Abstract
Mitochondrial fusion is a highly coordinated process that mixes and unifies the mitochondrial compartment for normal mitochondrial functions and mitochondrial DNA inheritance. Dysregulated mitochondrial fusion causes mitochondrial fragmentation, abnormal mitochondrial physiology and inheritance, and has been causally linked with a number of neuronal diseases. Here, we identified a diterpenoid derivative 15-oxospiramilactone (S3) that potently induced mitochondrial fusion to restore the mitochondrial network and oxidative respiration in cells that are deficient in either Mfn1 or Mfn2. A mitochondria-localized deubiquitinase USP30 is a target of S3. The inhibition of USP30 by S3 leads to an increase of non-degradative ubiquitination of Mfn1/2, which enhances Mfn1 and Mfn2 activity and promotes mitochondrial fusion. Thus, through the use of an inhibitor of USP30, our study uncovers an unconventional function of non-degradative ubiquitination of Mfns in promoting mitochondrial fusion.
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Introduction
Mitochondria are highly dynamic organelles undergoing constant fission and fusion to maintain normal morphology, which is important for mitochondrial functions and fundamental cellular processes1,2. Several key molecules are known to mediate this complex process. Mfn1 and Mfn2 are GTPases anchored to the outer mitochondrial membrane3. The homo- and heterodimerization between Mfn1 and Mfn2 are essential for the tethering of adjacent mitochondria before the complete fusion of neighboring mitochondria4,5,6,7. Another GTPase, OPA1, localized in the intermembrane space and the inner membrane of mitochondria, is responsible for fusion of the inner mitochondrial membrane8,9. Dysregulated activity of fusion mediators leads to extensive mitochondrial fragmentation and severe mitochondrial dysfunction, such as loss of mitochondrial potential and defect in respiratory capacity, possibly as a consequence of the loss of mitochondrial DNA (mtDNA) in individual mitochondria10,11. Mice lacking Mfn1, Mfn2 or OPA1 die at an early embryonic stage, indicating that fusion factors are strictly required during early development12,13. Moreover, point mutations in Mfn2 or OPA1 lead to severe neurodegenerative diseases such as Charcot-Marie-Tooth type 2A and dominant optic atrophy14,15. On the other hand, mitochondrial fission is regulated by another GTPase family member, dynamin-related protein 1 (Drp1)16. Drp1 is recruited to mitochondria by mitochondrial fission factor or MiD49/51 and self-assembles into spirals surrounding the mitochondria to drive membrane constriction and fission16,17,18,19. Cells lacking Drp1 showed deficiency in mitochondrial fission and exhibited abnormally elongated mitochondria20. Despite the importance of mitochondrial dynamics in many biological processes, including embryo development, neuron degeneration, cellular metabolism and cell survival, the regulatory mechanisms by which the mitochondrial fusion and fission processes are orchestrated to fulfill these complex functions remain poorly understood. In particular, little is known about how mitochondrial fusion is regulated. Recently, the mitofusin binding protein (MIB) was found to be a negative regulator of Mfn121.
Early studies in yeast revealed that ubiquitination affects mitochondrial morphology and mitochondrial inheritance22. In mammalian cells, several E3 ligases were found to localize at or translocate to mitochondria to mediate ubiquitination of Mfn1/2 or Drp1 for their degradation23,24,25,26,27,28,29,30. Recent research has shown that ubiquitination not only leads the protein substrate to the proteasome or lysosome for degradation, but also regulates various cellular functions, including signal transduction, endocytic trafficking and DNA repair without affecting protein stability31. Many proteins contain ubiquitin-binding domains or motifs that function as ubiquitin receptors for protein-protein interactions32. It is thus intriguing to determine whether such a mechanism is involved in regulating mitochondrial dynamics. Protein ubiquitination is a reversible process and this reversibility is accomplished by deubiquitinases that remove ubiquitin from their substrates33. There are about 100 deubiquitinases in the human genome, and more than half of human deubiquitinases belong to the ubiquitin-specific protease (USP) subfamily that contains critical cysteine and histidine residues in the reactive center34. A number of deubiquitinases are reported to play critical roles in diverse cellular and physiological functions such as cell signaling, histone modification and so on35,36. Abnormal deubiquitinase activity is closely related to tumor cell survival as these enzymes modulate TGF-β, Wnt and TNF signaling pathways37. Several small molecules that inhibit distinct deubiquitinases have been identified, and these small molecules would be useful tools for studying the molecular mechanisms underlying the actions of these deubiquitinases, in addition to their potential therapeutic applications38,39.
In the present study, we identified a small natural derivative S3, which potently activated mitochondrial fusion accompanied by restoration of normal mitochondrial function. We found that S3-induced inhibition of USP30, a mitochondria-localized deubiquitinase, increased the ubiquitination of Mfn1 and Mfn2 without affecting their protein levels. This non-degradative ubiquitination of Mfns is involved in regulation of mitochondrial fusion.
Results
S3-induced mitochondrial re-networking in the absence of either Mfn1 or Mfn2
To understand the regulatory mechanism of mitochondrial fusion and fission, we screened for small molecules that could induce the elongation of mitochondria in Mfn1-knockout (Mfn1−/−) MEF cells. In these cells, small-fragmented mitochondria dispersed within the cell and the elongation of mitochondria was readily detectable. From the 300 compounds obtained, we identified 15-oxospiramilactone, a diterpenoid derivative (named S3 hereafter)40, which could induce remarkable mitochondrial elongation in cells that lack Mfn1. Using a mitochondrial matrix-targeted DsRed protein, we monitored mitochondrial morphological changes at the single-cell level in real time (Figure 1A). Following the addition of 5 μM S3, the mitochondrial morphology changed from spheres to highly-interconnected filaments, and the disrupted mitochondrial network was rebuilt within 2 h. S3-induced mitochondrial morphological change occurs in a dose- and time-dependent manner (Figure 1A and 1B). Treatment with 2 μM S3 for 24 h could efficiently induce mitochondrial elongation in approximately 80% of the cells without affecting the cell viability, while concentration higher than 5 μM could kill the cells through apoptosis38 (Supplementary information, Figure S1). We thus chose this dose and timepoint for further experiments.
To demonstrate that S3 induces complete mitochondrial fusion, but not mere mitochondria association or aggregation, we carried out an ultrastructural analysis by electron microscopy (EM). EM pictures showed that following S3 treatment, the dot-like or rod-like mitochondria in Mfn1−/− or Mfn2−/− MEF cells were changed to an interconnected mitochondrial network with branching (Figure 1C), indicating that S3 induces complete and coordinated mitochondrial fusion.
We next sought to understand if S3-induced mitochondrial fusion is dependent on the core mitochondrial fusion machinery. We compared the effects of S3 treatment on mitochondrial morphology in WT, Mfn1−/−, Mfn2−/−, Mfn1/2-double knockout (Mfn Dko) and OPA1-knockout (OPA1−/−) MEF cells. All mitochondria in these mutant cells were fragmented and dot-like or rod-like as described earlier. We found that S3 induced a remarkable mitochondrial elongation in cells that were deficient in either Mfn1 or Mfn2 (Figure 1D and 1E). Actually, in most of these S3-treated cells, mitochondria were well interconnected to form a mitochondrial reticulum similar to that observed in WT cells. However, S3 failed to change the mitochondrial morphology when both Mfn1 and Mfn2 were deleted, or in cells that were deficient in OPA1. These data demonstrate that OPA1 and at least one of the Mfns are required for S3-induced mitochondrial fusion.
To further clarify whether S3-induced mitochondrial fusion requires functional Mfns, we overexpressed GTPase mutants of Mfn1 and Mfn2 in Mfn Dko cells. As shown in Supplementary information, Figure S2, when WT Mfn1 or Mfn2 was expressed in Mfn Dko cells, mitochondria became highly fused and aggregated. After S3 treatment, the mitochondrial morphology did not show much change due to the already very condensed structure. However, when GTPase mutants of Mfns (Mfn1 K88T or Mfn2 K109A) were expressed in Mfn Dko cells, mitochondria remained fragmented in the absence or presence of S3, which indicates that S3-induced mitochondrial fusion is dependent on the normal function of Mfns. These data showed that S3 requires functional Mfns (either Mfn1 or Mfn2) to induce mitochondrial fusion.
Restoration of mitochondrial oxidative phosphorylation and the distribution of mtDNA
Previous studies have revealed that cells that are deficient in Mfn1, Mfn2 or OPA1 have impaired mitochondrial functions10,11. It is therefore important to determine whether S3 can restore mitochondrial functions in these cells. We first monitored Δψm using a mitochondria-specific dye MitoTracker Red, whose sequestration into the mitochondria is dependent on Δψm. Cells were transfected with mitoGFP, which is located in the mitochondrial matrix independent of Δψm, and then stained with MitoTracker Red. In WT cells, GFP-marked mitochondria were uniformly stained by MitoTracker Red and the two fluorophores were completely colocalized (Figure 2A). However, Mfn1−/−, Mfn2−/−, Mfn Dko and OPA1−/− cells showed heterogeneity in Δψm. A portion of the mitochondria in these cells were marked only by mitoGFP, but not by MitoTracker Red. Importantly, following S3 treatment, the mitochondria fused and the mitochondrial network remerged with the overall Δψm recovered in Mfn1−/− and Mfn2−/− cells (Figure 2A), indicating that the Δψm had been restored by the whole mitochondrial reticulum. However, S3 failed to restore the loss of Δψm in Mfn Dko or OPA1−/− cells, which is consistent with their unchanged mitochondrial morphology (Figure 1D and 1E).
We next measured the cellular ATP levels. In Mfn1−/− or Mfn2−/− cells, S3 induced a significant increase in the ATP levels (Figure 2B). However, there was no difference between the untreated and treated Mfn Dko cells (Figure 2B), indicating that the increase in ATP levels is related to the restoration of the mitochondrial network. To verify that the increase of ATP level is due to the increase of mitochondrial oxidative phosphorylation (OXPHOS), we estimated the OXPHOS capacity as previously described41 (Figure 2C). A substrate of OXPHOS, methylpyruvate (MeP), was added to the adherent cells to activate respiration and the ATP level was measured at an interval of 5 min. Oligomycin, an inhibitor of ATP synthase, was used to confirm that the ATP level increase is derived from mitochondria.
Interestingly, untreated Mfn1−/−, Mfn2−/− or Mfn Dko cells showed weak or no increase in the ATP level upon MeP treatment, as previously reported41. However, after S3 treatment, Mfn1−/− and Mfn2−/− cells showed a significant increase in the level of ATP when treated with MeP, while the ATP level of Mfn Dko cells still remained at the basal level. These results suggest that the increase in the cellular ATP level occurred mainly because of the enhanced ATP production from mitochondria.
A distinguishing feature of mitochondria is the existence of mitochondrial DNA (mtDNA), which encode components of the electron transport chain. Previous reports have shown that mitochondrial fusion is important for the maintenance of mtDNA, and that cells that are deficient in Mfn1 or Mfn2 have abnormal mtDNA inheritance42,43. Using a specific antibody that recognizes DNA, we found that in Mfn1−/− or Mfn2−/− or OPA1−/− cells, a portion of the mitochondria lack mtDNA, which is consistent with previous reports42,43. As expected, in S3-treated Mfn1−/− or Mfn2−/− cells, the mitochondrial network was rebuilt and the mtDNA was distributed throughout the mitochondrial network (Figure 2D and 2E). In contrast, in S3-treated OPA1−/− cells, this did not occur due to the complete lack of mitochondrial fusion. We also measured the numbers of mtDNA copies in untreated and S3-treated cells. Our results showed that the overall mtDNA copy numbers were not changed after S3 treatment (Supplementary information, Figure S3). Clearly, S3 only induced redistribution of mtDNA through restoration of the mitochondrial network without affecting the total mtDNA copy number.
S3-induced activation of mitochondrial fusion re-networks mitochondria
Mitochondrial morphology is regulated by two opposing processes, namely fusion and fission. S3-induced re-networking of mitochondria could be due to either activation of fusion or inhibition of fission. To clarify this question, we first assayed the rate of mitochondrial fusion using a mitochondria-targeted photoactive fluorescence protein, Mito-PAGFP, as previously described44. After activation by 405 nM exciting light, activated Mito-PAGFP will diffuse to other mitochondria accompanied by the occurrence of mitochondrial fusion. Thus the rate of fusion can be calculated by the decline in fluorescence intensity. In Mfn1−/− or Mfn2−/− cells, due to the lack of fusion, the intensity of fluorescence remained stable over 3 h. Strikingly, upon S3 treatment, the rate of mitochondrial fusion dramatically increased to a level that is comparable to that of the WT cells (Figure 3), as reflected by the rapid diffusion of fluorescence within the mitochondrial network. Overexpression of Drp1 did not decelerate the rate of mitochondrial fusion in both S3-treated and untreated Mfn1−/− cells (Figure 3). In contrast, there is no decrease of fluorescence intensity in Mfn Dko cells when treated with S3 (Figure 3).
To further testify whether S3-induced mitochondrial fusion is due to the inhibition of Drp1, which is responsible for mitochondrial fission, we overexpressed Drp1 in WT, Mfn1−/− and Mfn2−/− cells (Supplementary information, Figure S4A and S4B). The results showed that Drp1 could not prevent S3-induced mitochondrial fusion. S3 did not affect either the localization or GTPase activity of Drp1 (Supplementary information, Figure S4C and S4D). As the phosphorylation of Drp1 also regulates its activity in the process of mitochondrial fission, we checked the phosphorylation status of Drp1 after S3 treatment and did not find any change (Supplementary information, Figure S4E). Taken together, we conclude that S3 clearly enhances mitochondrial fusion without affecting the activity of the main fission component Drp1.
Deubiquitinase USP30 is a target of S3 in S3-induced mitochondrial fusion
To understand the molecular mechanism of S3-induced mitochondrial fusion, we checked the protein levels of Mfn1 and Mfn2, which are the master factors in this process. However, we did not detect any significant change in Mfn1 and Mfn2 protein levels even after a prolonged period of S3 treatment (Figure 4A). Interestingly, the ubiquitination of both Mfn1 and Mfn2 increased after S3 treatment (Figure 4B), suggesting that S3 may regulate the function of Mfn1/2 via induction of ubiquitination. The cycloheximide (CHX) chase assay revealed that S3 has no effect on the degradation of Mfn1/2 (Figure 4C).
It is of interest to note that USP30 is a deubiquitinase localized on mitochondria and can affect mitochondrial morphology in an Mfn1/2-dependent manner45. Then we synthesized a Biotin-modified S3 to test whether S3 directly binds to USP30 (Supplementary information, Figure S5). We incubated the cell lysates with Biotin-S3 and found that Myc-tagged USP30 could be pulled down by Biotin-S3, confirming the direct interaction between USP30 and S3 (Figure 4D). As S3 is a “thiol-Michael addition” molecule, it is likely that Biotin-S3 binds to cysteine in the catalytic domain of USP30. Several mutants of USP30 were generated, each containing a point mutation in the catalytic domain of USP30 (Figure 4E). Among them, two mutants (C77S and H452A) involve substitution of residues that are critical for deubiquitinase activity, and the other two (C234S and C284S) involve cysteine residues that were randomly chosen, and thus serve as controls. The binding of S3 to USP30 was abolished when C77 was mutated, while other mutations of cysteine or histidine residues failed to abolish the binding. Thus, we concluded that C77 in the catalytic domain of USP30 is the main binding site of Biotin-S3. We also showed that S3 could inhibit the deubiquitinase activity of USP30 in vitro (Supplementary information, Figure S6), as assayed by its cleavage of Lys48- and Lys63-linked Ub4 chains to produce ubiquitin trimers. Taken together, these data show that S3 directly inhibits the deubiquitinase activity of USP30 through its interaction with the cysteine residue in the catalytic domain.
We next examined whether USP30 inhibition is responsible for the mitochondrial fusion induced by S3 (Figure 5A and 5B). Mfn1−/− and Mfn2−/− cells were transfected with WT USP30 or a USP30 mutant (USP30-C77S) and the percentage of cells with filamental mitochondria was analyzed following S3 treatment. In untransfected Mfn1−/− or Mfn2−/− cells, approximately 80% of the cells contained fused mitochondria after S3 treatment, whereas only ∼35% of Mfn1−/− cells and ∼38% of Mfn2−/− cells that were transfected with USP30 showed this phenotype. In contrast, overexpression of USP30-C77S did not affect S3-induced mitochondrial fusion in Mfn1−/− or Mfn2−/− cells, indicating that S3-induced mitochondrial fusion was partially inhibited by WT, but not by the inactive form of USP30. These data suggest that S3 may induce mitochondrial fusion via inhibition of USP30 activity.
To confirm that USP30 affects mitochondrial fusion in the absence of Mfn1 or Mfn2, we employed the knockdown approach to specifically downregulate its expression by shRNAs in Mfn1−/− or Mfn2−/− cells (Figure 5C, 5D and Supplementary information, Figure S7A). Interestingly, we found that knockdown of USP30 in Mfn1−/− and Mfn2−/− cells resulted in significant promotion of mitochondrial fusion (Figure 5D), which resembles the effect of S3 treatment. Approximately, 70% of Mfn1−/− cells and 75% of Mfn2−/− cells contain filamental mitochondria upon USP30-shRNA transfection, compared to 3% in scramble-transfected Mfn1−/− and 11% in scramble-transfected Mfn2−/− cells. However, S3 treatment cannot further increase the percentage of cells with filamental mitochondria in USP30-shRNA-tranfected Mfn1−/− or Mfn2−/− cells, indicating that depletion of USP30 is sufficient to render cells insensitive to S3 treatment. Collectively, these data clearly indicate that USP30 is a target of S3, and is responsible for mediating S3-induced mitochondrial fusion in Mfn1−/− or Mfn2−/− cells.
We also tested whether knockdown of USP30 can enhance mitochondrial function as S3 did. We found that in both Mfn1−/− and Mfn2−/− cells, knockdown of USP30 recovered the mitochondrial network along with the restoration of the overall Δψm, as indicated by the complete colocalization of Mitotracker Red and mitoGFP (Supplementary information, Figure S7B). Furthermore, the cellular ATP levels increased in both cell lines after knockdown of USP30 (Supplementary information, Figure S7C). These results indicate that USP30-knockdown cells have similar phenotypes in mitochondrial function as S3-treated cells.
USP30 regulates non-degradative ubiquitination of Mfn1/2
We next investigated whether USP30 regulates non-degradative ubiquitination of Mfn1 and Mfn2. We first examined whether USP30 had a physical interaction with Mfn1 or Mfn2. Immunoprecipitation was performed using lysates from HeLa cells overexpressing c-Myc-tagged USP30, and endogenous Mfn1 and Mfn2 were found to interact with USP30-Myc (Figure 6A). A pull-down assay showed that purified USP30-MBP protein can pull down Mfn1 or Mfn2 from the whole cell lysates, suggesting a direct interaction (Figure 6B). Importantly, we also found that USP30 could affect the ubiquitination levels of Mfn1 and Mfn2. When USP30 was overexpressed in HeLa cells, the ubiquitination levels of both Mfn1 and Mfn2 were obviously decreased compared to vector-transfected control cells (Figure 6C). In contrast, the ubiquitination levels of both Mfn1 and Mfn2 were not altered in cells expressing USP30-C77S. To further demonstrate that the regulatory function of USP30 in ubiquitination of Mfn1 and Mfn2 is specific, we performed rescue experiments. We stably knocked down USP30 by using RNAi in HeLa cells and then reintroduced the RNAi-resistant WT USP30 (Figure 6C). Indeed, ubiquitination of Mfn1 and Mfn2 significantly increased in USP30-RNAi cells and the ubiquitination of Mfn1 and Mfn2 was recovered to the levels similar to those in control cells when USP30 was reintroduced into these cells. The overall protein levels of Mfn1 and Mfn2 were not changed when USP30 expression level was altered.
To further confirm that USP30-regulated ubiquitination is non-degradative, we performed CHX chase assay in USP30-overexpressing and -knockdown cells. Our results showed that there was no significant difference in the degradation rate of Mfn1 and Mfn2 when USP30 was overexpressed or knocked down (Figure 6D and 6E). These results suggest that S3-induced ubiquitination of Mfn1 and Mfn2 does not lead to protein degradation. Taken together, we conclude that USP30 can regulate the non-proteolytic ubiquitination of Mfn1 and Mfn2.
Discussion
In the current study, we first identified a small natural compound, 15-oxospiramilactone (S3) derived from spiramine A of Spiraea japonica, which potently induces mitochondrial fusion. In previous studies, high concentrations of S3 were found to induce apoptosis, through inhibition of the Wnt pathway40 or upregulation of Bim46. However, at a low concentration, such as 2 μM, S3 does not induce apoptosis, indicating a completely different mechanism for the mitochondrial fusion induced by S3. S3-induced mitochondrial fusion is dependent on the existing fusion factors on both the outer and inner mitochondrial membranes as S3 treatment fails to to induce fusion in the absence of both Mfns or OPA1. To the best of our knowledge, S3 is the first identified naturally derived small molecule from plants that activates mitochondrial fusion and facilitates restoration of the mitochondrial network. Several chemical compounds including Mdivi-1, 15d-PGJ2 and ethacrinic acid have been reported to induce mitochondrial elongation through the inhibition of mitochondrial fission mediated by Drp147,48,49,50,51, which differs from the mechanism of S3-induced mitochondrial fusion as S3 does not inhibit Drp1 activity or phosphorylation (Supplementary information, Figure S4). However, Drp1 is not the only molecule involved in mitochondrial fission, whether S3 affects other molecular pathways in mitochondrial fission needs further investigation.
Recently, Tondera et al.41 reported that severe cell stresses, such as mRNA translation inhibition, UV irradiation and actinomycin D treatment that downregulates protein synthesis, can trigger mitochondrial fusion in an OPA1-, Mfn1- but not Mfn2-dependent manner. This stress-induced mitochondria hyperfusion (SIMH) is dependent on the presence of stomatin-like protein 2 (SLP2). However, S3-induced fusion depends on either Mfn1 or Mfn2 and does not induce the degradation of proteins we examined, and knockdown of SLP2 did not affect the mitochondrial fusion induced by S3 (Supplementary information, Figure S8). These results indicate that S3-induced mitochondrial fusion is different from SIMH.
Using this novel compound as a tool, we further uncovered a novel regulatory mechanism of mitochondrial fusion through the inhibition of a mitochondria-localized deubiquitinase USP30. We found that S3, which is a “thio-Michael addition” agent, can specifically react with the cysteine residue in the catalytic domain of USP30 to inhibit its deubiquitinase activity. UPS30 physically interacts with Mfns and decreases ubiquitination of Mfn1 and Mfn2, whereas mutation of the active cysteine (C77) in the catalytic domain to serine abolishes its deubiquitinase activity, and thus the USP30-C77S mutant is unable to affect the ubiquitination of Mfns. Our data are in agreement with a previous study showing that disruption of USP30 resulted in mitochondrial elongation in an Mfn1/2-dependent manner45. Furthermore, our data suggests a novel mechanism by which this deubiquitinase regulates mitochondrial fusion. Specifically, we showed that inhibition of USP30 could lead to enhanced ubiquitination of Mfn1 or Mfn2, which promotes mitochondrial fusion. It is worth noting that S3 treatment remarkably increases the ubiquitination levels of both proteins without downregulating their protein levels, indicating that this specific ubiquitination is not related to protein degradation but to functional regulation. Ubiqutination-mediated protein-protein interactions have been demonstrated to play a key role for diverse cellular functions31. Recently, ubiquitination has been shown to regulate intermolecular interaction during mitochondrial fusion. Anton et al.52 found that the yeast homolog of human USP15, Ubp12, could modulate non-proteolytic ubiquitination and fusion activity of Fzo1 (yeast homolog of Mfns). Whether USP15 plays a similar role in mammalian cells remains unknown and merits further exploration. Nonetheless, our data indicate a previously undescribed regulatory mechanism of mitochondrial fusion, which involves USP30-regulated non-proteolytic ubiquitination of Mfns. More exploration is needed to further elucidate the comprehensive molecular mechanism of mitochondrial fusion regulated by non-degradative ubiquitination in mammalian cells.
Our results show that S3 can effectively trigger mitochondrial fusion to restore mitochondrial functions. It has been shown that a significant portion of individual mitochondria exhibited a loss of mtDNA and membrane potential in Mfns- or OPA1-deficient cells10,42,53. S3 can restore the normal distribution of mtDNA and recover the Δψm. Thus, S3 increases the ATP level and OXPHOS capacity within the rebuilt mitochondrial network. The restoration of mitochondrial function and mtDNA abundance is important as abnormality of mitochondrial fusion is closely linked with their pathophysiologic functions; for example, mutations in Mfn2 or OPA1 are known to cause severe neurodegenerative diseases14,15. Thus, S3 has therapeutic implications for treatment of these non-curable diseases related to defects in mitochondrial dynamics.
Materials and Methods
Cell culture and transfection
HeLa cells, WT, Mfn1−/−, Mfn2−/−, Mfn Dko and OPA1−/− MEF cells were cultured in complete Dulbecco's minimum essential medium supplemented with 10% heat inactivated fetal calf serum, 100 U/ml penicillin and 100 μg/ml streptomycin in 5% CO2 at 37 °C. Transfections were performed using Lipofectamine 2000 (Invitrogen) according to the manufacturers instructions.
Chemicals and antibodies
The following antibodies were used: anti-Mfn1 and anti-Mfn2 monoclonal antibody (Abnova); anti-cytochrome c antibody (BD Biosciences); anti-ubiquitin (P4D1) and anti-c-Myc monoclonal antibody (Santa Cruz); anti-USP30 polyclonal antibody (AVIVA); and anti-DNA monoclonal antibody (Millipore).
MitoTracker Red was purchased from Invitrogen. All other reagents were from Sigma (St. Louis, MO, USA) unless otherwise stated.
Vectors
A cDNA encoding mouse USP30 was obtained from a mouse skeletal muscle library by polymerase chain reaction amplification and then inserted into the Kpnl-Xhol sites of pCDNA4/TO/Myc-His (Invitrogen) to generate a USP30-Myc plasmid. USP30-MBP was constructed by cloning the cDNA fragment encoding residues 57-517 of USP30 into the BamHI and HindIII site of pMAL-c2X (New England Biolabs), respectively. The pSilencer2.1-U6 Puro-USP30 RNAi was a kind gift from Shigehisa Hirose (Tokyo Institute of Technology, Japan). The Mito-PAGFP plasmid was a kind gift from Jean-Claude Martinou (University of Geneva, Switzerland).
Quantification of mitochondrial morphology
To visualize the mitochondrial network with MitoTracker Red staining, cells grown on coverslips were incubated in a growth medium supplemented with 50 nM MitoTracker Red for 20 min, washed in fresh warm medium and fixed with 4% methyl aldehyde solution for 15 min. The coverslips were washed three times with PBS and visualized using an LSM510 meta confocal microscope (Zeiss, Germany). Cells displaying a highly interconnected, tubular mitochondrial network (> 50% of the mitochondria in the whole cell population) were counted.
Immunocytochemistry and transfection
For immunocytochemistry, MEF cells were grown on collagen-coated slides and transfected with pCDNA4/TO-USP30-Myc or USP30-C77S-Myc. Cells were transfected using Lipofectamine 2000 according to the manufacturers instructions. Twenty four hour after transfection, cells were treated with 2 μM S3 for another 24 h. After staining with Mitotracker Red, cells were washed with PBS, fixed with 4% (wt/vol) PFA in PBS for 15 min and permeabilized with 0.2% (vol/vol) Triton X-100 for 10 min. After washing with PBS, cells were labeled at 4 °C overnight with a c-Myc antibody. The next day, cells were washed with PBS and labeled with a combination of FITC-conjugated anti-mouse secondary antibodies (Dianova, Germany). Cell nuclei were stained with the fluorescent chromatin dye Hoechst 33342 (Molecular Probes, USA).
Electron microscopy
S3-treated or untreated cells were fixed for 2 h at room temperature (RT) in a culture medium supplemented with 2.5% glutaraldehyde. After washing in 100 mM phosphate buffer (KH2/Na2HPO4, pH 7.4), cells were post-fixed for 60 min at RT in 1% osmium tetroxide (OSO4). After washing in phosphate buffer, cells were dehydrated in 50, 70, 80, 90 and 100% ethanol (for 8 min for each procedure). The samples were then infiltrated sequentially in 1:1 (vol/vol) ethanol:Spurr resin (Polyscience), 1:3 ethanol:Spurr resin for 30 min for each procedure, 100% Spurr resin for 3 h and finally 100% Spurr resin for 24 h at 60 °C for polymerization. Ultra-thin sections were isolated on nickel grids and stained for 10 min in 2% uranyl acetate and for 5 min in Reynold's lead citrate, and examined at 60 kV using a Philips M400 transmission electron microscope.
Immunoprecipitation
Cells were lysed in 1% (v/v) NP40 in PBS supplemented with protease inhibitors, then c-Myc, Mfn-1 or Mfn-2 antibodies were added and the mixture rotated at 4 °C for 4 h. A total of 20 μl Protein G sepaharose (Santa Cruz) was then added and the mixture rotated at 4 °C for a further 4 h. The antibody-bound beads were washed three times with PBS and then resuspended in 2× loading buffer containing 0.1 M DTT. After boiling, the supernatant was then separated by SDS-PAGE and transferred to a nitrocellulose filter membrane for western blotting.
Measurement of ATP levels
ATP levels were measured using the ATP Determination Kit (Beyotime Institute of Biotechonology) according to the manufacturers protocol.
Analysis of protein expression
Briefly, cells were washed and lysed in a lysis buffer containing 150 mMNaCl, 25 mM HEPES pH 7.4, 1% NP40, 0.25% sodium deoxycholate, 1 mM EGTA, 1 mM DTT, with protease inhibitors. Proteins from total cell lysates were resolved on SDS-PAGE and transferred to a nitrocellulose membrane. The membranes were blocked with 5% non-fat dry milk and 0.1% Tween-20 for 2 h at RT and incubated with the indicated antibodies at 4 °C overnight. Immune complexes were detected with a HRP-conjugated secondary antibody and visualized by ECL (Pierce).
Biotin-S3 pull-down assay
Cells were washed and lysed in a lysis buffer on ice for 30 min. After centrifugation, the supernatant was incubated with 0.5 mM Biotin-S3 or Biotin at RT for 30 min, and then precipitated with ice-cold acetone to remove excess Biotin-S3. The air-dried pellet was dissolved in a 150 μl denaturing buffer (25 mM HEPES pH 7.7, 2 mM EDTA, 2.5% SDS). Two volumes of binding buffer (25 mM HEPES pH 7.7, 2 mM EDTA, 1% Triton X-100, 150 mM NaCl) with 50 μl streptavidin-agarose beads (Pierce) was added and incubated for 3 h at RT. The resin was washed five times with a washing buffer (25 mM HEPES pH 7.7, 2 mM EDTA, 0.5% Triton X-100, 600 mM NaCl), boiled in SDS-PAGE loading buffer for 5 min, and subjected to western blot analysis.
Protein purification
The BL21(DE3) bacteria harboring expression plasmid of the N-terminal MBP-tagged USP30 was cultured in LB containing 20 μg/ml ampicillin. Isopropyl thiogalactoside (0.3 mM) was added and the cells were cultured for another 12 h at 18 °C. The bacterial cells were recovered and subjected to sonification in a lysis buffer (0.1% Triton X-100 in PBS and protease inhibitors). The lysate was centrifuged at 10 000 g for 30 min and the supernatant was incubated with Amylose Resin (New England Biolabs) for 2 h at RT. The resin was washed with PBS until excess proteins were completely removed. The USP30-MBP was eluted with 10 mM maltose in PBS. In total, 200 μg of USP30-MBP was cleaved by 5 μl Factor Xa at 4 °C for 24 h and the cleaved USP30 were used to detect deubiquitinase activity in vitro.
Statistical analysis
In quantitative analyses using cultured cells represented as histograms, values were obtained from three independent experiments and expressed as mean ± SD. Statistical analysis was performed using the Student's t test, with P-values < 0.05 considered significant. *P < 0.05 and **P < 0.01 versus the corresponding controls are indicated in the figures. All statistical data were calculated with the GraphPad Prism software.
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Acknowledgements
We thank David C Chan (California Institute of Technology, USA) for generously providing us with the Mfn1−/−, Mfn2−/− and OPA1−/− cells and Mfn Dko cells. We thank Mark Bartlam (Nankai University, China) and Aiming Zhou (Cleveland State University Cleveland, USA) for their help on the writing. Research in Chen's laboratory was supported by the Natural Science Foundation of China (NSFC; 91213304 and 81130045), the Ministry of Sciences and Technology (2011CB910903 and 2010CB912204) and the NSFC-joint foundation of Yunnan Province (U1032603).
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( Supplementary information is linked to the online version of the paper on the Cell Research website.)
Supplementary information
Supplementary information, Figure S1
The effect of S3 on cell viability. (PDF 221 kb)
Supplementary information, Figure S2
Functional Mfn1 or Mfn2 is required for S3-induced mitochondrial fusion. (PDF 120 kb)
Supplementary information, Figure S3
Quantification of mtDNA in Mfn1−/− and Mfn2−/− MEFs after S3 treating. (PDF 78 kb)
Supplementary information, Figure S4
S3-induced mitochondrial elongation does not occur through inhibition of Drp1. (PDF 129 kb)
Supplementary information, Figure S5
Synthesis of Biotin-labeled S3. (PDF 50 kb)
Supplementary information, Figure S6
S3 inhibited Deubiquitinase activity of USP30. (PDF 102 kb)
Supplementary information, Figure S7
Knock down of USP30 resembles the effects of S3 on mitochondrial function. (PDF 130 kb)
Supplementary information, Figure S8
S3-induced mitochondrial fusion is not dependent on SLP2. (PDF 99 kb)
Supplementary information, Data S1
Materials and Mathods (PDF 32 kb)
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Yue, W., Chen, Z., Liu, H. et al. A small natural molecule promotes mitochondrial fusion through inhibition of the deubiquitinase USP30. Cell Res 24, 482–496 (2014). https://doi.org/10.1038/cr.2014.20
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DOI: https://doi.org/10.1038/cr.2014.20
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