellular components without membrane boundaries. Emerging research has illuminated how dysregulated LLPS is integral to cancer development by influencing tumorigenesis, metastasis, immune system evasion, and resistance to therapy. The subtle differences in LLPS are crucial for understanding cancer progression and finding new treatments. However, despite its significant implications in oncology, the potential of specifically targeting LLPS in cancer therapy has not been thoroughly investigated. This review delves into the mechanisms of LLPS, exploring physiological triggers and their consequences in cancer biology. We discuss the profound impact of LLPS on the hallmarks of cancer and outline innovative strategies aimed at targeting LLPS. These strategies include the direct inhibition of phase condensate formation and the modulation of related signaling pathways. Although targeting LLPS poses several challenges, such as specificity and delivery methods, it represents a promising frontier in cancer treatment, potentially revolutionizing how we approach cancer therapy. This review emphasizes the academic and therapeutic importance of LLPS, advocating for it as an exciting and valuable target for future cancer treatment strategies.

Keywords

biomolecular condensate / phase separation / tumor biology / tumor therapy

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Xingwen Wang, Minqiao Lu, Yi Zhang, Jiangwen Ma, Ying Hu. Phase Separation: A New Dimension to Understanding Tumor Biology and Therapy. MEDCOMM - Oncology, 2025, 4(2): e70018 DOI:10.1002/mog2.70018

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	D. Hanahan, “Hallmarks of Cancer: New Dimensions,” Cancer Discovery 12, no. 1 (2022): 31–46.

[2]	S. F. Banani, H. O. Lee, A. A. Hyman, and M. K. Rosen, “Biomolecular Condensates: Organizers of Cellular Biochemistry,” Nature Reviews Molecular Cell Biology 18, no. 5 (2017): 285–298.

[3]	S. Alberti, A. Gladfelter, and T. Mittag, “Considerations and Challenges in Studying Liquid–Liquid Phase Separation and Biomolecular Condensates,” Cell 176, no. 3 (2019): 419–434.

[4]	Y. Dai, L. You, and A. Chilkoti, “Engineering Synthetic Biomolecular Condensates,” Nature Reviews Bioengineering 1 (2023): 466–480.

[5]	B. Wang, L. Zhang, T. Dai, et al., “Liquid–Liquid Phase Separation in Human Health and Diseases,” Signal Transduction and Targeted Therapy 6, no. 1 (2021): 290.

[6]	X. Tong, R. Tang, J. Xu, et al., “Liquid–Liquid Phase Separation in Tumor Biology,” Signal Transduction and Targeted Therapy 7, no. 1 (2022): 221.

[7]	A. Boija, I. A. Klein, and R. A. Young, “Biomolecular Condensates and Cancer,” Cancer Cell 39, no. 2 (2021): 174–192.

[8]	S. Mehta and J. Zhang, “Liquid–Liquid Phase Separation Drives Cellular Function and Dysfunction in Cancer,” Nature Reviews Cancer 22, no. 4 (2022): 239–252.

[9]	T. Pederson, “The Nucleolus,” Cold Spring Harbor Perspectives in Biology 3, no. 3 (2011): a000638.

[10]	T. Hirose, K. Ninomiya, S. Nakagawa, and T. Yamazaki, “A Guide to Membraneless Organelles and Their Various Roles in Gene Regulation,” Nature Reviews Molecular Cell Biology 24, no. 4 (2023): 288–304.

[11]	C. M. Gallo, J. T. Wang, F. Motegi, and G. Seydoux, “Cytoplasmic Partitioning of P Granule Components Is Not Required to Specify the Germline in C. Elegans,” Science 330, no. 6011 (2010): 1685–1689.

[12]	E. B. Wilson, “The Structure of Protoplasm,” Science 10, no. 237 (1899): 33–45.

[13]	A. A. Hyman and C. P. Brangwynne, “Beyond Stereospecificity: Liquids and Mesoscale Organization of Cytoplasm,” Developmental Cell 21, no. 1 (2011): 14–16.

[14]	C. R. Landry, E. D. Levy, D. Abd Rabbo, K. Tarassov, and S. W. Michnick, “Extracting Insight From Noisy Cellular Networks,” Cell 155, no. 5 (2013): 983–989.

[15]	K. Tarassov, V. Messier, C. R. Landry, et al., “An In Vivo Map of the Yeast Protein Interactome,” Science 320, no. 5882 (2008): 1465–1470.

[16]	L. P. Bergeron-Sandoval, N. Safaee, and S. W. Michnick, “Mechanisms and Consequences of Macromolecular Phase Separation,” Cell 165, no. 5 (2016): 1067–1079.

[17]	C. P. Brangwynne, “Phase Transitions and Size Scaling of Membrane-Less Organelles,” Journal of Cell Biology 203, no. 6 (2013): 875–881.

[18]	Y. Shin and C. P. Brangwynne, “Liquid Phase Condensation in Cell Physiology and Disease,” Science 357, no. 6357 (2017): aaf4382.

[19]	C. P. Brangwynne, C. R. Eckmann, D. S. Courson, et al., “Germline P Granules Are Liquid Droplets That Localize by Controlled Dissolution/Condensation,” Science 324, no. 5935 (2009): 1729–1732.

[20]	P. Li, S. Banjade, H. C. Cheng, et al., “Phase Transitions in the Assembly of Multivalent Signalling Proteins,” Nature 483, no. 7389 (2012): 336–340.

[21]	M. Kato, T. W. Han, S. Xie, et al., “Cell-Free Formation of RNA Granules: Low Complexity Sequence Domains Form Dynamic Fibers Within Hydrogels,” Cell 149, no. 4 (2012): 753–767.

[22]	A. T. Hertig, “The Primary Human Oocyte: Some Observations on the Fine Structure of Balbiani's Vitelline Body and the Origin of the Annulate Lamellae,” American Journal of Anatomy 122, no. 1 (1968): 107–137.

[23]	J. G. Gall, “The Centennial of the Cajal Body,” Nature Reviews Molecular Cell Biology 4, no. 12 (2003): 975–980.

[24]	H. Schatten and Q. Y. Sun, “The Role of Centrosomes in Fertilization, Cell Division and Establishment of Asymmetry During Embryo Development,” Seminars in Cell & Developmental Biology 21, no. 2 (2010): 174–184.

[25]	M. A. Dobrynin, E. O. Bashendjieva, and N. I. Enukashvily, “Germ Granules in Animal Oogenesis,” Journal of Developmental Biology 10, no. 4 (2022): 43.

[26]	R. Ma, Y. Zhang, J. Zhang, et al., “Targeting Pericentric Non-Consecutive Motifs for Heterochromatin Initiation,” Nature 631, no. 8021 (2024): 678–685.

[27]	M. Lafarga, I. Casafont, R. Bengoechea, O. Tapia, and M. T. Berciano, “Cajal's Contribution to the Knowledge of the Neuronal Cell Nucleus,” Chromosoma 118, no. 4 (2009): 437–443.

[28]	A. H. Fox, Y. W. Lam, A. K. L. Leung, et al., “Paraspeckles,” Current Biology 12, no. 1 (2002): 13–25.

[29]	H. de Thé, C. Chomienne, M. Lanotte, L. Degos, and A. Dejean, “The t(15;17) Translocation of Acute Promyelocytic Leukaemia Fuses the Retinoic Acid Receptor α Gene to a Novel Transcribed Locus,” Nature 347, no. 6293 (1990): 558–561.

[30]	N. L. Kedersha, M. Gupta, W. Li, I. Miller, and P. Anderson, “RNA-Binding Proteins Tia-1 and Tiar Link the Phosphorylation of Eif-2α to the Assembly of Mammalian Stress Granules,” Journal of Cell Biology 147, no. 7 (1999): 1431–1442.

[31]	J. Lovén, H. A. Hoke, C. Y. Lin, et al., “Selective Inhibition of Tumor Oncogenes by Disruption of Super-Enhancers,” Cell 153, no. 2 (2013): 320–334.

[32]	T. Murakami, S. Qamar, J. Q. Lin, et al., “ALS/FTD Mutation-Induced Phase Transition of FUS Liquid Droplets and Reversible Hydrogels Into Irreversible Hydrogels Impairs RNP Granule Function,” Neuron 88, no. 4 (2015): 678–690.

[33]	D. Sun, R. Wu, J. Zheng, P. Li, and L. Yu, “Polyubiquitin Chain-Induced p62 Phase Separation Drives Autophagic Cargo Segregation,” Cell Research 28, no. 4 (2018): 405–415.

[34]	X. Yu, L. Zhang, J. Shen, et al., “The STING Phase-Separator Suppresses Innate Immune Signalling,” Nature Cell Biology 23, no. 4 (2021): 330–340.

[35]	J. Ren, Z. Zhang, Z. Zong, L. Zhang, and F. Zhou, “Emerging Implications of Phase Separation in Cancer,” Advanced Science 9, no. 31 (2022): e2202855.

[36]	W. Y. C. Huang, S. Alvarez, Y. Kondo, et al., “A Molecular Assembly Phase Transition and Kinetic Proofreading Modulate Ras Activation by SOS,” Science 363, no. 6431 (2019): 1098–1103.

[37]	X. Su, J. A. Ditlev, E. Hui, et al., “Phase Separation of Signaling Molecules Promotes T Cell Receptor Signal Transduction,” Science 352, no. 6285 (2016): 595–599.

[38]	S. Banjade, Q. Wu, A. Mittal, W. B. Peeples, R. V. Pappu, and M. K. Rosen, “Conserved Interdomain Linker Promotes Phase Separation of the Multivalent Adaptor Protein Nck,” Proceedings of the National Academy of Sciences 112, no. 47 (2015): E6426–E6435.

[39]	S. A. Fromm, J. Kamenz, E. R. Nöldeke, A. Neu, G. Zocher, and R. Sprangers, “In Vitro Reconstitution of a Cellular Phase-Transition Process That Involves the mRNA Decapping Machinery,” Angewandte Chemie International Edition 53, no. 28 (2014): 7354–7359.

[40]	D. M. Mitrea, J. A. Cika, C. S. Guy, et al., “Nucleophosmin Integrates Within the Nucleolus via Multi-Modal Interactions With Proteins Displaying R-Rich Linear Motifs and rRNA,” eLife 5 (2016): 13571.

[41]	M. Zeng, Y. Shang, Y. Araki, T. Guo, R. L. Huganir, and M. Zhang, “Phase Transition in Postsynaptic Densities Underlies Formation of Synaptic Complexes and Synaptic Plasticity,” Cell 166, no. 5 (2016): 1163–1175.

[42]	M. J. Cuneo, B. G. O'Flynn, Y. H. Lo, N. Sabri, and T. Mittag, “Higher-Order SPOP Assembly Reveals a Basis for Cancer Mutant Dysregulation,” Molecular Cell 83, no. 5 (2023): 731–745.

[43]	W. Wang, S. Qiao, G. Li, et al., “A Histidine Cluster Determines YY1-Compartmentalized Coactivators and Chromatin Elements in Phase-Separated Enhancer Clusters,” Nucleic Acids Research 50, no. 9 (2022): 4917–4937.

[44]	F. Ding, Y. Zhao, H. Liu, and W. Zhang, “Core-Shell Magnetic Microporous Covalent Organic Framework With Functionalized Ti(iv) for Selective Enrichment of Phosphopeptides,” Analyst 145, no. 12 (2020): 4341–4351.

[45]	T. Tan, B. Gao, H. Yu, et al., “Dynamic Nucleolar Phase Separation Influenced by Non-Canonical Function of LIN28A Instructs Pluripotent Stem Cell Fate Decisions,” Nature Communications 15, no. 1 (2024): 1256.

[46]	C. Shen, R. Li, R. Negro, et al., “Phase Separation Drives RNA Virus-Induced Activation of the NLRP6 Inflammasome,” Cell 184, no. 23 (2021): 5759–5774.

[47]	I. Kwon, M. Kato, S. Xiang, et al., “Phosphorylation-Regulated Binding of RNA Polymerase II to Fibrous Polymers of Low-Complexity Domains,” Cell 155, no. 5 (2013): 1049–1060.

[48]	X. Zhou, L. Sumrow, K. Tashiro, et al., “Mutations Linked to Neurological Disease Enhance Self-Association of Low-Complexity Protein Sequences,” Science 377, no. 6601 (2022): eabn5582.

[49]	T. Qiu, Y. Kong, G. Wei, et al., “CCDC6-RET Fusion Protein Regulates Ras/MAPK Signaling Through the Fusion-GRB2-SHC1 Signal Niche,” Proceedings of the National Academy of Sciences 121, no. 23 (2024): e2322359121.

[50]	N. Chappidi, T. Quail, S. Doll, et al., “PARP1-DNA Co-Condensation Drives DNA Repair Site Assembly to Prevent Disjunction of Broken DNA Ends,” Cell 187, no. 4 (2024): 945–961.

[51]	J. Guillén-Boixet, A. Kopach, A. S. Holehouse, et al., “RNA-Induced Conformational Switching and Clustering of G3BP Drive Stress Granule Assembly by Condensation,” Cell 181, no. 2 (2020): 346–361.

[52]	P. Yang, C. Mathieu, R. M. Kolaitis, et al., “G3BP1 Is a Tunable Switch That Triggers Phase Separation to Assemble Stress Granules,” Cell 181, no. 2 (2020): 325–345.

[53]	M. Du and Z. J. Chen, “DNA-Induced Liquid Phase Condensation of cGAS Activates Innate Immune Signaling,” Science 361, no. 6403 (2018): 704–709.

[54]	J. Wang, L. Wang, J. Diao, et al., “Binding to m(6)A RNA Promotes YTHDF2-mediated Phase Separation,” Protein & Cell 11, no. 4 (2020): 304–307.

[55]	X. Liu, Y. Xiong, C. Zhang, et al., “G-Quadruplex-Induced Liquid–Liquid Phase Separation in Biomimetic Protocells,” Journal of the American Chemical Society 143, no. 29 (2021): 11036–11043.

[56]	C. P. Brangwynne, P. Tompa, and R. V. Pappu, “Polymer Physics of Intracellular Phase Transitions,” Nature Physics 11, no. 11 (2015): 899–904.

[57]	H. Falahati and A. Haji-Akbari, “Thermodynamically Driven Assemblies and Liquid–Liquid Phase Separations in Biology,” Soft Matter 15, no. 6 (2019): 1135–1154.

[58]	P. Pullara, I. Alshareedah, and P. R. Banerjee, “Temperature-Dependent Reentrant Phase Transition of RNA-Polycation Mixtures,” Soft Matter 18, no. 7 (2022): 1342–1349.

[59]	T. P. Dao, R. M. Kolaitis, H. J. Kim, et al., “Ubiquitin Modulates Liquid–Liquid Phase Separation of UBQLN2 via Disruption of Multivalent Interactions,” Molecular Cell 69, no. 6 (2018): 965–978.

[60]	J. A. Riback, C. D. Katanski, J. L. Kear-Scott, et al., “Stress-Triggered Phase Separation Is an Adaptive, Evolutionarily Tuned Response,” Cell 168, no. 6 (2017): 1028–1040.

[61]	T. M. Franzmann, M. Jahnel, A. Pozniakovsky, et al., “Phase Separation of a Yeast Prion Protein Promotes Cellular Fitness,” Science 359, no. 6371 (2018): eaao5654.

[62]	J. P. Brady, P. J. Farber, A. Sekhar, et al., “Structural and Hydrodynamic Properties of an Intrinsically Disordered Region of a Germ Cell-Specific Protein on Phase Separation,” Proceedings of the National Academy of Sciences 114, no. 39 (2017): E8194-e203.

[63]	G. Krainer, T. J. Welsh, J. A. Joseph, et al., “Reentrant Liquid Condensate Phase of Proteins Is Stabilized by Hydrophobic and Non-Ionic Interactions,” Nature Communications 12, no. 1 (2021): 1085.

[64]	G. Zhang, Z. Wang, Z. Du, and H. Zhang, “mTOR Regulates Phase Separation of PGL Granules to Modulate Their Autophagic Degradation,” Cell 174, no. 6 (2018): 1492–1506.

[65]	H. Zhang, S. Shao, Y. Zeng, et al., “Reversible Phase Separation of HSF1 Is Required for an Acute Transcriptional Response During Heat Shock,” Nature Cell Biology 24, no. 3 (2022): 340–352.

[66]	Y. Wu, L. Zhou, Y. Zou, et al., “Disrupting the Phase Separation of KAT8-IRF1 Diminishes PD-L1 Expression and Promotes Antitumor Immunity,” Nature Cancer 4, no. 3 (2023): 382–400.

[67]	Z. Qin, X. Fang, W. Sun, et al., “Deactylation by SIRT1 Enables Liquid–Liquid Phase Separation of IRF3/IRF7 In Innate Antiviral Immunity,” Nature Immunology 23, no. 8 (2022): 1193–1207.

[68]	Y. Fujioka, J. M. Alam, D. Noshiro, et al., “Phase Separation Organizes the Site of Autophagosome Formation,” Nature 578, no. 7794 (2020): 301–305.

[69]	T. Zhao, X. Yang, G. Duan, et al., “Phosphorylation-Regulated Phase Separation of Syndecan-4 and Syntenin Promotes the Biogenesis of Exosomes,” Cell Proliferation 57, no. 10 (2024): e13645.

[70]	M. Hofweber, S. Hutten, B. Bourgeois, et al., “Phase Separation of FUS Is Suppressed by Its Nuclear Import Receptor and Arginine Methylation,” Cell 173, no. 3 (2018): 706–719.

[71]	C. Yang, Z. Wang, Y. Kang, et al., “Stress Granule Homeostasis Is Modulated by TRIM21-mediated Ubiquitination of G3BP1 and Autophagy-Dependent Elimination of Stress Granules,” Autophagy 19, no. 7 (2023): 1934–1951.

[72]	T. Nakamura, C. Hipp, A. Santos Dias Mourão, et al., “Phase Separation of FSP1 Promotes Ferroptosis,” Nature 619, no. 7969 (2023): 371–377.

[73]	Z. Zong, F. Xie, S. Wang, et al., “Alanyl-tRNA Synthetase, AARS1, Is a Lactate Sensor and Lactyltransferase That Lactylates p53 and Contributes to Tumorigenesis,” Cell 187, no. 10 (2024): 2375–2392.

[74]	K. Kamagata, S. Kanbayashi, M. Honda, et al., “Liquid-Like Droplet Formation by Tumor Suppressor p53 Induced by Multivalent Electrostatic Interactions Between Two Disordered Domains,” Scientific Reports 10, no. 1 (2020): 580.

[75]	S. Sanulli, M. J. Trnka, V. Dharmarajan, et al., “HP1 Reshapes Nucleosome Core to Promote Phase Separation of Heterochromatin,” Nature 575, no. 7782 (2019): 390–394.

[76]	A. Shakya, S. Park, N. Rana, and J. T. King, “Liquid–Liquid Phase Separation of Histone Proteins in Cells: Role in Chromatin Organization,” Biophysical Journal 118, no. 3 (2020): 753–764.

[77]	W. Sun, Q. Dong, X. Li, et al., “The SUN-Family Protein Sad1 Mediates Heterochromatin Spatial Organization Through Interaction With Histone H2A-H2B,” Nature Communications 15, no. 1 (2024): 4322.

[78]	E. F. Hammonds, M. C. Harwig, E. A. Paintsil, E. A. Tillison, R. B. Hill, and E. A. Morrison, “Histone H3 and H4 Tails Play an Important Role in Nucleosome Phase Separation,” Biophysical Chemistry 283 (2022): 106767.

[79]	J. Lou, Q. Deng, X. Zhang, et al., “Heterochromatin Protein 1 Alpha (HP1α) Undergoes a Monomer to Dimer Transition That Opens and Compacts Live Cell Genome Architecture,” Nucleic Acids Research 52 (2024): 10918–10933.

[80]	R. Pantier, M. Brown, S. Han, et al., “MeCP2 Binds to Methylated DNA Independently of Phase Separation and Heterochromatin Organisation,” Nature Communications 15, no. 1 (2024): 3880.

[81]	W. Li, L. Wu, H. Jia, et al., “The Low-Complexity Domains of the KMT2D Protein Regulate Histone Monomethylation Transcription to Facilitate Pancreatic Cancer Progression,” Cellular & Molecular Biology Letters 26, no. 1 (2021): 45.

[82]	S. Bhattacharya, J. J. Lange, M. Levy, L. Florens, M. P. Washburn, and J. L. Workman, “The Disordered Regions of the Methyltransferase SETD2 Govern Its Function by Regulating Its Proteolysis and Phase Separation,” Journal of Biological Chemistry 297, no. 3 (2021): 101075.

[83]	B. Shi, W. Li, and H. Jiang, “Epigenetic Condensates Regulate Chromatin Activity and Tumorigenesis,” Molecular & Cellular Oncology 8, no. 5 (2021): 1997040.

[84]	Y. He, S. Wang, S. Liu, et al., “MSL1 Promotes Liver Regeneration by Driving Phase Separation of STAT3 and Histone H4 and Enhancing Their Acetylation,” Advanced Science 10, no. 23 (2023): e2301094.

[85]	B. Lu, R. Qiu, J. Wei, et al., “Phase Separation of Phospho-HDAC6 Drives Aberrant Chromatin Architecture in Triple-Negative Breast Cancer,” Nature Cancer 5 (2024): 1622–1640.

[86]	Y. Hagihara, S. Asada, T. Maeda, T. Nakano, and S. Yamaguchi, “Tet1 Regulates Epigenetic Remodeling of the Pericentromeric Heterochromatin and Chromocenter Organization in DNA Hypomethylated Cells,” PLoS Genetics 17, no. 6 (2021): e1009646.

[87]	D. Flores-Solis, I. P. Lushpinskaia, A. A. Polyansky, et al., “Driving Forces Behind Phase Separation of the Carboxy-Terminal Domain of RNA Polymerase II,” Nature Communications 14, no. 1 (2023): 5979.

[88]	L. Zuo, G. Zhang, M. Massett, et al., “Loci-Specific Phase Separation of FET Fusion Oncoproteins Promotes Gene Transcription,” Nature Communications 12, no. 1 (2021): 1491.

[89]	A. Boija, I. A. Klein, B. R. Sabari, et al., “Transcription Factors Activate Genes Through the Phase-Separation Capacity of Their Activation Domains,” Cell 175, no. 7 (2018): 1842–1855.

[90]	X. Zheng, K. Diktonaite, and H. Qiu, “Epigenetic Reader Bromodomain-Containing Protein 4 in Aging-Related Vascular Pathologies and Diseases: Molecular Basis, Functional Relevance, and Clinical Potential,” Biomolecules 13, no. 7 (2023): 1135.

[91]	D. Cai, D. Feliciano, P. Dong, et al., “Phase Separation of YAP Reorganizes Genome Topology for Long-Term YAP Target Gene Expression,” Nature Cell Biology 21, no. 12 (2019): 1578–1589.

[92]	M. Yu, Z. Peng, M. Qin, et al., “Interferon-γ Induces Tumor Resistance to Anti-PD-1 Immunotherapy by Promoting YAP Phase Separation,” Molecular Cell 81, no. 6 (2021): 1216–1230.

[93]	Q. Peng, L. Wang, Z. Qin, et al., “Phase Separation of Epstein-Barr Virus EBNA2 and Its Coactivator EBNALP Controls Gene Expression,” Journal of Virology 94, no. 7 (2020): e01771-19.

[94]	G. Tang, H. Xia, Y. Huang, et al., “Liquid–Liquid Phase Separation of H3K27me3 Reader BP1 Regulates Transcriptional Repression,” Genome Biology 25, no. 1 (2024): 67.

[95]	A. Hu, G. Chen, B. Bao, et al., “Therapeutic Targeting of CNBP Phase Separation Inhibits Ribosome Biogenesis and Neuroblastoma Progression via Modulating SWI/SNF Complex Activity,” Clinical and Translational Medicine 13, no. 4 (2023): e1235.

[96]	D. Ji, C. Shao, J. Yu, et al., “FOXA1 Forms Biomolecular Condensates That Unpack Condensed Chromatin to Function as a Pioneer Factor,” Molecular Cell 84, no. 2 (2024): 244–260.

[97]	Y. Zhou, R. Niu, Z. Tang, et al., “Plant HEM1 Specifies a Condensation Domain to Control Immune Gene Translation,” Nature Plants 9, no. 2 (2023): 289–301.

[98]	L. Li, L. Yao, M. Wang, X. Zhou, and Y. Xu, “Phase Separation in DNA Damage Response: New Insights Into Cancer Development and Therapy,” Biochimica et Biophysica Acta (BBA)—Reviews on Cancer 1879, no. 6 (2024): 189206.

[99]	R. Zavaliev, R. Mohan, T. Chen, and X. Dong, “Formation of NPR1 Condensates Promotes Cell Survival During the Plant Immune Response,” Cell 182, no. 5 (2020): 1093–1108.

[100]

J. Y. Kang, Z. Wen, D. Pan, et al., “LLPs of FXR1 Drives Spermiogenesis by Activating Translation of Stored mRNAs,” Science 377, no. 6607 (2022): eabj6647.

[101]

L. Yang, Z. Zhang, P. Jiang, et al., “Phase Separation-Competent FBL Promotes Early Pre-rRNA Processing and Translation in Acute Myeloid Leukaemia,” Nature Cell Biology 26, no. 6 (2024): 946–961.

[102]

B. Shi, J. Heng, J. Y. Zhou, et al., “Phase Separation of Ddx3xb Helicase Regulates Maternal-to-Zygotic Transition in Zebrafish,” Cell Research 32, no. 8 (2022): 715–728.

[103]

Y. Chen, R. Wan, Z. Zou, et al., “O-GlcNAcylation Determines the Translational Regulation and Phase Separation of YTHDF Proteins,” Nature Cell Biology 25, no. 11 (2023): 1676–1690.

[104]

Y. Zhuang, Z. Li, S. Xiong, et al., “Circadian Clocks Are Modulated by Compartmentalized Oscillating Translation,” Cell 186, no. 15 (2023): 3245–3260.

[105]

D. Schlütermann, N. Berleth, J. Deitersen, et al., “FIP200 Controls the TBK1 Activation Threshold at SQSTM1/p62-Positive Condensates,” Scientific Reports 11, no. 1 (2021): 13863.

[106]

X. Shi, A. L. Yokom, C. Wang, L. N. Young, R. J. Youle, and J. H. Hurley, “ULK Complex Organization in Autophagy by a C-Shaped FIP200 N-Terminal Domain Dimer,” Journal of Cell Biology 219, no. 7 (2020): e201911047.

[107]

T. P. López-Palacios and J. L. Andersen, “Kinase Regulation by Liquid–Liquid Phase Separation,” Trends in Cell Biology 33, no. 8 (2023): 649–666.

[108]

X. Niu, L. Zhang, Y. Wu, et al., “Biomolecular Condensates: Formation Mechanisms, Biological Functions, and Therapeutic Targets,” MedComm 4, no. 2 (2023): e223.

[109]

L. L. Feng, S. Y. Bie, Z. H. Deng, et al., “Ubiquitin-Induced RNF168 Condensation Promotes DNA Double-Strand Break Repair,” Proceedings of the National Academy of Sciences 121, no. 28 (2024): e2322972121.

[110]

K. Bao, Y. Ma, Y. Li, et al., “A Di-Acetyl-Decorated Chromatin Signature Couples Liquid Condensation to Suppress DNA End Synapsis,” Molecular Cell 84, no. 7 (2024): 1206–1223.

[111]

G. Zhu, J. Xie, W. Kong, et al., “Phase Separation of Disease-Associated SHP2 Mutants Underlies MAPK Hyperactivation,” Cell 183, no. 2 (2020): 490–502.

[112]

S. Kilic, A. Lezaja, M. Gatti, et al., “Phase Separation of 53BP1 Determines Liquid-Like Behavior of DNA Repair Compartments,” EMBO Journal 38, no. 16 (2019): e101379.

[113]

L. Bian, Y. Meng, M. Zhang, and D. Li, “MRE11-RAD50-NBS1 Complex Alterations and DNA Damage Response: Implications for Cancer Treatment,” Molecular Cancer 18, no. 1 (2019): 169.

[114]

B. R. Levone, S. C. Lenzken, M. Antonaci, et al., “FUS-Dependent Liquid–Liquid Phase Separation Is Important for DNA Repair Initiation,” Journal of Cell Biology 220, no. 5 (2021): e202008030.

[115]

H. Fu, R. Liu, Z. Jia, et al., “Poly(ADP-Ribosylation) of P-TEFb by PARP1 Disrupts Phase Separation to Inhibit Global Transcription After DNA Damage,” Nature Cell Biology 24, no. 4 (2022): 513–525.

[116]

X. J. Fan, Y. L. Wang, W. W. Zhao, et al., “NONO Phase Separation Enhances DNA Damage Repair by Accelerating Nuclear EGFR-Induced DNA-PK Activation,” American Journal of Cancer Research 11, no. 6 (2021): 2838–2852.

[117]

Y. Hu, Q. Xie, S. Chen, et al., “Par3 Promotes Breast Cancer Invasion and Migration Through Pull Tension and Protein Nanoparticle-Induced Osmotic Pressure,” Biomedicine & Pharmacotherapy 155 (2022): 113739.

[118]

Y. Zhang, L. Yan, Z. Zhou, et al., “SEPA-1 Mediates the Specific Recognition and Degradation of P Granule Components by Autophagy in C. Elegans,” Cell 136, no. 2 (2009): 308–321.

[119]

B. Guan and H. W. Xue, “Arabidopsis Autophagy-Related3 (ATG3) Facilitates the Liquid–Liquid Phase Separation of ATG8e to Promote Autophagy,” Science Bulletin 67, no. 4 (2022): 350–354.

[120]

E. C. Petronilho, M. M. Pedrote, M. A. Marques, et al., “Phase Separation of p53 Precedes Aggregation and Is Affected by Oncogenic Mutations and Ligands,” Chemical Science 12, no. 21 (2021): 7334–7349.

[121]

Q. Xiao, C. K. McAtee, and X. Su, “Phase Separation in Immune Signalling,” Nature Reviews Immunology 22, no. 3 (2022): 188–199.

[122]

D. B. McAffee, M. K. O'Dair, J. J. Lin, et al., “Discrete Lat Condensates Encode Antigen Information From Single pMHC:TCR Binding Events,” Nature Communications 13, no. 1 (2022): 7446.

[123]

T. Dai, L. Zhang, Y. Ran, et al., “MAVS deSUMOylation by SENP1 Inhibits Its Aggregation and Antagonizes IRF3 Activation,” Nature Structural & Molecular Biology 30, no. 6 (2023): 785–799.

[124]

D. Liu, K. K. Lum, N. Treen, et al., “IFI16 Phase Separation via Multi-Phosphorylation Drives Innate Immune Signaling,” Nucleic Acids Research 51, no. 13 (2023): 6819–6840.

[125]

M. U. Gack, Y. C. Shin, C. H. Joo, et al., “TRIM25 RING-Finger E3 Ubiquitin Ligase Is Essential for Rig-I-Mediated Antiviral Activity,” Nature 446, no. 7138 (2007): 916–920.

[126]

F. Jobe, J. Simpson, P. Hawes, E. Guzman, and D. Bailey, “Respiratory Syncytial Virus Sequesters NF-κB Subunit p65 to Cytoplasmic Inclusion Bodies to Inhibit Innate Immune Signaling,” Journal of Virology 94, no. 22 (2020): e01380-20.

[127]

Q. Zhu, C. Zhang, T. Qu, et al., “MNX1-AS1 Promotes Phase Separation of IGF2BP1 to Drive C-Myc-Mediated Cell-Cycle Progression and Proliferation in Lung Cancer,” Cancer Research 82, no. 23 (2022): 4340–4358.

[128]

E. Zlotorynski, “Condensates Burst the Bridge for Transcription,” Nature Reviews Molecular Cell Biology 25, no. 3 (2024): 159.

[129]

H. Gao, H. Wei, Y. Yang, et al., “Phase Separation of DDX21 Promotes Colorectal Cancer Metastasis via MCM5-Dependent EMT Pathway,” Oncogene 42, no. 21 (2023): 1704–1715.

[130]

A. Tulpule, J. Guan, D. S. Neel, et al., “Kinase-Mediated RAS Signaling via Membraneless Cytoplasmic Protein Granules,” Cell 184, no. 10 (2021): 2649–2664.

[131]

C. Chen, G. Fu, Q. Guo, S. Xue, and S. Z. Luo, “Phase Separation of p53 Induced by Its Unstructured Basic Region and Prevented by Oncogenic Mutations in Tetramerization Domain,” International Journal of Biological Macromolecules 222, no. Pt A (2022): 207–216.

[132]

L. Zhang, X. Geng, F. Wang, et al., “53BP1 Regulates Heterochromatin Through Liquid Phase Separation,” Nature Communications 13, no. 1 (2022): 360.

[133]

J. L. Silva, D. Foguel, V. F. Ferreira, et al., “Targeting Biomolecular Condensation and Protein Aggregation Against Cancer,” Chemical Reviews 123, no. 14 (2023): 9094–9138.

[134]

L. E. Wong, A. Bhatt, P. S. Erdmann, et al., “Tripartite Phase Separation of Two Signal Effectors With Vesicles Priming B Cell Responsiveness,” Nature Communications 11, no. 1 (2020): 848.

[135]

W. Zhou, L. Mohr, J. Maciejowski, and P. J. Kranzusch, “cGAS Phase Separation Inhibits TREX1-Mediated DNA Degradation and Enhances Cytosolic DNA Sensing,” Molecular Cell 81, no. 4 (2021): 739–755.

[136]

W. Kolch and A. Pitt, “Functional Proteomics to Dissect Tyrosine Kinase Signalling Pathways In Cancer,” Nature Reviews Cancer 10, no. 9 (2010): 618–629.

[137]

B. R. Sabari, A. Dall'Agnese, A. Boija, et al., “Coactivator Condensation at Super-Enhancers Links Phase Separation and Gene Control,” Science 361, no. 6400 (2018): aar3958.

[138]

X. Han, D. Yu, R. Gu, et al., “Roles of the BRD4 Short Isoform in Phase Separation and Active Gene Transcription,” Nature Structural & Molecular Biology 27, no. 4 (2020): 333–341.

[139]

R. A. Stewart, Z. Ding, U. S. Jeon, et al., “Wnt Target Gene Activation Requires β-Catenin Separation Into Biomolecular Condensates,” PLoS Biology 22, no. 9 (2024): e3002368.

[140]

K. Meyer, K. Yserentant, R. Cheloor-Kovilakam, et al., “YAP Charge Patterning Mediates Signal Integration Through Transcriptional Co-Condensates,” bioRxiv (2024), https://doi.org/10.1101/2024.08.10.607443.

[141]

X. Hu, X. Wu, K. Berry, et al., “Nuclear Condensates of YAP Fusion Proteins Alter Transcription to Drive Ependymoma Tumourigenesis,” Nature Cell Biology 25, no. 2 (2023): 323–336.

[142]

B. K. Wu, S. C. Mei, E. H. Chen, Y. Zheng, and D. Pan, “YAP Induces an Oncogenic Transcriptional Program Through TET1-mediated Epigenetic Remodeling in Liver Growth and Tumorigenesis,” Nature Genetics 54, no. 8 (2022): 1202–1213.

[143]

W. Li, J. Hu, B. Shi, et al., “Biophysical Properties of AKAP95 Protein Condensates Regulate Splicing and Tumorigenesis,” Nature Cell Biology 22, no. 8 (2020): 960–972.

[144]

Q. Shi, X. Jin, P. Zhang, et al., “SPOP Mutations Promote p62/SQSTM1-Dependent Autophagy and Nrf2 Activation in Prostate Cancer,” Cell Death & Differentiation 29, no. 6 (2022): 1228–1239.

[145]

B. Lu, C. Zou, M. Yang, et al., “Pharmacological Inhibition of Core Regulatory Circuitry Liquid–Liquid Phase Separation Suppresses Metastasis and Chemoresistance in Osteosarcoma,” Advanced Science 8, no. 20 (2021): e2101895.

[146]

X. Lu, J. Wang, W. Wang, et al., “Copy Number Amplification and SP1-activated lncRNA MELTF-AS1 Regulates Tumorigenesis by Driving Phase Separation of YBX1 to Activate ANXA8 in Non-Small Cell Lung Cancer,” Oncogene 41, no. 23 (2022): 3222–3238.

[147]

Z. Liu, Y. Yang, A. Gu, et al., “Par Complex Cluster Formation Mediated by Phase Separation,” Nature Communications 11, no. 1 (2020): 2266.

[148]

G. Fonteneau, A. Redding, H. Hoag-Lee, et al., “Stress Granules Determine the Development of Obesity-Associated Pancreatic Cancer,” Cancer Discovery 12, no. 8 (2022): 1984–2005.

[149]

J. Zhang, Z. Ni, Y. Zhang, et al., “DAZAP1 Phase Separation Regulates Mitochondrial Metabolism to Facilitate Invasion and Metastasis of Oral Squamous Cell Carcinoma,” Cancer Research 84 (2024): 3818–3833.

[150]

R. Sun, S. Zhang, Y. Liu, and D. Li, “Chemical Probes for Investigating Protein Liquid–Liquid Phase Separation and Aggregation,” Current Opinion in Chemical Biology 74 (2023): 102291.

[151]

M. Esposito, C. Fang, K. C. Cook, et al., “TGF-β-induced DACT1 Biomolecular Condensates Repress Wnt Signalling to Promote Bone Metastasis,” Nature Cell Biology 23, no. 3 (2021): 257–267.

[152]

W. Wang, B. Yun, R. G. Hoyle, et al., “CYTOR Facilitates Formation of FOSL1 Phase Separation and Super Enhancers to Drive Metastasis of Tumor Budding Cells in Head and Neck Squamous Cell Carcinoma,” Advanced Science 11, no. 4 (2024): e2305002.

[153]

Z. J. He, K. He, S. W. Cai, et al., “Phase Separation of RNF214 Promotes the Progression of Hepatocellular Carcinoma,” Cell Death & Disease 15, no. 7 (2024): 483.

[154]

T. Noguchi, Y. Sekiguchi, T. Shimada, et al., “LLPS of SQSTM1/p62 and NBR1 as Outcomes of Lysosomal Stress Response Limits Cancer Cell Metastasis,” Proceedings of the National Academy of Sciences 120, no. 43 (2023): e2311282120.

[155]

Q. Liu, J. Li, W. Zhang, et al., “Glycogen Accumulation and Phase Separation Drives Liver Tumor Initiation,” Cell 184, no. 22 (2021): 5559–5576.

[156]

J. Li, W. Wang, S. Li, et al., “Smad2/3/4 Complex Could Undergo Liquid Liquid Phase Separation and Induce Apoptosis Through TAT in Hepatocellular Carcinoma,” Cancer Cell International 24, no. 1 (2024): 176.

[157]

V. Calderone, J. Gallego, G. Fernandez-Miranda, et al., “Sequential Functions of CPEB1 and CPEB4 Regulate Pathologic Expression of Vascular Endothelial Growth Factor and Angiogenesis in Chronic Liver Disease,” Gastroenterology 150, no. 4 (2016): 982–997.

[158]

T. A. Baudino, C. McKay, H. Pendeville-Samain, et al., “c-Myc Is Essential for Vasculogenesis and Angiogenesis During Development and Tumor Progression,” Genes & Development 16, no. 19 (2002): 2530–2543.

[159]

Y. Jiang, G. Lei, T. Lin, et al., “1,6-Hexanediol Regulates Angiogenesis via Suppression of Cyclin A1-Mediated Endothelial Function,” BMC Biology 21, no. 1 (2023): 75.

[160]

S. Chen, K. Lu, Y. Hou, et al., “YY1 Complex in M2 Macrophage Promotes Prostate Cancer Progression by Upregulating Il-6,” Journal for Immunotherapy of Cancer 11, no. 4 (2023): e006020.

[161]

F. Meng, Z. Yu, D. Zhang, et al., “Induced Phase Separation of Mutant NF2 Imprisons the cGAS-STING Machinery to Abrogate Antitumor Immunity,” Molecular Cell 81, no. 20 (2021): 4147–4164.

[162]

C. Dai, J. Cao, Y. Tang, Y. Jiang, C. Luo, and J. Zheng, “YTHDF3 Phase Separation Regulates HSPA13-Dependent Clear Cell Renal Cell Carcinoma Development and Immune Evasion,” Cancer Science 115, no. 8 (2024): 2588–2601.

[163]

K. Takayama, T. Kosaka, T. Suzuki, et al., “Subtype-Specific Collaborative Transcription Factor Networks Are Promoted by OCT4 in the Progression of Prostate Cancer,” Nature Communications 12, no. 1 (2021): 3766.

[164]

J. Xie, H. He, W. Kong, et al., “Targeting Androgen Receptor Phase Separation to Overcome Antiandrogen Resistance,” Nature Chemical Biology 18, no. 12 (2022): 1341–1350.

[165]

J. Liu, Y. Xie, J. Guo, et al., “Targeting NSD2-mediated SRC-3 Liquid–Liquid Phase Separation Sensitizes Bortezomib Treatment in Multiple Myeloma,” Nature Communications 12, no. 1 (2021): 1022.

[166]

J. Shi, S. Y. Chen, X. T. Shen, et al., “NOP53 Undergoes Liquid–Liquid Phase Separation and Promotes Tumor Radio-Resistance,” Cell Death Discovery 8, no. 1 (2022): 436.

[167]

Z. Chen, J. Chen, V. G. Keshamouni, and M. Kanapathipillai, “Polyarginine and Its Analogues Inhibit p53 Mutant Aggregation and Cancer Cell Proliferation In Vitro,” Biochemical and Biophysical Research Communications 489, no. 2 (2017): 130–134.

[168]

A. Soragni, D. M. Janzen, L. M. Johnson, et al., “A Designed Inhibitor of p53 Aggregation Rescues p53 Tumor Suppression in Ovarian Carcinomas,” Cancer Cell 29, no. 1 (2016): 90–103.

[169]

G. Zhu, J. Xie, Z. Fu, et al., “Pharmacological Inhibition of SRC-1 Phase Separation Suppresses YAP Oncogenic Transcription Activity,” Cell Research 31, no. 9 (2021): 1028–1031.

[170]

C. Wang, H. Lu, X. Liu, et al., “A Natural Product Targets BRD4 to Inhibit Phase Separation and Gene Transcription,” iScience 25, no. 1 (2022): 103719.

[171]

W. Lan, P. Santofimia-Castaño, M. Swayden, et al., “ZZW-115-Dependent Inhibition of NUPR1 Nuclear Translocation Sensitizes Cancer Cells to Genotoxic Agents,” JCI Insight 5, no. 18 (2020): e138117.

[172]

C. Kan, Z. Tan, L. Liu, et al., “Phase Separation of SHP2E76K Promotes Malignant Transformation of Mesenchymal Stem Cells by Activating Mitochondrial Complexes,” JCI Insight 9, no. 8 (2024): e170340.

[173]

L. Wang, Q. Liu, N. Wang, et al., “Oleic Acid Dissolves cGAS-DNA Phase Separation to Inhibit Immune Surveillance,” Advanced Science 10, no. 14 (2023): e2206820.

[174]

H. K. Shirnekhi, B. Chandra, and R. W. Kriwacki, “Dissolving Fusion Oncoprotein Condensates to Reverse Aberrant Gene Expression,” Cancer Research 83, no. 20 (2023): 3324–3326.

[175]

H. de Thé, P. P. Pandolfi, and Z. Chen, “Acute Promyelocytic Leukemia: A Paradigm for Oncoprotein-Targeted Cure,” Cancer Cell 32, no. 5 (2017): 552–560.

[176]

L. C. Reineke, W. C. Tsai, A. Jain, J. T. Kaelber, S. Y. Jung, and R. E. Lloyd, “Casein Kinase 2 Is Linked to Stress Granule Dynamics Through Phosphorylation of the Stress Granule Nucleating Protein G3BP1,” Molecular and Cellular Biology 37, no. 4 (2017): e00596-16.

[177]

T. Moroishi, C. G. Hansen, and K. L. Guan, “The Emerging Roles of YAP and TAZ in Cancer,” Nature Reviews Cancer 15, no. 2 (2015): 73–79.

[178]

Y. Li, Y. Feng, S. Geng, F. Xu, and H. Guo, “The Role of Liquid–Liquid Phase Separation In Defining Cancer EMT,” Life Sciences 353 (2024): 122931.

[179]

S. K. Das, A. K. Pradhan, P. Bhoopathi, et al., “The MDA-9/Syntenin/IGF1R/STAT3 Axis Directs Prostate Cancer Invasion,” Cancer Research 78, no. 11 (2018): 2852–2863.

[180]

S. Saad, G. Cereghetti, Y. Feng, P. Picotti, M. Peter, and R. Dechant, “Reversible Protein Aggregation Is a Protective Mechanism to Ensure Cell Cycle Restart After Stress,” Nature Cell Biology 19, no. 10 (2017): 1202–1213.

[181]

G. Azzam and J. L. Liu, “Only One Isoform of Drosophila melanogaster CTP Synthase Forms the Cytoophidium,” PLoS Genetics 9, no. 2 (2013): e1003256.

[182]

M. Hunkeler, A. Hagmann, E. Stuttfeld, et al., “Structural Basis for Regulation of Human Acetyl-CoA Carboxylase,” Nature 558, no. 7710 (2018): 470–474.

[183]

M. Prouteau and R. Loewith, “Regulation of Cellular Metabolism Through Phase Separation of Enzymes,” Biomolecules 8, no. 4 (2018): 160.

[184]

Z. L. Liu, H. H. Chen, L. L. Zheng, L. P. Sun, and L. Shi, “Angiogenic Signaling Pathways and Anti-Angiogenic Therapy for Cancer,” Signal Transduction and Targeted Therapy 8, no. 1 (2023): 198.

[185]

K. Tsafou, P. B. Tiwari, J. D. Forman-Kay, S. J. Metallo, and J. A. Toretsky, “Targeting Intrinsically Disordered Transcription Factors: Changing the Paradigm,” Journal of Molecular Biology 430, no. 16 (2018): 2321–2341.

[186]

Z. Zhang, Z. Boskovic, M. M. Hussain, et al., “Chemical Perturbation of an Intrinsically Disordered Region of TFIID Distinguishes Two Modes of Transcription Initiation,” eLife 4 (2015): e07777.

[187]

H. V. Erkizan, Y. Kong, M. Merchant, et al., “A Small Molecule Blocking Oncogenic Protein EWS-FLI1 Interaction With RNA Helicase A Inhibits Growth of Ewing's Sarcoma,” Nature Medicine 15, no. 7 (2009): 750–756.

[188]

J. Shi, J. S. Stover, L. R. Whitby, P. K. Vogt, and D. L. Boger, “Small Molecule Inhibitors of Myc/Max Dimerization and Myc-Induced Cell Transformation,” Bioorganic & Medicinal Chemistry Letters 19, no. 21 (2009): 6038–6041.

[189]

T. Berg, S. B. Cohen, J. Desharnais, et al., “Small-Molecule Antagonists of Myc/Max Dimerization Inhibit Myc-Induced Transformation of Chicken Embryo Fibroblasts,” Proceedings of the National Academy of Sciences 99, no. 6 (2002): 3830–3835.

[190]

P. Santofimia-Castaño, N. Fraunhoffer, X. Liu, et al., “Targeting NUPR1-dependent Stress Granules Formation to Induce Synthetic Lethality in Kras(G12D)-Driven Tumors,” EMBO Molecular Medicine 16, no. 3 (2024): 475–505.

[191]

S. Adnane, A. Marino, and E. Leucci, “LncRNA in Human Cancers: Signal From Noise,” Trends in Cell Biology 32, no. 7 (2022): 565–573.

[192]

Y. Gao, M. Jiang, F. Guo, et al., “A Novel lncRNA MTAR1 Promotes Cancer Development Through IGF2BPs Mediated Post-Transcriptional Regulation of c-MYC,” Oncogene 41, no. 42 (2022): 4736–4753.

[193]

R. H. Li, T. Tian, Q. W. Ge, et al., “A Phosphatidic Acid-Binding lncRNA SNHG9 Facilitates LATS1 Liquid–Liquid Phase Separation to Promote Oncogenic YAP Signaling,” Cell Research 31, no. 10 (2021): 1088–1105.

[194]

I. A. Klein, A. Boija, L. K. Afeyan, et al., “Partitioning of Cancer Therapeutics in Nuclear Condensates,” Science 368, no. 6497 (2020): 1386–1392.

[195]

M. Kato and S. L. McKnight, “A Solid-State Conceptualization of Information Transfer From Gene to Message to Protein,” Annual Review of Biochemistry 87 (2018): 351–390.

[196]

P. A. Ivanov, E. M. Chudinova, and E. S. Nadezhdina, “Disruption of Microtubules Inhibits Cytoplasmic Ribonucleoprotein Stress Granule Formation,” Experimental Cell Research 290, no. 2 (2003): 227–233.

[197]

W. M. Babinchak, B. K. Dumm, S. Venus, et al., “Small Molecules as Potent Biphasic Modulators of Protein Liquid–Liquid Phase Separation,” Nature Communications 11, no. 1 (2020): 5574.

[198]

F. Wippich, B. Bodenmiller, M. G. Trajkovska, S. Wanka, R. Aebersold, and L. Pelkmans, “Dual Specificity Kinase DYRK3 Couples Stress Granule Condensation/Dissolution to mTORC1 Signaling,” Cell 152, no. 4 (2013): 791–805.

[199]

T. Liang, Y. Dong, I. Cheng, et al., “In Situ Formation of Biomolecular Condensates as Intracellular Drug Reservoirs for Augmenting Chemotherapy,” Nature Biomedical Engineering 8, no. 11 (2024): 1469–1482.

[200]

H. Chen, Y. Bao, X. Li, et al., “Cell Surface Engineering by Phase-Separated Coacervates for Antibody Display and Targeted Cancer Cell Therapy,” Angewandte Chemie International Edition 63, no. 44 (2024): e202410566.

[201]

P. H. Peng, K. W. Hsu, and K. J. Wu, “Liquid–Liquid Phase Separation (LLPS) in Cellular Physiology and Tumor Biology,” American Journal of Cancer Research 11, no. 8 (2021): 3766–3776.

[202]

F. Gasset-Rosa, S. Lu, H. Yu, et al., “Cytoplasmic TDP-43 De-Mixing Independent of Stress Granules Drives Inhibition of Nuclear Import, Loss of Nuclear TDP-43, and Cell Death,” Neuron 102, no. 2 (2019): 339–357.

[203]

K. Li, X. Xie, R. Gao, et al., “Spatiotemporal Protein Interactome Profiling Through Condensation-Enhanced Photocrosslinking,” Nature Chemistry 17, no. 1 (2025): 111–123.

[204]

S. Yang, H. Yu, X. Xu, et al., “Aiegen-Conjugated Phase-Separating Peptides Illuminate Intracellular RNA Through Coacervation-Induced Emission,” ACS Nano 17, no. 9 (2023): 8195–8203.

[205]

X. Su, “Car-T Entering a New ‘Phase’: Improving CAR-T Function by Harnessing Phase Separation,” Cancer Research 85, no. 6 (2025): 1011–1012

[206]

R. Ma, L. Zheng, H. Yu, D. Huo, H. Zhao, and H. Zhang, “Chirality Engineering-Regulated Liquid–Liquid Phase Separation of Stress Granules and Its Role in Chemo-Sensitization and Side Effect Mitigation,” Journal of Colloid and Interface Science 685 (2025): 637–647.

[207]

Y. Wang, C. Yu, G. Pei, W. Jia, T. Li, and P. Li, “Dissolution of Oncofusion Transcription Factor Condensates for Cancer Therapy,” Nature Chemical Biology 19, no. 10 (2023): 1223–1234.

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