Activation of LRP6 with HLY78 Attenuates Oxidative Stress and Neuronal Apoptosis via GSK3β/Sirt1/PGC-1α Pathway after ICH

Background Oxidative stress and neuronal apoptosis have important roles in the pathogenesis after intracerebral hemorrhage (ICH). Previous studies have reported that low-density lipoprotein receptor-related protein 6 (LRP6) exerts neuroprotection in several neurological diseases. Herein, we investigate the role of LRP6 receptor activation with HLY78 to attenuate oxidative stress and neuronal apoptosis after ICH, as well as the underlying mechanism. Methods A total of 199 CD1 mice were used. ICH was induced via injection of autologous blood into the right basal ganglia. HLY78 was administered via intranasal injection at 1 h after ICH. To explore the underlying mechanism, LRP6 siRNA and selisistat, a Sirt1 selective antagonist, were injected intracerebroventricularly at 48 h before ICH induction. Neurobehavioral tests, Western blot, and immunofluorescence staining were performed. Results The expression of endogenous p-LRP6 was gradually increased and expressed on neurons after ICH. HLY78 significantly improved the short- and long-term neurobehavioral deficits after ICH, which was accompanied with decreased oxidative stress and neuronal apoptosis, as well as increased expression of p-GSK3β, Sirt1, and PGC-1α, as well as downregulation of Romo-1 and C-Caspase-3. LRP6 knockdown or Sirt1 inhibition abolished these effects of HLY78 after ICH. Conclusion Our results suggest that administration of HLY78 attenuated oxidative stress, neuronal apoptosis, and neurobehavioral impairments through the LRP6/GSK3β/Sirt1/PGC-1α signaling pathway after ICH.


Introduction
Intracerebral hemorrhage (ICH) is one of the most dangerous subtypes of stroke and affects more than 1 million people annually [1,2]. Despite extensive research into ICH pathology, a clinically approved neuroprotective treatment remains elusive [3]. There is growing evidence to suggest that overproduction of reactive oxygen species (ROS) serves as a key mechanism leading to brain injury after ICH [4]. Imbalance of ROS production and consumption leads to macromolecular damage, cellular signal transduction disor-der, cell death, and tissue damage [5,6]. Therefore, targeting oxidative stress and the subsequent neuronal apoptosis would be an effective way to improve the overall outcome of ICH.
Low-density lipoprotein receptor-related protein 6 (LRP6) is a Wnt coreceptor belonging to the low-density lipoprotein receptors (LDLRs) and is a transmembrane cell surface protein that induces the typical Wnt signaling pathway [7,8]. LRP6 is involved in embryonic development, body fat, glucose homeostasis, and bone cell metabolism through induction of typical Wnt signaling pathways.
Additionally, the role of LPR6 in cardiovascular system diseases has been extensively studied [9][10][11][12]. As research progressed, it was found that LRP6 activation could participate in neuroprotection in neurological disorders. Several studies have confirmed that LPR6 exerts neuroprotective effects through various mechanisms such as those that are antiinflammatory, antioxidant, antiapoptotic, and protective of BBB integrity in focal cerebral ischemia and subarachnoid hemorrhage [13][14][15]. However, no studies have validated the neuroprotective role of LRP6 in brain injury after ICH.
HLY78 is a small molecule lycopene derivative that promotes LRP6 phosphorylation and Wnt signaling [16]. The antiapoptotic effect of HLY78 has also been demonstrated in tumors and in SAH [15,17]. However, the role of HLY78 in ICH remains unexplored.
PGC-1α (peroxisome proliferator-activated receptor gamma coactivator 1-alpha) plays a key role in mitochondrial production and antioxidation [18]. Xu et al. demonstrated that PGC-1α exerts neuroprotective effects after SAH by entering the nucleus to promote antioxidative stress and antiapoptotic effects [19]. However, to date, few studies have explored the role of PGC-1α in ICH. Activation of PGC-1α requires Sirt1 (silent information regulator 1) acetylation [20]. Sirt1 reportedly improves mitochondrial function and attenuates brain injury by increasing PGC-1α levels [21]. Sirt1 interacts with GSK3β, and Koga et al. similarly found that Sirt1 upregulation can be mediated by GSK3β [22,23] Under oxidative stress, LRP6 overexpression promoted the increased phosphorylation of GSK3β in cardiomyocytes [8].
In the current study, we hypothesized that LRP6 activation with HLY78 would attenuate mitochondria-mediated oxidative stress and neuronal apoptosis, thus improving neurological outcome after ICH. The potential mechanism may involve the GSK3β/Sirt1/PGC-1α signaling pathway.

Methods and Materials
All experimental protocols and procedures were approved by the Ethics Committee of Fudan University and in accordance with the National Institutes of Health guidelines.
2.1. Animals. Adult male CD1 mice weighing 25-35 g were purchased from Shanghai JieSiJie Laboratory Animal Co., Ltd. Mice were housed in a standard temperature and humidity-controlled room with a 12 h light/12 h dark cycle and ad libitum access to food and water.

ICH
Model. The ICH model was induced via autologous blood injection as previously described [24]. Briefly, after deeply anesthetizing the mice with intraperitoneal injection of ketamine/xylazine (100/10 mg/kg), they were placed prone on a stereotactic head frame (Kopf Instruments, CA). Next, 30 μl of autologous arterial blood collected from the left femoral artery was slowly injected into the right basal ganglia (coordinates: 1.5 mm lateral to the midline, 0.9 mm posterior to bregma, and 3.5 mm subdural) via a micro infusion pump (Harvard Instruments, MA). After injection, the needle remained in place for an additional 10 minutes to prevent extravasation of blood. Finally, the drill hole was sealed with bone wax, the skin incision was sutured, and the mice were allowed to recover. The body temperature of the mice was maintained throughout the procedure using an electronic thermostat-controlled heating blanket (37 ± 0:5°C). The sham mice underwent the same surgical procedure, except for blood injection.

Drug Administration
2.3.1. Intranasal Administration. HLY78 or DMSO was administered via intranasal (i.n) injection while under isoflurane anesthesia at 1 h after ICH as previously described [25]. Specifically, DMSO (vehicle) or HLY78 (0.6 mg/kg, 1.2 mg/kg, and 2.4 mg/kg) was administered as nose drops (5 μL/drop) over a period of 30 min, alternating drops every 5 min between the left and right nares. The total volume delivered in each mouse was 30 μL.

Intracerebroventricular
Injection. LRP6 siRNA (500 pmol/5 μl; OriGene Technologies, MD, USA), scrambled siRNA (5 μl), or selisistat was injected via intracerebroventricular injection (i.c.v.) at 48 h prior to surgery as previously described [26]. After being deeply anesthetized, the mice were placed in a stereotaxic apparatus. The needle was inserted into the left lateral ventricle (coordinates relative to bregma: 0.3 mm posterior, 1.0 mm lateral, and 2.3 mm deep) through a burr hole on the skull. The drugs were administrated at a rate of 0.5 μl/min using an infusion pump. After injection, the needle remained in the same position for another 10 minutes to prevent leakage. After remaining in place for 10 minutes, it was slowly withdrawn over a period of 5 minutes.

Experiment Design.
A total of five separate experiments were performed as depicted in Figure 1.

Experiment 1. Time-Course and Cellular Localization.
To determine the endogenous protein levels and cellular localization of p-LRP6, 40 mice were randomly divided into 6 groups: sham (n = 8), ICH-3 h (n = 6), ICH-6 h (n = 6), ICH-12 h (n = 6), ICH-24 h (n = 8), and ICH-72 h (n = 6). The p-LRP6 protein levels were detected by Western blot in the right cerebral hemisphere, and the cellular localization of p-LRP6 was assessed via immunofluorescence staining.  [27]. The modified Garcia test consists of seven separate tests including spontaneous activity, symmetry of limb movement, forelimb extension, climbing, proprioception, response to a vibrating screen, and lateral rotation. Each of these has a possible score of 3, with a maximum score of 21 representing optimal neurobehavioral function.
The forelimb placement test was performed by holding the mouse's trunk and then bringing its left vibrissae into   The corner test was performed in a 30°corner formed by two transparent plates. The mouse was placed on the platform and guided to turn in the corner. The result was recorded as a percentage of the behavior of the left turn.
2.5.2. Long-Term Neurobehavioral Test. Foot fault tests were used to assess sensory function and were conducted on weeks 1-3 after ICH, as previously described [28]. The mice were allowed to move freely for 2 minutes on a wire mesh covered with 2 cm × 2 cm squares. The number of missed steps in which the mouse's left forelimb slipped through one of the square holes was recorded.
The rotarod test is commonly used to assess motor coordination in animals [29]. The mice were placed on the rotating cylinder, the starting speed was set at 5 RPM, and the time of the mice falling was recorded for 5 consecutive times. The average time of the 5 times was finally taken.
Morris water maze experiments were performed on days 23 to 28 after ICH to assess the learning and memory functions of the mice as previously described [30]. During the first 5 days of the experiment, the mice were randomly placed in the pool from different points each time until they swam to the platform selectively placed in a quadrant of the pool and remained there. The distance they swam and the time it took to find the platform were recorded. On the 6th day of the experiment, the platform was removed and the mice were placed into the water to swim for 60 s. The movement trajectory of the mice and the time spent in the platform quadrant were recorded.
2.6. Immunofluorescence Staining 2.6.1. Histology. After being deeply anesthetized, the mice were transcardially perfused with PBS, followed by 10% formalin. Then, the brains were removed and placed in 10% formalin for 1 day, followed by placement in 30% sucrose solution for 3 days until the brains were frozen in OCT and sliced into 10 μm coronal sections using a cryostat. These sections were stored at -80°C for subsequent experiments.
2.6.2. Double Immunofluorescence Staining. Double immunofluorescence staining was performed as previously described [31]. After being washed 3 times with 0.01 M PBS for 10 minutes each, the slides were then incubated in 0.3% Triton X-100 for 10 minutes, followed by incubation in 5% donkey serum at room temperature for 2 hours. The brain sections were then incubated overnight at 4°C with the following primary antibodies: anti-p-LRP6 (1 : 50, MyBioSource Inc., USA) and anti-NeuN (1 : 100, Abcam, USA). The sections were then washed with PBS and incubated with the corresponding secondary antibody (1 : 100, Jackson Immuno Research, USA) for 1 hour at room temperature. Lastly, they were visualized and photographed with a fluorescence microscope (Leica Microsystems, Germany).
2.6.3. DHE Staining. Dihydroethidium (DHE) staining was conducted to evaluate ROS production as previously described [32]. The brain sections were incubated with freshly prepared dihydroethidium (2 μmol/L) (Thermo Fisher Scientific, USA) for 30 min at 37°C in the dark. The images were captured using a fluorescence microscope, and the fluorescence intensity was quantified with the ImageJ software.
2.6.4. TUNEL Staining. Terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) staining was conducted using the Apoptosis Detection Kit (Roche, USA) according to the manufacturer's instructions for quantification of the apoptosis of neurons surrounding the hematoma 24 hours after ICH [33]. The TUNEL-positive neurons were counted manually at ×200 magnification in the perihematomal region. Data were expressed as the ratio of TUNELpositive neurons (%).
2.6.5. FJC Staining. Degenerated neurons were stained using the Fluoro-Jade C (FJC) Ready-to-Dilute Staining Kit (Biosensis, USA) according to the manufacturer's instructions. FJC-positive neurons were counted in six sections of each brain using the ImageJ software to assess the extent of neuronal damage. Data were expressed as cells/ mm 2 as the average number of FJC-positive neurons in each region.

Western Blot.
Western blot was performed as previously described [34]. After being deeply anesthetized and transcardially perfused with frozen PBS, the right hemisphere of the mouse brain was collected and stored at -80°C until use. The brain tissue was homogenized in RIPA lysis buffer (Santa Cruz Biotechnology Inc., USA) and then centrifuged at 12,000 RPM at 4°C for 30 min, and the supernatant was normalized to a solution with equal protein concentration. The protein solution was mixed with loading buffer reagent and then denatured (95°C, 10 min). Protein samples with equal volumes were loaded on an SDS-PAGE gel, and then, the electrophoresed protein bands were transferred to a nitrocellulose membrane. The membrane was incubated with the following primary antibodies overnight at 4°C: anti , and anti-β-actin (1 : 5000, Santa Cruz Biotechnology Inc., USA). Then, the appropriate secondary antibody (Santa Cruz Biotechnology, USA) was applied to the membranes and incubated for 1 h at room temperature. Immunoblots were then visualized with ECL Plus chemiluminescence reagent kit (Amersham Bioscience, USA) and quantified using the ImageJ software.
2.8. Statistical Analysis. All data were expressed as the mean and standard deviation (mean ± SD) and analyzed with GraphPad Prism (GraphPad Software, USA). Multiple comparisons were analyzed using one-way ANOVA and post 4 Oxidative Medicine and Cellular Longevity hoc Bonferroni test. Two-way ANOVA, followed by Tukey post hoc test, was used to compare the changes according to the different levels of multiple categorical variables. Data were screened for normality using the Shapiro-Wilk test.
Since data were not normally distributed, the betweengroup differences were analyzed with nonparametric test. p < 0:05 was considered to be statistically significant.  (Figures 2(a) and 2(b)). To confirm the cellular location of p-LRP6, double immunofluorescence staining was performed at 24 hours after ICH, as the protein expression peaked at this time point. The results showed that p-LRP6 was abundantly expressed on neurons, and the number of p-LRP6-positive neurons increased significantly after ICH (Figure 2(c)).       4(b)). Romo-1 is a marker of oxidative stress. Our data showed that Romo-1 was significantly increased in the vehicle group compared to the sham group at 24 hours after ICH, and treatment with HLY78 significantly decreased the level of Romo-1 (p < 0:05 Figures 4(c) and 4(d)).

HLY78 Reduced Neuronal Apoptosis and Neuronal
Degeneration at 24 h after ICH. Since ICH could cause neu-ronal apoptosis and degeneration, TUNEL staining and FJC staining were used to determine whether HLY78 reduced damage 24 hours after ICH. Compared with the sham group, TUNEL-positive neurons and FJC-positive neurons in the perihematomal area were significantly increased in the ICH+vehicle group at 24 hours after ICH, but HLY78 treatment reduced the number of TUNEL-positive and FJCpositive neurons (p < 0:05 Figures 5(a)-5(d)). Western blot data showed that C-Caspase-3 was significantly increased after ICH, and that HLY78 treatment could reduce the expression of C-Caspase-3 (Figures 6(a) and 6(f)). These results suggest that HLY78 treatment can significantly reduce neuronal damage in ICH.     In the probe quadrant trial, the ICH+vehicle group spent less time in the target quadrant when the platform was removed compared to the sham group, while the time spent in the target quadrant was significantly increased in the ICH+HLY78 group compared to the ICH+vehicle group (p < 0:05 Figures 7(a) and 7(d)). These results showed that HLY78 significantly improved memory and learning dysfunction after ICH.
Regarding the rotarod test, the mice in the ICH+vehicle group had significantly shorter falling latency than the sham group. Consistently, the ICH+vehicle group had more foot faults of the left forelimb when compared with sham groups in foot fault tests after ICH. However, HLY78 treatment significantly improved the behavioral performance in foot fault test and rotarod test in ICH mice (p < 0:05, Figures 7(b) and 7(c)).

Endogenous Brain LRP6 Knockdown Exacerbated
Neurological Deficits at 24 h after ICH. To assess the role of endogenous LRP6 after ICH, LRP6 siRNA was administered 48 h before ICH induction. Western blot results showed that the protein level of LRP6 was significantly decreased in LRP6 siRNA-treated naïve mice or ICH mice when compared with the scr siRNA group (p < 0:05, Figures 8(a) and 8(b)), indicating the LRP6 knockdown efficiency of siRNA. In naïve mice, LRP6 knockdown did not adversely affect the neurological function of the mice, whereas in ICH mice, LRP6 knockdown exacerbated neurobehavioral deficits (p < 0:05, Figures 8(c) and 8(d)). Taken together, these results suggest its role as an endogenous protective response to stress and deleterious stimuli in the acute phase after ICH.

HLY78 Attenuates Oxidative Stress and Neuronal
Apoptosis via LPR6/GSK3β/Sirt1/PGC-1α Signaling Pathway at 24 h after ICH. Western blot data showed that the expression of p-GSK3β, Sirt1, PGC-1α, Romo-1, and C-Caspase-3 was significantly increased 24 hours after ICH when compared with the sham group. HLY78 treatment further increased the expression of p-GSK3β, Sirt1, and PGC-1α, but the expression of C-Caspase-3 and Romo-1 was decreased in the ICH+HLY78 group when compared with the ICH+vehicle group. LRP6 siRNA was given 48 hours prior to ICH induction to knock down the gene of LRP6, which was done to assess the involvement of LRP6 in the antiapoptotic and antioxidant pathways of HLY78 after ICH. Our data showed that pretreatment with LRP6 siRNA significantly reduced the downstream molecules p-GSK3β, Sirt1, and PGC-1α when compared to the ICH+HLY78+scr siRNA group. However, compared to the control group, the ICH+HLY78+LRP6 siRNA group observed a significant overexpression of C-Caspase-3 and Romo-1 expression (p < 0:05, Figures 6(a)-6(f)). These results suggest that HLY78 exerts antiapoptotic and antioxidant neuroprotective effect mediated through LRP6.
To verify the role of Sirt1 in LRP6-mediated neuroprotective effects, selisistat, a specific inhibitor of Sirt1, was   11 Oxidative Medicine and Cellular Longevity administered. Western blot analysis showed that selisistat did not affect the protein expression level of GSK3β. However, the levels of Sirt1 and PGC-1α were significantly decreased, whereas the levels of C-Caspase-3 and Romo-1 were increased in the ICH+HLY78+selisistat group when compared with the ICH+HLY78+DMSO group (p < 0:05, Figures 9(a)-9(f)). Thus, Sirt1 acts as a downstream factor of LRP6, and its inhibitory effect abolishes the antiapoptotic and antioxidative stress effects of HLY78. These results suggest that LRP6 activation by HLY78 attenuated oxidative stress, neuronal apoptosis, and neurological deficits after ICH in mice, partially through the GSK3β/Sirt1/PGC-1α signaling pathway.

Discussion
Intracerebral hemorrhage (ICH) is a stroke subtype associated with high rates of mortality and disability. Oxidative stress and neuronal apoptosis play important roles in the pathogenesis of early brain injury (EBI) after ICH [5,35]. Therefore, inhibition of oxidative stress and neuronal apoptosis are potential therapeutic targets for ICH-induced secondary brain injury (SBI), which would provide a promising strategy for clinical treatment. In the present study, we focused on the effects of HLY78 treatment in reducing OS-induced neuronal degeneration and apoptosis after ICH. The major novel findings of this study are as follows: (1) endogenous expression of p-LRP6 in brain was abundantly expressed on neurons, which increased in a timedependent manner and peaked at 24 h after ICH; (2) intranasal administration of HLY78 remarkably reduced oxidative stress and neuronal apoptosis 24 h after ICH and improved short-and long-term neurological deficits; (3) HLY78 treatment was associated with upregulation of p-GSK3β, Sirt1, and PGC-1α and downregulation of C-Caspase-3 and Romo-1 at 24 h after ICH. (4) Silence of LRP6 or inhibition of Sirt1 partially reversed the effects of HLY78 on the expression of p-GSK3β, Sirt1, PGC-1α, C-Caspase-3, and Romo-1. These results suggest that HLY78 is neuroprotective against OS-induced neuronal damage after ICH. This protection is exerted at least partially through the LRP6/GSK3β/Sirt1/PGC-1α signaling pathway.
LRP6 belongs to the low-density lipoprotein (LDL) receptor-related family and is a transmembrane cell surface protein. After Wnt binds to its receptor, Frizzled, LRP6 forms a complex with Wnt-Frizzled to exert biological effects and promote the transcription of target genes [7]. Its molecular mechanism involves a variety of biological processes, including cancer development, immune response, or cellular metabolism [36,37]. A study by Wang et al. indicated that LRP6 could improve myocardial ischemia after refocusing injury through antioxidant and antiapoptotic effects [8,38]. In recent years, the role of LRP6 in neurological diseases has also been gradually investigated. The role of LRP6 is crucial in embryonic development and synapse formation, and loss of LRP6 leads to severe neurological deficits, including reduced production of granule cells in the hippocampus, defects in thalamic development, and impaired neocortical neuronal proliferation [39,40]. Liu et al. found that LRP6 mRNA and protein levels are significantly downregulated compared to age-matched controls in human AD brains [41]. Likewise, LRP6 haploinsufficiency increases proinflammatory markers, mitochondrial dysfunction, and stroke volume [13]. Harriott     confirm the changes in LRP6 expression and its neuroprotective effects after ICH. Our study found that p-LRP6 protein expression levels were significantly upregulated and abundantly expressed on neurons after ICH, which is consistent with the previous findings [14,15]. Thus, the temporal elevation of p-LRP6 protein expression may be an endogenous neuroprotective mechanism after ICH. However, this upregulation was not sufficient to counteract the overall brain injury in ICH mice. To further confirm this hypothesis, we used siRNA to knock down LRP6 protein expression before surgery, and the Western blot results showed that LRP6 siRNA administration significantly downregulated the LRP6 protein expression. Further neurobehavioral experiments confirmed that in naïve mice, knocking down LRP6 did not have an effect on neurological function, whereas in ICH mice, knocking down LRP6 clearly exacerbated the neurological deficits found in the mice. These results likewise suggest that LRP6 plays a neuroprotective role in ICH.
HLY78 is a novel lycorine derivative and has previously been shown to promote LRP6 phosphorylation and Wnt/ β-catenin signaling by enhancing Axin-LRP6 association [43]. In the SAH model, intranasal administration of HLY78 also upregulated the expression of p-LRP6 protein, which in turn functioned as an antiapoptotic agent and protected the integrity of the BBB [14,15]. However, the role of HLY78 in ICH has not yet been explored. Intranasal administration of drugs is a noninvasive method that can bypass the BBB for delivering drugs that target central nervous system disorders [44,45]. Therefore, we administered HLY78 intranasally at 1 hour after ICH in this study. The results showed that HLY78 treatment significantly improved short-and long-term outcome, improved deficits in learning and memory found in ICH mice, and attenuated oxidative stress levels and neuronal damage in the perihematomal area. These results suggest that HLY78 may be an effective drug for treating ICH.
Then, we studied the underlying mechanisms behind LRP6-mediated antioxidative stress and antiapoptotic effects. Under oxidative stress, LRP6 overexpression promoted the increased phosphorylation of GSK3β in cardiomyocytes [46]. Luo et al. demonstrated that LRP6 has a neuroprotective role in ischemic stroke by promoting the phosphorylation of GSK3β [15]. Consistent with previous studies, we found a significant upregulation of p-GSK3β expression in the brain after ICH, which suggests that endogenous upregulation does not completely reverse brain injury in ICH. The phosphorylation level of GSK3β was significantly increased after intranasal administration of HLY78, an agonist of LRP6. Sirt1 is reportedly a major regulator of mitochondrial biogenesis and lipid metabolism and has been shown to be necessary for promoting oxidative stress-induced MEF cell death [47,48]. It interacts with GSK3β, and Koga et al. similarly found that upregulation of Sirt1 can be mediated by GSK3β [22,23]. Sirt1 activation reportedly improves mitochondrial function and reduces brain damage by increasing the level of PGC-1α [19,21]. PGC-1α is involved in cellular energy and plays a key role in regulating mitochondrial production and antioxidation [18,49]. Furthermore, Cordani et al. found that PGC-1α could reduce ROS production by regulating UCP2 levels and by protecting mitochondria from ROS-induced damage [50]. To further validate this possible underlying mechanism, we administered LRP6 siRNA and selisistat, a Sirt1 selective antagonist, concomitantly with HLY78 treatment. They reversed the HLY78 on downstream proteins, including   GSK3β, Sirt1, PGC-1α, cleaved caspase-3, and Romo-1. Thus, these observations suggest that the antioxidative and antiapoptotic effects of HLY78 were, at least in part, through the LRP6/GSK3β/Sirt1/PGC-1α signaling pathway.
The present study has several limitations. First, we applied LPR6 siRNA to knock down LRP6 in the brain in this study, and a transgenic animal model is needed to further validate our findings. Second, we focused only on the GSK3β/Sirt1/PGC-1α axis as the underlying mechanism of neuroprotection provided by HLY78 after ICH and could not exclude other molecular signaling pathways associated with the benefits of LRP6. Finally, gender and age differences were not assessed in this study.

Conclusion
In conclusion, the activation of LRP6 with HLY78 improved neurological deficits by attenuating oxidative stress and neuronal apoptosis after ICH. The antioxidative and antiapoptotic effects were, at least in part, through the GSK3β/Sirt1/ PGC-1α signaling pathway. Thus, LRP6 may serve as a novel therapeutic target to ameliorate SBI after ICH.

Data Availability
The data support the findings of this study and are available from the corresponding author upon reasonable request.

Ethical Approval
All experimental protocols and procedures were approved by the Ethics Committee of the Fudan University and in accordance with the National Institutes of Health guidelines.

16
Oxidative Medicine and Cellular Longevity