[ad_1]
Summary
Practical analyses of genes linked to heritable types of Parkinson’s illness (PD) have revealed basic insights into the organic processes underpinning pathogenic mechanisms. Mutations in PARK15/FBXO7 trigger autosomal recessive PD and FBXO7 has been proven to control mitochondrial homeostasis. We investigated the extent to which FBXO7 and its Drosophila orthologue, ntc, share useful homology and explored its position in mitophagy in vivo. We present that ntc mutants partially phenocopy Pink1 and parkin mutants and ntc overexpression supresses parkin phenotypes. Moreover, ntc can modulate basal mitophagy in a Pink1- and parkin-independent method by selling the ubiquitination of mitochondrial proteins, a mechanism that’s opposed by the deubiquitinase USP30. This basal ubiquitination serves because the substrate for Pink1-mediated phosphorylation that triggers stress-induced mitophagy. We suggest that FBXO7/ntc works in equilibrium with USP30 to offer a checkpoint for mitochondrial high quality management in basal situations in vivo and presents a brand new avenue for therapeutic approaches.
Quotation: Sanchez-Martinez A, Martinez A, Whitworth AJ (2023) FBXO7/ntc and USP30 antagonistically set the ubiquitination threshold for basal mitophagy and supply a goal for Pink1 phosphorylation in vivo. PLoS Biol 21(8):
e3002244.
https://doi.org/10.1371/journal.pbio.3002244
Educational Editor: Yi-Hsien Su, Academia Sinica, TAIWAN
Acquired: April 7, 2023; Accepted: July 11, 2023; Revealed: August 3, 2023
Copyright: © 2023 Sanchez-Martinez et al. That is an open entry article distributed beneath the phrases of the Inventive Commons Attribution License, which allows unrestricted use, distribution, and replica in any medium, offered the unique creator and supply are credited.
Information Availability: All information wanted to judge the conclusions within the paper are current within the paper and/or the Supplementary Supplies. This research contains no information deposited in exterior repositories.
Funding: This work was supported by MRC core funding (MC_UU_00028/6 to A.J.W.) and by the Basque Authorities Postdoctoral Fellowship (POS_2022_2_0045 and wage to A.M.). The funders had no position in research design, information assortment and evaluation, resolution to publish, or preparation of the manuscript.
Competing pursuits: The authors have declared that no competing pursuits exist.
Abbreviations:
ADP,
adenosine diphosphate; CNS,
central nervous system; OMM,
outer mitochondrial membrane; PD,
Parkinson’s illness; SEM,
scanning electron microscopy; siRNA,
small interfering RNA
Introduction
Parkinson’s illness (PD) is the second commonest neurodegenerative dysfunction. Autosomal recessive mutations within the genes encoding the mitochondrial kinase PINK1 (PINK1) and the E3 ubiquitin ligase Parkin (PRKN) are related to early-onset parkinsonism. These genes have been proven to perform in a typical mitochondrial high quality management pathway whereby mitochondria are degraded by autophagy (mitophagy). Briefly, PINK1 is partially imported to wholesome polarised mitochondria the place it’s cleaved and subsequently degraded within the cytosol [1]. Upon mitochondrial depolarisation, PINK1 is stabilised on the outer mitochondrial membrane (OMM) the place it phosphorylates ubiquitin-Ser65 (pS65-Ub) conjugated to OMM proteins [2,3]. This acts as a sign for Parkin to be recruited and phosphorylated, relieving its autoinhibitory conformation, and permitting it to additional ubiquitinate OMM proteins in shut proximity [4,5] that can function further substrates for PINK1 making a feed-forward mechanism [6]. Counteracting mitochondrial ubiquitination, USP30, a mitochondrial outer membrane deubiquitinase, removes ubiquitin (Ub) from Parkin substrates appearing as a adverse regulator of mitophagy [7]. The buildup of pS65-Ub on the OMM triggers the recruitment of autophagy receptors, which promote autophagosome recruitment and, finally, degradation of the broken mitochondria [8,9].
Nonetheless, most of our understanding of the perform of PINK1 and Parkin come from the utilisation of mitochondrial uncouplers or inhibitors in cultured cells, normally at the side of Parkin overexpression [8,10]. Therefore, there’s a want to grasp these mechanisms in additional physiological mannequin techniques. Drosophila melanogaster fashions have delivered basic insights into the physiological perform of the homologues Pink1 and parkin (adopting FlyBase nomenclature), offering a wonderful system to review mitochondrial homeostasis [11–16]. Curiously, whereas proteomic evaluation of mitochondrial turnover in Drosophila helps a job of Pink1/parkin in mitochondrial high quality management [17], research utilizing pH-sensitive fluorescent mitophagy reporters confirmed that Pink1 and parkin had minimal affect on basal mitophagy [18–21]. Thus, many questions endure relating to the mechanisms of motion of Pink1/parkin in mitochondrial high quality management in vivo and the potential contribution of different key gamers.
Mutations within the gene encoding F-box protein 7 (FBXO7) have been discovered to trigger autosomal recessive early-onset parkinsonism just like these brought on by mutations in PINK1 and PRKN [22,23], motivating a necessity to grasp how FBXO7 is said to PINK1/Parkin biology. F-box domain-containing proteins are important elements of the SCF-type (Skp1-Cul1-F-box) E3-ubiquitin ligase complexes, that are liable for recruiting Ub goal substrates by way of the F-box area [24]. FBXO7 has each SCF-dependent and SCF-independent actions [25,26]. Though it has been beforehand proven to cooperate with PINK1 and Parkin in mitophagy [27], how this happens in vivo is poorly characterised warranting additional investigation in an animal mannequin. Drosophila encode a single homologue of FBXO7 referred to as nutcracker (ntc), which was recognized in a display for genes that management caspase activation throughout a late stage of spermatogenesis [28]. ntc shares sequence, construction, and a few useful similarities with mammalian FBXO7 [26,28,29] and has been proven to control proteasome perform by way of its binding associate PI31, an interplay that’s conserved in FBXO7 [28,29]. Thus, Drosophila offers a genetically tractable system to review position of ntc/FBXO7 in mitochondrial high quality management in vivo.
Mitochondrial high quality management mechanisms are believed to have an essential pathophysiological position in PD. Nonetheless, how this course of is orchestrated in vivo and the upstream elements concerned are nonetheless unclear. Due to this fact, we sought to research the connection between ntc, Pink1 and parkin, and their position in mitophagy, particularly basal mitophagy. We have now discovered that ntc is ready to compensate for the absence of parkin however not Pink1. Furthermore, ntc performs an essential position in selling basal mitophagy in a Pink1- and parkin-independent method, which is opposed by its counteracting associate USP30. This mechanism units a threshold for basal mitophagy by regulating the steady-state ranges of ubiquitin on OMM proteins, subsequently modulating the degrees of pS65-Ub. Collectively, we offer proof of a novel checkpoint for basal mitophagy that might doubtlessly function therapeutic goal for neurodegenerative issues.
Outcomes
Overexpression of ntc can rescue parkin however not Pink1 mutant phenotypes
The F-box area localised within the C-terminal of Drosophila ntc shares appreciable sequence similarity with that of human FBXO7 [28]. Each proteins have a conserved valine residue concerned in substrate recognition, together with widespread interacting companions, e.g., PI31 [26,29]. Nonetheless, a useful conservation in between FBXO7 and ntc has not been formally examined in vivo. Notably, it has been proven that FBXO7 functionally interacts with mammalian PINK1 and Parkin and genetically interacts with parkin in Drosophila [27]. Due to this fact, as an preliminary exploration of the useful homology between ntc and FBXO7, we examined for the same genetic interplay between ntc and parkin. Drosophila parkin mutants current a number of disease-relevant phenotypes, together with locomotor deficits, dopaminergic neurodegeneration, and a extreme mitochondrial disruption resulting in flight muscle degeneration [13,14]. Strikingly, overexpression of ntc by the robust ubiquitous daughterless (da)-GAL4 driver considerably rescued these parkin phenotypes (Fig 1A–1D). On the molecular degree, we noticed that ntc can also be in a position to lower the steady-state ranges of the Drosophila Mitofusin (MFN1/MFN2) homologue, Marf, which has been beforehand proven to be elevated in parkin mutants [16] (Fig 1E). These outcomes assist a useful homology between FBXO7 and ntc, and, furthermore, point out that ntc can at the very least partially substitute for parkin in vivo.
Fig 1. ntc overexpression is ready to rescue parkin however not Pink1 mutants.
(A) Climbing capacity of 2-day-old management and parkin mutants alone or with transgenic expression of ntc with the ever present driver da-GAL4. Chart present imply ± 95% CI and n values. Kruskal–Wallis nonparametric take a look at with Dunn’s submit hoc take a look at correction for a number of comparisons; **** P < 0.0001. (B) Quantification of dopaminergic neurons (PPL1 cluster) in 30-day-old management and parkin mutants alone or with transgenic expression of ntc with the ever present driver da-GAL4. Information represented as imply ± SEM; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; **** P < 0.0001. (C) Toluidine blue staining and (D) TEM evaluation of thoraces from 2-day-old management and parkin mutant alone or with transgenic expression of ntc with the ever present driver da-GAL4. Scale bars; high = 200 μm, center = 10 μm, backside = 2 μm. (E) Immunoblot evaluation from complete fly lysates of Marf steady-state ranges from 2-day-old management and parkin mutants alone or with transgenic expression of ntc with the ever present driver da-GAL4. Numbers beneath blots indicated the imply ± SD of Marf ranges normalised to ATP5A loading management throughout 3 replicate experiments. (F) Climbing and (G) flight capacity of 2-day-old management and Pink1 mutants alone or with transgenic expression of ntc with the ever present driver da-GAL4. Chart present imply ± 95% CI; n proven in chart. Kruskal–Wallis nonparametric take a look at with Dunn’s submit hoc take a look at correction for a number of comparisons; **** P < 0.0001. (H) Immunoblot evaluation from complete fly lysates of Marf steady-state ranges from 2-day-old management and Pink1 mutants alone or with transgenic expression of ntc with the ever present driver da-GAL4. Numbers beneath blots indicated the imply ± SD of Marf ranges normalised to ATP5A loading management throughout 3 replicate experiments. (I) Evaluation of the compound eye by (high panels) mild microscopy or (center and backside panels) SEM of 2-day-old management, overexpression of ntc, Pink1 or each mix utilizing the GMR-GAL4 driver. Scale bars; high and center = 100 μm, backside = 50 μm. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information. SEM, scanning electron microscopy; TEM, transmission electron microscopy.
In distinction, assessing the useful relationship between ntc and Pink1 in an analogous method, ntc overexpression was unable to rescue climbing or flight locomotor defects of Pink1 mutants, nor the elevated Marf steady-state ranges (Fig 1F–1H). Moreover, the neurodegenerative “tough eye” phenotype—generally used for testing genetic interactors [30,31]—induced by Pink1 overexpression, in a robustly stereotyped method, was not enhanced by ntc overexpression as beforehand proven for parkin [15]. These outcomes mirror equal analyses of FBXO7 [27] and point out that Pink1 and ntc don’t clearly genetically work together.
ntc mutants partially phenocopy Pink1/parkin mutants
If ntc performs comparable features to the Pink1/parkin pathway in Drosophila, we reasoned that ntc mutants might phenocopy Pink1/parkin mutants. Supporting this, ntc mutants, like Pink1 and parkin mutants, are male sterile as a consequence of faulty sperm individualization [11–13,28,32]. To increase this, we assessed ntc mutants for traditional Pink1/parkin phenotypes as described above. ntc mutants homozygous for an amorphic nonsense mutation (ntcms771; abbreviated as ntc–/–) confirmed a marked defect in climbing and flight capacity (Fig 2A and 2B). We verified this was doubtless particular to ntc by assessing a hemizygous situation (ntc–/Df) with comparable outcomes (Fig 2A and 2B). Importantly, transgenic re-expression of ntc was in a position to considerably rescue the climbing and flight deficit (Fig 2A and 2B), confirming that the phenotype is particularly brought on by lack of ntc perform. Additionally just like Pink1/parkin mutants, ntc mutants confirmed a dramatically shortened lifespan, with median survival of roughly 7 days in comparison with roughly 55 days for controls (Fig 2C), which was virtually utterly rescued by transgenic re-expression of ntc (Fig 2C).
Fig 2. Lack of ntc has motor and lifespan deficits, no gross impact on mitochondria however elevated sensitivity to oxidative stress.
Evaluation of (A) climbing and (B) flight talents of 2-day-old management and ntc mutants alone or with transgenic expression of ntc with the ever present driver da-GAL4. Chart present imply ± 95% CI and n values. Kruskal–Wallis nonparametric take a look at with Dunn’s submit hoc take a look at correction for a number of comparisons; ** P < 0.01, *** P < 0.001, **** P < 0.0001. (C) Lifespan assay of management and ntc mutants alone or with transgenic expression of ntc with the ever present driver da-GAL4; n proven in chart. Log rank (Mantel–Cox) take a look at; **** P < 0.0001. (D) Quantification of dopaminergic neurons (PPL1 cluster) in 10-day-old management and ntc mutants alone. Information represented as imply ± SEM; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction. (E) (High panel) Immunohistochemistry with anti-ATP5A staining and (backside panel) TEM of 2-day-old grownup thoraces from management and ntc mutants. Scale bars; high = 10 μm, backside = 2 μm. (F) Mitochondrial morphology in motoneurons from the ventral nerve twine of third instar larvae in management and ntc mutants, overexpressing mito-GFP with the pan-neuronal driver nSyb-GAL4. Scale bars = 10 μm. (G) Oxygen consumption charge from advanced I and complicated II of 2-day-old management and ntc mutants. Information represented as imply ± SEM; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction. (H) ATP ranges of 2-day-old management and ntc mutants alone or with transgenic expression of ntc with the ever present driver da-GAL4. Information represented as imply ± SEM; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, ** P < 0.01. (I) Lifespan assay of management and ntc mutants handled with 10 μm paraquat; n proven in chart. Log rank (Mantel–Cox) take a look at; **** P < 0.0001. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information. TEM, transmission electron microscopy.
Nonetheless, in distinction to Pink1/parkin mutants, we didn’t noticed lack of DA neurons within the PPL1 clusters of ntc mutants, though the brief lifespan restricted the evaluation to solely 10-day-old flies (Fig 2D). Likewise, immunohistochemical analyses of ntc mutants revealed no obvious disruption of mitochondrial morphology or integrity at confocal or electron-microscopy ranges in flight muscle (Fig 2E) or larval central nervous system (CNS) (Fig 2F). Analysing mitochondrial respiratory capability, ntc mutants weren’t constantly completely different from controls regardless of a downward development (Fig 2G). However, ATP ranges have been diminished in ntc mutants (Fig 2H), which was rescued by re-expression of wild-type ntc.
Oxidative stress is a constant function of PD pathology and regular ageing. Many fashions of PD present sensitivity to oxidative stressors similar to paraquat (PQ), together with Drosophila parkin mutants [33,34]. Equally, ntc mutants additionally confirmed elevated sensitivity to PQ publicity (Fig 2I). Collectively, these outcomes present that lack of ntc causes beforehand undescribed phenotypes that affect organismal vitality just like, but additionally completely different from, Pink1/parkin mutants, although the consequences are typically much less extreme.
ntc regulates basal mitophagy and antagonises USP30 in a Pink1/parkin-independent method
Earlier work confirmed that FBXO7 facilitates PINK1/Parkin-mediated mitophagy upon mitochondrial depolarisation in cultured cells [27]. Thus, we subsequent sought to find out whether or not Drosophila ntc acts to advertise mitophagy in vivo. The mito-QC reporter offers a delicate and sturdy reporter for mitophagy whereby the GFP of OMM-localised tandem mCherry-GFP is quenched within the acidic lysosome, revealing mitolysosomes as “mCherry-only” puncta [35]. Importantly, within the absence of potent mitochondrial toxins—not readily relevant in vivo—the steady-state evaluation of mito-QC offers an perception into basal mitophagy [20,36]. Quantifying basal mitophagy in larval neurons revealed a major discount in ntc mutants in comparison with controls, which was rescued upon re-expression of ntc (Fig 3A and 3B). Conversely, ntc overexpression considerably elevated basal mitophagy (Fig 3C and 3D). To confirm these outcomes, we analysed another mitophagy reporter with a mitochondrial matrix-targeted model of mito-QC, termed mtx-QC, with equal outcomes (S1A and S1B Fig). Thus, ntc is each mandatory and enough to advertise basal mitophagy. Equally, transgenic expression of FBXO7 additionally elevated mitophagy in larval neurons, underscoring their shared performance (S2A and S2B Fig). Additional validating these ends in human cells stably expressing the mito-QC reporter [37], small interfering RNA (siRNA)-mediated knockdown of FBXO7 additionally considerably diminished basal mitophagy (S2C–S2E Fig). Collectively, these outcomes assist a conserved perform of FBXO7/ntc in regulating basal mitophagy.
Fig 3. ntc impacts basal mitophagy and counteracts USP30.
(A, B) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and ntc mutant alone or with transgenic expression of ntc with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; ** P < 0.01. Scale bars = 10 μm. (C, D) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and transgenic expression of ntc with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; *** P < 0.001. Scale bars = 10 μm. (E, F) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and knockdown of USP30 with the pan-neuronal driver nSyb-GAL4 alone or together with ntc mutant. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, *** P < 0.001. Scale bars = 10 μm. (G) Climbing capacity of 10-day-old flies overexpressing USP30 alone or together with ntc or parkin with the ever present driver Act-GAL4. Chart present imply ± 95% CI; n proven in chart. Kruskal–Wallis nonparametric take a look at with Dunn’s submit hoc take a look at correction for a number of comparisons; **** P < 0.0001. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information. CNS, central nervous system.
Whereas stress-induced mitophagy has been extensively studied, particularly in cultured cell traces, mechanisms regulating basal mitophagy are poorly characterised in vivo. Underneath basal situations lack of USP30, a longtime regulator of mitophagy, results in accumulation of ubiquitinated OMM proteins, and sustained USP30 loss or inhibition promotes mitophagy in vitro [38–42], however in vivo characterisation stays restricted. Upon USP30 knockdown, we noticed a major improve in basal mitophagy in larval neurons, utilizing each the mito-QC (Fig 3E and 3F) and mtx-QC reporters (S1A and S1B Fig), and in grownup flight muscle (S3A and S3B Fig). These outcomes point out that USP30 certainly inhibits basal mitophagy in vivo as anticipated. Importantly, we discovered that the induction of basal mitophagy by lack of USP30 requires the exercise of ntc because it was abolished in an ntc mutant background (Fig 3E and 3F).
As an orthogonal strategy to check for genetic interplay on the organismal degree, we discovered that whereas USP30 knockdown didn’t trigger any gross defect in grownup viability or behaviour (S3C Fig), USP30 overexpression brought about a locomotor defect (Fig 3G). This phenotype was utterly suppressed by co-expression of ntc (Fig 3G), in step with the opposing actions of Ub-ligase and deubiquitinase and supporting the concept of ntc appearing upstream of USP30. Curiously, whereas parkin overexpression additionally suppressed the USP30 overexpression phenotype as anticipated (S3D Fig), different Ub-ligases linked to mitophagy, Mul1 and March5 [39,43–47], confirmed no suppression of this phenotype (S3D Fig). Furthermore, just like parkin loss [20] or overexpression (S3E and S3F Fig), lack of Mul1 or March5 had no impact on basal mitophagy (S3G–S3J Fig). Collectively, these information spotlight the specificity of ntc and USP30 as essential and opposing regulators of basal mitophagy.
Given the beforehand established hyperlinks between FBXO7 and USP30 with toxin-induced PINK1/Parkin mitophagy in cultured human cells, we subsequent analysed whether or not the induction of basal mitophagy by ntc overexpression or USP30 knockdown concerned the Pink1/parkin pathway in vivo. As beforehand reported [20], the absence of parkin or Pink1 didn’t affect basal mitophagy in larval neurons (Fig 4A–4D). Nonetheless, overexpression of ntc was nonetheless in a position to induce mitophagy within the absence of both parkin or Pink1 (Fig 4A–4D). Likewise, USP30 knockdown additionally elevated mitophagy independently of parkin and Pink1 (Fig 5A–5D), in step with in vitro findings [38,39,48,49]. Notably, the induction of mitophagy by USP30 knockdown in Pink1 or parkin mutant backgrounds required the perform of ntc (Fig 5A–5D), additional underscoring the significance of ntc in basal mitophagy.
Fig 4. ntc regulates basal mitophagy in a parkin- and Pink1-independent method.
(A, B) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and parkin mutant alone or with transgenic expression of ntc with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, ** P < 0.01. Scale bars = 10 μm. (C, D) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and Pink1 mutant alone or with transgenic expression of ntc with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, ** P < 0.01. Scale bar = 10 μm. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information. CNS, central nervous system.
Fig 5. ntc is required for USP30 knockdown induced basal mitophagy within the absence of parkin or Pink1.
(A, B) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management, knockdown of USP30 with the pan-neuronal driver nSyb-GAL4 alone or together with ntc mutants in a parkin mutant background. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, ** P < 0.01, *** P < 0.001. Scale bars = 10 μm. (C, D) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management, knockdown of USP30 with the pan-neuronal driver nSyb-GAL4 alone, or together with ntc mutants in a Pink1 mutant background. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, ** P < 0.01. Scale bar = 10 μm. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information. CNS, central nervous system.
Normal autophagy isn’t grossly affected upon USP30 or ntc manipulations
Though beforehand validated as a dependable mitophagy reporter in vivo, we nonetheless verified that the elevated mitolysosome formation (mitophagy) by ntc overexpression or USP30 knockdown happens by way of canonical autophagy flux because it was abrogated within the absence of Atg8a, the primary fly homologue of human ATG8 members of the family GABARAP/LC3, in each wild-type or parkin mutant backgrounds (S4A–S4D Fig). However, the noticed improve in mitolysosomes could possibly be as a consequence of a rise in nonselective autophagy [50,51]. Thus, we used plenty of well-established orthogonal assays to evaluate the impact of those mitophagy-inducing manipulations on common autophagy.
First, we examined the extent of lipidated Atg8a (Atg8a-II) that’s integrated into autophagosomal membranes and is used as a sign of autophagy induction [52,53]. Neither USP30 knockdown, ntc overexpression nor ntc loss had any impact on autophagy induction (Fig 6A and 6B). Equally, the steady-state ranges of ref(2)P, the homologue of mammalian p62, which accumulates upon autophagic blockage [54], was additionally not affected in any of the situations (Fig 6C and 6D). We additionally analysed the autophagy flux reporter GFP-mCherry-Atg8a [55–57]. Quantification of mCherry-Atg8a puncta (autolysosomes) confirmed no modifications upon manipulating ranges of USP30 or ntc (Fig 6E and 6F). Collectively, these outcomes assist that the impact noticed upon manipulation of USP30 or ntc is particular for basal mitophagy and never a consequence of altered common autophagic flux.
Fig 6. Manipulating mitophagy by altering ranges of USP30 or ntc don’t impact common autophagy.
(A, B) Consultant immunoblot from complete fly lysates of Atg8a (non-lipidated) I and II (lipidated) in management, USP30 knockdown, ntc overexpression, and ntc mutant with the ever present driver da-GAL4. Information represented as imply ± SD; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction. (C, D) Consultant immunoblot from complete fly lysates of ref(2)P/p62 in management, USP30 knockdown, ntc overexpression, and ntc mutant with the ever present driver da-GAL4. Information represented as imply ± SD; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction. (E, F) Confocal microscopy evaluation and quantification of the red-only (autolysosomes) puncta per cell of larval CNS expressing the autophagy flux marker GFP-mCherry-Atg8a together with USP30 knockdown, ntc overexpression, and ntc mutant with the pan-neuronal driver nSyb-GAL4. Information represented as imply ± SEM; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; scale bar = 10 μm. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information. CNS, central nervous system.
ntc will increase basal mitochondrial ubiquitin and promotes phospho-ubiquitin formation
To realize a mechanistic perception into the regulation of basal mitophagy by ntc and USP30, we analysed their affect on mitochondrial ubiquitination. According to their molecular features, each ntc overexpression and USP30 knockdown elevated the whole quantity of ubiquitin current in mitochondria-enriched fractions beneath basal situations (Figs 7A and 7B and S5A), whereas whole Ub remained unchanged (S5B Fig). Certainly, latest research point out that USP30 acts to take away preexisting OMM ubiquitin beneath basal situations, influencing the brink wanted for Parkin activation [38,58].
We have now just lately described that lack of parkin causes a major accumulation of pS65-Ub, in step with parkin selling the degradation of pS65-Ub labelled mitochondria [59]. In contrast to lack of parkin, lack of ntc alone didn’t result in pS65-Ub construct up (Fig 7C and 7D). Nonetheless, parkin:ntc double mutants lead to a major discount within the amassed pS65-Ub ranges (Fig 7C and 7D), and overexpression of ntc within the parkin mutant background elevated the quantity of pS65-Ub in comparison with parkin mutants alone (Fig 7E and 7F). These outcomes are in step with ntc selling basal mitochondrial ubiquitination, which is phosphorylated by Pink1 to drive mitophagy. Thus, collectively these information counsel that ntc and USP30 work antagonistically to arrange an OMM ubiquitin threshold wanted for subsequent mitochondrial clearance.
Fig 7. Each ntc overexpression and USP30 depletion promote accumulation of ubiquitin within the mitochondria and are mandatory for pS65-Ub formation.
(A) Consultant immunoblot and quantification of (B) mitochondrial ubiquitin (P4D1) in management, ntc overexpression and USP30 knockdown with the ever present driver da-GAL4. Information represented as imply ± SD; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05. (C, D) Consultant immunoblot and quantification of mitochondrial pS65-Ub in parkin mutants, ntc mutants, and the double parkin:ntc mutant. Information represented as imply ± SD; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, **** P < 0.0001. (E, F) Consultant immunoblot and quantification of mitochondrial pS65-Ub in management and parkin mutants alone or with the transgenic expression of ntc with the ever present driver da-GAL4. Information represented as imply ± SD; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; **** P < 0.0001. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information.
Dialogue
Mutations in FBXO7 have been linked to familial parkinsonism however the mechanisms of pathogenesis are poorly understood [22,23]. We have now characterised the putative Drosophila homologue, ntc, to evaluate the useful homology with FBXO7 and its potential as a mannequin to grasp the perform of FBXO7 in vivo.
FBXO7 has been genetically linked to Drosophila Pink1 and parkin and proven to facilitate PINK1/Parkin-mediated mitophagy in vitro. The Drosophila fashions have offered precious insights into Pink1/parkin biology and genetic interactors have highlighted complementary pathways in mitochondrial homeostasis. Right here, we present that ntc mutants partially phenocopy Pink1/parkin phenotypes in locomotor perform, lifespan, and sensitivity to paraquat, in step with a job in mitochondria high quality management. We additionally noticed the identical genetic relationship as beforehand reported for FBXO7 [27], specifically, that overexpression of ntc can rescue all parkin mutant phenotypes however not for Pink1 mutants. It’s price noting that in our earlier research [27], we carried out an preliminary characterisation of ntc because the putative homologue of FBXO7 however noticed no phenotypes paying homage to Pink1/parkin mutants and provisionally concluded that ntc was not a useful homologue of FBXO7. Nonetheless, these analyses have been performed utilizing a hypomorphic allele (ntcf07259) in homozygosity, weakening the phenotype penetrance. Within the present research, we now have carried out our analyses with an amorphic allele, in parallel to research evaluating transgenic expression of ntc with FBXO7, therefore, supporting a useful homology between ntc and FBXO7.
Importantly, FBXO7 has beforehand been proven to facilitate the PINK1/Parkin pathway to advertise stress-induced mitophagy in vitro [27,60]. Nonetheless, whether or not it regulates mitophagy in vivo is poorly characterised. Certainly, mitophagy itself can happen by way of completely different regulators and stimuli and represents solely one in every of a number of mechanisms of mitochondrial high quality management [61,62]. For instance, most research have utilised a mitochondrial toxification stimulus to mannequin substantial “injury;” nonetheless, basal mitophagy happens as a housekeeping-type mechanism to control mitochondrial amount or piecemeal turnover. The event of genetically encoded mitophagy reporters has offered a strong strategy to observe each stress-induced and basal mitophagy in vivo. We have now proven right here that ntc is ready to modulate basal mitophagy in a Pink1/parkin-independent method, which is conserved by FBXO7 in human cell traces. Curiously, a latest research emphatically described FBXO7 as performing no position in stress-induced Parkin-dependent mitophagy [63], although basal mitophagy was not particularly analysed. Related to this, further work from our group [64] and others [65] has proven that basal mitophagy will increase with age, presumably in response to age-related stresses, which is selectively affected by Pink1/parkin highlighting a physiologically related stress. The truth that FBXO7 doesn’t robustly have an effect on acute toxin-induced mitophagy in cultured cells [63] doubtless displays the exaggerated and non-physiological nature of this strategy that masks extra delicate, physiologically related processes.
Compared to stress-induced mitophagy, the regulation of basal mitophagy is poorly characterised, significantly in metazoa. Whereas early research confirmed the mitochondrial deubiquitinase USP30 antagonises PINK1/Parkin-mediated mitophagy [41,66,67], latest research have established a job in basal mitophagy [38–40,42]. The rising view suggests the primary position of USP30 is appearing as a part of a high quality management course of for intra-mitochondrial proteins throughout import by way of the translocon [39,42] and that basal mitochondrial ubiquitination offers the initiating substrate for PINK1 signalling. This paradigm requires an Ub ligase to offer basal ubiquitination that USP30 acts upon. Whereas Phu and colleagues [42] steered that this can be mediated by way of March5, this was not concurred by Ordureau and colleagues [39]. Thus, the ligase offering the basal ubiquitination is unclear, and the position of USP30 in basal mitophagy in vivo remained to be established.
Right here, we demonstrated that knockdown of USP30 in vivo does certainly improve basal mitophagy in neurons and muscle, in step with the in vitro research. This additionally established a paradigm for a extra deeply evaluation of ntc’s perform in basal mitophagy. Whereas the induction of basal mitophagy by USP30 knockdown is Pink1/parkin-independent as anticipated, it nonetheless required the perform of ntc. In distinction, overexpression of parkin or depletion of both Mul1 or March5 didn’t have an effect on neuronal basal mitophagy in our assay. The antagonistic relationship between USP30 and parkin was additionally evident from genetic interactions on the organismal degree (rescue of a climbing defect), as anticipated, and was recapitulated with ntc. Such an interplay was additionally not evident with Mul1 and March5. Mechanistically, we discovered that ntc promotes mitochondrial ubiquitination beneath basal situations, which was mirrored by the down-regulation of USP30, in step with the concept that basal ubiquitination alerts basal mitophagy. Thus, our information counsel that ntc/FBXO7 offers basal ubiquitination that’s antagonised by USP30, which facilitates basal mitophagy upon a but unclear stimulus.
The present mechanistic view of PINK1/Parkin stress-induced mitophagy signalling posits that upon mitochondrial depolarisation or import blocking, PINK1 turns into stabilised within the translocon, phosphorylates latent, preexisting Ub, which promotes the recruitment of Parkin, triggering the feed-forward mechanism. Ubiquitination of import substrates would supply a prepared supply of latent Ub for PINK1 to phosphorylate as/when it turns into activated. Curiously, USP30 has been discovered to be related to TOMM20, a bona fide substrate of FBXO7 [68], and different translocon assemblies, the place basally ubiquitinated translocon import substrates accumulate [39]. According to ntc offering the basal ubiquitination on this mannequin, pS65-Ub that accumulates in parkin mutants is each diminished by lack of ntc and elevated by its overexpression.
Whereas we now have proven that ntc overexpression is enough to induce basal mitophagy, independently of Pink1/parkin, and it is ready to rescue parkin mutant phenotypes, curiously, it isn’t in a position to rescue Pink1 phenotypes. As pressured overexpression of ntc will increase basal ubiquitination, it follows that already excessive ranges of substrate for Pink1 circumvents the necessity for parkin ubiquitination exercise (therefore, why ntc overexpression can substitute for lack of parkin) when stress-induced mitophagy is required. Nonetheless, regardless of excessive ranges of latent ubiquitination, this alone isn’t enough to set off stress-induced mitophagy within the absence of Pink1-mediated phosphorylation (therefore, why ntc overexpression can’t rescue Pink1 mutants). These findings additional underscore the mechanistic and useful variations between basal and stress-induced mitophagy.
Analysing the potential position of ntc/FBXO7 in mitophagy and the connection with Pink1/parkin in vivo has highlighted the complexity of how completely different types of mitophagy might affect tissue homeostasis and relate to organismal phenotypes. As acknowledged earlier than, there are numerous completely different types of mitochondrial high quality management and mitophagy, and these carry out completely different features in mobile remodelling and homeostasis [61,62]. It follows that some types of mitophagy might dramatically affect neuromuscular homeostasis when disrupted, whereas others might not. For instance, proof helps that PINK1/Parkin promote stress-induced mitophagy however are minimally concerned in basal mitophagy, and Drosophila mutants current a number of sturdy phenotypes. In distinction, ntc/FBXO7 (and USP30) regulate basal mitophagy and facilitate PINK1/Parkin mitophagy by offering the initiating ubiquitination, but their mutant phenotypes solely loosely resemble these of Pink1/parkin mutants.
How do these types of mitophagy correlate with the mitochondrial/organismal phenotypes? The Pink1/parkin phenotypes are in step with a catastrophic lack of integrity in energy-intensive, mitochondria-rich tissues brought on by the dearth of a vital protecting measure (induced mitophagy) for a particular circumstance (doubtless, mitochondrial “injury” arising from an enormous metabolic burst). In distinction, whereas lack of ntc causes a partial (however not full) lack of basal mitophagy, the tissues affected in Pink1/parkin mutants seem to have the ability to address lack of this “housekeeping” mitochondrial QC course of, in step with there being partially redundant pathways. Notably, these tissues are nonetheless in a position to mount a stress-induced response by way of Pink1/parkin as we now have noticed paraquat-induced accumulation of pS65-Ub within the ntc mutant (S5C Fig), reinforcing that stress-induced mitophagy can occur within the absence of ntc. Consequently, ntc mutants don’t current the identical degenerative phenotypes as Pink1/parkin mutants and preserve comparatively regular mitochondrial perform. Therefore, it appears doubtless that the extra ntc mutant phenotypes of motor deficits and drastically brief lifespan are as a consequence of further features of ntc/FBXO7, similar to regulation of proteasome perform and caspase activation, and never mitophagy.
In abstract, we suggest a mannequin (Fig 8) wherein FBXO7/ntc acts to prime OMM proteins with ubiquitin that’s counteracted by USP30. This offers a key regulatory checkpoint in high quality management, for instance, throughout mitochondrial protein import. It’s doubtless that occasional defects in import or protein misfolding might result in a rise of Ub above a threshold that’s enough to impress basal mitophagy. Nonetheless, when the necessity arises this inhabitants of latent Ub might subsequently be phosphorylated by PINK1 (and amplified by Parkin) to set off selective degradation upon particular stimulation. Though extra research are required to grasp the interaction between FBXO7/ntc, USP30, Pink1, and parkin, this research offers a basis to additional elucidate the interaction between these mechanisms of mitochondrial high quality management and reinforces its potential as a therapeutic goal.
Fig 8. Proposed mannequin for basal and stress-induced mitophagy regulated by ntc, USP30, and parkin.
In basal, wholesome situations, FBXO7/ntc acts to prime OMM proteins with ubiquitin counteracted by USP30. This offers a key surveillance checkpoint in high quality management of mitochondrial protein import and/or protein injury. Occasional defects in import or protein misfolding might result in an Ub threshold that provokes basal mitophagy. Nonetheless, when the necessity arises within the presence of a stress, for instance, the place the membrane might turn out to be depolarised, this inhabitants of latent Ub might subsequently be phosphorylated by Pink1 and amplified by parkin to set off selective degradation upon particular stimulation. Created with BioRender.com. OMM, outer mitochondrial membrane.
Supplies and strategies
Drosophila shares and procedures
Drosophila have been raised beneath customary situations in a temperature-controlled incubator with a 12 h:12 h mild:darkish cycle at 25°C and 65% relative humidity, on meals consisting of agar, cornmeal, molasses, propionic acid, and yeast. ntcms771, UAS-ntc, and PBac{WH}CG10855f07259 strains have been kindly offered by H. Steller. park25 mutants and UAS-parkinC2 [13], UAS-FBXO7 [27], and UAS-mito-QC traces [20] have been beforehand described. Pink1B9 mutants [12] have been offered by J. Chung (SNU). UAS-Mul1 and Mul1A6 mutants have been kindly offered by Ming Guo. UAS-USP30 traces have been kindly offered by Ugo Mayor. UAS-USP30 RNAi (NIG-Fly 3016R[II]) was obtained from the NIG-Fly assortment. The next strains have been obtained from Bloomington Drosophila Inventory Middle (BDSC, RRID:SCR_006457): w1118 (RRID:BDSC_6326), da-GAL4 (RRID:BDSC_55850), nSyb-GAL4 (RRID:BDSC_51635), GMR-GAL4 (RRID:BDSC_1104), Mef2-GAL4 (RRID:BDSC_27390), Act-GAL4 (RRID:BDSC_25374), Atg8a [KG07569] (Atg8a-/-) (RRID:BDSC_14639), UAS-GFP-mCherry-Atg8a (RRID:BDSC_37749), and Df(3L)Exel6097 (RRID:BDSC_7576). UAS-lacZ was obtained from FlyORF (RRID: FlyBase_FBst0503118). The next strains have been obtained from Vienna Drosophila Analysis Centre (VDRC): UAS-LacZRNAi (v51446), UAS-March5 RNAi KK (v105711), and UAS-March5 RNAi GD(v33309). UAS-mtx-QC and UAS-March5 traces have been generated as follows: mtx-QC mCherry-GFP was amplified from UAS-mito-QC and cloned in-frame with the mitochondrial concentrating on sequence from hCOX8A into pUAST.attB and inserted in attP40 and attP16 websites; whereas for March5 (CG9855), full-length cDNA was cloned into pUAST vector and transgenesis carried out by random insertion. A full description of the genotypes used on this research is proven in S1 Desk.
Locomotor and lifespan assays
For locomotor assays, climbing (adverse geotaxis assay) was assessed as beforehand described, with minor modifications [13]. For lifespan experiments, flies have been grown beneath similar situations at low density. Progeny have been collected beneath very mild anaesthesia and saved in tubes of roughly 20 males every. Flies have been transferred each 2 to three days to contemporary tubes with regular meals for regular lifespan and tubes with 10 mM paraquat in a filter paper for the oxidative stress lifespan. The variety of lifeless flies was recorded on every switch. P.c of survival was calculated on the finish of the experiment after correcting for any unintentional loss.
Histology of grownup thoraces
Thoraces have been ready from 5-day-old grownup flies and handled as beforehand described [13]. Semi-thin sections have been then taken and stained with Toluidine blue, whereas ultra-thin sections have been examined utilizing a FEI Tecnai G2 Spirit 120KV transmission electron-microscope.
Mild microscopy imaging and scanning electron microscopy of Drosophila eye
Mild microscopy imaging was assessed utilizing a Nikon motorised SMZ stereo zoom microscope fitted with 1× Apo lens. Prolonged focus pictures have been then generated utilizing Nikon Components software program utilizing the identical settings for all of the genotypes. Flies have been anaesthetised with CO2 through the course of. Scanning electron microscopy (SEM) was carried out based on a regular protocol [69]. All animals of a given genotype displayed basically similar phenotypes and randomly chosen consultant pictures are proven. Photographs have been taken utilizing an SEM microscope (Philips XL-20 SEM).
Immunohistochemistry and pattern preparation
Drosophila brains have been dissected from 30-day-old flies and immuno-stained with anti-tyrosine hydroxylase (Immunostar Inc. #22491) as described beforehand [14]. Brains have been imaged with an Olympus FV1000 confocal with SIM-scanner on a BX61 upright microscope. Tyrosine hydroxylase-positive neurons have been counted beneath blinded situations. For immunostaining, grownup flight muscle mass have been dissected in PBS and glued in 4% formaldehyde for 30 min, permeabilized in 0.3% Triton X-100 for 30 min, and blocked with 0.3% Triton X-100 plus 1% bovine serum albumin in PBS for 1 h at RT. Tissues have been incubated with ATP5A antibody (Abcam Cat# ab14748, RRID:AB_301447; 1:500), diluted in 0.3% Triton X-100 plus 1% bovine serum albumin in PBS in a single day at 4°C, then rinsed 3 occasions 10 min with 0.3% Triton X-100 in PBS, and incubated with the suitable fluorescent secondary antibodies in a single day at 4°C. The tissues have been washed 3 occasions in PBS and mounted on slides utilizing ProLong Diamond Antifade mounting medium (Thermo Fisher Scientific) and picture subsequent day. For mitolysosome evaluation of mito-QC and mtx-QC, tissues have been dissected and handled as beforehand described [20].
Mitochondrial morphology in larval mind
Third instar larvae overexpressing UAS-mitoGFP with the pan-neuronal driver nSyb-GAL4 have been dissected in PBS and glued in 4% formaldehyde for 30 min. The tissues have been washed 3 occasions in PBS and mounted on slides utilizing ProLong Diamond Antifade mounting medium (Thermo Fisher Scientific) and picture subsequent day in a Zeiss LSM880 confocal microscope (63×/1.4 NA).
ATP ranges
The ATP assay was carried out as described beforehand [70]. Briefly, 5 male flies of the indicated age for every genotype have been homogenised in 100 μL 6M guanidine-Tris/EDTA extraction buffer and subjected to speedy freezing in liquid nitrogen. Homogenates have been diluted 1/100 with the extraction buffer and blended with the luminescent answer (CellTiter-Glo Luminescent Cell Viability Assay (Promega, RRID:SCR_006724)). Luminescence was measured with a SpectraMax Gemini XPS luminometer (Molecular Gadgets). The typical luminescent sign from technical triplicates was expressed relative to protein ranges, quantified utilizing the DC Protein Assay equipment (Bio-Rad Laboratories, RRID:SCR_008426). Information from 2 to 4 unbiased experiments have been averaged and the luminescence expressed as a proportion of the management.
Respirometry
Mitochondrial respiration was assayed at 30°C by high-resolution respirometry utilizing an Oxygraph-2k high-resolution respirometer (OROBOROS Devices) utilizing a chamber quantity set to 2 mL. Calibration with the air-saturated medium was carried out day by day. Information acquisition and evaluation have been carried out utilizing Datlab software program (OROBOROS Devices). 5 flies per genotype have been homogenised in Respiration Buffer [120 mM sucrose, 50 mM KCl, 20 mM Tris–HCl, 4 mM KH2PO4, 2 mM MgCl2, and 1 mM EGTA, 1 g L−1 fatty acid-free BSA (pH 7.2)]. For coupled (state 3) assays, advanced I-linked respiration was measured at saturating concentrations of malate (2 mM), glutamate (10 mM), L-proline (10 mM), and adenosine diphosphate (ADP, 2.5 mM). Complicated II-linked respiration was assayed in Respiration Buffer supplemented with 0.15 μm rotenone, 10 mM succinate, and a pair of.5 mM ADP. Respiration was expressed as oxygen consumed per fly. Flies’ weight was equal in all genotypes examined.
Picture evaluation and quantification of mitolysosomes
Evaluation of mitolysosomes was executed as beforehand described [20]. Briefly, spinning disk microscopy-generated pictures from dissected larval brains or grownup thoraces have been processed utilizing Imaris (model 9.0.2) evaluation software program (BitPlane; RRID:SCR_007370) to determine and rely particular person red-only puncta. The GFP and mCherry alerts have been adjusted to scale back background noise and retain solely the distinct mitochondria community and crimson puncta, respectively. A floor rendered 3D construction similar to the mitochondria community was generated utilizing the GFP sign. This quantity was subtracted from the crimson channel to retain the mCherry sign that didn’t colocalize with the GFP-labelled mitochondria community. The mitolysosomes puncta have been chosen based on their depth and an estimated measurement of 0.5 μm diameter, beforehand measured with Imaris. Moreover, the puncta have been filtered with a minimal measurement lower off of 0.2 μm diameter. The remaining puncta have been counted because the variety of mitolysosomes. Larval CNS soma have been analysed individually the place discrete cells could possibly be distinguished. The imply variety of mitolysosomes per cell was calculated per animal. Information factors within the quantification charts present imply mitolysosomes per cell for particular person animals, the place n ≥ 6 animals for every situation.
Evaluation and quantification of autolysosomes utilizing the GFP-mCherry-Atg8a site visitors mild reporter
Third instar larval brains have been dissected in phosphate buffered saline (PBS) and glued with 4% formaldehyde (FA) pH 7 (Thermo Scientific)/PBS for 20 min at room temperature. Samples have been then washed in PBS adopted by water to take away salts. ProLong antifade mounting media (Thermo Scientific) was used to mount the samples and imaged the day after. Confocal pictures, acquired with a Zeiss LSM880 microscope with the 63×/1.4 NA oil, have been processed utilizing FIJI (Picture J). The quantification of autolysosomes was carried out utilizing FIJI (Picture J) with the 3D Objects Counter Plugin. An space of curiosity was chosen by selecting 6 to 10 cells per picture. The brink was based mostly on matching the masks with the fluorescence. All puncta bigger than 0.049 μm3 was thought-about an autolysosome. Information factors within the quantification charts present imply mitolysosomes per cell for particular person animals, the place n ≥ 3 animals for every situation.
Mitochondrial enrichment by differential centrifugation
All steps have been carried out on ice or at 4°C. For immunoblotting evaluation and biochemical fractionation from small numbers of flies (10–30), a modified mitochondrial enrichment process was carried out. Flies have been ready both contemporary or after flash-freezing in liquid nitrogen, with all direct comparisons carried out with flies that have been ready in the identical method. Flies have been transferred right into a Dounce homogeniser containing 700 μL Answer A (70 mM sucrose, 20 mM HEPES (pH 7.6), 220 mM mannitol, 1 mM EDTA) containing cOmplete protease inhibitors (Roche) and PhosSTOP phosphatase inhibitors (Roche), and manually homogenised with 50 strokes of a pestle. The homogenate was transferred to an Eppendorf tube, an additional 500 μL of Answer A was added to the homogeniser and the pattern was homogenised with an additional 10 strokes. The homogenates have been pooled and incubated for 30 min, then centrifuged for five min at 800 × g. The supernatant (containing mitochondria) was transferred to a brand new tube and clarified twice by centrifugation for five min at 1,000 × g. The clarified supernatant was then centrifuged for 10 min at 10,000 × g, and the post-mitochondrial supernatant was discarded and the pellet retained for evaluation. The mitochondrial pellet was washed as soon as in Answer A containing solely protease inhibitors, after which as soon as in Answer A with out inhibitors. The washed mitochondrial pellet was resuspended in 50 to 200 μL Sucrose Storage Buffer, the protein content material decided by BCA assay (Thermo Pierce) and saved at −80°C till wanted.
Antibodies and dyes
The next mouse antibodies have been used for immunoblotting (WB) on this research: ATP5A (Abcam, ab14748, 1:10,000), actin (Millipore, MAB1501, 1:5,000), Ubiquitin (clone P4D1, Cell Signalling Expertise, 3936, 1:1,000), Ubiquitin (clone FK2, MBL, D058-3, 1:1,000). The next rabbit antibodies have been used on this research: pS65-Ub (Cell Signalling Applied sciences, 62802S, 1:1,000), Marf ([16], 1:1,000), GABARAP/Atg8a (Abcam ab109364, 1:1,000), ref(2)P/p62 (Abcam ab178440, 1:1,000). The next secondary antibodies have been used: sheep anti-mouse (HRP-conjugated, GE Healthcare, NXA931V, 1:10,000), donkey anti-rabbit (HRP-conjugated, GE Healthcare, NA934V, 1:10,000).
Complete-animal lysis and immunoblotting
For the evaluation of complete cell lysates by immunoblot, 180 μL chilly RIPA buffer (150 mM NaCl, 1% (v/v) NP-40, 0.5% (w/v) sodium deoxycholate, 0.1% (w/v) SDS, 50 mM Tris (pH 7.4)), supplemented with cOmplete protease inhibitors, was added to 2 mL tubes containing 1.4 mm ceramic beads (Fisherbrand 15555799). Animals (5 to twenty per replicate) have been harvested and saved on ice or flash-frozen in liquid N2, with all direct comparisons carried out with flies that have been harvested in the identical method. The flies have been added to the tubes containing RIPA buffer and lysed utilizing a Minilys homogeniser (Bertin Devices) with the next settings: most pace, 10 s on, 10 s on ice, for a complete of three cycles. After lysis, samples have been returned to ice for 10 min then centrifuged 5 min at 21,000 × g, 4°C. A complete of 90 μL supernatant was transferred to a contemporary Eppendorf tube and centrifuged an additional 10 min at 21,000 × g. Roughly 50 μL supernatant was then transferred to a contemporary Eppendorf tube and the protein content material decided by BCA assay as above, and 30 μg whole protein was then diluted in Laemmli Pattern Buffer (Bio-Rad, 1610747) and analysed by SDS-PAGE utilizing Mini-PROTEAN TGX Gels 4% to twenty% (Bio-Rad, 4561093). For the evaluation of mitochondria-enriched fractions, 30 μg mitochondrial protein was aliquoted right into a tube, centrifuged for 10 min at 16,000 × g, the supernatant eliminated and the pellet resuspended in Laemmli Pattern Buffer (Bio-Rad, 1610747) to SDS-PAGE evaluation as above. Gels have been transferred onto pre-cut and soaked PVDF membranes (1704156, BioRad) utilizing the BioRad Transblot Turbo switch system, and blots have been instantly stained with No-Stain Protein Labeling Reagent (Invitrogen, A44449) the place indicated, based on the producer’s directions. Fluorescence depth was measured utilizing a BioRad Chemidoc MP utilizing the IR680 setting. Blots have been then washed by light shaking 3 occasions for five min in PBS containing 0.1% (v/v) Tween-20 (PBST) and blocked by incubation with PBST containing 3% (w/v) BSA for 1 h. Blots have been washed an additional 3 occasions as above then incubated at 4°C in a single day with major antibodies in PBST containing 3% (w/v) BSA. An extra 3 washes have been carried out then the blots have been incubated for 1 h in secondary antibodies made up in PBST containing 3% (w/v) BSA. Blots have been then washed twice in PBST and as soon as in PBS previous to incubation with ECL Prime western blotting system (Cytiva, RPN2232). Blots have been imaged utilizing the BioRad Chemidoc MP utilizing publicity settings to minimise overexposure. Picture evaluation was carried out utilizing FIJI (Picture J) and pictures have been exported as TIFF information for publication. For paraquat therapy, flies have been maintained in tubes (10 to twenty flies per replicate) containing 6 semi-circular items of filter paper (90 mm diameter, Cat#1001–090) saturated with 5% (w/v) sucrose answer containing 10 mM paraquat. Sucrose-only hunger experiments have been carried out as above, with the omission of paraquat. After 3 days, the flies have been anaesthetised with gentle CO2 and stay flies solely have been harvested and course of for immunoblotting as described above.
ARPE-19-MQC cells
ARPE-19-MQC-FIS1 cells have been used to evaluate mitophagy in a human cell mannequin. Briefly, cells have been transfected in reverse with RNAiMax (13778075, Thermo Fisher Scientific) and non-targeting management siRNA (ON-TARGETplus Non-targeting Management Pool, D-001810-10-20, Horizon Discovery) or FBXO7 siRNA (ON-TARGETplus Human FBXO7 siRNA, L-013606-00-0010, Horizon Discovery). After 48 h, knockdown cells have been seeded into and Ibidi dish (IB-81156) Thistle Scientific Ltd), and after 72 h cells have been imaged stay by a spinning disk microscope and generated pictures have been processed utilizing Imaris as beforehand described.
Statistical evaluation
Information are reported as imply ± SEM or imply ± 95% CI as indicated in determine legends, and the n numbers of distinct organic replicates are proven in every graph. For statistical analyses of lifespan experiments, a log rank (Mantel–Cox) take a look at was used. For behavioural analyses, a Kruskal–Wallis nonparametric take a look at with Dunn’s submit hoc take a look at correction for a number of comparisons was used. The place a number of teams have been in contrast, statistical significance was calculated by one-way ANOVA with Bonferroni submit hoc take a look at correction for a number of samples. This take a look at was utilized to dopaminergic neuron evaluation and mitophagy the place greater than 2 teams have been in contrast. For Ub and pS65-Ub abundance, a one-way ANOVA with Dunnett’s correction for a number of comparisons was used. When solely 2 teams have been in contrast, a Welch’s t take a look at was used. The absence of statistical evaluation in between any group displays “no statistical significance.” All of the samples have been collected and processed concurrently and due to this fact no randomisation was applicable. Until in any other case indicated, all of the acquisition of pictures and evaluation was executed in blind situations. Statistical analyses have been carried out utilizing GraphPad Prism 9 software program (GraphPad Prism, RRID:SCR_002798). Statistical significance was represented in all circumstances as follows: * P < 0.05, ** P < 0.01, *** P < 0.001, and **** P < 0.0001.
Supporting info
S1 Fig. mito-QC reporter focused to the mitochondrial matrix (mtx-QC) reproduces the outcomes noticed with the mito-QC.
(A, B) Confocal microscopy evaluation of the mtx-QC reporter in larval CNS of management, ntc mutant, ntc overexpression and USP30 knockdown with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05. Scale bars = 10 μm. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information.
https://doi.org/10.1371/journal.pbio.3002244.s001
(TIFF)
S2 Fig. FBXO7 impacts basal mitophagy in vivo Drosophila neurons and in a human cell line.
(A, B) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and the transgenic expression of FBXO7 with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; *** P < 0.001. Scale bar = 10 μm. (C) Immunoblot evaluation of the knockdown of FBXO7 in human ARPE-19 cells expressing the mito-QC reporter. Arrow exhibits FBXO7 band; * exhibits nonspecific band. (D, E) Confocal microscopy evaluation of the mito-QC reporter in ARPE-19 human cell line of management siRNA and FBXO7 siRNA. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. Two-tailed t take a look at; ** P < 0.01. Scale bars = 10 μm. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information.
https://doi.org/10.1371/journal.pbio.3002244.s002
(TIFF)
S3 Fig. USP30 however neither March5 nor MUL1 can modulate mitophagy in vivo.
(A, B) Confocal microscopy evaluation of the mito-QC reporter in 2-day-old grownup thoraces of management and USP30 knockdown with the muscular driver Mef2-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. Two-tailed t take a look at; * P < 0.05. Scale bar = 10 μm. (C) Climbing capacity of 2-day-old flies expressing USP30 RNAi with the ever present driver da-GAL4 or with the pan-neuronal driver nSyb-GAL4. Chart present imply ± 95% CI and n values. Kruskal–Wallis nonparametric take a look at with Dunn’s submit hoc take a look at correction for a number of comparisons. (D) Climbing capacity of 10-day-old flies overexpressing USP30 alone or together with parkin, March5 or Mul1 with the ever present driver Act-GAL4. Chart present imply ± 95% CI and n values. Kruskal–Wallis nonparametric take a look at with Dunn’s submit hoc take a look at correction for a number of comparisons; **** P < 0.0001. (E, F) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and parkin overexpression with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. Two-tailed t take a look at. Scale bar = 10 μm. (G, H) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and Mul1 mutant. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. Two-tailed t take a look at. Scale bar = 10 μm. (I, J) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and March5 knockdowns with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. Two-tailed t take a look at. Scale bar = 10 μm. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information.
https://doi.org/10.1371/journal.pbio.3002244.s003
(TIFF)
S4 Fig. Improve in mitophagy ranges requires the important autophagy issue Atg8.
(A, B) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management, knockdown of USP30, overexpression of ntc, and ntc mutant within the Atg8a mutant background with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, *** P < 0.001. Scale bar = 10 μm. (C, D) Confocal microscopy evaluation of the mito-QC reporter in larval CNS of management and parkin mutant alone or with the USP30 knockdown within the presence or absence of Atg8a, with the pan-neuronal driver nSyb-GAL4. Mitolysosomes are evident as GFP-negative/mCherry-positive (red-only) puncta; n proven in chart. One-way ANOVA with Bonferroni submit hoc take a look at correction; * P < 0.05, ** P < 0.01, **** P < 0.0001. Scale bar = 10 μm. Full particulars of numerical information and analyses underlying the quantitative information could be present in S1 Information.
https://doi.org/10.1371/journal.pbio.3002244.s004
(TIFF)
S5 Fig. Evaluation of whole Ub in subcellular fractions and pS65-Ub upon oxidative stress-induction.
(A) Consultant immunoblot of the subcellular fractionation of 2-day-old flies with the transgenic expression of ntc or USP30 RNAi with the ever present driver da-GAL4. Cytosolic- and mitochondria-enriched fractions are label with Actin and ATP5a, respectively. (B) Consultant immunoblot of whole ubiquitin (FK2) of 2-day-old flies in management, ntc overexpression and USP30 knockdown with the ever present driver da-GAL4. (C) Consultant immunoblot of pS65-Ub ranges of 2-day-old flies handled with paraquat (PQ) in management and ntc mutants.
https://doi.org/10.1371/journal.pbio.3002244.s005
(TIFF)
S1 Uncooked Photographs. Authentic scan pictures for Figs 1E, 1H, 6A, 6C, 7A, 7C, 7E, S2C, S5A, S5B, and S5C.
https://doi.org/10.1371/journal.pbio.3002244.s008
(PDF)
Acknowledgments
We kindly thank Herman Steller for generously sharing the ntc traces, Ugo Mayor for the USP30 overexpression traces, and Ian Ganley for the ARPE-19-MQC cells. We thank Roberta Tufi for performing the ATP assay, Wing Hei Au and Federica De Lazzari for feedback and edits on the manuscript, and all of the members of the Whitworth’s lab for discussions. Shares have been obtained from the Bloomington Drosophila Inventory Middle which is supported by grant NIH P40OD018537.
References
- 1.
Yamano Okay, Youle RJ. PINK1 is degraded by way of the N-end rule pathway. Autophagy. 2013;9(11):1758–69. Epub 2013/10/15. pmid:24121706; PubMed Central PMCID: PMC4028335. - 2.
Okatsu Okay, Kimura M, Oka T, Tanaka Okay, Matsuda N. Unconventional PINK1 localization to the outer membrane of depolarized mitochondria drives Parkin recruitment. J Cell Sci. 2015;128(5):964–78. Epub 2015/01/23. pmid:25609704; PubMed Central PMCID: PMC4342580. - 3.
Okatsu Okay, Koyano F, Kimura M, Kosako H, Saeki Y, Tanaka Okay, et al. Phosphorylated ubiquitin chain is the real Parkin receptor. J Cell Biol. 2015;209(1):111–28. Epub 2015/04/08. pmid:25847540; PubMed Central PMCID: PMC4395490. - 4.
Gladkova C, Maslen SL, Skehel JM, Komander D. Mechanism of parkin activation by PINK1. Nature. 2018;559(7714):410–4. Epub 2018/07/12. pmid:29995846; PubMed Central PMCID: PMC6071873. - 5.
Sauve V, Sung G, Soya N, Kozlov G, Blaimschein N, Miotto LS, et al. Mechanism of parkin activation by phosphorylation. Nat Struct Mol Biol. 2018;25(7):623–30. Epub 2018/07/04. pmid:29967542. - 6.
Ordureau A, Sarraf SA, Duda DM, Heo JM, Jedrychowski MP, Sviderskiy VO, et al. Quantitative proteomics reveal a feedforward mechanism for mitochondrial PARKIN translocation and ubiquitin chain synthesis. Mol Cell. 2014;56(3):360–75. Epub 2014/10/07. pmid:25284222; PubMed Central PMCID: PMC4254048. - 7.
Bingol B, Sheng M. Mechanisms of mitophagy: PINK1, Parkin, USP30 and past. Free Radic Biol Med. 2016;100:210–22. Epub 2016/04/21. pmid:27094585. - 8.
Lazarou M, Sliter DA, Kane LA, Sarraf SA, Wang C, Burman JL, et al. The ubiquitin kinase PINK1 recruits autophagy receptors to induce mitophagy. Nature. 2015;524(7565):309–14. Epub 2015/08/13. pmid:26266977; PubMed Central PMCID: PMC5018156. - 9.
Yamano Okay, Kikuchi R, Kojima W, Hayashida R, Koyano F, Kawawaki J, et al. Vital position of mitochondrial ubiquitination and the OPTN-ATG9A axis in mitophagy. J Cell Biol. 2020;219(9). Epub 2020/06/20. pmid:32556086; PubMed Central PMCID: PMC7480101. - 10.
Pickrell AM, Youle RJ. The roles of PINK1, parkin, and mitochondrial constancy in Parkinson’s illness. Neuron. 2015;85(2):257–73. Epub 2015/01/23. pmid:25611507; PubMed Central PMCID: PMC4764997. - 11.
Clark IE, Dodson MW, Jiang C, Cao JH, Huh JR, Seol JH, et al. Drosophila pink1 is required for mitochondrial perform and interacts genetically with parkin. Nature. 2006;441(7097):1162–6. Epub 2006/05/05. pmid:16672981. - 12.
Park J, Lee SB, Lee S, Kim Y, Track S, Kim S, et al. Mitochondrial dysfunction in Drosophila PINK1 mutants is complemented by parkin. Nature. 2006;441(7097):1157–61. Epub 2006/05/05. pmid:16672980. - 13.
Greene JC, Whitworth AJ, Kuo I, Andrews LA, Feany MB, Pallanck LJ. Mitochondrial pathology and apoptotic muscle degeneration in Drosophila parkin mutants. Proc Natl Acad Sci U S A. 2003;100(7):4078–83. Epub 2003/03/19. pmid:12642658; PubMed Central PMCID: PMC153051. - 14.
Whitworth AJ, Theodore DA, Greene JC, Benes H, Wes PD, Pallanck LJ. Elevated glutathione S-transferase exercise rescues dopaminergic neuron loss in a Drosophila mannequin of Parkinson’s illness. Proc Natl Acad Sci U S A. 2005;102(22):8024–9. Epub 2005/05/25. pmid:15911761; PubMed Central PMCID: PMC1142368. - 15.
Poole AC, Thomas RE, Andrews LA, McBride HM, Whitworth AJ, Pallanck LJ. The PINK1/Parkin pathway regulates mitochondrial morphology. Proc Natl Acad Sci U S A. 2008;105(5):1638–43. Epub 2008/01/31. pmid:18230723; PubMed Central PMCID: PMC2234197. - 16.
Ziviani E, Tao RN, Whitworth AJ. Drosophila parkin requires PINK1 for mitochondrial translocation and ubiquitinates mitofusin. Proc Natl Acad Sci U S A. 2010;107(11):5018–23. Epub 2010/03/03. pmid:20194754; PubMed Central PMCID: PMC2841909. - 17.
Vincow ES, Merrihew G, Thomas RE, Shulman NJ, Beyer RP, MacCoss MJ, et al. The PINK1-Parkin pathway promotes each mitophagy and selective respiratory chain turnover in vivo. Proc Natl Acad Sci U S A. 2013;110(16):6400–5. Epub 2013/03/20. pmid:23509287; PubMed Central PMCID: PMC3631677. - 18.
Cornelissen T, Verstreken P, Vandenberghe W. Imaging mitophagy within the fruit fly. Autophagy. 2018;14(9):1656–7. Epub 2018/07/12. pmid:29995555; PubMed Central PMCID: PMC6135567. - 19.
Kim YY, Um JH, Yoon JH, Kim H, Lee DY, Lee YJ, et al. Evaluation of mitophagy in mt-Keima Drosophila revealed a vital position of the PINK1-Parkin pathway in mitophagy induction in vivo. FASEB J. 2019;33(9):9742–51. Epub 2019/05/24. pmid:31120803. - 20.
Lee JJ, Sanchez-Martinez A, Martinez Zarate A, Beninca C, Mayor U, Clague MJ, et al. Basal mitophagy is widespread in Drosophila however minimally affected by lack of Pink1 or parkin. J Cell Biol. 2018;217(5):1613–22. Epub 2018/03/04. pmid:29500189; PubMed Central PMCID: PMC5940313. - 21.
McWilliams TG, Prescott AR, Montava-Garriga L, Ball G, Singh F, Barini E, et al. Basal Mitophagy Happens Independently of PINK1 in Mouse Tissues of Excessive Metabolic Demand. Cell Metab. 2018;27(2):439–49 e5. Epub 2018/01/18. pmid:29337137; PubMed Central PMCID: PMC5807059. - 22.
Di Fonzo A, Dekker MC, Montagna P, Baruzzi A, Yonova EH, Correia Guedes L, et al. FBXO7 mutations trigger autosomal recessive, early-onset parkinsonian-pyramidal syndrome. Neurology. 2009;72(3):240–5. Epub 2008/11/29. pmid:19038853. - 23.
Zhou ZD, Lee JCT, Tan EK. Pathophysiological mechanisms linking F-box solely protein 7 (FBXO7) and Parkinson’s illness (PD). Mutat Res Rev Mutat Res. 2018;778:72–8. Epub 2018/11/21. pmid:30454685. - 24.
Skowyra D, Craig KL, Tyers M, Elledge SJ, Harper JW. F-box proteins are receptors that recruit phosphorylated substrates to the SCF ubiquitin-ligase advanced. Cell. 1997;91(2):209–19. Epub 1997/11/05. pmid:9346238. - 25.
Hsu JM, Lee YC, Yu CT, Huang CY. Fbx7 features within the SCF advanced regulating Cdk1-cyclin B-phosphorylated hepatoma up-regulated protein (HURP) proteolysis by a proline-rich area. J Biol Chem. 2004;279(31):32592–602. Epub 2004/05/18. pmid:15145941. - 26.
Kirk R, Laman H, Knowles PP, Murray-Rust J, Lomonosov M, Meziane el Okay, et al. Construction of a conserved dimerization area inside the F-box protein Fbxo7 and the PI31 proteasome inhibitor. J Biol Chem. 2008;283(32):22325–35. Epub 2008/05/23. pmid:18495667. - 27.
Burchell VS, Nelson DE, Sanchez-Martinez A, Delgado-Camprubi M, Ivatt RM, Pogson JH, et al. The Parkinson’s disease-linked proteins Fbxo7 and Parkin work together to mediate mitophagy. Nat Neurosci. 2013;16(9):1257–65. Epub 2013/08/13. pmid:23933751; PubMed Central PMCID: PMC3827746. - 28.
Bader M, Arama E, Steller H. A novel F-box protein is required for caspase activation throughout mobile reworking in Drosophila. Improvement. 2010;137(10):1679–88. Epub 2010/04/16. pmid:20392747; PubMed Central PMCID: PMC2860250. - 29.
Bader M, Benjamin S, Wapinski OL, Smith DM, Goldberg AL, Steller H. A conserved F field regulatory advanced controls proteasome exercise in Drosophila. Cell. 2011;145(3):371–82. Epub 2011/05/03. pmid:21529711; PubMed Central PMCID: PMC3108249. - 30.
Track S, Jang S, Park J, Bang S, Choi S, Kwon KY, et al. Characterization of PINK1 (PTEN-induced putative kinase 1) mutations related to Parkinson illness in mammalian cells and Drosophila. J Biol Chem. 2013;288(8):5660–72. Epub 2013/01/11. pmid:23303188; PubMed Central PMCID: PMC3581423. - 31.
Whitworth AJ, Lee JR, Ho VM, Flick R, Chowdhury R, McQuibban GA. Rhomboid-7 and HtrA2/Omi act in a typical pathway with the Parkinson’s illness elements Pink1 and Parkin. Dis Mannequin Mech. 2008;1(2–3):168–74; dialogue 73. Epub 2008/12/03. pmid:19048081; PubMed Central PMCID: PMC2562193. - 32.
Riparbelli MG, Callaini G. The Drosophila parkin homologue is required for regular mitochondrial dynamics throughout spermiogenesis. Dev Biol. 2007;303(1):108–20. Epub 2006/11/25. pmid:17123504. - 33.
Meulener M, Whitworth AJ, Armstrong-Gold CE, Rizzu P, Heutink P, Wes PD, et al. Drosophila DJ-1 mutants are selectively delicate to environmental toxins related to Parkinson’s illness. Curr Biol. 2005;15(17):1572–7. Epub 2005/09/06. [pii] pmid:16139213. - 34.
Malik BR, Godena VK, Whitworth AJ. VPS35 pathogenic mutations confer no dominant toxicity however partial lack of perform in Drosophila and genetically work together with parkin. Hum Mol Genet. 2015;24(21):6106–17. Epub 2015/08/08. pmid:26251041; PubMed Central PMCID: PMC4599670. - 35.
Allen GF, Toth R, James J, Ganley IG. Lack of iron triggers PINK1/Parkin-independent mitophagy. EMBO Rep. 2013;14(12):1127–35. Epub 2013/11/02. pmid:24176932; PubMed Central PMCID: PMC3981094. - 36.
Shen JL, Fortier TM, Wang R, Baehrecke EH. Vps13D features in a Pink1-dependent and Parkin-independent mitophagy pathway. J Cell Biol. 2021;220(11). Epub 2021/08/31. pmid:34459871; PubMed Central PMCID: PMC8406608. - 37.
Montava-Garriga L, Singh F, Ball G, Ganley IG. Semi-automated quantitation of mitophagy in cells and tissues. Mech Ageing Dev. 2020;185:111196. Epub 2019/12/18. pmid:31843465; PubMed Central PMCID: PMC6961211. - 38.
Marcassa E, Kallinos A, Jardine J, Rusilowicz-Jones EV, Martinez A, Kuehl S, et al. Twin position of USP30 in controlling basal pexophagy and mitophagy. EMBO Rep. 2018;19(7). Epub 2018/06/14. pmid:29895712; PubMed Central PMCID: PMC6030704. - 39.
Ordureau A, Paulo JA, Zhang J, An H, Swatek KN, Cannon JR, et al. International Panorama and Dynamics of Parkin and USP30-Dependent Ubiquitylomes in iNeurons throughout Mitophagic Signaling. Mol Cell. 2020;77(5):1124–42 e10. Epub 2020/03/07. pmid:32142685; PubMed Central PMCID: PMC7098486. - 40.
Rusilowicz-Jones EV, Jardine J, Kallinos A, Pinto-Fernandez A, Guenther F, Giurrandino M, et al. USP30 units a set off threshold for PINK1-PARKIN amplification of mitochondrial ubiquitylation. Life Sci Alliance. 2020;3(8). Epub 2020/07/09. pmid:32636217; PubMed Central PMCID: PMC7362391. - 41.
Bingol B, Tea JS, Phu L, Reichelt M, Bakalarski CE, Track Q, et al. The mitochondrial deubiquitinase USP30 opposes parkin-mediated mitophagy. Nature. 2014;510(7505):370–5. Epub 2014/06/05. pmid:24896179. - 42.
Phu L, Rose CM, Tea JS, Wall CE, Verschueren E, Cheung TK, et al. Dynamic Regulation of Mitochondrial Import by the Ubiquitin System. Mol Cell. 2020;77(5):1107–23 e10. Epub 2020/03/07. pmid:32142684. - 43.
Yun J, Puri R, Yang H, Lizzio MA, Wu C, Sheng ZH, et al. MUL1 acts in parallel to the PINK1/parkin pathway in regulating mitofusin and compensates for lack of PINK1/parkin. Elife. 2014;3:e01958. Epub 2014/06/06. pmid:24898855; PubMed Central PMCID: PMC4044952. - 44.
Rojansky R, Cha MY, Chan DC. Elimination of paternal mitochondria in mouse embryos happens by way of autophagic degradation depending on PARKIN and MUL1. Elife. 2016;5. Epub 2016/11/18. pmid:27852436; PubMed Central PMCID: PMC5127638. - 45.
Zheng J, Chen X, Liu Q, Zhong G, Zhuang M. Ubiquitin ligase MARCH5 localizes to peroxisomes to control pexophagy. J Cell Biol. 2022;221(1). Epub 2021/11/09. pmid:34747980; PubMed Central PMCID: PMC8579195. - 46.
Chen Z, Liu L, Cheng Q, Li Y, Wu H, Zhang W, et al. Mitochondrial E3 ligase MARCH5 regulates FUNDC1 to fine-tune hypoxic mitophagy. EMBO Rep. 2017;18(3):495–509. Epub 2017/01/21. pmid:28104734; PubMed Central PMCID: PMC5331199. - 47.
Koyano F, Yamano Okay, Kosako H, Kimura Y, Kimura M, Fujiki Y, et al. Parkin-mediated ubiquitylation redistributes MITOL/March5 from mitochondria to peroxisomes. EMBO Rep. 2019;20(12):e47728. Epub 2019/10/12. pmid:31602805; PubMed Central PMCID: PMC6893362. - 48.
Liang JR, Martinez A, Lane JD, Mayor U, Clague MJ, Urbe S. USP30 deubiquitylates mitochondrial Parkin substrates and restricts apoptotic cell demise. EMBO Rep. 2015;16(5):618–27. Epub 2015/03/06. pmid:25739811; PubMed Central PMCID: PMC4428036. - 49.
Pan W, Wang Y, Bai X, Yin Y, Dai L, Zhou H, et al. Deubiquitinating enzyme USP30 negatively regulates mitophagy and accelerates myocardial cell senescence by way of antagonism of Parkin. Cell Loss of life Dis. 2021;7(1):187. Epub 2021/07/23. pmid:34290230; PubMed Central PMCID: PMC8295395. - 50.
Lazarou M, McKenzie M, Ohtake A, Thorburn DR, Ryan MT. Evaluation of the meeting profiles for mitochondrial- and nuclear-DNA-encoded subunits into advanced I. Mol Cell Biol. 2007;27(12):4228–37. Epub 2007/04/18. pmid:17438127; PubMed Central PMCID: PMC1900046. - 51.
Nguyen TN, Padman BS, Usher J, Oorschot V, Ramm G, Lazarou M. Atg8 household LC3/GABARAP proteins are essential for autophagosome-lysosome fusion however not autophagosome formation throughout PINK1/Parkin mitophagy and hunger. J Cell Biol. 2016;215(6):857–74. Epub 2016/11/20. pmid:27864321; PubMed Central PMCID: PMC5166504. - 52.
Jipa A, Vedelek V, Merenyi Z, Urmosi A, Takats S, Kovacs AL, et al. Evaluation of Drosophila Atg8 proteins reveals a number of lipidation-independent roles. Autophagy. 2021;17(9):2565–75. Epub 2020/12/01. pmid:33249988; PubMed Central PMCID: PMC8496532. - 53.
Yoshii SR, Mizushima N. Monitoring and Measuring Autophagy. Int J Mol Sci. 2017;18(9). Epub 2017/08/29. pmid:28846632; PubMed Central PMCID: PMC5618514. - 54.
Lorincz P, Mauvezin C, Juhasz G. Exploring Autophagy in Drosophila. Cell. 2017;6(3). Epub 2017/07/15. pmid:28704946; PubMed Central PMCID: PMC5617968. - 55.
Mauvezin C, Ayala C, Braden CR, Kim J, Neufeld TP. Assays to observe autophagy in Drosophila. Strategies. 2014;68(1):134–9. Epub 2014/03/29. pmid:24667416; PubMed Central PMCID: PMC4048785. - 56.
Nagy P, Karpati M, Varga A, Pircs Okay, Venkei Z, Takats S, et al. Atg17/FIP200 localizes to perilysosomal Ref(2)P aggregates and promotes autophagy by activation of Atg1 in Drosophila. Autophagy. 2014;10(3):453–67. Epub 2014/01/15. pmid:24419107; PubMed Central PMCID: PMC4077884. - 57.
Low P, Varga A, Pircs Okay, Nagy P, Szatmari Z, Sass M, et al. Impaired proteasomal degradation enhances autophagy by way of hypoxia signaling in Drosophila. BMC Cell Biol. 2013;14:29. Epub 2013/06/27. pmid:23800266; PubMed Central PMCID: PMC3700814. - 58.
Gersch M, Gladkova C, Schubert AF, Michel MA, Maslen S, Komander D. Mechanism and regulation of the Lys6-selective deubiquitinase USP30. Nat Struct Mol Biol. 2017;24(11):920–30. Epub 2017/09/26. pmid:28945249; PubMed Central PMCID: PMC5757785. - 59.
Usher JL, Sanchez-Martinez A, Terriente-Felix A, Chen PL, Lee JJ, Chen CH, et al. Parkin drives pS65-Ub turnover independently of canonical autophagy in Drosophila. EMBO Rep. 2022:e202153552. Epub 2022/10/18. pmid:36250243. - 60.
Zhou ZD, Xie SP, Sathiyamoorthy S, Noticed WT, Sing TY, Ng SH, et al. F-box protein 7 mutations promote protein aggregation in mitochondria and inhibit mitophagy. Hum Mol Genet. 2015;24(22):6314–30. Epub 2015/08/28. pmid:26310625. - 61.
Ashrafi G, Schwarz TL. The pathways of mitophagy for high quality management and clearance of mitochondria. Cell Loss of life Differ. 2013;20(1):31–42. Epub 2012/06/30. pmid:22743996; PubMed Central PMCID: PMC3524633. - 62.
Pickles S, Vigie P, Youle RJ. Mitophagy and High quality Management Mechanisms in Mitochondrial Upkeep. Curr Biol. 2018;28(4):R170–R85. Epub 2018/02/21. pmid:29462587; PubMed Central PMCID: PMC7255410. - 63.
Kraus F, Goodall EA, Smith IR, Jiang Y, Paoli JC, Adolf F, et al. PARK15/FBXO7 is dispensable for PINK1/Parkin mitophagy in iNeurons and HeLa cell techniques. bioRxiv. 2023:2022.11.02.514817. pmid:37334901 - 64.
Martinez A, Sanchez-Martinez A, Pickering JT, Twyning MJ, Terriente-Felix A, Chen P-L, et al. Mitochondrial CISD1/Cisd accumulation blocks mitophagy and genetic or pharmacological inhibition rescues neurodegenerative phenotypes in Pink1/parkin fashions. bioRxiv. 2023:2023.05.14.540700. - 65.
Cornelissen T, Vilain S, Vints Okay, Gounko N, Verstreken P, Vandenberghe W. Deficiency of parkin and PINK1 impairs age-dependent mitophagy in Drosophila. Elife. 2018;7. Epub 2018/05/29. pmid:29809156; PubMed Central PMCID: PMC6008047. - 66.
Cunningham CN, Baughman JM, Phu L, Tea JS, Yu C, Coons M, et al. USP30 and parkin homeostatically regulate atypical ubiquitin chains on mitochondria. Nat Cell Biol. 2015;17(2):160–9. Epub 2015/01/27. pmid:25621951. - 67.
Ordureau A, Heo JM, Duda DM, Paulo JA, Olszewski JL, Yanishevski D, et al. Defining roles of PARKIN and ubiquitin phosphorylation by PINK1 in mitochondrial high quality management utilizing a ubiquitin alternative technique. Proc Natl Acad Sci U S A. 2015;112(21):6637–42. Epub 2015/05/15. pmid:25969509; PubMed Central PMCID: PMC4450373. - 68.
Teixeira FR, Randle SJ, Patel SP, Mevissen TE, Zenkeviciute G, Koide T, et al. Gsk3beta and Tomm20 are substrates of the SCFFbxo7/PARK15 ubiquitin ligase related to Parkinson’s illness. Biochem J. 2016;473(20):3563–80. Epub 2016/08/10. pmid:27503909; PubMed Central PMCID: PMC5260939. - 69.
Sullivan WA, Hawley RS. Drosophila protocols. Chilly Spring Harbor Laboratory Press; 2000. - 70.
Pogson JH, Ivatt RM, Sanchez-Martinez A, Tufi R, Wilson E, Mortiboys H, et al. The Complicated I Subunit NDUFA10 Selectively Rescues Drosophila pink1 Mutants by way of a Mechanism Impartial of Mitophagy. PLoS Genet. 2014;10(11):e1004815. Epub 2014/11/21. pmid:25412178; PubMed Central PMCID: PMC4238976.
[ad_2]