Biomolecular condensates: Formation mechanisms, biological functions, and therapeutic targets

Abstract Biomolecular condensates are cellular structures composed of membraneless assemblies comprising proteins or nucleic acids. The formation of these condensates requires components to change from a state of solubility separation from the surrounding environment by undergoing phase transition and condensation. Over the past decade, it has become widely appreciated that biomolecular condensates are ubiquitous in eukaryotic cells and play a vital role in physiological and pathological processes. These condensates may provide promising targets for the clinic research. Recently, a series of pathological and physiological processes have been found associated with the dysfunction of condensates, and a range of targets and methods have been demonstrated to modulate the formation of these condensates. A more extensive description of biomolecular condensates is urgently needed for the development of novel therapies. In this review, we summarized the current understanding of biomolecular condensates and the molecular mechanisms of their formation. Moreover, we reviewed the functions of condensates and therapeutic targets for diseases. We further highlighted the available regulatory targets and methods, discussed the significance and challenges of targeting these condensates. Reviewing the latest developments in biomolecular condensate research could be essential in translating our current knowledge on the use of condensates for clinical therapeutic strategies.

Biomolecular condensates are membraneless compartments and nonmembrane-bound bodies, which were first discovered in the 19th century. 1,2 They exist throughout eukaryotic cells and play an extremely important role in various biological processes. 3 The formation of these condensates requires their components to undergo a liquid-liquid phase separation or aggregation process, which changes them from a state of dissolution to a state of separation from their surroundings. While the processes of phase separation rely on different elementary steps and ionic strength compared with aggregation, which could form condensates even without phase separation, these two processes are apparently mechanistically connected. 4 There is a direct link between them in many diseaseassociated proteins, that the formation of condensates by phase separation often followed by aggregation to a less dynamic state. 5 Recent research of condensates has focused on their biological functions with the discovery of properties and molecular mechanisms of their formation and function. 6 Numerous pathological and physiological processes are associated with dysfunction of the condensates at different scales, which provide promising targets for clinical research on related diseases. 7 These works provided exciting discoveries and as of late has added to our understanding of the condensates. Therefore, a more extensive description of these condensates is urgently needed for the development of novel therapies.
Here, we have reviewed the current understanding of biomolecular condensates and the molecular mechanisms of their formation and function. Moreover, we summarized the functions of condensates and therapeutic targets for diseases. We further highlight the available regulatory targets and methods, and discussed the significance and challenges of targeting these condensates.

PROPERTIES OF BIOMOLECULAR CONDENSATES
We propose that there are three properties of biomolecular condensates that determine whether the condensates are formed. Also, the properties obtained by condensates provide new features for cellular components and alter pathological or physiological processes. These properties include: condensates are in liquid-or solid-like state, consist of dynamic components, and present a multiphase immiscible state.

Biomolecular condensates in liquidor solid-like state
The interaction between proteins or RNAs promotes phase separation and produces micron-sized droplets ( Figure 1). 8 There are many liquid-like state and long-established condensates in cells, such as ribonucleoprotein (RNP) particles, stress granules (SGs), and P granules. RNP particles play a unique role in epigenetic and posttranscriptional regulation. 2 SGs are formed when cells are stimulated by external pressure to suspend the translation process of mRNA, and they quickly depolymerize to restore normal cell physiological functions when external pressure is relieved. P granules are composed of protein and RNA in the germ cells of Caenorhabditis elegans. They flow out of the nucleus under shear force and then drip and fuse into larger droplets. 9 LAF-1, the DDX3 RNA helicase in P granules, can also be separated into droplets in vitro. 10 Moreover, a member of the ADP-ribosyl transferase family, poly ADP-ribose (PAR) polymerase 1, recognizes DNA damage sites and synthesizes PAR chains. 11 PAR attracts fused in sarcoma (FUS) to the DNA damage site and further form droplets rich in damaged DNA. 12 These condensates are normally in liquid state with high fluidity but can sometimes be more viscous and viscoelastic-like solids. In RNP particles, inactivation of the RNA helicase results in a transition from liquid to solid state. 13 The spindle-defective protein 5 (SPD-5) is required for centrosome assembly. Recombinant SPD-5 can form dense droplets in vitro, which are dynamic and liquid at first but then harden. 14 The Balbiani body in Xenopus oocytes is another condensate in solid-like state. The rigid Balbiani body protects its isolated components from damage and stores macromolecules and organelles for the next generation. 15 The influx of protons and a pronounced acidification of the cytoplasm also lead to extensive macromolecular assembly of proteins and reduced the fluidity of the cytoplasm, ultimately transforming the cytoplasm into a solid-like state with stronger mechanical stability. 16 Moreover, the liquid-solid phase transition is necessary for F I G U R E 1 Properties of biomolecular condensates. The three properties of biomolecular condensates. There were a large number of condensates in liquid-like state at different locations in cells such as SGs, P granules, RNP, and PARP1. The high fluidity of these condensates contributes to their ability to regulate the rate of chemical reactions. There are also a large number of solid-like condensates present in cells such as Balbiani body, SPD-5, and Oskar ribonucleoprotein granule. These condensates have less fluidity, but function to protect their contents. The components in the condensates such as Disheveled, Dyn2γ, and γ-tubulin are able to move freely and dynamically exchange with the surrounding molecules, which support its ability to regulate biochemical processes in cells. The components of the condensates such as P granules, SGs, and paraspeckles are usually not uniformly distributed but in a multiphase immiscible state. RNP, ribonucleoprotein; SPD-5, spindle-defective protein 5; PARP1, poly (ADP-ribose) polymerase 1; SGs, stress granules. the formation of the Oskar RNP granule and participate in Drosophila embryonic development. 17 Prion protein (PrP) spontaneously phase-separates into droplets under physiological conditions and gradually matures into solid-like βrich amyloid with self-replicating function. 18 Collectively, biomolecular condensates are either liquid or solid.

Dynamic components in biomolecular condensates
The components in biomolecular condensates maintain a state of free movement and can be dynamically exchanged with surrounding molecules (Figure 1). Fluorescence recovery after photobleaching technology enables the quantitative study of component mobility in these conden-sates. In P granules, components quickly exchanged with the surrounding cytoplasm or nucleus. 9 Disheveled is a cytoplasmic protein that acts as a key effector upstream of Wnt signaling pathway, which has a strong propensity to form punctate. It has been reported that there is a continuous material exchange between Disheveled and cytoplasmic components. 19 Moreover, Dyn2γ or γ-tubulin complex can be exchanged with cytoplasmic components within a few minutes after photobleaching. 20

Multiphase immiscible state in biomolecular condensates
Several proteins are contained in biomolecular condensates, while a small number of these proteins is required to promote the formation of droplets in vitro, and most of them likely have a synergistic effect to promote phase separation ( Figure 1). 21,22 The P granules have a heterostructure with a specific composition of RNP particles sequestered in the different region. The assembly of P granules in embryos can be regulated by phosphorylation, suggesting that their substructures have clear molecular specificity. 23 Jain et al. 24 reported SGs contain a stable core structure and a dynamic shell. In paraspeckles, AG-rich RNA and long noncoding RNA Neat1 are distributed along the boundaries. 25 Collectively, to understand biomolecular condensates, we must describe as closely as possible the communities of biomolecular which comprise them. Biomolecular condensates contain a variety of substances and present a heterogeneous immiscible state of dense and dilute phases. The accepted criteria for defining a condensate are that it is spherical, fused, and recovered from photobleaching. 26 Live-cell fluorescence confocal microscopy and 1,6hexanediol are commonly used to characterize the localization or properties of condensates. 27 However, it should be noted that less evidence is not enough to definitively prove that the structure is a condensate. The fast recovery of photobleaching may be due to the reversible binding of proteins to porous solid structure. 26 1,6-Hexanediol is able to alter the membrane permeability of living cells, which can lead to additional artifacts. 28

FORMATION MECHANISMS OF BIOMOLECULAR CONDENSATES
Recent studies have revealed the formation and function mechanisms of biomolecular condensates. These mechanisms empower the components assemble into condensates and further perform various duties. Understanding these mechanisms not only advances our knowledge of biomolecular condensates, but also provides the basis for the research of transformation by using condensates. In this section, we reviewed formation mechanisms of condensates.

The formation of condensates depends on multivalent interactions
Recent studies have focused on their biological function with the discovery of their physical properties and production mechanisms. An increasing amount of experimental evidence suggests that multivalent interactions regulates the formation of biomolecular condensates. 3 There are five main types of multivalent interactions: cationanion, dipole-dipole, cation-π, π-π, and hydrophobic interactions. 29 Cation-anion interactions refer to the attractive or repulsive interaction between molecules with cation and anion, and dipole-dipole interactions refer to the attraction between positively charged part and negatively charged part (Figure 2A). The Nephrin intracellular domain is able to assemble with anionic partners to form condensates. 30 The main component of the nuage or germ granule, Ddx4, needs extremely strong cation-anion and dipole-dipole interaction to facilitate phase separation. 31 In addition, there is a special type of dipole-dipole interaction known as hydrogen bonding. 32 Hydrogen bonds allowing polypeptide chain to form secondary protein, which further form tertiary protein through multivalent interactions. It has been reported that a peptide from the primary adhesive protein Mfp-5, GK-16*, requires dihydroxyphenylalanine and glycine mediated hydrogen bonds for phase separation. 33 Histidine residues in histidinerich squid beak proteins generate condensates by forming hydrogen bonds with tyrosine. 34 Cation-π interactions are commonly found between amino acid with cation and aromatic amino acid ( Figure 2B). In mussel foot protein-1 residues, cation-π interactions can overcome the repulsion of cation-anion interactions and promoting phase separation of molecules with same charge. 35 π-π interactions are usually found in aromatic amino acid ( Figure 2C). Intriguingly, π-π interactions have also been reported to be present in nonaromatic amino acid such as fragile X mental retardation protein. 36 Hydrophobic interactions refer to hydrophobic groups that avoid water in close proximity to each other ( Figure 2D). Tropoelastin relies on hydrophobic interactions to facilitate phase separation. 37

Thermodynamic aspects of condensate formation
In the classic thermodynamic context, the formation of condensates is a transient and nonequilibrium process, that is, the initial equilibrium state of the system is changed through appropriate changes in thermodynamic conditions, and the condensates are formed by nucleation, growth, and coarsening. 38 This is a density transition event that occurs when the concentration of biomoleculars exceeds the saturation concentration, resulting in the formation of a dense phase enriched in biomoleculars, which is relatively depleted by a dilute phase. 39,40 This concentration threshold also known as the percolation threshold that defines the gel point. 41 Due to differences in surface curvature, the interaction between biomoleculars on the surface of small condensates less than big condensates further leads to small condensates to lose more easily ( Figure 2E). Larger condensates will grow at the expense of smaller condensates. F I G U R E 2 Formation mechanism of biomolecular condensates. (A) Nephrin forms condensates through cation-anion and dipole-dipole interactions. In these interactions, oppositely charged ion and biomoleculars attract each other to promote phase separation. GK-16* and HBPs form condensates through hydrogen bonds. In these interactions, hydrogen ion donor and acceptor attract each other to promote phase separation. (B) Mfp-1 forms condensates through cation-π interactions. In these interactions, cations and aromatic amino acid attract each other to promote phase separation. Mfp-1, mussel foot protein-1. (C) FMRP forms condensates through π-π interactions. In these interactions, mainly aromatic amino acids such as arginine attract each other to promote phase separation. FMRP, fragile X mental retardation protein. (D) Tropoelastin forms condensates through hydrophobic interactions. In these interactions, biomoleculars with hydrophobic regions attract each other and repel water to further promote phase separation. (E) In the thermodynamic process, condensates are stable when the biomolecular concentration exceeds the saturation concentration. With the increase of biomolecular concentration, the condensates change from dilute phase to dense phase. Small condensates cannot hold onto their proteins as well as larger condensates, which promotes diffusion flux from small to large condensates. E, binding energy; T, temperature; S, entropy.
In addition to the formation of condensates, changes in thermodynamic conditions such as concentration or temperature are also associated with altered size and number of condensates. 29,38 For example, the size of enhancer condensates depends critically on the concentration of transcription factors (TFs) that bind enhancers. 42,43 Due to different surface curvature, the number of small to large condensates tends to decrease gradually, and small condensates can grow or shrink rapidly, whereas large condensates takes several days. 40 The residence time of component reactants is strongly influenced by the size of condensates. Molecular diffusion also depends on the size. It has been reported that the effective mesh size of LAF-1 condensates is 3-8 nm, which determines the size scale of molecular diffusion and permeability. 44 Moreover, the initiation of the antiviral immune response may be related to the size of the condensates formed around dsDNA in the cytoplasm. 45 Together, in the process of condensate formation, peptide with different chemical properties and RNAs with anion could establish various affinity interactions, which enable these component to assemble. Due to entropy-driven effects, such assembly would inherently reduce the solubility of the molecules, thus promote the formation of condensates. Regulating the formation of biomolecular condensates needs to focus

4.1
The mechanism of biomolecular condensates function Biomolecular condensates are able to increase the concentration of their internal components and lead to changes in the chemical reaction rate ( Figure 3A). Condensates formed by the polyethylene glycol/dextran aqueous two-phase system can increase RNA concentration and ribozyme cleavage rates. 46 Low-molecular-weight mononucleotides and cationic peptides facilitate phase separation that further selectively chelate porphyrins, inor-ganic nanoparticles, and enzymes. This enrichment effect ultimately increases the phosphorylation rate of glucose. 47 Moreover, biomolecular condensates can also form lateral compartments enriched for particular lipids and proteins on cell membranes. 48 Biomolecular condensates have isolation effect that enables them to maintain a homeostatic environment ( Figure 3B). Heterochromatin components such as nucleosomes and DNA are preferentially distributed in droplets formed by heterochromatin protein 1α. 49 TIS granules, formed by RNA-binding protein (RBP) TIS11B, are able to further interweave with the endoplasmic reticulum to form a reticular network and maintain a different physicochemical environment from the cytoplasm. 50 P granules act as protein size filters in the transport of molecules to the nucleus by excluding proteins larger than 45 kDa. 51 Moreover, the specific receptor protein for the selective autophagy cargo aminopeptidase I, autophagy-related protein 19, is localized only on the surface of aminopeptidase I droplets in vitro and in vivo but does not penetrate into the droplets. 52 Biomolecular condensates also have position effect that allowing them to localize to specific regions of cell ( Figure 3C). Nucleophosmin 1 (NPM1) forms condensates in the nucleolus with proteins containing arginine-rich linear motif and ribosomal RNA. 53 Spotted POZ protein, a substrate linker for cullin3-RING ubiquitin ligase, forms condensates at the nuclear speckles. 54 Besides, P-bodies (PBs), the condensates formed by mRNA decapping and 5′→3′ degradation reactions occur abnormally, anchored on microtubules and exhibit spatially restricted motion that depends on microtubules. 55 The N-terminus of Annexin A11 promotes the formation of membraneless RNA granules, and the C-terminus interacts with and localizes to lysosomes. 56 Moreover, Nephrin, Nck, and N-WASP are able to promote phase separation on lipid bilayer membranes and increase the residence time of N-WASP and Arp2/3 complexes on the membranes. 57

Functions of biomolecular condensates
In recent years, a series of evidences have shown that multifunctional condensates are not only related to physiological processes, but also to pathological processes (Table 1). Given the pivotal role of biomolecular condensates in biological processes, its targeting is promising for clinical research. 7 In the following section, we summarized the functions of these condensates at three different biological scales including molecular scale, cellular scale, and tissue scale ( Figure 4).

Molecular functions regulated by biomolecular condensates
At the molecular scale, biomolecular condensates are critical for amplification, transcription, translation, and posttranslational modification process. For example, nuclear condensates are critical for the establishment and stabilization of BuGZ functions in the assembly of spindle, 130 allowing the enrichment of tubulin along microtubules. 105 Phase transition of chromatin that is induced by global histone deacetylation confers precise movement of chromosomes during cell division. 131 RNP particles are involved in synthesis of ribosomal RNA, maturation of small nuclear RNA and mRNA. 132 Mediator promotes phase separation with activation domain of TFs such as Oct4, Sox2, and Nanog, further regulating the transcription process. 94 Arabidopsis FLL2 promotes the liquid-liquid separation of poly(A) complexes and regulates transcriptional process. 86 Moreover, condensates formed by RBP FXR1 activate translation of RNA and drive spermiogenesis. 88 Intriguingly, it has been recently reported that TFs are able to directly activate transcription before phase separation occurs, but the formation of condensates has transcriptional repressive function. 133,134 Cytoplasmic protein YTHDF induced by heat shock binds to m6A-modified mRNAs, significantly enhances phase separation, and alerts stability and translation process. 128 Furthermore, condensates are also involved in UPS and autophagosome process, which provide quality control of protein synthesis. 62

Cellular processes involved in biomolecular condensates
At the cellular scale, condensates have been found to be closely related to transport and signal transduction. Sphingolipids are commonly found in eukaryotic cells participate in intracellular material transport process and as structural molecules of cell membranes. During the maturation of the Golgi cistern, sphingolipids attract and facilitate phase separation of cholesterol in the bilayer of gall vesicles, further regulating the fusion process of the vesicles. 108 It was reported that cell surface transmembrane receptors require condensates for signal transduction. In Wnt/βcatenin signaling pathway, the destruction complex functions by forming condensates. 112 However, transforming growth factor-beta induces the expression of DACT1 and forms condensates in the cytoplasm which further inhibits Wnt signaling. 111 Xue et al. 135 recently reported basic fibroblast growth factors form condensates with heparan sulphate proteoglycans and activate FGFR signaling pathway. Besides, cytoplasmic scaffolds zonula occludens-1, zonula occludens-2, and claudins phase separate to regulate the assembly of tight junctions. 117

4.2.3
The role of biomolecular condensates in tissue

Immunological processes regulated by condensates
Mounting evidence has highlighted that biomolecular condensates are directly relevant to immune signaling and immune modulation. 116,136,137 On the plasma membrane, immune signaling including T cell receptor (TCR) and B cell receptor (BCR) signaling pathway is regulated by condensates. The main component of the TCR signaling pathway is the discrete TCR microclusters on the TA B L E 1 Physiological/pathological processes regulated by biomolecular condensates. membrane. These microclusters consist of a series of proteins including TCR, CD28, PD1, ZAP70, LCK, LAT, PLCγ1, GRB2, and SOS1. [138][139][140] It has been reported that four proteins in TCR microclusters, LAT, PLCγ1, GRB2, and SOS1, are able to form condensates. 141,142 These condensates participate in the activation, the baseline level reset after activation of TCR signaling, and the spatial organization of signaling receptors to further influence ligand binding. 140,143,144 In the BCR signaling pathway, scaffold protein SLP65 and its binding partner CIN85 form condensates in the cytoplasm of resting B cells, and bind to the plasma membrane after BCR activation. 145 These condensates function to facilitate calcium signaling and downstream signaling pathways. 146 In the cell, stimulator of interferon genes (STING) pathway, SG pathway, inflammasome pathway, and nuclear factor-κB (NF-κB) signaling pathway are regulated by condensates. Cyclic GMP-AMP synthase (cGAS) combines double-stranded DNA from pathogens or DNA damage, and activate the STING signaling pathway to induce the expression of inflammatory cytokines. 45,147 Recent reports have shown that cGAS not only binds to DNA and protects F I G U R E 4 Functions of biomolecular condensates. The functions of biomolecular condensates. At molecular scale, biomolecular condensates are critical for amplification, transcription, translation, and posttranslational modification process such as phosphorylation, acetylation, ubiquitination, SUMOylation, and methylation. At cellular scale, condensates participate in signal transduction, stress sensing, and transportation processes. At tissue scale, condensates involved in DNA damage, oncogenes express, antibody resistance, amyotrophic lateral sclerosis, frontotemporal dementia, ischemia-reperfusion, calcium parado, innate immunity, and adaptive immunity processes. Pol, polymerase; SGs, stress granules; PBs, P-bodies; FUS, fused in sarcoma.

Physiological/pathological processes Condensates Location References
it from interpretation, but also forms condensates with RNA and enhance STING signaling pathway when DNA concentration is low. [148][149][150] STING and its downstream components TBK1 and IRF3 also undergo phase separation process, but they suppress innate immune signaling. 137,151 Droplets composed of DNA repair proteins such as Rad52 interact with different types of DNA damage-inducible microtubule filaments, promote the localization of DNA repair proteins to damage sites, and maintain genome stability. 66 FUS is capable of phase separation at sites of DNA damage. 12 Moreover, the virus uses condensates to evade immune surveillance. ORF9, ORF52, and VP22 from viruses combined with DNA to form droplets and prevents cGAS activation. [152][153][154] Nuclear domain 10 forms condensates and restricts the expression of viral genes after viral DNA invades nucleus. 155 In recent years, SARS-CoV-2 has emerged as an urgent threat to global public health, which virus is assembled by the interaction of SARS-CoV-2 nucleocapsid protein (SARS2-NP), viral RNA genome, and M protein. 156,157 SARS2-NPs can form condensates that impair the binding of mitochondrial antiviral signaling proteins and IFN response for immune evasion and attract RNA-dependent RNA polymerase complex to promote virus replication. 121,158 Under external stress conditions, eukaryotic cells form SGs and PBs, which store large amounts of mRNA and inhibit the translation process of cells. 159 Recent studies have shown that G3BP1 bind to RNF125 in virus-induced SGs to promote its degradation. 160 G3BP1 is also able to directly interact with proteins such as retinoic acidinducible gene I and protein kinase R to act as a positive regulator of the innate immune pathway and block protein translation and viral replication. 161 PrP Sup35 forms condensates under external pressure and specific pH conditions in yeast. 126 Thermoregulatory protein heat-shock TF 1 generates condensates and efficiently drives gene transcription of heat-shock-proteins to maintain intracellular protein homeostasis. 162 Inflammasome is composed of sensor proteins, apoptosis-associated speck-like protein containing a CARD, and Caspase 1, which regulates the response to viral invasion through cytokine secretion and gasdermin D mediated pyroptosis. 163 Shen et al. 164 found that NLRP6 inflammasome can form condensates with doublestranded RNA and is efficiently triggered by lipoteichoic acid.
The TFs of the NF-κB signaling pathway include p65, RelB, c-Rel, NF-κB1, and NF-κB2, which regulate numerous inflammatory mediators, chemokines, and cytokines to activate immune response. 165 In cells infected with respiratory syncytial virus, p65 subunit, MAVS, and MDA5 tend to form condensates in the vicinity of the nucleus, which prevent them from being transferred to the nucleus to activate transcription of antiviral genes. 166 In addition, the IκB kinase complex is responsible for activating the NF-κB signaling pathway. NF-κB essential modulator is a subunit of the IκB kinase complex, which can form condensates by combining ubiquitin-binding domain, zinc finger, and K63-linked or linear polyubiquitin chains, and further activate NF-κB signaling. 113

Other processes regulated by condensates
At the tissue scale, a range of diseases including cancer, aging, and cardiac diseases are associated with abnormality condensates. Alternative lengthening of telomeres-associated promyelocytic leukemia nuclear bodies forms condensates to maintain telomere length in response to DNA damage. 167 NUP98-HOXA9 fusion protein forms puncta and regulates oncogene transcription in phase separation-dependent process. 168 SS18 has oncogenic activity by forming condensates in synovial sarcoma. 169 Glutamine in tumor microenvironment competitively inhibits mitochondrial fission in macrophages, maintains phase separation of WIP/WASP, and results in clinical antibody resistance. 170 Protein arginine methyltransferases form condensates, and its inhibitor have therapeutic effects in cancer and aging diseases. 171 Moreover, mislocalization of RBPs outside the nucleus such as FUS, TAF15, hnRNP A1, hnRNP A2, and TDP-43 leads to amyotrophic lateral sclerosis and frontotemporal dementia. 172 Furthermore, phosphatidylserine and phosphatidylethanolamine are present in the cytoplasmic globules and phase separate in the presence of calcium ions. These condensates are associated with structural changes in heart muscle cells following ischemia-reperfusion and calcium paradox. 173 In conclusion, biomolecular condensates play important roles at the molecular, cellular, and tissue scales. Therapies targeting various condensate diseases can be envisaged. 174 Biomolecular condensates provide emerging explanations for a number of previous biological processes. The synergy between biotechnology, pharmaceutical industry, and expertise from disparate fields is the key to the clinical application of these condensates.

BIOMOLECULAR CONDENSATES SERVE AS THERAPEUTIC TARGETS FOR DISEASES
The extensive biological effects of biomolecular condensates make them potential therapeutic targets for diseases. An increasing number of studies indicates that condensates are involved in various disease processes ( Figure 5 and Table 2). Here, we the reviewed diseases for which condensates can be used as therapeutic targets. These diseases include cancers, amyotrophic lateral sclerosis, kabuki syndrome, and heart and immune disease.

Condensates are therapeutic targets for a variety of cancers
In breast cancer, a large number of condensates with regulatory effects have been found. p53-binding protein 1 is capable of phase separation in chromatin, resulting in an elevated p53 response that impairs cancer cell survival. 193 AKAP95, a nuclear protein that regulates transcription and RNA splicing, supports tumorigenesis by forming F I G U R E 5 Therapeutic condensates in different diseases. The therapeutic condensates in different diseases. These diseases include: glioblastoma, breast cancer, lung cancer, gastric cancer, liver cancer, kidney cancer, prostate cancer, myeloma, leukemia, sarcomas, skin cancer, cervical cancer, ovarian cancer, colon cancer, pancreatic cancer, and mesothelioma; amyotrophic lateral sclerosis; kabuki syndrome; heart diseases; innate and adaptive immune diseases.
condensates and regulating gene expression. 213 HP1α can form condensates, which has a regulatory effect on the growth of breast cancer. 49,215 The condensates of RBP non-POU domain-containing octamer binding (NONO) regulate tumor cell proliferation by binding to mRNA of proliferation-related genes. 218 Mutations of speckle-type pox virus and zinc finger protein alter the formation of condensates and promote breast cancer progression. 54 The condensate NPM1 specifically binds to the PD-L1 promoter in breast cells and activates PD-L1 transcription, further inhibiting T cell activity in vitro and in vivo. 106,216 WIP/WASP produces condensates that prevent the protein kinase C-θ from phosphorylating WIP and reduce efficacy of promising therapeutic antibodies. 170 Furthermore, YTHDF3 increases breast cancer metastasis by enhancing the translation of m6a-enriched transcripts of ST6GALNAC5, GJA1, and EGFR. 104 Lung cancer or non-small cell lung cancer includes lung adenocarcinoma, lung squamous cell carcinoma, and large cell lung cancer. BRD4 inhibitor JQ1 inhibits proliferation of non-small cell lung cancer cell line subsets by inhibiting FOSL1 expression. 198 EML4/ALK/RET activates RAS signaling pathway in lung cancer cells through the formation of condensates. 212 SKP2 RNAs, the target of NONO, are highly expressed in small cell and non-small cell lung cancer. Inhibition of SKP2 can induce apoptosis of tumor cells and inhibit the cell invasion. 65 YAP and TAZ are widely activated in human malignancies and are essential for the initiation or growth of most solid tumors, which induces cancer cell proliferation, drug resistance, and metastasis. It has been reported that increased expression or nuclear localization of YAP or TAZ was associated with higher histological grade, advanced TNM, and lymph-node metastasis of lung cancer. 176 In addition, SUMOylation of YTHDF2 significantly increases its binding affinity to m6A-modified mRNA, subsequently leading to dysregulation of gene expression in lung cancer progression. 103 TA B L E 2 Therapeutic condensates in different diseases.

STING/TBK1
Condensates constrained STING and TBK1 to prevent innate immunity from overactivation. 137 WASP Loss of WASP condensates promoters leads to aberrant epigenetic activation. 184 Adaptive immunity GRB2/SOS1 SOS1 acts both as a RasGEF and as a scaffold to nucleate GRB2-dependent adaptor oligomerization. 141 LAT/PLCγ1 PLCγ1 protects LAT from dephosphorylation by the phosphatase CD45 and promotes LAT-dependent ERK activation and SLP76 phosphorylation. 142 SLP65/CIN85 SLP65/CIN85 complex is responsible for Ca 2+ and NF-κB responses. 146 Mesothelioma YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 185 Pancreatic cancer YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 176 (Continues)

Therapeutic condensates Mechanisms References
Colon cancer BRD4 BRD4 participates in super enhancers organization and oncogenes expression regulation. 186

ENL
Condensates are necessary for rapid transcriptional induction. 83 SFPQ SFPQ interacts with lncRNA-422 to activate downstream pathways. 187 YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 188 Ovarian cancer DAXX DAXX overexpression enhanced the proliferation, colony formation, and migration of ovarian cancer cells. 189 HP1α HP1α promotes abnormal growth and the potential for neoplasia. 190 Cervical cancer BRD4 BRD4 participates in super enhancers organization and oncogenes expression regulation. 191,192 Skin cancer YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 100 Sarcomas 53BP1 Condensates cause an elevated p53 response and impair cell survival in cancer cells. 193 BRD4/CHOP/FUS BRD4, CHOP, and FUS form condensates and act as super enhancers. 194 EWS/FLI EWS and FLI forming local high-concentration hubs of TFs. 84,85 HSF1 HSF1 is a chaperone transcriptional regulator that is fundamental to cell survival or death. 89,195 SS18 Condensates contribute to the oncogenic activity of SS18-SSX in synovial sarcomas. 169

TAF15
Condensates promote transcription of abnormal genes and contribute to their oncogenic transformation in sarcomas. 196 Myeloma BRD4 BRD4 participates in super enhancers organization and oncogenes expression regulation. 197,198 YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 199,200 Prostate cancer BRD4 BRD4 participates in super enhancers organization and oncogenes expression regulation. 201

CBX2
CBX2 promoted the proliferation, invasion and migration of cells by activating the YAP/β-catenin pathway. 202

MED1
MED1 is essential for androgen receptor mediated transcription. 203 SPOP Disease-associated SPOP mutations that lead to the accumulation of proto-oncogenic proteins. 54 Kidney cancer SPOP Condensation fails to promote the degradation of androgen receptor located in the nucleus, leading to activation of cancer progression. 204 Leukemia MED1 MED1 plays an important role in gene-specific transcriptional activation and maintenance of leukemia. 92 NPM1 NPM1-mutated AML is a WHO classification for lympho-hematopoietic tumors. 205 NUP98-HoxA9 NUP98-HoxA9 results in transcriptional activation of leukemogenic genes. 95,168 PML Mutations in the PML/RARA arsenic-binding site lead to drug resistance in patients. 206

TAF15
Condensates promote transcription of abnormal genes and contribute to their oncogenic transformation in leukemia. 196 UTX Loss of IDR in UTX is responsible for abolishing tumor suppression. 207 YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 208 (Continues)

Therapeutic condensates Mechanisms References
Liver cancer Riα RIα condensates induce aberrant cAMP signaling. 115 SFPQ SFPQ leads to cisplatin resistance in liver cancer. 209 YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 210 Gastric cancer CBX2 CBX2 promoted the proliferation, invasion, and migration of cells by activating the YAP/β-catenin pathway. 211 YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 176 Lung cancer BRD4 BRD4 participates in super enhancers organization and oncogenes expression regulation. 198 EML4/ALK/RET Condensates locally concentrate the RAS activating complex and activate RAS in a lipid membrane-independent manner. 212 NONO NONO is a key regulator for cancer proliferation through the pre-mRNA splicing of cell proliferation-related genes. 65 YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 176

YTHDF2
SUMOylation of YTHDF2 increases its binding affinity of m6A-modified mRNAs and results in deregulated gene expressions. 103 Breast cancer 53BP1 Condensates cause an elevated p53 response and impair cell survival in cancer cells. 193

BRD4
BRD4 participates in super enhancers organization and oncogenes expression regulation. 214 HP1α HP1α promotes abnormal growth and the potential for neoplasia. 215 NONO NONO is a key regulator for cancer proliferation through the pre-mRNA splicing of cell proliferation-related genes. 65 NPM1 NPM1 binds to PD-L1 promoter specifically in TNBC cells and activates PD-L1 transcription, thus inhibiting T cell activity. 216 SPOP Disease-associated SPOP mutations that lead to the accumulation of proto-oncogenic proteins. 54 WIP/WASP Condensates prevent protein kinase C-θ to phosphorylate WIP during phagocytosis. 170 YAP/TAZ YAP/TAZ activates target genes and is directly involved in the control of S-phase entry and mitosis. 100,217 YTHDF2 YTHDF2 interacts with mRNAs encoding proteins in the MAPK pathway and increases global translation rates. 102

YTHDF3
YTHDF3 enhances the translation of transcripts associated with tumor metastasis. 104 Liver cancer includes hepatocellular carcinoma, cholangiocarcinomas, and hepatoblastoma. cAMP-dependent protein kinase type I regulatory subunit, RIα, can form condensates rich in cAMP and PKA activity. Loss of RIα in normal cells increases cell proliferation and induces cell transformation. PKA fusion oncoprotein associated with liver cancer can effectively block the formation of condensates and improve the abnormal cAMP signaling pathway. 115 An RNA-and DNA-binding protein, splicing factor proline-and glutamine-rich, can induce cisplatin resistance in liver cancer cells. 209 Recent studies have shown that splicing factor proline-and glutamine-rich is essential for DNA repair and paraspeckle formation and is capable of forming condensates. 219 Increased expression of YAP or TAZ was also associated with poor prognosis of liver cancer. 210 In leukemia, condensates of MED1 play an important role in the E2A-PBX1-driven gene-specific transcriptional activation and the maintenance of leukemia. 92 Genetic abnormalities caused by NPM1 mutations often occur in human acute myeloid leukemia, which accounts for about one-third of all cases. 205 The condensates of NUP98-HOXA9, which regulate transcriptional activity and transform hematopoietic cells, are critical for the development of leukemia. 168 Nuclear bodies PML play a key role in the treatment of acute promyelocytic leukemia and are druggable. 206 FUS/EWS/TAF15 fusion oncoproteins were able to promote abnormal gene transcription by forming condensates and contribute to their oncogenic transformation ability in leukemia. 196 UTX is an important tumor suppressor that encodes the histone H3K27 demethylase and regulates genome-wide histone modification and higher-order chromatin interactions by forming condensates. 207 Moreover, increasing the level of YAP1 in malignant hematologic diseases can restore the apoptosis induced by nuclear ABL1 kinase and alleviate the disease process. 208 Gliomas include astrocytoma, oligodendroglioma, oligoastrocytoma, and glioblastoma multiforme. BRD4, YAP/TAZ, and YTHDF2 have regulatory effects on glioblastoma. BRD4, YAP/TAZ form condensates and participate in the assembly of super enhancers to further regulate cellular gene transcription. 90,220 Inhibition of BRD4 can inhibit the proliferation of glioma cells and promote the apoptosis of tumor cells, and knockout of YAP/TAZ can prevent tumor formation in SCID mice injected with primary cancer cell lines in situ. 175,176 YTHDF2 stabilizes MYC and VEGFA transcription in glioma cells in an m6a-dependent manner and enhances tumor activity. 178,221 In clinical prostate cancer tumor samples, BRD4 protein levels were inversely associated with tumor response after radiation therapy. 201 The condensates of CBX2 organize the Polycomb group, which inhibits major regulators of development and differentiation by organizing chromatin structure. 58 The use of inhibitors of CBX2 in the treatment of prostate cancer is highly desirable. 202 CDK7-specific inhibitor THZ1 also inhibits prostate tumor growth by blocking MED1 corecruitment genome-wide and reverses the drug-resistant phenotype caused by hyperphosphorylated MED1. 203 Furthermore, speckle-type pox virus and zinc finger protein mutations contribute to prostate cancer by accumulating proto-oncogene proteins that interfere with phase separation and colocalization in membraneless organelles. 54 In Ewing's sarcoma tumors, condensates formed by EWS and FLI are functionally associated with transactivation capacity and carcinogenic potential of cells. 84 BRG1/BRM-associated factor complexes can also be recruited by EWS-FLI1 fusion proteins into tumor-specific enhancers and contribute to target gene activation. 85 Condensates of FUS/EWS/TAF15 can also promote the abnormal gene transcription and the onco-genic transformation ability in sarcoma. 196 Furthermore, the FUS-CHOP fusion protein can also form condensates with BRD4 and caused myxoid liposarcoma. 194 Besides, heat-shock factor 1 is a transcriptional regulator of chaperone and is capable of forming condensates. Inhibiting the formation of these condensates can promote the activity of heat shock factor 1 and cell survival and reduce the incidence of sarcoma. 89,195 The condensates of SS18 recruit BRG1, which can be used as a marker for synovial sarcoma. 169 p53-binding protein 1 is associated with various DNA repair or cell cycle factors and is involved in the cell's response to DNA double-strand breaks. 193 Gastric cancer originates in the glandular epithelium of the stomach. In gastric cancer, CBX2 is capable of forming condensates that concentrate DNA and nucleosomes. 58 Deletion of CBX2 blocks the YAP/β-catenin pathway and inhibits the tumor cell proliferation, migration, and invasion. 211 YAP mRNA and protein levels are upregulated in gastric cancer. Reintroduction of YAP in YAP-mutated gastric cancer cell line MKN45 can promote its growth as subcutaneous tumors. 176 Colorectal cancer originates in the mucosal epithelium of the colon and rectum. Concentrations of the super elongation complex component, ENL, were associated with colorectal cancer-specific mortality. 222 Recent studies have shown that the condensates formed by ENL can isolate and concentrate positive TF b in inactive HEXIM1 and activate transcription processes. 83 BRD4 is strongly enriched at TERT promoter in colon cancer cells. 186 Splicing factor proline-and glutamine-rich loss can reduce the proliferation of colorectal cancer cells driven by BRAFV600E kinase and specifically induce S-phase arrest and apoptosis. 187 High level of YAP expression is also a factor for poor prognosis and is associated with cetuximab resistance. 188 In ovarian cancer cells, DAXX interacts with promyelocytic leukemia protein and is localized to nuclear bodies PML in the subnuclear domain. This process enhances proliferation, colony formation, migration, and drug resistance in multiple ovarian cancer cell lines, whereas RNA interference with DAXX can reverse these processes. 189 Besides, human ovarian cancer cell line treated with 17allylamino-17-demethoxygeldanamycin was accompanied by downregulation of HP1α expression. 190 In addition, BRD4 recruits transcriptional regulatory complex to acetylated chromatin, and its inhibitors are therapeutic for myeloma. 197,198 In cervical cancer, NSD3 and JMJD6 are recruited into regulatory genes in a BRD4-dependent manner to regulate transcriptional activity. 191 Gαq can promote YAP-dependent growth of uveal melanoma cells. 200 Verteporfin, a YAP inhibitor, blocks tumor growth in uveal melanoma cells containing the Gq/11 mutations. 199 Pancreatic-specific knockout of YAP improves tumor progression in mouse model of pancreatic cancer. 223 YAP/TAZ signaling pathway is also significantly changed in skin cancer 224 and malignant pleural mesothelioma tumors, and the inhibitors of YAP/TAZ signaling pathway can effectively reverse the phenotype of the diseases. 185 Besides, speckle-type pox virus and zinc finger protein act as substrate connectors for cullin 3-based E3 ligase. It is capable of target proteins for ubiquitination and subsequent proteasome degradation, and its abnormality may be involved in the occurrence and progression of human kidney cancer. 204

Condensates are critical for immune disease
In innate immunity, the dsDNA sensor cGAS can form condensates with dsDNA or RNA to activate downstream signaling pathways. Abnormal cGAS activity can lead to diseases such as Aicardi-Goutieres syndrome. 148 G3BP1 is an important antiviral protein that is essential for SG assembly in innate immunity, which activates innate immune responses through transcription of NF-κB and JNK. 161 IKBKG can form condensates with polybiquitin chains. 113 A decrease in condensates of IKBKG due to mutations leads to human immunodeficiency, while an increase leads to inflammatory diseases. 183 SIRT1 agonists can inhibit the hyperacetylation of IRF3/IRF7 in DNAbinding domain, promote the formation of condensates, activate innate immunity, and ultimately reduce viral load and mortality in mice. 151 Herpes simplex virus is the cause of various herpes diseases including cold sores, interstitial keratitis, and encephalitis. Nuclear bodies nuclear domain 10 are able to cluster on viral DNA and restrict the expression of viral genes. 155 NLRP6 can form condensates with dsRNA to induce inflammasome activation and interferon production to perform host defense functions. 164 Varicella-Zoster virus tegument protein ORF9 can bind to cGAS and form condensates with DNA, which inhibiting cGAS to produce cGAMP, and eventually causing chickenpox and shingles. 153 Notably, herpesvirus-coated membrane proteins ORF52 and VP22 undergo phase separation with DNA in vitro and in cells, which effectively disrupt preformed condensates of cGAS-DNA. 154 The respiratory syncytial virus nucleocapsid protein can form condensates with p65 and block the innate immune interferon signal pathway. 166 SARS-CoV-2 nucleocapsid RNA and protein also form condensates that allow efficient transcription of viral RNA, which can be interfered by small molecules or biologics. 158 The condensates of STING were able to constrained TBK1 to prevent excessive activation of innate immunity, while microtubule inhibitors could hinder the generation of these condensates and increase the produc-tion of type I interferon in DNA virus-infected cells. 137 Moreover, the condensates formed by WASP, SRSF2, RNA, and Pol II are able to control RNA transcription and splicing, and defects in condensate formation lead to Wiskott-Aldrich syndrome. 184 In adaptive immunity, GRB2 and SOS1 can form condensates, which bind to T cell adaptor protein LAT and promote thymus cell development. 141 PLCγ1 is also able to directly cross-link LAT through its two SH2 domains to form condensates that protect LAT from dephosphorylation by CD45 and promote LAT-dependent ERK activation and SLP76 phosphorylation. 142 In addition, effective B cell activation requires condensates formed by the proline-rich motif of SLP65, the nine SH3 domains of trimeric CIN85, and the lipid vesicle. 146

Condensates in amyotrophic lateral sclerosis, Kabuki syndrome, and heart disease
Amplification of short nucleotide repeats contributes to the formation of condensates and can cause several neurological and neuromuscular diseases. DMPK forms condensates and produces amyotrophic lateral sclerosis. 179 FUS contains intrinsic disordered domains is able to form condensates at sites of DNA damage and in stressed cytoplasm and associated with the neurodegenerative disease. 12 Condensates formed by TAF15/hnRNP A1/hnRNP A2 are important drivers of amyotrophic lateral sclerosis. 172 In addition, the altered condensates of TDP-43 can selectively modify its RNA-regulatory network, further affecting the course of amyotrophic lateral sclerosis. 180 Kabuki syndrome patients have characteristic facial features, mild bone abnormalities, intellectual impairment, and postpartum growth defects. MLL4 regulates chromatin compartmentalization by forming condensates, and haploinsufficiency of MLL4 leads to changes in nuclear architecture in Kabuki syndrome. 181 Phosphatidylserine and phosphatidylethanolamine can undergo phase separation in the presence of calcium ions. These condensates are associated with irreversible destruction of sarcolemma, ischaemia, ischaemia and reperfusion, and the calcium paradox. 173 Furthermore, SHP2 mutants form condensates that recruit and activate wild-type SHP2 to promote MAPK activation, which results in developmental disorders in humans. 182 Together, biomolecular condensates can be therapeutic targets for diseases such as cancer, amyotrophic lateral sclerosis, kabuki syndrome, and heart and immune diseases. These evidence make condensates an essential candidate for therapeutic intervention. Therefore, the regulation of condensates is becoming a timely and exciting challenge. Related research will open up more possibilities for future drug discovery.

Regulatory targets of biomolecular condensates
Emerging understanding of the mechanisms of condensate formation and function provides novel therapeutic opportunities. Among the components involved in the condensates, many of them were found to be able to serve as regulatory targets. In this section, we comprehensively discussed the latest findings of regulatory targets of biomolecular condensates. These targets include nucleic acid, amino acid, protein repeat domain, intrinsically disordered region (IDR), macromolecule, ATP, and pH.

6.1.1
Nucleic acid serves as a key component of condensates In many cases, nucleic acid functions to facilitate phase separation ( Figure 6A). DNA binds to heterochromatin protein 1α and promotes phase separation. 49 RNA binds to G3BP1 to promote the formation of condensates then regulate the translation process. 225 There are two highly conserved polybasic regions in the N-terminal of PrP fragment, which have charge complementarity with nucleic acid. 18 In the presence of 150 mM NaCl, the addition of crude tRNA promotes PrP phase separation, which further turn into solid-like condensates. 18 However, during phase separation of prion-like RBPs, a high RNA:protein ratio inhibits formation of condensates. 226 Intriguingly, RNA not only contributes to the formation of condensates but also is able to regulate itself by binding to condensates. The polyglutamine (polyQ) protein Whi3 generates different condensates depending on the RNA sequence further induce RNA conformational changes. 227

6.1.2
Amino acid affects the formation of condensates Amino acid mutations or modifications can modulate phase separation ( Figure 6B). Phosphorylation of serine 149 of G3BP inhibits the formation of SGs. 228 The adaptor protein Nck promotes condensate formation through three SRC homology 3 domains that bind to multiple prolinerich fragments in N-WASP, and an SH2 domain binds to multiple phosphotyrosine sites in Nephrin. 229 Three evenly distributed tryptophan-binding pockets in Arg-onaute2 and glycine/tryptophan-rich domain in TNRC6B produce condensates. 230 Moreover, different phosphorylation patterns in serine/threonine of fragile X mental retardation protein and tyrosine of CAPRIN1 are associated with phase separation. 231

6.1.3
Protein repeat domain contribute to condensate formation Protein repeat domain is critical for the formation of biomolecular condensates ( Figure 6C). A lot of evidence showed that mutated protein repeats change the solubility of proteins and contribute to a variety of developmental and neurodegenerative diseases. 232 It has been reported that the VASA-related P granule proteins GLH-1, GLH-2, and GLH-4 contain nuclear pore complex-like FG repeat domains in C. elegans. 51

IDR is required for proteins to form condensates
Intrinsically disordered proteins refer to functional proteins that cannot fold into a clear spatial structure (Figure 6D), which typically have the IDR. 233 Proteins with IDRs are also involved in multivalence protein interactions and tend to form condensates. 5 The N-terminus of dual-specificity kinase DYRK3 form SGs through its IDR and kinase activity. 234 IDR of FUS promote condensate formation when DNA damage or cytoplasmic stress. 124 Moreover, CsoS2, Ddx4, NPM1, and Xvelo also promote phase separation through homotypic interactions of its IDR. 15,31,106,235 6.1.5 Macromolecule crowding and confinement promote the assembly of condensates It has been reported that the addition of organic additives and salts increases crowding and confinement effects in solution and further influence the formation of condensates ( Figure 6E). 236 Crowding effect refers to the volume repulsion effect of one soluble macromolecule on another soluble macromolecule, and confinement effect refers to effect of the fixed boundary on solubility of the macromolecule. These effects promote the assembly of SPD-5, cGAS, microtubule polymerase ZYG-9, and microtubule stabilizing protein TPXL-1 into condensates. 14,45 Moreover, although the Golgi protein GM130 is not an inherently disordered protein, its overexpression still enables the formation of droplets. 237 Notably, molecular chaperones can partially counteract these effects by allowing the protein to fold within the chaperone cavity and releasing the native-like protein. 238 Protein disulfide isomerase, a protein folding catalyst acts as a molecular chaperone, prevent the accumulation of lysozyme in the crowded state. 239 6.1. 6 ATP and pH regulate the formation of condensates Recently, the dynamic changes of ATP and pH related to cellular respiration have been discovered in process of phase separation ( Figure 6F). ATP participated in the assembly of SGs and viscosity of the nucleolus. 24 Shi et al. 240 revealed that ATP promote Ddx3xb undergo liquid-liquid phase separation through its N-terminal IDR. Besides, either ATP or the DEAD-box ATPase Dhh1 modulate the formation of PBs. 241 Changes in pH also affect the size and solubility of condensates. 242 A lower pH lead to a decrease in cytoplasmic fluidity and inhibits phase separation of ovalbumin. 243 Collectively, we summarize the current regulatory targets of biomolecular condensates, which are capable of acting as drivers and disruptors of condensate formation and function. More importantly, condensates are considered to be an emerging explanation for a large number of previously unknown phenomena, and further exploration is needed to explore more available regulatory targets for regulating condensates to interfere with various physiological and pathological functions.

Regulatory methods of biomolecular condensates
In order to regulate the formation of biomolecular condensates, here are some methods that can be used against the above six targets. Modulating the formation of these condensates provides potential strategy for treatment of diseases. In this section, we comprehensively discussed the latest findings of available regulatory methods of biomolecular condensates (Figure 7). These methods include DNA editing, RNA interference, protein degradation, and molecule drugs treatment.

6.2.1
Editing DNA involved in condensate formation DNA editing relies on DNA recognition elements and a variety of endonucleases to introduce mutations into genes, which interfere the formation of condensates at the DNA stage. 244 There are four types of DNA editing systems commonly used: meganuclease, zinc-finger nuclease, transcription activator-like effector nuclease, and CRISPR-Cas system. Meganucleases are also known as homing endonucleases, which are a class of highly sequence-specific and efficient enzymes found in yeast. 245 Meganucleases system can specifically recognize DNA sequences ranging in length from 14 to 40 base pairs, then cleave homologous alleles without introns to generate double-strand breaks and stimulate gene repair processes for homing. 246 The zinc-finger nuclease system relies on zinc finger proteins and endonucleases. Zinc finger proteins can bind DNA and recognize 9 bp DNA through their Cys2-His2 fingers, and endonucleases can induce double-strand breaks at specific positions in DNA, further achieving the purpose of gene deletion or addition through nonhomologous end joining or homology-directed repair pathways. 247 The transcription activator-like effector nuclease system is similar as the zinc-finger nuclease system, which also requires the fusion of DNA-binding elements to the nonspecific FokI nuclease. The difference between two systems is that the DNA-binding elements in the transcription activator-like effector nuclease system are derived from Xanthomonas transcription activator-like effectors, which contain a highly conserved repeat sequence that recognizes specific DNA sequence. 248 The CRISPR/Cas system was originally discovered in bacteria and shows an antiviral function by cleaving nucleic acids that invade cells, which is currently the most used gene editing system. 249 This system can cut DNA sequences via two pathways: one relies on multiprotein complexes, and the other relies on a single Cas protein. Notably, these systems have the disadvantage of off-target editing. [250][251][252] Recently, Shin et al. recently reported CasDrop, a novel optogenetic technology developed based on DNA editing, regulate phase separation of inherently disordered proteins. 98 Intriguingly, the presence or absence of the specific nucleic acid can be further determined by DNA F I G U R E 6 Regulatory targets of biomolecular condensates. The six regulatory targets of biomolecular condensates: (A) nucleic acids are essential for the formation of condensates such as G3BP1, Whi3, and prion protein; (B) amino acids such as positively charged amino acids, negatively charged amino acids and hydrophobic amino acids are involved in the formation of condensates; (C) protein repeat domain such as the FG motif of GLH-1, GLH-2, and GLH-4 is critical for condensates stability; (D) intrinsically disordered region is able to regulate the formation of condensates such as DYRK3; (E) concentration, crowding effect and edge effect can regulate the formation of condensates; (F) ATP is involved in the formation of condensates such as Ddx3xb, SGs, and PBs; pH is related to condensate formation such as Ovalbumin. The red area in (B) represents the R group of amino acid. IDR, intrinsically disordered region; PrP, prion protein; SPD-5, spindle-defective protein 5; cGAS, cyclic GMP-AMP synthase.
editing-based phase separation. The 60 bp poly-T DNA and poly-l-lysine promote phase separation and result in a turbid solution, whereas the addition of CRISPR/Cas12a or Cas13a cleaves specific DNA or RNA sequences and inhibits the formation of condensates. 253

6.2.2
Interfering RNA disrupts biomoleculars to form condensates RNA interference (RNAi) modulate phase separation at the RNA stage. There are two types of RNAi used: small RNA and antisense oligonucleotides (ASOs). 254 The small RNA can be divided into three categories: short interfering RNAs, repeat-associated short interfering RNAs, and microRNAs. In the process of gene silencing, these RNAs rearrange in the RNP to form RNA-induced silencing complexes, which further recognize complementary mRNA through its single-stranded siRNA and induce mRNA degradation. 255 ASOs are single strands of deoxynucleotides that usually 8-50 bp in length, which were found to have the ability to inhibit the translation of Rous sarcoma viral RNA in 1978. 256 ASOs can bind to RNA to form a DNA-RNA complex, which enables RNA to be degraded by RNase H and ultimately inhibit protein expression. 257 Recent studies have shown that the fluidity of PAR and their response to extracellular osmotic pressure can be reduced by small RNA. 258 NONO-TF E3 translocation renal cell carcinoma is a subtype of renal cell carcinoma. 259 203 and promotes GSK3β-mediated degradation. 260 Abnormal amplification sequences are toxic to cells and are sufficient to result in trinucleotide repeat expansion diseases such as Alzheimer's disease, Parkinson's disease, Huntington's disease, amyotrophic lateral sclerosis, and prion diseases. 261 The RNA sequences of them contain a regular pattern of G and C nucleotides that are capable of intermolecular multivalent interactions that further lead to phase separation. 232 Small RNA and 6×CTG ASOs induce RNase H-catalyzed degradation of huntingtin mRNA and alleviate disease phenotype in the cerebrospinal fluid. 179,262 Moreover, mutations in SOD1 result in neurotoxicity and lead to amyotrophic lateral sclerosis. 263 Therapies that directly deliver ASOs of SOD1 reduce the amount of mutant SOD1 in fibroblasts from amyotrophic lateral sclerosis patients and significantly slow disease progression. 264

6.2.3
Eliminate proteins to prevent condensate assembly There are four types of protein degradation technologies commonly used: proteolysis targeting chimera, lysosometargeting chimaera, autophagy-targeting chimera, and autophagosome-tethering compound (ATTEC). 265 The protein degradation function of the proteolysis targeting chimera relies on the UPS system in the cell that bind both the target protein and the ubiquitin ligase, resulting in the ubiquitination and further degradation of the target protein. 266,267 The lysosome-targeting chimaera, autophagy-targeting chimera, and ATTEC rely on lysosomal degradation system. The lysosomal degradation system needs lysosomes to degrade extracellular substances, plasma membrane proteins, cytosolic components, or organelles. There are two lysosomal degradation pathways in eukaryotic cells: the endosome-lysosomal pathway and the autophagy pathway. Specifically, the endosomelysosomal pathway degrades endocytic substances and excess cellular components through a membrane binding process. 268 In autophagy pathway, a part of the cytoplasm is engulfed by phagocytes to form autophagosomes, which are further fused with and degraded by lysosomes. 269 These protein degradation methods can degrade polyQ proteins, such as mutant ATXN3, which can result in type III spinocerebellar ataxia disease. Li et al. 270 reported a small-molecule compounds interact with LC3 and mutant HTT but not with wild-type HTT protein, reduce mutant HTT protein and improve phenotype in Huntington's disease. Intriguingly, nonprotein substrate molecules can also be degraded by ATTEC. 271

6.2.4
Efficient regulation of condensate formation by molecule drugs Molecule drugs treatment can modulate phase separation effectively. 1,6-Hexanediol inhibits phase separation by disrupting hydrophobic interactions. 272 1,6-Hexanediol inhibits phase separation of architectural long noncoding RNA NEAT1 and prevents assembly process of paraspeckles. 77 Qiao et al. 273 reported pinin, a protein localizes to desmosomes and nucleus, formed condensates with METTL3 then suppressed by 1,6-hexanediol. Moreover, 1,6-hexanediol prevents phase separation of SARS2-NP, IDR-rich scaffold protein NSP5, RNA chaperone NSP2, BRD4, and MED1 effectively. 90,121,274 Furthermore, specific concentrations of 1,6-hexanediol lead to nucleosome clutches larger and more evenly distributed in the cells, result in irreversible changes in chromatin. 275 BRD4 and MED1 are two bromodomain-containing molecules that modulate the formation of transcriptional condensates. The inhibitor JQ1 can bind to their bromodomain and prevent phase separation. 80 MED1 also forms condensates with estrogen receptor alpha in an estrogendependent manner. 94 Tamoxifen is able to inhibit estrogen production and prevent the formation of the MED1 condensates. 80 Besides, condensates formed by mediator and TFs are sensitive to transcriptional inhibitors. 93 Ammonium acetate at 100 mM interferes with multivalent interactions in the 47×CAG RNA condensates and further leads to its degradation. 179 Doxorubicin also blocks the formation of CAG RNA condensates in vitro. 179 Together, DNA editing, RNAi, protein degradation, and molecule drugs treatment can regulate phase separation effectively. However, these methods still have off-target effects with unpredictable and irreversible consequences and the possible impact needs to be carefully considered. The combination of biochemistry and biophysics will greatly benefit the development of new techniques. These technologies can further provide new opportunities for basic and clinical research in related diseases.

CONCLUDING REMARKS AND FUTURE PERSPECTIVES
In the past few years, significant progress has been made in the biomolecular condensates. In this review, we highlighted the importance in elucidating the regulation of biomolecular condensates. Amplification, transcription, translation, and posttranslational modification process at molecular scale, and transport and signal transduction at cellular scale process are all involved in condensates. Numerous diseases were caused by aberrant condensate formation. There are a range of regulatory targets and methods functions depend on the formation and function mechanism of condensates, which provides new opportunities for drug development and clinical treatment of diseases.
Biomolecular condensates are emerging as attractive new targets for drug discovery. Many proteins and nucleic acids of high therapeutic value all work in condensates. There have been a series of reports suggesting that condensates are druggable. A number of approved drugs such as cisplatin and tamoxifen that have been shown to form condensates that affect the concentration and activity of the drug. 80 Drug-like molecules that modulate the formation of condensates in a selective manner have been identified by screening. 121,276 Posttranslational modification has a strong regulatory effect on the formation and dissolution of condensates. 277 There are a number of small molecules that have completed clinical trials have been able to target condensates (Table 3). It is tempting to speculate that many other potential drugs may exert their pharmacological benefit by modifying the condensates.
However, there are still several issues to be addressed in continued research. First, a large number of proteins should be further examined. Whether they function by forming condensates? Many proteins with known functions, especially TFs, may be involved in biological processes as condensates. As this hypothesis is tested, we will discover more ways to regulate these proteins. What molecular mechanisms are involved? Condensates are usually formed from more than one component, and the components do not necessarily interact directly with each other. Exploring the components in condensates will provide new targets for clinical treatment. Second, biomolecular condensates provide a large number of potential drug targets for treatment of diseases, such as aging diseases, and the phase transition of chemotherapeutic drugs in cancer treatment. What are the druggability of these targets? Preliminary evidence has shown that disrupt the assembly and disassembly of these condensates are important in health and disease. In order to fully develop approved drugs for clinical application, further validation of these molecular is needed. Third, how to develop more technologies based on the selective generation or degradation of condensates? Condensates are involved in a large number of biological functions, however, current regulatory methods still have side effects. There is an urgent need to integrate other disciplines to develop techniques for more effective intervention in condensate formation and function. Furthermore, the condensates are regulated by multivalent interactions and thermodynamic conditions and have relatively stable material properties. Therefore, it is attractive to develop an easily manipulated condensates system to selectively promote and inhibit the assembly and function of target molecules even if they do not contain IDR. Solving these problems may require drawing on disciplines such as biochemistry and biophysics. These issues must be met to provide novel therapies in the future.

A U T H O R C O N T R I B U T I O N
X. N. conceived and drafted the manuscript, drew the figures, and discussed the concepts of the manuscript. Lei. Z. conceived and drafted the manuscript, and discussed the concepts of the manuscript. Y.W. provided valuable discussion and funding. Z. Z. and B. W. discussed the concepts of the manuscript. Long. Z., F. Z., and J. L. provided valuable discussion and revised the manuscript. All authors have read and approved the final manuscript.

A C K N O W L E D G M E N T S
We thank Yanwei Li, Guifeng Xiao, Wei Yin, and Zhaoxiaonan Lin from the Core Facilities and Zhejiang University School of Medicine for their technical support.

C O N F L I C T O F I N T E R E S T S TAT E M E N T
The authors declare no conflict of interest.