Abstract
Parkinson’s disease (PD) is a progressive neurodegenerative disease characterized by mitochondrial dysfunction and accumulation of alpha-synuclein (α-Syn)-containing protein aggregates known as Lewy bodies (LB). Here, we investigated the entry of α-Syn into mitochondria to cause mitochondrial dysfunction and loss of cellular fitness in vivo. We show that α-Syn expressed in yeast and human cells is constitutively imported into mitochondria. In a transgenic mouse model, the level of endogenous α-Syn accumulation in mitochondria of dopaminergic neurons and microglia increases with age. The imported α-Syn is degraded by conserved mitochondrial proteases, most notably NLN and PITRM1 (Prd1 and Cym1 in yeast, respectively). α-Syn in the mitochondrial matrix that is not degraded interacts with respiratory chain complexes, leading to loss of mitochondrial DNA (mtDNA), mitochondrial membrane potential and cellular fitness decline. Importantly, enhancing mitochondrial proteolysis by increasing levels of specific proteases alleviated these defects in yeast, human cells, and a PD model of mouse primary neurons. Together, our results provide a direct link between α-synuclein-mediated cellular toxicity and its import into mitochondria and reveal potential therapeutic targets for the treatment of α-synucleinopathies.
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Introduction
Alpha-synuclein is a presynaptic protein prominently implicated in Parkinson’s disease (PD), the second largest neurodegenerative disorder characterized by symptoms of motor dysfunction that result from progressive loss of dopaminergic (DA) neurons in the substantia nigra1. A hallmark of PD is the formation of α-Syn-containing neuronal aggregates known as Lewy bodies and Lewy neurites, in an age-dependent manner2,3,4. α-Syn is a 140 amino acids (aa) polypeptide that contains three domains5: N-terminal lipid-binding α-helix (residues 1–60), amyloid-binding central domain (NAC, residues 61–95)6, and C-terminal acidic tail (residues 95–140). Mutations in or elevated dosage of the SNCA gene encoding α-Syn causes familial PD7. In animal and cell models, overexpression of α-Syn is sufficient to cause cellular toxicity and PD-like pathology and symptoms8. However, the mechanism underlying α-Syn toxicity remains enigmatic. Equally unclear is how α-Syn proteostasis is maintained at an early age since most patients with familial PD develop pathology and symptoms only after decades.
Mitochondrial dysfunction is another hallmark of PD characterized by loss of mtDNA, increased oxidative stress due to reactive oxygen species (ROS), deterioration of metabolic activities, and reduced calcium homeostasis9. Disruption of the electron transport chain complexes with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) is sufficient to cause parkinsonian-like symptoms in mice10. Furthermore, mutations in genes encoding mitochondrial proteins such as Parkin and PINK1, also cause familial PD11. Recent studies suggest that α-Syn interacts with mitochondrial outer membrane import channel proteins TOM20 and TOM4012,13. In an α-Syn preformed fibril (PFF)-treated mouse model of PD, the majority of a pathogenic form of α-Syn (serine 129 phosphorylated α-Syn) binds to mitochondria and alters cellular respiration14. α-Syn also interacts with the Voltage-Dependent Anion Channel (VDAC) of the mitochondrial outer membrane in HeLa cells15. In addition to mitochondrial outer membrane proteins, α-Syn also interacts selectively with cardiolipin in mitochondria16. A recent study suggests that the conversion of monomeric α-Syn into toxic oligomeric states preferentially occurs on mitochondrial membranes via interactions with mitochondrial cardiolipin17. Moreover, α-Syn has been detected in the mitochondrial intermembrane space18 and interacts with complex I, causing reduced complex I activity and increased production of ROS19,20. Artificial targeting of α-Syn into mitochondria by linking it with a mitochondrial targeting sequencing impaired mitochondrial respiration in human dopaminergic neurons, arguing for the toxicity of accumulating α-Syn in mitochondria21. However, it is unclear whether the import of α-Syn into mitochondria is a spontaneous process or occurs only under pathogenic conditions.
The budding yeast Saccharomyces cerevisiae has been a useful model for understanding how α-Syn may perturb basic cellular functions that could be extended to human cells22,23,24,25. These studies demonstrated that α-Syn interferes with a broad range of membrane-based processes to exert its toxicity, such as lipid metabolism, vesicular trafficking, Ca2+ and Mn2+ transport, protein quality control, and mitochondrial functions26,27. In this study, we examined α-Syn in mitochondria using a split-GFP system (spGFP)28, which allows α-Syn to be specifically visualized once it enters the mitochondrial matrix in vivo, in contrast to lengthy biochemical fractionation during which the non-native mitochondrial protein could be degraded. We implemented this system in yeast and cultured mammalian cells, as well as in mice, by tagging the endogenous SNCA gene with a part of the spGFP. We show that α-Syn can be constitutively imported into mitochondria in these diverse models. The mitochondrial pool of α-Syn forms puncta but can also be efficiently degraded by specific mitochondrial proteases. The mitochondria-associated α-Syn interacts with proteins comprising diverse pathways and leads to mitochondrial defects similar to those reported for PD neurons. Enhancing mitochondrial degradation of α-Syn rescues the observed cellular defects and may represent a therapeutic approach to alleviate mitochondrial and cellular toxicity caused by α-Syn.
Results
α-Syn is imported into mitochondria in yeast and cultured human cells
To visualize the entry of α-Syn into the mitochondrial matrix, we took advantage of the spGFP system28,29, in which the eleventh β-strand of GFP (GFP11) was introduced to the COOH terminus of human α-Syn (α-Syn-GFP11). In yeast, the other part of GFP containing the first ten β-strands (GFP1–10) was targeted to the mitochondrial matrix by linking to the COOH terminus of a mitochondrial matrix protein Grx529. The mitochondrial outer membrane was labeled with Fis1 transmembrane domain tagged with mCherry30. α-Syn-GFP11 was expressed in yeast using the constitutive GAP promoter, which allows cells to grow in the normal glucose-containing medium, and α-Syn imported into the mitochondrial matrix enables reconstitution of GFP fluorescence (Fig. 1a). Confocal live-cell imaging showed that α-Syn spGFP fluorescence colocalized with mitochondria (Fig. 1b). As positive and negative controls in the Grx5-GFP1–10 background, the GFP11-tagged mitochondrial matrix protein Mdh1 or cytosolic protein Gpm1 showed strong or no GFP signal, respectively, in mitochondria (Fig. 1b). The expression levels of α-Syn and Gpm1 were comparable (Supplementary Fig. 1a). Super-resolution microscopy further showed that α-Syn formed puncta within mitochondria (Fig. 1c), and these puncta colocalized with the mitochondrial matrix disaggregase Hsp78 (Supplementary Fig. 1b), suggesting that α-Syn aggregates in mitochondria. To biochemically confirm the presence of α-Syn in the mitochondrial matrix, we purified mitochondria from the yeast strain above and performed a protease protection assay (Fig. 1d, e). Digitonin and Triton X-100 were used to permeabilize the mitochondrial outer membrane and inner membrane, respectively, and protease K treatment to degrade α-Syn that was not protected by membranes. Immunoblot analysis showed the presence of α-Syn in both the mitochondrial intermembrane space and the mitochondrial matrix (Fig. 1d, e).
We also applied the α-Syn spGFP system to human RPE1 cells by expressing α-Syn tagged with GFP11 and mitochondrial matrix-targeted mCherry-GFP1–10 (MTS-mCherry-GFP1–10)31 and found that α-Syn was present in mitochondria by imaging, and this occurred in 26.8% of transfected cells by flow cytometry analysis. (Fig. 1f, g, l).
To determine which domain of α-Syn was essential for accumulation inside mitochondria, each of the three α-Syn structural domains5,6 (N-terminal lipid binding, NAC domain, and C-terminal unstructured domain) were tagged with GFP11 and co-expressed with Grx5-GFP1–10 in yeast (Fig. 1h–j). Both the N-terminal and C-terminal domains on their own, but not the central NAC domain, were imported into mitochondria constitutively (Fig. 1i, j). Fragments containing the N-terminal domain plus the NAC domain, or the NAC domain plus the C-terminal domain, were also imported into mitochondria (Fig. 1i and Supplementary Fig. 1c–e), suggesting that either N-terminal or C-terminal is sufficient to be imported into mitochondria. We further tested if the above mechanisms found in yeast were conserved in humans. The N-terminal domain, but not the NAC or C-terminal domain, was imported into mitochondria in RPE1 cells, although the N-terminal domain was imported less efficiently than full-length α-Syn (Fig. 1k, l). However, because the protein expression level of the C-terminal domain was exceedingly low compared with full-length α-Syn, which could be caused by instability of the C-terminal domain, the lack of spGFP signal in mitochondria may not reflect an import defect (Fig. 1k, l and Supplementary Fig. 1f, g).
α-Syn accumulates in the mitochondria of dopaminergic neurons and microglia in mouse brains in an age-dependent manner
To examine if the endogenous α-Syn is imported into mitochondria in vivo of mammals, we generated a transgenic mouse model in which the COOH terminus of endogenous SNCA gene was tagged with GFP11, and MTS-mCherry-GFP1–10 under CAG promoter was ubiquitously expressed by inserting into the Rosa26 locus, both via CRISPR-Cas9-mediated genome editing (Fig. 2a). This mouse model allows visualization of mitochondrial import of α-Syn in different tissues and cell types during mouse aging (Fig. 2a). MTS-mCherry-GFP1–10 fluorescence emitted by mCherry also colocalized with a mitochondrial protein TOM20 by immunofluorescence in mouse brain slices (Supplementary Fig. 2d). Compared to the wild-type, α-Syn spGFP-tagged mouse brain showed a moderate reduction in the protein level of α-Syn (Supplementary Fig. 2f, g). Nonetheless, by confocal imaging of spGFP fluorescence in tissue slices, we detected the accumulation of α-Syn spGFP signal in mitochondria of mouse brain in 5-month-old mice (Fig. 2b). The mitochondria-associated α-Syn spGFP signal was enriched in the midbrain and was present in cells that stained positive for tyrosine hydrolase (Th), a marker specific for dopaminergic neurons (Fig. 2b). Interestingly, the accumulation of α-Syn in mitochondria in Th+ neurons correlated with age: whereas the spGFP signal was low in 2- and 5-month-old animals, it increased dramatically in 11- and 21-month-old mouse brains (Fig. 2c, d). Furthermore, in the brains of old animals, α-Syn spGFP was frequently observed in Th- cells (Fig. 2c and Supplementary Fig. 2a, b). Using different cell type markers, we found that the α-Syn accumulated in mitochondria of microglia marked by IBA1 (Ionized calcium binding adapter molecule 1), but not in cells stained with astrocyte maker GFAP (Fig. 2e, f and Supplementary Fig. 2c, e). In microglia, some of the large puncta containing α-Syn spGFP and MTS-mCherry colocalized with p62, an autophagosome marker, in 11 and 28, but not 5-month-old brains (Fig. 2g), suggesting that mitophagy of the α-Syn-containing mitochondria were increased in aged cells.
α-Syn interacts with functional complexes in mitochondria and causes mitochondrial dysfunction
α-Syn was reported to impair mitochondrial functions through its interactions with components of the electron transport chain19, and its interaction with complex I reduced complex I activity and increased ROS production. To verify the interaction of α-Syn with the oxidative phosphorylation machineries, we expressed α-Syn spGFP system in strains expressed mScarlet-I labeled NDI1, a NADH-ubiquinone oxidoreductase32 or ATP533, a component of Complex V, separately (Fig. 3a). After disrupting the outer and inner membranes of purified mitochondria with 1% Triton X-100 containing lysis buffer, Atp5 and Ndi1 remained associated with α-Syn puncta (Fig. 3b). Consistently, the mouse ortholog of ATP5, Atp5o, also colocalized with α-Syn puncta in 11-month-old mouse brains (Supplementary Fig. 3e).
Since the electron transport chain is important for producing the proton gradient across the mitochondrial inner membrane, we measured mitochondrial membrane potential (ΔΨ) with Tetramethylrhodamine (TMRM) staining34. Mitochondria with α-Syn accumulation showed a marked decline in ΔΨ (Fig. 3c, d). Similarly, α-Syn overexpression also reduced mitochondrial membrane potential in RPE1 cells by staining with MitoView405, which is for monitoring changes in mitochondrial membrane potential in live cells (Fig. 3e and Supplementary Fig. 3f). We also measured the frequencies of respiration-deficient cells, which indicate the loss of mtDNA using 2,3,5-triphenyltetrazolium chloride (TTC) staining35 in yeast expressing α-Syn. DAPI staining confirmed the loss of mtDNA in TTC-negative cells. We found that α-Syn accumulation in the mitochondria of yeast cells resulted in an increased loss of mtDNA (Fig. 3f, g). Furthermore, inducible expression of α-Syn and its subsequent accumulation in mitochondria caused mitochondrial fragmentation in both yeast and RPE1 cells (Figs. 3h, i, 5g and Movie S1). Although α-Syn under the constitutive GAP promoter in yeast cells did not significantly affect cell growth, acute high-level expression from a second copy of α-Syn with a β-estradiol-inducible GEM system36 significantly impaired cell growth (Fig. 3j). These data together showed that high-level α-Syn causes mitochondrial dysfunction and cellular fitness decline.
Imported α-Syn is degraded in mitochondria
We used time-lapse imaging to track the fate of α-Syn spGFP in mitochondria over time. When α-Syn was under constitutive expression, the spGFP signal in mitochondria was maintained at a steady level throughout the course of the observation (Fig. 4a, b and Movie S2). When treating these cells with CCCP, which blocked the import of α-Syn, the α-Syn spGFP signal in mitochondria decreased with a half-life of 6.9 min (Fig. 4a, b and Movie S3), while the spGFP signal of the matrix protein Grx5 did not change, suggesting that α-Syn was rapidly degraded in mitochondria (Supplementary Fig. 3g and Movie S4).
To identify mitochondrial proteases responsible for the degradation of α-Syn, we moderately increased the copy number of each of the known mitochondrial proteases by using centromeric plasmids from the molecular barcoded yeast (MoBY) library, in which each gene is controlled by its native promoter and terminator37. Increased copy number of several mitochondrial proteases significantly reduced the steady-state level of α-Syn spGFP, but not Grx5-spGFP, in mitochondria (Fig. 4c–e and Supplementary Fig. 3a, b, d). Plasmids expressing Cym1 and Prd1 had the strongest effect on reducing α-Syn spGFP accumulation in mitochondria, whereas deletion of CYM1 or PRD1 significantly increased the accumulation of α-Syn in mitochondria (Fig. 4e and Supplementary Fig. 3c). On the other hand, overexpression of Pim1, Lon protease found to be involved in aggregate dissolution after heat shock29, or Nma111/Ynm3, a serine protease whose human ortholog HtrA2 has genetic association with PD38, did not affect α-Syn accumulation in mitochondria (Fig. 4e and Supplementary Fig. 3a).
Enhancing specific mitochondrial proteolytic activities reduces α-Syn toxicity
To determine whether elevating the level of mitochondrial proteases that can degrade α-Syn would reduce the cellular toxicity and mitochondrial defects caused by α-Syn expression, we moderately increased the gene copy number using the aforementioned MoBY system. Cym1, Prd1, Imp2 or Atp23 proteases showed the highest inhibitory effects on α-Syn accumulation in mitochondria (Fig. 4c, d) and rescued growth defects caused by the induced high-level expression of α-Syn (Fig. 5a, b). Moreover, increasing copy numbers of these mitochondrial proteases also restored mitochondria membrane potential in α-Syn-expressing cells (Fig. 5c, d).
To examine if increasing the level of Prd1 homolog could rescue mitochondrial defects in human cells, we generated RPE1 cell lines expressing dox-inducible α-Syn spGFP system with or without stable ectopic expression of NLN (Prd1 ortholog) under the PFFV promoter (Supplementary Fig. 3h, i). The overexpressed NLN is predominately localized to mitochondria in RPE1 cells, as confirmed by immunostaining (Fig. 5e, f), significantly reduced α-Syn accumulation in mitochondria and mitochondrial fragmentation caused by the induced high-level expression of α-Syn (Fig. 5e, g, h). To further test whether overexpression of NLN could rescue PD pathologies in a neuronal model of synucleinopathy, we applied preformed fibrils of mouse α-Syn (α-Syn PFF)39 to primary neurons from the α-Syn spGFP transgenic mouse. PFF seeds the recruitment of endogenous α-Syn into pSer129-α-Syn-positive aggregates that recapitulate features of the Lewy bodies and Lewy neurites in PD40. Primary cortical neurons from α-Syn spGFP mouse were isolated and treated with α-Syn PFF for 14 days starting at 7 days in vitro (DIV7). Compared to the control, overexpression of NLN decreased α-Syn accumulation in mitochondria as well as pSer129-α-Syn aggregates in PFF-treated primary neurons (Fig. 5i and Supplementary Fig. 3j). Collectively, our results suggest that enhancing the level of NLN rescues defects caused by synucleinopathy in yeast, human cells, and mouse primary neurons.
Discussion
The data presented above have shed light on a direct link between α-synucleinopathies and mitochondrial dysfunction, two hallmarks of PD. We show that the α-Syn import into mitochondria is conserved in yeast, mouse, and human cells. During mouse aging, α-Syn accumulation in mitochondria of DA neurons and microglia gradually increased, which helps explain why age is a risk factor for PD41. The decline of proteostasis during aging may lead to increased import of misfolded proteins into mitochondria, including α-Syn. This could overwhelm the proteolytic apparatus, leading to the accumulation of misfolded proteins in mitochondria, which further compromises mitochondrial functions21. Dysfunctional mitochondria would have reduced contribution to maintaining cytosolic proteostasis and cause metabolic stress, leading to further accumulation of α-Syn and other misfolded proteins in the cytosol, forming protein aggregates such as Lewy bodies. This vicious cycle may lead to neuronal death.
A recent study targeted α-Syn directly into mitochondria with MTS, which severely damaged mitochondrial functions in DA neurons21, confirming the detrimental effects of accumulating α-Syn in mitochondria. We note that the spGFP reporter only detects the mitochondrial pool of α-Syn and cannot assess the relative portion of α-Syn in mitochondria comparing to cytosol, however, our data show that even small amount of accumulation of α-Syn in mitochondria could significantly damage mitochondrial functions. In C. elegans, neurons can dispose mitochondria and protein aggregates in exophers42. It will be interesting to determine if there is a similar mechanism in mammals that would help remove α-Syn-containing mitochondria in a non-cell-autonomous fashion, when mitophagy failed to clear them in neurons. Recent studies found that microglia can uptake α-Syn released from neurons43, and mitochondria can be transferred between microglia44. It is currently unclear if the α-Syn-containing mitochondria accumulated in microglia during aging originate from neurons or arise directly in microglia cells caused by high levels of α-Syn accumulation in mitochondria.
Our data also suggest that enhancing certain mitochondrial proteases rescues both α-Syn toxicity and mitochondrial dysfunction. Other studies have shown that enhancing mitochondrial proteostasis reduces Aβ proteotoxicity45,46 and extends the lifespan of worms47. These findings suggest that rescuing mitochondrial proteostasis can antagonize age-associated defects. On the contrary, inhibiting mitochondrial proteases, such as HtrA2 and Lon protease, significantly aggravates α-Syn seeding, as well as amyloid-β 1–42 (Aβ42) aggregation in human neuroblastoma cells (SH-SY5Y)48. Our data suggest that increasing the levels of specific mitochondrial proteases such as Neurolysin significantly reduced the accumulation of α-Syn in mitochondria and rescued the mitochondrial dysfunction brought about by α-Syn overexpression. The variable expression of different mitochondrial proteases that are responsible for the degradation of imported α-Syn may help explain the cell-type-specific vulnerability of α-synucleinopathies and mitochondrial dysfunction in PD. By analyzing the GTEx RNA-seq database49 and a published single-cell RNA-seq dataset50, we found that the transcript level of Neurolysin is increased in substantia nigra where DA neurons are enriched during normal human aging (Supplementary Fig. 4a), but reduced in DA neurons derived from induced pluripotent stem cell (iPSC) carrying the GBA-N370S PD risk variant compared to the healthy control50 (Supplementary Fig. 4b). Therefore, the reduced expression of Neurolysin in DA neurons may explain the DA neuron-specific toxicity of α-synucleinopathies and mitochondrial dysfunction in PD. Further study is required to determine if increasing Neurolysin levels or stimulating its proteolytic activity in DA neurons of aged brains could reduce α-Syn accumulation in mitochondria and hereby alleviate mitochondrial dysfunction and neuronal death in PD.
Methods
Yeast strains, plasmids, and culture media
Yeast strains of the BY4741 background (MATa his3Δ1 leu2Δ0 met15Δ0 ura3Δ0) were used in this study, and the detailed strain genotypes are listed in Supplementary Table 1. Gene deletion and tagging (HA, mcherry, GFP11, and GFP) in this study were performed with PCR-mediated homologous recombination51 or picked from the Yeast KO Collection52, and verified by PCR genotyping. Both GFP11 and MTS–mCherry–GFP1–10 plasmids of yeast and mammalian systems were from our previous study29. GFP1–10 was in frame with the mitochondria targeting sequence (MTS) and mCherry in MTS-mCherry-GFP1–10 constructs or used for tagging of the endogenous Grx5. The MoBY library37 was purchased from Dharmacon Reagents (Catalog ID: YSC5432). The mSC-II library was a gift from Michael Knop lab33. Cells were grown in YPD for biochemistry and growth assays, in synthetic complete (SC) medium for imaging. The respective media contained either 2% glucose (YPD, SC-complete) or 2% galactose (YPGal, SC-Glucose + Gal). OD600 was used to estimate the amount of yeast cells used in various experiments.
Animals
Parental mice C57BL/6J for making the α-Syn spGFP transgenic mice were obtained from the Jackson Laboratories (strain #000664). All mice housing, breeding, and experiment procedures were performed according to the guidelines of the Laboratory Animal Manual of the National Institute of Health Guide to the Care and use of Experimental Animals and were approved by Johns Hopkins University Animal Care and Use Committee. Mice were housed in a 12 h light/dark cycle with free access to food and water. Randomized mixed-gender groups were used for animal experiments.
The α-Syn spGFP transgenic mice were generated and characterized in this study, using homology-directed repair-based, CRISPR-Cas9-induced precise gene editing as described below. CAG promoter-driven MTS (Su9)-mCherry-GFP1–10 sequence was inserted into the safe harbor Rosa26 locus using a plasmid containing the construct flanked by ROSA26 homologous sequence (1083 bp upstream/4341 bp downstream overlap). They were microinjected together with CRISPR Cas9 protein and crRNA (CGCCCATCTTCTAGAAAGAC) into one-cell embryos of C57BL/6J mice (strain #000664 from the Jackson Laboratory) by the Transgenic Core Laboratory in Johns Hopkins University, resulting in the MTS-mCherry-GFP1–10 mice. PCR genotyping was performed with primer pairs forward TTCCCTCGTGATCTGCAACTC and reverse CTTTAAGCCTGCCCAGAAGACT for WT Rosa26; forward GTGGGAGCGGGTAATGAACTTT and reverse TCCTGCAATGATGAATCTTGAGTGA for MTS-mCherry-GFP1–10 knock-in. The correct insertion generated a band size of 69 bp. GFP11 targeted COOH terminus of the endogenous SNCA gene was created by using crRNA (CCGGCAGATCTTAGGAGATT), Cas9, and DNA template (GAAGGCTACCAAGACTATGAGCCTGAAGCCGGGGGATCCGGTCGACCCGGAGGCGGTTCTAGAGATCATATGGTTTTGCATGAATATGTTAATGCTGCTGGTATTACT), resulting the α-Syn-GFP11 mice. PCR genotyping was performed with primer pairs forward CCTGATATTAGGAAGGCTACCAAGACT and reverse CGCCTCCGGGTCGA for GFP11 knock-in; forward CCTGATATTAGGAAGGCTACCAAGACT and reverse GCACTTGTACGCCATGGAAGA for WT SNCA. Injections were performed by the Transgenic Core Laboratory at Johns Hopkins University. Crossing α-Syn-GFP11 and MTS-mCherry-GFP1–10 mice resulted in the α-Syn spGFP mice. Homozygous α-Syn spGFP mice were PCR genotyped and used in this study.
Antibodies
HA-tag (C29F4): mAb #3724, Cell Signaling Technology. Anti-Tom70 antibody, anti-Dld1 antibody, and anti-Abf2 antibody were kindly provided by S. Claypool’s laboratory (Johns Hopkins University). Anti-mouse IgG, HRP-linked Antibody, Cell Signaling Technology, Cat# 7076. mCherry antibody: PA5–34974, Invitrogen. GAPDH (D16H11) XP® Rabbit antibody: CS#5174S, Cell Signaling. PGK1 Monoclonal Antibody (22C5D8): #459250, Invitrogen. Ms mAb to NLN, ab119802, Abcam. Map2 Alexa Fluor 647 conjugated anti-MAP2, #801806, BioLegend. Iba1/AIF-1(E4O4W) XP Rabbit mAb, #17198 S, Cell Signaling Technology. Rabbit anti-Tyrosine Hydroxylase pAb, NB300–109, NOVUS. Rb mAb to Alpha-synuclein phosphor S129, ab51253, abcam. Purified Mouse Anti-alpha-Synuclein, #610787, BD Biosciences. Purified anti-GFAP, #801103, BioLegend. Purified anti-p62(SQSTM1), #814802, BioLegend. Goat pAb to Ms IgG (Alexa Fluor 405), ab175660, Abcam. Goat pAb to Rb IgG (Alexa Fluor 647), ab150079, Abcam. Goat pAb to Rb IgG (Alexa Fluor 405), ab175652, Abcam. ATP5O Polyclonal antibody, 10994–1-AP, Proteintech. GFP11-tag antibody, #48545, Signalway Antibody. β-Actin (D6A8) Rabbit antibody, #8457 S, Cell Signaling.
Confocal microscopy and quantification
Live-cell images were acquired using a Yokagawa CSU-10 spinning disc on the side port of a Carl Zeiss 200 M inverted microscope. Laser 488/561 nm excitation was applied to excite GFP/mCherry, respectively, and the emission was collected through the appropriate filters onto a Hamamatsu C9100–13 EMCCD on the spinning disc confocal system. For multi-track acquisition, the configuration of alternating excitation was applied to avoid the bleed-through of GFP. The spinning disc was equipped with a 100×1.45 NA Plan-Apochromat objective and a 63×1.4 oil Plan-Apochromat objective, respectively. For 3D imaging, 0.5-μm step size for 5–6 μm in total in Z for yeast cells; 1-μm step size was applied for human cells. Images were acquired using MetaMorph (version 7.0; MDS Analytical Technologies) on the CSU-10 spinning disc system. Zeiss LSM880-Airyscan FAST Super-Resolution microscopy equipped with 63×/1.4 PlanApo oil was used for yeast, human cells, and mouse brain sections. The super-resolution images were generated by Airyscan processing.
Live yeast cells imaging: yeast cells were cultured in SC medium overnight at 30 °C. Then they were refreshed in SC medium for at least 3 h at 30 °C to an OD600 around 0.1–0.25. For 3D time-lapse imaging, cells were laid on a SC-complete agarose gel pad or cultured in a MatTek (P35G-0–14-C) glass bottom dish that were treated with Concanavalin A (MP Biomedicals, Cat# IC150710.2). Each z series was acquired with a 0.5-μm step size. For GEM inducible systems, 1 M of β-estradiol (E2758–1G, Sigma) was added to the SC-complete medium upon induction. The image processing was performed using the ImageJ software (NIH) or the Imaris software. For visualization purposes, some of the images in the figures were scaled with bilinear interpolation and shown as a max projection on Z for fluorescent channels.
Quantification of spGFP fluorescence was done using a custom Python code that was published in our previous study29. In brief, after reading the mCherry and GFP channel z stacks, the intensities were summed along the z-axis. The resulting 2D image in the GFP channel was then subject to random walk segmentation to segment out the yeast cells from the background and watershed segmentation to separate adjacent cells. The segmentation algorithms were taken from the Scikit image library. After segmentation, the median GFP and mCherry intensities in each cell were calculated. For each cell, the mCherry channel was thresholded at 5% of maximal value in order to detect mitochondria, and median GFP intensity within mitochondria was calculated. This median GFP intensity and mCherry intensity were used in the following analyses. Characterization of mitochondrial volume per piece was derived from the voxel volume of segmented mitochondria.
Mitochondrial isolation and protease protection assay
Mitochondrial purification was based on a published protocol53. In brief, yeast cells expressing α-Syn-HA spGFP were cultured in YPD to an OD600 of about 0.3–0.4. Cells were collected by centrifugation and treated with Tris-DTT buffer (0.1 M Tris, 10 mM DTT, adjusted pH to 9.4). After washing with SP buffer (1.2 M sorbital, 20 mM KPi, pH 7.4), cells were treated with 0.5 mg/ml zymolase100T (US Biological) at 30 °C for 40 min. Spheroplasts were then washed with SEH buffer (0.6 M sorbital, 20 mM HEPES-KOH pH 7.4, 2 mM MgCl2, 1 mM EGTA pH 8.0, protease cocktail (P2714, Sigma), 10 µM benzamidine-HCl (B6506), 1 µg/ml 1,10-phenanthroline (P9375), PMSF 1 mM was added before use) and broken with a Dounce homogenizer. The homogenate was centrifuged at 1500×g (low speed) for 5 min at 4 °C. Supernatant was collected and centrifuged at 12,000×g (high speed) for 10 min at 4 °C. The pellet containing mitochondria was used for protease protection assays.
Purified mitochondria were washed three times with import buffer without ATP (3% w/v fatty acid-free BSA, 250 mM sucrose, 80 mM KCl, 5 mM MgCl2, 2 mM KH2PO4, 10 mM MOPS-KOH, pH 7.2) to remove the protease inhibitor. Then the mitochondria were spun down at 4 °C, 13,000 rpm for 10 min. Mitochondria were resuspended, and the same amount was added to four different 1.5-ml tubes. Group 1 was used as untreated total mitochondria. Group 2 was treated with protease K for 35 min at room temperature to assess protection by the mitochondrial outer membrane. Group 3 was treated with digitonin to permeabilize the outer membrane and Group 4 was treated with Triton X-100 to permeabilize the inner membrane. Then, Groups 3 and 4 underwent the same protease treatment as Group 2. The volume difference was equalized with the SEH buffer. Immediately after the treatment, all the samples were either taken for imaging or treated with PMSF and boiled for 15 min in SDS sample buffer for immunoblotting analysis.
Mammalian cell culture, transfection, and imaging
Human RPE1 (ATCC CRL4000, authenticated by ATCC based on Ep-16 antigen as determined by flow cytometry using the Ep-16 monoclonal antibody and cytokeratins as determined by immunocytochemistry using a pan-cytokeratin antibody) cells were cultured in Dulbecco’s Modified Eagle Medium: Nutrient Mixture F-12 (DMEM/F12) (GIBCO), supplemented with 10% (v/v) fetal bovine serum (FBS), 100 IU/ml penicillin and maintained at 37 °C with 5% CO2 in a humidified incubator. Transient transfections were performed with Lipofectamine 3000 (Invitrogen) according to the manufacturer’s instructions. RPE1 cells were double transfected with MTS–mCherry–GFP1–10 and α-Syn tagged with GFP11. After 24 or 48 h of transfection, samples were collected for flow cytometry analysis or confocal imaging.
Lenti vector construction, production, and transduction
The α-Syn spGFP expression lentiviral vectors were generated by cloning the α-Syn-GFP11 into a pTRE-Bsd vector and MTS-mCherry-GFP1–10 into a pEF1a-Neo vector, respectively. The pSFFV-NLN-Puro plasmid was synthesized by Twist Bioscience. The lentiviral vectors were transfected into HEK293FT cells together with packaging vectors psPAX2 and pMD2.G (1:1.5:1.5) to generate the lentiviruses. The viral supernatants were collected at 48 and 72 h after transfection and concentrated by ultracentrifugation for 2 h at 50,000×g. Viral particles were resuspended into a serum-free medium and stored at −80 °C. RPE1 cells were infected with inducible α-Syn spGFP expression lentiviral vectors with or without NLN overexpression, and mouse primary neurons were infected by lentivirus carrying NLN at DIV 6.
Mouse primary neuronal culture and α-Syn PFF transduction
Primary cortical and midbrain neurons were prepared from E18 pups of α-Syn spGFP transgenic mice and cultured in Neurobasal media supplemented with B-27, 0.5 mM L-glutamine, penicillin and streptomycin (Invitrogen, Grand Island, NY, USA) on cell culture plates or coverslips coated with poly-l-lysine (50 μg/ml, Sigma, #P1024–100MG). The neurons were maintained by changing the medium every 3–4 days. Mouse α-Syn PFF (final concentration 5 µg/mL) and phosphate-buffered saline (PBS) control were added at 7 days in vitro (DIV) and incubated for 10–21 days followed by imaging or biochemical experiments for toxicity assays. Overexpression of NLN by lentivirus transduction was performed one day prior to α-Syn PFF and PBS treatment.
Immunofluorescence analysis
RPE1 cells were cultured on fibronectin (5 μg/cm2, Sigma F2006)–coated glass bottom dishes (MatTek). Mouse primary neurons were cultured on poly-l-lysine (50 μg/ml) coated glass bottom dishes or coverslips. Fixation was performed using 4% paraformaldehyde (PFA) at 30 °C for 15 min, followed by three times PBS washing. Cells were blocked with goat serum 10% in blocking buffer (1× PBS buffer, 0.3% Triton X-100, and 10% goat serum) at room temperature for 1 h. Primary antibody incubation was performed at 4 °C overnight. After washing with three times PBS, cells were incubated with fluorescent secondary antibodies for 1 h at room temperature in the dark. After three times washing with PBS, cells were mounted with a Prolong glass antifade mountant (P36980, Invitrogen) for imaging.
Immunohistochemistry and quantitative analysis
Mice were transcardiac perfused with ice-cold PBS followed by fixation with 4% paraformaldehyde/PBS (pH 7.4) as described previously with somemodifications54,55. Brains were collected and postfixed for 24 h in 4% paraformaldehyde and cryoprotected in 30% sucrose/PBS (pH 7.4) solution for 1–2 weeks in 4 °C. All samples were frozen in an OCT buffer and 20 mm serial coronal sections were cut with a microtome (MICROM HM550). The cryosections were mounted on Superfrost Plus slides. For immunohistochemistry, the cryosections were surrounded by an ImmEdge pen circle and blocked with 10% goat serum/PBS plus 0.3% Triton X-100. Then incubated with primary antibodies, followed by incubation with goat anti-rabbit lgG Alexa fluor 647/405 antibody or goat anti-mouse lgG Alexa fluor 405 antibodies (Abcam). Sections were mounted with Prolong glass antifade mountant (P36980, Invitrogen) and cover slide sealed with nail polish for imaging. The images were taken by Zeiss LSM880 microscope and analysed with ImageJ and Imaris software.
Tissue lysate preparation
Mice were perfused with ice-cold 1× PBS, the brains were dissected from the skulls. The midbrain tissue was homogenized in a 1× RIPA Buffer (Sigma) and protease/phosphatase inhibitor cocktail (Cell Signaling Technology, 5872S) and lysed with a Dounce homogenizer. Lysates were centrifuged at 14,000 rpm (Eppendorf 5430R) at 4 °C for 30 min and the supernatant was collected. The protein concentration was measured via Pierce BCA protein assay Kit (Thermo 23225) and analyzed by immunoblot.
Cell lysate preparation
For RPE1 cells: Cells were washed with PBS and scraped and collected for centrifuge at 2000 rpm for 5 min at RT. The cell pellet was resuspended in lysis buffer which includes PIPA buffer supplemented with 0.1% SDS and Protease-Phosphatase inhibitor cocktail. Then the lysate was incubated on ice for 15 min, followed by sonication using QSONICA digital sonicator set as 70 amplitudes, pulse on/off 30 s each cycle for in total 5 min at 4 °C. Then the lysate was incubated on ice for an additional 15 min. The lysate was centrifuged at 13,000×g for 5 min at 4 °C and the supernatant was collected. Protein levels were quantified using the Pierce BCA protein assay Kit (Thermo 23225) with BSA standards and analyzed by immunoblot.
For mouse primary neurons: Cells were washed with PBS to remove debris. Cells were scraped in PBS and collected for centrifuge at 2000 rpm for 5 min at RT. Resuspend the cell pellet in lysis buffer (1% Triton X-100 and Protease/Phosphatase inhibitor in PBS) and vortex briefly. Then freeze-thaw on chilled water and dry ice three times with 15 s vortex after each thaw. The samples were centrifuged at 14,000 rpm for 30 min at 4 °C. The supernatants were collected for Triton X-100-soluble fraction. The cell pellet was resuspended in SDS cell lysis buffer (2%SDS, 1% Triton X-100, and Protease-Phosphatase inhibitor in PBS) and pipette several times to dissolve the pellet. Then freeze-thaw on chilled water and dry ice three times with 15 s vortex after each thaw. The samples were centrifuged at 14,000 rpm for 30 min at 4 °C. The supernatants were collected for SDS-soluble fraction. Protein levels were quantified using the Pierce BCA protein assay Kit (Thermo 23225) with BSA standards and analyzed by immunoblot.
For yeast cells: cells were centrifuged at 21,000×g for 2 min at 4 °C and removed the supernatants. Cells were washed with 1 ml ddH2O and centrifuged again at 21,000×g for 2 min at 4 °C. Then removed the supernatant and add 100 µl 1x LDS sample buffer with 40 mM DTT to resuspend cells. The cells were incubated at 100 °C for 10 min and vortexed with 100 µl glass beads for 1 min, then another 5 min incubation at 100 °C. The cells were centrifuged at 21,000×g for 2 min at room temperature and collected the supernatant for immunoblot.
Immunoblot analysis
Electrophoresis on 4–12% or 4–20% gradient SDS-PAGE gel was performed with proteins from mouse brain tissues, primary neurons, RPE1 cells, and yeast cells, as described above. The proteins were then transferred to PVDF membranes using iBlot2 (Thermo Fisher Scientific). The membranes were blocked with blocking solution (Odyssey blocking TBS buffer was used for fluorescent-dye conjugated secondary antibodies and Tris-buffered saline with 5% BSA and 0.1% Tween-20 was used for HRP-conjugated secondary antibodies) for 1 h and incubated with primary antibody at 4 °C overnight. The bands were visualized using Clarity Western ECL substrate (Bio-Rad) or fluorescent-dye conjugated secondary antibodies. Data were acquired using LI-COR imaging systems (LI-COR Biosciences) and analyzed with Image Studio (LI-COR Biosciences). All blots were processed in parallel and derived from the same experiments. Uncropped membranes are available as supplementary information.
Drug treatment
Cycloheximide (C4859, Sigma) was added to a final concentration of 100 μg/ml. CCCP (C2759, Sigma) was dissolved in DMSO or ethanol to 20 mM as stock and 25 μM was used to treat cells. MG132 (c2211, Sigma) was dissolved in DMSO and 80 μM was used to treat yeast cells.
Membrane potential measurements
Tetramethylrhodamine methyl ester (TMRM) (Sigma-Aldrich, Cat# T5428–25MG) staining was performed for cells without mCherry labels. Cells were incubated with 2.5 µM TMRM at 30 °C for 10 min and washed three times before recording. Mammalian cells were incubated with 100 nM MitoView™ 405 dye (Biotium, Cat# 70070-T) at 37 °C for 15 min and directly for imaging without washing.
TTC staining assay
TTC staining assays were performed using the agar medium overlay method35. Yeast strains were growing on normal selected plates and cultured at 30 °C for 48 h, then the melted soft agar (1.5%) containing 1 mg/ml TTC was gently poured onto the colonies and incubated at room temperature for 2 h. The TTC staining activity was judged by the color of the colonies, as the white compound can be enzymatically changed to red in normal respiratory-competent cells but not in respiration-deficient cells. The plates were documented by a document scanner and analyzed by ImageJ software.
Yeast cell fixation and DAPI staining
Yeast cells were cultured in SC medium overnight at 30 °C. Then they were refreshed in SC medium for at least 3 h at 30 °C to an OD600 around 0.1–0.25. The cells were spun down and removed medium, added 4% paraformaldehyde, and incubated at room temperature for 15 min. Then washed once with KPO4/sorbitol and resuspended in KPO4/sorbitol containing 0.2 µg/ml DAPI until imaging by a Nikon Ti-E inverted fluorescence microscope.
Detergent resistance assay
Log-phase yeast cells cultured in YPD were collected by centrifugation (5000×g, 6 min) and then washed once with ddH2O, followed by 10 mM DTT treatment for 5 min (pH 9.3) at 30 °C. The cells were then washed with sorbitol buffer (pH 7.5, 1.2 M sorbitol) followed by 8 min digestion with 1 mg/ml Zymolyase 100 T in Zymolyase buffer. The cells then were washed twice with SEH buffer (0.6 M sorbitol, 20 mM HEPES-KOH pH 7.4, 2 mM MgCl2, protease cocktail (sigma), PMSF 1 mM was added before use) to remove the Zymolyase and were lysed with a dounce homogenizer. The homogenate was centrifuged at 1500×g for 5 min at 4 °C, and then the supernatant was collected and centrifuged at 12,000×g for 10 min at 4 °C. The pellet was resuspended and imaged to ensure mitochondria were intact. Then 1% Triton X-100 was added and incubated on ice for 10 min before confocal imaging. The mitochondrial membranes were removed by detergent extraction, which was confirmed by imaging.
Yeast growth assays
For recording yeast growth, cells of the indicated genotypes were cultured in corresponding media. Overnight cultures were refreshed for 4 h at 30 °C and the OD600 of the cells was measured and adjusted to 0.04 in 200 μL and added to a 96-well plate. The wells along the plate’s perimeter were filled with 200 μL medium without sample to avoid evaporation and the plate was sealed with parafilm. The optical density (OD) at 600 nm was continuously monitored at 30 °C using a Tecan Infinite M200 Pro every 30 min. The data were extracted and analyzed using Magellan 7 software and the R package GroFit (https://cran.r-project.org/src/contrib/Archive/grofit/)56.
Flow cytometry
Cells (yeast or mammalian) were analyzed on the Attune NxT flow cytometer (Thermo Fisher Scientific) equipped with appropriate filter sets. Appropriate gating was applied for single-cell populations. Gating for fluorescent reports was based on negative controls. Statistical analysis was performed with GraphPad Prism software.
RNA-seq analysis
Single-cell RNA-seq data from iPSC-derived DA neurons were obtained from EMBL-EBI Biostudies (Accession # E-MTAB-7303). Raw counts were log normalized with top variable genes according to published protocols57. To remove potential technical confounders, we applied f-scLVM and regressed out hidden factors58. Beta-Poisson model was used to estimate differential expression between PD and normal cells59. Bulk RNA-seq from GTEx V8 brain analysis tissues were obtained from the GTEx portal (https://gtexportal.org/home/datasets). After log normalization, we regressed out covariates similar to the GTEx consortium pipeline including PEER factors, genotype principal components, donor sex, and sequencing batch to obtain normalized expression levels.
Quantification and statistical analysis
Please refer to the Figure legends or the Method details for a description of the sample size and statistical details. Statistical analysis was performed with Prism 5 (GraphPad Software, La Jolla, USA) and p values <0.05 were considered significant.
Data availability
All data needed to evaluate the conclusions are available in the main text or the supplementary materials. Additional data and materials related to this study can be requested from the authors. Requests for resources and reagents should be directed to and will be fulfilled by the corresponding author, RL (rong@jhu.edu). Single-cell RNA-seq data were obtained from EBI (accession E-MTAB-7303). Bulk RNA-seq data was obtained from GTEx v8 (https://gtexportal.org/home/datasets). No new datasets were generated.
Change history
23 July 2024
Supplementary Videos 1-4 were originally published with the wrong file names. The original article has been corrected.
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Acknowledgements
The authors acknowledge the joint participation by the Diana Helis Henry Medical Research Foundation Parkinson’s Disease Program H-2017 through its direct engagement in the continuous active conduct of medical research in conjunction with The Johns Hopkins Hospital and the Johns Hopkins University School of Medicine. This work was initially supported by the grant R35 GM118172 from the NIH and subsequently a grant from ReStem Biotech to R.L. This work was supported by the Office of the Director and the National Institute of General Medical Sciences of the National Institutes of Health under award number S10OD023548. This work was supported in part by the grants from the JPB Foundation to T.M.D. T.M.D. is the Leonard and Madlyn Abramson Professor in Neurodegenerative Diseases. The authors thank the transgenic mouse core at Johns Hopkins University.
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Conceptualization: X.Z. and R.L.; methodology: X.Z., L.R., H.W., J.Z., T.L., G.S., Y.D., Y.W., G.B., A.S., R.C., and S.R.; investigation: X.Z. and L.R.; writing: X.Z., L.R., J.Z., V.L.D., T.M.D., and R.L.; supervision and main funding acquisition: R.L.
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A patent titled “Treatment of alpha-synuclein-mediated disease” has been filed on which X.Z. and R.L. are inventors.
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Zhang, X., Ruan, L., Wang, H. et al. Enhancing mitochondrial proteolysis alleviates alpha-synuclein-mediated cellular toxicity. npj Parkinsons Dis. 10, 120 (2024). https://doi.org/10.1038/s41531-024-00733-y
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DOI: https://doi.org/10.1038/s41531-024-00733-y