PINK1-dependent phosphorylation of PINK1 and Parkin is essential for mitochondrial quality control

Mitochondrial dysfunction has been linked to the pathogenesis of a large number of inherited diseases in humans, including Parkinson's disease, the second most common neurodegenerative disorder. The Parkinson's disease genes pink1 and parkin, which encode a mitochondrially targeted protein kinase, and an E3 ubiquitin ligase, respectively, participate in a key mitochondrial quality-control pathway that eliminates damaged mitochondria. In the current study, we established an in vivo PINK1/Parkin-induced photoreceptor neuron degeneration model in Drosophila with the aim of dissecting the PINK1/Parkin pathway in detail. Using LC-MS/MS analysis, we identified Serine 346 as the sole autophosphorylation site of Drosophila PINK1 and found that substitution of Serine 346 to Alanine completely abolished the PINK1 autophosphorylation. Disruption of either PINK1 or Parkin phosphorylation impaired the PINK1/Parkin pathway, and the degeneration phenotype of photoreceptor neurons was obviously alleviated. Phosphorylation of PINK1 is not only required for the PINK1-mediated mitochondrial recruitment of Parkin but also induces its kinase activity toward Parkin. In contrast, phosphorylation of Parkin by PINK1 is dispensable for its translocation but required for its activation. Moreover, substitution with autophosphorylation-deficient PINK1 failed to rescue pink1 null mutant phenotypes. Taken together, our findings suggest that autophosphorylation of PINK1 is essential for the mitochondrial translocation of Parkin and for subsequent phosphorylation and activation of Parkin.

Mitochondria have a fundamental role in eukaryotic metabolic processes by generating adenosine triphosphate as a cellular energy source. Dysfunctional mitochondria deprive cells of energy, produce toxic reactive oxygen species, and other pro-death mediators to initiate cell death. The mitochondrial quality-control pathways that evolved to maintain the integrity of mitochondria therefore have key roles in the normal function of cells. 1,2 The pathogenesis of a large number of inherited diseases in humans, including Parkinson's disease, has been linked to mitochondrial dysfunction. [3][4][5] The pink1 and parkin genes encode a mitochondrially targeted protein kinase and an E3 ubiquitin ligase, respectively. Mutations in both genes are known to cause early-onset Parkinson's disease. 6,7 A large number of studies have demonstrated that PINK1 functions upstream of Parkin in a key mitochondrial quality-control pathway that is known as mitophagy. 8,9 Mitophagy is a selective form of autophagy that targets dysfunctional mitochondria for lysosomal degradation and protects cells from mitochondrial damage. 10 In damaged mitochondria, PINK1 accumulates on the outer membrane (OMM) of depolarized mitochondria. 11,12 The accumulation of PINK1 is essential both for the recruitment of Parkin onto depolarized mitochondria and for the activation of Parkin. Parkin has been shown to initiate ubiquitination of numerous OMM proteins, to initiate selective autophagy, and to function in the degradation of damaged mitochondria. 8,[13][14][15][16] PINK1 kinase activity is required to induce the translocation of Parkin to depolarized mitochondria, and several mutations in the pink1 gene that yield stable PINK1 that lacks kinase activity have been associated with Parkinsonisms. [17][18][19] PINK1 accumulated on the OMM has been shown to phosphorylate Parkin and is required for the recruitment of Parkin. [20][21][22][23][24][25] Studies with mammalian cells have shown that, upon depolarization, PINK1 can autophosphorylate at residues S228 and S402, a situation that also appears to be involved in the recruitment of Parkin. 24,26 Recently, it has been suggested that S402 phosphorylation appears to be important for PINK1 function, as this is known to be involved in PINK1 dimerization, Parkin recruitment, and the induction of mitophagy. 24,27 However, despite the fact that many PINK1 substrates have been identified, precisely how PINK1 kinase activity is involved in the recruitment of Parkin to the depolarized mitochondria remains unclear.
In this study, we established a PINK1/Parkin-induced cell death model in Drosophila. We identified a single PINK1 autophosphorylation site at the S346 residue, which is conserved as S228 in mammals. Expression of a truncated PINK1 with an S346A mutation abolished PINK1-induced phosphorylation of both PINK1 and Parkin, the recruitment of Parkin to mitochondria, and consequent cell death. Moreover, PINK1 S346A failed to rescue pink1 null mutant phenotypes, whereas both PINK1 S519A and PINK1 S346D

Results
Establishment of an in vivo PINK1/Parkin-induced photoreceptor neuron degeneration model. PINK1 is known to be imported and degraded in mitochondria in normal conditions. However, in HeLa cells, stabilized PINK1 on the OMM recruits Parkin and causes the elimination of mitochondria. 8,12 To establish an in vivo system of PINK1induced activation of mitochondrial quality-control pathway, we replaced residues 1-93 of PINK1 with the OMM anchor from the N-terminal region of TOM20, and TOM20-PINK1-GFP stably accumulated on the mitochondrial in normal conditions ( Figure 1a). In Schneider 2 (S2) cells, upon coexpression with mCherry-Parkin, which was randomly distributed in cytosol when expressed by itself, TOM20-PINK1-GFP recruited mCherry-Parkin to mitochondria ( Figure 1b). In contrast, PINK1 with a kinase-dead (PINK1 D479A or PINK1 KD ) mutation prevent the mitochondrial recruitment of Parkin ( Figure 1b). The Drosophila compound eye is a powerful system to study the pathogenesis of neurodegenerative diseases. 28 We next expressed GFP-tagged TOM20-PINK1 proteins in the fly compound eyes using the GMR (Glass Multiple Reporter) promoter and found that both GMR-tom20-pink1-GFP and GMR-tom20-pink1 KD -GFP flies had truncated PINK1 expressed and normal eye morphology (Figure 1c). To check the cellular effects of expressing truncated PINK1 in detail, we examined the morphology of retinae by transmission electron microscopy (TEM). Each ommatidium from normal compound eyes contains seven intact photoreceptor cells with microvillar structure named rhabdomere. Each individual ommatidium from GMR-tom20-pink1-GFP compound eyes contained a full complement of seven intact photoreceptor cells (Figure 1d). We reasoned that the lack of obvious cell death observed in the mitochondrial-targeted PINK1 in photoreceptor neurons might result from the low expression level of endogenous Parkin in compound eyes. Therefore, we additionally expressed Flag-tagged Parkin with the GMR promoter. Coexpression of TOM20-PINK1-GFP and Flag-Parkin resulted in glassy eyes with an absence of pigmentation, representing severe degeneration of retina cells, whereas the eye morphology of the GMR-tom20-pink1 KD -GFP/GMR-flagparkin flies was normal (Figure 1c). These differences did not result from low expression levels of PINK1 KD , as both GMR-tom20-pink1 KD -GFP and GMR-tom20-pink1-GFP had similar PINK1-GFP protein levels (Supplementary Figure S1). To verify the degeneration phenotype of photoreceptor neurons detected externally, we examined the morphology of retinae by TEM. The GMR-tom20-pink1-GFP/GMR-flag-parkin flies completely lacked photoreceptor cells, whereas there was no loss of photoreceptor cells and/or rhabdomeres observed in the GMR-tom20-pink1 KD -GFP/GMR-flag-parkin flies (Figure 1d).
To investigate whether autophagy was involved in the retinal cell death, we coexpressed TOM20-PINK1-GFP and Flag-Parkin in an autophagy-deficient background. Both atg1 RNAi and atg7 KO failed to alleviate the degeneration of photoreceptor cells (Figure 1c). We next assessed whether loss of mitochondria was associated with PINK1/Parkininduced cell death. First, we checked mitochondrial membrane potential using JC-10 assay. The addition of CCCP resulted in the complete loss of membrane potential, whereas the expression of TOM20-PINK1 and Parkin did not affect mitochondrial membrane potential, indicating that the PINK1/ Parkin-induced cell death is irrespective of the mitochondrial membrane potential (Supplementary Figure S2). Furthermore, mitochondrial proteins, including ND42, COXIV, and Acon, did not decrease in the degenerating retina, indicating that PINK1/Parkin-mediated cell death is not caused by mitochondrial loss (Supplementary Figure S3). Therefore, the PINK1/Parkin-induced cell death is independent of mitochondrial autophagy.
PINK1 phosphorylation is required for the activation of PINK1/Parkin signaling. To investigate the in vivo role of PINK1 autophosphorylation, we expressed TOM20-PINK1-GFP with a S346A or a S346D mutation in the fly compound eyes. Unlike wild-type PINK1, coexpression of TOM20-PINK1 S346A -GFP and Flag-Parkin did not lead to external retinal degeneration on the first day ( Figure 3a). However, consistent with the phos-tag gel results, mutation on the other putative phosphorylation site of PINK1 (PINK1 S519A ) caused a severe absence of pigmentation upon coexpression with Parkin as the similar extension as with wild-type PINK1 ( Figure 3a). These results emphasize again that S346 is the sole autophosphorylation site of PINK1. Coexpression of the TOM20-PINK1 S346D -GFP and Flag-Parkin caused external eye degeneration, although this was not as severe as for wildtype PINK1. The different effects of PINK1 S346A and PINK1 S346D on retinal degeneration are not due to expressing different levels of PINK1 (Supplementary Figure S1). However, coexpression of Parkin reduced the stability of both wildtype PINK1 and PINK1 S346D , which indicated that PINK1 might also be the substrate of Parkin (Supplementary Figure S5). We used TEM to evaluate photoreceptor neuron integrity. Similar to the light microscopic results, the expression of Parkin with either wild-type TOM20-PINK1 or TOM20-PINK1 S519A completely abolished photoreceptor cells in young flies (o1-day old, Figure 3b). A severe loss of photoreceptor cells was also detected in GMR-pink1 S346D -GFP/GMR-flag-parkin flies, but this did not occur in GMR-pink1 S346A -GFP/GMR-flag-park flies at day 1 ( Figure 3b). To further check whether the unphosphorylated PINK1 caused neurodegeneration in aged animals, we performed optical neutralization assay to count the number of rhabdomeres per ommatidium during aging 29 (Figure 3d). We found that GMR-pink1 S346D -GFP/GMR-flag-parkin flies displayed a near complete loss of photoreceptor cells on day 10, whereas flies expressing PINK1 S346A reserved most of their photoreceptor cells (Figures 3c and d). Therefore, autophosphorylation of PINK1 on S346 is required for the activation of the PINK1/Parkin pathway.
Phosphorylation of Parkin is required for the activation of the PINK1/Parkin pathway. We next queried whether PINK1 autophosphorylation alone was sufficient for the activation of the PINK1/Parkin pathway. We introduced a Drosophila S2 cells transfected with tom20-pink1-GFP or tom20-pink1 KD -GFP were analyzed with Phos-tag gel electrophoresis. Prokaryotic expressed TOM20-PINK1-GFP was used as an internal control for unmodified PINK1 (lane 1). Anti-GFP antibody was used for immunoblotting analysis. (b) Tandem mass (MS/MS) spectrum analysis of the in vivo autophosphorylation site of Drosophila PINK1. TOM20-PINK1-GFP or TOM20-PINK1 KD -GFP purified from transgenic fly heads of GMR-tom20-pink1-GFP or GMR-tom20-pink1 KD -GFP was subjected to LC-MS/MS analysis. A sole phosphorylated peptide, equivalent to amino acids 338-353, was identified only from tom20-pink1-GFP transgenic flies. The b and y ions are marked in the spectrum and also illustrated along the peptide sequence shown on top of the spectrum. The subscript p marks a phosphorylation modification on Ser-346. (c) Multiple sequence alignment of PINK1 residues neighboring S346 with various organisms. S346 (boxed) has been evolutionarily conserved across all species. (d) Serine 346 was confirmed to be the sole autophosphorylation site of PINK1. Whole-cell lysates of Drosophila S2 cells transfected with wild-type or mutant forms of TOM20-PINK1-GFP were subjected to phos-tag gel electrophoresis. The high molecular shift in the phos-tag gel completely disappeared in the S346A mutation but was unaffected in the S519A mutation Figure 3 Phosphorylation of both PINK1 and Parkin is required for activation of the PINK1/Parkin pathway. (a) Stereo fluorescence microscopic images of Drosophila compound eyes from wt, GMR-tom20-pink1-GFP/GMR-flag-parkin (pink1+parkin), GMR-tom20-pink1 S346A -GFP/GMR-flag-parkin (pink1 S346A +parkin), GMR-tom20-pink1 S519A -GFP/GMR-flag-parkin (pink1 S519A +parkin), GMR-tom20-pink1 S346D -GFP/GMR-flag-parkin (pink1 S346D +parkin), GMR-tom20-pink1 S346D KD -GFP/GMR-flag-parkin (pink1 S346D KD + parkin), GMR-tom20-pink1-GFP/GMR-flag-parkin S94A (pink1+parkin S94A ), and GMR-tom20-pink1 S346A -GFP/GMR-flag-parkin S94A (pink1 S346A +parkin S94A ). PINK1 with phosphorylation deficient (Serine to Alanine) mutation on residue 346 (S346A) but not on residue 519 (S519A) abolished the photoreceptor neuron degeneration phenotype, whereas phosphorylation mimic (Serine to Aspartic acid) mutation on residue 346 (S346D) of PINK1 caused obvious external eye degeneration, although this was less severe than wild-type PINK1. Scale bar represents 100 μm.   Figure S6A). Therefore, we substituted the Ser94 residue with Ala to abolish this PINK1-induced Parkin phosphorylation and expressed Parkin S94A in the compound eyes ( Supplementary Figures S6B and C). Coexpression of TOM20-PINK1 and Parkin S94A did not result in a severe retinal degeneration phenotype as with wild-type Parkin (Figures 3a and b), which suggested that PINK1 kinase activity toward Parkin is also essential for the activation of the PINK1/Parkin pathway.
To further check whether GMR-tom20-pink1/GMR-flagparkin S94A flies underwent an age-dependent retinal degeneration, we counted the number of rhabdomeres per ommatidium on aged animals ( Figure 3d). The flies with TOM20-PINK1 and Parkin S94A coexpressed displayed a mild age-dependent loss of photoreceptor cells (Figures 3c and d). Moreover, GMR-pink1 S346A -GFP/GMR-flag-parkin S94A flies displayed a similar severity of photoreceptor cell degeneration as flies with PINK1 S346A and wild-type Parkin coexpressed, which indicated that Parkin phosphorylation is an event downstream of autophosphorylation of PINK1 on S346 (Figures 3c and d). The more profound suppressive effect of phosphorylation-deficient substitution on PINK1 over Parkin suggested that PINK1-mediated phosphorylation of PINK1 and Parkin might have different roles in the mitochondrial quality-control pathway. Nevertheless, phosphorylation of both PINK1 and Parkin is required for the activation of PINK1/Parkin signaling.
Parkin recruitment by PINK1 is dependent on phosphorylation of PINK1 but independent of phosphorylation of Parkin. We reasoned that the abolishment of the phosphorylation of PINK1 or Parkin might fail to activate the PINK1/Parkin pathway by disrupting the Parkin recruitment to the OMM and/or causing impairment of Parkin activity. We tested the first hypothesis by examining the localization of Parkin in the third instar eye discs. Although Parkin colocalized with wild-type PINK1 and TOM20 on mitochondria, PINK1 lacking kinase activity failed to recruit Parkin to mitochondria and had low Mander's coefficient values with Parkin, confirming that PINK1 kinase activity is required for mitochondrial translocation of Parkin in vivo (Figures 4a, b, g,  Supplementary Figures S7A, B, and G). Similar to PINK1 KD , PINK1 with the S346A replacement did not efficiently recruit Parkin to mitochondria, whereas the S346D mutation induced Parkin translocation and displayed significantly higher Mander's coefficient values compared with PINK1 KD (Figures 4c,  d, g, Supplementary Figures S7C, D, and G). However, although Parkin S94A did not cause severe retinal cell degeneration in combination with TOM20-PINK1, it still efficiently colocalized with TOM20-PINK1 and mitochondria when coexpressed (Figures 4f, g, Supplementary Figures  S7F and G). To completely exclude the influence of Parkin phosphorylation on its translocation to mitochondria, we also checked localization of Parkin in eye discs expressing TOM20-PINK1 S346D KD -GFP and Flag-Parkin. We found that PINK1 S346D KD had the same Mander's coefficient value with Parkin as PINK1 S346D did (Figures 4d, e, g, Supplementary  Figures S7D, E, and G). These results suggest that PINK1 autophosphorylation is required and sufficient for Parkin translocation and that PINK1-dependent phosphorylation of Parkin is dispensable for its mitochondrial translocation.
Autophosphorylation of PINK1 activates its kinase activity toward Parkin. As PINK1 autophosphorylation is an upstream event of Parkin phosphorylation, autophosphorylation of PINK1 may be also required for PINK1 kinase activity toward Parkin. To examine this possibility, we coexpressed TOM20-PINK1 and Parkin in S2 cells and checked the phosphorylation status of Parkin. We observed no evidence of Parkin phosphorylation in samples lacking TOM20-PINK1-GFP expression (Figure 5a). However, when coexpressed with TOM20-PINK1, Parkin exhibited a shift that was indicative of phosphorylation ( Figure 5a). This phosphorylation modification of Parkin is dependent on PINK1 kinase activity as no phosphorylated band was detected when Parkin was coexpressed with TOM20-PINK1 KD (Figure 5a). Moreover, there was no gel shift for Parkin when it was coexpressed with non-phosphorylated PINK1 (PINK1 S346A ) (Figure 5b), which suggested that the phosphorylation on PINK1 S346 activates its kinase activity toward Parkin.
Autophosphorylation-deficient PINK1 failed to rescue the degeneration phenotypes of the pink1 mutant flies. To investigate the in vivo roles of PINK1 autophosphorylation, we constructed multiple transgenic lines possessing a pink1 genomic rescue transgene with different autophosphorylation capacities. These included wild-type PINK1 (pink1 WT ), phospho-deficient PINK1 (pink1 S346A ), phospho-mimic PINK1 (pink1 S346D ), and another putative phospho-deficient PINK1 (pink1 S519A ). The pink1 B9 mutants displayed abnormal wing posture, crushed thorax, and slower climbing speed phenotypes, which were fully rescued by the expression of the wild-type or S346D form of PINK1 (Figure 6a). 31,32 However, autophosphorylation-deficient PINK1 (pink1 S346A ) failed to alleviate the climbing defects of the pink1 B9 mutants (Figure 6a). Moreover, consistent with previous results that S346 is the sole autophosphorylation site of Drosophila PINK1, pink1 S519A still fully rescued the climbing defects caused by PINK1 deficiency (Figure 6a).
The defective mitochondria in indirect flight muscles (IFMs) is the reason for the downturned wing and reduction of climbing ability in the pink1 B9 flies. 31,32 We thereby used TEM to examine the effects of PINK1 autophosphorylation on IFMs' mitochondria in detail. Exactly similar to wild-type PINK1, the expression of either pink1 S346D or pink1 S519A in the pink1 B9 mutant showed normal mitochondrial morphology and densely packed cristae structure in the fly thorax (Figure 6b). In contrast, disorganized muscle fibers and swelled mitochondria with very few cristae were still observed in the pink1 B9 mutant, in which a phospho-deficient form of PINK1 (PINK1 S346A ) was expressed (Figure 6b).
The loss of dopaminergic neurons is one of the major characteristics of Parkinson's disease. 33 We therefore examined whether the autophospho-deficient pink1 mutants could rescue the dopaminergic neurodegeneration phenotype  (Figure 6c). 32 There was no statistical significance in the number of dopaminergic neurons between wild-type, pink1 B9 and pink1 B9 with pink1 WT , pink1 S346A , pink1 S346D , and pink1 S519A transgenes expressed on the first day of eclosion. However, at 20 days of age, a small but significant loss of dopaminergic neurons was detected in the pink1 B9 flies compared with the wild type (Figure 6d and Supplementary Figure S8). This gradual loss of dopaminergic neurons in the pink1 mutant animals was fully rescued by the expression of pink1 S346D and pink1 S519A as well as of pink1 WT , whereas pink1 S346A did not affect the reduction of dopaminergic neurons in the pink1 B9 brain (Figure 6d and Supplementary Figure S8). Taken together, these phenotypic and behavioral analyses strongly support that autophosphorylation of PINK1 on Serine 346 has a key role in its function in mitochondrial quality control in vivo.

Discussion
PINK1 has been reported to phosphorylate many mitochondria-associated proteins, including Mfn2, NdufA10, Bcl-xL, and motor/adaptor complex Miro. [34][35][36][37] However, phosphorylation of these mitochondrial proteins may not have a key role in PINK1/Parkin-dependent mitophagy, as targeting of PINK1 to other organelles such as peroxisomes and lysosomes that lack these PINK1 substrates can also induce organelle selective autophagy. 12 Therefore, PINK1 and additional cytosolic targets may be mediators of PINK1 kinaseinduced Parkin translocation and mitophagy. We established a genetic model in Drosophila of the induction of the PINK1/ Parkin pathway through coexpression of mitochondriatargeted PINK1 and Parkin and found that PINK1 and Parkin were both phosphorylated by PINK1 kinase. Furthermore, disruption of PINK1 phosphorylation prevented the mitochondrial translocation of Parkin, and the absence of Parkin phosphorylation abolished PINK1/Parkin-induced cell death. Therefore, PINK1-dependent phosphorylation of both PINK1 and Parkin is essential for the PINK1/Parkin-mediated mitochondrial quality-control pathway. Mitochondrial uncoupler CCCP depolarizes the mitochondria and induces the selective removal of dysfunctional mitochondria in a PINK1-and Parkin-dependent manner. 38 However, our study indicates that activated PINK1 and Parkin caused photoreceptor neuron death irrespective of the mitochondrial dysfunction, as coexpression of PINK1 and Parkin did not affect mitochondrial membrane potential. Moreover, activated PINK1-and Parkin-mediated cell death was unaffected by knocking out atg7 or knocking down atg1. 39,40 Furthermore, mitochondrial resident proteins remain unchanged in dead retinal cells, indicating that the PINK1/ Parkin-induced cell death is not due to a complete loss of mitochondria. In conclusion, consistent with the previous study, PINK1/Parkin induced cell death independently of mitochondrial autophagy. 41 The molecular mechanisms of the PINK1/Parkin-induced cell death need to be elucidated in future studies.
A previous study reported autophosphorylation of PINK1 observed at residues S228 and S402 following mitochondria depolarization in human cells. 26 Here we demonstrated that fly PINK1 was autophosphorylated at only one site, Ser346, which is conserved with Ser228 in human PINK1. We showed that substitution of Ser346 with Ala completely abolished PINK1 autophosphorylation. Phosphorylation of human PINK1 on Ser402 has been reported to be involved in PINK1 dimerization, Parkin recruitment, and the induction of mitophagy. 27,42 However, we found no evidence of phosphorylation modification at this site in flies. Moreover, pink1 S519A mutants can rescue all the degeneration phenotypes of pink1 B9 to the same extent as the wild-type PINK1 did. In contrast, the expression of PINK1 S346A failed to rescue the degeneration phenotypes of pink1 null mutants. Therefore, autophosphorylation of PINK1 on Ser346 is essential for its function in mitochondrial quality control in vivo.
PINK1 phosphorylates human Parkin at Ser65, a modification that appears to regulate ubiquitin-ligase activity and mitophagy in cultured cells and in flies. 22,30,43 It has also been reported that Ser65 phosphorylation of human Parkin by PINK1 is required for mitochondrial translocation of Parkin in  Figure 5 PINK1 autophosphorylation is required for its kinase activity toward Parkin. (a) Parkin undergoes PINK1 kinase activity-dependent phosphorylation modification. Whole-cell lysates of S2 cells cotransfected with flag-parkin and tom20-pink1-GFP or tom20-pink1 KD -GFP were subjected to phos-tag gel electrophoresis. (b) The phosphorylationdeficient PINK1 (S346A) did not phosphorylate Parkin efficiently. S2 cells were cotransfected with mcherry-parkin and wild-type or mutant tom20-pink1-GFP Figure 6 Autophosphorylation-deficient PINK1 failed to rescue the pink1 mutant phenotypes. (a) Expression of the phospho-deficient pink1 S346A transgene failed to rescue abnormal climbing abilities of the pink1 B9 mutant. Genomic transgenes expressing wild-type PINK1 (pink1 B9 ;;pink1 WT ) or mutant PINK1 (pink1 B9 ;;pink1 S346A , pink1 B9 ;;pink1 S346D , and pink1 B9 ;;pink1 S519A ) were introduced into pink1 null background (pink1 B9 ). Male flies that were 1-3 days old were used for the assay, and significant differences were determined using Student's t-test (NS: not significant; **Po0.01; n = 150-161). (b) TEM images of the IFMs from wt, pink1 B9 , pink1 B9 ;;pink1 WT , pink1 B9 ;;pink1 S346A , pink1 B9 ;; pink1 S346D , and pink1 B9 ;;pink1 S519A flies at 3-5 days old. Arrows indicate mitochondria, and arrow heads indicate muscle fibers. The scale bars represent 1 and 0.5 μm on the upper and bottom panels, respectively. (c and d) Expression of pink1 S519A and pink1 S346D but not pink1 S346A prevented age-dependent loss of dopaminergic neuron in cultured cells. 21,44,45 However, using a Drosophila system, we found that, although the absence of PINK1-mediated phosphorylation of Parkin blocked PINK1/Parkin-induced cell death, phosphorylation-deficient Parkin still translocated to PINK1-targeted mitochondria. This might be because the absence of PINK1-mediated phosphorylation of Parkin blocked its activation without affecting its translocation. Moreover, disruption of PINK1 kinase activity in the autophospho-mimic form of PINK1 did not affect its ability to recruit Parkin. It is clear that phosphorylation of Parkin by PINK1 is not required for Parkin translocation to PINK1targeted mitochondria.
The autophosphorylation of PINK1 is required but not sufficient to induce Parkin function, as the phospho-mimetic S346D mutants did not activate Parkin and drive cell death when PINK1 lacked its kinase activity. Rather, the autophosphorylation of PINK1 was a prerequisite for its kinase activity toward Parkin, as PINK1 with the unphosphorylated S346A mutation had reduced kinase activity against Parkin. Moreover, autophosphorylation of PINK1 is essential to induce Parkin translocation. However, although autophospho-mimic PINK1 was able to induce Parkin translocation in the absence of kinase activity, the efficiency is not as high as wild-type PINK1. Recent evidence suggests that PINK1 controls translocation and activity of Parkin by phosphorylating ubiquitin. [23][24][25]46 Therefore, it is possible that PINK1dependent phosphorylation of ubiquitin also contribute to Parkin mitochondrial translocation.
Based on the data from our current work and along with previous work, we propose that PINK1 is autophosphorylated when stabilized on depolarized mitochondria, a process that promotes the mitochondrial translocation of Parkin and increases its kinase activity on Parkin (Figure 7). After being recruited to the mitochondria, Parkin is phosphorylated and activated by PINK1 to ubiquitinate its substrates, further promoting mitophagy (Figure 7). Recent evidence suggests that PINK1 controls Parkin E3 ligase activity not only by phosphorylating Parkin but also by phosphorylating ubiquitin, [23][24][25] and the phosphorylation of ubiquitin on residue Ser65 is also required for Parkin accumulation on damaged mitochondria. 46 Therefore, it is also possible that phosphorylation of other PINK1 substrates such as ubiquitin is affected by PINK1 autophosphorylation, and such events may have key roles in the PINK1/Parkin pathway.
The wild-type and truncated pink1 or parkin DNA sequences were subcloned into the pGMR-attB vector for use in generating the transgenic fly strains. The pink1 genomic rescue constructs pink1 WT , pink1 S346A , pink1 S519A , and pink1 S346D were generated by replacing the GMR sequence of pGMR-attB-pink1, pGMR-attB-pink1 S346A , and pGMR-attB-pink1 S346D plasmids with pink1 endogenous promoter sequence (−1291 to +715 base pairs 5′ to the transcription starting site). 31 The constructs were injected into M(3xP3-RFP.attPZH-86Fb) or M(3xP3-RFP.attPZH--36B) embryos, and site-specific transformants were identified on the basis of eye color. 48 All transgenic lines were subsequently tested for protein expression levels by western blotting. Generation of TOM20 antibodies. Polyclonal antibodies against Drosophila TOM20 were generated by immunizing a rat with peptides conjugated to KLH.

Figure 7
A model of PINK1-mediated phosphorylation in the PINK1/Parkin pathway. (a) In damaged mitochondria, PINK1 stabilized on the mitochondrial OMM undergoes autophosphorylation on S346 in normal conditions. The phosphorylated PINK1 promotes Parkin mitochondrial translocation and phosphorylate Parkin on residue S94, which activates Parkin E3 ubiquitin ligase activity to ubiquitinate its mitochondrial substrates for initiating the autophagy of mitochondria. (b) Without autophosphorylation modification on S346A mutant, PINK1 fails to recruit, phosphorylate, and activate Parkin. Therefore, inactive Parkin randomly distributes in the cytosol upon phosphorylation deficient PINK1 S346A anchored on the mitochondrial OMM. (c) Parkin with PINK1-dependent phosphorylation deficient in its ubiquitin-like domain can still be recruited to mitochondria by PINK1 but is not able to activate the PINK1/Parkin pathway The peptides used to generate the anti-TOM20 antibodies comprised amino acids 128-147 (QEFGNRAAEGNDGPIVLGQS) of Drosophila TOM20.
Transmission electron microscopy. Fly heads or thoraxes were dissected, fixed, dehydrated, and embedded in LR White resin as described previously. 49 Thin sections (85 nm) were cut with a microtome and examined by TEM (JEM-1400 electron microscope; JEOL, Tokyo, Japan). The images were acquired using a model 832 Gatan camera (Gatan, Inc., Pleasanton, CA, USA).
Optical neutralization assay. The rhabdomeres of ommatidium were examined directly by the technique of optical neutralization. 29 Briefly, the heads of flies were immerged into mineral oil in an orientation with antennas facing up and were examined by a DIC light microscope (Nikon, Tokyo, Japan).
Immunoprecipitation and mass spectrometric analysis. Fly heads were homogenized in buffer A with 1% NP-40. The supernants were then immunoprecipitated using GFP-Trap magnetic beads (Chromotek, Planegg-Martinsried, Germany). After washing twice with buffer A, the beads were resuspended in SDS sample buffer and fractionated by SDS-PAGE. Protein bands on the SDS-PAGE gel excised and de-stained, followed by in-gel digestion with trypsin (10 ng/μl trypsin, 50 mM ammonium bicarbonate, pH 8.0) overnight at 37°C. Peptides were extracted sequentially with 5% formic acid/50% acetonitrile and 0.1% formic acid/75% acetonitrile and then concentrated by nitrogen purging. The extracted peptides were separated on an analytical capillary column (50 μm × 15 cm) packed with 5 μm spherical C18 reversed phase material (YMC). A Waters nanoAcquity UPLC system (Waters, Milford, MA, USA) was used to generate the following UPLC gradient: 0-30% B in 40 min, 30-70% B in 15 min (A = 0.1% formic acid in water, B = 0.1% formic acid in acetonitrile). The eluted peptides were introduced via a nano-ESI ion source into an LTQ Orbitrap Velos mass spectrometer (ThermoFisher Scientific, Waltham, MA, USA). The mass spectrometer was operated in data-dependent mode, with one MS scan followed by four CID (collision-induced dissociation) and four HCD (high-energy collisional dissociation) MS/MS scans for each duty cycle. Database searches were performed on an in-house Mascot server (Matrix Science Ltd., London, UK) against the PINK1 protein sequence. Searches examined the following modifications: oxidation on methionine, carbamidomethylation on cysteine, and phosphorylation on serine/ threonine/tyrosine. The tandem mass spectra of matched phosphorylated peptides were checked for the phosphorylation site.
To evaluate the phosphorylation levels of the PINK1 and Parkin proteins in the absence of phosphorylation site-specific antibody, 6% polyacrylamide gels containing 50 μM phostag acrylamide (Wako Chemicals, Osaka, Japan) and 100 μM MnCl 2 were used. After electrophoresis, phostag acrylamide gels were washed in general transfer buffer containing 0.02% SDS and 2 mM EDTA and then replaced with general transfer buffer lacking EDTA. After completely washing out manganese ions, the proteins were transferred onto Immobilon-FL transfer membranes (Millipore) and immunoblotted using a standard protocol.
Immunostaining. Eye discs from third instar larvae were dissected in PBS solution (pH 6.8) and fixed in 4% paraformaldehyde in PBS buffer for 40 min. The fixed eye discs were incubated in diluted primary anti-serum, rat anti-TOM20 (1:200), mouse anti-Flag (1:500, Sigma), and Rabbit anti-GFP (1:1,000, Invitrogen), followed by staining with secondary antibody anti-Rat Alexa Fluor 647 (1:500, Invitrogen), anti-mouse Alexa Fluor 568 (1:500, invitrogen), and anti-Rabbit Alexa Fluor 488 (1:500, Invitrogen). To detect the colocalization of PINK1, Parkin, and mitochondria in S2 cells, S2 cells were cotransfected with pMTa-tom20-pink1-GFP and PIB-mcherry-parkin. The transfected cells were fixed with 4% paraformaldehyde and stained with the TOM20 antibody (1:200), followed by anti-Rat Alexa Fluor 647-conjugated secondary antibody (1:500; Invitrogen). Images were captured with an Eclipse Ni microscope confocal microscope (Nikon). The Mander's Overlap Coefficient as a measure of colocalization between Parkin and PINK1 was calculated in confocal fluorescence microscopic images using the ImageJ software (National Institutes of Health, Bethesda, MD, USA). For counting dopaminergic neurons, adult brains were dissected and stained with rabbit anti-TH antibody (1:200, Millipore), followed by anti-Rabbit Alexa Fluor 488 antibody (1:500, Invitrogen). TH immunoreactive cells were imaged with an Eclipse Ni microscope confocal microscope (Nikon), and DA neurons of the DL1 cluster were counted. 50 Measurement of mitochondrial membrane potential. The dye JC-10 (Enzo Life Sciences, Farmingdale, NY, USA) was used to evaluate mitochondrial membrane potential. The third instar larval eye discs were dissected and labeled with JC-10 as described. 49 Images were obtained on a Nikon A1 confocal microscope. The ratio of fluorescence emissions at 525 and 590 nm was used for quantification analysis.