Biomolecular condensates at the nexus of cellular stress, protein aggregation disease and ageing

Amyotrophic lateral sclerosis caused by TARDBP mutations: from genetics to TDP-43 proteinopathy

Mutations in the TARDBP gene, which encodes the TDP-43 protein, account for only 3-5% of familial cases of amyotrophic lateral sclerosis and less than 1% of cases that are apparently idiopathic. However, the discovery of neuronal inclusions of TDP-43 as the neuropathological hallmark in the majority of cases of amyotrophic lateral sclerosis has transformed our understanding of the pathomechanisms underlying neurodegeneration. An individual TARDBP mutation can cause phenotypic heterogeneity. Most mutations lie within the C-terminus of the TDP-43 protein. In pathological conditions, TDP-43 is mislocalised from the nucleus to the cytoplasm, where it can be phosphorylated, cleaved, and form insoluble aggregates. This mislocalisation leads to dysfunction of downstream pathways of RNA metabolism, proteostasis, mitochondrial function, oxidative stress, axonal transport, and local translation. Biomarkers for TDP-43 dysfunction and targeted therapies are being developed, justifying cautious optimism for personalised medicine approaches that could rescue the downstream effects of TDP-43 pathology.

NSCLC cells sustain phase separation of cytoplasmic membrane-less organelles to protect themselves against cisplatin treatment

Cisplatin is the first platinum compound used for anticancer therapy, including non-small cell lung cancer (NSCLC). However, the clinical efficacy of cisplatin is strongly limited by cisplatin resistance. Hence, illuminating the mechanism of cisplatin resistance will aid in the development of therapeutic strategies that improve the sensitivity of cancer cells to cisplatin. Interestingly, membrane-less organelles, which are formed through biomolecular condensation in association with phase separation, have been recently linked with cancers. Here, we reveal a new molecular basis of cisplatin resistance in NSCLC, showing that cisplatin kills cancer cells by the alteration of cytoplasmic membrane-less organelles. Specifically, cisplatin treatment results in the disassembly of processing bodies (PBs) and the assembly of stress granule (SG)-like granules which are different from canonical SGs in NSCLC cells, but not cisplatin-resistant NSCLC cells. Moreover, alterations of PBs and noncanonical SG-like granules are associated with cisplatin-induced cancer cell death. Importantly, we found that disrupting PBs and canonical SGs with cycloheximide and FDA-approved pyrvinium helps cisplatin to kill cisplatin-resistant NSCLC cells. Taken together, our findings provide insight into the role of membrane-less organelle regulation in cisplatin resistance and offer an effective solution for overcoming cisplatin resistance in NSCLC.

Electric field-induced control of protein crystal morphology

In a previous study (D. Ray, et al., J. Phys. Chem. Lett., 2024, 15, 8108-8113), we found that an alternating electric field considerably affects the location of the crystallization boundary and the liquid-liquid phase separation line as well as crystallization kinetics in lysozyme solutions containing sodium thiocyanate (NaSCN). The present study extends this work by investigating the influence of the same electric field on the microscopic appearance of lysozyme crystals as they form from a supersaturated solution. We observe a variety of distinct crystal morphologies, which we classify as single- and multi-arm crystals, flower-like crystal structures, whiskers, and sea-urchin crystals. Crystal morphologies exhibit significant variations with changes in protein and salt concentrations, and the electric field strongly alters the morphology-state diagram in the protein-versus-salt concentration plane. This alteration is likely due to the field effect on protein-protein interactions. We believe the effect is mediated by the field-enhanced adsorption of SCN- ions to the surface of lysozyme, ultimately driving the observed changes in crystallization behavior. These findings offer insights into how electric fields can be used to control crystal formation and morphology in protein systems.

Proximity-activated DNA scanning encoded sequencing for massive access to membrane proteins nanoscale organization

Cellular structure maintenance and function regulation critically depend on the composition and spatial distribution of numerous membrane proteins. However, current methods face limitations in spatial coverage and data scalability, hindering the comprehensive analysis of protein interactions in complex cellular nanoenvironment. Herein, we introduce proximity-activated DNA scanning encoded sequencing (PADSE-seq), an innovative technique that utilizes flexible DNA probes with adjustable lengths. These dynamic probes are anchored at a single end, enabling free swings within a nanoscale range to perform global scanning, recording, and accumulating of information on diverse proximal proteins in random directions along unrestricted paths. PADSE-seq leverages the autonomous cyclic cleavage of single-stranded DNA to sequentially activate encoded probes distributed throughout the local area. This process triggers strand displacement amplification and bidirectional extension reactions, linking proteins barcodes with molecular barcodes in tandem and further generating millions to billions of amplicons embedded with the combinatorial identifiers for next-generation sequencing analysis. As a proof of concept, we validated PADSE-seq for mapping the distribution of over a dozen kinds of proteins, including HER1, EpCAM, and PDL1, in proximity to HER2 in breast cancer cell lines, demonstrating its ability to decode multiplexed protein proximities at the nanoscale. Notably, we observed that the spatial distribution of proximal proteins around low-abundance target proteins exhibited greater diversity across regions with variable proximity ranges. This method offers a massive access for high-resolution and comprehensive mapping of cellular molecular interactions, paving the way for deeper insights into complex biological processes and advancing the field of precision medicine.

Targeting a key disulfide linkage to regulate RIG-I condensation and cytosolic RNA-sensing

Maintaining innate immune homeostasis is critical for preventing infections and autoimmune diseases but effective interventions are lacking. Here we identified C864-C869-mediated intermolecular disulfide-linkage formation as a critical step for human RIG-I activation that can be bidirectionally regulated to control innate immune homeostasis. The viral-stimulated C864-C869 disulfide linkage mediates conjugation of an SDS-resistant RIG-I oligomer, which prevents RIG-I degradation by E3 ubiquitin-ligase MIB2 and is necessary for RIG-I to perform liquid-liquid phase separation to compartmentalize downstream signalsome, thereby stimulating type I interferon signalling. The corresponding C865S 'knock-in' caused an oligomerization defect and liquid-liquid phase separation in mouse RIG-I, which inhibited innate immunity, resulting in increased viral load and mortality in mice. Using unnatural amino acids to generate covalent C864-C869 linkage and the development of an interfering peptide to block C864-C869 residues, we bidirectionally regulated RIG-I activities in human diseases. These findings provide in-depth insights on mechanism of RIG-I activation, allowing for the development of methodologies that hold promising implications in clinics.

Coalescence-Driven Local Crowding Promotes Liquid-to-Solid-Like Phase Transition in a Homogeneous and Heterogeneous Droplet Assembly: Regulatory Role of Ligands

Liquid-to-solid-like phase transition (LSPT) of disordered proteins via metastable liquid-like droplets is a well-documented phenomenon in biology and is linked to many pathological conditions including neurodegenerative diseases. However, very less is known about the early microscopic events and transient intermediates involved in the irreversible protein aggregation of functional globular proteins. Herein, using a range of microscopic and spectroscopic techniques, we show that the LSPT of a functional globular protein, human serum albumin (HSA), is exclusively driven by spontaneous coalescence of liquid-like droplets involving various transient intermediates in a temporal manner. We show that interdroplet communication via coalescence is essential for both initial aggregation and growth of amorphous aggregates within individual droplets, which subsequently transform to amyloid-like fibrils. Immobilized droplets neither show any nucleation nor any growth upon aging. Moreover, we found that the exchange of materials with the dilute dispersed phase has negligible influence on the LSPT of HSA. Our findings reveal that interfacial properties effectively modulate the feasibility and kinetics of LSPT of HSA via ligand binding, suggesting a possible regulatory mechanism that cells utilize to control the dynamics of LSPT. Furthermore, using a dynamic heterogeneous droplet assembly of two functional proteins, HSA and human serum transferrin (Tf), we show an intriguing phenomenon within the fused droplets where both liquid-like and solid-like phases coexist within the same droplet, which eventually transform to a mixed fibrillar assembly. These microscopic insights not only highlight the importance of interdroplet interactions behind the LSPT of biomolecules but also showcase its adverse effect on the structure and function of other functional proteins in a crowded and heterogeneous protein assembly.

Applications of Liquid-Liquid Phase Separation in Biosensing

Phase separation, particularly liquid-liquid phase separation (LLPS), has emerged as a powerful tool in biological research, offering unique advantages for visualizing and analyzing biomolecular interactions. This review highlights recent advances in leveraging LLPS to develop experimental techniques for studying protein-protein interactions (PPIs), protein-RNA interactions, and enzyme activity. The integration of LLPS with advanced techniques has expanded its applications, offering new possibilities for unraveling the complexities of cellular function and disease mechanisms. Looking forward, the development of more versatile, sensitive, and targeted LLPS-based methods is poised to transform molecular biology, providing deeper insights into cellular dynamics and facilitating therapeutic advancements.

Toward Design Principles for Biomolecular Condensates for Metabolic Pathways

Biology uses membrane-less organelles or biomolecular condensates as dynamic reaction compartments that can form or dissolve to regulate biochemical pathways. This has led to a flurry of research aiming to design new synthetic organelles that function as reaction crucibles for enzymes and biomolecular cascades in biotechnology. The mechanisms by which a condensate can enhance multistep biochemical processes including mass action, tuning the chemical environment, scaffolding and metabolic channelling is reviewed. These mechanisms are not inherently beneficial for the rate of enzymatic processes but can also inhibit a reaction. Similarly, some aspects of condensates are likely intrinsically inhibitory including retardation of diffusion, where the net effect of a condensate will be a trade-off between inhibitory and stimulatory effects. It is discussed which generalizable conclusions can be drawn so far and how close it is to design principles for condensates for enzyme cascades in microbial cell factories including which reactions are likely to be enhanced by condensates and which type of condensate will be suited for which reaction.

Versatility of vimentin assemblies: From filaments to biomolecular condensates and back

Cytoskeletal structures shape and confer resistance to cells. The intermediate filament protein vimentin forms versatile structures that play key roles in cytoskeletal crosstalk, in the integration of cellular responses to a variety of external and internal cues, and in the defense against stress. Such multifaceted roles can be fulfilled thanks to the vast variety of vimentin proteoforms, which in turn arise from the combinations of a myriad of tightly regulated posttranslational modifications. Diverse vimentin proteoforms will differentially shape its polymeric assemblies, underlying vimentin ability to organize in filaments, bundles, squiggles, droplets, cell surface-bound and/or various secreted forms. Interestingly, certain vimentin dots or droplets have been lately categorized as biomolecular condensates. Biomolecular condensates are phase-separated membraneless structures that are critical for the organization of cellular components and play important roles in pathophysiology. Recent findings have unveiled the importance of low complexity sequence domains in vimentin filament assembly. Moreover, several oxidants trigger the transition of vimentin filaments into phase-separated biomolecular condensates, a reversible process that may provide clues on the role of condensates as seeds for filament formation. Revisiting previous results in the light of recent knowledge prompts the hypothesis that vimentin condensates could play a role in traffic of filament precursors, cytoskeletal crosstalk and cellular responses to stress. Deciphering the "vimentin posttranslational modification code", that is, the structure-function relationships of vimentin proteoforms, constitutes a major challenge to understand the regulation of vimentin behavior and its multiple personalities. This will contribute to unveil essential cellular mechanisms and foster novel opportunities for drug discovery.

A conserved motif in Henipavirus P/V/W proteins drives the fibrillation of the W protein from Hendra virus

The Hendra (HeV) and Nipah (NiV) viruses are high-priority, biosafety level-4 pathogens that cause fatal neurological and respiratory disease. Their P gene encodes not only the P protein, an essential polymerase cofactor, but also the virulence factors V and W. We previously showed that the W protein of HeV (WHeV) forms amyloid-like fibrils and that one of its subdomains, PNT3, fibrillates in isolation. However, the fibrillation kinetics is much faster in the case of the full-length WHeV compared to PNT3, suggesting that another WHeV region contributes to the fibrillation process. In this work, we identified the region spanning residues 2-110 (PNT1) as the crucial region implicated in WHeV fibrillation. Through site-directed mutagenesis, combined with thioflavin T binding experiments and negative-staining transmission electron microscopy, we showed that a predicted cryptic amyloidogenic region (CAR) within PNT1 is the main driver of fibrillation and deciphered the underlying molecular mechanism. Using FTIR, we showed that PNT1 fibrils are enriched in cross β-sheets. Sequence alignment revealed conservation of the CAR across the Henipavirus genus and enabled the identification of a hitherto never reported pro-amyloidogenic motif. The ability to form fibrils was experimentally shown to be a common property shared by Henipavirus PNT1 proteins. Overall, this study sheds light on the molecular mechanisms underlying WHeV fibrillation and calls for future studies aimed at exploring the relevance of the newly identified pro-amyloidogenic motif as a valuable target for antiviral approaches.

The nonlinear cysteine redox dynamics in the i-space: A proteoform-centric theory of redox regulation

The post-translational redox regulation of protein function by cysteine oxidation controls diverse biological processes, from cell division to death. However, most current site-centric paradigms fail to capture the nonlinear and emergent nature of redox regulation in proteins with multiple cysteines. Here, we present a proteoform-centric theory of redox regulation grounded in the i-space. The i-space encapsulates the theoretical landscape of all possible cysteine proteoforms. Using computational approaches, we quantify the vast size of the abstract i-space, revealing its scale-free architecture-elucidating the disproportionate influence of cysteine-rich proteins. We define mathematical rules governing cysteine proteoform dynamics. Their dynamics are inherently nonlinear, context-dependent, and fundamentally constrained by protein copy numbers. Monte Carlo simulations of the human protein PTP1B reveal extensive i-space sampling beyond site-centric models, supporting the "oxiform conjecture". This conjecture posits that highly oxidised proteoforms, molecules bearing multiple oxidised cysteines, are central to redox regulation. In support, even 90%-reduced proteomes can house vast numbers of unique, potentially functioanlly diverse, oxiforms. This framework offers a transformative lens for understanding the redox biology of proteoforms.

Supramolecular Switching of Liquid-Liquid Phase Separation for Orchestrating Enzyme Kinetics

Dynamic liquid-liquid phase separation (LLPS) of intrinsically disordered proteins (IDPs) and associated assembly and disassembly of biomolecular condensates play crucial roles in cellular organization and metabolic networks. These processes are often regulated by supramolecular interactions. However, the complex and disordered structures of IDPs, coupled with their rapid conformational fluctuations, pose significant challenges for reconstructing supramolecularly-regulated dynamic LLPS systems and quantitatively illustrating variations in molecular interactions. Inspired by the structural feature of IDPs that facilitates LLPS, we designed a simplified phase-separating molecule, Nap-o-Nap, consisting of two naphthalene moieties linked by an ethylene glycol derivative. This compound exhibits LLPS under physiological conditions, forming coacervate microdroplets that undergo multiple cycles of disassembly and reassembly upon stoichiometric addition of Cucurbit[7]uril and Adamantane, respectively, based upon competitive host-guest interactions. Importantly, such reversible control offers a unique route to quantify entropically dominant nature (ΔS=14.0 cal ⋅ mol-1 ⋅ K-1) within the LLPS process, in which the binding affinity of host-guest interactions (ΔG=-14.9 kcal ⋅ mol-1) surpass that of the LLPS of Nap-o-Nap (ΔG=-2.1 kcal ⋅ mol-1), enabling the supramolecular regulation process. The supramolecularly switched LLPS, along with selective client recruitment and exclusion by resultant coacervates, provides a promising platform for either boosting or retarding enzymatic reactions, thereby orchestrating biological enzyme kinetics.

Sizes, conformational fluctuations, and SAXS profiles for intrinsically disordered proteins

The preponderance of intrinsically disordered proteins (IDPs) in the eukaryotic proteome, and their ability to interact with each other, and with folded proteins, RNA, and DNA for functional purposes, have made it important to quantitatively characterize their biophysical properties. Toward this end, we developed the transferable self-organized polymer (SOP-IDP) model to calculate the properties of several IDPs. The values of the radius of gyration (R g $$ {R}_g $$ ) obtained from SOP-IDP simulations are in excellent agreement (correlation coefficient of 0.96) with those estimated from SAXS experiments. For AP180 and Epsin, the predicted values of the hydrodynamic radii (R h s $$ {R}_h\mathrm{s} $$ ) are in nearly quantitative agreement with those from fluorescence correlation spectroscopy (FCS) experiments. Strikingly, the calculated SAXS profiles for 36 IDPs are also nearly superimposable on the experimental profiles. The dependence ofR g $$ {R}_g $$ and the mean end-to-end distance (R ee $$ {R}_{ee} $$ ) on chain length,N $$ N $$ , follows Flory's scaling law,R α ≈ a α N 0.588 $$ {R}_{\alpha}\approx {a}_{\alpha }{N}^{0.588} $$ (α = g , $$ \alpha =g, $$ ande $$ e $$ ), suggesting that globally IDPs behave as synthetic polymers in a good solvent. This finding depends on the solvent quality, which can be altered by changing variables such as pH and salt concentration. The values ofa g $$ {a}_g $$ anda e $$ {a}_e $$ are 0.20 and 0.48 nm, respectively. Surprisingly, finite size corrections to scaling, expected on theoretical grounds, are negligible forR g $$ {R}_g $$ andR ee $$ {R}_{ee} $$ . In contrast, only by accounting for the finite sizes of the IDPs, the dependence of experimentally measurableR h $$ {R}_h $$ onN $$ N $$ can be quantitatively explained usingν = 0.588 $$ \nu =0.588 $$ . Although Flory scaling law captures the estimates forR g $$ {R}_g $$ ,R ee $$ {R}_{ee} $$ , andR h $$ {R}_h $$ accurately, the spread of the simulated data around the theoretical curve is suggestive of of sequence-specific features that emerge through a fine-grained analysis of the conformational ensembles using hierarchical clustering. Typically, the ensemble of conformations partitions into three distinct clusters, having different equilibrium populations and structural properties. Without any further readjustments to the parameters of the SOP-IDP model, we also obtained nearly quantitative agreement with paramagnetic relaxation enhancement (PRE) measurements for α-synuclein. The transferable SOP-IDP model sets the stage for several applications, including the study of phase separation in IDPs and interactions with nucleic acids.

Current amyloid inhibitors: Therapeutic applications and nanomaterial-based innovations

Amyloid proteins have long been in the spotlight for being involved in many degenerative diseases including Alzheimer´s, Parkinson´s or type 2 diabetes, which currently cannot be prevented and for which there is no effective treatment or cure. Here we provide a comprehensive review of inhibitors that act directly on the amyloidogenic pathway (at the monomer, oligomer or fibril level) of key pathological amyloids, focusing on the most representative amyloid-related diseases. We discuss the latest advances in preclinical and clinical trials, focusing on cutting-edge developments, particularly on nanomaterials-based inhibitors, which offer unprecedented opportunities to address the complexity of protein misfolding disorders and are revolutionizing the landscape of anti-amyloid therapeutics. Notably, nanomaterials are impacting critical areas such as bioavailability, penetrability and functionality of compounds currently used in biomedicine, paving the way for more specific therapeutic solutions tailored to various amyloid-related diseases. Finally, we highlight the window of opportunity opened by comparative analysis with so-called functional amyloids for the development of innovative therapeutic approaches for these devastating diseases.

Hallmarks of aging in age-related macular degeneration and age-related neurological disorders: novel insights into common mechanisms and clinical relevance

Age-related macular degeneration (AMD) and age-related neurological diseases (ANDs), such as Alzheimer's and Parkinson's Diseases, are increasingly prevalent conditions that significantly contribute to global morbidity, disability, and mortality. The retina, as an accessible part of the central nervous system (CNS), provides a unique window to study brain aging and neurodegeneration. By examining the associations between AMD and ANDs, this review aims to highlight novel insights into fundamental mechanisms of aging and their role in neurodegenerative disease progression. This review integrates knowledge from the emerging field of aging research, which identifies common denominators of biological aging, specifically loss of proteostasis, impaired macroautophagy, mitochondrial dysfunction, and inflammation. Finally, we emphasize the clinical relevance of these pathways and the potential for cross-disease therapies that target common aging hallmarks. Identifying these shared pathways could open avenues to develop therapeutic strategies targeting mechanisms common to multiple degenerative diseases, potentially attenuating disease progression and promoting the healthspan.

The splicing auxiliary factor OsU2AF35a enhances thermotolerance via protein separation and promoting proper splicing of OsHSA32 pre-mRNA in rice

Heat stress significantly impacts global rice production, highlighting the critical need to understand the genetic basis of heat resistance in rice. U2AF (U2 snRNP auxiliary factor) is an essential splicing complex with critical roles in recognizing the 3'-splice site of precursor messenger RNAs (pre-mRNAs). The U2AF small subunit (U2AF35) can bind to the 3'-AG intron border and promote U2 snRNP binding to the branch-point sequences of introns through interaction with the U2AF large subunit (U2AF65). However, the functions of U2AF35 in plants are poorly understood. In this study, we discovered that the OsU2AF35a gene was vigorously induced by heat stress and could positively regulate rice thermotolerance during both the seedling and reproductive growth stages. OsU2AF35a interacts with OsU2AF65a within the nucleus, and both of them can form condensates through liquid-liquid phase separation (LLPS) following heat stress. The intrinsically disordered regions (IDR) are accountable for their LLPS. OsU2AF35a condensation is indispensable for thermotolerance. RNA-seq analysis disclosed that, subsequent to heat treatment, the expression levels of several genes associated with water deficiency and oxidative stress in osu2af35a-1 were markedly lower than those in ZH11. In accordance with this, OsU2AF35a is capable of positively regulating the oxidative stress resistance of rice. The pre-mRNAs of a considerable number of genes in the osu2af35a-1 mutant exhibited defective splicing, among which was the OsHSA32 gene. Knocking out OsHSA32 significantly reduced the thermotolerance of rice, while overexpressing OsHSA32 could partially rescue the heat sensitivity of osu2af35a-1. Together, our findings uncovered the essential role of OsU2AF35a in rice heat stress response through protein separation and regulating alternative pre-mRNA splicing.

Selective phase separation of transcription factors is driven by orthogonal molecular grammar

Protein production is critically dependent on gene transcription rates, which are regulated by RNA polymerase and a large collection of different transcription factors (TFs). How these transcription factors selectively address different genes is only partially known. Recent discoveries show that the differential condensation of separate TF families through phase separation may contribute to selectivity. Here we address this by conducting phase separation studies on six TFs from three different TF families with residue-scale coarse-grained molecular dynamics simulations. Our exploration of ternary TF phase diagrams reveals four dominant sticker motifs and two orthogonal driving forces that dictate the resultant condensate morphology, pointing to sequence-dependent orthogonal molecular grammar as a generic molecular mechanism that drives selective transcriptional condensation in gene expression.

TDP-43 seeding induces cytoplasmic aggregation heterogeneity and nuclear loss of function of TDP-43

Cytoplasmic aggregation and nuclear depletion of TAR DNA-binding protein 43 (TDP-43) are hallmarks of several neurodegenerative disorders. Yet, recapitulating both features in cellular systems has been challenging. Here, we produced amyloid-like fibrils from recombinant TDP-43 low-complexity domain and demonstrate that sonicated fibrils trigger TDP-43 pathology in human cells, including induced pluripotent stem cell (iPSC)-derived neurons. Fibril-induced cytoplasmic TDP-43 inclusions acquire distinct biophysical properties, recapitulate pathological hallmarks such as phosphorylation, ubiquitin, and p62 accumulation, and recruit nuclear endogenous TDP-43, leading to its loss of function. A transcriptomic signature linked to both aggregation and nuclear loss of TDP-43, including disease-specific cryptic splicing, is identified. Cytoplasmic TDP-43 aggregates exhibit time-dependent heterogeneous morphologies as observed in patients-including compacted, filamentous, or fragmented-which involve upregulation/recruitment of protein clearance pathways. Ultimately, cell-specific progressive toxicity is provoked by seeded TDP-43 pathology in human neurons. These findings identify TDP-43-templated aggregation as a key mechanism driving both cytoplasmic gain of function and nuclear loss of function, offering a valuable approach to identify modifiers of sporadic TDP-43 proteinopathies.

Synthesis and Characterization of Phase-Separated Extracellular Condensates in Interactions with Cells

Biomolecular condensates formed through liquid-liquid phase separation play key roles in intracellular organization and signaling, yet their function in extracellular environments remains largely unexplored. Here, we establish a model using heparan sulfate, a key component of the extracellular matrix, to study extracellular condensate-cell interactions. We demonstrate that heparan sulfate can form condensates with a positively charged counterpart in serum-containing solutions, mimicking the complexity of extracellular fluid, and supporting cell viability. We observe that these condensates adhere to cell membranes and remain stable, enabling a versatile platform for examining extracellular condensate dynamics and quantifying their rheological properties as well as their adhesion forces with cellular surfaces. Our findings and methodology open new avenues for understanding the organizational roles of condensates beyond cellular boundaries.

Decoupling Phase Separation and Fibrillization Preserves Activity of Biomolecular Condensates

Age-dependent transition of metastable, liquid-like protein condensates to amyloid fibrils is an emergent phenomenon of numerous neurodegeneration-linked protein systems. A key question is whether the thermodynamic forces underlying reversible phase separation and maturation to irreversible amyloids are distinct and separable. Here, we address this question using an engineered version of the microtubule-associated protein Tau, which forms biochemically active condensates. Liquid-like Tau condensates exhibit rapid aging to amyloid fibrils under quiescent, cofactor-free conditions. Tau condensate interface promotes fibril nucleation, impairing their activity to recruit tubulin and catalyze microtubule assembly. Remarkably, a small molecule metabolite, L-arginine, selectively impedes condensate-to-fibril transition without perturbing phase separation in a valence and chemistry-specific manner. By heightening the fibril nucleation barrier, L-arginine counteracts age-dependent decline in the biochemical activity of Tau condensates. These results provide a proof-of-principle demonstration that small molecule metabolites can enhance the metastability of protein condensates against a liquid-to-amyloid transition, thereby preserving condensate function.

Zinc ions trigger the prion protein liquid-liquid phase separation

Prion diseases are characterized by the misfolding and conversion of the monomeric prion protein (PrP) to a multimeric aggregated pathogenic form, known as PrPSc. We and others have recently shown that biomolecular condensates formed via liquid-liquid phase separation of PrP can undergo maturation to solid-like species that resemble pathological aggregates, and this process is modulated by DNA, RNA, and oxidative conditions. Conversely, the most well-studied ligand of PrP, copper ions, induce liquid-like condensates of PrP that accumulate Cu2+in vitro, and live PrPC-expressing cells show condensation at the cell surface as triggered by physiologically relevant conditions of Cu2+ and protein concentrations. Since PrP can also bind to Zn2+ through its intrinsically disordered N-terminal domain, though with different affinities and binding modes than Cu2+, we hypothesized that Zn2+ could modulate PrP phase separation differently from copper ions. Using an appropriate buffer with negligible metal ion binding, as well as relevant pH, ionic strength, molecular crowding, and Zn2+ concentrations, we show that recombinant PrP undergoes phase separation with Zn2+. Furthermore, we show that metal ion-induced condensation of PrP is dependent on the N-terminal domain (residues 23-90). In vitro Fluorescence Recovery After Photobleaching (FRAP) experiments and thioflavin T aggregation kinetics support key differences in the molecular properties of PrP:Zn2+versus PrP:Cu2+ phase separated states. FRAP analysis indicated that both Cu2+ and Zn2+ promote liquid-like PrP condensates; however, PrP:Zn2+condensates exhibit a faster recovery. Cu2+ pronouncedly inhibits seed-induced PrP misfolding, whereas Zn2+ provides a milder delay in PrP aggregation. Our findings provide insights on Zn2+-induced phase separation of PrP, supporting a variety of previously proposed functions of PrP in metal sequestering and uptake, processes that could be effectively regulated through biomolecular condensation.

Multiphasic condensates formed with mono-component of tetrapeptides via phase separation

Biomolecular condensates, formed by liquid-liquid phase separation of biomacromolecules, play crucial roles in regulating physiological events in biological systems. While multiphasic condensates have been extensively studied, those derived from a single component of short peptides have not yet been reported. Here, we report the symmetrical core-shell structural biomolecular condensates formed with a programmable tetrapeptide library via phase separation. Our findings reveal that tryptophan is essential for core-shell structure formation due to its strongest homotypical π-π interaction, enabling us to modulate the structure of condensates from core-shell to homogeneous by altering the amino acid composition. Molecular dynamics simulation combined with cryogenic focused ion beam scanning electron microscopy and cryogenic electron microscopy show that the inner core of multiphasic tetrapeptide condensates is solid-like, consisting of ordered structures. The core is enveloped by a liquid-like shell, stabilizing the core structure. Furthermore, we demonstrate control over multiphasic condensate formation through intrinsic redox reactions or post-translational modifications, facilitating the rational design of synthetic multiphasic condensates for various applications on demand.

Crosstalk Between Phase-Separated Membraneless Condensates and Membrane-Bound Organelles in Cellular Function and Disease

Compartmentalization in eukaryotic cells allows the spatiotemporal regulation of biochemical processes, in addition to allowing specific sets of proteins to interact in a regulated as well as stochastic manner. Although membrane-bound organelles are thought to be the key players of cellular compartmentalization, membraneless biomolecular condensates such as stress granules, P bodies, and many others have recently emerged as key players that are also thought to bring order to a highly chaotic environment. Here, we have evaluated the latest studies on biomolecular condensates, specifically focusing on how they interact with membrane-bound organelles and modulate each other's functions. We also highlight the importance of this interaction in neurodegenerative and cardiovascular diseases as well as in cancer.

Nuclear and genome dynamics underlying DNA double-strand break repair

Changes in nuclear shape and in the spatial organization of chromosomes in the nucleus commonly occur in cancer, ageing and other clinical contexts that are characterized by increased DNA damage. However, the relationship between nuclear architecture, genome organization, chromosome stability and health remains poorly defined. Studies exploring the connections between the positioning and mobility of damaged DNA relative to various nuclear structures and genomic loci have revealed nuclear and cytoplasmic processes that affect chromosome stability. In this Review, we discuss the dynamic mechanisms that regulate nuclear and genome organization to promote DNA double-strand break (DSB) repair, genome stability and cell survival. Genome dynamics that support DSB repair rely on chromatin states, repair-protein condensates, nuclear or cytoplasmic microtubules and actin filaments, kinesin or myosin motor proteins, the nuclear envelope, various nuclear compartments, chromosome topology, chromatin loop extrusion and diverse signalling cues. These processes are commonly altered in cancer and during natural or premature ageing. Indeed, the reshaping of the genome in nuclear space during DSB repair points to new avenues for therapeutic interventions that may take advantage of new cancer cell vulnerabilities or aim to reverse age-associated defects.

A globular protein exhibits rare phase behavior and forms chemically regulated orthogonal condensates in cells

Proteins with chemically regulatable phase separation are of great interest in the fields of biomolecular condensates and synthetic biology. Intrinsically disordered proteins (IDPs) are the dominating building blocks of biomolecular condensates which often lack orthogonality and small-molecule regulation desired to create synthetic biomolecular condensates or membraneless organelles (MLOs). Here, we discover a well-folded globular protein, lipoate-protein ligase A (LplA) from E. coli involved in lipoylation of enzymes essential for one-carbon and energy metabolisms, that exhibits structural homomeric oligomerization and a rare LCST-type reversible phase separation in vitro. In both E. coli and human U2OS cells, LplA can form orthogonal condensates, which can be specifically dissolved by its natural substrate, the small molecule lipoic acid and its analogue lipoamide. The study of LplA phase behavior and its regulatability expands our understanding and toolkit of small-molecule regulatable protein phase behavior with impacts on biomedicine and synthetic biology.

Light-induced programmable solid-liquid phase transition of biomolecular condensates for improved biosynthesis

Keeping condensates in liquid-like states throughout the biosynthesis process in microbial cell factories remains an ongoing challenge. Here, we present a light-controlled phase regulator, which maintains the liquid-like features of synthetic condensates on demand throughout the biosynthesis process upon light induction, as demonstrated by various live cell-imaging techniques. Specifically, the tobacco etch virus (TEV) protease controlled by light cleaves intrinsically disordered proteins (IDPs) to alter their valency and concentration for controlled phase transition and programmable fluidity of cellular condensates. As a proof of concept, we harness this capability to significantly improve the production of squalene and ursolic acid (UA) in engineered Saccharomyces cerevisiae. Our work provides a powerful approach to program the solid-liquid phase transition of biomolecular condensates for improved biosynthesis.

Aging-dependent evolving electrochemical potentials of biomolecular condensates regulate their physicochemical activities

A passive consequence of macromolecular condensation is the establishment of an ion concentration gradient between the dilute and dense phases, which in turn governs distinct electrochemical properties of condensates. However, the mechanisms that regulate the electrochemical equilibrium of condensates and their impacts on emergent physicochemical functions remain unknown. Here we demonstrate that the electrochemical environments and the physical and chemical activities of biomolecular condensates, dependent on the electrochemical potential of condensates, are regulated by aging-associated intermolecular interactions and interfacial effects. Our findings reveal that enhanced dense-phase interactions during condensate maturation continuously modulate the ion distribution between the two phases. Moreover, modulating the interfacial regions of condensates can affect the apparent pH within the condensates. To directly probe the interphase and interfacial electric potentials of condensates, we have designed and implemented electrochemical potentiometry and second harmonic generation-based approaches. Our results suggest that the non-equilibrium nature of biomolecular condensates might play a crucial role in modulating the electrochemical activities of living systems.

Protein codes promote selective subcellular compartmentalization

Cells have evolved mechanisms to distribute ~10 billion protein molecules to subcellular compartments where diverse proteins involved in shared functions must assemble. In this study, we demonstrate that proteins with shared functions share amino acid sequence codes that guide them to compartment destinations. We developed a protein language model, ProtGPS, that predicts with high performance the compartment localization of human proteins excluded from the training set. ProtGPS successfully guided generation of novel protein sequences that selectively assemble in the nucleolus. ProtGPS identified pathological mutations that change this code and lead to altered subcellular localization of proteins. Our results indicate that protein sequences contain not only a folding code but also a previously unrecognized code governing their distribution to diverse subcellular compartments.

Peptide-mediated liquid-liquid phase separation and biomolecular condensates

Liquid-liquid phase separation (LLPS) is a cornerstone of cellular organization, driving the formation of biomolecular condensates that regulate diverse biological processes and inspire innovative applications. This review explores the molecular mechanisms underlying peptide-mediated LLPS, emphasizing the roles of intermolecular interactions such as hydrophobic effects, electrostatic interactions, and π-π stacking in phase separation. The influence of environmental factors, such as pH, temperature, ionic strength, and molecular crowding on the stability and dynamics of peptide coacervates is examined, highlighting their tunable properties. Additionally, the unique physicochemical properties of peptide coacervates, including their viscoelastic behavior, interfacial dynamics, and stimuli-responsiveness, are discussed in the context of their biological relevance and engineering potential. Peptide coacervates are emerging as versatile platforms in biotechnology and medicine, particularly in drug delivery, tissue engineering, and synthetic biology. By integrating fundamental insights with practical applications, this review underscores the potential of peptide-mediated LLPS as a transformative tool for advancing science and healthcare.

Granular component sub-phases direct ribosome biogenesis in the nucleolus

The hierarchical, multiphase organization of the nucleolus underlies ribosome biogenesis. Ribonucleoprotein particles that regulate ribosomal subunit assembly are heterogeneously disposed in the granular component (GC) of the nucleolus. However, the molecular origins of the GC's spatial heterogeneity and its association with ribosomal subunit assembly remain poorly understood. Here, using super-resolution microscopy, we uncover that key GC biomolecules, including nucleophosmin (NPM1), surfeit locus protein 6 (SURF6), and ribosomal RNA (rRNA), are heterogeneously localized within sub-phases in the GC. In vitro reconstitution showed that these GC biomolecules form multiphase condensates with SURF6/rRNA-rich core and NPM1-rich shell, providing a mechanistic basis for GC's spatial heterogeneity. SURF6's association with rRNA is weakened upon ribosome subunit assembly, enabling NPM1 to extract assembled subunits from condensates-suggesting an assembly-line-like mechanism of subunit efflux from the GC. Our results establish a framework for understanding the heterogeneous structure of the GC and reveal how its distinct sub-phases facilitate ribosome subunit assembly.

Proteasome dynamics in response to metabolic changes

Proteasomes, essential protease complexes in protein homeostasis, adapt to metabolic changes through intracellular movements. As the executive arm of the ubiquitin-proteasome system, they selectively degrade poly-ubiquitinated proteins in an ATP-dependent process. The primary proteasome configuration involved in this degradation is the 26S proteasome, which is composed of a proteolytically active core particle flanked by two regulatory particles. In metabolically active cells, such as proliferating yeast and mammalian cancer cells, 26S proteasomes are predominantly nuclear and actively engaged in protein degradation. However, during nutrient deprivation or stress-induced quiescence, proteasome localization changes. In quiescent yeast, proteasomes initially accumulate at the nuclear envelope. During prolonged quiescence with decreased ATP levels, proteasomes exit the nucleus and are sequestered into cytoplasmic membraneless organelles, so-called proteasome storage granules (PSGs). In mammalian cells, starvation and stress trigger formation of membraneless organelles containing proteasomes and poly-ubiquitinated substrates. The proteasome condensates are motile, reversible, and contribute to stress resistance and improved fitness during aging. Proteasome condensation may involve liquid-liquid phase separation, a mechanism underlying the assembly of membraneless organelles.

Tubulin transforms Tau and α-synuclein condensates from pathological to physiological

Proteins phase-separate to form condensates that partition and concentrate biomolecules into membraneless compartments. These condensates can exhibit dichotomous behaviors in biology by supporting cellular physiology or instigating pathological protein aggregation 1-3 . Tau and α- synuclein (αSyn) are neuronal proteins that form heterotypic (Tau:αSyn) condensates associated with both physiological and pathological processes. Tau and αSyn functionally regulate microtubules 8-12 , but are also known to misfold and co-deposit in aggregates linked to various neurodegenerative diseases 4,5,6,7 , which highlights the paradoxically ambivalent effect of Tau:αSyn condensation in health and disease. Here, we show that tubulin modulates Tau:αSyn condensates by promoting microtubule interactions, competitively inhibiting the formation of homotypic and heterotypic pathological oligomers. In the absence of tubulin, Tau-driven protein condensation accelerates the formation of toxic Tau:αSyn heterodimers and amyloid fibrils. However, tubulin partitioning into Tau:αSyn condensates modulates protein interactions, promotes microtubule polymerization, and prevents Tau and αSyn oligomerization and aggregation. We distinguished distinct Tau and αSyn structural states adopted in tubulin-absent (pathological) and tubulin-rich (physiological) condensates, correlating compact conformations with aggregation and extended conformations with function. Furthermore, using various neuronal cell models, we showed that loss of stable microtubules, which occurs in Alzheimer's disease and Parkinsons disease patients 13,14 , results in pathological oligomer formation and loss of neurites, and that functional condensation using an inducible optogenetic Tau construct resulted in microtubule stablization. Our results identify that tubulin is a critical modulator in switching Tau:αSyn pathological condensates to physiological, mechanistically relating the loss of stable microtubules with disease progression. Tubulin restoration strategies and Tau-mediated microtubule stabilization can be potential therapies targeting both Tau-specific and Tau/αSyn mixed pathologies.

Chaperone-Mediated Heterotypic Phase Separation Prevents the Amyloid Formation of the Pathological Y145Stop Prion Protein Variant

Biomolecular condensates formed via phase separation of proteins and nucleic acids are crucial for the spatiotemporal regulation of a diverse array of essential cellular functions and the maintenance of cellular homeostasis. However, aberrant liquid-to-solid phase transitions of such condensates are associated with several fatal human diseases. Such dynamic membraneless compartments can contain a range of molecular chaperones that can regulate the phase behavior of proteins involved in the formation of these biological condensates. Here, we show that a heat shock protein 40 (Hsp40), Ydj1, exhibits a holdase activity by potentiating the phase separation of a disease-associated stop codon mutant of the prion protein (Y145Stop) either by recruitment into Y145Stop condensates or via Y145Stop-Ydj1 two-component heterotypic phase separation that arrests the conformational conversion of Y145Stop into amyloid fibrils. Utilizing site-directed mutagenesis, multicolor fluorescence imaging, single-droplet steady-state and picosecond time-resolved fluorescence anisotropy, fluorescence recovery after photobleaching, and fluorescence correlation spectroscopy, we delineate the complex network of interactions that govern the heterotypic phase separation of Y145Stop and Ydj1. We also show that the properties of such heterotypic condensates can further be tuned by RNA that promotes the formation of multicomponent multiphasic protein-RNA condensates. Our vibrational Raman spectroscopy results in conjunction with atomic force microscopy imaging reveal that Ydj1 effectively redirects the self-assembly of Y145Stop towards a dynamically-arrested non-amyloidogenic pathway, preventing the formation of typical amyloid fibrils. Our findings underscore the importance of chaperone-mediated heterotypic phase separation in regulating aberrant phase transitions and amyloid formation associated with a wide range of deadly neurodegenerative diseases.

The Hippo pathway: Organ size control and beyond

The Hippo signaling pathway is a highly conserved signaling network for controlling organ size, tissue homeostasis, and regeneration. It integrates a wide range of intracellular and extracellular signals, such as cellular energy status, cell density, hormonal signals, and mechanical cues, to modulate the activity of YAP/TAZ transcriptional coactivators. A key aspect of Hippo pathway regulation involves its spatial organization at the plasma membrane, where upstream regulators localize to specific membrane subdomains to regulate the assembly and activation of the pathway components. This spatial organization is critical for the precise control of Hippo signaling, as it dictates the dynamic interactions between pathway components and their regulators. Recent studies have also uncovered the role of biomolecular condensation in regulating Hippo signaling, adding complexity to its control mechanisms. Dysregulation of the Hippo pathway is implicated in various pathological conditions, particularly cancer, where alterations in YAP/TAZ activity contribute to tumorigenesis and drug resistance. Therapeutic strategies targeting the Hippo pathway have shown promise in both cancer treatment, by inhibiting YAP/TAZ signaling, and regenerative medicine, by enhancing YAP/TAZ activity to promote tissue repair. The development of small molecule inhibitors targeting the YAP-TEAD interaction and other upstream regulators offers new avenues for therapeutic intervention. SIGNIFICANCE STATEMENT: The Hippo signaling pathway is a key regulator of organ size, tissue homeostasis, and regeneration, with its dysregulation linked to diseases such as cancer. Understanding this pathway opens new possibilities for therapeutic approaches in regenerative medicine and oncology, with the potential to translate basic research into improved clinical outcomes.

Dysregulated ribosome quality control in human diseases

Precise regulation of mRNA translation is of fundamental importance for maintaining homeostasis. Conversely, dysregulated general or transcript-specific translation, as well as abnormal translation events, have been linked to a multitude of diseases. However, driven by the misconception that the transient nature of mRNAs renders their abnormalities inconsequential, the importance of mechanisms that monitor the quality and fidelity of the translation process has been largely overlooked. In recent years, there has been a dramatic shift in this paradigm, evidenced by several seminal discoveries on the role of a key mechanism in monitoring the quality of mRNA translation - namely, Ribosome Quality Control (RQC) - in the maintenance of homeostasis and the prevention of diseases. Here, we will review recent advances in the field and emphasize the biological significance of the RQC mechanism, particularly its implications in human diseases.

The mechanobiology of biomolecular condensates

The central goal of mechanobiology is to understand how the mechanical forces and material properties of organelles, cells, and tissues influence biological processes and functions. Since the first description of biomolecular condensates, it was hypothesized that they obtain material properties that are tuned to their functions inside cells. Thus, they represent an intriguing playground for mechanobiology. The idea that biomolecular condensates exhibit diverse and adaptive material properties highlights the need to understand how different material states respond to external forces and whether these responses are linked to their physiological roles within the cell. For example, liquids buffer and dissipate, while solids store and transmit mechanical stress, and the relaxation time of a viscoelastic material can act as a mechanical frequency filter. Hence, a liquid-solid transition of a condensate in the force transmission pathway can determine how mechanical signals are transduced within and in-between cells, affecting differentiation, neuronal network dynamics, and behavior to external stimuli. Here, we first review our current understanding of the molecular drivers and how rigidity phase transitions are set forth in the complex cellular environment. We will then summarize the technical advancements that were necessary to obtain insights into the rich and fascinating mechanobiology of condensates, and finally, we will highlight recent examples of physiological liquid-solid transitions and their connection to specific cellular functions. Our goal is to provide a comprehensive summary of the field on how cells harness and regulate condensate mechanics to achieve specific functions.

Kat7 accelerates osteoarthritis disease progression through the TLR4/NF-κB signaling pathway

Osteoarthritis (OA) is a common degenerative bone and joint disease with an unclear pathogenesis. Our study identified that the histone acetyltransferase encoded by Kat7 is upregulated in the affected articular cartilage of OA patients and in a mice model of medial meniscal instability-induced OA. Chondrocyte-specific knockdown of Kat7 expression exhibited a protective effect on articular cartilage integrity. In vitro experiments demonstrated that KAT7 promotes cartilage catabolism, inhibits cartilage anabolism, and induces chondrocyte senescence and apoptosis. Conversely, knocking down Kat7 was shown to protect chondrocyte function. Corresponding in vivo results indicated that silencing Kat7 effectively enhances cartilage anabolism, prevents articular cartilage damage, and significantly slows OA progression. Mechanistically, KAT7 activates the TLR4/NF-κB signaling pathway, and inhibition of this pathway reverses the catabolic effects and restores anabolic activity in the presence of Kat7 overexpression. Collectively, these findings confirm the critical role of KAT7 in the pathogenesis of OA and suggest that Kat7 represents a potential therapeutic target for OA treatment. KEY MESSAGES: There is a lack of clinically effective drugs for the treatment of osteoarthritis (OA). Kat7 plays a key role in the development of OA. Knocking down Kat7 expression can alleviate the progression of OA. Kat7 accelerates the progression of OA by activating the TLR4/NF-KB signaling pathway.

PARPs and ADP-ribosylation-mediated biomolecular condensates: determinants, dynamics, and disease implications

Biomolecular condensates are cellular compartments that selectively enrich proteins and other macromolecules despite lacking enveloping membranes. These compartments often form through phase separation triggered by multivalent nucleic acids. Emerging data have revealed that poly(ADP-ribose) (PAR), a nucleic acid-based protein modification catalyzed by ADP-ribosyltransferases (commonly known as PARPs), plays a crucial role in this process. This review focuses on the role of PARPs and ADP-ribosylation, and explores the principles and mechanisms by which PAR regulates condensate formation, dissolution, and dynamics. Future studies with advanced tools to examine PAR binding sites, substrate interactions, PAR length and structure, and transitions from condensates to aggregates will be key to unraveling the complexity of ADP-ribosylation in health and disease, including cancer, viral infection, and neurodegeneration.

Significant roles in RNA-binding for the amino-terminal regions of Drosophila Pumilio and Nanos

The Drosophila Pumilio (Pum) and Nanos (Nos) RNA-binding proteins govern abdominal segmentation in the early embryo, as well as a variety of other events during development. They bind together to a compound Nanos Response Element (NRE) present in thousands of maternal mRNAs in the ovary and embryo, including hunchback (hb) mRNA, thereby regulating poly-adenylation, translation, and stability. Many studies support a model in which mRNA recognition and effector recruitment are carried out by distinct regions of each protein. The well-ordered Pum and Nos RNA-binding domains (RBDs) are sufficient to specifically recognize NREs; the larger intrinsically disordered N-terminal regions (NTRs) of each protein have been thought to act by recruiting mRNA regulators. Here we use yeast interaction assays and experiments testing the regulation of hb mRNA in vivo to show that the NTRs play a significant role in recognition of the NRE, acting via two mechanisms. First, the Pum and Nos NTRs interact in trans to promote assembly of the Pum/Nos/NRE ternary complex. Second, the Pum NTR acts via an unknown mechanism in cis, modifying NRE recognition by its RBD. The ability of the NTR to alter binding to the NRE is conserved in human Pum2.

Polyphosphate: The "Dark Matter" of Bacterial Chromatin Structure

Polyphosphate (polyP), broadly defined, consists of a chain of orthophosphate units connected by phosphoanhydride bonds. PolyP is the only universal inorganic biopolymer known to date and is present in all three domains of life. At a first approximation polyP appears to be a simple, featureless, and flexible polyanion. A growing body of evidence suggests that polyP is not as featureless as originally thought: it can form a wide variety of complexes and condensates through association with proteins, nucleic acids, and inorganic ions. It is becoming apparent that the emergent properties of the condensate superstructures it forms are both complex and dynamic. Importantly, growing evidence suggests that polyP can affect bacterial chromatin, both directly and by mediating interactions between DNA and proteins. In an increasing number of contexts, it is becoming apparent that polyP profoundly impacts both chromosomal structure and gene regulation in bacteria, thus serving as a rarely considered, but highly important, component in bacterial nucleoid biology.

Rational design of phytovirucide inhibiting nucleocapsid protein aggregation in tomato spotted wilt virus

Ineffectiveness of managing plant viruses by chemicals has posed serious challenges in crop production. Recently, phase separation has shown to play a key role in viral lifecycle. Using inhibitors that can disturb biomolecular condensates formed by phase separation for virus control has been reported in medical field. However, the applicability of this promising antiviral tactic for plant protection has not been explored. Here, we report an inhibitor, Z9, that targets the tomato spotted wilt virus (TSWV) N protein. Z9 is capable of interacting with the amino acids in the nucleic acid binding region of TSWV N, disrupting the assembly of N and RNA into phase-separated condensates, the reduction of which is detrimental to the stability of the N protein. This study provides a strategy for phase separation-based plant virus control.

Multi-omics analysis identifies a liquid-liquid phase separation-related subtypes in head and neck squamous cell carcinoma

Background

Growing evidence indicates that abnormal liquid-liquid phase separation (LLPS) can disrupt biomolecular condensates, contributing to cancer development and progression. However, the influence of LLPS on the prognosis of head and neck squamous cell carcinoma (HNSCC) patients and its effects on the tumor immune microenvironment (TIME) are not yet fully understood. Therefore, we aimed to categorize patients with HNSCC based on LLPS-related genes and explored their multidimensional heterogeneity.

Methods

We integrated the transcriptomic data of 3,541 LLPS-related genes to assess the LLPS patterns in 501 patients with HNSCC within The Cancer Genome Atlas cohort. Subsequently, we explored the differences among the three LLPS subtypes using multi-omics analysis. We also developed an LLPS-related prognostic risk signature (LPRS) to facilitate personalized and integrative assessments and then screened and validated potential therapeutic small molecule compounds targeting HNSCC via experimental analyses.

Result

By analyzing the expression profiles of 85 scaffolds, 355 regulators, and 3,101 clients of LLPS in HNSCC, we identified three distinct LLPS subtypes: LS1, LS2, and LS3. We confirmed notable differences among these subtypes in terms of prognosis, functional enrichment, genomic alterations, TIME patterns, and responses to immunotherapy. Additionally, we developed the LPRS, a prognostic signature for personalized integrative assessments, which demonstrated strong predictive capability for HNSCC prognosis across multiple cohorts. The LPRS also showed significant correlations with the clinicopathological features and TIME patterns in HNSCC patients. Furthermore, the LPRS effectively predicted responses to immune checkpoint inhibitor therapy and facilitated the screening of potential small-molecule compounds for treating HNSCC patients.

Conclusion

This study presents a new classification system for HNSCC patients grounded in LLPS. The LPRS developed in this research offers improved personalized prognosis and could optimize immunotherapy strategies for HNSCC.

Liquid condensates: a new barrier to loop extrusion?

Liquid-liquid phase separation (LLPS), driven by dynamic, low-affinity multivalent interactions of proteins and RNA, results in the formation of macromolecular condensates on chromatin. These structures are likely to provide high local concentrations of effector factors responsible for various processes including transcriptional regulation and DNA repair. In particular, enhancers, super-enhancers, and promoters serve as platforms for condensate assembly. In the current paradigm, enhancer-promoter (EP) interaction could be interpreted as a result of enhancer- and promoter-based condensate contact/fusion. There is increasing evidence that the spatial juxtaposition of enhancers and promoters could be provided by loop extrusion (LE) by SMC complexes. Here, we propose that condensates may act as barriers to LE, thereby contributing to various nuclear processes including spatial contacts between regulatory genomic elements.

A biophysical basis for the spreading behavior and limited diffusion of Xist

Xist RNA initiates X inactivation as it spreads in cis across the chromosome. Here, we reveal a biophysical basis for its cis-limited diffusion. Xist RNA and HNRNPK together drive a liquid-liquid phase separation (LLPS) that encapsulates the chromosome. HNRNPK droplets pull on Xist and internalize the RNA. Once internalized, Xist induces a further phase transition and "softens" the HNRNPK droplet. Xist alters the condensate's deformability, adhesiveness, and wetting properties in vitro. Other Xist-interacting proteins are internalized and entrapped within the droplet, resulting in a concentration of Xist and protein partners within the condensate. We attribute LLPS to HNRNPK's RGG and Xist's repeat B (RepB) motifs. Mutating these motifs causes Xist diffusion, disrupts polycomb recruitment, and precludes the required mixing of chromosomal compartments for Xist's migration. Thus, we hypothesize that phase transitions in HNRNPK condensates allow Xist to locally concentrate silencing factors and to spread through internal channels of the HNRNPK-encapsulated chromosome.

Phase-Separated Spiropyran Coacervates as Dual-Wavelength-Switchable Reactive Oxygen Generators

Low-molecular-weight compounds of certain structural features may form coacervates through liquid-liquid phase separation (LLPS). These coacervates can enter mammalian cells and affect cellular physiology. Controlling the properties of the coacervates inside cells, however, is a challenge. Here, we report photochemical reactions of spiropyran (SP)-based coacervates with two wavelengths of light, in vitro, in the cell, and in animals, generating reactive oxygen species (ROS) for photo-controlled cell killing. We identify an SP-containing compound, SP-PEG8-SP, that forms coacervates (SP-C) in the aqueous solution. Photo illumination by a UV light triggers the isomerization of SP to merocyanine (MC), switching SP-C to the fluorescent coacervates MC-C. A visible light converts MC-C back to SP-C and induces ROS generation. Notably, coacervate formation increases the compound's ROS generation efficiency. The SP-C/MC-C coacervate system (collectively called spiropyran coacervates) can spontaneously enter cells, and a dual-wavelength-controlled reversible on/off switch and spatiotemporal-resolved ROS production is realized within the cytoplasm. Light-induced ROS generation leads to cytotoxicity to cancer cells, tumor organoids, and tumors in vivo, supporting spiropyran coacervates' potential use as coacervate photosensitizers in photodynamic therapies.

Nonstop mutations cause loss of renal tumor suppressor proteins VHL and BAP1 and affect multiple stages of protein translation

Nonstop extension or stop-loss mutations lead to the extension of a protein at its carboxyl terminus. Recently, nonstop mutations in the tumor suppressor SMAD Family Member 4 (SMAD4) have been discovered to lead to proteasomal SMAD4 degradation. However, this mutation type has not been studied in other cancer genes. Here, we explore somatic nonstop mutations in the tumor suppressor genes BRCA1 Associated Protein 1 (BAP1) and Von Hippel-Lindau (VHL) enriched in renal cell carcinoma. For BAP1, nonstop mutations generate an extremely long extension. Instead of proteasomal degradation, the extension decreases translation and depletes BAP1 messenger RNA from heavy polysomes. For VHL, the short extension leads to proteasomal degradation. Unexpectedly, the mutation alters the selection of the translational start site shifting VHL isoforms. We identify germline VHL nonstop mutations in patients leading to the early onset of severe disease manifestations. In summary, nonstop extension mutations inhibit the expression of renal tumor suppressor genes with pleiotropic effects on translation and protein stability.

Phosphorylation of CRYAB induces a condensatopathy to worsen post-myocardial infarction left ventricular remodeling

Protein aggregates are emerging therapeutic targets in rare monogenic causes of cardiomyopathy and amyloid heart disease, but their role in more prevalent heart-failure syndromes remains mechanistically unexamined. We observed mislocalization of desmin and sarcomeric proteins to aggregates in human myocardium with ischemic cardiomyopathy and in mouse hearts with post-myocardial infarction ventricular remodeling, mimicking findings of autosomal-dominant cardiomyopathy induced by the R120G mutation in the cognate chaperone protein CRYAB. In both syndromes, we demonstrate increased partitioning of CRYAB phosphorylated on serine 59 to NP40-insoluble aggregate-rich biochemical fraction. While CRYAB undergoes phase separation to form condensates, the phosphomimetic mutation of serine 59 to aspartate (S59D) in CRYAB mimics R120G-CRYAB mutants with reduced condensate fluidity, formation of protein aggregates, and increased cell death. Conversely, changing serine to alanine (phosphorylation-deficient mutation) at position 59 (S59A) restored condensate fluidity and reduced both R120G-CRYAB aggregates and cell death. In mice, S59D CRYAB knockin was sufficient to induce desmin mislocalization and myocardial protein aggregates, while S59A CRYAB knockin rescued left ventricular systolic dysfunction after myocardial infarction and preserved desmin localization with reduced myocardial protein aggregates. 25-Hydroxycholesterol attenuated CRYAB serine 59 phosphorylation and rescued post-myocardial infarction adverse remodeling. Thus, targeting CRYAB phosphorylation-induced condensatopathy is an attractive strategy to counter ischemic cardiomyopathy.

A Single Amino Acid Model for Hydrophobically Driven Liquid-Liquid Phase Separation

This study proposes fluorenylmethoxycarbonyl (Fmoc)-protected single amino acids (Fmoc-AAs) as a minimalistic model system to investigate liquid-liquid phase separation (LLPS) and the elusive liquid-to-solid transition of condensates. We demonstrated that Fmoc-AAs exhibit LLPS depending on the pH and ionic strength, primarily driven by hydrophobic interactions. Systematic examination of the conditions under which each Fmoc-AA undergoes LLPS revealed distinct residue-dependent trends in the critical concentrations and phase behavior. Importantly, we elucidated the liquid-to-solid transition process, suggesting that it may be driven by a molecular mechanism different from that of LLPS. Fmoc-AA condensates showed promise for biomolecular enrichment and catalytic applications. This work provides significant insights into the molecular mechanisms of LLPS and the subsequent liquid-to-solid transition, offering a robust platform for future studies related to protocells and protein aggregation diseases.

Nucleotide-specific RNA conformations and dynamics within ribonucleoprotein condensates

Ribonucleoprotein (RNP) condensates have distinct physiological and pathological significance, but the structure of RNA within them is not well understood. Using contrast-variation solution X-ray scattering, which discerns only the RNA structures within protein-RNA complexes, alongside ensemble-based structural modeling we characterize the conformational changes of flexible poly-A, poly-U and poly-C single stranded RNA as it interacts with polybasic peptides, eventually forming condensed coacervate mixtures. At high salt concentrations, where macromolecular association is weak, we probe association events that precede the formation of liquid-like droplets. Structural changes occur in RNA that reflect charge screening by the peptides as well as π - π interactions of the bases with basic residues. At lower salt concentrations, where association is enhanced, poly-A RNA within phase separated RNP mixtures exhibit a broad scattering peak, suggesting subtle ordering. Coarse-grained molecular dynamics simulations are used to elucidate the nucleotide-specific dynamics within RNP condensates. While adenine-rich condensates behave like stable semidilute solutions, uracil-rich RNA condensates appear to be compositionally fluctuating. This approach helps understand how RNA sequence contributes to the molecular grammar of RNA-protein phase separation.