Your search keyword '"liquid–liquid phase separation (LLPS)"' showing total 7 results

1. ALS-causing hPFN1 mutants differentially disrupt LLPS of FUS prion-like domain.

Author

Kang, Jian, Lim, Liangzhong, and Song, Jianxing

Subjects

*AMYOTROPHIC lateral sclerosis, *PHASE separation, *RNA-binding proteins, *MOTOR neuron diseases, *NEURODEGENERATION

Abstract

hPFN1 mutations including C71G cause ALS by gain of toxicity but the mechanism still remains unknown. Stress granules (SGs) are formed by phase separation of the prion-like domain (PLD) of RNA-binding proteins including FUS, whose inclusion was also associated with ALS. C71G-hPFN1 triggers seed-dependent co-aggregation with FUS/TDP-43 to manifest the prion-like propagandation but its biophysical basis remains unexplored. Here by DIC imaging we first showed that three hPFN1 mutants have differential capacity in disrupting the dynamics of liquid droplets formed by phase separation of FUS prion-like domain (PLD). C71G-hPFN1 co-exists with the folded and unfolded states, thus allowing to simultaneously characterize conformations, hydrodynamics and dynamics of the interactions of both states with the phase separated FUS PLD by NMR. The results reveal that the folded state is not significantly affected while by contrast, the unfolded state has extensive interactions with FUS PLD. As a consequence, the dynamics of FUS liquid droplets become significantly reduced. Such interactions might act to recruit C71G-hPFN1 into the droplets, thus leading to the increase of the local concentrations and subsequent co-aggregation of C71G-hPFN1 with FUS. Our study sheds the first light on the biophysical basis by which hPFN1 mutants gain toxicity to cause ALS. As other aggregation-prone proteins have no fundamental difference from hPFN1 mutants, aggregation-prone proteins might share a common capacity in disrupting phase separation responsible for organizing various membrane-less organelles. As such, the mechanism for C71G-hPFN1 might also be utilized by other aggregation-prone proteins for gain of toxicity to trigger diseases and aging. [Display omitted] • C71G-, E117G- and G118V-hPFN1 cause ALS by gain of toxicity with unknown mechanism. • FUS phase separates for forming SGs, a central target for neurodegenerative diseases. • Here three ALS-causing hPFN1 mutants were shown to disrupt FUS phase separation. • The unfolded state of C71G-hPFN1 dynamically interacts with FUS as decoded by NMR. • Aggregation-prone proteins may gain toxicity commonly by disrupting phase separation. [ABSTRACT FROM AUTHOR]

Published

2023

2. Calcium promotes α-synuclein liquid-liquid phase separation to accelerate amyloid aggregation.

Author

Huang, Shuai, Xu, Bingkuan, and Liu, Yinghui

Subjects

*PHASE separation, *ALPHA-synuclein, *AMYLOID, *AMYLOID beta-protein, *PARKINSON'S disease, *PROTEIN fractionation

Abstract

α-Synuclein (α-Syn) is an aggregation-prone protein whose accumulation in Lewy bodies leads to neurodegenerative diseases like Parkinson's disease (PD). Calcium plays a critical role in neurons, and calcium dysregulation is one of the risk factors of PD. It is known that Ca2+ interacts with α-Syn and affects its assembly. However, how Ca2+ regulates α-Syn aggregation remains unclear. Here, we reported that Ca2+ accelerates α-Syn amyloid aggregation through the modulation of protein phase separation. We observed that Ca2+ promotes the formation of α-Syn liquid droplets but does not change the protein fluidity inside the droplets. Further studies showed Ca2+-involved α-Syn droplets are still able to fuse. A metal chelator eliminated Ca2+-induced enlargement of α-Syn droplets, suggesting the influence of Ca2+ on α-Syn assembly could be reversed at the stage of liquid-liquid phase separation (LLPS). Interestingly, our data showed Ca2+ still promoted α-Syn phase separation in the presence of the lipid membranes. In addition, Ca2+/α-syn droplets could efficiently recruit lipid vesicles to the surface of these condensates. Our findings demonstrate that Ca2+ facilitates α-Syn phase separation to accelerate amyloid aggregation and pave the path for understanding the implications of Ca2+ in α-Syn accumulation and PD. • Ca2+ facilitates the formation of α-Syn liquid droplets. • Ca2+ accelerates α-Syn amyloid aggregation through the modulation of protein phase separation. • Ca2+ promotes α-Syn phase separation in the presence of the lipid membranes. [ABSTRACT FROM AUTHOR]

Published

2022

3. An improved macromolecular crowding sensor CRONOS for detection of crowding changes in membrane-less organelles under stressed conditions.

Author

Miyagi, Tamami, Yamanaka, Yoshiaki, Harada, Yuichiro, Narumi, Satoshi, Hayamizu, Yuhei, Kuroda, Masahiko, and Kanekura, Kohsuke

Subjects

*FLUORESCENCE resonance energy transfer, *PATHOLOGICAL physiology, *ORGANELLES, *MACROMOLECULAR dynamics, *SCAFFOLD proteins, *AMYOTROPHIC lateral sclerosis

Abstract

Membrane-less organelles (MLOs) formed by liquid-liquid phase separation (LLPS) play pivotal roles in biological processes. During LLPS, proteins and nucleotides are extremely condensed, resulting in changes in their conformation and biological functions. Disturbed LLPS homeostasis in MLOs is thought to associate with fatal diseases such as amyotrophic lateral sclerosis. Therefore, it is important to detect changes in the degree of crowding in MLOs. However, it has not been investigated well due to the lack of an appropriate method. To address this, we developed a genetically encoded macromolecular crowding sensor CRONOS (cro wding sensor with m N e o nGreen and m S carlet-I) that senses the degree of macromolecular crowding in MLOs using a fluorescence resonance energy transfer (FRET) system. CRONOS is a bright biosensor with a wide dynamic range and successfully detects changes in the macromolecular volume fraction in solution. By fusing to the scaffold protein of each MLO, we delivered CRONOS to MLO of interest and detected previously undescribed differences in the degree of crowding in each MLO. CRONOS also detected changes in the degree of macromolecular crowding in nucleolus induced by environmental stress or inhibition of transcription. These findings suggest that CRONOS can be a useful tool for the determination of molecular crowding and detection of pathological changes in MLOs in live cells. • CRONOS is a bright, protein-based macromolecular crowding sensor. • CRONOS detects changes in macromolecular crowding in solutions. • CRONOS reveals differences in macromolecular crowding in membrane-less organelles. • Macromolecular crowding in the nucleolus is affected by various stresses. [ABSTRACT FROM AUTHOR]

Published

2021

4. ATP biphasically modulates LLPS of SARS-CoV-2 nucleocapsid protein and specifically binds its RNA-binding domain.

Author

Dang, Mei, Li, Yifan, and Song, Jianxing

Subjects

*SARS-CoV-2, *PROTEIN binding, *VIRAL proteins, *PHASE separation, *PROTEIN domains

Abstract

SARS-CoV-2 is a highly contagious coronavirus causing the ongoing pandemic. Very recently its genomic RNA of ∼30 kb was decoded to be packaged with nucleocapsid (N) protein into phase separated condensates. Interestingly, viruses have no ability to generate ATP but host cells have very high ATP concentrations of 2–12 mM. A key question thus arises whether ATP modulates liquid-liquid phase separation (LLPS) of the N protein. Here we discovered that ATP not only biphasically modulates LLPS of the viral N protein as we previously found on human FUS and TDP-43, but also dissolves the droplets induced by oligonucleic acid. Residue-specific NMR characterization showed ATP specifically binds the RNA-binding domain (RBD) of the N protein with the average Kd of 3.3 ± 0.4 mM. The ATP-RBD complex structure was constructed by NMR-derived constraints, in which ATP occupies a pocket within the positive-charged surface utilized for binding nucleic acids. Our study suggests that ATP appears to be exploited by SARS-CoV-2 to promote its life cycle by facilitating the uncoating, localizing and packing of its genomic RNA. Therefore the interactions of ATP with the viral RNA and N protein might represent promising targets for design of drugs and vaccines to terminate the pandemic. Image 1 • SARS-CoV-2 genomic RNA is packaged with its N protein via phase separation. • Here we discovered that ATP biphasically modulates phase separation of N protein. • ATP also specifically bind the RNA-binding domain of N protein with Kd of 3.3 mM. • ATP is thus critical for uncoating, localizing and packing of the viral genomic RNA. • ATP-Nprotein-RNA interactions represent key targets for drug of drugs and vaccines. [ABSTRACT FROM AUTHOR]

Published

2021

5. ATP-driven reactions are required for the assembly of large stress granules.

Author

Eum, Hongsik, Shin, Yejin, Song, Youngsup, Kim, Yongsub, and Kang, Sang-Wook

Subjects

*SMALL molecules, *CHEMICAL reactions, *KINASE inhibitors, *PHASE separation, *ADENOSINE triphosphate, *NUCLEOPROTEINS

Abstract

Stress granules (SGs) are functional messenger ribonucleoprotein aggregates, and their assembly is an important cellular process required for remodeling the signaling network to cope with extensive environmental stresses. SG formation is a stepwise process that involves the formation of a stable core followed by a less stable outer shell, and this process is often hampered by faulty regulation of protein phosphorylation. It remains unclear, however, which kinase activity is essential for SG formation. Here, we screened small molecule library of kinase inhibitors using a well-validated fluorogenic SG probe. Our screen, time-lapse microscopy, and biochemical analyses identified an ATP-mimetic SG inhibitor that selectively interferes with the fusion and growth, rather than the initial assembly, of SG core structures into the large assemblies. Thus, SGs utilize ATP-dependent chemical reactions to achieve their functional architectures. • We created, optimized, and validated a fluorogenic stress granule monitoring system. • We discovered an ATP-mimetic inhibitor that inhibits stress granule formation. • 5′-iodotubercidin interferes with the growth of stress granule core structures. • Uncharacterized ATP-driven reactions are required for stress granule maturation. [ABSTRACT FROM AUTHOR]

Published

2020

6. ATP enhances at low concentrations but dissolves at high concentrations liquid-liquid phase separation (LLPS) of ALS/FTD-causing FUS.

Author

Kang, Jian, Lim, Liangzhong, and Song, Jianxing

Subjects

*ADENOSINE triphosphate, *PROTEINS

Abstract

Abstract ATP is the universal energy currency but mysteriously its cellular concentration is much higher than that needed for providing energy. Recently ATP was decoded to act as a hydrotrope to dissolve liquid-liquid phase separation (LLPS) of FUS whose aggregation leads to ALS/FTD. By DIC microscopy and NMR, here we characterized the effect of ATP on LLPS of FUS and its N-/C-terminal domains. Very unexpectedly, we found that like nucleic acids, ATP enhances LLPS of FUS at low but dissolves at high concentrations. Intriguingly, ATP monotonically dissolves LLPS of NTD, while it induces LLPS of CTD at low but dissolves at high concentrations. Our study reveals for the first time that ATP can enhance LLPS most likely by behaving as a bivalent binder. Most importantly, our results imply that age-dependent reduction of ATP concentrations may not only result in decreasing its capacity in preventing protein aggregation, but also in enhancing aggregation. Graphical abstract Image 1 Highlights • ATP is the energy currency but mysteriously with very high cellular concentrations. • ATP was recently decoded to dissolve LLPS of FUS whose aggregation leads to ALS. • Here we found for the first time that ATP can also enhance LLPS of FUS. • Therefore additional to being a hydrotrope, ATP also acts as a bivalent binder. • Our finding offers key clues in understanding age-dependent protein aggregation. [ABSTRACT FROM AUTHOR]

Published

2018

7. TDP-43 NTD can be induced while CTD is significantly enhanced by ssDNA to undergo liquid-liquid phase separation.

Author

Wang, Lu, Kang, Jian, Lim, Liangzhong, Wei, Yuanyuan, and Song, Jianxing

Subjects

*SINGLE-stranded DNA, *LIQUID-liquid transformations, *NEURODEGENERATION, *ALZHEIMER'S disease, *AMYOTROPHIC lateral sclerosis

Abstract

TDP-43 inclusions are characterized by a large spectrum of neurodegenerative diseases such as ALS and Alzheimer's. Functionally, TDP-43 is engaged in forming dynamic granules via liquid-liquid phase separation (LLPS), which is now recognized to be a general principle for organizing a variety of cellular membrane-less organelles. TDP-43 is composed of the N-terminal domain (NTD) adopting an ubiquitin-like fold, two RRMs and C-terminal domain (CTD) with the low-complexity (LC) prion-like sequences. Previously, only the CTD was found to undergo LLPS to form dynamic liquid droplets with relatively small numbers and sizes. Here we found for the first time that ssDNA can induce the NTD as well as significantly enhance the CTD to undergo LLPS. Further systematic investigations with 10 ssDNA of different sequences and lengths reveal that two distinct mechanisms exist respectively for the ssDNA-mediated LLPS of the NTD and CTD. As most, if not all functions of TDP-43, are involved in contacting nucleic acids including ssDNA, our results imply that nucleic acids might mediate the physiological functions and pathological roles of TDP-43 by previously-unappreciated mechanisms. [ABSTRACT FROM AUTHOR]

Published

2018