Abstract
Deficiency of the protein Wolfram syndrome 1 (WFS1) is associated with multiple neurological and psychiatric abnormalities similar to those observed in pathologies showing alterations in mitochondrial dynamics. The aim of this study was to examine the hypothesis that WFS1 deficiency affects neuronal function via mitochondrial abnormalities. We show that down-regulation of WFS1 in neurons leads to dramatic changes in mitochondrial dynamics (inhibited mitochondrial fusion, altered mitochondrial trafficking, and augmented mitophagy), delaying neuronal development. WFS1 deficiency induces endoplasmic reticulum (ER) stress, leading to inositol 1,4,5-trisphosphate receptor (IP3R) dysfunction and disturbed cytosolic Ca2+ homeostasis, which, in turn, alters mitochondrial dynamics. Importantly, ER stress, impaired Ca2+ homeostasis, altered mitochondrial dynamics, and delayed neuronal development are causatively related events because interventions at all these levels improved the downstream processes. Our data shed light on the mechanisms of neuronal abnormalities in Wolfram syndrome and point out potential therapeutic targets. This work may have broader implications for understanding the role of mitochondrial dynamics in neuropsychiatric diseases.
Deficiency of the protein Wolframin in Wolfram syndrome triggers a stress cascade in the endoplasmic reticulum; this leads to altered calcium homeostasis, which in turn impairs mitochondrial dynamics and consequently inhibits neuronal development.
Author Summary
Wolfram syndrome (WS) is a genetic disorder characterized by diabetes insipidus, diabetes mellitus, optic atrophy, deafness, and brain atrophy. Brain abnormalities occur at the earliest stage of clinical symptoms, suggesting that Wolfram syndrome has a pronounced impact on early brain development. The majority of Wolfram syndrome cases are caused by mutations in the gene Wolfram syndrome 1 (WFS1), which encodes for a protein localized to the endoplasmic reticulum (ER) membrane. However, the clinical symptoms of WS resemble mitochondrial disease symptoms, suggesting strong mitochondrial involvement.
In this manuscript, we demonstrate that deficiency of the gene WFS1 triggers an ER-stress cascade, which impairs the function of the IP3-receptor calcium channel, leading to altered calcium homeostasis. The latter leads to dysregulation of mitochondrial dynamics, as characterized by augmented mitophagy—a selective degradation of mitochondria—and inhibited mitochondrial trafficking and fusion, which results in lower levels of ATP and, thus, inhibits neuronal development. These results shed new light onto the mechanisms of neuronal abnormalities in Wolfram syndrome and point out potentially new therapeutic targets. Moreover, our results unravel two rather unexpected links that have an impact beyond the relatively rare Wolfram syndrome. First, relatively mild stress of the ER can seriously disturb mitochondrial dynamics, explaining why alterations at the level of the ER could lead to a mitochondrial phenotype. Second, increased levels of mitophagy, leading to excessive and unwanted mitochondrial clearance, are harmful for neurons. Furthermore, since alterations in the gene WFS1 take place in different neurologic and psychiatric disorders, our work may also have broad implications for understanding the role of mitochondrial dynamics in neuropsychiatric diseases.
Introduction
Wolfram syndrome (WS) is a genetic disorder characterized by diabetes insipidus, diabetes mellitus, optical atrophy, and deafness (DIDMOAD) and brain atrophy that results in death in middle adulthood, typically due to brainstem atrophy-induced respiratory failure [1]. About 60% of patients with WS develop a neurological or psychiatric disorder, including psychosis, episodes of severe depression, and impulsive and aggressive behaviour. Importantly, brain abnormalities occur at the earliest stage of clinical symptoms, suggesting that WS has a pronounced impact on early brain development [2]. The majority of WS cases are related to mutations in the gene Wolfram syndrome 1 (wolframin, WFS1), which encodes a protein localized in the endoplasmic reticulum (ER) membrane. A number of studies have pointed out the involvement of WFS1 in Ca2+ homeostasis and ER stress regulation [3–5]. It has been suggested that the ER stress plays a causative role in WS.
At the same time, the clinical symptoms of WS resemble mitochondrial disease symptoms, such as deafness, optic atrophy, and psychiatric disorders. Moreover, the affected tissues and organs in WS have a high metabolic demand, and most of the clinical manifestations of WS are consistent with an energy metabolism defect. Therefore, another hypothesis has been forwarded that WS is caused by mitochondrial dysfunction [6,7]. This hypothesis is indirectly supported by more recent findings that another causative gene, CISD2, identified in patients with type 2 WS, is associated with mitochondrial abnormalities and activation of mitophagy [8,9].
Importantly, these hypotheses are not mutually exclusive, because ER stress is also capable of impairing mitochondrial function [10]. This rationale further supports the idea that mitochondrial disorders are involved in the pathogenesis of WS.
In the present work, using primary neuronal cultures, we show that WFS1 downregulation leads to marked impairment of mitochondrial dynamics, which, in turn, inhibits neuronal development. We demonstrate that WFS1 deficiency triggers an ER stress associated with inositol 1,4,5-trisphosphate receptor (IP3R) dysfunction, leading to altered cell calcium homeostasis. The latter, in turn, is involved in the dysregulation of mitochondrial dynamics (mitophagy and fusion-fission cycle) in neurons. These results shed new light on the mechanisms of neuronal abnormalities in WS and point out potentially new therapeutic targets.
Results
WFS1 Deficiency Impairs Mitochondrial Dynamics
Mitochondrial fusion and fission dynamics were measured using photoconvertible mitochondrially targeted Kikume Green-Red, which enables the quantification of fusion events between green- and red-emitting mitochondria (S1 Video, Fig 1A). There was a significant, 3-fold decrease in the number of fusion events in Wfs1 shRNA-treated neurons (efficiency of Wfs1 shRNA is demonstrated in S1 Fig) compared with scrambled shRNA-treated controls (from 0.029 ± 0.001 to 0.010 ± 0.001 fusion/mito/min, respectively, n = 80 neurons, p < 0.0001; see also Fig 1B, which shows a representative experiment). Also, the mitochondrial fission rate was decreased in Wfs1 shRNA-treated neurons (from 0.027 ± 0.001 to 0.010 ± 0.001 fission/mito/min, n = 80 neurons, p < 0.0001), suggesting that WFS1 deficiency greatly prolongs the fusion–fission cycle. These changes in the fusion–fission cycle were associated with a 20% decrease in mitochondrial length (Fig 1C). Overexpression of human shRNA-insensitive wild-type (wt) WFS1 but not P724L mutant (which occurs in WS) restored the mitochondrial fusion dynamics and length in the Wfs1 shRNA-treated group (Fig 1B and 1C). The inhibition of mitochondrial fusion was also observed in cerebellar granule neurons in which the fusion rate decreased from 0.036 ± 0.006 fusion/mito/min in control to 0.008 ± 0.003 fusion/mito/min in WFS1-deficient neurons (n = 16 neurons, p = 0.001).
We also quantified mitochondrial fusion and fission dynamics in neurons isolated from Wfs1-/- and Wfs1+/+ mice. Of significance, a 2.5-fold decrease in the number of fusion events in neurons from Wfs1-/- compared with those from Wfs1+/+ mice was observed (Fig 1D). Again, this decrease was associated with an approximate 25% decrease in mitochondrial length (Fig 1E). Moreover, Wfs1 shRNA suppression of fusion rate and induction of mitochondrial shortening in Wfs1+/+ neurons had no effect in Wfs1-/- neurons, thus showing its specificity. In contrast, overexpression of shRNA-insensitive WFS1 restored the mitochondrial fusion dynamics and length in Wfs1-/- neurons while having relatively little effect in Wfs1+/+ neurons (Fig 1D and 1E). No difference, however, was observed between Wfs1-/- and Wfs1+/+ brains in mRNA expression of the main fusion and fission proteins (S2 Fig).
To measure mitophagy, we expressed the mitochondrially targeted pH-dependent protein Keima, the excitation spectrum of which shifts (green to red in Fig 1F) when mitochondria are delivered to acidic lysosomes. The number of autolysosomes containing mitochondria was increased both in wt neurons transfected with Wfs1 shRNA and in neurons isolated from Wfs1-deficient animals (Fig 1G and 1H). Also, the number of mitochondria-containing autophagosomes (LC3-positive dots co-localizing with a mitochondrial marker; S3 Fig) was significantly increased in neuronal bodies of Wfs1 shRNA-treated neurons (13.8 ± 1.1 versus 8.8 ± 0.8 in scrambled shRNA-transfected neurons, p = 0.0004, n = 50 neurons). Overexpression of human shRNA-insensitive wt WFS1 in the Wfs1 shRNA-treated group reduced the mitophagy close to control level (Fig 1G). Note that Wfs1 silencing enhances LC3-I conversion to LC3-II (S4 Fig), suggesting increased autophagy.
Together, the LC3 and Keima assays demonstrate that WFS1 deficiency increases mitochondrial removal (mitophagic flux) rather than inhibiting the formation of autolysosomes containing mitochondria. Importantly, WFS1-deficient neurons showed fewer mitochondria in axons. Analysis of mitochondrial density in neurites revealed an approximate 30% decrease in mitochondrial mass both for Wfs1 shRNA-treated neurons and for neurons isolated from Wfs1-/- mice (Fig 1I–1K). This effect was phenocopied by Wfs1 shRNA in Wfs1+/+ neurons and rescued by wt WFS1 overexpression in Wfs1-/- neurons.
Mitochondrial trafficking was also disturbed in WFS1-deficient neurons. Mitochondria in these neurons showed a decrease in velocity in both antero- and retrograde motion (Table 1, S5 Fig). Mitochondria from WFS1-deficient neurons also changed their direction during motion more often and made more individual runs, whereas the length of these runs was shorter. These data explain the oscillatory-like movement we frequently observed in WFS1-deficient neurons (S2 and S3 Videos). We also measured the contact rate of mitochondria as an indirect parameter of mitochondrial movement. This parameter was also significantly reduced in neurons isolated from Wfs1-deficient mice and restored by WFS1 overexpression (S6 Fig).
Table 1. Parameters of mitochondrial trafficking in neurons transfected with scrambled shRNA or Wfs1 shRNA.
Motility parameter | Scrambled shRNA | Wfs1 shRNA | P-value |
---|---|---|---|
Fraction of time in motion | 0.39 ± 0.01 (0.31) | 0.40 ± 0.01 (0.33) | 0.3932 |
Velocity when in motion (μm/s) | 1.41 ± 0.09 (0.65) | 1.14 ± 0.12 (0.59) | 0.0047 |
Velocity when in anterograde motion (μm/s) | 1.18 ± 0.08 (0.64) | 0.95 ± 0.10 (0.60) | 0.0107 |
Velocity when in retrograde motion (μm/s) | 1.11 ± 0.08 (0.60) | 0.95 ± 0.09 (0.56) | 0.0358 |
Change of direction during motion (turn/min) | 0.37 ± 0.02 (0.20) | 0.62 ± 0.04 (0.42) | 0.0001 |
Average length of anterograde run (μm) | 4.10 ± 0.66 (0.71) | 2.64 ± 0.75 (0.71) | 0.0422 |
Average length of retrograde run (μm) | 3.22 ± 0.55 (0.71) | 2.68 ± 0.62 (0.71) | 0.1439 |
Number of anterograde runs (run/min) | 0.71 ± 0.02 (0.67) | 0.83 ± 0.03 (0.80) | 0.0001 |
Number of retrograde runs (run/min) | 0.70 ± 0.03 (0.62) | 0.81 ± 0.03 (0.81) | 0.0015 |
Data are presented as the mean ± SEM (median is shown in brackets, n = 383 for scrambled shRNA and n = 327 for Wfs1 shRNA, Mann-Whitney test).
WFS1 Deficiency Is Associated with Decreased Mitochondrial Membrane Potential and Cellular ATP
We performed a quantitative analysis of mitochondrial membrane potential using the ratiometric mitochondrial membrane potential-sensitive fluorescent probe JC-10 (emitting light from 525 nm to 590 nm depending on mitochondrial membrane potential). Neurons were first transfected with Wfs1 siRNA using the N-TER nanoparticle siRNA transfection system to ensure >70% transfection efficiency. The results obtained demonstrated a 10% decrease in red to green fluorescence ratio, suggesting a slight depolarisation in the Wfs1 siRNA group (Figs 2A and S7). Interestingly, an increased number of polarised, tetramethylrhodamine ethyl ester (TMRE)-positive mitochondria were observed inside autophagosomes in WFS1-deficient neurons (S8 Fig); this suggests that WFS1 deficiency may induce mitophagy of active, polarised mitochondria. We also performed indirect reactive oxygen species (ROS) measurements using an NRF2 reporter gene assay, which showed no difference between the scrambled and Wfs1 shRNA-transfected neurons (Fig 2B).
Next, we estimated cell ATP levels using the fluorescence resonance energy transfer (FRET)-based ATP sensor ATeam, which employs the epsilon subunit of a bacterial F0F1-ATPase. Control experiments with deoxyglucose/oligomycin or glutamate reduced neuronal ATP levels and demonstrated the expected decline in FRET signal, showing the validity of our approach (Fig 2C). The results obtained (Fig 2D) show that the cellular ATP level is reduced in WFS1-deficient neurons.
Impairment of Mitochondrial Dynamics Is Linked to WFS1 Deficiency-Induced Mild ER Stress
It has been previously demonstrated that WFS1 deficiency leads to ER stress in different rodent and human cell lines [5], WFS1-deficient β-cells [11], and WFS1-deficient mouse retinas [12]. We checked whether the suppression of WFS1 in neurons also induced ER stress. Using reporter constructs for ATF6, IRE1-XBP1, and PERK-ATF4 pathways, we demonstrate (Fig 3A) that WFS1 suppression activates luciferase reporter constructs with a promoter containing ATF6 and ATF4 binding sites, but not the XBP1 splicing reporter. This WFS1 deficiency-induced activation, however, was weak when compared with that induced by overexpression of ATF6, ATF4, and IRE1 (Fig 3B).
To test whether the effect of WFS1 deficiency on mitochondrial dynamics is associated with ER stress, we mitigated ER stress by overexpressing the ER chaperon HSPA5. Fig 3C and 3D demonstrate that wt HSPA5 and its ATPase-deficient mutant (T37G), but not its protein binding-defective mutant (P495L), restore the Wfs1 shRNA-suppressed fusion rate. Also, wt HSPA5 partially suppressed WFS1 deficiency-induced mitophagy (Fig 3E).
Importantly, activation of major ER stress-response pathways by overexpressing ATF6, ATF4, or IRE1 neither inhibited mitochondrial fusion nor induced mitochondrial shortening or mitophagy (Fig 3F–3H). Furthermore, ATF4 and ATF6 shRNAs were not able to restore mitochondrial fusion rate or decrease mitophagy in WFS1-deficient neurons (Fig 3I–3L). These data suggest that although WFS1 deficiency-induced mild ER stress is followed by disturbed mitochondrial dynamics, the latter is not mediated by these major ER stress-response pathways.
IP3R-Controlled Calcium Homeostasis Is Impaired in WFS1-Deficient Neurons
An earlier report demonstrated that ER stress-impaired IP3R-mediated Ca2+ release from the ER [13]. It is noteworthy to mention that IP3R rather than ryanodine receptors are primarily responsible for Ca2+ release in cortical neurons (S9A Fig). To test whether IP3R-mediated Ca2+ homeostasis is impaired in WFS1-deficient neurons, we loaded neurons with both the Ca2+ sensor Fluo-4 and a membrane-permeant caged derivative of IP3. IP3 uncaging-induced Ca2+ release from the ER to cytosol was notably decreased in WFS1-deficient neurons (Fig 4A). Similarly, the selective group I metabotropic glutamate receptor agonist dihydroxyphenylglycine (DHPG), which stimulates phospholipase C and promotes endogenous IP3 formation, induced diminished cytosolic Ca2+ transients in WFS1-deficient neurons (Fig 4B). No difference was observed in basal ER [Ca2+] (S10 Fig) or in maximal ER Ca2+ uptake capacity (S9B Fig), suggesting that the decreased IP3-dependent Ca2+ release was not due to reduced ER Ca2+ levels. Also, no difference was observed in the cytosolic Ca2+ transients elicited by an inhibitor of endoplasmic reticulum Ca2+ ATPase, 30 μM cyclopiazonic acid (CPA), suggesting that there is no difference in releasable ER Ca2+ between control and Wfs1 silenced neurons (S9C and S10D Figs).
It has been proposed that the IP3 receptor is involved in Ca2+-induced Ca2+ release from the ER (for review, see [14]). Thus, it is reasonable to suggest that impaired IP3R function would affect Ca2+ release from the ER during neuronal depolarisation. Indeed, by following changes in cytosolic Fluo-4 fluorescence, we observed that cytosolic Ca2+ transients in neurons in response to glutamate or KCl were up to 2-fold lower in WFS1-deficient neurons when compared with control groups (Fig 4C and 4D).
We next tested whether decreased IP3-dependent Ca2+ release is associated with altered basal cytosolic [Ca2+] levels. We used a FRET-based Ca2+ sensor to enable measurement of cytosolic [Ca2+] before and after KCl treatment. The data obtained demonstrated increased basal [Ca2+] in WFS1-deficient neurons, whereas stimulation led to lower maximal [Ca2+] (Fig 4E–4G). Accordingly, the amplitude of Ca2+ transient was significantly decreased (Fig 4H). Similarly, a decrease was observed when aequorin-emitted bioluminescence was used to quantify the maximal [Ca2+] after stimulation (Fig 4I). Furthermore, pre-treatment with Araguspongin B, an inhibitor of IP3-dependent Ca2+ release, suppressed KCl-induced cytosolic Ca2+ transients in wt neurons (Fig 5A), whereas overexpression of the active fragment of IP3R restored the cytosolic Ca2+ transients in WFS1-deficient neurons (Fig 5D).
These findings suggest that WFS1 deficiency induces lower IP3R-mediated Ca2+ release.
Disturbed Calcium Homeostasis Is Responsible for Impaired Mitochondrial Dynamics in WFS1-Deficient Neurons
Next, we checked whether the disturbed cytosolic Ca2+ homeostasis could be responsible for the impaired mitochondrial dynamics observed in WFS1-deficient neurons. Indeed, IP3R inhibition by Araguspongin B suppressed the mitochondrial fusion rate and initiated mitophagy in wt neurons (Fig 5B and 5C). In contrast, overexpression of the active fragment of IP3R corrected the WFS1 deficiency-induced changes in mitochondrial dynamics (Fig 5E and 5F). The latter suggests a direct link between IP3R-mediated ER calcium release and mitochondrial dynamics.
Furthermore, treatment of WFS1-deficient neurons with the L-type Ca2+ channel activator, Bay K 8644, restored cytosolic Ca2+ transients (Fig 5G), restored the fusion rate, and inhibited mitophagy (Fig 5H and 5I). A similar rescue was obtained by overexpressing plasma membrane ORAI calcium release-activated calcium modulator 1 (ORAI1), which also corrected cytosolic Ca2+ transients, restored the fusion rate, and suppressed mitophagy in WFS1-deficient neurons (Fig 5J–5L). These experiments suggest that disturbed cytosolic Ca2+ homeostasis, rather than ER Ca2+ specifically, or direct ER-mitochondria Ca2+ channelling, is responsible for impaired mitochondrial dynamics in WFS1-deficient neurons.
WFS1 Deficiency Delays Neuronal Development and Impairs Neuronal Survival
Because WS has been shown to be associated with both neurodegeneration and impaired early brain development [2], we further aimed to test whether the alterations in Ca2+ homeostasis and mitochondrial dynamics affect neuronal development or/and survival. WFS1 deficiency delayed the development of cortical neurons markedly (Fig 6A and 6B; see S1 Table for original data). The longest axon and the axonal tree were significantly shorter, and the number of axonal tips was lower in developing DIV2-DIV4 Wfs1 shRNA-transfected neurons (Fig 6C–6F). However, in relatively mature neurons, at DIV6, the axonal length and branching was similar to control. Fig 6G demonstrates that the survival of WFS1-deficient neurons is also impaired; transfection of Wfs1 shRNA led to relatively slight but significant loss of neurons. Interestingly, WFS1 suppression decreased significantly the density of synapses when measured at DIV19 but not at earlier stages (Fig 6H and 6I). To examine whether the compromised development and survival we observed in vitro have relevance in vivo, we further conducted ex vivo magnetic resonance imaging of the brains of 1-y-old Wfs1-deficient male mice. Volumetric analysis did not demonstrate a significant change in total cerebral volume, but there was a marked reduction of the optic nerve and brain stem volumes in Wfs1 deficient mice (Fig 7A–7G). A slight decrease was also observed in cortical area at the level of striatum (Fig 7H). Thus, these results suggest that WFS1 is indispensable for appropriate neuronal development, morphology, and survival both in vitro and in vivo.
Correction of IP3R Function and Mitophagy Rescues Developmental Delay in WFS1 Deficiency
We next tested the possibility that delayed neuronal development in WFS1 deficiency is a consequence of IP3R dysfunction and/or impaired mitochondrial dynamics. If this hypothesis is correct, it could open the possibility of improving neuronal development by restoring cytosolic Ca2+ homeostasis or mitochondrial dynamics. Indeed, overexpression of IP3R improved Ca2+ homeostasis, protected against WFS1 deficiency-induced developmental delay and also partially restored axonal growth (Fig 8A–8C). Importantly, this overexpression did not suppress ER stress (S11 Fig), thus suggesting that IP3R-mediated Ca2+ disturbances rather than ER stress per se are responsible for the neuronal development delay. Furthermore, overexpression of ORAI1 normalized cytosolic Ca2+ homeostasis and also protected neurons against the development delay (S12 Fig).
Finally, we tested whether specific suppression of mitophagy in WFS1 deficiency by co-expression of Wfs1 shRNA with Pink1 or Parkin shRNAs could rescue the neuronal development. Both shRNAs suppressed effectively the WFS1 deficiency-induced mitophagy and restored mitochondrial density (Fig 8D, 8H, 8E and 8I), demonstrating that WFS1 deficiency activates selective Pink1-Parkin-dependent mitophagy. The latter suggestion is supported by the finding that Parkin translocation to mitochondria was higher in Wfs1 shRNA-expressing PC6 cells, PC12 cells (S13 Fig), and in neurons (S14 Fig). Moreover, Pink1 and Parkin shRNAs restored the fusion rate and contact rate (an indirect parameter for mitochondrial movement; Fig 8F, 8J, 8G and 8K), suggesting the relevance of mitophagy in these processes. Most importantly, suppression of mitophagy by expressing Pink1 or Parkin shRNAs accelerated development and restored the axonal growth in WFS1-deficient neurons (Fig 8L–8Q). At the same time, Parkin and Pink1 shRNAs neither suppressed WFS1 deficiency-induced ER stress nor restored Ca2+ transients (S15 Fig), suggesting that the impairment of mitochondrial dynamics is a downstream event relative to the Ca2+ homeostasis disturbances and that overactivated mitophagy is the primary reason for delayed neuronal development in WFS1-deficient neurons.
We also tested whether the inhibition of mitochondrial fission proteins could protect mitochondria in WFS1-deficient neurons and rescue the neurons from the developmental delay. Treatment with negative dominant DRP1 (nd DRP1) reversed the negative effects of WFS1 deficiency on fusion and density loss and restored normal development (S16A–S16C Fig). nd DRP1 also protected against the inhibition of mitochondrial fusion induced by the ER stressor Brefeldin A (S16D Fig). Brefeldin A itself showed too strong a negative effect on neuronal survival, making it impossible to estimate neuronal development.
Discussion
Our results uncover a chain of causal links relating ER stress, cytosolic Ca2+ disturbances, impaired mitochondrial dynamics, and delayed neuronal development in WFS1-deficient neurons. We demonstrate that WFS1 deficiency induces ER stress in neurons (as has already been shown in other cell types [5,15]), affecting the IP3R receptor. This was associated with higher cytosolic Ca2+ at resting conditions (which is consistent with previously reported elevated basal cytosolic [Ca2+] in Wfs1 deficient iPS cells [16]) but lower maximal [Ca2+] under stimulated conditions, suggesting reduced amplitude of IP3R-mediated Ca2+ release in WFS1-deficient neurons. We show that the amplitude of IP3R-mediated Ca2+ release induced by photolysis of caged IP3 or by activating endogenous IP3 production by the metabotropic glutamate receptor agonist DHPG was significantly lower in WFS1-deficient neurons. The exact mechanism of this WFS1-dependent IP3R dysfunction is not clear; however, it has been previously shown that ER stress induced IP3R inhibition by impairing the IP3R-HSPA5 interaction [13].
We further demonstrate that altered Ca2+ homeostasis disturbs mitochondrial dynamics. Mitochondria in WFS1-deficient neurons do not move properly, they do not fuse and split apart as frequently as their wt counterparts, and they undergo mitophagy more frequently. Overexpression of the active IP3R fragment restores IP3R-mediated Ca2+ release and corrects all perturbations in mitochondrial dynamics, suggesting that these events are causally linked. Pharmacological inhibition of IP3R by Araguspongin B phenocopied the effects of WFS1 deficiency, confirming the connection between reduced ER Ca2+ release and impaired mitochondrial dynamics. Importantly, we were able to correct mitochondrial dynamics by activating store-operated calcium entry or by activating L-type Ca2+ channels pharmacologically, linking the lower ER Ca2+ release with impaired mitochondrial dynamics. Potentially, there are several ways how ER Ca2+ release could influence mitochondrial dynamics. Lowered levels of ER Ca2+ release could directly activate/deactivate mitochondrial and/or cytoskeleton proteins involved in mitochondrial dynamics. One may suggest that Ca2+ affects activity or expression of these proteins through the calcium/calmodulin (CaM) kinase signalling cascade, which may not be sufficiently activated in WFS1 deficiency. This question deserves specific further study.
We also demonstrate that the mechanism linking WFS1 deficiency-related ER stress with impaired mitochondrial dynamics involves two Parkinson’s disease-related proteins, PINK1 and Parkin. Both Pink1 and Parkin shRNAs supressed WFS1 deficiency-induced mitophagy back to control levels. These data suggest that WFS1 deficiency may activate the PINK1 and Parkin pathway (supported by our finding demonstrating increased Parkin translocation to mitochondria under basal conditions), which has been shown to inhibit mitochondrial movement [17] and fusion-fission dynamics [18–20] and induce mitophagy [21–24]. Importantly, Pink1 and Parkin shRNAs also restored mitochondrial fusion–fission dynamics and trafficking, suggesting activation of PINK1-Parkin pathway to be the primary event leading to impaired trafficking and fusion rate as well as to mitophagy. The result that PINK1 or Parkin silencing (which improves mitochondrial dynamics in WFS1 deficient neurons) does not correct ER stress Ca2+ responses in WFS1 deficiency suggests that regulation of mitochondrial dynamics by the PINK1-Parkin pathway is downstream to cytosolic Ca2+ homeostasis.
In principle, there are two potential explanations for how PINK1-Parkin pathway could be involved. First, mitochondrial depolarization could lead to PINK1 accumulation in the mitochondrial outer membrane and Parkin translocation to mitochondria, inhibiting mitochondrial fusion and trafficking and inducing mitophagy. This explanation could be supported by our finding that mitochondria in WFS1-deficient neurons were slightly depolarised. Another explanation would be that overactivation of the PINK1-Parkin pathway occurs independently of mitochondrial membrane potential, leading to the removal of healthy and polarised mitochondria. We earlier observed a similar phenomenon in mutant alpha-synuclein expressing neurons where PINK1-Parkin-dependent mitophagy started to eliminate polarised mitochondria [25]. It cannot be excluded that both of these explanations are also valid for WFS1-deficient neurons. Slight mitochondrial depolarisation may increase the rate of mitochondrial removal, and PINK1-Parkin dependent mitophagy could start to eliminate functional or at least partly functional mitochondria. This excessive mitochondrial removal should then lead to decreased mitochondrial density and ATP production, both of which were observed in WFS1-deficient neurons and compromise the bioenergetic status of cells.
Compared with the majority of other cell types, in which mitochondrial turnover is high, mitochondrial turnover is relatively low in neurons. It might therefore be suggested that neurons cannot afford to lose mitochondria at a high rate, as it would lead to energy deficits. Instead, it might be energetically more favourable for neurons to keep “partially defective” mitochondria than to consume them through mitophagy; in other words, “partially defective” mitochondria are the lesser evil. In contrast, under pathological conditions associated with increased levels of autophagy and mitophagy, excessive and unwanted mitochondrial clearance would lead to bioenergetic deficits harmful to neurons (in our case, an increased number of partially defective mitochondria and increased removal of these partially defective mitochondria, leading to reduced mitochondrial mass). It is likely that this event is not limited to Wfs1-deficient neurons but might also be observed in the future in other neurodegenerative conditions.
There is also some limited evidence in the literature that WFS1 is associated with Parkinson pathways. Shadrina et al. [26] demonstrated that the synonymous polymorphism C1645T in the WFS1 gene increases the risk of Parkinson's disease in Russian patients. Kõks et al. [27] demonstrated recently that WFS1 silencing in HEK cells primarily affected the expression of genes belonging to the Parkinson’s signalling ingenuity canonical pathway. Moreover, WFS1-deficient mice demonstrate impaired function of the dopaminergic system [28].
Another important discovery is that WFS1 deficiency delays neuronal development and impairs neuronal survival in primary neuronal culture. Ex vivo magnetic resonance imaging of the brains of Wfs1-/- mice also demonstrated clear atrophy and/or degeneration of the brain stem, which is the main structure atrophied in Wolfram syndrome patients and the cause of death due to respiratory failure [1]. This is also consistent with an earlier clinical study suggesting that WFS1 had a pronounced impact on early brain development [2]. Compared with healthy and type 1 diabetic control groups, a cohort of young WS patients at relatively early stages of disease showed smaller intracranial volumes and preferentially affected grey matter volume and white matter microstructural integrity. According to our data, the link between WFS1 deficiency and delayed neuronal development appears to be mediated by impaired mitochondrial dynamics, because suppression of the PINK1-Parkin pathway also corrected the development delay. Our results do not allow us to elucidate the exact mechanism by which disturbed mitochondrial dynamics delays neuronal development; however, some putative mechanisms could be proposed. Impaired mitochondrial trafficking in WFS1-deficient neurons might negatively affect the delivery of energy-producing mitochondria to the sites where energy is most needed. For example, inhibition of mitochondrial transport results in the loss of mitochondria from peripheral nerve terminals that may reduce local ATP supply and affect ATP-dependent processes. Besides, any serious disturbances in mitochondrial fusion–fission dynamics may impair the maintenance of mitochondrial function and further compromise neuronal energy requirements. Disruption of mitochondrial fusion results in mitochondrial dysfunction and loss of respiratory capacity (for review, see [29]). Finally, excessive mitophagy that decreases mitochondrial mass will also affect the capacity of total energy production in neurons. Notably, neuronal growth is associated with increased energy demand and may be slowed by energy deficits.
Our discovery that WFS1 deficiency-elicited perturbations in Ca2+ homeostasis leads to disturbed mitochondrial dynamics and impaired neuronal development may help us to understand the pathophysiology of some psychiatric disorders. Indeed, WS has been associated with psychiatric pathologies (for review, see [30]), such as severe depression, psychosis, dementia, impulsive-aggressive behaviour leading to suicide attempts, and frequent hospitalization [31]. Heterozygous carriers of mutant WFS1, who are estimated to be as high as 1% of the general population, may also be at increased risk for mood disorders. Swift et al. [32] suggested that heterozygous WS carriers are 26-fold more likely to require psychiatric hospitalization compared with non-carriers, and these heterozygotes may constitute approximately 25% of all individuals hospitalized with depression and suicide attempts. These findings were confirmed in several further papers [33–35], although some reports failed to find an association [36–38]. This discrepancy is likely related to differences in cohorts of patients and requires further investigation. However, in general, our data are consistent with a growing body of evidence suggesting that impaired mitochondrial function (including mitochondrial dynamics) may lead to a disruption of normal neural plasticity and reduced cellular resilience, which may, in turn, promote the development of mood and psychotic disorders.
In conclusion, our data suggest a causal relationship between ER stress, cytosolic Ca2+ disturbances, impaired mitochondrial dynamics, and delayed neuronal development in WFS1-deficient neurons. This mechanism sheds new light on the development of neuronal abnormalities in Wolfram syndrome and points out potential therapeutic targets. Moreover, our results unravel two rather unexpected links having impact beyond the relatively rare Wolfram syndrome. Firstly, relatively mild ER stress/impaired ER Ca2+ release could seriously disturb mitochondrial dynamics, thus providing an explanation as to why alterations at the ER level could lead to a mitochondrial phenotype. Secondly, impaired mitochondrial dynamics could affect neuronal development, suggesting that proper mitochondrial dynamics might be crucial for neurodevelopment. Since alterations in WFS1 function seem to take place in different neurological disorders [30,32], our work may also have rather broad implications for understanding the role of mitochondrial dynamics in neuropsychiatric diseases.
Methods
Plasmids and Chemicals
Plasmids expressing scrambled shRNA or shRNA against rat Wfs1 (KR46208N), rat Atf6 (KR51427H), rat Atf4 (R42749N), rat Parkin (KR50238N), and rat Pink1 (KR55105N) were from SABiosciences. shRNAs against Parkin and PINK1 have been validated by us earlier [20]. shRNAs against ATF6 and ATF4 supressed the expression of respective mRNAs by 74% and 68%. Plasmids expressing mitochondrial DsRed2 (632421) and EGFP (6085–1) were from Clontech. Mito-Keima was from Amalgaam (AM-V0251), and mito-KikGR1 was constructed as described earlier [39]. ATeam (51958), ATF6 (11975), ATF6-GL3 (11976), ATF4 (26114), ATF4-luc (21850), WFS1 wt (13011), WFS1 P724L (13012), IRE1α (13009), D1ER (36325), D3cpv (36323), DRP1 K38A, EGFP-LC3 (24920), HSPA5 wt (27164), HSPA5 T37G (27165), HSPA5 P495L (27166), NRF2 (21555), ORAI1 (21638), PSD-95 (15463), and pAAV-hSyn-DsRedExpress (22907) were obtained from Addgene (Cambridge, MA). The IP3R1 channel fragment (MmCD00312368) was from PlasmID, pRL-CMV (E2261) was from Promega Co., and mKate2-mito (FP187) was from Evrogen. XBP1ΔDBD-LUC was a kind gift from Dr. T. Iwawaki, YFP-Parkin from Dr. R. Youle, cytosolic aequorin from Dr. R. Rizzuto, DRP1 K38A from Dr. G. Szabadkai, pGL3-rNQO1 Dr. J. Alam, and PINK1 from Dr. E. Deas. DHPG (0805) and Bay K 8644 (1544) were from Tocris Bioscience, Brefeldin A (B6542) and Cyclopiazonic acid (C1530) were from Sigma-Aldrich, and Araguspongin B was from Cayman Chemical (10006797). All fluorescence dyes and culture media were from Life Technologies.
Cell Cultures
Primary rat neuronal cultures were prepared from less than 1-d-old neonatal Wistar rats as described earlier [39]. Briefly, cortices were dissected in ice-cold Krebs–Ringer solution containing 0.3% BSA and then trypsinised in 0.8% trypsin for 10 min at 37°C. The cells were then triturated in a 0.008% DNase solution containing 0.05% soybean trypsin inhibitor. Cells were resuspended in Basal Medium Eagle with Earle's salts (BME) containing 10% heat-inactivated fetal bovine serum (FBS), 25 mM KCl, 2 mM glutamine, and 100 μg/ml gentamicin, and then plated onto 35-mm glass-bottomed dishes (MatTek, MA), which were pre-coated with poly-L-lysine, at a density of 106 cells per dish in 2 ml of cell suspension. After incubating for 3 h, the medium was changed to Neurobasal-A medium containing B-27 supplement, 2 mM GlutaMAX-I, and 100 μg/ml gentamicin.
To prepare primary cultures of cerebellar granule cells, the cerebella from 8-d-old Wistar rats were dissociated by trypsinising in 0.25% trypsin at 35°C for 15 min, followed by trituration in a 0.004% DNase solution containing 0.05% soybean trypsin inhibitor. Cells were resuspended in BME containing 10% FBS, 25 mM KCl, 2 mM glutamine, and 100 μg/ml gentamicin. Neurons were plated onto 35 mm glass-bottomed dishes that were pre-coated with poly-L-lysine at a density of 1.3 × 106 cells/ml. 10 μM cytosine arabinoside was added 24 h after plating to prevent the proliferation of glial cells.
Primary cortical neurons were isolated using the same protocol from 1-d-old wt and Wfs1-deficient mice [40] obtained from mating of background-matched wt and Wfs1-deficient mice, respectively. The permissions for the animal studies were given to E. Vasar (No. 39 and 29) and D. Safiulina (No. 51) by the Estonian National Board of Animal Experiments in accordance with the European Communities Directive of 24 November 1986 (86/609/EEC).
PC12 or PC6 cells were grown in RPMI-1640 medium supplemented with 10% horse serum and 5% FBS on collagen IV-coated 100-mm plastic dishes or on 35-mm glass-bottomed dishes. All culture media and supplements were obtained from Invitrogen.
Transfection
Neurons were transfected at DIV2 (with exception of neuronal maturation and axonal growth experiments). For transfection of cells growing on glass-bottomed dishes, the conditioned medium was replaced with 100 μl Opti-MEM I medium containing 2% Lipofectamine 2000 and 1 to 2 μg of total DNA with an equal amount of each different plasmid. The dishes were incubated for 3 to 4 h, after which fresh medium was added. For biochemical analyses, the cells were transfected in 100-mm plastic dishes as described above, except that the total volume of the transfection mixture was increased with proportionally adjusted Lipofectamine 2000 and DNA. For some experiments with shRNA-expressing plasmids that also contained a neomycin resistance gene (shRNA efficiency testing and Parkin translocation), the PC12 cell medium was supplemented with 200 μg/ml G418 for 6–7 d.
Note that despite relatively low transfection efficiency in neurons, the transfected plasmids were mostly localised to the same cells. When neurons were transfected with plasmids encoding mitochondrial CFP, mitochondrial YFP, and mitochondrial mKate2, 93 ± 1% transfected cells expressed all three markers, 5 ± 1% expressed two markers, and 2 ± 0.4% expressed one marker (n = 4 dishes; 100 cells were analysed per dish; S17 Fig).
Mitochondrial Fusion Rate Analysis
For mitochondrial fusion rate analysis, cortical neuronal cultures transfected with mito-KikGR1 plasmid and plasmids of interest as described earlier [39] and examined at DIV 7–8. A laser scanning confocal microscope (LSM 510 Duo, Carl Zeiss Microscopy GmbH) equipped with a LCI Plan-Neofluar 63×/1.3 water immersion DIC M27 objective was used. The temperature was maintained at 37°C using a climate chamber. For fusion acquisition, mito-KikGR1 was illuminated with a 488-nm argon laser line to visualize the intense green mitochondrial staining. Selected mitochondria were then photoconverted to red using a 405-nm diode laser and illuminated using a 561 nm DPSS laser. The images were taken at 10-s intervals for 10 min, the fate of all activated mitochondria was followed throughout the time-lapse, and the fusion and fission events were recorded.
Mitochondrial Density and Length
For whole-cell mitochondrial density measurements, the neurons were transfected with GFP, mitochondrial pDsRed2, scrambled shRNA or shRNA, and plasmids of interest. At DIV 8, the entire axon and dendrites from randomly selected neurons were visualised using a laser scanning confocal microscope. Neurons were reconstructed using Neurolucida and LSM5 software, and mitochondrial density was analysed. Mitochondrial length measurements were performed as described previously [39].
Mitophagy Assays
Primary cortical neurons transfected with mitochondrially targeted Keima plus scrambled shRNA, and plasmids of interest were studied at DIV 7–8. The excitation spectrum of Keima shifts from 440 to 586 nm when mitochondria are delivered to acidic lysosomes, which enables quantification of mitophagy. Images were acquired by a laser scanning confocal microscope using the laser lines 458 nm (green, mitochondria at neutral pH) and 561 nm (red, mitochondria under acidic pH) at 5–6 d after transfection, and red dots were counted blindly.
In another set of experiments, neurons were transfected with pEGFP-LC3, mKate2-mito, and scrambled shRNA or Wfs1 shRNA. The co-localization of EGFP-LC3 dots and mitochondrial mKate2-mito was analysed.
Cytosolic ATP Measurement
Neurons expressing the ATP sensor ATeam and scrambled or Wfs1 shRNA were excited using a 458 nm line (10%) of Ar-laser, the CFP emission was acquired at 465–500 nm and the FRET signal at 520–570 nm. The ratio of the FRET/CFP fluorescence intensity was calculated from the signal coming from the cytosol.
Mitochondrial Membrane Potential
For membrane potential measurements, primary neurons (plated at lower density, 2.5 x 105 cells/ml) were transfected with 20 nM validated siRNA against Wfs1 (Sigma-Aldrich: SASI_Rn02_00265296 Rat NM_031823; Wfs1 siRNA suppressed 80 ± 1% of endogenous WFS1 expression in primary cortical cells as estimated by RT-PCR, n = 3) using the N-TER Nanoparticle siRNA Transfection System (Sigma-Aldrich). Briefly, a mixture of target and scrambled siRNA (20 nM) diluted in siRNA buffer and NTER transfection reagent diluted in ddH20 was preincubated at RT for 20 min. Growth medium was then removed and replaced with Opti-MEM I containing the target or scrambled siRNA mixture. After a 3-h incubation at 37°C, Opti-MEM I was changed to Neurobasal-A medium containing B-27 supplement, 2 mM GlutaMAX-I, and 100 μg/ml gentamicin. After transfection, the cells were incubated for 72–96 h in a humidified 5% CO2/95% air incubator at 37°C. The N-TER Nanoparticle siRNA Transfection System was relatively non-toxic, yielding a survival rate of 82 ± 4% (five dishes and five dishes in vehicle treated group) at 16 h after transfection (estimated with LIVE/DEAD Viability/Cytotoxicity Kit, for mammalian cells [Invitrogen]).
For JC-10 loading, siRNA-transfected dishes were kept in 10 μM JC-10 dissolved in culture media and incubated at 37°C for 20 min. After dye-loading, the cells were kept in Krebs-Ringer solution supplemented with 1mM Ca2+ and visualized using a laser scanning confocal microscope equipped with a LCI Plan-Neofluar 63×/1.3 water immersion DIC M27 objective. Dishes were then treated with 5 μM FCCP to obtain background values.
For visualizing mitochondria with preserved membrane potential in autophagosomes, the neurons were transfected with LC3-EGFP and Wfs1 shRNA. On the fourth day after transfection, the cells were stained with the mitochondrial membrane potential sensitive dye tetramethylrhodamine ethyl ester (TMRE) at a concentration of 50 nM in complete NeurobasalTM-B medium at 37°C for 30 min and visualized in Krebs-Ringer solution supplemented with 1 mM Ca2+ using confocal microscope equipped with a 100×/oil objective.
Calcium Measurements
For Fluo-4 based measurements, neurons were transfected with scrambled shRNA or Wfs1 shRNA, plasmids of interests, and mKate2-mito to visualise transfected cells. Five days later, cells were loaded with 5 μM Fluo-4 AM in Hank’s Balanced Salt Solution (HBSS with Ca2+ and Mg2+) for 30 min at 37°C, followed by 10 min incubation in HBSS without dye to allow complete de-esterification of intracellular AM esters. Fluo-4 AM was excited using a 488-nm argon laser, and emitted fluorescence was quantified using a LSM 510 confocal microscope. Time-lapse images were recorded at 2-s intervals for 1 min before and 2 min after the induction of Ca2+ transients. Cytosolic Ca2+ transients were induced by 25 mM KCl, 200 μM DHPG, 2 mM glutamate, or by the photoactivatable membrane-permeant caged derivative of IP3. In the latter case, cells were co-loaded with 2.5 μM Fluo4-AM and 4 μM Ins(1,4,5)P3-PM (SiChem) for 90 min at 37°C. Photolysis of caged IP3 by irradiating the individual cells with near-UV laser (405 nm) for 10 s was used to release active IP3. Fluorescence signals from single transfected neurons identified with mKate2-mito were analysed, and mean changes in fluorescence intensities were calculated. Examples of Fluo-4 time-lapse images in control or Wfs1-siRNA transfected neurons are depicted in S18 Fig.
For the FRET-based analysis of cytosolic and ER Ca2+ levels, neurons were transfected with the genetically encoded FRET-based chameleon indicators D3cpv or D1ER, respectively, and scrambled shRNA or Wfs1 shRNA. Transfected neurons were rinsed once and then allowed to equilibrate in HBSS containing Ca2+ and Mg2+ for 20 min. Neurons were excited at 405 nm and emission acquired at 465–510 (CFP) and 520–555 (FRET).
For bioluminescence-based calcium measurements, neurons were transfected with cytosolic aequorin together with shRNAs and plasmids of interest. Five days later, cells were incubated for 30 min with 3 μM ViviRen Live Cell Substrate (Promega) in Krebs buffer containing 1 mM CaCl2 and 0.5% BSA at 37°C. Ca2+ uptake was stimulated by 25 mM KCl and experiments were terminated by lysing the cells with 2.5% Triton X-100 in Ca2+-rich solution to measure the maximal activity of aequorin. Aequorin luminescence was monitored by Victor X5 Multilabel Plate Reader (PerkinElmer).
Luciferase Reporter Assays
Primary neurons or PC12 cells growing in 96-well plates were transfected with the desired firefly luciferase reporter plasmid, Renilla luciferase, and plasmids of interest. The luciferase assays were performed 48–96 h later using Dual-Glo Luciferase Assay reagent (Promega) according to the manufacturer's instructions. The promoter activities for NRF2, ATF6, ATF4, and IRE firefly luciferase luminescence were normalized to Renilla luciferase signal.
Neuronal Maturation, Axonal Growth, and Synaptic Density
For neuronal maturation experiments, cortical neurons were transfected at DIV1 with a plasmid expressing neuron-specific pAAV-hSyn-DsRed1 and scrambled shRNA or Wfs1 shRNA. Live-cell morphology was visually examined using a fluorescence microscope (Olympus IX70, 20x/0.70 water immersion objective) on randomly selected fields (minimum 30 fields per group) on the indicated days in culture. Neurons were classified into the four subgroups depending on their maturation stage (Type I: lamellipodia; Type II: immature neuron, sprouting of several minor neurites; Type III: axon and dendrite formation, neuronal polarisation and branching; Type IV: neuron with adult-like morphology, ongoing maturation of differentiated processes).
For the axonal growth analysis, images of cultured cortical neurons (DIV2 to DIV6) were captured using an Olympus IX70 inverted microscope with a 20x objective and traced manually using Neurolucida software (MBF Bioscience). The length of the axonal tree, length of the longest axon, and number of axon tips were measured using Neurolucida Explorer.
For synapse detection, neurons were transfected at DIV2 with GFP and shRNAs. Neurons were fixed and permeabilized at DIV4, DIV6, or DIV18 using the Image-iT Fixation/Permeabilization Kit (Life Technologies) according to the manufacturer’s protocol. Fixed neurons were then incubated with the primary antibody mouse anti-PSD95 (1:1000, ab2723, Abcam) in the presence of 3% normal goat serum at 4°C for 24 h. After washing, the cells were further incubated with the secondary antibody goat anti-mouse DyLight 594 (1:1000, ab96873, Abcam) at room temperature for 1 h and visualised using LSM510 confocal microscope (63×/1.3 water immersion objective). The immunofluorescent puncta close to soma colocalizing with GFP were quantified manually. The PSD-95 positive puncta co-localizing with GFP marked neurites were quantified manually.
Magnetic Resonance Imaging
The majority of mice were generated from Wfs+/- male and female [40] breeding pairs. Additional Wfs+/+ mice (2) were generated from a separate breeding pair on a similar background. Mice were housed in a temperature- and humidity-controlled room. Food and water were available ad libitum, and mice were kept on a 12:12 h light:dark cycle. At 1 y of age, mice were deeply anesthetized and perfused with 0.1 M PBS followed by 4% paraformaldehyde (4°C). Brains were left in skulls to preserve anatomy and incubated in 4% PFA overnight at 4°C and then in PBS until 2 days prior to imaging. Skulls were then placed in 2 mM gadovist in PBS and incubated at 4°C with rocking until imaging. A T2 RARE sequence was used for imaging using a 94/20 Bruker BioSpec small animal MRI with the following parameters: Tr, 900 ms; TE, 47.13 ms; imaging matrix, 512 x 360 x 80; spatial resolution, 0.0444 x 0.03 x 0.2 mm for an imaging time of approximately 3 h and 4 min. Volumes were segmented manually by an observer blinded to genotype using ITK-SNAP (V3.2.0). For the cortex at the level of the striatum, the volume of cortex from bregma +1.70 mm to -2.18 mm was quantified. For the optic nerve, volumes were calculated for optic nerve rostral to the optic chiasm. For brain stem (pons and medulla), the most rostral portions of the pons and the most caudal portion of the medulla ventral to the cerebellum are not included in the Paxinos atlas; thus, quantification of brain stem began at the most rostral portion of the pons, ventral to the interpeduncular nucleus and dorsal to the mammillary body (approximately bregma +3.62 mm), and ended at the termination of the overlying cerebellum (approximately bregma -8.5 mm).
RT-PCR
Total RNA was isolated from age-matched Wfs1-/- and Wfs1+/+ using the Qiagen RNeasy Mini Kit. Conversion to cDNA was performed by reverse transcription using 1 μg of total RNA with SuperScript III RT kit (Invitrogen). Specific primers were designed for amplification of Mfn2, Mfn1, Opa1, Drp1, Fis1, Miro2, and Cox4 genes. qPCR was performed on an ABI PRISM 7900HT Sequence Detection System. Reactions were performed using an ABI SYBRGreen PCR Master Mix, and raw data were analysed using the ΔΔCt method. All Ct values were normalised to the control gene synaptophysin (SYN).
Statistics
Data are presented as the mean ± SEM. The number of replicates for each type of experiments is given in S2 Table. The D’Agostino-Pearson omnibus test was used to test the normality of distribution. t tests, Mann Whitney test, Wilcoxon signed rank test, one-way ANOVAs followed by Bonferroni posthoc test (selected pairs), or Kruskal-Wallis tests followed by the Dunn test were used to compare differences between experimental samples and control groups. Two-way ANOVAs were used to analyse interactions between two treatments. P values of less than 0.05 were considered statistically significant.
Supporting Information
Acknowledgments
We thank Dr. T. Iwawaki, Dr. R. Youle, Dr. R. Rizzuto, Dr. Szabadkai, Dr. Alam, and Dr. E. Deas for providing the plasmids used in this study. We thank Ulla Peterson for her preparation of primary neurons. We also thank Indrek Heinla, Mait Nigul, Katarína Jašková, Lucia Lichvarova, Liia Feoktistova, Ksenja Labonarskaja, and Victoria Vdovenkova for their help.
Abbreviations
- CaM
calmodulin
- DHPG
dihydroxyphenylglycine
- DIDMOAD
diabetes insipidus, diabetes mellitus, optical atrophy, and deafness
- ER
endoplasmic reticulum
- FRET
fluorescence resonance energy transfer
- IP3R
inositol 1,4,5-trisphosphate receptor
- ROS
reactive oxygen species
- TMRE
tetramethylrhodamine ethyl ester
- WFS1
Wolfram syndrome 1
- WS
Wolfram syndrome
- wt
wild-type
Data Availability
All relevant data are within the paper and its Supporting Information files.
Funding Statement
This work was supported by grants from the Estonian Research Council (www.etag.ee) to AK (IUT2-5), EV (IUT20-41), MC (MJD35 and PUT771), and VC (PUT513); from the European Union's Horizon 2020 research and innovation programme (ec.europa.eu/programmes/horizon2020) to AK (692202); from the European Regional Development Fund (http://ec.europa.eu/regional_policy/en/funding/erdf) to AK and EV (Project No. 2014-2020.4.01.15-0012); from the Slovak Academy of Sciences (www.sav.sk) to MC (SASPRO 0063/01/02) and by the Estonian-French research program Parrot. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
References
- 1.Barrett TG, Bundey SE, Fielder AR, Good PA. Optic atrophy in Wolfram (DIDMOAD) syndrome. Eye. 1997;11:882–888. [DOI] [PubMed] [Google Scholar]
- 2.Hershey T, Lugar HM, Shimony JS, Rutlin J, Koller JM, Perantie DC, et al. Early brain vulnerability in Wolfram syndrome. PLoS ONE. 2012;7:e40604 10.1371/journal.pone.0040604 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 3.Osman AA, Saito M, Makepeace C, Permutt MA, Schlesinger P, Mueckler MJ. Wolframin expression induces novel ion channel activity in endoplasmic reticulum membranes and increases intracellular calcium. J Biol Chem. 2003;278:52755–52762. [DOI] [PubMed] [Google Scholar]
- 4.Takei D, Ishihara H, Yamaguchi S, Yamada T, Tamura A, Katagiri H, et al. WFS1 protein modulates the free Ca(2+) concentration in the endoplasmic reticulum. FEBS Lett. 2006;580:5635–5640. [DOI] [PubMed] [Google Scholar]
- 5.Fonseca SG, Fukuma M, Lipson KL, Nguyen LX, Allen JR, Oka Y, et al. WFS1 is a novel component of the unfolded protein response and maintains homeostasis of the endoplasmic reticulum in pancreatic beta-cells. J Biol Chem. 2005;280:39609–39615. [DOI] [PubMed] [Google Scholar]
- 6.Kanki T, Klionsky DJ. Mitochondrial abnormalities drive cell death in Wolfram syndrome 2. Cell Res. 2009;19:922–923. 10.1038/cr.2009.94 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 7.Ross-Cisneros FN, Pan BX, Silva RA, Miller NR, Albini TA, Tranebjaerg L, et al. Optic nerve histopathology in a case of Wolfram Syndrome: a mitochondrial pattern of axonal loss. Mitochondrion. 2013;13:841–845. 10.1016/j.mito.2013.05.013 [DOI] [PubMed] [Google Scholar]
- 8.Chen YF, Kao CH, Chen YT, Wang CH, Wu CY, Tsai CY, et al. Cisd2 deficiency drives premature aging and causes mitochondria-mediated defects in mice. Genes Dev. 2009;15:1183–1194. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 9.Wiley SE, Andreyev AY, Divakaruni AS, Karisch R, Perkins G, Wall EA, et al. Wolfram Syndrome protein, Miner1, regulates sulphydryl redox status, the unfolded protein response, and Ca2+ homeostasis. EMBO Mol Med. 2013;5:904–918. 10.1002/emmm.201201429 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 10.Win S, Than TA, Fernandez-Checa JC, Kaplowitz N. JNK interaction with Sab mediates ER stress induced inhibition of mitochondrial respiration and cell death. Cell Death Dis. 2014;5:e989 10.1038/cddis.2013.522 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 11.Shang L, Hua H, Foo K, Martinez H, Watanabe K, Zimmer M, Kahler DJ, et al. β-cell dysfunction due to increased ER stress in a stem cell model of Wolfram syndrome. Diabetes. 2014;63:923–933. 10.2337/db13-0717 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 12.Bonnet Wersinger D, Benkafadar N, Jagodzinska J, Hamel C, Tanizawa Y, Lenaers G, et al. Impairment of visual function and retinal ER stress activation in Wfs1-deficient mice. PLoS ONE. 2014;9:e97222 10.1371/journal.pone.0097222 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 13.Higo T, Hamada K, Hisatsune C, Nukina N, Hashikawa T, Hattori M, et al. Mechanism of ER stress-induced brain damage by IP(3) receptor. Neuron. 2010;68:865–878. 10.1016/j.neuron.2010.11.010 [DOI] [PubMed] [Google Scholar]
- 14.Berridge MJ. Inositol trisphosphate and calcium signalling mechanisms. Biochim Biophys Acta. 2009;1793:933–940. 10.1016/j.bbamcr.2008.10.005 [DOI] [PubMed] [Google Scholar]
- 15.Fonseca SG, Ishigaki S, Oslowski CM, Lu S, Lipson KL, Ghosh R, et al. Wolfram syndrome 1 gene negatively regulates ER stress signaling in rodent and human cells. J Clin Invest. 2010;120:744–755. 10.1172/JCI39678 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 16.Lu S, Kanekura K, Hara T, Mahadevan J, Spears LD, Oslowski CM, et al. A calcium-dependent protease as a potential therapeutic target for Wolfram syndrome. Proc Natl Acad Sci USA. 2014;111:E5292–E5301. 10.1073/pnas.1421055111 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 17.Wang X, Schwarz TL. The mechanism of Ca2+ -dependent regulation of kinesin-mediated mitochondrial motility. Cell. 2009;136:163–174. 10.1016/j.cell.2008.11.046 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 18.Gegg ME, Cooper JM, Chau KY, Rojo M, Schapira AH, Taanman JW. Mitofusin 1 and mitofusin 2 are ubiquitinated in a PINK1/parkin-dependent manner upon induction of mitophagy. Hum Mol Genet. 2010;9:4861–4870. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 19.Ziviani E, Tao RN, Whitworth AJ. Drosophila parkin requires PINK1 for mitochondrial translocation and ubiquitinates mitofusin. Proc Natl Acad Sci USA. 2010;107:5018–5023. 10.1073/pnas.0913485107 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 20.Choubey V, Cagalinec M, Liiv J, Safiulina D, Hickey MA, Kuum M, et al. BECN1 is involved in the initiation of mitophagy: it facilitates PARK2 translocation to mitochondria. Autophagy. 2014;10:1105–1119. 10.4161/auto.28615 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 21.Narendra D, Tanaka A, Suen DF, Youle RJ. Parkin is recruited selectively to impaired mitochondria and promotes their autophagy. J Cell Biol 2008;183:795–803. 10.1083/jcb.200809125 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 22.Geisler S, Holmstrom KM, Skujat D, Fiesel FC, Rothfuss OC, Kahle PJ et al. PINK1/Parkin-mediated mitophagy is dependent on VDAC1 and p62/SQSTM1. Nat Cell Biol. 2010;12:119–131. 10.1038/ncb2012 [DOI] [PubMed] [Google Scholar]
- 23.Matsuda N, Sato S, Shiba K, Okatsu K, Saisho K, Gautier CA, et al. PINK1 stabilized by mitochondrial depolarization recruits Parkin to damaged mitochondria and activates latent Parkin for mitophagy. J Cell Biol. 2010;189:211–221. 10.1083/jcb.200910140 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 24.Narendra DP, Jin SM, Tanaka A, Suen DF, Gautier CA, Shen J et al. PINK1 is selectively stabilized on impaired mitochondria to activate Parkin. PLoS Biol. 2010;8:e1000298 10.1371/journal.pbio.1000298 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 25.Choubey V, Safiulina D, Vaarmann A, Cagalinec M, Wareski P, Kuum M, et al. Mutant A53T alpha-synuclein induces neuronal death by increasing mitochondrial autophagy. J Biol Chem. 2011;286:10814–10824. 10.1074/jbc.M110.132514 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 26.Shadrina M, Nikopensius T, Slominsky P, Illarioshkin S, Bagyeva G, Markova E, et al. Association study of sporadic Parkinson's disease genetic risk factors in patients from Russia by APEX technology. Neurosci Lett. 2006;405:212–216. [DOI] [PubMed] [Google Scholar]
- 27.Kõks S, Overall RW, Ivask M, Soomets U, Guha M, Vasar E, et al. Silencing of the WFS1 gene in HEK cells induces pathways related to neurodegeneration and mitochondrial damage. Physiol Genomics. 2013;45:82–190. [DOI] [PubMed] [Google Scholar]
- 28.Visnapuu T, Plaas M, Reimets R, Raud S, Terasmaa A, Kõks S, et al. Evidence for impaired function of dopaminergic system in Wfs1-deficient mice. Behav Brain Res. 2013;244:90–99. 10.1016/j.bbr.2013.01.046 [DOI] [PubMed] [Google Scholar]
- 29.Westermann B. Bioenergetic role of mitochondrial fusion and fission. Biochim Biophys Acta. 2012;1817:1833–1838. 10.1016/j.bbabio.2012.02.033 [DOI] [PubMed] [Google Scholar]
- 30.Flint J, Kendler KS. The genetics of major depression. Neuron. 2014;81:484–503. 10.1016/j.neuron.2014.01.027 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 31.Swift RG, Sadler DB, Swift M. Psychiatric findings in Wolfram syndrome homozygotes. Lancet. 1990;336:667–669. [DOI] [PubMed] [Google Scholar]
- 32.Swift RG, Polymeropoulos MH, Torres R, Swift M. Predisposition of Wolfram syndrome heterozygotes to psychiatric illness. Mol Psychiatry. 1998;3:86–91. [DOI] [PubMed] [Google Scholar]
- 33.Sequeira A, Kim C, Seguin M, Lesage A, Chawky N, Desautels A, et al. Wolfram syndrome and suicide: Evidence for a role of WFS1 in suicidal and impulsive behavior. Am J Med Genet B Neuropsychiatr Genet. 2003;119B:108–113. [DOI] [PubMed] [Google Scholar]
- 34.Swift M, Swift RG. Wolframin mutations and hospitalization for psychiatric illness. Mol Psychiatry. 2005;10:799–803. [DOI] [PubMed] [Google Scholar]
- 35.Zalsman G, Mann MJ, Huang YY, Oquendo MA, Brent DA, Burke AK, et al. Wolframin gene H611R polymorphism: no direct association with suicidal behavior but possible link to mood disorders. Prog. Neuropsychopharmacol. Biol Psychiatry. 2009;33:707–710. 10.1016/j.pnpbp.2009.03.017 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 36.Furlong RA, Ho LW, Rubinsztein JS, Michael A, Walsh C, Paykel ES, et al. Rare coding variant within the wolframin gene in bipolar and unipolar affective disorder cases. Neurosci Lett. 1999;277:123–126. [DOI] [PubMed] [Google Scholar]
- 37.Ohtsuki T, Ishiguro H, Yoshikawa T, Arinami TJ. WFS1 gene mutation search in depressive patients: detection of five missense polymorphisms but no association with depression or bipolar affective disorder. Affect Disord. 2000;8:11–17. [DOI] [PubMed] [Google Scholar]
- 38.Torres R, Leroy E, Hu X, Katrivanou A, Gourzis P, Papachatzopoulou A, et al. Mutation screening of the Wolfram syndrome gene in psychiatric patients. Mol Psychiatry. 2001;6:39–43: [DOI] [PubMed] [Google Scholar]
- 39.Cagalinec M, Safiulina D, Liiv M, Liiv J, Choubey V, Wareski P, et al. Principles of the mitochondrial fusion and fission cycle in neurons. J Cell Sci. 2013;126:2187–2197. 10.1242/jcs.118844 [DOI] [PubMed] [Google Scholar]
- 40.Luuk H, Plaas M, Raud S, Innos J, Sütt S, Lasner H, et al. Wfs1-deficient mice display impaired behavioural adaptation in stressful environment. Behav Brain Res. 2009;198:334–345. 10.1016/j.bbr.2008.11.007 [DOI] [PubMed] [Google Scholar]
Associated Data
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