Aggregation of ALS-linked FUS mutant sequesters RNA binding proteins and impairs RNA granules formation

Protein aggregate/inclusion is one of hallmarks for neurodegenerative disorders including amyotrophic lateral sclerosis (ALS). FUS/TLS, one of causative genes for familial ALS, encodes a multifunctional DNA/RNA binding protein predominantly localized in the nucleus. C-terminal mutations in FUS/TLS cause the retention and the inclusion of FUS/TLS mutants in the cytoplasm. In the present study, we examined the effects of ALS-linked FUS mutants on ALS-associated RNA binding proteins and RNA granules. FUS C-terminal mutants were diffusely mislocalized in the cytoplasm as small granules in transiently transfected SH-SY5Y cells, whereas large aggregates were spontaneously formed in ∼10% of those cells. hnRNP A1, hnRNP A2, and SMN1 as well as FUS wild type were assembled into stress granules under stress conditions, and these were also recruited to FUS mutant-derived spontaneous aggregates in the cytoplasm. These aggregates stalled poly(A) mRNAs and sequestered SMN1 in the detergent insoluble fraction, which also reduced the number of nuclear oligo(dT)-positive foci (speckles) in FISH (fluorescence in situ hybridization) assay. In addition, the number of P-bodies was decreased in cells harboring cytoplasmic granules of FUS P525L. These findings raise the possibility that ALS-linked C-terminal FUS mutants could sequester a variety of RNA binding proteins and mRNAs in the cytoplasmic aggregates, which could disrupt various aspects of RNA equilibrium and biogenesis.     

Protein Arginine Methyltransferase 1 and 8 Interact with FUS to Modify Its Sub-Cellular Distribution and Toxicity In Vitro and In Vivo

Amyotrophic lateral sclerosis (ALS) is a late onset and progressive motor neuron disease. Mutations in the gene coding for fused in sarcoma/translocated in liposarcoma (FUS) are responsible for some cases of both familial and sporadic forms of ALS. The mechanism through which mutations of FUS result in motor neuron degeneration and loss is not known. FUS belongs to the family of TET proteins, which are regulated at the post-translational level by arginine methylation. Here, we investigated the impact of arginine methylation in the pathogenesis of FUS-related ALS. We found that wild type FUS (FUS-WT) specifically interacts with protein arginine methyltransferases 1 and 8 (PRMT1 and PRMT8) and undergoes asymmetric dimethylation in cultured cells. ALS-causing FUS mutants retained the ability to interact with both PRMT1 and PRMT8 and undergo asymmetric dimethylation similar to FUS-WT. Importantly, PRMT1 and PRMT8 localized to mutant FUS-positive inclusion bodies. Pharmacologic inhibition of PRMT1 and PRMT8 activity reduced both the nuclear and cytoplasmic accumulation of FUS-WT and ALS-associated FUS mutants in motor neuron-derived cells and in cells obtained from an ALS patient carrying the R518G mutation. Genetic ablation of the fly homologue of human PRMT1 (DART1) exacerbated the neurodegeneration induced by overexpression of FUS-WT and R521H FUS mutant in a Drosophila model of FUS-related ALS. These results support a role for arginine methylation in the pathogenesis of FUS-related ALS.     

Genome wide array analysis indicates that an amyotrophic lateral sclerosis mutation of FUS causes an early increase of CAMK2N2 in vitro

Mutations in the RNA binding protein FUS (fused in sarcoma) have been linked to a subset of familial amyotrophic lateral sclerosis (ALS) cases. The mutations are clustered in the C-terminal nuclear localization sequence (NLS). Various FUS mutants accumulate in the cytoplasm whereas wild-type (WT) FUS is mainly nuclear. Here we investigate the effect of one ALS causing mutant (FUS-ΔNLS, also known as R495X) on pre-mRNA splicing and RNA expression using genome wide exon-junction arrays. Using a non-neuronal stable cell line with inducible FUS expression, we detected early changes in RNA composition. In particular, mutant FUS-ΔNLS increased calcium/calmodulin-dependent protein kinase II inhibitor 2 (CAMK2N2) at both mRNA and protein levels, whereas WT-FUS had no effect. Chromatin immunoprecipitation experiments showed that FUS-ΔNLS accumulated at the CAMK2N2 promoter region, whereas promoter occupation by WT-FUS remained constant. Given the loss of FUS-ΔNLS in the nucleus through the mutation-induced translocation, this increase of promoter occupancy is surprising. It indicates that, despite the obvious cytoplasmic accumulation, FUS-ΔNLS can act through a nuclear gain of function mechanism.     

FUS-NLS/Transportin 1 Complex Structure Provides Insights into the Nuclear Targeting Mechanism of FUS and the Implications in ALS

The C-terminal nuclear localization sequence of FUsed in Sarcoma (FUS-NLS) is critical for its nuclear import mediated by transportin (Trn1). Familial amyotrophic lateral sclerosis (ALS) related mutations are clustered in FUS-NLS. We report here the structural, biochemical and cell biological characterization of the FUS-NLS and its clinical implications. The crystal structure of the FUS-NLS/Trn1 complex shows extensive contacts between the two proteins and a unique α-helical structure in the FUS-NLS. The binding affinity between Trn1 and FUS-NLS (wide-type and 12 ALS-associated mutants) was determined. As compared to the wide-type FUS-NLS (K_D = 1.7 nM), each ALS-associated mutation caused a decreased affinity and the range of this reduction varied widely from 1.4-fold over 700-fold. The affinity of the mutants correlated with the extent of impaired nuclear localization, and more importantly, with the duration of disease progression in ALS patients. This study provides a comprehensive understanding of the nuclear targeting mechanism of FUS and illustrates the significance of FUS-NLS in ALS.     

The FUS about arginine methylation in ALS and FTLD

EMBO J (2012) 31 22, 4258–4275 doi:10.1038/emboj.2012.261; published online September112012In a time where links between amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration (FTLD) neurodegeneration are becoming increasingly clear, it is important to establish the convergent and divergent mechanisms responsible for this. Accordingly, Dormann et al (2012) have identified that methylation of the Fused in sarcoma (FUS) RGG3 domain is involved in the cytoplasmic mislocalisation of ALS-FUS mutants, through a transportin-dependent mechanism. By contrast, hypomethylation in this domain may play a role in the aberrant accumulation of FUS in FTLD-FUS. This work showcases arginine methylation as a phenomenon to watch out for in neurodegenerative pathology.The nuclear RNA/DNA-binding protein, FUS, first burst onto the ALS scene in 2009 when it was discovered that mutations in this protein are causative for familial ALS (Kwiatkowski et al, 2009; Vance et al, 2009). It is now thought to be responsible for 4% of familial (and rare sporadic) ALS cases. In ALS patients with FUS mutations (ALS-FUS), the FUS protein is deposited in abnormal protein inclusions in neurons and glia and nuclei often show a reduced FUS staining (Lagier-Tourenne et al, 2010). Fascinatingly, this abnormal FUS deposition is also observed in several subtypes of FTLD, subsequently termed as FTLD-FUS. However, unlike in ALS-FUS, there are no known FUS mutations in this disease (Da Cruz and Cleveland, 2011). Dormann et al (2012) now broaden our knowledge of how ALS-causing mutations in FUS lead to its abnormal cytoplasmic deposition in neurons and glia, and for the first time suggest a mechanism through which this could also occur in FTLD-FUS, in the absence of FUS mutations.The majority of pathogenic mutations identified in ALS-FUS are located at the C-terminus of the protein within a region identified to be a proline-tyrosine nuclear localization signal (PY-NLS) (Figure 1). The PY-NLS binds to the nuclear import receptor transportin (TRN), which facilitates FUS transport into the nucleus. Pathogenic FUS mutations affect key residues of the PY-NLS or completely delete the signal sequence and thus impair nuclear import of FUS (Dormann et al, 2010). This nuclear transport defect is likely directly involved in pathogenesis, as mutations that cause a very severe nuclear import deficit (e.g., FUS-P525L), are associated with earlier disease onset and a rapid disease course (Dormann et al, 2010).Open in a separate windowFigure 1(A) Schematic diagram showing the domain structure of FUS. SYGQ-rich, serine, tyrosine, glycine, glutamine-rich domain; RRM, RNA recognition motif; ZnF, zinc finger; PY, proline-tyrosine nuclear localization signal (PY-NLS). (B) Schematic diagram summarizing the divergent mechanisms by which arginine methylation (or absence thereof) may bring about FUS mislocalization and accumulation in ALS-FUS and FTLD-FUS. In ALS-FUS caused by FUS mutations, neuronal cytoplasmic inclusions contain methylated FUS, but are negative for EWS, TAF15 and TRN. Dormann et al (2012) propose that these FUS-specific inclusions result from the combination of a genetic defect (point mutations in the PY-NLS that impair transportin binding) and post-translational modification (arginine methylation in RGG3 domain that also impairs transportin binding). By contrast in FTLD-FUS, neuronal cytoplasmic inclusions contain all three FET proteins and transportin, but are not immunoreactive with meFUS-specific antibodies. It is therefore possible that hypomethylation of the FET proteins and thus increased transportin binding may be involved in the co-deposition of these proteins in FTLD-FUS.FUS and other related PY-NLS-containing FET proteins such as Ewing sarcoma (EWS) protein and TATA-binding protein-associated factor 15 (TAF15) have been described to undergo extensive asymmetric dimethylation in their arginine-glycine-glycine (RGG) domains (Araya et al, 2005; Hung et al, 2009; Jobert et al, 2009). In recent times, it has been established that this arginine methylation can affect their nuclear localization (Araya et al, 2005; Jobert et al, 2009; Tradewell et al, 2012). In this issue, Dormann et al (2012) sought to delve further into the mechanism by which this occurs. They began their studies in a similar fashion to Tradewell and colleagues, by confirming that inhibiting global arginine methylation using the general methylation inhibitor, adenosine-2,3-dialdehyde (AdOx) could restore the lost nuclear localization of both HA-tagged cytoplasmic ALS-causing mutants and cytoplasmic EWS and TAF15 point mutants in HeLa cells. As AdOx is capable of inhibiting protein, DNA and lipid methylation, they also investigated the effect of specifically preventing protein methylation on the localization of the severe FUS-P525L ALS mutant. In these experiments, siRNA-mediated silencing of PRMT1, the protein arginine methyltransferase responsible for the majority of cellular protein arginine dimethylation, successfully restored the nuclear localization of FUS-P525L, thus confirming the importance of arginine methylation in the cytoplasmic localization of ALS-FUS mutants. After performing this groundwork, Dormann and colleagues then began an elegant set of experiments to unravel the mechanism behind their results. They first wanted to identify whether TRN was involved. Co-expression of GFP-tagged TRN inhibitor peptide with HA-tagged FUS-P525L in HeLa cells lead to a complete prevention of the normal nuclear accumulation of FUS-P525L upon AdOx treatment. Thus, identifying a critical role for TRN in the observed nuclear import of ALS-FUS mutants upon demethylation.Dormann et al (2012) next sought to determine how arginine methylation may impact the nuclear import of FUS by TRN. Their first step was to determine which arginine residues in FUS were involved. With this came the ground-breaking finding that it is actually arginine residues in the RGG3 motif N-terminal to the PY-NLS (Figure 1), rather than in the PY-NLS itself that can modulate TRN-dependent nuclear import of mutant FUS. Through NMR spectroscopy, Dormann and colleagues were then able to show that arginine residues in the FUS RGG3 motif can bind directly to TRN. These observations were taken further via studies of the interaction of recombinant FUS-RGG3 domain or synthetic FUS peptides with TRN by isothermal titration calorimetry. Here, they showed that the FUS-P525L mutant bound weakly or not at all to TRN, but in the presence of the unmethylated RGG3 domain the binding affinity of the mutant was rescued to WT-like levels. These observations were validated by the fact that the unmethylated RGG3 domain alone was able to bind TRN in the absence of a C-terminal PY-NLS with an affinity similar to that of the WT PY-NLS. Methylation of the RGG3 peptide completely prevented this binding. Through these experiments Dormann et al (2012) were able to show for the first time that residues outside of the PY-NLS can be involved in FUS nuclear import. Furthermore, they were able to establish a working model by which this occurs: they propose that in normal situations, the PY-NLS anchors the FUS C-terminus to TRN and the adjacent RGG repeats stabilize the interaction. Methylation of the RGG repeats interferes with TRN binding, but in WT FUS the affinity of the PY-NLS for TRN is sufficient to allow nuclear import to continue. By contrast, in the methylated P525L mutant, weak binding of both the methylated RGG domain and the c-terminus of the PY-NLS to TRN abrogates FUS nuclear import, thus causing its cytoplasmic accumulation.On the basis of their model, Dormann et al (2010) predicted that cytoplasmically mislocalized ALS FUS mutants would be methylated in their RGG3 domains. To test this hypothesis, they generated two monoclonal antibodies specific to the methylated RGG3 domain (meFUS antibodies). Cytosolic FUS mutants, such as FUS-P525L, were recognized by the meFUS-specific antibodies in HeLa cells, thus strongly suggesting that methylation of FUS mutants is a contributing factor to their cytoplasmic retention.Having generated the valuable tools of meFUS-specific antibodies, Dormann et al (2010) next turned their attention to the analysis of whether the intriguing shared property of cytoplasmic FUS accumulation in ALS-FUS and FTLD-FUS could be related to arginine methylation. In direct support of their cell-culture experiments, they discovered that there was a strong and consistent co-labelling of all FUS-positive cytoplasmic neuronal and glial inclusions with the meFUS antibody in post-mortem tissue from ALS-FUS patients. However, the surprise came when they began analysing post-mortem tissues from various subtypes of FTLD-FUS patients. Here, they could not see any labelling of FUS-positive neuronal and glial cytoplasmic and intranuclear inclusions with the meFUS-specific antibody. This strongly suggests that a different FUS cytoplasmic retention mechanism is in play in FTLD-FUS patients compared to ALS-FUS patients. In support of this, inclusions in ALS-FUS patients have recently been identified to contain only the FUS protein, while inclusions in FTLD-FUS show a clear co-deposition of all FET proteins (FUS, EWS, and TAF15) along with TRN itself (Neumann et al, 2012). From this, Dormann et al (2012) conclude that mislocalization of FUS in ALS is likely a phenomenon resulting directly from mutations in the nuclear localization signal that is exacerbated by arginine methylation in the RGG3 domain, whereas FUS mislocalization in FTLD-FUS may result from a more general defect in TRN-mediated nuclear import of FET proteins (Figure 1). Indeed, they speculate that in FTLD, hypomethylation of the FET proteins by a yet to be determined mechanism may lead to excessively tight binding of these proteins to TRN. This in turn may lead to impaired dissociation of FET-TRN complexes, which could over time lead to the co-deposition of FET proteins and TRN in cytoplasmic and nuclear inclusions in FTLD patients. The results of future experiments performed to test this hypothesis will doubtless be of huge significance for the FTLD field. Furthermore, this study raises many questions about the normal cellular role of FUS arginine methylation. Is it for example involved in the fine tuning of the shuttling of FUS into and out of the nucleus and if this is the case could arginine methylation in the RGG1 and RGG2 domains, one of which (RGG1) is close to the FUS nuclear export signal, also be involved in regulating FUS localization? All this remains to be seen…     

R521C and R521H mutations in FUS result in weak binding with Karyopherinβ2 leading to Amyotrophic lateral sclerosis: a molecular docking and dynamics study

Fused in sarcoma (FUS) gene encodes the RNA binding protein FUS. This gene is mapped to chromosome 16p11.2. The FUS protein binds with karyopherineβ2 (Kapβ2) through its proline/tyrosine nuclear localization signal (PY-NLS) that helps in the localization of FUS protein within the nucleus. Arginine residue in 521 position (R521) of PY-NLS plays a vital role in the binding of FUS protein with Kapβ2. Mutations in this position (R521C and R521H) are the most predominant mutations associated with amyotrophic lateral sclerosis (ALS). However, the mechanism by which these mutations lead to ALS is poorly understood. We examined the binding behaviour of the mutants FUS (R521C) and FUS (R521H) with Kapβ2 through protein–protein docking and molecular dynamics simulation. The binding patterns of mutants were compared with the binding behaviour of wild FUS–Kapβ2. Our results suggest that these mutants have relatively weak binding affinity with Kapβ2 when compared with wild FUS–Kapβ2 as indicated by the lesser number of interactions found between the mutant FUS and Kapβ2. Hence, these mutations weakens the binding and this results in the cytoplasmic mislocalization of mutant FUS; and thereby it increases the severity of ALS.     

Loss of fused in sarcoma (FUS) promotes pathological Tau splicing

A subset of amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration (FTLD) patients present pathological redistribution and aggregation of the nuclear protein fused in sarcoma (FUS) in the cytoplasm. Although FUS associates with the spliceosomal complex, no endogenous neuronal splicing targets have been identified. Here we identify Tau mRNA as a physiological splicing target of FUS. In mouse brain, FUS directly binds to Tau pre-mRNA, and knockdown of FUS in hippocampal neurons leads to preferential inclusion of Tau exons 3 and 10. FUS knockdown causes significant growth cone enlargement and disorganization reminiscent of Tau loss of function. These findings suggest that disturbed cytoskeletal function and enhanced expression of the neurodegeneration-associated Tau exon 10 might contribute to FTLD/ALS with FUS inclusions.     

The Effect of PRMT1-Mediated Arginine Methylation on the Subcellular Localization,Stress Granules,and Detergent-Insoluble Aggregates of FUS/TLS

Fused in sarcoma/translocated in liposarcoma (FUS/TLS) is one of causative genes for familial amyotrophic lateral sclerosis (ALS). In order to identify binding partners for FUS/TLS, we performed a yeast two-hybrid screening and found that protein arginine methyltransferase 1 (PRMT1) is one of binding partners primarily in the nucleus. In vitro and in vivo methylation assays showed that FUS/TLS could be methylated by PRMT1. The modulation of arginine methylation levels by a general methyltransferase inhibitor or conditional over-expression of PRMT1 altered slightly the nucleus-cytoplasmic ratio of FUS/TLS in cell fractionation assays. Although co-localized primarily in the nucleus in normal condition, FUS/TLS and PRMT1 were partially recruited to the cytoplasmic granules under oxidative stress, which were merged with stress granules (SGs) markers in SH-SY5Y cell. C-terminal truncated form of FUS/TLS (FUS-dC), which lacks C-terminal nuclear localization signal (NLS), formed cytoplasmic inclusions like ALS-linked FUS mutants and was partially co-localized with PRMT1. Furthermore, conditional over-expression of PRMT1 reduced the FUS-dC-mediated SGs formation and the detergent-insoluble aggregates in HEK293 cells. These findings indicate that PRMT1-mediated arginine methylation could be implicated in the nucleus-cytoplasmic shuttling of FUS/TLS and in the SGs formation and the detergent-insoluble inclusions of ALS-linked FUS/TLS mutants.     

The FUS gene is dual‐coding with both proteins contributing to FUS‐mediated toxicity

Novel functional coding sequences (altORFs) are camouflaged within annotated ones (CDS) in a different reading frame. We show here that an altORF is nested in the FUS CDS, encoding a conserved 170 amino acid protein, altFUS. AltFUS is endogenously expressed in human tissues, notably in the motor cortex and motor neurons. Over‐expression of wild‐type FUS and/or amyotrophic lateral sclerosis‐linked FUS mutants is known to trigger toxic mechanisms in different models. These include inhibition of autophagy, loss of mitochondrial potential and accumulation of cytoplasmic aggregates. We find that altFUS, not FUS, is responsible for the inhibition of autophagy, and pivotal in mitochondrial potential loss and accumulation of cytoplasmic aggregates. Suppression of altFUS expression in a Drosophila model of FUS‐related toxicity protects against neurodegeneration. Some mutations found in ALS patients are overlooked because of their synonymous effect on the FUS protein. Yet, we show they exert a deleterious effect causing missense mutations in the overlapping altFUS protein. These findings demonstrate that FUS is a bicistronic gene and suggests that both proteins, FUS and altFUS, cooperate in toxic mechanisms.     

Toxic gain of function from mutant FUS protein is crucial to trigger cell autonomous motor neuron loss

FUS is an RNA‐binding protein involved in amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Cytoplasmic FUS‐containing aggregates are often associated with concomitant loss of nuclear FUS. Whether loss of nuclear FUS function, gain of a cytoplasmic function, or a combination of both lead to neurodegeneration remains elusive. To address this question, we generated knockin mice expressing mislocalized cytoplasmic FUS and complete FUS knockout mice. Both mouse models display similar perinatal lethality with respiratory insufficiency, reduced body weight and length, and largely similar alterations in gene expression and mRNA splicing patterns, indicating that mislocalized FUS results in loss of its normal function. However, FUS knockin mice, but not FUS knockout mice, display reduced motor neuron numbers at birth, associated with enhanced motor neuron apoptosis, which can be rescued by cell‐specific CRE‐mediated expression of wild‐type FUS within motor neurons. Together, our findings indicate that cytoplasmic FUS mislocalization not only leads to nuclear loss of function, but also triggers motor neuron death through a toxic gain of function within motor neurons.     

Expression of human FUS/TLS in yeast leads to protein aggregation and cytotoxicity,recapitulating key features of FUS proteinopathy

Mutations in the fused in sarcoma/translocated in liposarcoma (FUS/TLS) gene have been associated with amyotrophic lateral sclerosis (ALS). FUS-positive neuropathology is reported in a range of neurodegenerative diseases, including ALS and fronto-temporal lobar degeneration with ubiquitin-positive pathology (FTLD-U). To examine protein aggregation and cytotoxicity, we expressed human FUS protein in yeast. Expression of either wild type or ALS-associated R524S or P525L mutant FUS in yeast cells led to formation of aggregates and cytotoxicity, with the two ALS mutants showing increased cytotoxicity. Therefore, yeast cells expressing human FUS protein recapitulate key features of FUS-positive neurodegenerative diseases. Interestingly, a significant fraction of FUS expressing yeast cells stained by propidium iodide were without detectable protein aggregates, suggesting that membrane impairment and cellular damage caused by FUS expression may occur before protein aggregates become microscopically detectable and that aggregate formation might protect cells from FUS-mediated cytotoxicity. The N-terminus of FUS, containing the QGSY and G rich regions, is sufficient for the formation of aggregates but not cytotoxicity. The C-terminal domain, which contains a cluster of mutations, did not show aggregation or cytotoxicity. Similar to TDP-43 when expressed in yeast, FUS protein has the intrinsic property of forming aggregates in the absence of other human proteins. On the other hand, the aggregates formed by FUS are thioflavin T-positive and resistant to 0.5% sarkosyl, unlike TDP-43 when expressed in yeast cells. Furthermore, TDP-43 and FUS display distinct domain requirements in aggregate formation and cytotoxicity.     

Arginine methylation next to the PY‐NLS modulates Transportin binding and nuclear import of FUS

Fused in sarcoma (FUS) is a nuclear protein that carries a proline‐tyrosine nuclear localization signal (PY‐NLS) and is imported into the nucleus via Transportin (TRN). Defects in nuclear import of FUS have been implicated in neurodegeneration, since mutations in the PY‐NLS of FUS cause amyotrophic lateral sclerosis (ALS). Moreover, FUS is deposited in the cytosol in a subset of frontotemporal lobar degeneration (FTLD) patients. Here, we show that arginine methylation modulates nuclear import of FUS via a novel TRN‐binding epitope. Chemical or genetic inhibition of arginine methylation restores TRN‐mediated nuclear import of ALS‐associated FUS mutants. The unmethylated arginine–glycine–glycine domain preceding the PY‐NLS interacts with TRN and arginine methylation in this domain reduces TRN binding. Inclusions in ALS‐FUS patients contain methylated FUS, while inclusions in FTLD‐FUS patients are not methylated. Together with recent findings that FUS co‐aggregates with two related proteins of the FET family and TRN in FTLD‐FUS but not in ALS‐FUS, our study provides evidence that these two diseases may be initiated by distinct pathomechanisms and implicates alterations in arginine methylation in pathogenesis.     

Intranuclear Aggregation of Mutant FUS/TLS as a Molecular Pathomechanism of Amyotrophic Lateral Sclerosis

Dominant mutations in FUS/TLS cause a familial form of amyotrophic lateral sclerosis (fALS), where abnormal accumulation of mutant FUS proteins in cytoplasm has been observed as a major pathological change. Many of pathogenic mutations have been shown to deteriorate the nuclear localization signal in FUS and thereby facilitate cytoplasmic mislocalization of mutant proteins. Several other mutations, however, exhibit no effects on the nuclear localization of FUS in cultured cells, and their roles in the pathomechanism of fALS remain obscure. Here, we show that a pathogenic mutation, G156E, significantly increases the propensities for aggregation of FUS in vitro and in vivo. Spontaneous in vitro formation of amyloid-like fibrillar aggregates was observed in mutant but not wild-type FUS, and notably, those fibrils functioned as efficient seeds to trigger the aggregation of wild-type protein. In addition, the G156E mutation did not disturb the nuclear localization of FUS but facilitated the formation of intranuclear inclusions in rat hippocampal neurons with significant cytotoxicity. We thus propose that intranuclear aggregation of FUS triggered by a subset of pathogenic mutations is an alternative pathomechanism of FUS-related fALS diseases.     

ALS-linked FUS mutations dysregulate G-quadruplex-dependent liquid–liquid phase separation and liquid-to-solid transition

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease characterized by the accumulation of protein aggregates in motor neurons. Recent discoveries of genetic mutations in ALS patients promoted research into the complex molecular mechanisms underlying ALS. FUS (fused in sarcoma) is a representative ALS-linked RNA-binding protein (RBP) that specifically recognizes G-quadruplex (G4)-DNA/RNAs. However, the effects of ALS-linked FUS mutations on the G4-RNA-binding activity and the phase behavior have never been investigated. Using the purified full-length FUS, we analyzed the molecular mechanisms of multidomain structures consisting of multiple functional modules that bind to G4. Here we succeeded to observe the liquid–liquid phase separation (LLPS) of FUS condensate formation and subsequent liquid-to-solid transition (LST) leading to the formation of FUS aggregates. This process was markedly promoted through FUS interaction with G4-RNA. To further investigate, we selected a total of eight representative ALS-linked FUS mutants within multidomain structures and purified these proteins. The regulation of G4-RNA-dependent LLPS and LST pathways was lost for all ALS-linked FUS mutants defective in G4-RNA recognition tested, supporting the essential role of G4-RNA in this process. Noteworthy, the P525L mutation that causes juvenile ALS exhibited the largest effect on both G4-RNA binding and FUS aggregation. The findings described herein could provide a clue to the hitherto undefined connection between protein aggregation and dysfunction of RBPs in the complex pathway of ALS pathogenesis.     

Recruitment into stress granules prevents irreversible aggregation of FUS protein mislocalized to the cytoplasm

Fused in sarcoma (FUS) belongs to the group of RNA-binding proteins implicated as underlying factors in amyotrophic lateral sclerosis (ALS) and certain other neurodegenerative diseases. Multiple FUS gene mutations have been linked to hereditary forms, and aggregation of FUS protein is believed to play an important role in pathogenesis of these diseases. In cultured cells, FUS variants with disease-associated amino acid substitutions or short deletions affecting nuclear localization signal (NLS) and causing cytoplasmic mislocalization can be sequestered into stress granules (SGs). We demonstrated that disruption of motifs responsible for RNA recognition and binding not only prevents SG recruitment, but also dramatically increases the protein propensity to aggregate in the cell cytoplasm with formation of juxtanuclear structures displaying typical features of aggresomes. Functional RNA-binding domains from TAR DNA-binding protein of 43 kDa (TDP-43) fused to highly aggregation-prone C-terminally truncated FUS protein restored the ability to enter SGs and prevented aggregation of the chimeric protein. Truncated FUS was also able to trap endogenous FUS molecules in the cytoplasmic aggregates. Our data indicate that RNA binding and recruitment to SGs protect cytoplasmic FUS from aggregation, and loss of this protection may trigger its pathological aggregation in vivo.