Abstract
Aberrantly expressed fused in sarcoma (FUS) is a hallmark of FUS-related amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Wildtype FUS localises to synapses and interacts with mitochondrial proteins while mutations have been shown to cause to pathological changes affecting mitochondria, synapses and the neuromuscular junction (NMJ). This indicates a crucial physiological role for FUS in regulating synaptic and mitochondrial function that is currently poorly understood. In this paper we provide evidence that mislocalised cytoplasmic FUS causes mitochondrial and synaptic changes and that FUS plays a vital role in maintaining neuronal health in vitro and in vivo. Overexpressing mutant FUS altered synaptic numbers and neuronal complexity in both primary neurons and zebrafish models. The degree to which FUS was mislocalised led to differences in the synaptic changes which was mirrored by changes in mitochondrial numbers and transport. Furthermore, we showed that FUS co-localises with the mitochondrial tethering protein Syntaphilin (SNPH), and that mutations in FUS affect this relationship. Finally, we demonstrated mutant FUS led to changes in global protein translation. This localisation between FUS and SNPH could explain the synaptic and mitochondrial defects observed leading to global protein translation defects. Importantly, our results support the ‘gain-of-function’ hypothesis for disease pathogenesis in FUS-related ALS.
Similar content being viewed by others
Introduction
Amyotrophic Lateral Sclerosis (ALS) and Frontotemporal Dementia (FTD) are both fatal neurodegenerative diseases which show a large degree of clinical, pathological and genetic overlap between patients1. Mutations in Fused in sarcoma (FUS) are found in 5% of ALS patients while pathological FUS aggregates are found in 10% of FTD patients2,3,4. The majority of FUS mutations reside within the C-terminus of the protein which contains the nuclear localising signal (NLS) and is essential for FUS to traffic between the nucleus and cytoplasm5,6,,6. Under physiological conditions, FUS is a predominately nuclear protein which has a role in RNA processing7. However, a growing body of evidence has shown that FUS has an essential cytoplasmic role in neurons involved in transport and local protein translation, especially at the synapse. FUS has been shown to be located at both the pre- and post-synapse8,9,,9 as well as interacting with GluA1, the AMPA receptor subunit, which is a post-synaptic protein10. Evidence points towards FUS being essential for dendritic reorganisation by regulating synaptic mRNAs11,12,,12 with FUS depletion leading to a decrease in GluA1 expression resulting in supressed synaptic transmission and changes in synaptic maturation10. Notably, FUS has been implicated in the regulation of splicing and the transcription of synaptic mRNAs which could be involved in local translation at the synapse13,14,,14. Mutations in the NLS lead to varying levels of accumulated mutant FUS in neuron terminals and have been shown to cause significant hypomethylation of arginine’s which decreases new protein synthesis15. Therefore, accumulating evidence points towards FUS having a vital cytoplasmic role for mRNA transport within axons and dendrites to facilitate local translation at the synapse16. However, how mutated cytoplasmic FUS contributes to synaptic degeneration still needs to be elucidated.
Mitochondria are essential for synaptic plasticity, spine development and general neuronal function with ATP demand being correlated to synaptic integrity within a dendrite17. The pathogenesis of numerous neurodegenerative diseases, including ALS, has been associated with mitochondrial dysfunction and demonstrates that mitochondrial function is essential for maintaining neuronal integrity18,19,20. In ALS specifically, there is accumulating evidence in both mouse and Drosophila models that degeneration of the NMJ, accompanied by mitochondrial abnormalities, is an early pre-symptomatic disease event21,22,23,24,25 FUS has been shown to interact with mitochondrial proteins (HSP60; ATP synthase β-subunit) and mutations in FUS which increase cytoplasmic FUS have been associated with mitochondrial fragmentation within neurons26,27,,27. Additionally, it has been shown that a subset of FTD patients show an increase in FUS expression within damaged mitochondrial cristae27. It is therefore clear that healthy mitochondria are essential for synaptic functioning in the context of ALS, however the involvement of FUS is relatively unknown.
Here, we report in vitro and in vivo evidence that overexpression of mutant FUS causes differential synaptic defects which appear to depend on the level of mislocalised cytoplasmic FUS. Additionally, we have provided evidence for a relationship between synaptic and mitochondrial abnormalities due to mutant FUS by identifying a novel interaction between FUS and the mitochondrial anchor protein, syntaphilin (SNPH) which is essential for synaptic maintenance. These results indicate that FUS is intricately involved in synaptic and mitochondrial functioning and that the degree of mislocalised FUS can lead to specific abnormalities which contribute to neurodegeneration.
Results
FUS is enriched at, and colocalises with pre- and post-synapses in rat primary neurons
To investigate whether FUS was localised to the synapse, we performed immunocytochemistry using rat primary cortical neurons to co-stain for endogenous FUS and pre- and post-synaptic markers. Neurons were aged to DIV21 to ensure expression of both pre- and post-synaptic markers. Besides its expected localisation within the nucleus, FUS was also localised within puncta in neurites (Fig. 1). FUS colocalised with 75% of synaptophysin puncta (Fig. 1A, SYN, pre-synaptic) and 50.25% of post synaptic density-95 (Fig. 1B, PSD-95) puncta. This indicates that FUS is present on both sides of synaptic buttons with a preferential localisation for the pre-synapse at DIV21 (p < 0.05).
Mutant FUS leads to alterations at the synapse
To investigate whether mutations in FUS affected the synapse, we over-expressed two different mutant forms of FUS in primary neurons. R514G is an NLS point mutation originally identified by us in 2009 in a British Family and replicated in German ALS patients that results in a moderate increase of cytoplasmic FUS in cell culture models (FUSR514G)2,6,28. Secondly, we created a truncation mutation (K510X) that results in the loss of the entire NLS from the C-terminus of the protein showing a predominantly cytoplasmic localisation (FUSΔNLS)6. These two contrasting mutations allow us to investigate mild and severe variants of FUS mutations to determine whether the degree of mislocalisation affects the observed phenotype. eGFP-FUSWT, eGFP-FUSR514G and eGFP-FUSΔNLS were transfected into DIV6 rat primary neurons alongside control eGFP-only to investigate if a change in pre-synaptic SYN puncta was observed (Fig. 2). Quantification of the expression of the plasmids suggests all are expressed at the similar levels (Fig. S1). As expected eGFP-FUSWT was predominantly nuclear whilst the mutant proteins misclocalised to the cytoplasm (Fig. 2A). There was no significant difference in the number of SYN puncta between the control and eGFP-FUSWT conditions indicating that transfection of eGFP-FUSWT did not influence the number of SYN puncta (Fig. 2C). However, there was a significant increase in the number of SYN puncta of the neurons in the eGFP-FUSR514G compared to eGFP-FUSWT (p < 0.05) and a significant decrease in the number of SYN puncta expressing eGFP-FUSΔNLS compared to eGFP-FUSWT (p < 0.001) suggesting potentially different effects of the two mutations (Fig. 2C). Secondly, as mutant FUS has been shown to affect dendritic branching in mouse models, an analysis of this was undertaken by analysing the MAP2 staining of transfected neurons16. This showed that only transfection of eGFP-FUSΔNLS led to a significant decrease in the ability to grow dendritic branches compared to the control (Fig. 2B,D,E).
We also investigated if a similar effect would occur on the post-synaptic side by staining for the common post synaptic marker PSD-95. DIV14 Rat primary neurons were transduced with either HA-FUSWT, HA-FUSR514G or HA-FUSΔNLS before being grown to DIV21 to ensure full development of the post synapse (Fig. 3A). As we observed with the pre-synaptic side, expression of HA-FUSR514G resulted in a significant increase in PSD-95 puncta when compared to HA-FUSWT (p < 0.05), whilst HA-FUSΔNLS led to a significant reduction in PSD-95 puncta compared to wildtype (p < 0.001) (Fig. 3A,C). In this case transduction of either WT or mutant FUS led to a reduction in branching compared to the control at this stage (Fig. 3B,D,E). This suggests that perhaps any increase in FUS, in this case by overexpression, may lead to synaptic disruption.
Mutant FUS affects the NMJ in zebrafish
To investigate whether synaptic changes were also seen in an in vivo model, we developed a transient transgenic approach in zebrafish to visualise and temporally monitor the motor neuron. In our model, expression of GFP-tagged FUS was driven by an mnx1 promoter which has previously been shown to drive expression in motor and interneurons of the zebrafish spinal cord29,30. This novel model results in expression of eGFP-FUS in a single motor neuron per injection and therefore we have used it to assess neuronal morphology and not behaviour. However, previous zebrafish models have shown a link between expression of mutant FUS and impaired locomotor activity due to synaptic changes31,32. We used the Gal4/UAS system to express eGFP-FUSWT, eGFP-FUSR514G and eGFP-FUSΔNLS to explore changes specifically in ventrally innervating primary motor neurons. Previous data has shown that FUS is abundant at the NMJ and that denervation of the NMJ is an early pathological hallmark of ALS-FUS22,33. Therefore, we sought to establish whether mutant FUS disrupted the formation of the NMJ. Zebrafish co-injected with MNX1:Gal4 and either UAS: eGFP-FUSWT, UAS: eGFP-FUSR514G or UAS: eGFP-FUSΔNLS, were fixed and stained for the pre-synaptic NMJ marker SV2 and the post-synaptic NMJ marker alpha-bungarotoxin (αBTX) at 2 days post fertilisation (Fig. 4). We observed a significant reduction in the number of BTX and SV2 puncta in cells expressing eGFP-FUSR514G (p < 0.05) and eGFP-FUSΔNLS (p < 0.05) compared to eGFP-FUSWT (Fig. 4B). Furthermore, investigation into the degree of colocalization between BTX and SV2 showed a significant reduction for both eGFP-FUSR514G (p < 0.05) and eGFP-FUSΔNLS (p < 0.0001) compared to eGFP-FUSWT (Fig. 4B).
Following our discovery that the different mutations in FUS led to substantial synaptic defects, we sought to investigate the extent of the developmental defect of the misexpressing caudal primary motor neuron. Expression of MNX-specific eGFP-FUSR514G or eGFP-FUSΔNLS resulted in a reduction in the length of the primary motor axon expressing eGFP-FUS when compared to eGFP-FUSWT (Fig. 5A,B). Interestingly, this reduction only reached statistical significance in the ΔNLS mutant (p < 0.05, Fig. 5A,B). However, the expression of either mutants led to significant decreases in the number of secondary and tertiary branches that expressed eGFP-FUS. There was a significant reduction in secondary motor neuron branches in both the eGFP-FUSR514G (p < 0.05) and eGFP-FUSΔNLS (p < 0.001) expressing zebrafish when compared to eGFP-FUSWT (Fig. 5B). Whilst there are never large numbers of tertiary branches (eGFP control averaged only 4 tertiary branches), eGFP-FUSWT motor neurons expressing cells presented an average of 2.83 tertiary branches per axon whilst none were detected in any analysed motor neurons expressing eGFP-FUSR514G or eGFP-FUSΔNLS (Fig. 5A,B). This may indicate a delay in branching in neurons expressing higher levels of cytoplasmic FUS or as we are measuring the extent of the eGFP signal, rather than a neuronal marker in the motor neurons, this may reflect the extent to which mutant eGFP-FUS is transported in the motor axons. Subsequently, we sought to confirm this change in eGFP-FUS expressing axonal complexity in this in vivo system by using sholl analysis (Fig. 5C,D). This demonstrated that axonal branching was significantly reduced within primary motor neurons in both eGFP-FUSR514G (p < 0.05–0.001) and eGFP-FUSΔNLS (p < 0.05–0.0001) expressing motor neurons compared to eGFP-FUSWT (Fig. 5C,D).
Mutant FUS affects neuronal mitochondria
We have previously shown that alterations to the morphology and a reduction in the number of mitochondria are very early disease events in a mouse model of ALS-FUS22. We proceeded to investigate if alterations to mitochondria could explain the observed in vitro and in vivo synaptic effects caused by mutant FUS. To do this we co-transfected rat primary neurons with eGFP, eGFP-FUSWT, eGFP-FUSR514G or eGFP-FUSΔNLS together with DS-MitoRed, which localises to mitochondria and investigated the number and size of mitochondria within the neurites of individual neurons (Fig. 6). In the eGFP-FUSR514G cells, there was a non-significant increase in the number of mitochondria compared to eGFP-FUSWT expressing neurons (p = 0.12) whilst in eGFP-FUSΔNLS there was a significant loss of mitochondria compared to eGFP-FUSWT (p < 0.01) (Fig. 6A,B). To investigate the health of the mitochondria we investigated morphological defects by assessing the size of the mitochondria themselves. Whilst there was no difference in size when comparing eGFP-FUSΔNLS to eGFP-FUSWT neurons (p > 0.99), there was a striking increase in the average size of the mitochondria in cells transfected with eGFP-FUSR514G compared to eGFP-FUSWT (p < 0.05) (Fig. 6A,C). To investigate whether this affected mitochondrial transport, live imaging of the mitochondria in the transfected neurons was performed (Fig. 7A). An analysis of the overall motility of mitochondria in the transfected cells showed that there was a significant reduction in movement when eGFP-FUSWT was transfected compared to the eGFP only control (Fig. 7B, p < 0.01). The presence of the eGFP-FUSΔNLS mutant led to an even greater reduction (Fig. 7B, p < 0.01) in the overall motility of mitochondria compared to any other condition. However, in contrast, there was a non-significant increase in movement in the eGFP-FUSR514G transfected neurons (Fig. 7B, p = 0.34). To determine whether there were directional differences in the motility of the mitochondria, we analysed the anterograde or retrograde movement separately. Whilst both eGFP-FUSWT and eGFP-FUSR514G showed reduced anterograde movement compared to the eGFP control (Fig. 7C, p < 0.05), there was an even greater loss of movement in the eGFP-FUSΔNLS mutant (Fig. 7C, p < 0.0001). Furthermore, when assessing retrograde movement there was no difference when comparing eGFP-FUSWT to the eGFP control (Fig. 7C, p = 0.66). There was however a significant increase when comparing eGFP-FUSR514G to eGFP-FUSWT or eGFP control conditions (Fig. 7C, p < 0.05). As with the anterograde movement, the presence of eGFP-FUSΔNLS resulted in almost no retrograde transport of mitochondria. Further we analysed the duration of the mitochondrial movement in each condition. In the anterograde direction that there is a slight reduction in the average length of mitochondrial movements when comparing eGFP-FUSR514G to eGFP-FUSWT (p = 0.9) and a significant decrease when comparing eGFP-FUSΔNLS to eGFP-FUSWT (p = 0.002). In contrast, there is a slight increase in the average duration of each mitochondrial movement in the retrograde direction when comparing eGFP-FUSR514G to eGFP-FUSWT (p = 0.77) which matches the increased motility seen. As expected, there is a significant decrease in the duration of mitochondrial movement when comparing eGFP-FUSΔNLS to eGFP-FUSWT (p = 0.01) which fits with the almost stationary mitochondria seen in this condition. Interestingly our results demonstrate a striking mitochondrial phenotype for each respective mutation as FUSΔNLS leads to a reduction in mitochondria and a complete loss of mitochondrial movement whereas FUSR514G appears to lead to more swollen mitochondria which are more frequently moving towards the soma.
FUS localises with the mitochondrial anchor, syntaphilin (SNPH)
We next examined if FUS interacted with mitochondrial proteins directly which could explain these effects of mutant FUS. We specifically looked at Syntaphilin (SNPH) due to its significant role in mitochondrial anchoring and its relationship to the synapse34,35,,35. In order to confirm that SNPH was localised to mitochondria, we used super resolution microscopy (iSIM) to investigate the co-localisation of endogenous SNPH and a mitochondrial marker, TOM-20. This showed that TOM20 puncta colocalised with ~ 80% of SNPH (Fig. S2). Next, we investigated the localisation of endogenous FUS and SNPH within neurons. Results indicate that both FUS and SNPH form puncta in the soma and neurite and that FUS puncta colocalised with ~ 72% of SNPH (Fig. 8A). In order to determine whether FUS and SNPH more closely interacted, we used a Proximity Ligation Assay (PLA) which detects protein–protein interactions which are < 40 nm apart. PLA indicated that FUS was in close proximity to SNPH (Fig. 8B,C) and that a stronger localisation was found in the soma when compared to neurites (Fig. 8B,C, p < 0.0001).
Mutant FUS leads to changes in interactions with SNPH
Having shown that FUS co-localises with SNPH, we investigated whether overexpression of WT and mutant FUS would change the FUS-SNPH localisation pattern as mutations in FUS are known to alter interactions with mitochondrial proteins such as HSP60 and ATP5B25,26,,26. HA-FUSWT, HA-FUSR514G and HA-FUSΔNLS were transfected into rat primary neurons, along with eGFP-SNPH to ensure there was sufficient signal from both proteins, and a PLA was performed (Fig. 9 and Fig. S3). PLA indicated that there was a significant co-localisation between HA-FUSWT and eGFP-SNPH and this was predominantly focused in the soma. The presence of HA-FUSR514G led to a significant decrease in FUS-SNPH co-localisation when compared to HA- FUSWT (Fig. 9, p < 0.01) which correlates with the increased movement of mitochondria seen with the R514G mutant. Surprisingly though there was no alteration of HA-FUSΔNLS compared to HA- FUSWT suggesting that although this mutation almost abolishes the movement of mitochondria, it may not be due to an alteration in its potential interaction with SNPH as measured here.
Protein translation is impaired in the presence of mutant FUS
Previously, it has been shown that mutations in FUS reduce axonal protein synthesis36 and so to determine whether we saw a similar phenotype, we investigated whether protein translation was affected in our cellular model. We used the surface sensing of translation (SUnSET) assay in which puromycin, a structural analogue of aminoacyl tRNAs, is incorporated into nascent polypeptides and prevents elongation, allowing us to directly monitor translation37. Primary cortical neurons were transfected with eGFP-FUSWT, eGFP-FUSR514G and eGFP-FUSΔNLS respectively before puromycin treatment and analysed by measuring the intensity within the soma and neurites (Fig. 10A). The presence of eGFP-FUSΔNLS led to a small non-significant decrease in protein translation in the soma when compared to eGFP-FUSWT (Fig. 10B, p = 0.5704). In contrast, eGFP-FUSR514G led to a small increase in translation in the soma when compared to eGFP-FUSWT (Fig. 10B, p = 0.4042). Analysis of the protein synthesis in the neurites showed that there was a similar pattern that this time reached significance in the eGFP-FUSR514G transfected neurons when compared to eGFP-FUSWT (Fig. 10C, p < 0.01) whilst eGFP-FUSΔNLS still showed a small decrease when compared to eGFP-FUSWT (Fig. 10C, p = 0.5704). Interestingly, overexpression of eGPF-FUSWT alone reduced the amount of translation compared to the control which matches previous data regarding mitochondrial movement suggesting that the two processes are closely linked.
Discussion
In this study, we have shown that mutations in FUS led to alterations in synaptic protein expression and reduced the complexity of neurites and axons in vitro and in vivo and that these defects correspond to mitochondrial abnormalities observed in neurites with each respective FUS mutant. More importantly we have generated novel data showing FUS co-localises with the mitochondrial anchor protein SNPH in neurons, and that mutations in FUS alter this. Finally, we show that mutant FUS alters protein translation at the soma and in particular, neurites. Overall, we have presented evidence which supports a possible relationship between synaptic and mitochondrial function and neuronal health in which FUS appears to be a key player. It is well known that neuronal mitochondria are highly dynamic and transported through the neuron to regions of high metabolic demand. Therefore, it is possible that ATP demand is correlated to synaptic integrity within a neuron17 and an increase in mitochondrial number in FUSR514G could explain the observed increase in synapses. Conversely, a decrease in mitochondrial number and therefore ATP, could explain the associated decrease in synapses in FUSΔNLS leading to the degeneration of the neuron. Further, there is evidence in primary cortical neurons that alterations in mitochondrial transport affect synaptic activity indicating that there is a link between mitochondrial and synaptic changes38. Taken together, this data adds to the accumulating body of evidence that FUS plays a role in mitochondrial and synaptic function, and that the level of mislocalised cytoplasmic FUS can lead to varying effects on neuronal function8,26. Future studies into whether mitochondrial physiology is affected by mutations in FUS will help us to understand the relationship between increased cytoplasmic FUS, mitochondrial health and trafficking, and synaptic activity.
One of the more interesting aspects of this work was that specific FUS mutations can lead to different cellular phenotypes in vitro, suggesting that the degree to which FUS is mislocalised can have differential downstream consequences. Even an increase in the amount of wildtype protein was sufficient to cause some cellular phenotypes such as reducing mitochondrial movement. Given that there are ALS patients who have 3’ UTR mutations39 that lead to an increase in wildtype protein and that there are mouse models in which this increase alone is sufficient to cause an ALS like phenotype, it is not a surprise that we see such occurrences. Moreover, when we introduced a mutation that specifically and moderately increases cytoplasmic FUS (FUSR514G), this results in an increase in synapses, and mitochondrial number, size, and speed of axonal transport. Whereas FUSΔNLS, a mutation that results in complete abolishment of the nuclear-localising signal and a very large increase in cytoplasmic FUS, contrasts FUSR514G by demonstrating synaptic and mitochondrial deficit with a complete loss of axonal transport. Patients with truncation mutations suffer from a very young onset and aggressive form of ALS28. In comparison those with a FUSR514G mutation have a later onset and longer form of the disease though this is still often more severe than those with the sporadic form of the disease (2; 5). This suggests that the FUSR514G phenotype might represent an early disease response to the increased cytoplasmic FUS and that the FUSΔNLS phenotype might mimic an aggressive end stage timepoint. It is worth noting that we see different but internally consistent phenotypes in vivo and in vitro for FUSR514G. This may be due to the increased sensitivity of the zebrafish motor neurons to mislocalised cytoplasmic FUS, compared to somewhat more resilient cortical neurons, as assessed in our cell culture studies. This may reflect why motor neurons are selectively vulnerable in disease.
In this study, we showed that each mutation causes significant changes in mitochondrial transport. Mitochondria are transported anterogradely from the soma towards the synapse due to the high metabolic demand34. We show that FUS and SNPH localise together in neurites. This is of importance as SNPH acts as a stable anchor for mitochondria and is essential for synaptic modification and functionality by ensuring the presence of mitochondria near synapses34. Interestingly, neurons overexpressing FUSR514G show a decrease in co-localisation with SNPH within the soma. This observation fits with our data, showing a greater number of motile mitochondria being transported within the neuron in cells transfected with FUSR514G. This altered interaction could explain both the potential increase in mitochondria numbers in the neurite and the increased retrograde transport we observe within our in vitro dataset. It is possible that the neuron is trying to compensate for the excess cytoplasmic FUS and stay functional by taking damaged mitochondria back to the cell body to be degraded40. However, we observed a non-significant decrease in FUS-SNPH co-localisation in neurons expressing FUSΔNLS within the soma and neurite. This suggests that although there is a similar co-localisation pattern when compared to FUSWT, we also showed that there were fewer mitochondria anyway so those that exist could be trapped within the soma or stationary in the neurite and not being transported. This could explain the decrease in mitochondrial transport and the overall number of mitochondria. It is also interesting to note that FUS and another ALS protein, ANXA11, are also found in G3BP1 stress granules linking them to similar cellular functions41,42 In addition, recent work has shown that ANXA11, acts as a link between lysosomes and hnRNP-containing RNA granules for axonal transport41 and it may be that FUS acts as link between RNA and mitochondria in a similar manner.
Our data also confirms previous data showing that mutations in FUS affect protein synthesis36,43. Moreover, translation defects appear to be specific to the degree of mislocalised cytoplasmic FUS depending on the mutation present. As with our previous data, FUSR514G led to an increase in translation in affected soma and neurites whereas FUSΔNLS led to a decrease. Previous reports have demonstrated that mutant FUS interacts with polyribosomes and that a toxic ‘gain of function’ in the cytoplasm affects translation43. Therefore, it is likely that the changes in global translation alongside the mitochondrial abnormalities we observe lead to the synaptic abnormalities exhibited by each specific mutant. It has previously been shown that mitochondria act as a local fuel source and that disruption of these mitochondria affects local translation44. Further mutations in the endosome protein Rab7a, which cause Charcot-Marie-Tooth Disease type 2B, result in altered axonal protein synthesis and trafficking of mitochondria45. This suggests that there are strong links between mitochondrial transport, endosomes and local translation.
We have presented in vivo and in vitro evidence that FUS is essential for maintenance of neuronal health and that specific FUS mutations can cause differing mitochondrial and synaptic disruption, depending on the degree of cytoplasmic mislocalisation. This might explain some previously conflicting reports on the effect of mutations in FUS on neuronal function. Future studies will be needed to better understand the potential interaction between FUS-SNPH to prove if changes in the co-localisation could partially explain the synaptic and mitochondrial defects observed in vitro and in vivo seen here.
Methods
Cell culture
All neuronal culture techniques were performed under sterile conditions. Coverslips were coated with 1% Poly-D-lysine hydrobromide in PBS (Sigma) and incubated at 37 °C overnight and washed with PBS prior to the seeding of rat primary cortical neurons at 70,000 cells/ml in 500 μl/well.
Animal experiments
All animal experiments have been authorised by the KCL ethics Review Committee and under the HO license 70/7577. All animal experiments were performed in accordance with the relevant guidelines and following regulated procedures and all authors complied with the ARRIVE guidelines for animal research. The study is reported in accordance with the ARRIVE guidelines and we have presented all details that allow for accurate follow up including group sizes, age, and detailed experimental procedures for each animal experiment.
DNA transfection
For each transfection, 500 ng DNA was mixed with 1 μl of Lipofectamine 2000 (Invitrogen) in 25 μl of HEPES (Gibco) and DMEM (Gibco) solution per well. Prior to addition of DNA, coverslips were removed and placed in a 350 μl of fresh media (without pen/strep). DNA mix was incubated for 1 h at 37 °C before adding in a drop wise manner to DIV6 neurons. 6–8 h post transfection coverslips were replaced in the old media, before fixation 48 h later.
Viral transduction
Virus was added to rat primary neurons at DIV14 to achieve an infection rate of 1 × 107 virus particles/ml. Following the day of transduction, 250 μl of cortical media was removed and 300 μl of fresh cortical media was added onto the cells before fixation occurred at DIV21.
Immunofluorescence
Primary neurons were fixed in 4% paraformaldehyde for 10 min and then ice cold methanol for 10 min before being probed with selected primary antibodies overnight at 4 °C. Antibodies were used as follows rabbit anti-synaptophysin I (1:300, Synaptic Systems), rabbit anti-FUS (1:300, Sigma), mouse anti-FUS (1:200, Proteintech), mouse anti-PSD95 (1:500, AbCam), mouse anti-HA (1:1000, CoVance), chicken anti-MAP2 (1:1000, AbCam), mouse anti-FUS (H6) (1:200, Santa Cruz), rabbit anti-SNPH (1:200, ProteinTech). Goat anti-rabbit, anti-mouse or anti-chicken Alexaflour 488/564/640 secondary antibodies (1:500, Invitrogen) were added the following day for two hours at room temperature in the dark. DAPI (4ʹ,6-diamidino-2-phenylindole (Sigma) counterstaining (1.25 μg/ml) was added as a nuclear stain before cover slips were mounted.
Quantitative image analysis
Images were taken on a Leica TCS-SP5 laser scanning confocal microscope and imaged at × 63 with a numerical aperture of 1.4 (with a digital zoom of 2.5). Images were taken at 10–14 Z-sacks with 0.5 μm increment before being processed in Image J.
Colocalisation analysis
Images of selected neurites were extracted, and their length (100 μm) was recorded. After splitting each channel, a Gaussian and median filter (with a radius of 10 pixels) was applied to the channel of interest, individually. The median image was subtracted from the Gaussian channel and a threshold was selected. Particles were then analysed from the channel before overlaying puncta onto the other channel of interest to allow measurement of colocalization which was determined by subtracting the area of the overlaid puncta from the under laid puncta (colocalisation was only counted if 50% and over). Analysis was performed on three separate dendrites per cell (N = 9) from three individual experiments at DIV21. All statistical analysis to determine significance between groups was performed using GraphPad Prism 9 using a student’s T-Test.
Analysis of synaptic puncta and mitochondria
Maximum projection images were converted to 8-bit grayscale and individual channels were then used to select the threshold which was kept consistent to the control (eGFP) channel. Puncta and mitochondria were thresholded to be bigger than five pixels in size. Images were obtained from three independent experiments and three dendrites from five different cells were analysed for each repeat for each condition. All statistical analysis to determine significance between groups was performed using GraphPad Prism 9 using a One-Way ANOVA with post-hoc tukey’s multiple comparisons test.
Analysis of dendritic complexity
Maximum projection images of the MAP2 channel were then converted into an 8-bit gray scale image and dendrites were traced using an available plugin (Neuron J). After tracing, sholl analysis was performed to assess dendritic complexity from the soma at 10 μm increments. Sholl analysis is a quantitative measure of the shape and/size of a dendritic tree. To measure dendritic complexity, concentric circles were drawn from the centre of the neuron and the number of times each dendritic branch intersects, branching is assessed (number of intersections divided by area against distance). Traces were analysed from 10 individual cells across three individual experiments per condition. All statistical analysis to determine significance between groups was performed using GraphPad Prism 9 using a Two-Way ANOVA with a post-hoc tukey’s multiple comparisons test which compared the sample effects within each row.
Quantitative image analysis of mitochondrial dynamic using kymographs
Cells were plated in an Ibidi 8 well plate at 50, 000 cell/ml. Following co-transfection with GFP-FUS constructs (250 ng) and a Ds-Mitored plasmid (250 ng) at DIV6, cells were incubated for 48 h before imaging on the Nikon Eclipse Ti Spinning disk confocal microscope at 63X. Images were taken every 30 s over 10 min. Channels were split using Image J and a line was drawn along a dendrite (100 μm), to create a kymograph using an Image J plugin. After a kymograph had been created, individual particles were traced using neuron J plugin on Image J to calculate if a particle moved in a retrograde or anterograde direction. Stationary mitochondria were counted if there was no visible movement of that particle in the kymograph. Mitochondrial dynamics were performed on a single dendrite from eight individual cells across three individual experiments per condition. All statistical analysis to determine significance between groups was performed using GraphPad Prism 9 using a One-Way ANOVA with post-hoc tukey’s multiple comparisons test.
Proximity ligation assay
Proximity ligation assays (PLAs) were performed essentially as the manufacture instructions (Sigma-Aldrich). Briefly, neurons were fixed in 4% paraformaldehyde in PBS and probed with mouse anti-FUS (1:200, Proteintech) and anti-SNPH (1:200, Proteintech), and signals developed using a Duolink In Situ Orange kit (Sigma-Aldrich). Following PLAs, neurons were immunolabeled for chicken anti-MAP2 (1:1000, AbCam). Images were taken at × 60 (oil) on a Nikon Ti-E Two Camera microscope. Images were analysed in ImageJ and positive puncta counted using the cell counting tool. Five somas for each image were analysed for the soma count and 3 different neurites for each of five cells per image were analysed with three biological replicates carried out.
Puromycin assay
Following transfection of DIV6 neurons as previously described, neurons were treated with 1 mL/well of 1 × ACSF (10 × ACSF with H2O, Glucose 11 mM and HEPES 5 mM), MgCl2 1.25 mM and CaCl2 mM (pH 7.4) at DIV8. Following a 1-h incubation, 5μL of puromycin (P8833, 10 mg/mL, Sigma Aldrich) was added to each well. After 10 min, cells were fixed and immunostained with mouse anti-puromycin (1:1000, 3RH11, Kerafast) and chicken anti-MAP2 (1:1000, AbCam). Images were taken with a Nikon iSIM super resolution microscope at × 100 (oil) objective. Puromycin puncta were thresholded to be bigger than five pixels in size and average intensity was calculated. Images were obtained from three independent experiments and five different somas and neurites were analysed for each repeat for each condition and values were normalised to threshold. All statistical analysis to determine significance between groups was performed using GraphPad Prism 9 using a One-Way ANOVA with post-hoc tukey’s multiple comparisons test.
Fish stock maintenance, husbandry and embryo collection
All Danio rerio lines were raised and maintained at 28 °C on a 14 h light/ 10 h dark cycle in the Guy’s Campus Zebrafish facility, London. Embryos were collected and incubated in dishes filled with system water with methylene blue in a 28 °C incubator until experimentation. Morphological staging was used to determine embryo development46.
Microinjection procedure
To deliver the plasmid into individual embryos, 1 mm single capillary needles with filament (world precision instruments) were pulled on a model P-97 flaming/brown micropipette puller (Sutter instrument Co.). Once the micropipette was created, 2.8 μl of plasmid was taken up and attached to manual micromanipulator apparatus. 0.5 nl of plasmid solution (50 ng/μl) was measured on a graticule (Pyser-SGI) and injected into a 1-cell stage embryo using the Picospritzer 111 microinjector (Parker instrumentation).
UAS: eGFP-FUS constructs
Homologous sticky-end restriction sites were used (PciI and NheI) to allow insertion of the UAS promoter. Initially, both the pN2 5UAS eGFP and the pC1 CMV eGFP-FUS were digested with PciI (NEB). Following digestion, each digested plasmid was purified and then digested with NheI (NEB). After each plasmid had been digested with both enzymes, the UAS insert and eGFP vector were gel extracted, and gel purified (Qiagen) before being ligated and transformed into competent cells (NEB). UAS: eGFP-FUSWT and eGFP-FUSR514G and eGFP-FUSΔNLS constructs were microinjected at 25 ng/μl along with 25 ng/μl of MNX1:Gal4 plasmid.
Immunofluorescence
2-day post fertilisation (Long pec) embryos were fixed and, if needed, stained overnight with primary antibody mouse anti-SV2 (1:100, DSHB) followed by overnight staining with alexa-555 conjugated anti-alpha Bungarotoxin (1:100, Invitrogen) and alexa-conjugated goat anti-mouse (1:1000, Invitrogen).
Morphological analysis of motor neurons
Images were taken on a Nikon Eclipse C1 confocal microscope using a × 40 water objective (N.A. 0.8). Images were based on eGFP expression and z-stacks taken at 1 μm increments. Maximum projection images of the eGFP channel were converted into an 8-bit gray scale image and axons were traced using an available plugin on Image J (Neuron J). After tracing, sholl analysis was performed to assess dendritic complexity from the soma at 10 μm increments. To measure axonal length and branch numbers, axonal branches that were 0.5 μm and larger were included in the axonal branching analysis. Neurons were obtained from six independent experiments and six axons of each condition were chosen. All statistical analysis to determine significance between groups was performed using GraphPad Prism 9 using a One-Way ANOVA with post-hoc tukey’s multiple comparisons test, unless otherwise stated.
Quantification of synaptic density and colocalisation
Z-sacks images with 1 μm increment which were obtained using a × 40 oil objective (N.A. 1.3) and obtained on the Zeiss Axio Imager Z2 LSM 800 Confocal. Maximum projection images were converted to 8-bit gray-scale in Image J and individual channels were then used to select the threshold which was kept consistent to the control (eGFP) channel. Following imaging, selected axons were extracted and their length was recorded (which allowed calculation of density). Colocalisation analysis was performed as for the rat primary neuron analysis. Analysis was performed on six separate axons from six biological replicates. All statistical analysis to determine significance between groups was performed using GraphPad Prism 9 using a One-Way ANOVA with post-hoc tukey’s multiple comparisons test.
Data availability
The datasets used and analysed during the current study are available from the corresponding author on reasonable request. Representative is presented and all data analysed during this study are included in this published article [and its supplementary information files].
Abbreviations
- ALS:
-
Amyotrophic lateral sclerosis
- ALS-FUS:
-
ALS-associated FUS
- FTD:
-
Frontotemporal dementia
- FUS:
-
Fused in sarcoma
- NLS:
-
Nuclear localising signal
- NMJ:
-
Neuromuscular junction
- SNPH:
-
Syntaphilin
- SYN:
-
Synaptophysin
- PSD-95:
-
Post-synaptic density 95
- BTX:
-
Bungarotoxin
- SV2:
-
Synaptic vesicle 2
- PLA:
-
Proximity ligation assay
References
Henstridge, C. M. et al. Synapse loss in the prefrontal cortex is associated with cognitive decline in amyotrophic lateral sclerosis. Acta Neuropathol. 135, 213–226 (2017).
Vance, C. et al. Mutations in FUS, an RNA processing protein, cause familial amyotrophic lateral sclerosis type 6. Science 323(5918), 1208–1211 (2009).
Kwiatkowski, T. J. et al. Mutations in the FUS/TLS gene on chromosome 16 cause familial amyotrophic lateral sclerosis. Science [Internet]. 323(5918), 1205–1208 (2009).
Neumann, M. et al. A new subtype of frontotemporal lobar degeneration with FUS pathology. Brain 132(11), 2922–2931 (2009).
Dormann, D. et al. ALS-associated fused in sarcoma (FUS) mutations disrupt transportin-mediated nuclear import. EMBO J. 29(16), 2841–2857 (2010).
Vance, C. et al. ALS mutant FUS disrupts nuclear localization and sequesters wild-type FUS within cytoplasmic stress granules. Hum. Mol. Genet. 22(13), 2676–2688 (2013).
Van, B. M. & Landers, J. E. RNA processing pathways in amyotrophic lateral sclerosis. Neurogenetics 11, 275–290 (2010).
Schoen, M. et al. Super-resolution microscopy reveals presynaptic localization of the ALS/FTD related protein FUS in hippocampal neurons. Front. Cell. Neurosci. https://doi.org/10.3389/fncel.2015.00496 (2016).
Deshpande, D. et al. Synaptic FUS localization during motoneuron development and its accumulation in human ALS synapses. Front. Cell. Neurosci. https://doi.org/10.3389/fncel.2019.00256 (2019).
Udagawa, T. et al. FUS regulates AMPA receptor function and FTLD/ALS-associated behaviour via GluA1 mRNA stabilization. Nat. Commun. https://doi.org/10.1038/ncomms8098 (2015).
Fujii, R. TLS facilitates transport of mRNA encoding an actin-stabilizing protein to dendritic spines. J. Cell Sci. 118(24), 5755–5765 (2005).
Belly, A., Moreau-Gachelin, F., Sadoul, R. & Goldberg, Y. Delocalization of the multifunctional RNA splicing factor TLS/FUS in hippocampal neurones: Exclusion from the nucleus and accumulation in dendritic granules and spine heads. Neurosci. Lett. 379(3), 152–157 (2005).
Liu-Yesucevitz, L. et al. Local RNA translation at the synapse and in disease. J. Neurosci. 31, 16086–16093 (2011).
Shigeoka, T. et al. Dynamic axonal translation in developing and mature visual circuits. Cell 166, 181–192 (2016).
Qamar, S. et al. FUS phase separation is modulated by a molecular chaperone and methylation of arginine cation-π interactions. Cell 173(3), 720–734 (2018).
Sephton, C. F. et al. Activity-dependent FUS dysregulation disrupts synaptic homeostasis. Proc. Natl. Acad. Sci. 111(44), E4769–E4778 (2014).
Todorova, V. & Blokland, A. Mitochondria and synaptic plasticity in the mature and aging nervous system. Curr. Neuropharmacol. 15, 166–173 (2016).
Wang, X. et al. Impaired balance of mitochondria fission and fusion in Alzheimer disease. J. Neurosci. 29(28), 9090–9103 (2009).
Hunt, R. J. & Bateman, J. M. Mitochondrial retrograde signaling in the nervous system. FEBS Lett. 592, 663–678 (2018).
Martinez-Vicente, M. Neuronal mitophagy in neurodegenerative diseases. Front. Mol. Neurosci. https://doi.org/10.3389/fnmol.2017.00064 (2017).
Rogers, R. S. et al. Impaired mitophagy plays a role in denervation of neuromuscular junctions in ALS mice. Front. Neurosci. https://doi.org/10.3389/fnins.2017.00473 (2017).
So, E. et al. Mitochondrial abnormalities and disruption of the neuromuscular junction precede the clinical phenotype and motor neuron loss in hFUSWT transgenic mice. Hum. Mol. Genet. 27(3), 463–474 (2018).
Sharma, A. et al. ALS-associated mutant FUS induces selective motor neuron degeneration through toxic gain of function. Nat. Commun. https://doi.org/10.1038/ncomms10465 (2016).
Shahidullah, M. et al. Defects in synapse structure and function precede motor neuron degeneration in drosophila models of FUS-related ALS. J. Neurosci. 33(50), 19590–19598 (2013).
Hayes, L. R. et al. Distal denervation in the SOD1 knockout mouse correlates with loss of mitochondria at the motor nerve terminal. Exp. Neurol. 318, 251–257 (2019).
Deng, J. et al. FUS interacts with ATP synthase beta subunit and induces mitochondrial unfolded protein response in cellular and animal models. Proc. Natl. Acad. Sci. U.S.A. 115, E9678–E9686 (2018).
Deng, J. et al. FUS interacts with HSP60 to promote mitochondrial damage. PLoS Genet. 11(9), e1005357 (2015).
Waibel, S. et al. Truncating mutations in FUS/TLS give rise to a more aggressive ALS-phenotype than missense mutations: A clinico-genetic study in Germany. Eur. J. Neurol. 20(3), 540–546 (2013).
Svahn, A. J. et al. Nucleo-cytoplasmic transport of TDP-43 studied in real time: Impaired microglia function leads to axonal spreading of TDP-43 in degenerating motor neurons. Acta Neuropathol. 136(3), 445–459 (2018).
Zelenchuk, T. A. & Brusés, J. L. In vivo labeling of zebrafish motor neurons using an mnx1 enhancer and Gal4/UAS. Genesis 49, 546–554 (2011).
Armstrong, G. A. B. & Drapeau, P. Loss and gain of FUS function impair neuromuscular synaptic transmission in a genetic model of ALS. Hum. Mol. Genet. 22(21), 4282–4292 (2013).
Bourefis, A. R., Campanari, M. L., Buee-Scherrer, V. & Kabashi, E. Functional characterization of a FUS mutant zebrafish line as a novel genetic model for ALS. Neurobiol. Dis. 142, 104935 (2020).
Picchiarelli, G. et al. FUS-mediated regulation of acetylcholine receptor transcription at neuromuscular junctions is compromised in amyotrophic lateral sclerosis. Nat. Neurosci. 22, 1793–1805 (2019).
Kang, J. S. et al. Docking of axonal mitochondria by syntaphilin controls their mobility and affects short-term facilitation. Cell 132, 137–148 (2008).
Vaccaro, V., Devine, M. J., Higgs, N. F. & Kittler, J. T. Miro1-dependent mitochondrial positioning drives the rescaling of presynaptic Ca 2+ signals during homeostatic plasticity. EMBO Rep. 18, 231–240 (2017).
López-Erauskin, J. et al. ALS/FTD-linked mutation in FUS suppresses intra-axonal protein synthesis and drives disease without nuclear loss-of-function of FUS. Neuron 2, 2 (2018).
Schmidt, E. K., Clavarino, G., Ceppi, M. & Pierre, P. SUnSET, a nonradioactive method to monitor protein synthesis. Nat. Methods. 2, 2 (2009).
Chang, D. T. W., Honick, A. S. & Reynolds, I. J. Mitochondrial trafficking to synapses in cultured primary cortical neurons. J. Neurosci. 26(26), 7035–7045 (2006).
Sabatelli, M. et al. Mutations in the 3′ untranslated region of FUS causing FUS overexpression are associated with amyotrophic lateral sclerosis. Hum. Mol. Genet. 22(23), 4748–4755 (2013).
Lovas, J. R. & Wang, X. The meaning of mitochondrial movement to a neuron’s life. Biochim. Biophys. Acta Mol. Cell Res. 1833(1), 184–194 (2013).
Liao, Y. C. et al. RNA granules hitchhike on lysosomes for long-distance transport, using annexin A11 as a molecular tether. Cell 179(1), 147–164 (2019).
Markmiller, S. et al. Context-dependent and disease-specific diversity in protein interactions within stress granules. Cell 172(3), 590–604 (2018).
Sévigny, M. et al. FUS contributes to mTOR-dependent inhibition of translation. J. Biol. Chem. 295, 18459–18473 (2020).
Rangaraju, V., Lauterbach, M. & Schuman, E. M. Spatially stable mitochondrial compartments fuel local translation during plasticity. Cell 176, 73–84 (2019).
Cioni, J. M. et al. Late endosomes act as mRNA translation platforms and sustain mitochondria in axons. Cell 176, 56–72 (2019).
Kimmel, C. B., Ballard, W. W., Kimmel, S. R., Ullmann, B. & Schilling, T. F. Stages of embryonic development of the zebrafish. Dev. Dyn. 203(3), 253–310 (1995).
Acknowledgements
The authors would like to thank Dr George Chenell at the Wohl Cellular Imaging Centre (Institute of Psychiatry, Psychology and Neuroscience, King’s College London) for their help with training and image acquisition. We thank Zuhang Sheng (National Institute of Health, Bethesda) for the kind gift of the SNPH constructs.
Funding
This work was funded by the following: King’s College London Studentship (CV), Motor Neuron Disease Association (CV, JCM), Medical Research foundation UK (BNS), The Van Geest Foundation (BNS, JCM), MRC (CH- MR/T033126/1).
Author information
Authors and Affiliations
Contributions
S.S. performed zebrafish and neuronal experiments. S.T. performed P.L.A. and puromycin assays. S.S., C.V. and J.C.M. conceived and designed the experiments and directed the primary neuron work whilst C.H., N.N. and B.N.S. oversaw the zebrafish work. E.G. provided the rat primary neurons for the experiments. All authors edited the manuscript. All authors read and approved the final manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Salam, S., Tacconelli, S., Smith, B.N. et al. Identification of a novel interaction of FUS and syntaphilin may explain synaptic and mitochondrial abnormalities caused by ALS mutations. Sci Rep 11, 13613 (2021). https://doi.org/10.1038/s41598-021-93189-6
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-021-93189-6
- Springer Nature Limited
This article is cited by
-
Aberrant protein aggregation in amyotrophic lateral sclerosis
Journal of Neurology (2024)
-
Neuronal dysfunction caused by FUSR521G promotes ALS-associated phenotypes that are attenuated by NF-κB inhibition
Acta Neuropathologica Communications (2023)
-
Nutritional and metabolic factors in amyotrophic lateral sclerosis
Nature Reviews Neurology (2023)
-
Zebrafish as a Model Organism for Studying Pathologic Mechanisms of Neurodegenerative Diseases and other Neural Disorders
Cellular and Molecular Neurobiology (2023)