Research Paper Volume 13, Issue 3 pp 4079—4095
Microglia exosomal miRNA-137 attenuates ischemic brain injury through targeting Notch1
- 1 Department of Rehabilitation Medicine, Shenzhen Longhua District Central Hospital, Shenzhen, China
- 2 Postdoctoral Research Workstation of Harbin Sport University, Harbin 150008, China
- 3 Harbin Sport University, Harbin 150008, China
- 4 Hanan Branch of Second Affiliated Hospital of Heilongjiang University of Traditional Chinese Medicine, Harbin 150001, China
- 5 Second Affiliated Hospital of Heilongjiang University of Traditional Chinese Medicine, Harbin 150001, China
- 6 Heilongjiang University of Traditional Chinese Medicine, Harbin, China
- 7 Postdoctoral Research Station of Heilongjiang Academy of Traditional Chinese Medicine, Harbin, China
Received: April 21, 2020 Accepted: September 28, 2020 Published: January 10, 2021
https://doi.org/10.18632/aging.202373How to Cite
Copyright: © 2021 Zhang et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Abstract
Microglia are the resident immune cells in the central nervous system and play an essential role in brain homeostasis and neuroprotection in brain diseases. Exosomes are crucial in intercellular communication by transporting bioactive miRNAs. Thus, this study aimed to investigate the function of microglial exosome in the presence of ischemic injury and related mechanism. Oxygen-glucose deprivation (OGD)-treated neurons and transient middle cerebral artery occlusion (TMCAO)-treated mice were applied in this study. Western blotting, RT-PCR, RNA-seq, luciferase reporter assay, transmission electron microscope, nanoparticle tracking analysis, immunohistochemistry, TUNEL and LDH assays, and behavioral assay were applied in mechanistic and functional studies. The results demonstrated that exosomes derived from microglia in M2 phenotype (BV2-Exo) were internalized by neurons and attenuated neuronal apoptosis in response to ischemic injury in vitro and in vivo. BV2-Exo also decreased infarct volume and behavioral deficits in ischemic mice. Exosomal miRNA-137 was upregulated in BV2-Exo and participated in the partial neuroprotective effect of BV2-Exo. Furthermore, Notch1 was a directly targeting gene of exosomal miRNA-137. In conclusion, these results suggest that BV2-Exo alleviates ischemia-reperfusion brain injury through transporting exosomal miRNA-137. This study provides novel insight into microglial exosomes-based therapies for the treatment of ischemic brain injury.
Introduction
Microglia are the resident immune cells in the central nervous system (CNS) and play an essential role in brain homeostasis and host defense against pathogens [1]. Over the past decades, microglia have received increasing scientific interest due to their essential roles in CNS health and diseases [2, 3]. In the healthy brain, the diverse functions of microglia have been demonstrated in many previous studies, from shaping learning-related plasticity to guiding the development of neuronal circuits [2, 3]. Meanwhile, growing evidence shows that microglia are involved in many CNS diseases, for example, traumatic brain injury such as spinal cord lesions, neurogenerative disorders such as Parkinson’s diseases, and psychiatric diseases such as schizophrenia [4]. Therefore, understanding the physiological roles of microglia is critical to apply their functions in the therapies for brain diseases.
Ischemia-reperfusion injury (IRI) occurring in the brain results in irreversible loss of neurons and traumatic tissue damage in the IRI-targeted and surrounding areas [5]. Following IRI, a group of detrimental biological factors significantly emerge in the CNS, including excitatory neurotransmitters, excess ion influx, generation of free radicals, as well as inflammatory factors [6–8]. Inflammatory responses in the brain are tightly involved in the activation of microglia. Activated microglia, named M1 phenotype, secrete a mass of pro-inflammatory cytokines that exacerbating neuronal damage [6, 7]. However, other studies have reported that activated microglia, named M2 phenotype, can exert neuroprotective roles through enhancing neural proliferation and differentiation, leading to resolution of inflammation and tissue repair [7–9]. Kigerl et al. reported that microglia in M2 state promote CNS repair and attenuate secondary inflammatory-associated injury [10]. Essentially, studying the mechanism underlying the neuroprotective effect of microglia would be beneficial to develop effective treatments for IRI injury.
Exosomes, 40-100 nm in diameter, are small extracellular vesicles generated from various types of cells, including neurons, cancer cells, epithelial cells, and chondrocytes [11]. Previous studies have suggested that various bioactive components, such as lipids, proteins, mRNAs, microRNAs (miRNAs), and other non-coding RNAs (ncRNAs), have been identified in the lumen of exosomes [12]. Furthermore, these biological components can be taken up by neighboring or distant cells, then regulating the physiology of recipient cells [13]. Given such characteristics, exosomes play crucial roles in intercellular communication [13]. Regarding microglial exosomes, a study conducted by Huang et al. reported that the traumatic brain injury (TBI)-induced upregulation of exosomal miRNA-124-3p derived from microglia exerts an inhibitory effect on neuronal inflammation and promotes the neurogenesis [14]. In another study reported by Ge et al., the elevation of microglial exosomal miRNA-124-3p improves cognitive ability and alleviates neurodegeneration resulted from repetitive mild traumatic brain injury (rmTBI) [15]. Furthermore, microglial exosomes attenuate photoreceptor injury and promote angiogenesis in the animal model of retinopathy of prematurity [16]. As such, microglial exosomes have great potential for developing therapeutic strategies for brain diseases.
As mentioned above, miRNAs can be transported by exosomes between cells and play essential roles in the regulation of cellular biology [17]. MiRNAs, a class of short non-coding RNAs, can modulate gene expression through targeting 3’UTR of mRNA or promoting the degradation of mRNA [18]. It has been well-studied that miRNAs participate in various physiological and pathological processes, such as cell proliferation, autophagy, apoptosis, differentiation, tumor cell migration, and cell metabolism [18–20]. Meanwhile, the roles of exosomal miRNAs also have been reported in many diseases. For example, Vinas et al. demonstrated that exosomal miRNA-486-5p derived from human endothelial colony forming cell inhibits apoptosis of endothelial cells and attenuates ischemic injury in the kidney [21]. Also, exosomes derived from cardiac progenitor cells suppress cardiomyocyte apoptosis through exosomal miRNA-21 under oxidative stress [22]. Exosomal miRNA-25 originated from bone marrow mesenchymal stem cells can decrease malondialdehyde content and increase superoxide dismutase activity, thus protecting spinal cords in response to transient ischemia [23].
Collectively, given these previous findings, we hypothesize that microglial exosomal miRNAs might play neuroprotective effects in the mouse brain under ischemic injury. Thus, this study aimed to address our hypothesis and related mechanisms.
Results
BV2-CM attenuated OGD-induced neuronal death
Microglia in M2 phenotype play a crucial neuroprotective role in several brain diseases, such as cerebral ischemia [24] and Parkinson's disease [25]. To detmine the mechanism underlying the neuroprotective effect of microglia, BV2 cells were treated with IL-4 (20 ng/mL) to polarized to M2 phenotype [7, 26]. The results showed that both mRNA and protein expressions of CD206 and ARG, M2 microglia markers [27], were upregulated, compared with control BV2 cells (Figure 1A, 1B). In addition, we found that M2 BV2 cells-conditioned medium (BV2-CM) decreased apoptosis in neurons in the presence of OGD treatment (Figure 1C). In LDH assay, BV2-CM decreased LDH activity, indicating less cellular injury was detected in neurons after OGD treatment (Figure 1D). Intriguingly, we also observed that the addition of GW4869, an inhibitor of exosome secretion [28], partially reversed the effect of BV2-CM on OGD-treated neurons (Figure 1C, 1D). These results together suggested that BV2-derived exosomes may participate in a neuroprotective mechanism in response to OGD.
Figure 1. M2-phenotype microglia-conditioned medium attenuated oxygen-glucose deprivation (OGD)-induced neuronal death. (A) mRNA expressions of CD206 and ARG in BV2 cells treated with or without IL-4 treatment. (B) Protein expressions of CD206 and ARG in BV2 cells treated with or without IL-4 treatment. (C) TUNEL assay for detecting apoptosis in neurons in 1) control, 2) OGD, 3) OGD plus M2-phenotype microglia-conditioned medium (OGD+BV2-CM), and 4) OGD plus M2-phenotype microglia-conditioned medium plus exosome secretion inhibitor GW4869 (OGD+BV2-CM+GW4869). Scale bar = 20 μm. (D) Lactate dehydrogenase (LDH) assay for detecting LDH activity in neurons in 1) control, 2) OGD, 3) OGD+BV2-CM, and 4) OGD+BV2-CM+GW4869. Data are presented as mean±SD. *, p<0.05. At least three replicates were available for statistical analysis in each treatment.
BV2-Exo identification
Next, we isolated exosomes from BV2 cells in M2 phenotype through the ultracentrifugation procedure. By TEM, the morphology of exosomes displayed classic spherical shape (Figure 2A), and nanoparticle tracking analysis revealed that the size of exosomes was in the range of 40-130 nm (Figure 2B). Also, Western blotting assay suggested that the exosome markers CD63 and Tsg101 were positively expressed in the exosomes, compared with those of BV2 cells (Figure 2C). Collectively, these results indicated that we successfully isolated exosomes from BV2 cells in M2 phenotype.
Figure 2. Identification of M2-phenotype microglia-derived exosomes (BV2-Exo). (A) Morphology of BV2-Exo, as determined by transmission electron microscopy. Scale bar = 500 nm (left panel) and 100 nm (right panel). (B) Size distribution of exosomes, as determined by nanoparticle tracking analysis. (C) Expression of exosome markers CD63 and Tsg101 in BV2-Exo and BV2 cells. Data are presented as mean±SD. *, p<0.05. At least three replicates were available for statistical analysis in each treatment.
BV2-Exo attenuated neuronal apoptosis induced by OGD
Then, we aimed to determine whether BV2-Exo could be internalized by neurons. BV2-Exo was cocultured with neurons, and the confocal images revealed that PKH26-labeled red BV2-Exo were found in the cytoplasm of MAP2-positive neurons labeled with green fluorescence (Figure 3A). CCK-8 and LDH assays suggested that BV2-Exo significantly increased cell viability of neurons cocultured with BV2-Exo for 24 hours, followed by OGD (Figure 3B, 3D). Apoptosis of neurons induced by OGD was also attenuated by BV2-Exo, as detected by TUNEL staining (Figure 3C). Furthermore, in vivo study, we found that BV2-Exo could also be taken up by neurons of the ischemic mouse brain (Figure 3E). Applying neurobehavioral testing to evaluate neurobehavioral performance in mice treated BV2-Exo, the results showed that BV2-Exo treatment attenuated behavioral deficits induced by tMCAO, compared with those treated with PBS control treatment (Figure 3F). We also observed that the mice treated with BV2-Exo after tMCAO had less infarct area and apoptosis than those in the control group (Figure 3G, 3H). Together, our observations demonstrated that BV2-Exo plays a neuroprotective role in neuronal injury induced by ischemic injury in both in vitro and in vivo.
Figure 3. M2-phenotype microglia-derived exosomes (BV2-Exo) attenuated neuronal apoptosis induced by ischemic injury. (A) BV2-Exo was internalized by neurons in vitro, as imaged by confocal microscopy. Red color indicated exosomes (PKH26), blue color indicated nuclei (DAPI), and green color indicated neurons (MAP2). Scale bar = 25 μm. (B) Cell viability of neurons treated with OGD or OGD plus BV2-Exo, as determined by CCK-8 assay. (C) TUNEL assay for detecting apoptosis in neurons treated with OGD or OGD plus BV2-Exo. Scale bar = 20 μm. (D) Lactate dehydrogenase (LDH) assay for detecting LDH activity in neurons treated with OGD or OGD plus BV2-Exo. (E) BV2-Exo was internalized by neurons in vivo, as imaged by confocal microscopy. Red color indicated exosomes (PKH26), blue color indicated nuclei (DAPI), and green color indicated neurons (MAP2). Scale bar = 25 μm. (F) Modified neurological severity score for mice treated with control treatment (PBS) and BV2-Exo after tMCAO. (G) Relative infarct volume in brains of mice treated with control treatment (PBS) and BV2-Exo after tMCAO, displayed as brain cresyl violet staining and brain tissues of ischemic mice treated with indicated treatments. Yellow dotted boxes represent the infarct areas. (H) Double-staining of NeuN/TUNEL in brain sections of mice treated with control treatment (PBS) and BV2-Exo after tMCAO. Red color indicated NeuN and green color indicated TUNEL staining. Scale bar = 25 μm. Data are presented as mean±SD. *, p<0.05. At least three replicates were available for statistical analysis in each treatment.
MiRNA-137 was associated with the neuroprotective effect of BV2-Exo
Exosomal miRNAs have been demonstrated as critical functional factors in exosome-mediated intercellular communication [29]. Thus, we speculated that miRNAs might play an essential role in the neuroprotective effect of BV2-Exo. By performing RNA-seq, we identified a group of differentially expressed miRNAs between BV2-Exo and BV2 Exo-CN, as shown in heatmap and volcano plot (Figure 4A, 4B). The results revealed that miRNA-137 was one of the upregulated miRNAs. Given the essential role of miRNA-137 in IRI reported by multiple previous studies [30–32], we hypothesized that miRNA-137 might be an essential mediator for the function of BV2-Exo. Then, we applied RT-PCR assay to verify the results obtained from RNA-seq analysis, and we found that miRNA-137 was also increased in BV2-Exo, relative to BV2 Exo-CN (Figure 4C). Meanwhile, the expression of miRNA-137 was decreased in BV2-Exo derived from BV2 cells treated with miRNA-137-IN (Figure 4C). After OGD treatment, the level of miRNA-137 was increased in neurons treated with BV2-Exo, whereas decreased in those treated with BV2-Exo derived from BV2 cells treated with miRNA-137-IN (Figure 4D). Thus, these results suggested the involvement of miRNA-137 in BV2-Exo-related neuroprotection.
Figure 4. MiRNA-137 was upregulated in M2-phenotype microglia-derived exosomes (BV2-Exo). (A, B). Heatmap and volcano plot of expression profiles for differentially expressed miRNAs between BV2-Exo and exosomes derived from control BV2 cells (BV2 Exo-CN), as determined by RNA-seq analysis. (C) Expression of miRNA-137 in 1) BV2 Exo-CN, 2) BV2-Exo, 3) BV2-Exo derive from BV2 cells treated with miRNA-137 inhibitor (BV2-Exo+miRNA-137-IN), and 4) BV2-Exo derive from BV2 cells treated with miRNA-137 inhibitor negative control (BV2-Exo+miRNA-137-NC), as detected by RT-PCR. (D) Expression of miRNA-137 in neurons treated with 1) control, 2) OGD, 3) OGD plus BV2-Exo, 4) OGD plus BV2-Exo+miRNA-137-IN, and 5) OGD plus BV2-Exo+miRNA-137-NC, as detected by RT-PCR. Data are presented as mean±SD. *, p<0.05. At least three replicates were available for statistical analysis in each treatment.
BV2-Exo attenuated neuronal apoptosis induced OGD through miRNA-137
To further determine the function of miRNA-137, we found that the expression of cleaved caspase-3 was significantly decreased in BV2-Exo-treated neurons after OGD, while partially rescued by treatment of BV2-Exo derived from BV2 cells treated with miRNA-137-IN (Figure 5A). For LDH assay, LDH activity was increased by OGD treatment, which was reversed by BV2-Exo and BV2-Exo derived from BV2 cells treated with miRNA-137-IN with different degrees (Figure 5B). Notably, we did not observe the different effects of these treatments on LDH activity in neurons under normal conditions (Figure 5C). Furthermore, TUNEL assay revealed that BV2-Exo with reduced expression of miRNA-137 could also partially reverse the effect of BV2-Exo on apoptosis after OGD (Figure 5D). Together, these results suggested that miRNA-137 participates in, at least in part, the neuroprotective effect of BV2-Exo.
Figure 5. M2-phenotype microglia-derived exosomes (BV2-Exo) attenuated neuronal apoptosis induced oxygen-glucose deprivation (OGD) through miRNA-137. (A) Protein expressions of caspase-3 and cleaved caspase-3 in neurons treated with 1) control, 2) OGD, 3) OGD plus BV2-Exo, 4) OGD plus BV2-Exo+miRNA-137-IN, and 5) OGD plus BV2-Exo+miRNA-137-NC, as detected by Western blotting assay. (B) Lactate dehydrogenase (LDH) assay for detecting LDH activity in neurons treated with 1) control, 2) OGD, 3) OGD plus BV2-Exo, 4) OGD plus BV2-Exo+miRNA-137-IN, and 5) OGD plus BV2-Exo+miRNA-137-NC. (C) LDH assay for detecting LDH activity in neurons treated with 1) control, 2) BV2-Exo, 3) BV2-Exo plus BV2-Exo+miRNA-137-IN, and 4) BV2-Exo plus BV2-Exo+miRNA-137-NC. (D) TUNEL assay for detecting apoptosis in neurons treated with 1) control, 2) OGD, 3) OGD plus BV2-Exo, 4) OGD plus BV2-Exo+miRNA-137-IN, and 5) OGD plus BV2-Exo+miRNA-137-NC. Data are presented as mean±SD. *, p<0.05. At least three replicates were available for statistical analysis in each treatment.
MiRNA-137 mediated the function of BV2-Exo through targeting Notch1
To determine the downstream targeting gene of miRNA-137, we performed bioinformatics analysis in several databases, including MiRanda (MicroRNA.org)) and TargetScan (http://www.targetscan.org). The results showed that there was a potential binding site of miRNA-137 in 3’UTR of Notch1 (Figure 6A). Through performing luciferase reporter assay, the results showed that the luciferase activity was decreased in 293T cells co-transfected with miRNA-137 mimics and luciferase reporter plasmids containing wild-type miRNA-137 binding site, compared with those treated with plasmids containing mutant miRNA-137 binding site (Figure 6B). Also, we found that BV2-Exo significantly decreased mRNA expression of Notch1, which was partially reversed by inhibition of miRNA-137 expression in BV2-Exo (Figure 6C). To further investigate the function of Notch1 in the ischemic mouse model, BV2-Exo, BV2-Exo with reduced expression of miRNA-137, and BV2-Exo with reduced expression of miRNA-137 plus Cren (a selective inhibitor of Notch1) were administrated to ischemic mice, respectively. The results demonstrated that protein expression of Notch1 was decreased in the brains of mice treated with BV2-Exo and BV2-Exo with reduced expression of miRNA-137 plus Cren, while increased in mice treated with BV2-Exo with reduced expression of miRNA-137 (Figure 7A). Functionally, decreased expression of Notch1 induced by BV2-Exo was associated with decreased neurobehavioral deficits, fewer infarct areas in the brain, and less apoptosis (Figure 7B–7D). In contrast, the elevation of Notch1 induced by the downregulation of miRNA-137 led to more severe behavioral deficits, more infarct areas, and more apoptosis (Figure 7B–7D). We also noticed that the effect of increased Notch1 was reversed by Notch1 inhibitor Cren. Furthermore, the expression of cleaved caspase-3 was decreased in mice treated with BV2-Exo and BV2-Exo with reduced expression of miRNA-137 plus Cren while increased in mice treated with BV2-Exo with reduced expression of miRNA-137, compared with those in the control group (Figure 7E). Collectively, these findings suggested that neuroprotective role of BV2-Exo was mediated through miRNA-137/Notch1 pathway.
Figure 6. MiRNA-137 directly targeted Notch1. (A) Putative binding site in 3’UTR of Notch1, as predicted by bioinformatics software. (B) Luciferase reporter assay of miRNA-137 targeting on 3’UTR of Notch1. (C) mRNA expression of Notch1 in neurons treated with 1) control, 2) OGD, 3) OGD plus BV2-Exo, 4) OGD plus BV2-Exo+miRNA-137-IN, and 5) OGD plus BV2-Exo+miRNA-137-NC, as detected by RT-PCR. Data are presented as mean±SD. *, p<0.05. At least three replicates were available for statistical analysis in each treatment.
Figure 7. M2-phenotype microglia-derived exosomes (BV2-Exo) attenuated tMCAO-induced neuronal apoptosis through Notch1. (A) Protein expression of Notch1 in brains of mice treated with 1) control, 2) tMCAO plus BV2-Exo, 3) tMCAO plus BV2-Exo+miRNA-137-IN, 4) tMCAO plus BV2-Exo+miRNA-137-IN and Crenigacestat, and 5) tMCAO plus BV2-Exo+miRNA-137-NC, as detected by Western blotting assay. (B) Modified neurological severity score for mice treated with 1) control, 2) tMCAO plus BV2-Exo, 3) tMCAO plus BV2-Exo+miRNA-137-IN, 4) tMCAO plus BV2-Exo+miRNA-137-IN and Crenigacestat, and 5) tMCAO plus BV2-Exo+miRNA-137-NC. (C) Relative infarct volume in brains of mice treated with 1) control, 2) tMCAO plus BV2-Exo, 3) tMCAO plus BV2-Exo+miRNA-137-IN, 4) tMCAO plus BV2-Exo+miRNA-137-IN and Crenigacestat, and 5) tMCAO plus BV2-Exo+miRNA-137-NC, displayed as brain cresyl violet staining and brain tissues of ischemic mice treated with indicated treatments. Yellow dotted boxes represent the infarct areas. (D) Double-staining of NeuN/TUNEL in brain sections of mice treated with 1) control, 2) tMCAO plus BV2-Exo, 3) tMCAO plus BV2-Exo+miRNA-137-IN, 4) tMCAO plus BV2-Exo+miRNA-137-IN and Crenigacestat, and 5) tMCAO plus BV2-Exo+miRNA-137-NC. Red color indicated NeuN and green color indicated TUNEL staining. Scale bar = 25 μm. (E) Protein expression of caspase-3 and cleaved caspase-3 in brains of mice treated with 1) control, 2) tMCAO plus BV2-Exo, 3) tMCAO plus BV2-Exo+miRNA-137-IN, 4) tMCAO plus BV2-Exo+miRNA-137-IN and Crenigacestat, and 5) tMCAO plus BV2-Exo+miRNA-137-NC, as detected by Western blotting assay. Data are presented as mean±SD. *, p<0.05. At least three replicates were available for statistical analysis in each treatment.
Discussion
Microglial colonize the CNS and play essential roles in brain development and maintaining the function of CNS [33], primarily including 1) the housekeeping function for maintaining neuronal health and normal physiological function; 2) the sentinel function for the constant perception of environmental changes; as well as 3) defensive function required for neuroprotection [2, 3]. It has been demonstrated that microglial dominate sites of CNS injury in which they promote both injury and repair [34]. Distinct microglial subsets may cause these different effects, i.e., “classically activated” pro-inflammatory (M1) or “alternatively activated” anti-inflammatory (M2) cells [7, 35]. Accumulating evidence shows that microglia in M2 phenotype display notable neuroprotective effect in many brain diseases, such as cerebral ischemia [24], intracerebral hemorrhage [36], and Parkinson's disease [25]. As such, investigating the mechanism underlying the neuroprotective effect of M2-phenotype microglia would make a significant contribution to the treatment of brain injuries and diseases. In this study, we reported that exosomes secreted by microglia BV2 cells in M2 phenotype were internalized by neurons that were subjected to ischemic injury, thereby promoting the survival of ischemic neurons through exosomal miRNA-137 via Notch1 pathway.
Over the last decade, numerous studies demonstrate that the effect of exosomes in intercellular communication constitutes an essential mechanism for local and systematic intercellular transportation of bioactive cargos, such as proteins, DNA, mRNAs, long noncoding RNAs (lncRNAs), and miRNAs, which can significantly regulate the physiological processes in the recipient cells [37, 38]. Given these critical roles, exosome-mediated therapeutic strategies have received growing attention and applied in many diseases studies, including cancers [39], cardiovascular diseases [40, 41], and metabolic disease [42]. Meanwhile, microglia-derived exosomes also display essential roles in the development and progression of CNS diseases [43]. For example, Chang et al. reported that alpha-synuclein-induced exosomes express higher levels of major histocompatibility complex (MHC) class II molecules and membrane tumor necrosis factor alpha (TNF-alpha) and promote neuron apoptosis, suggesting that microglial exosomes might be critical mediators for neurodegeneration in Parkinson's disease [44]. A recent study reported by Li et al. suggested that TBI-induced increase of miRNA-124-3p in microglial exosomes suppresses neuronal autophagy, thereby proecting injured nerve [45]. In addition, exosomes generated from lipopolysaccharide (LPS)-activated microglia promote neuron apoptosis, which can reversed by the knockdown of TNF-inducible protein 3 (TNFAIP3) [45]. In the present study, we observed that M2-phenotype BV2 cell-conditioned medium could reduce neuronal death and apoptosis following OGD, in which BV2-Exo is an essential factor mediating the neuroprotective role of BV2 cell-conditioned medium. Together, microglial exosomes exert critical role in the neuroprotection in the CNS diseases, including ischemic injury.
It has been well documented that miRNAs are tightly involved in the regulation of diverse physiological and pathological processes [46, 47]. For ischemic brain injury, the crucial neuroprotective roles of miRNAs have uncovered in many previous studies. For instance, miRNA-21 and miRNA29b are unregulated in neurons, whereas miRNA-30b, miRNA-137, and miRNA-107 are downregulated in astrocytes in the presence of OGC treatment, suggesting the distinct role of each miRNA in different types of neural cells under ischemic condition [48]. Zhao et al. demonstrated that miRNA-23a-3p attenuates ischemic injury in mice treated with focal cerebral ischemia-reperfusion, which associated with an upregulated level of superoxide dismutase and reduced production of reactive nitrogen species [49]. Furthermore, Stary et al. reported that the inhibition of miRNA-200c leads to a significant reduction in infarct volume and neurological deficit through targeting reelin, indicating miRNA-200c is a potential biological target for mitigating injury induced by transient cerebral ischemia [50]. In the present study, RNA-seq and RT-PCR analysis revealed that miRNA-137 was upregulated in BV2-Exo, relative to BV2-Exo-CN. Furthermore, the knockdown of miRNA-137 could partially reverse the neuroprotective effect of BV2-Exo. Collectively, these results indicate the involvement of miRNA-137 in the role of microglial exosomes. MiRNA-137 is abundantly expressed in the CNS and participates in the regulation of neuron maturation and differentiation [30, 31]. Li et al. demonstrated that miRNA-137 is a hypoxia-responsive miRNA to inhibit mitophagy through targeting mitophagy receptors NIX and FUNDC1 [32]. In addition, miRNA-137 exerts an inhibitory effect on anesthesia-induced neurodegeneration and memory loss in the hippocampus through silencing CDC42 [51]. Taken together, these results indicate that miRNA-137 is an essential miRNA to modulate protective responses in the brain.
To further investigate the mechanism in which microglia exosomal miRNA-317 plays a neuroprotective role in response to ischemic injury, we applied bioinformatics analysis and luciferase reporter assay to determine the downstream targeting gene of exosomal miRNA-317. Our results revealed that Notch1 was a direct target of miRNA-137 and that BV2-Exo derived from miRNA-137-knockdown BV2 cells plus Notch1 inhibitor Crenigacestat exerts a similar neuroprotective role as BV2-Exo alone. Our observations are consistent with a previous study reporting that miRNA-137 protects neurons from OGD-induced injury via targeting Notch1 signaling pathway [52]. It has been demonstrated that Notch signaling pathway plays a critical role in ischemia-associated injury in various physiological systems, such as the kidney [53] and heart [54]. In the CNS, the upregulation of miRNA-210 is associated with angiogenesis in ischemic brain cortexes of adult rats through the involvement of Notch1 signaling [55]. LncRNA GAS5 promotes mouse ischemic stroke through acting as a competing endogenous RNA (ceRNA) for miRNA-137 to regulate Notch1 signaling [56]. Also, Li et al. reported the importance of miRNA-137/Notch1 pathway in hypoxia-associated retinal injury [57]. Notably, to the best of our best knowledge, we first reported that Notch1 acts as a downstream target of exosomal miRNA in ischemic injured neurons, suggesting that Notch signaling is also essential for intercellular communication between injured cells and the surrounding microenvironment. These observations might also provide a potential target for developing treatments for ischemic injury in the brain.
With regard to the limits of this study, the first should be addressed is the cell line used in our study. Although BV2 cells are an immortalized neonatal mouse microglia cells, which is a universal surrogate of primary microglia in vitro experiments [58], BV2 cells have a different gene expression profile than primary microglia and differentially behave in response to stimuli [59]. Thus, the results obtained from BV2 cells can not be applied entirely in primary microglia. Secondly, due to the relatively small sample size in vivo experiments, the results of these experiments should be interpreted with caution until more samples are used to study further.
In conclusion, the results suggest that microglial exosomes could alleviate ischemic brain injury in vitro and in vivo through transporting exosomal miRNA-137 and its targeting gene Notch1. This study provides novel insight into the development of exosomal miRNAs-based therapeutic strategies for ischemic brain injury.
Materials and Methods
Cell culture
BV2 cells were purchased from Elabscience (Wuhan, China) and cultured in Dulbecco's modified Eagle medium (DMEM) (Sigma-Aldrich, Shanghai, China) supplemented with 10% Fetal Bovine Serum (FBS) (Thermo Fisher Scientific, Waltham, USA), 1% streptomycin, and 1% penicillin (Thermo Fisher Scientific, Waltham, USA). BV2 cells were subjected to interleukin 4 (IL-4) (20 ng/mL) for 48 hours to convert to M2 phenotype, which was verified using PCR and Western blotting assay to detect M2 microglia markers. After identification, BV2 M2 cells were seeded in culture dishes for 24 hours, and the medium was collected and centrifuged at 500×g for 5 min. The supernatant was collected as the conditioned medium (BV2-CM) for subsequent experiments. Primary cortical neurons were collected from C57BL/6 mice at 16-18 embryonic days (Department of Laboratory Animal Science, Fudan University, Shanghai) as previously described [60]. Primary neurons were cultured in an incubator at 37° C in 5% CO2, and the medium was replaced every three days. Primary neurons were used for subsequent experiments between 7 and 10 days in culture.
Oxygen-glucose deprivation (OGD) treatment
Before OGD treatment, primary cortical neurons were treated with 20 μg exosomes (BV2-Exo) or BV2-Exo-CN for 24 hours. Oxygen-glucose deprivation (OGD) treatments were performed in a sealed chamber filled with 95% N2 and 5% CO2. During OGD treatment, cells were cultured in deoxygenated glucose-free DMEM (Thermo Fisher Scientific, Waltham, USA). After 45-min OGD treatment, cells were moved to a regular incubator to recover for 12 hours, and the medium was replaced with normal maintenance medium.
Real-time PCR
Total RNA was isolated from exosomes or brain tissues using PolyATtract® mRNA Isolation Systems (Promega, Madison, USA) according to the manufacturer's instruction. RNA concentration and purity were determined using NanoDrop 2000 (Thermo Fisher Scientific, Waltham, USA) according to the manufacturer's instruction. Reverse transcription was performed using GoScript™ Reverse Transcription System (Promega, Madison, USA) according to the manufacturer's instruction. RT-PCR assay was performed using GoTaq® Green Master Mix (Promega, Madison, USA) in 7900 HT PCR system (ABI, Foster City, USA) according to the manufacturer's instructions. The primer information was list in Table 1. The expressions of GAPDH and U6 were used as control. The relative expressions were calculated using 2-ΔΔCt method [61].
Table 1. Primer information.
Genes | Primers sequences |
CD206 | F: 5’- AAGGCGGTGACCTCACAAG -3’ |
CD206 | R: 5’- AAAGTCCAATTCCTCGATGGTG -3’ |
ARG | F: 5’- CAAGCTGGGAATTGGCAAAG -3’ |
ARG | R: 5’- GGTCCAGTCCATCAACATCAA -3’ |
Notch1 | F: 5’- GCAGTTGTGCTCCTGAAGAA -3’ |
Notch1 | R: 5’- CGGGCGGCCAGAAAC -3’ |
GAPDH | F: 5’- AAGGTGAAGGTCGGAGTCAAC -3’ |
GAPDH | R: 5’- GGGGTCATTGATGGCAACAATA -3’ |
U6 | F: 5'- CTCGCTTCGGCAGCACA -3' |
U6 | R: 5’- AACGCTTCACGAATTTGCGT -3’ |
MiRNA-137 | 5’- CTACAAAGGGAAGCCCTTTC -3’ |
Western blotting
Total protein was isolated from the ipsilateral hemisphere samples, and the amount of protein was measured using Pierce™ BCA Protein Assay Kit (Thermo Fisher Scientific, Waltham, USA). The procedure of Western blotting was performed as previously described [62]. The primary antibodies were as follows: CD63 (1:1000), Tsg101 (1:1000), CD206 (1:1000) (Abcam, Shanghai, China); caspase-3 (1:1000), cleaved caspase-3 (1:1000), ARG (1:200), Notch1 (1:500), and GAPDH (1:1000) (BD Biosciences, San Jose, USA). Proteins were determined using enhanced chemiluminescence (MilliporeSigma, Burlington, USA) and photographed using a Molecular Imager VersaDoc 4000 system (Bio-Rad, Hercules, USA).
Cell transfection, luciferase reporter assay and exosome labeling
BV2 cells (2 × 106 cells) were transfected with lentiviruses containing miRNA-137 inhibitor (miRNA-137-IN) (OriGene, Rockville, USA) for 72 hours, according to the manufacturer's instructions. Lentivirus containing negative control shRNA was used as a control (miRNA-137-NC). HEK 293T cells (2 × 106 cells) (Sigma-Aldrich, Shanghai, China) were co-transfected with miRNA-137 mimics (RiboBio, Guangzhou, China) and luciferase reporter plasmids containing wild-type or a mutant miRNA-137 binding site in 3’UTR of Notch1 using the Lipofectamine™ 3000 Transfection Reagent (Invitrogen, Waltham, MA, USA) according to the manufacturer’s instructions. At 24 hours post-transfection, relative luciferase activities were measured using the dual-luciferase reporter assay kit (Promega, Madison, USA). Exosomes were fluorescently labeled using the PKH26 Fluorescent Cell Linker Kits according to the manufacturer's instructions (Sigma-Aldrich, Shanghai, China).
Exosome isolation and identification
Exosomes (BV2-Exo) were isolated from the culture supernatant of M2 BV2 cells using the ultracentrifugation method, as previously described [63]. Briefly, donor cell M2 BV2 cells were washed with PBS solution twice, and the medium was replaced with exosome-free medium (ultracentrifugation at 100,000 g for 16 hours) for 48 hours. Then, the supernatant was collected and was subjected to serial ultracentrifugation at 2000×g for 30 min, 10000×g for 30 min, and 100000×g for 60 min at 4° C. Next, exosomes were washed with PBS solution once at 100000×g for 60 min and were suspended for further identification. Exosomes (BV2-Exo-CN) isolated from BV2 without being treated IL-4 were used as control. The protein content of exosomes was measured using Pierce™ BCA Protein Assay Kit (Thermo Fisher Scientific, Waltham, USA). Exosomal markers CD63 and TSG101 were determined by Western blotting assay. Then, transmission electron microscope (TEM) (Philips, Amsterdam, Netherlands) and nanoparticle tracking analysis were performed to verify the identification of exosomes, as previously described [63].
RNA-seq
Total RNA and cDNA of BV2-Exo and BV2-Exo-CN were prepared as described above. The procedure of RNA-seq was performed on Illumina Hiseq2500 platform according to the manufacturer's instructions Majorbio Biotech Co., Ltd. (Shanghai, China). RNA-seq analysis was performed as previously described [64] and the instruction provided by Majorbio Biotech Co., Ltd. The clean reads were obtained through quality control and then blasted against the Rfam database to annotate the miscellaneous RNAs [65]. After filtering snRNA, scRNA, rRNA, and other non-coding RNA, the remaining sRNAs were aligned to the miRBase version 21.0 to identify the known and novel miRNAs. Then, the differential miRNA expression profile was calculated by the package DESeq2 [66] and edgeR [67]. MiRNAs with |log2fold change| ≥2 and Padj-value <0.05 were identified as statistical differences. Volcano plots and heatmaps of differential miRNA expression profiles were plotted by R Package TRAPR [68].
Immunohistochemistry and TUNEL assay
Immunohistochemistry assay was performed as previously described [69, 70]. The primary antibodies used were as follows: CD206 (1:500), AGR (1:500), MAP2 (1:500) (Abcam, Shanghai, China). The double-staining of TUNEL/DAPI was performed for in vitro study using TUNEL Assay Kit according to the manufacturer's instructions (Abcam, Shanghai, China). The double-staining of NeuN/TUNEL was performed for the infarct area of brain sections for in vivo study (Abcam, Shanghai, China). For the quantification of apoptotic cells, the stained cells or sections were viewed under a fluorescence microscope (Olympus, Tokyo, Japan). The mean of TUNEL-positive cells at least 5 random microscopic regions were counted for each sample by two independent lab technicians.
CCK-8 and lactate dehydrogenase (LDH) assay
Cell viability was determined using Cell Counting Kit-8 (CCK-8) according to the manufacturer's instructions (Dojindo, Kumamoto, Japan). Absorbance was determined at 450 nm using a microplate reader (BioTek, Winooski, USA). Lactate dehydrogenase (LDH) assay was performed to determine the death rate of primary neurons using LDH assay kit according to the manufacturer's instructions (Abcam, Shanghai, China).
In vivo ischemic mouse model
All experiments performed on animals were approved by the Institutional Animal Care and Use Committee of Heilongjiang University of Traditional Chinese Medicine. Thirty-six C57BL/6 male mice (6-8 weeks old; 24-28 g) (Department of Laboratory Animal Science, Fudan University, Shanghai) were randomly divided into six groups (n=12). Except for mice in the sham group (n=12), the other thirty mice were subjected to transient middle cerebral artery occlusion (tMCAO) surgery, as previously described [71]. To verify the success of surgery, the interruption and reperfusion of surface cerebral blood flow was confirmed using transcranial laser Doppler (DRK4, Devon, UK). After surgery, mice were randomly divided into five groups (n=12), including 1) PBS group: mice were injected with PBS (200 μl); 2) BV2-Exo group: mice were injected with BV2-Exo; 3) BV2-Exo-miRNA-137-IN group: mice were injected with exosomes derived from BV2 cells treated with miRNA-137-IN; 4) BV2-Exo-miRNA-137-IN+ Crenigacestat group: mice were co-injected with exosomes derived from BV2 cells treated with miRNA-137-IN and 100 μg/kg Crenigacestat (Cren) (LY3039478) [72]. 5) miRNA-137-NC group: mice were injected with exosomes derived from BV2 cells treated with miRNA-137-NC. The injection of exosomes (100 μg/day) was immediately performed through the tail vein after the surgery and lasted for three consecutive days. Three days after surgery, six mice in each group were used for detecting RNA and protein expressions, and the other six mice were used for immunohistochemistry assay. Infarct volume was evaluated as previously described [73]. Briefly, the brain was sectioned in a cryostat into a series of 20 μm sections and strained with 0.1% cresyl violet. The ratio of staining in the ipsilateral and contralateral hemispheres was determined using ImageJ [74]. The influence of postischemic edema to the infarct volume was corrected for swelling by comparing nonischemic and ischemic hemispheres, as previously described [75, 76]. The infarct volume was calculated through the formula:
where V indicates volume, h indicates the distance between the two adjacent sections, contralateral area subtracts normal area of the ipsilateral hemisphere was calculated as the infarct area ΔS, andΔ;Sn and ΔSn+1 indicates the different area between the two adjacent sections [77].
Neurobehavioral testing
To determine neurobehavioral performance, all mice underwent modified neurological severity score (mNSS) testing 1 day before and 3 days after tMCAO surgery, in which motor, reflex, and balance functions were evaluated. The evaluation score was from a normal score 0 to the most severe deficit score 14 [78].
Statistical analysis
Data were represented as mean ± standard deviation (SD). Comparisons between groups were performed using ANOVA and Student's t-test. Statistical analysis was performed using SPSS 13.0 (SPSS, Inc., Chicago, USA). p<0.05 was regarded as statistical difference.
Author Contributions
Dianquan Zhang, Kai Liu, Cheng Cui, Guofeng Cai and Zhe Zhuang performed the majority of experiments and analyzed the data; Guoliang Cai, Manchao Sun and Kunping Jia performed the molecular investigations; Wenli Song, Hong Wang, Xiuzhen Wang and Siying Pei designed and coordinated the research; Shengnan Xu and Sihui Guo wrote the paper.
Conflicts of Interest
The authors declare that they have no conflicts of interest.
Funding
The project was funded by State Administration of Traditional Chinese Medicine of the Heilongjiang Province (ZHY16-027) and Harbin Municipal Science and Technology Bureau -Youth reserve talent project (2017RAQXJ170).
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