Familial ALS-associated SFPQ variants promote the formation of SFPQ cytoplasmic aggregates that reduce surface AMPA receptor expression in primary neurons

DNA constructs

The construction of pCDF11-SFPQ-276–535, pGEX6p1-SFPQ-276–598, and pGEX6p1-RXRα-DBD (residues 130-228) has been described elsewhere [7, 19]. The N533H and L534I mutations in the pEGFP-SFPQ and pGEX6P1-SFPQ-276–598 constructs were generated with the Q5 site-directed mutagenesis kit (New England Biolabs). All constructs were verified by DNA sequencing. Plasmid DNAs encoding the myc-tagged GluA1 and GluA2 subunits of AMPARs were gifts from Prof. Richard Huganir and have been described previously [23, 24].

Protein expression and purification

His6-tagged SFPQ-276–535 L534I was expressed and purified by the method previously reported for wild-type (WT) His-tagged SFPQ-276–535 [7]. The procedures for the expression and purification of GST-tagged RXRα-DBD-130–228 (encoding amino acid residues 130 – 228 of human RXRα) were performed according to a previous report [25]. GST-tagged SFPQ constructs (SFPQ-276–598 WT, SFPQ-276–598 N533H, and SFPQ-276–598 L534I) were expressed and purified by the method previously reported for GST-SFPQ-276–598 WT [19]. Following the cleavage of the GST-tag, recombinant proteins were then eluted from a HiLoad 16/600 Superdex 200 pg column (GE Healthcare) equilibrated with 20 mM Tris-HCl (pH 7.5), 300 mM NaCl. Final protein samples were concentrated to 4 – 8 mg/ml, snap-frozen using liquid nitrogen and stored at -80°C.

Zinc-binding assay

Due to the formation of infinite polymers and protein precipitation upon zinc binding, we were not able to measure the binding affinity of SFPQ to zinc directly [26]. Instead, measurements of the zinc-binding affinities of the SFPQ-276-598 WT and mutant proteins (SFPQ-276–598 N533H and SFPQ–276-598 L534I) were achieved with the Fluozin-3 competitive zinc-binding assay as previously described [19, 27]. Briefly, competition by ethylenediaminetetraacetic acid (EDTA)-treated SFPQ proteins in 20 mM MOPS (pH 7.0), 250 mM NaCl for Zn(II) binding was assessed by monitoring the decrease in the fluorescence of 150 nM Fluozin-3-Zn(II) with an excitation wavelength of 485 nm and emission wavelength of 520 nm in response to increasing SFPQ protein concentrations. The data were analyzed using the equation, log₁₀[inhibitor] versus response – variable slope, in Prism (GraphPad Software) to determine the IC₅₀ value for zinc-binding.

Crystallization and X-ray diffraction data collection

Crystals of the Zn-SFPQ-276–535 L534I complex were grown using the same strategy as for SFPQ WT 276-535 in complex with Zn(II). Briefly, SFPQ-276–535 (2.5 mg/ml) and RXRα-DBD-130–228 (1 mg/ml), both in 20 mM Tris-HCl (pH 7.5), 500 mM NaCl were mixed at a molar ratio of 1:1 and incubated for one hour before being concentrated to 15 mg/ml. The crystals were grown using the hanging-drop vapor diffusion method at 20°C by mixing 2 μl of SFPQ-RXRα-DBD (7.5 mg/ml) with 2 μl of reservoir solution [0.1 M MES (pH 6.0), 0.2 M calcium chloride, and 12% (w/v) PEG 4000] and equilibrating against 0.5 ml reservoir solution. Prior to cryo-cooling, crystals were successively transferred to artificial reservoir solutions containing 20% ethylene glycol in 10% increments. Diffraction data were recorded on beamline MX2 at the Australian Synchrotron [28] at a wavelength of 0.954 Å at 100 K. Additional datasets were collected for metal identification at low- and high-energy remote wavelengths of 9560 eV and 9760 eV, respectively, at 100 K. The data were processed with XDS [29], and merged and scaled with AIMLESS [30]. Crystals belong to space group P2₁ with unit cell parameters of a = 61.6, b = 62.7, c = 67.8 Å, and β = 96.1°, similar to those of the WT crystals [19]. Data collection and merging statistics for the native data set are summarized in Table 1 and those for the data sets collected for metal identification in Supplementary Table S1.

Structure solution and refinement

The crystal structure was refined using the Zn-SFPQ complex structure (PDB code 6OWJ [19]) as the initial model after removing all non-protein atoms and mutating L534 to alanine. Iterative model building with COOT [31] and refinement with REFMAC5 [32] within the CCP4 suite [33] was carried out. The final model consisted of two chains of SFPQ (residues 283 – 535 in Chain A and residues 290 – 368, 371 – 535 in Chain B), two Zn atoms (one of the two with half occupancy), and 277 water molecules. The quality of the model was validated using MOLPROBITY[34]. The refinement statistics are included in Table 1. The atomic coordinates have been deposited in the Protein Data Bank as entry 7SP0.

Zinc treatment and SFPQ localization assay

Primary cortical neurons were prepared from embryonic day 18 rat pups as described previously [35]. Neurons were transfected at days in vitro (DIV) 13 using Lipofectamine 2000 (Invitrogen). The next day, they were treated with either 100 μM ZnCl₂ for 4 h or water (vehicle control), and subsequently fixed with 4% paraformaldehyde/4% sucrose solution in PBS. Following extensive washes, the neurons were stained with anti-MAP2 antibody (M3696, Sigma-Aldrich) before mounting them onto glass slides using ProLong Diamond anti-fade mounting medium with DAPI (Invitrogen). Slides were imaged on a Zeiss Axio Imager epifluorescence microscope. The fractions of neurons containing nuclear or cytoplasmic GFP-SFPQ aggregates over total transfected neurons were quantified and normalized to the GFP-SFPQ WT without ZnCl₂ treatment group.

Dendritic spine analysis

Neurons were co-transfected with the structural marker td-Tomato and pEGFP-SFPQ, either WT, N533H or L534I mutants for 48 h. Fixed neurons were imaged with a 100X oil-immersion objective on an inverted Diskovery spinning disk confocal microscope. Secondary dendrites of co-transfected neurons were randomly imaged as z-stacks with a 0.4 μm step size over a range of approximately 5-10 μm. Spine analysis was performed on raw image stacks (z-plane) using ImageJ software. Spine density was calculated as the total number of spines per sum of all measured dendritic lengths for each neuron. All clear protrusions from the dendrite, irrespective of their orientation relative to the imaging plane, were included in the analyses.

Surface staining assay

To determine the level of AMPARs on the plasma membrane of primary neurons, we performed an antibody-feeding assay as previously described [23]. Neurons were co-transfected with pRK5-myc-GluA1 or pRK5-myc-GluA2 with pEGFP alone or pEGFP-SFPQ, either WT, N533H or L534I mutants, for 48 h. Surface AMPARs were labeled by incubating live neurons with mouse anti-myc antibody (MCA2200, BioRad) for 30 min at 4°C prior to 10 min fixation in ice-cold parafix solution (4% paraformaldehyde, 4% sucrose in PBS). Following cell permeabilization (0.25% Triton X-100 in PBS, 10 min) and blocking (10% normal goat serum, 1 h) at room temperature, total myc-GluA1/2 was labeled with rabbit anti-myc antibody (71D10, Cell Signaling Technology) at 4°C overnight. The surface and total myc-GluA1 or myc-GluA2 were subsequently visualized by Alexa-568-conjugated anti-mouse and Alexa-647-conjugated anti-rabbit secondary antibodies, respectively. Images were collected with a 63X oil-immersion objective on a Zeiss LSM510 confocal microscope. Fluorescence intensities were quantified using ImageJ software (NIH) for surface and total receptors. Data were expressed as the surface/total AMPAR ratio.

SFPQ N533H and L534I display higher zinc-binding affinities than WT protein

We have previously identified an intermolecular zinc-coordinating center within the SFPQ DBHS domain that comprises His-483, His-528, His-530, and the carbonyl group of Leu-535 (Fig. 1A, B). The identification of two fALS-associated SFPQ missense variants in the proximity of the SFPQ zinc-coordinating center (N533H and L534I) suggests that they may affect the affinity of SFPQ to zinc. In particular, the additional histidine residue in the N533H mutant may be involved in zinc coordination, thereby enhancing the affinity of SFPQ to zinc. To test this hypothesis, we performed a competitive zinc-binding assay on the purified SFPQ DBHS domain containing the N533H or L534I mutations using the fluorescent zinc indicator, Fluozin-3 [19]. The calculated affinity (IC₅₀) of SFPQ N533H (0.25 μM) and L534I (0.54 μM) binding to zinc was approximately 5.8- and 2.7-fold higher than that of the WT protein (1.45 μM), respectively (Fig. 1C and Suppl. Table S2), confirming that these fALS-associated mutations cause significant increases in SFPQ zinc-binding affinity. Although the effect of SFPQ N533H was expected, it was surprising to observe the increased zinc-binding affinity for the L534I mutant given the subtle nature of the substitution. It is also noteworthy that the slope of fluorescence reduction was significantly steeper for SFPQ L534I than SFPQ WT, whereas that of SFPQ N533H was modest, represented by Hill slopes of -25.1 (L534I), -12.4 (N533H), and -5.9 (WT) (Fig. 1C and Suppl. Table S2). The crystal structure of SFPQ L534I in complex with zinc described below partly explains this cooperativity.

The crystal structure of SFPQ L534I reveals a secondary zinc-binding site

To gain insights into the structural basis of the enhanced zinc-binding affinity of the fALS-associated SFPQ mutant, we solved the crystal structure of the SFPQ dimerization domain (residue 276-535) containing the L534I mutation in complex with Zn(II) (Fig. 2A). The approach to produce crystals of SFPQ WT in complex with Zn(II) was the same as that used previously [19]. Briefly, the DNA-binding domain of retinoic X receptor α (RXRα), which contains two zinc finger domains, was incubated with the SFPQ L534I mutant protein (1:1 molar ratio) and crystallized by the hanging-drop vapor diffusion method at 20°C [19]. The overall structure of SFPQ L534I in complex with Zn(II) is similar to that of SFPQ WT with the root mean square deviation (r.m.s.d.) of 0.28 Å between them (496 common Cα superposed) (Fig. 2A and Suppl. Fig. S1). Consistent with SFPQ WT, the intermolecular interaction mediated by zinc also results in infinite polymerization of SFPQ L534I (Fig. 2B, C). Given the subtle nature of the substitution from leucine to isoleucine, these observations were expected. However, the structural refinement of SFPQ L534I revealed a surprising additional metal density, which also mediates the intermolecular interaction of SFPQ (Fig. 2B, C). The identity of this metal ion was confirmed as zinc by calculating the anomalous difference Fourier maps from diffraction data collected at energies near the zinc X-ray absorption edge: 9760 eV (f”_Zn = 3.77 e^-) and 9560 eV (f”_Zn = 0.57 e^-) (Fig. 2D, E and Suppl. Fig. S2).

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Fig. 2

The crystal structure of the SFPQ L534I mutant reveals a second zinc-binding site. A Stereo view of the dimerization domain of the human SFPQ (residues 276 – 535) L534I mutant in complex with zinc in cartoon presentation with Chain A in gray and Chain B in the same color scheme as in the schematic domain organization below. The Zn atoms are shown as black spheres. B, C Zinc-mediated infinite polymerization observed in the crystal structure of SFPQ L534I from the side (B) and top (C) views. Chains A and B are shown in cyan and pink, respectively, while the neighboring symmetry-related dimers are shown in gray. D Zinc centers in the crystal structure of the SFPQ L534I mutant. The intermolecular interaction mediated by two zinc atoms is shown with Chain A and Chain B in cyan and pink, respectively, while the neighboring dimer (symmetry operator: x, y, z – 1) is shown in gray. E Close-up view of the zinc centers with overlaid anomalous difference Fourier map (|F⁺| – |F^-|, contoured at 7 σ) from the diffraction data collected at 9760 eV near the Zn X-ray absorption edge (f”_Zn = 3.77 e^-) for zinc identification. The positions of the L534I mutation are shown with the side chain of Ile in stick presentation. F Zinc center 1 is coordinated by H483 (Chain A), H530 (Chain B), H528* (Chain A of neighboring dimer), and carbonyl oxygen of L535* (Chain A of neighboring dimer). The asterisk (*) denotes a symmetry-related dimer (x, y, z – 1). G The partially occupied zinc center 2 (occupancy of 0.5) is coordinated by E529 (Chain B), H483* and E489* (Chain B of neighboring dimer).

A closer inspection of the two zinc centers showed that the first zinc coordinating center (Zn center 1) is almost indistinguishable from that of SFPQ WT, coordinated by His A483, His B530, His A*528 and a carbonyl oxygen of Leu A*535, where the asterisk (*) denotes a symmetry-related dimer (x, y, z – 1) (Fig. 2F). The Zn²⁺ ion in this center is fully occupied with a comparable B-factor value (22.4 Ų) to those of ligating atoms (average B-factor of 20.9 Ų). The anomalous signal from the second center (Zn center 2) is, however, significantly lower than that of Zn center 1 (Fig. 2E), indicating that this site is not fully occupied. The second zinc coordination center is composed of three amino acid residues: Glu B*489, Glu B529, and His B*483 (symmetry operator: x, y, z – 1). Further supporting the partially occupied zinc, the side chain of two out of three of these amino acids is also observed in two different conformations (Fig. 2G). The side chains of Glu B529 and His B*483 are in the ‘in’ position coordinating zinc, whereas in the absence of zinc, they take on the ‘out’ conformation. Zinc in the second center is modeled with the occupancy of 0.5 in the final structure with a comparable B-factor value (28.1 Ų) to those ligating atoms (average B-factor of 26.8 Ų). The fourth zinc-ligating atom is likely to be a partially occupied solvent atom; however, it could not be modeled in the final structure due to its low electron density (Suppl. Fig. S2). Taken together, the crystal structure of SFPQ L534I in complex with zinc reveals an additional zinc-binding site, providing the structural basis for the apparent increase in zinc-binding affinity in this mutant.

fALS-associated N533H and L534I mutants promote SFPQ cytoplasmic aggregation in neurons

Mislocalization and cytoplasmic aggregation of nuclear SFPQ are associated with the pathogenesis of ALS [15, 16]. We have previously demonstrated that the application of ZnCl₂ induces the cytoplasmic accumulation and aggregation of SFPQ in cultured neurons [19]. To determine the effect of N533H and L534I mutations on SFPQ localization, we transiently transfected primary cortical neurons with DNA constructs that encode GFP-SFPQ, either WT, N533H or L534I for 24 h. Under basal conditions, overexpression of GFP-SFPQ N533H and L534I significantly enhanced the propensity to form cytoplasmic aggregates in primary cortical neurons compared to the WT protein (Fig. 3A–C). As expected, the addition of 100 μM ZnCl₂ to the culture medium for 4 h significantly increased the number of neurons with cytoplasmic GFP-SFPQ aggregates in the somatodendritic regions (Fig. 3D). However, ZnCl₂ treatment did not result in a further increase in the proportion of neurons containing GFP-SFPQ cytoplasmic aggregates when transfected with the N533H and L534I mutants, suggestive of an occlusion effect (Fig. 3D). Together, these data indicate that the increase in zinc-binding affinity accounts for the elevation in the number of cytoplasmic aggregates observed in neurons that express these two fALS-associated SFPQ mutants.

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Fig. 3

fALS-associated N533H and L534I mutants promote the cytoplasmic aggregation of SFPQ. A Representative confocal images of primary cortical neurons expressing GFP-SFPQ (green) exhibiting nuclear localization (top panel) or cytoplasmic aggregates in the somatodendritic regions (bottom). Higher-magnification images are shown on the right panels. Scale bars, 50 μm or 10 μm (inset). B Quantification of the fraction of neurons with GFP-SFPQ cytoplasmic aggregates within individual experiments (Wilcoxon matched-pairs t-test, *p<0.05, N=5 independent experiments). C Quantification of the fraction of neurons with GFP- SFPQ cytoplasmic aggregates normalized to the value of the WT group. Data represent mean ± SEM (Welch’s unpaired t-test, **p<0.01, N=5 independent experiments). D Zinc-induced SFPQ aggregation is occluded in neurons expressing fALS-associated mutants. Primary cortical neurons expressing GFP-SFPQ, either WT, N533H or L534I mutants, were treated with 100 μM ZnCl₂ for 4 h. Data represent mean ± SEM, normalized to the WT group (two- way ANOVA, Sidak’s post-hoc multiple comparison test, *p<0.05, ns=not significant, N=3 independent experiments). Each data point was derived from one coverslip, which contained an average of 113 transfected neurons.

Cytoplasmic SFPQ aggregation causes a reduction in the level of surface GluA1 expression

Our observation that SFPQ cytoplasmic aggregates are largely localized in the soma and dendrites raises the question of whether these protein aggregates affect dendritic functions in primary neurons. To investigate this, we first examined the effect of SFPQ overexpression on the density of dendritic spines of neurons that co-expressed a structural marker td-Tomato and GFP or GFP-SFPQ, either WT, N533H or L534I (Fig. 4A). Interestingly, overexpression of GFP-SFPQ caused a significant reduction in the number of dendritic spines compared with those expressing soluble GFP alone (Fig. 4A, B). This effect was observed in all neurons containing nuclear or aggregated GFP-SFPQ (Fig. 4A, B). However, there was no significant difference between GFP-SFPQ WT or fALS mutants (Fig. 4C), suggesting that these mutations play no role in regulating the density of dendritic spines in primary neurons.

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Fig. 4

Overexpression of GFP-SFPQ reduces dendritic spine density, a phenotype that is not affected by fALS-associated SFPQ variants. A Confocal images of dendritic segments of neurons co-expressing the structural marker td-Tomato (red) and soluble GFP (left panels) or GFP-SFPQ (green) that exhibit nuclear localization (middle panels) or cytoplasmic aggregates in the somatodendritic regions (right panels). Scale bar, 10 μm (inset). B Quantification of dendritic spine density from neurons that express soluble GFP, nuclear GFP-SFPQ or GFP- SFPQ aggregates. Data are presented as mean ± SEM (one-way ANOVA, Tukey’s post-hoc multiple comparison test, *p<0.05 **p<0.01; GFP, n=14 neurons; nuclear, n=29 neurons; aggregate, n=18 neurons, N=2 independent experiments). C Quantification of dendritic spine density from neurons expressing GFP-SFPQ WT, N533H or L534I mutants. Data are presented as mean ± SEM (Welch’s unpaired t-test, ns=not significant; N=2 independent experiments).

Given that excitotoxicity and altered cortical excitability are pathophysiological features associated with ALS [36], we next investigated the effect of the N533H and L534I mutants on the surface expression of the GluA1 and GluA2 subunits of AMPARs, which mediate the majority of fast excitatory synaptic transmission in the mammalian central nervous system [37]. Primary neurons were transfected with myc-GluA1 or myc-GluA2 reporter constructs with plasmids that encode GFP or GFP-SFPQ, either WT, N533H or L534I, followed by a surface staining assay with anti-myc antibodies. Neurons that expressed nuclear GFP-SFPQ, regardless of its genotype, had normal levels of GluA1-containing AMPARs on the plasma membrane compared to those that expressed soluble GFP alone (Fig. 5A, B). However, cytoplasmic SFPQ aggregates caused a significant decrease in the expression of GluA1-containing AMPARs on the plasma membrane of neurons that overexpressed GFP-SFPQ WT, N533H or L534I (Fig. 5A–C). This effect was specific to GluA1 as cytoplasmic SFPQ aggregates did not affect the expression of surface GluA2-containing AMPARs in primary neurons (Fig. 5D, E). Collectively, our results indicate that the fALS-associated SFPQ variants, which promote the propensity of SFPQ to form cytoplasmic aggregates, may alter neuronal excitability by changing the subunit composition of neuronal AMPARs.

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Fig. 5

Cytoplasmic SFPQ aggregates selectively reduce the levels of GluA1- but not the GluA2-containing AMPARs on the plasma membrane. A Primary cortical neurons were co- transfected with plasmids encoding myc-GluA1 and GFP or GFP-SFPQ. Representative images of surface and total myc-GluA1 in neurons expressing soluble GFP, nuclear GFP-SFPQ or GFP-SFPQ cytoplasmic aggregates. Zoomed images are dendrites from the boxed regions. Scale bars, 20 μm or 10 μm (enlarged images). B Quantification of the surface/total GluA1 ratio normalized to the value of GFP-expressing neurons. Data are presented as mean ± SEM (Welch’s unpaired t-test, ***p<0.001; nuclear, n=48 neurons; aggregate, n=20 neurons, from two independent experiments). C Quantification of the surface/total GluA1 ratio from neurons expressing GFP-SFPQ WT, N533H or L534I mutants, normalized to the value of GFP- expressing neurons. Data are presented as mean ± SEM (Welch’s unpaired t-test, *p<0.05 **p<0.01; N=2 independent experiments). D Confocal images of primary neurons co- expressing myc-GluA2 and soluble GFP, nuclear GFP-SFPQ or GFP-SFPQ cytoplasmic aggregates. Scale bars, 20 μm or 10 μm (enlarged images). E Cytoplasmic SFPQ aggregation does not affect the expression of surface GluA2-containing AMPARs. Data represent mean ± SEM (Welch’s unpaired t-test, ns=not significant; nuclear, n=26 neurons; aggregate, n=43 neurons, from two independent experiments).

Structural basis of enhanced zinc-binding affinity in SFPQ L534I

The identification of a secondary zinc-binding site in the SFPQ L534I structure explains the apparent increase in zinc-binding affinity. It also explains the higher Hill slope measured in this variant in comparison to the WT protein. Given that there is more than one zinc-binding site in SFPQ L534I, we fitted the data from the zinc-binding assays with the IC₅₀ model instead of the one site non-linear fit in our previous study with SFPQ WT [19]. This raises the question as to which structural changes accommodate the second zinc-binding site in this variant. An overall structural comparison between the L534I mutant with SFPQ WT in complex with zinc reveals no obvious differences that can explain the increased zinc-binding of SFPQ L534I (Suppl. Fig. S1). The main structural deviations are concentrated at the end of N-terminal region upstream of the structured RRM1 due to lack of crystal contacts. Part of the NOPS domain in Chain A (residues 449 – 477) shows higher r.m.s.d. values than the mean value of 0.28 Å with greatest Cα r.m.s.d. of 1.0 Å (Met-469). However, how these subtle displacements increase the Zn²⁺-binding affinity of SFPQ L534I is not clear.

This led us to revisit the crystal structure of SFPQ WT in complex with zinc. The anomalous difference Fourier maps calculated from the diffraction data collected at the high Zn energy wavelength at 9760 eV clearly show the difference between WT and the L534I mutant (Suppl. Fig. S3). In the position corresponding to Zn center 2, there is a small anomalous signal that accounts for a possible weakly bound Zn(II) in SFPQ WT. However, it is significantly weaker than that of SFPQ L534I, reinforcing our observation that this mutation enhances the zinc-binding affinity of SFPQ in solution. The final model of SFPQ WT has a water molecule in this site with a B-factor value of 29.5 Ų, while Oε1 of Glu-489, a potential hydrogen donor to this water molecule, has a comparable B-factor value of 23.3 Ų. Although it is subtle, the substitution of leucine to isoleucine may affect the dynamics of SFPQ in solution, thereby facilitating the increased zinc-binding affinity. However, the precise underlying molecular mechanism requires further investigation.

At present, we are not able to ascertain if the additional histidine in SFPQ N533H is indeed replacing the carbonyl oxygen atom of Leu-535 in the zinc-coordinating center in the absence of the zinc-bound SFPQ N533H crystal structure. However, the fact that SFPQ N533H (0.25 μM) displays a higher zinc-binding affinity than SFPQ L534I (0.54 μM), and the failure to crystallize this mutant under the same conditions as SFPQ WT and L534I may indicate that SFPQ N533H has a different zinc center.

Cytoplasmic SFPQ aggregates selectively reduce the expression of GluA1-containing AMPARs

Excitotoxicity is a major cause of neuronal death in a number of neurodegenerative conditions, including ALS [39], with altered cortical excitability and synaptic dysfunction being identified as early pathophysiological features in this disease [36, 40]. Emerging evidence has demonstrated attenuated synaptic function in neurons expressing ALS-associated mutant proteins, particularly alterations in their dendritic arbor complexity, dendritic spine density and the level of postsynaptic ionotropic AMPARs [41-43]. We found that overexpression of GFP-SFPQ significantly downregulates the number of dendritic spines in primary cortical neurons compared to those that express soluble GFP. Interestingly, this effect was observed in all neurons with nuclear or cytoplasmic SFPQ aggregates. One plausible mechanism may involve the sequestration of an important SFPQ interacting partner FUS, leading to its loss of function and consequently, a deficit in dendritic spine morphogenesis [44-46]. Alternatively, overexpression of SFPQ can dysregulate the transcription of long genes, many of which are involved in neuronal development and neurite outgrowth [5]. Although SFPQ overexpression-induced loss of dendritic spines is not affected by fALS-associated SFPQ variants, our data suggest that SFPQ is an important regulator of dendritic spine formation and/or maturation in excitatory neurons, a finding which warrants further investigation.

AMPARs are assembled as two identical heterodimers of GluA1-4 subunits that form functional glutamate-gated ion channels. The presence of the GluA2 subunit renders AMPARs impermeable to Ca²⁺. Alterations in AMPAR subunit composition have been reported in human post-mortem tissues of ALS patients [47, 48] and in various ALS models that overexpress ALS-associated proteins, including TDP-43, FUS and C9ORF72 [44, 49-51]. Consistent with this notion, we found that neurons that contain cytoplasmic SFPQ aggregates have significantly reduced surface expression of GluA1-containing AMPARs compared to those that express nuclear SFPQ. This effect is specific to the GluA1 subunit as the aggregation of SFPQ does not affect the GluA2 subunit. Interestingly, the two fALS-associated SFPQ variants do not directly contribute to altering AMPAR subunit composition in neurons per se given that their effects are indistinguishable from those that express SFPQ WT.

ALS-associated alterations in AMPAR subunit composition can occur due to dysregulation of GRIA transcripts or inefficient RNA editing of GRIA2 mRNA that affects AMPAR permeability to Ca²⁺ [39, 52]. However, we posit that cytoplasmic SFPQ aggregates are likely to perturb the trafficking of GluA1-containing AMPARs in primary neurons. Our hypothesis is supported by the fact that SFPQ is present in AMPAR-containing vesicles purified from mouse whole brain lysates [53], and the demonstration that it also interacts with the motor protein KIF5 [11], which has previously been shown to regulate the dendritic transport of such vesicles [54-57]. Importantly, mutations in the KIF5A C-terminal cargo binding domain are associated with fALS [58, 59]. This highlights that disruption in KIF5- mediated transport of not only RNA granules but also neurotransmitter receptors contributes to the pathogenesis of ALS. Although our findings are consistent with the general idea of a perturbation of AMPAR subunit expression as a feature of ALS pathology, cytoplasmic SFPQ aggregates may not cause an increase in the expression of GluA2-lacking Ca²⁺-permeable AMPARs, at least in cortical neurons, that are thought to mediate the excessive Ca²⁺ influx and death of motor neurons [50, 60, 61]. However, it remains to be determined whether a similar effect is observed in motor neurons, given that the heterogeneity of AMPAR subunit expression has been observed in different regions of the brain and might be dependent on genetic causes of the disease [47].

In conclusion, our current study provides the structural basis to explain the high propensity of fALS-associated SFPQ variants to form cytoplasmic aggregates through enhanced zinc-binding affinity, leading to a loss in SFPQ function in neurons. Although, it is well established that genetic variants (familial or sporadic) are the main components that predispose (or cause) an individual to develop ALS [62], the molecular mechanisms underlying pathogenesis and disease progression are likely to differ, depending on the mutations. The SOD1 gene, which encodes the Cu²⁺/Zn²⁺ superoxide dismutase 1 that protects neurons from oxidative stress, is often mutated in fALS patients. Mechanistically, ALS-associated mutations alter the metal binding capacity of SOD1, leading to protein misfolding and aggregation. Accordingly, delivering zinc to mutant SOD1 exerts protective therapeutic effects in the SOD1-G37R ALS mouse model [63]. On the contrary, our findings predict that zinc supplementation would exacerbate SFPQ aggregation and therefore have negative impacts on neuronal function in patients carrying the N533H or L534I mutation. Thus, the outcomes of our study highlight the potential importance of personalized medicine – different mutations may require different interventions – in the treatment of ALS patients with distinct genetic variants.