Establishing cellular models of TDP-43 proteinopathy

Stable cellular models of ALS and FTD based on doxycycline (DOX)-inducible expression of various TDP-43 constructs (Fig. 1A) were generated in human neuroblastoma (SH-SY5Y) cells and human embryonic kidney (HEK293) cells. In both cell types, and in agreement with previous reports, after induction with 1 µg/ml DOX, HA-tagged wild-type (WT) TDP-43 was predominantly partial nuclear, TDP-43 with a deleted nuclear localisation sequence (ΔNLS) was both nuclear and cytoplasmic, and a C-terminal fragment of TDP-43 (amino acids 181–414; CTF) was predominantly cytoplasmic (Fig. 1B,C). The partial nuclear localisation of ΔNLS TDP-43 is likely to be due to its dimerisation with endogenous TDP-43, leading to co-import. Stable SH-SY5Y and HEK293 lines expressing enhanced GFP (EGFP)-tagged TDP-43 WT, ΔNLS and CTF recapitulated these localisation profiles. The expression of TDP-43 in both SH-SY5Y and HEK293 lines was dependent on the dose of DOX (Fig. 1D,E, EC₅₀; HEK293, 0.97 ng/ml; SH-SY5Y, 0.35 ng/ml).

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Fig. 1.

Establishing cellular models of TDP-43 proteinopathy. (A) A schematic of TDP-43 constructs used in this study. NES, nuclear export signal; RRM, RNA recognition motif. (B,C) Immunocytochemical analysis of TDP-43 expression and localisation in stable SH-SY5Y (B) and HEK293 (C) cell lines induced to express HA–TDP-43 constructs by a 48-h induction with DOX, showing nuclear localisation (WT), cytoplasmic localisation (CTF) or both (ΔNLS). Scale bar: 10 µm. (D,E) Cell-based ELISA validation of DOX-dose-dependent expression of HA–TDP WT in stable SH-SY5Y (D) and HEK293 (E) lines after a 48-h induction with DOX (EC₅₀; HEK293, 0.97 ng/ml; SH-SY5Y, 0.35 ng/ml).

Degradation of TDP-43

Next, we sought to investigate the relative degradation rates of the TDP-43 constructs. Because of its ability to autoregulate (Ayala et al., 2011), quantification of endogenous TDP-43 protein degradation cannot be performed by steady-state analyses. We exploited the inducible nature of our cellular model to perform non-radioactive pulse–chase experiments, in order to assay the relative degradation of HA–TDP-43 protein after removal of the DOX inducer. In all experiments, HA–TDP-43 expression was induced for 24 h using 10 ng/ml DOX to achieve almost maximal expression.

In HEK293 lines assayed over 72 h (Fig. 2A), wild-type TDP-43 was degraded with a half-life of 32.5 h. The 25-kDa CTF of TDP-43, which is predominantly cytoplasmic, was turned over far more rapidly, with a half-life of 11 h. TDP-43 ΔNLS, which is both nuclear and cytoplasmic, showed an intermediate rate of degradation, with a half-life of 24.4 h. Previous estimates of the half-life of untagged wild-type TDP-43 have ranged from 4 h to ≥34 h (Ling et al., 2010; Pesiridis et al., 2011; Watanabe et al., 2013).

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Fig. 2.

Degradation of TDP-43. (A) Degradation of HA–TDP-43 proteins in stable HEK293 cells as assessed by DOX pulse–chase experiments. TDP-43 CTF was degraded far more rapidly than TDP-43 ΔNLS or TDP-43 WT (t_1/2; HA–TDP-43 WT, 32.5 h; HA–TDP-43 ΔNLS, 24.4 h; HA–TDP-43 CTF, 11 h). (B) Degradation of HA–TDP-43 proteins in stable SH-SY5Y cells over a shorter timecourse, and allowing a delay after washout for the clearance of mRNA transcripts. HA–TDP-43 protein-degradation rates closely reflected those seen in HEK293 cells (t_1/2; HA–TDP-43 WT, 29.2 h; HA–TDP-43 ΔNLS, 16.6 h; HA–TDP-43 CTF, 10.2 h). (C) The degradation of HA–TDP-43 mRNA transcripts in stable SH-SY5Y cells as assessed by quantitative reverse transcriptase PCR. Transcripts for all three constructs decayed rapidly after DOX washout and had reached minima by 8 h (a representative experiment is shown, n = 2). (A–C) Arrowheads on schematics show the timepoints at which samples were taken.

In order to verify that the assay was not simply measuring the dilution of HA–TDP-43 protein by cell division or the slow decay of DOX-induced transcripts, we performed a modified experiment over a shorter timecourse in SH-SY5Y lines (Fig. 2B), and used quantitative PCR to assess transcript levels after DOX washout (Fig. 2C). SH-SY5Y cells have a doubling time of ∼48 h, compared to ∼24 h for HEK293. In addition, protein levels were assayed over a 24-h period that began 24 h after DOX washout (see schematic Fig. 2B), to ensure that DOX-induced transcripts were not still present as a substrate for continued protein synthesis. Indeed, using real-time reverse transcriptase PCR, we verified that HA–TDP-43 transcripts rapidly decayed after DOX washout (Fig. 2C). Published half-lives for the endogenous TDP-43 transcript in various cell types range from 1.9 h to 10.3 h (Ayala et al., 2011; Schwanhäusser et al., 2011; Sharova et al., 2009). The three HA–TDP-43 proteins were turned over at very similar rates in SH-SY5Y cells compared to HEK293 cells, despite the differing cell division rates of these cell lines and the use of a shorter timecourse in experiments using SH-SY5Y cells (t_1/2; HA–TDP-43 WT, 29.2 h; HA–TDP-43 ΔNLS, 16.6 h; HA–TDP-43 CTF, 10.2 h).

Involvement of the UPS and autophagy in the degradation of TDP-43

Having determined that TDP-43 degradation rates were consistent between cell lines and timecourses, we next analysed the pathway(s) by which TDP-43 was being degraded, using HEK293 lines. Inhibitors of the UPS or autophagy were included during the final 48 h of the DOX-washout period when protein degradation occurs (for schematic see Fig. 3A). Inhibitors were used in favour of genetic approaches in order to achieve temporal control and homogeneity across the cell population.

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Fig. 3.

Involvement of the UPS and autophagy in the degradation of TDP-43. (A) The relative HA–TDP-43 remaining in stable HEK293 cells at 72 h post-DOX washout, with inhibitors of autophagy or the UPS included during the last 48 h. 3MA, 3-methyladenine; Baf, bafilomycin; Epo, epoxomicin; MG, MG132; Veh, vehicle. The −DOX control lane represents the amount of HA–TDP-43 present at the 72-h washout point without expression having been induced (‘leakage’). All lanes for each construct are from the same blot, spliced as shown. (B) Western blot of LC3 levels after short treatments with the autophagy inhibitors 3MA and bafilomycin showing LC3-I and II accumulation with 3MA and LC3-II accumulation with bafilomycin. (C) The relative HA–TDP-43 remaining in stable HEK293 cells subjected to DOX pulse–chase with activators of autophagy included during the last 24 h of the 48-h chase period. LiCl, lithium chloride; Rapa, rapamycin; Tre, trehalose; Veh, vehicle. The bars represent means±s.e.m. *P≤0.05, **P≤0.01, ***P≤0.001 between vehicle and inhibitor-treated cells (two-way ANOVA, Bonferroni post-test).

These assays examined the total complement of TDP-43, of which ∼90% was detergent-soluble (Fig. 4D,E). The degradation of all three TDP-43 species was inhibited to varying degrees by the panel of inhibitors tested (Fig. 3A). The autophagy inhibitor 3-methyladenine (3MA) significantly inhibited the degradation of CTF TDP-43 (P≤0.05) and, to a lesser extent, the degradation of wild-type and ΔNLS TDP-43. 3MA showed minimal effect on the autophagy reporters p62 and LC3 (microtubule-associated protein 1 light chain 3 β) at the timepoint chosen for assay of TDP-43 levels (48 h 3MA); however, shorter timecourses of 3MA treatment revealed autophagy inhibition had occurred (Fig. 3B). The autophagosome–lysosome fusion inhibitor bafilomycin (Baf) only minimally inhibited the degradation of each TDP-43 species, despite effectively inhibiting autophagy as shown by the accumulation of LC3-II, the modified form of LC3 that associates with autophagosome membranes (Kabeya et al., 2000). In contrast to the moderate effects of autophagy inhibitors, the UPS inhibitor MG132 significantly inhibited the degradation of all three TDP-43 constructs (Fig. 3A, WT, P≤0.05; ΔNLS, P≤0.05; CTF, P≤0.001). The related UPS inhibitor epoxomicin also caused significant accumulation of wild-type, ΔNLS and CTF TDP-43 (all P≤0.05). The inhibition of both degradation pathways (by combined treatment with 3MA and MG132) did not inhibit the degradation of any of the protein constructs any more than MG132 alone. Activators of the autophagy pathway validated these findings because the addition of trehalose and LiCl during DOX washout substantially accelerated the degradation of CTF TDP-43 (Fig. 3C).

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Fig. 4.

 Inhibiton of the UPS, but not autophagy, induces the formation of detergent-resistant cytoplasmic aggregates of TDP-43. (A) Immunocytochemical analysis of stable SH-SY5Y lines induced to express HA–TDP-43 constructs by a 48-h induction with DOX in the presence of various inhibitors of the UPS or autophagy. When used alone, UPS inhibitors, but not autophagy inhibitors, induced the formation of ubiquitin (Ub)-positive TDP-43 macroaggregates (arrowheads). Scale bar: 10 µm. (B) Immunoprecipitation of HA–TDP-43 WT from HEK293 stable lines transfected with FLAG–Ub then induced with 1 µg/ml DOX alone or together with 3MA or MG132 for 24 h. Under non-denaturing conditions that preserve complexes (left) HA–TDP-43 WT co-immunoprecipitated with an increased amount of FLAG–Ub (smear >100 kDa) under treatment with 3MA and a greater amount again with MG132. Immunoprecipitation of denatured lysate (right) showed that HA–TDP-43 that was directly and covalently linked to FLAG–Ub only accumulated following MG132 treatment. IB, immunoblot. (C) TDP-43 aggregates are non-amyloid. Stable SH-SY5Y lines were induced to express HA–TDP-43 constructs by a 48-h induction with DOX in the absence or presence of MG132. In MG132-treated cells, thioflavin T staining detected amyloid aggregates that were independent of macroaggregates of HA–TDP-43 (dashed lines). MG132 treatment of parent SH-SY5Y cells induced macroaggregates (dashed line) with low levels of endogenous (Endo) TDP-43, likely owing to autoregulation of TDP-43 protein levels. Scale bar: 10 µm. (D,E) Four-step fractionation of stable SH-SY5Y lines induced to express HA–TDP-43 constructs by a 48-h induction with DOX. WT, upper white arrowhead; ΔNLS, middle black arrowhead; CTF, lower black arrowhead. The CTF was largely soluble in the low-salt (LS) fraction (TX, Triton X-100; Sark, sarkosyl). Note that the pellets from each step were resuspended in different volumes to ensure the detection of all fractions. Relative concentrations of the fractions are: Lys, 1; LS, 1; TX, 0.5; Sark, 3.33; urea 2.5. The bars represent means±s.e.m. (F,G) Solubility fractionation of the cells treated as in A, showing the lysate (L), RIPA-soluble (R) and urea-soluble (U) fractions of HA–TDP-43 WT (F) and ΔNLS (G). Urea fractions are concentrated 10-fold. Combined treatment with UPS and autophagy inhibitors (†) increased the amount of insoluble high-molecular-weight (HMW) TDP-43, particularly for TDP-43 ΔNLS (G). 3MA, 3-methyladenine; Baf, bafilomycin; Epox, epoxomicin; MG, MG132; Veh, vehicle.

UPS, but not autophagy, inhibition induces cytoplasmic TDP-43 macroaggregates

We sought to assess the phenotypic consequences of TDP-43 accumulation under either autophagic or UPS inhibition. Parallel biochemical and immunocytochemical studies were carried out in SH-SY5Y cells, as their large cytoplasm was more amenable to imaging than HEK293 cells.

To investigate the localisation and accumulation of TDP-43, its expression was induced with 1 µg/ml DOX in stable SH-SY5Y cells in the presence of inhibitors of the UPS or autophagy for 48 h. For both wild type and ΔNLS, inhibition of the UPS, but not autophagy, caused TDP-43 accumulation, resulting in the formation of macroaggregates (Fig. 4A). The UPS inhibitor MG132 induced the formation of large cytoplasmic aggregates in ∼20% of cells [WT, 17.4%±1.3 (224 cells counted); ΔNLS, 25.6%±3.4 (368 cells counted) (±s.e.m.)]. Epoxomicin also induced TDP-43 macroaggregates. By contrast, neither of the autophagy inhibitors 3MA or bafilomycin induced the formation of ubiquitylated TDP-43 macroaggregates. Interestingly, the co-application of MG132 and 3MA generated aggregates more robustly in cells expressing either HA–TDP-43 WT or HA–TDP-43 ΔNLS than did MG132 alone.

As shown in Fig. 1B,C, the HA–TDP-43 CTF was expressed at extremely low levels in both SH-SY5Y and HEK293 cells and was barely detectable by immunocytochemistry, likely because of its rapid degradation (as shown in Fig. 2A,B). Therefore, the localisation of the HA–TDP-43 CTF was not investigated further. We have found that an equivalent EGFP-tagged TDP-43 CTF forms aggregates under UPS inhibition but not under autophagy inhibition, similar to wild-type or ΔNLS TDP-43. However, the physiological relevance of the EGFP-tagged fragment is unclear, given that we and others (Li et al., 2011) find its steady state level to far exceed that of CTFs with small tags.

To examine more sensitively the conditions under which ubiquitylated TDP-43 accumulates, we performed co-immunoprecipitation after treatment with 3MA or MG132, under native or denaturing conditions (Fig. 4B). In HEK293 HA–TDP-43 WT stable lines transfected with FLAG-tagged ubiquitin (FLAG–Ub) and then induced with 1 µg/ml DOX alone, immunoprecipitation with anti-HA antibody yielded a small amount of FLAG–Ub, which ran as high-molecular-weight smears (>100 kDa). Induction with DOX plus 3MA for 24 h resulted in a small increase in the co-immunoprecipitation of FLAG–Ub by HA–TDP-43 WT, whereas treatment with MG132 for 24 h gave a more striking increase. This finding, which arose under non-denaturing immunoprecipitation conditions that preserve protein complexes, could reflect the formation of complexes containing HA–TDP-43 and ubiquitylated molecules, rather than direct ubiquitylation of HA–TDP-43. Indeed, using denaturing conditions (in which the lysate was boiled with 0.5% SDS to denature non-covalent interactions) a direct FLAG–Ub interaction with HA–TDP-43 was observed following MG132 treatment but not under basal or 3MA-treated conditions. These findings indicate that ubiquitylated TDP-43 accumulates predominantly when the UPS is blocked.

TDP-43 aggregates in human ALS and FTD were initially characterised as non-amyloid (Cairns et al., 2007); however, recent studies have found TDP-43 aggregates to be amyloid in at least a subset of cases (Bigio et al., 2013; Robinson et al., 2013). We used thioflavin T staining to determine whether the TDP-43 aggregates induced by UPS inhibition were amyloid. UPS inhibition induced the formation of multiple small amyloid aggregates, which were sometimes studded within TDP-43-positive macroaggregates; however, the TDP-43 macroaggregates themselves were negative for thioflavin T (Fig. 4C). These findings suggest that the macroaggregates are amorphous and non-amyloid.

We next investigated the relationship between macroaggregates detected by immunocytochemistry and detergent-insoluble species on western blot. Insoluble high-molecular-weight TDP-43 and insoluble fragmented TDP-43 have been described by Neumann and colleagues as hallmark features of ALS and FTD (Neumann et al., 2006). The sequential biochemical fractionation of TDP-43 proteins (generated by a 48-h induction of stable SH-SY5Y cells with 1 µg/ml DOX) demonstrated that, under basal conditions, HA-tagged wild-type or ΔNLS TDP-43 showed a similar biochemical profile to endogenous TDP-43, with a small proportion (7–21%) soluble in the low-salt fraction, the majority of the protein in the Triton X-100-soluble fraction (72–89%) and a minority of the protein soluble only in sarkosyl or urea (4–11%) (Fig. 4D,E). The HA-tagged CTF TDP-43 that was used in this study was almost completely soluble in low-salt and Triton X-100 fractions (>99%). Given its low expression levels, lack of aggregate formation and high basal solubility, the solubility of HA–TDP-43 CTF was not investigated further.

Using a simplified solubility protocol, previously validated to isolate insoluble aggregated TDP-43 (Winton et al., 2008), we analysed the effect of the inhibition of the UPS or autophagy on the solubility of wild-type and ΔNLS TDP-43 (Fig. 4F,G). As for the immunocytochemical experiments, TDP-43 expression in stable SH-SY5Y cells was induced with 1 µg/ml DOX in the presence of inhibitors of autophagy or the UPS for 48 h. The effect of UPS inhibitors on total TDP-43 levels (lysate) was more subtle than that shown in Fig. 3A, a result that is likely due to the differing experimental paradigm – the application of inhibitors during washout in Fig. 3A versus the application of inhibitors with continued overexpression in Fig. 4F,G. Owing to the low proportion of cells forming aggregates, we could not detect an increase in TDP-43 in the insoluble fraction under conditions which yielded immuno-detectable macroaggregates. However, combined UPS and autophagy inhibition (by treatment with 3MA and MG132) was shown to increase the level of insoluble high-molecular-weight (oligomeric) TDP-43, indicating that these species might be regulated by autophagy. Also of note, even under experimental conditions where TDP-43 appears diffuse by immunocytochemistry (Veh, 3MA, Baf) a significant amount of monomeric TDP-43 was insoluble in RIPA buffer.

TDP-43 aggregates induced by UPS inhibition or dual inhibition of the UPS and autophagy resemble those seen in human disease

We next characterised TDP-43 macroaggregates in terms of their labelling by molecules that target them for degradation. Given that dual inhibition of the UPS and autophagy increased the levels of insoluble TDP-43 and enhanced macroaggregation more than UPS inhibition alone, we compared the labelling of aggregates induced by dual inhibition with the labelling of those induced by UPS inhibition alone.

We first used untreated SH-SY5Y cells to characterise the basal pattern of staining of the degradation adaptor proteins ubiquilin-1 and -2 (UBQLN) and p62 (two of which, UBQLN2 and p62, are seen in aggregates in human ALS and FTD), and polyubiquitin chains with different internal lysine linkages (K48 and K63) (Fig. 5A). These adaptors were localised diffusely in untreated cells but colocalised with aggregates of wild-type (Fig. 5B,C) or ΔNLS TDP-43 (Fig. 5D,E) that had been induced with 1 µg/ml DOX plus either MG132 with 3MA or MG132 alone. Although 3MA enhanced the recruitment of HA–TDP-43 WT to perinuclear aggregates induced by MG132 treatment (Fig. 5, intensity plots), it did not alter the labelling profile of the aggregates.

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Fig. 5.

 TDP-43 aggregates induced by UPS inhibition or dual inhibition of the UPS and autophagy resemble those seen in human disease. (A) Immunocytochemical analysis of untreated SH-SY5Y cells showing the diffuse localisation of the degradation pathway proteins ubiquilin-1 or -2 (UBQLN) and p62, and K48- and K63-linked forms of ubiquitin (Ub). Scale bar: 25 µm. (B–E) Immunocytochemical analysis of stable SH-SY5Y lines induced to express HA–TDP-43 by a 48-h induction with DOX in the presence of UPS inhibition or combined inhibition of the UPS and autophagy. (B) HA–TDP-43 WT formed cytoplasmic macroaggregates (arrowheads) following treatment with DOX plus the proteasome inhibitor MG132 in stable SH-SY5Y cells. These aggregates were positive for post-translational modifications (PTMs) including K48- and K63-linked ubiquitin, ubiquilin-1 and -2 and p62. (C) Combined treatment with DOX, MG132 and the autophagy inhibitor 3MA enhanced the recruitment of HA–TDP-43 WT to macroaggregates, which were positive for the same markers as with MG132 treatment alone. (D) HA–TDP-43 ΔNLS also formed cytoplasmic aggregates following a 48-h treatment with DOX plus MG132 in stable SH-SY5Y cells. As was seen for HA–TDP-43 WT, these aggregates were positive for K48- and K63-linked ubiquitin, ubiquilin-1 and -2 and p62. (E) Combined treatment with DOX plus MG132 and 3MA did not markedly alter the recruitment of HA–TDP-43 ΔNLS to macroaggregates. Arrows on the bottom row of images in B–E represent the section taken for the intensity profiles shown below the images. Scale bars: 10 µm.

TDP-43 macroaggregates are cleared upon the restoration of UPS function

We next sought to specifically investigate the handling of insoluble TDP-43. We used 1 µg/ml DOX plus MG132, which acts reversibly, to induce the formation of insoluble TDP-43 WT or ΔNLS cellular aggregates and then we followed the fate of those aggregates after washout of MG132. DOX was maintained in the medium at a concentration of 1 µg/ml during washout to ensure that our findings reflected TDP-43 aggregate handling in the face of continued expression of TDP-43. End-point imaging showed that for both WT (Fig. 6A) and ΔNLS TDP-43 (Fig. 6B), cells given a 48-h washout period after MG132 treatment were devoid of TDP-43-positive and p62-positive aggregates, in stark contrast to cells fixed directly after the MG132 treatment. The biochemical correlate of this was a reduction in detergent-resistant high-molecular-weight TDP-43 following MG132 washout (Fig. 6C,D). These findings might indicate that there is selective survival of cells without TDP-43 aggregates or that aggregated TDP-43 is either refolded or degraded following restoration of UPS function.

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Fig. 6.

TDP-43 macroaggregates are cleared upon the restoration of UPS function. Immunocytochemical analysis of stable SH-SY5Y lines induced to form HA–TDP-43 WT (A) or HA–TDP-43 ΔNLS (B) aggregates (arrowheads) by a 48 h induction with DOX plus MG132 then fixed or subjected to MG132 washout (wo) after which the cells were left for a further 48 h. Scale bar: 10 µm. (C,D) Solubility fractionation of stable HA–TDP-43 WT (C) or HA–TDP-43 ΔNLS (D) SH-SY5Y lines either induced with DOX, induced to form aggregates by 48-h treatment with DOX plus MG132 or induced to form aggregates then subjected to MG132 washout after which the cells were left for a further 48 h. Lysate (L), RIPA-soluble (R) and urea-soluble (U) fractions are shown. Urea fractions are concentrated 10-fold. MG132 (*) increased the proportion of high-molecular-weight insoluble TDP-43 (HMW) and this was reversible upon MG132 washout (48 h). (E) Validation that EGFP-tagged TDP-43 WT is degraded over the same timecourse as HA–TDP-43 WT in stable SH-SY5Y cells (t_1/2; HA–TDP-43 WT, 29.2 h; EGFP–TDP-43 WT, 29.3 h). (F) Validation that both HA- and EGFP-tagged TDP-43 WT (grey arrowheads) are functional and can regulate the level of endogenous TDP-43 (black arrowhead) in stable SH-SY5Y cells. Black bars represent endogenous TDP-43 and grey bars represent exogenous TDP-43. UT, untransfected. (G) Live-cell imaging of stable SH-SY5Y lines induced to form EGFP–TDP-43 ΔNLS aggregates by 48 h induction with DOX plus MG132 then subjected to washout and followed for a further 15 h. In cells that cleared aggregates, the aggregates fragmented before clearance. Scale bar: 10 µm.

We therefore examined the clearance of aggregates in live cells, using stable SH-SY5Y cells transfected with EGFP-tagged TDP-43. We verified that the replacement of the N-terminal HA-tag with EGFP did not alter the timecourse of TDP-43 degradation by performing doxycycline pulse-chase experiments (Fig. 6E, t_1/2; EGFP–�TDP WT, 29.3 h; HA�–TDP WT, 29.2 h). We also verified that EGFP-tagged TDP-43 was functional, as evidenced by its ability to downregulate endogenous TDP-43 (Ayala et al., 2011) (Fig. 6F). We next performed live-cell imaging of cells with MG132-induced aggregates of EGFP–TDP-43 ΔNLS, which indicated that most aggregate-laden cells died over a 15-h washout period (69.3%±5.6) and also that aggregates were rapidly cleared by the surviving cells (Fig. 6G; supplementary material Movie 1). Owing to the low fluorescence intensity of EGFP–TDP WT aggregates, their clearance could not readily be measured in living cells.

TDP-43 aggregate clearance is due to the enhanced mobility of lower-order aggregated species, rather than the clearance of macroaggregated TDP-43

Previous work on other aggregate-prone proteins indicates that some aggregates (e.g. juxta-nuclear quality control aggregates, JUNQ) are mobile, readily exchange with the diffuse protein pool and can be cleared by the UPS (Ben-Gedalya et al., 2011; Kaganovich et al., 2008). To determine whether this was true for TDP-43, we performed fluorescence recovery after photobleaching (FRAP) on diffuse and macroaggregated EGFP–TDP-43 ΔNLS (Fig. 7A) in stable SH-SY5Y cells. FRAP measures both the proportion of a given protein pool that is mobile and the rate of mobility by examining the migration of fluorescent proteins back into a region that has been bleached of fluorescence.

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Fig. 7.

 TDP-43 aggregate clearance is due to enhanced mobility of lower-order aggregated species, rather than mobility of macroaggregated TDP-43. (A) Confocal images acquired during FRAP. EGFP–TDP-43-ΔNLS showed rapid fluorescence recovery for diffuse cytosolic forms (Cyt TDP) but no recovery for aggregated forms (Agg TDP), indicating that macroaggregated TDP-43 is immobile and unlikely to readily exchange with the diffuse pool. The white dashed line encloses the bleached area. Scale bar: 10 µm. (B) FRAP recovery curves, with bleaching at t = 0 and 100% representing the pre-bleach fluorescence intensity. The fraction of cytosolic TDP-43 that was mobile was slightly decreased in cells that were treated with MG132 (MG) but were devoid of aggregates (Cyt TDP −Agg) and was greatly decreased in cells containing an aggregate (Cyt TDP +Agg). (C) The fraction of TDP-43 that was mobile under various conditions. The decrease in the mobile fraction in cells treated with MG132 and containing an aggregate (Cyt TDP +Agg) was rescued 8–10 h after washout (wash). There was no mobilisation of macroaggregated TDP-43 upon washout. (D) The rate of FRAP recovery [given as K = ln(2)/t_1/2] for mobile species under various conditions. The FRAP rate was significantly decreased in cells that were treated with MG132 and contained an aggregate (Cyt TDP +Agg), which was reversed after washout. The bars represent means±s.e.m.; n.s., not significant. **P≤0.01, ***P≤0.001 between control and treated cells or as shown (one-way ANOVA, Bonferroni post-test).

We examined cells that were induced to express EGFP–TDP-43 using 1 µg/ml DOX alone, cells induced to form aggregates with 1 µg/ml DOX plus MG132, and cells induced to form aggregates then washed out and left in fresh medium containing 1 µg/ml DOX without MG132 for 8–10 h. Firstly, by bleaching diffuse cytosolic EGFP–TDP-43 ΔNLS we found that the proportion of diffuse TDP-43 protein that was mobile was reduced by inhibition of the UPS, both in cells devoid of aggregates and, more strikingly, in cells that contained large aggregates (Fig. 7B,C; percentage of TDP-43 that was mobile: DOX only, 69%±0.9; MG132 without aggregates, 64%±1, P≤0.01; MG132 with aggregates, 48%±1.6, P≤0.001; ±s.e.m.). Furthermore, we found that the TDP-43 within the aggregates was almost completely immobile, with the bleached portions of the aggregates remaining dark for the duration of FRAP imaging and not visibly exchanging with the diffuse pool (Fig. 7A–C; percentage of TDP-43 that was mobile: 2.7%±0.1, P≤0.001). At 8–10 h after the washout of MG132, there was a significant increase in the proportion of diffuse TDP-43 that was mobile in cells still containing large aggregates, suggesting there was mobilisation or clearance of previously immobile species (percentage of TDP that was mobile: 48%±1.6 before and 61%±0.7 after washout, P≤0.001). However, direct bleaching of macroaggregated TDP-43 showed that this species was not mobilised, as it showed no increase in the mobile fraction after washout.

Next, we examined the rate of fluorescence recovery (the speed of molecular movement) for mobile species of TDP-43 protein (Fig. 7D). Diffuse TDP-43 in vehicle-treated cells showed rapid recovery (t_1/2 = 3.4 s). Diffuse TDP-43 in cells exposed to UPS inhibition but without aggregates showed a similar rate of recovery (t_1/2 = 3.6 s), whereas TDP-43 in cells with aggregates showed significantly slower recovery (t_1/2 = 6.9 s). A decrease in the fluorescence recovery rate indicates increased binding or increased size of the TDP-43 particle, consistent with oligomerisation of TDP-43. At 8–10 h after the washout of MG132, there was an increase in the rate of recovery of diffuse TDP-43 in cells with large aggregates (t_1/2 = 6.9 s before versus 4.0 s after washout), suggesting that there had been removal or dissociation of slow-moving species.

TDP-43 aggregate clearance requires autophagy

Our findings suggested that during washout, slow-moving and immobile species were either resolved into mobile or faster-moving species, or were removed directly. Oligomeric or microaggregated species cannot be cleared directly by the UPS, and their clearance might require aggregate autophagy or ‘aggrephagy’ (Lamark and Johansen, 2012; Øverbye et al., 2007). Therefore, in order to test whether aggregate clearance involved autophagy, we first determined whether cells with TDP-43 aggregates contained autophagosomes, the double-membraned effectors of autophagy. Cells that were transfected with the autophagosome marker mCherry–GFP–LC3 showed a significant increase in the number of autophagosomes (GFP-positive puncta) in cells induced to form TDP-43 aggregates (1 µg/ml DOX plus MG132) compared to controls (Fig. 8A,B; autophagosomes per cell: WT, 36±8 MG132 versus 2±1 DOX, P≤0.01; ΔNLS, 31±9 MG132 versus 6±2 DOX, P≤0.05; ±s.e.m.).

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Fig. 8.

 TDP-43 aggregate clearance requires autophagy. (A) Autophagosomes in cells containing TDP-43 aggregates. Stable SH-SY5Y lines were transfected with mCherry–GFP–LC3 and then induced to form HA–TDP-43 WT or ΔNLS aggregates (arrowheads) by a 48-h induction with DOX plus MG132. (B) Quantification of the number of GFP–LC3-positive autophagosomes per cell in cells treated as in A. The bars represent means±s.e.m. *P≤0.05, **P≤0.01 between control and treated cells (unpaired Student’s t-tests with Welch's correction). (C) Live-cell imaging of stable SH-SY5Y lines that were induced to form EGFP–TDP-43 ΔNLS aggregates (arrowheads) by a 48-h induction with DOX plus MG132, then subjected to washout and followed for a further 15 h in the presence of bafilomycin (Baf). Aggregates fragmented but were not cleared. (D) Regression analysis of the relationship between the aggregate load (integrated intensity of aggregate) and clearance time in the presence or absence of autophagy inhibitors during washout (wo) [3MA, 3-methyladenine; Baf, bafilomycin; Veh, vehicle; Pearson's r = 0.72 (Veh wo); 0.70 (3MA wo); 0.23 (Baf wo)]. Small aggregates were cleared rapidly in the absence, but not presence, of autophagy inhibitors. In Baf wo cells a distinct population of aggregates that were not cleared by the end of imaging (scored as 15 h) can be seen (dashed line). (E) Relative rates of clearance of EGFP–TDP-43 ΔNLS aggregates according to the slopes of the lines shown in D. Note that the slope for Baf wo includes the ‘non-clearing’ population. The results are not significant by one-way ANOVA. Scale bars: 10 µm.

We next examined the impact of autophagy inhibition on aggregate clearance, by performing live imaging. Cells were induced to form aggregates of EGFP–TDP-43 ΔNLS using 1 µg/ml of DOX plus MG132, and inhibitors of autophagy were added during the washout period (Fig. 8C). As discussed, the majority of cells with aggregates died over the course of imaging. Aggregate-containing cells that died had significantly greater aggregate load than those that lived (average aggregate integrated intensity was 7328±1661, versus 1961±522 in cells that lived, P≤0.01, Student’s t-test with Welch’s correction; ±s.e.m.). For cells that survived the period of imaging, we plotted the relationship between the load of aggregated protein and the rate of clearance from the cell (Fig. 8D). In the absence of autophagy inhibitors, we found a positive linear relationship between the aggregated protein load and the time taken for clearance (Fig. 8D, Veh). When autophagy inhibitors were present, macroaggregates were still disassembled into smaller discrete aggregates, suggesting an autophagy-independent disaggregation step (Fig. 8D, Baf; supplementary material Movie 2). However, these aggregates then persisted in the cells. The slope of the line relating initial aggregate load with clearance time therefore flattened in the presence of autophagy inhibitors (Fig. 8D,E, relative slope 3MA, 0.74; Baf, 0.15). The presence of aggregates that completely failed to be cleared over the 15-h timecourse in the presence of bafilomycin, regardless of their size (Fig. 8D, dashed line), showed that aggregate clearance was strongly dependent on autophagy.