Adult male Sprague-Dawley rats (250-300 g) were bought from the Nanjing Biomedical Research Institute of Nanjing University. A prechiasmatic cistern injection models was built according to our previous study (13). Briefly, after anesthetization with avertin (200 mg/kg), rats were fixed in a stereotactic apparatus. The skin overlaying the anterior skull was opened, and a hole was drilled in the midline 7.5 mm anterior to the bregma. Blood (0.35 mL) from the femoral artery was injected through the hole over 20 s. Sham animals received the same procedure with injection of 0.35 ml of physiologic saline instead of blood.

In the first set of experiments, 48 rats (64 rats were used, 16 rats died) were divided into the following groups: SAH + vehicle (n= 15, 3 rats died), SAH+5 mg/kg EX527 (n= 16, 4 rats died), SAH + 10 mg/kg EX527 (n= 16, 4 rats died), SAH + 15 mg/kg EX527 (n= 17, 5 rats died) groups. Rats were killed at 24 h after SAH. Post-assessments included behavior performance, western blot, and histopathological study.

In the second set of experiments, a total of 142 rats (162 rats were used, 20 rats died) were randomly assigned into sham + vehicle (n= 28), SAH + vehicle (n= 34, 6 rats died), SAH + 50 mg/kg SRT1720 (n= 15, 3 rats died), SAH + 150 mg/kg SRT1720 (n= 32, 4 rats died), SAH + 250 mg/kg SRT1720 group (n= 14, 2 rats died), and SAH + 150 mg/kg SRT1720 + EX527 group (n=39, 5 rats died). Rats were killed at 24 h and 72 h after SAH. Post-assessments included neurological scores, western blotting, biochemical estimation, immunofluorescence staining, histopathological study, and brain water content analysis.

Primary neural cell culture was conducted from the cortex of neonatal rats according to previous studies (12, 30). For primary neurons culture, neuronal cells were cultured onto poly-D-lysine –coated plates and suspended in neurobasal media supplemented with B27, glutamate, Hepes, penicillin and streptomycin. For primary microglia culture, cortical cells were suspended in serum-free DMEM-F12 culture medium. The purity of primary microglia was more than 90% in our study ( Supplementary Figure 1 ). Regarding the neurons and microglia co-culture system, microglia were seeded in transwell upper chamber and the neurons were cultured in the plates. Co-culture medium was DMEM with 10% FBS. The co-culture system was harvested 24 h after indicated intervention.

For the in vitro SAH model, the co-culture system was stimulated with oxyhemoglobin (OxyHb, Bio Basic Inc., USA). The neuron-microglia co-cultures were divided into the following groups: control, OxyHb, OxyHb + SRT1720 (1, 5, and 10 μM), and OxyHb + SRT1720 + EX527. The culture medium and cells were collected for, ELISA, immunofluorescence staining, and cell viability analysis.

For in vivo, SRT1720 (Selleck) was prepared in 1% dimethyl sulfoxide (DMSO) in physiologic saline before use. SRT1720 or vehicle was administered intraperitoneally at 2 h after surgery and then once a day until euthanasia. EX527 (Sigma-Aldrich, St. Louis, MO, USA) was prepared in 1% (DMSO). EX527 or vehicle was administered intraperitoneally for 3 days before SAH construction. In vitro, SRT1720 was dissolved in culture medium. EX527 was dissolved in 1% DMSO (in physiologic saline) and then added to culture medium to reach a final concentration of 20 μM. The doses of SRT1720 and EX527 were selected according to previous studies (31–33).

As previously reported (18), primary neurons were incubated with 2,7-dichlorodihydrofluorescein diacetate (DCFH, Sigma) for 10 min at 37°C. DCFH fluorescence was measured under an inverted fluorescence microscope. The mean relative fluorescence intensity for each group was measured with the Image-Pro Plus system.

The lactate dehydrogenase (LDH) and Cell Counting Kit-8 (CCK-8) kits (Beyotime Biotechnology, China) were used to evaluate the viability of primary cultured neurons according to the manufacturer’s instructions.

Brain samples and culture medium were collected. The levels of IL-1β, tumor necrosis factor-α (TNF-α), IL-6, IL-18, ICAM-1, and CCL-2 were measured with ELISA kits according to the manufacturer instructions (Multi Sciences. China).

The levels of intracellular malondialdehyde (MDA), superoxide dismutase (SOD), and glutathione peroxidase (GSH-Px) were evaluated with commercially available kits (Nanjing Jiancheng Bioengineering Institute, Nanjing, China) in accordance with the manufacturer’s instructions.

Western blotting was performed according to our previous study (18). After sample preparation, equal amounts of protein samples were separated by polyacrylamide gel electrophoresis and transferred to a polyvinylidene difluoride membrane. The membrane was then incubated with primary antibodies against SIRT1 (1:200, cat# SC-15404, Santa Cruz), ac-FoxO1 (1:200, cat# sc-49437, Santa Cruz), NLRP3 (1:200, cat# SC-66846, Santa Cruz Biotechnology), adaptor apoptosis-related speck-like protein (ASC) (1:200, cat# SC-22514, Santa Cruz Biotechnology), caspase-1 (1:200, cat# SC-56036, Santa Cruz Biotechnology), caspase-1 p20 (1:200, cat# SC-398715, Santa Cruz Biotechnology), and β-actin (1:3000, cat# AP0060, Bioworld Technology, Minneapolis, MN, USA) overnight at 4°C. Subsequently, the membrane was incubated with horseradish peroxidase (HRP)-conjugated IgG for 2 h at room temperature. Protein bands were incubated with enhanced chemiluminescence solution (Thermo Fisher Scientific, Waltham, MA, USA). Band density was analyzed using Image J software.

Immunohistochemical staining was conducted as previously described (34). In brief, brain sections were fixed with 4% paraformaldehyde and embedded in paraffin. After being deparaffinized, the brain sections were incubated overnight at 4°C with primary antibodies against SIRT1 (1:50, Santa Cruz Biotechnology), NLRP3 (1:50, Santa Cruz Biotechnology), ASC (1:50, Santa Cruz Biotechnology), and caspase-1 p20 (1:50, Santa Cruz Biotechnology). After sections were washed with PBS, they were incubated with HRP-conjugated IgG for 60 min at room temperature. Slides were visualized by incubation with diaminobenzidine and hydrogen peroxide. Staining intensity was scored on a 0-to-4 scale system. In this system, 0 indicates no detectable positive cells and 4 indicates the highest density of positive cells.

Immunofluorescence staining was performed as previously described (34, 35). Briefly, brain sections (6 μm) were fixed with 4% paraformaldehyde. The sections were incubated overnight at 4°C with primary antibodies against Iba-1 (1:50, cat# SC-98468, Santa Cruz Biotechnology), NLRP3 (1:50, cat# SC-66846, Santa Cruz Biotechnology), caspase-1 p20 (1:50, cat# SC-398715, Santa Cruz Biotechnology) and NeuN (1:200, cat# MAB377, EMD Millipore, USA) followed by incubation with proper second antibodies. TUNEL staining was performed according to the manufacturer’s instructions (Roche Inc., Indianapolis, USA). Primary neurons were incubated with primary antibody against NeuN (1:200, cat# MAB377, EMD Millipore, USA) and caspase-1 p20 (1:50, cat# SC-398715, Santa Cruz Biotechnology) overnight at 4°C followed by incubation with proper second antibodies. The sections were visualized under a ZEISS HB050 inverted microscope system.

Nissl staining was conducted as previously described (34). In brief, coronal sections were immersed in cresol violet at 37°C for 20 minutes, and then then mounted onto microscope slides with Permount. Staining was visualized under a light microscope and normal neurons with round and palely stained nuclei were counted.

Neurologic functions were assessed using an 18-point scoring system reported by Sugawara et al (36). Rotarod test was used to assess motor deficits (30). The rotating speed was gradually increased from 4 to 40 rpm over a 5-min period. The latency to fall was recorded. The mean latency was calculated based on three consecutive trials.

All data were performed with GraphPad Prism 8.02 (GraphPad Software, La Jolla, CA, USA), and expressed as mean ± SD. Differences among multiple groups were compared by one-way analysis of variance with Bonferroni post hoc test. Statistical significance was inferred at P < 0.05. Linear regression was performed for correlational analysis. Values of P < 0.05 was considered statistically significant.

It has been demonstrated that EX527 is a potent and selective SIRT1 inhibitor. We used EX527 pretreatment to mimic SIRT1 knockout in this experiment. We first evaluated the effects of different doses of EX527 on SIRT1 expression. As shown, EX527 dose-dependently decreased SIRT1 expression after SAH (P < 0.05) ( Figures 1A, B ). In addition, EX527 pretreatment at 5, 10, and 15 mg/kg significantly aggravated neurological outcomes and motor functions after SAH (P < 0.05) ( Figures 1C, D ). However, there were no significant differences in SIRT1 expression and behavior functions between 10 mg/kg and 15 mg/kg EX527 treatment (P > 0.05) ( Figures 1A–D ). Thus, we chose 10 mg/kg EX527 for the remaining experiments. We then evaluated the effects of SIRT1 inhibition by EX527 on microglia polarization and NLRP3 inflammasome activation. Our data indicated that EX527 further induced M1 microglia (IBA1⁺/CD16/32⁺) polarization (P = 0.0084 for CD16/32 IOD, P = 0.0019 for CD16/32⁺IBA1⁺) and NLRP3 inflammasome activation (P = 0.0113 for NLRP3 IOD, P = 0.023 for NLRP3⁺IBA1⁺), with no statistical difference on M2 microglia (IBA1⁺/CD206⁺) transformation (P > 0.05) ( Figures 1E–M ).

SRT1720, a potent SIRT1 activator, was employed in our study. In a dose-response study, SRT1720 was administered to rats after SAH at 50, 150, and 250 mg/kg. Doses of 150 mg/kg and 250 mg/kg (P < 0.001, and P < 0.001, respectively), but not 50 mg/kg (P = 0.1126), markedly increased SIRT1 expression as compared with SAH + vehicle group ( Figure 2A ). Additionally, SRT1720 treatment at 150 and 250 mg/kg significantly improved neurologic scores (P = 0.0358, and P = 0.025, respectively) and rotarod performance (P > 0.05, and P = 0.0073, respectively), and ameliorated brain water content (P = 0.0103, and P = 0.0289, respectively) after SAH ( Figures 2B–D ). There were no significant differences between 150 and 250 mg/kg SRT1720 in SIRT1 expression (P > 0.05), neurological functions (P > 0.05) and brain edema (P > 0.05) ( Figures 2A–D ). Because 150 mg/kg was the optimum dose to provide maximal effect, we used this dose for the remaining experiments.

SIRT1 is implicated in a variety of pathophysiological processes, including immune response and redox stress. We first evaluated the effects of SRT1720 on SIRT1 signaling and the subsequent oxidative damage after SAH. Immunohistochemistry showed that the immunoreactivity of SIRT1 was significantly increased after SAH (P = 0.0148), which was further enhanced after SRT1720 supplementation (P = 0.0388) ( Figures 3A, B ). In contrast, EX527 abrogated the enhanced immunoreactivity of SIRT1 by SRT1720 (P < 0.001) ( Figures 3A, B ). Consistent with the immunohistochemistry data, western blot analysis showed that SRT1720 treatment significantly increased expression of SIRT1 (P = 0.0021) and decreased expression of acetyl-FoxO1 (P = 0.0026). These changes were all abated by EX527 pretreatment (P < 0.05) ( Figures 3C–E ). We then evaluated the effects of SRT1720 on oxidative damage after SAH. Double immunofluorescent staining indicated that SRT1720 treatment significantly reduced the 8-OHdG immunity when compared with SAH + vehicle group (P < 0.001) ( Figures 3F–H ). In addition, SRT1720 administration significantly decreased oxidative insults (P = 0.0055) and restored the impairment antioxidant systems after SAH, including SOD and GSH-px levels (P = 0.0019, and P < 0.001) ( Figures 3I–K ). However, EX527 pretreatment reversed the effects of SRT1720 on oxidative damage after SAH (P < 0.05) ( Figures 3F–H ).

It has been demonstrated that SIRT1 is implicated in the modulation of immune response and could reduce neuroinflammation in a variety of neurological disorders. We then evaluated the effects of SRT1720 on inflammatory response after SAH. As shown, SAH significantly increased IL-1β, IL-6, TNF-α, IL-18, ICAM-1, and CCL-2 (P < 0.001) protein levels in the cortex when compared with the sham + vehicle group. SRT1720 treatment markedly reduced these proinflammatory cytokines after SAH (P = 0.0172, P < 0.001, P = 0.0239, P< 0.001, P = 0.0166, and P < 0.001, respectively) ( Figures 4A–F ). However, all these changes were abrogated by EX527 pretreatment (P < 0.05) ( Figures 4A–F ).

It has been shown that SIRT1 can modulate the microglia polarization shift from the M1 phenotype and skew toward the M2 phenotype in a variety of disorders. We next evaluated the effects of SIRT1 activation by SRT1720 on M1/M2 microglia polarization following SAH. As shown, the proportion of M1 microglia (IBA1⁺/CD16/32⁺) was significantly increased after SAH as compared with sham group (P < 0.001), while treatment with SRT1720 decreased the amount of M1 microglia (P < 0.001). Additionally, SRT1720 markedly increased the quantity of M2 microglia (IBA1⁺/CD206⁺) after SAH when compared with SAH + vehicle group (P < 0.001) ( Figures 5A–F ). However, EX527 pretreatment reversed the effects of SRT1720 on M1/M2 microglia polarization after SAH (P < 0.001) ( Figures 5A–F ).

To understand the cellular mechanisms of microglia polarization by SIRT1, we measured NLRP3 inflammasome signaling after SAH. As shown in Figure 6 , western blot data showed that SAH insults significantly increased the levels of NLRP3, ASC, and cleaved caspase1 (P < 0.001) when compared with sham + vehicle group ( Figures 6A–E ). SRT1720 treatment markedly decreased the levels of NLRP3 (P < 0.001), ASC (P < 0.001), and cleaved caspase1 (P = 0.002) after SAH, all of which were evidently abated by EX527 pretreatment (P < 0.05) ( Figures 6A–E ). Double immunofluorescent staining confirmed that SRT720 treatment significantly reduced the expression of NLRP3 in microglia when compared with SAH + vehicle group (P < 0.001) ( Figures 6F–H ). Meanwhile, immunohistochemistry showed that the immunoreactivities of NLRP3 (P = 0.0057), ASC (P = 0.0065), and cleaved-caspase-1 (P = 0.0198) were significantly increased after SAH, which could be inhibited after SRT1720 supplementation (P = 0.0412, P = 0.0239, P = 0.0425, respectively) ( Figures 6I–L ). However, all these changes were prevented by EX527 pretreatment (P < 0.05) ( Figures 6F–L ). We also performed correlational studies to verify the relationship between SIRT1, NLRP3 inflammasome, and microglia polarization. Our data showed that SIRT1 activation correlated negatively with ROS overproduction (P = 0.0127), NLRP3 inflammasome (P = 0.0355), and the number of M1 microglia (P = 0.0224) ( Supplementary Figure 2A–C ). In contrast, the number of M2 microglia correlated positively with SIRT1 expression (P = 0.0341) ( Supplementary Figure 2D ). These data supported that SIRT1 was also involved in the modulation of microglia polarization after SAH.

Accumulating evidence indicated that both apoptosis and pyroptosis contribute to the EBI after SAH. Unlike apoptosis, pyroptosis is biochemically characterized as caspase-1 dependent and caspase-3 independent. Notably, suppression of NLPR3 inflammasome or caspase-1 reduces neuronal apoptosis and pyroptosis, and improves neurological outcomes in SAH models. We further explored the effects of SRT1720 on neuronal death and functional outcomes after SAH. As shown, the immunofluorescence staining results showed that there was a low level of caspase-1- and TUNEL-positive neurons in the sham group, which were dramatically increased after SAH (P = 0.001, and P < 0.001, respectively) ( Figures 7A–D ). In contrast, SRT1720 administration could significantly reduce the number of caspase-1- and TUNEL-positive neurons after SAH (P = 0.0126, and P < 0.001, respectively) ( Figures 7A–D ). Concomitant with the reduced neurodegeneration, SRT1720 treatment evidently improved neurological outcomes (P < 0.05) and rotarod performance (P < 0.05) after SAH ( Figures 7E, F ). In addition, Nissl staining showed that SRT1720 treatment significantly improved neuronal survival at 72h after SAH (P < 0.001) ( Figures 7G, H ). However, all these changes were abated by EX527 pretreatment (P < 0.05) ( Figures 7A–H ). These indirectly suggested that SRT1720 inhibited NLRP3 inflammasome-mediated neuronal death probably through SIRT1-dependent pathway.

To confirm the proposed crosstalk between microglial and neuronal cells, a transwell co-culture system was established in vitro. We first evaluated whether SRT1720 had beneficial effects in vitro SAH model. As shown, primary neurons and microglia stimulated with OxyHb induced a marked decrease in neuronal viability (P < 0.05), and increase in ROS generation (P < 0.001) and proinflammatory cytokines including IL-1β (P < 0.001) and IL-6 (P < 0.001), all of which were reversed by SRT1720 treatment (P < 0.05) ( Figures 8A–F ). In contrast, EX527 abrogated the beneficial effects of SRT1720 on oxidative stress, inflammatory response, and neuronal damage (P < 0.05) ( Figures 8A–F ). Consistent with the in vivo results, our findings indicated that SRT1720 could exert a cerebroprotective action against SAH damage in vitro.

To further explore the mechanisms of action of SRT1720 in vitro SAH model, we examined the possible effects of SRT1720 on SIRT1 and NLRP3 expression in neuron-microglia co-cultures by using double immunofluorescence staining. At the cellular level, SIRT1 is known as a nuclear protein, which is predominantly expressed in neurons. NLRP3 inflammasome is mainly expressed in microglia and the basal level of the NLRP3 inflammasome is low under physiological conditions. Consistent with previous studies, our immunofluorescence staining data indicated that SIRT1 was weakly expressed in primary neurons and the immunoreactivity of NLRP3 was low in primary microglia in the control group. OxyHb stimulation induced the expression of SIRT1 (P = 0.0397) and NLRP3 (P < 0.001) in the co-culture system. SRT1720 treatment could significantly enhance the expression of SIRT1 (P < 0.001) in primary cortical neurons and decrease NLRP3 expression (P = 0.002) in primary microglia, which could be abrogated by EX527 administration (P < 0.05) ( Figures 9A–D ). These data consistent with the results in vivo suggesting that SIRT1 could modulate NLRP3 inflammasome activation and SRT1720 treatment was able to activate SIRT1 and inhibit NLRP3 inflammasome signaling.

Both neuronal apoptosis and pyroptosis are involved in the pathophysiology of EBI after SAH. Since PI cannot pass intact plasma membrane and can only be present in DNA of cells where the plasma membrane has been injured. During pyroptosis, pores can be formed in the cell membrane and can be detected by PI staining [26]. Therefore, PI staining is widely used as a detection for neuronal pyroptosis. In our study, we performed PI and TUNEL staining to examine neuronal pyroptosis and apoptosis, respectively. Based on the data in vivo, we speculated that SIRT1 activation by SRT1720 could reduce neuronal apoptosis and pyroptosis in vitro. As shown, double immunofluorescence staining showed that PI- (P < 0.001) and TUNEL-positive (P < 0.001) neurons were significantly increased after OxyHb incubation, which could be decreased by SRT1720 administration (P = 0.0011, and P = 0.013, respectively) ( Figures 10A–D ). These confirmed that SRT1720 was able to reduce neuronal pyroptosis and apoptosis after SAH in vitro. In contrast, EX527 abated the protective effects of SRT1720 on neuronal cell death in vitro (P < 0.05) ( Figures 10A–D ). These findings indirectly indicated that SIRT1 activation by SRT1720 probably inhibited NLRP3 inflammasome-mediated pyroptosis and apoptosis.