Abstract
Cardiovascular disease remains the leading cause of morbidity and mortality worldwide. Cell death is a hallmark characteristic of various cardiac diseases, including myocardial infarction and heart failure. Emerging evidences suggest that necrosis is programmed and is one of the main forms of cell death in the pathological process in cardiac diseases. However, the molecular components regulating programmed necrosis in heart remain largely unidentified. Here we report that miR-30b, Cyclophilin D (CypD) and E2F1 constitute an axis that regulates necrosis. The results show that knockdown of CypD attenuated necrosis in the cellular model and also myocardial infarction in the animal model. miR-30b suppresses the translation of CypD and thus inhibits CypD-mediated necrotic cell death in cardiomyocytes. Cardiac-specific miR-30b transgenic mice exhibit reduced necrosis and myocardial infarct size upon ischemia/reperfusion (I/R) injury. Further, we identify that E2F1 transcriptionally represses miR-30b expression. Knockdown of E2F1 in cardiomyocytes inhibits necrotic cell death, and E2F1 knockout mice show reduced necrosis and myocardial infarct size upon I/R. Our present study identifies a novel signaling pathway composed of E2F1, miR-30b and CypD that regulates myocardial necrosis. This discovery will not only provide de novo regulators in the necrotic process but will also shed new light on the effective therapy of myocardial infarction and heart failure.
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Main
Necrosis and apoptosis are two forms of cell death, which have key roles in the process of development, homeostasis and diseases.1 Traditionally, necrosis is regarded as a passive and unregulated cell death, while apoptosis has long been considered as the sole form of programmed cell death. However, emerging evidences suggest that a proportion of necrosis is regulated by serial signaling events in a controlled and orchestrated manner.2 Recent data have shown that programmed necrosis is a complex process and is mediated by multiple signaling pathways.3, 4, 5, 6, 7, 8 Necrosis is observed in various heart diseases, including myocardial infarction, heart failure and stroke.9, 10, 11, 12 It has been reported that death receptor pathway and mitochondrial pathway13,14 are involved in the programmed necrosis during heart disease progression. These studies show that necrotic cell death has an important role in the occurrence and development of cardiac diseases. However, the molecular components regulating programmed necrosis in the heart remain largely unidentified.
Cyclophilin D (CypD) is a prolyl isomerase that has an important role in the formation of mitochondrial permeability transition pore (mPTP).15,16 CypD, mitochondrial adenine nucleotide translocator and a voltage-dependent anion channel together forms the mPTP.16 Among the three components of the mPTP, CypD lies in the center of regulating the pore opening. And the deletion of the CypD causes marked impairment of mPTP formation.17, 18, 19 It is believed that transient opening of mPTP, caused by limited oxidative stress or short periods of ischemia, preserves the ATP/ADP ratio in the mitochondria and mainly initiates the apoptosis, while the consistent opening of mPTP usually results in ATP depletion and finally leads to necrotic cell death.20,21 As mPTP opening is a critical event in some forms of necrotic cell death, the function of CypD is also important in the necrotic cell death pathway. Previous reports have shown that the mPTP in the inner mitochondrial membrane is involved in the mitochondrial pathway and CypD mediates the programmed necrosis.7,8 CypD has recently been shown to be able to regulate hydrogen peroxide (H2O2)-induced necrotic cell death.22,23 However, it is not yet clear whether CypD is a target of microRNAs (miRNAs), and the molecular regulation of CypD in the necrotic machinery remains to be elucidated. Addressing these questions will be of great importance to decipher and characterize the molecular pathway of necrosis.
miRNAs are a class of short single-stranded non-coding endogenous RNAs and act as negative regulators of gene expression by inhibiting mRNA translation or promoting mRNA degradation.24,25 Although the function of miRNAs has been widely studied in apoptosis, development, differentiation and proliferation, few works have focused on the function of miRNAs in the necrotic pathway. It has been reported that miR-155 targets to RIP1 and prevents cardiomyocyte progenitor cells’ necrosis.26 And miR-214 protects heart from ischemia/reperfusion (I/R) injury and necrotic cell death by targeting to NCX1 and inhibiting Ca2+ overload.27 The study of miRNA function in cardiomyocyte necrosis will shed new light on the necrotic cell death pathway and discover de novo therapeutic targets for heart failure.
E2F1 lies downstream of retinoblastoma protein, promotes apoptosis and suppresses cell proliferation.28,29 E2F1 is pivotal for cardiac function and mainly affect the metabolism of cardiomyocytes. E2F1 knockout mice have lower blood glucose levels and improved glucose oxidation and shows a variety of age-related defects.30 E2F1 mutation induces congestive heart failure.31 These studies further substantiate the notion that E2F1 might have an important role in the pathological development of heart disease. So far, few studies have focused on the E2F1 function in cell necrosis. As apoptosis and necrosis both exist in heart failure, it is likely that E2F1 participates in necrosis signaling pathway. It is of great importance to study and unveil the function of E2F1 in necrosis.
Our present study unveils that CypD is involved in the regulation of myocardial necrosis. Knockdown of CypD inhibits necrotic cell death in vivo and in vitro. In searching for the mechanism by which CypD is upregulated under necrotic condition, we identify that miR-30b participates in the suppressing of CypD translation. miR-30b inhibits necrotic program through targeting CypD. We further find that E2F1 transcriptionally represses miR-30b expression. E2F1 initiates necrotic program through downregulating miR-30b. Our results reveal a novel myocardial necrotic-regulating model, which is composed of E2F1, miR-30b and CypD. Modulation of their levels will shed new light on the necrotic cell death pathway and may represent a novel approach for interventional treatment of myocardial infarction and heart failure.
Results
CypD regulates H2O2-induced necrotic cell death in cardiomyocytes
It is well known that H2O2 induces necrotic cell death in various cell types.32, 33, 34 CypD, a protein considered to be involved in mPT, has recently been shown to be able to regulate H2O2 -induced necrotic cell death.22 However, the underlying molecular mechanism of CypD in necrosis remains to be elucidated. We tested whether CypD is related to the occurrence of necrosis induced by H2O2 in cardiomyocytes. We observed that H2O2 treatment led to a time-dependent increase in CypD expression (Figure 1a). Knockdown of CypD attenuated CypD levels and necrotic cell death (Figure 1b) induced by H2O2. These data suggest that CypD is involved in H2O2-induced necrotic cell death and has a functional role in caridomyocytes.
To understand the pathophysiological role of CypD, we tested whether CypD is involved in the pathogenesis of myocardial infarction in the animal model. Our results showed that CypD was elevated in response to I/R injury (Figure 1c). Myosin antibody injection technique was used to assess myocardial necrosis. I/R caused a massive increase in necrotic myosin-positive cells (Figure 1d). Knockdown of CypD by siRNA delivery showed a decrease in necrotic myosin-positive cells compared with the control group upon I/R (Figure 1d). Thus it indicates that knockdown of CypD results in a reduction in the myocardial necrosis. The myocardial infarct size was also reduced in the CypD knockdown group (Figure 1e), and the cardiac function was ameliorated by knockdown of CypD (Figure 1f). Taken together, it appears that CypD has a significant role in the regulation of myocardial necrosis and myocardial infarction.
miR-30b participates in the regulation of CypD expression
miRNAs are a class of small non-coding RNAs and act as negative regulators of gene expression. To explore the underlying mechanism by which CypD is upregulated upon H2O2 and I/R treatment, we tested whether CypD is regulated by miRNAs. We first screened some cardiac-associated miRNAs, which had been reported in the past several years by quantitative reverse transcription-PCR (qRT-PCR). Among these miRNAs, miR-30b levels were significantly downregulated upon H2O2 (Figure 2a), and other miRNAs remain unchanged (data not shown). We also analyzed the 3′UTR of CypD using the RNAhybrid program and observed that CypD was a potential target of miR-30b (Figure 2b), which promoted us to focus on the function of miR-30b. To identify the function of miR-30b, several approaches were used to explore whether CypD expression is regulated by miR-30b. We first tested whether overexpression or knockdown of miR-30b altered the expression of endogenous CypD. Our results showed that enforced expression of miR-30b resulted in a reduction of endogenous CypD (Figure 2c). Concomitantly, knockdown of endogenous miR-30b induced an increase in CypD expression (Figure 2d). Enforced expression of miR-30b also led to a reduction of CypD upon H2O2 treatment (Figure 2e). These results indicate that miR-30b can specifically regulate CypD.
We employed the luciferase assay system to test whether miR-30b influenced the translation of CypD. As shown in Figure 3g, the luciferase reporter assay revealed that the wild-type (WT) 3′UTR of CypD exhibited a low translation level in the presence of miR-30b, whereas the mutated 3′UTR (Figure 2f) did not show a significant response to miR-30b. Our data further showed that miR-30b reduced the expression of CypD with WT 3′UTR (Figure 2h, upper panel) but had no effect on the mutated 3′UTR (Figure 2h, low panel). To detect the role of miR-30b in the regulation of CypD in animal model, we generated transgenic mice with cardiac-specific overexpression of miR-30b (Supplementary Figure S1A). Five lines of miR-30b transgenic mice represented a high level of miR-30b in the heart (Supplementary Figure S1B). Our results showed that CypD expression level was downregulated in miR-30b transgenic mice (Figure 2i). Taken together, it suggests that CypD is a specific target of miR-30b.
miR-30b is able to inhibit necrotic cell death in vitro and in vivo
Next, we attempted to understand the function of miR-30b in necrotic machinery. Necrosis is morphologically characterized by increasing of cell volume, dilation of organelles, rupture of the plasma membrane and subsequent loss of intracellular contents. Cardiomyocytes upon exposure to H2O2 (750 μM) displayed obvious necrotic morphological characterization. However, compared with the mimic negative control (mimic-NC), enforced expression of miR-30b by the mimic (mimic-30b) group attenuated the necrotic morphological hallmarks, which were confirmed by electron microscopy (Figure 3a). miR-30b also attenuated necrotic cell death induced by H2O2 (Figure 3b). These data suggest that miR-30b has a fundamental role in H2O2-induced cardiomyocyte necrosis.
We further detected the role of miR-30b in the pathogenesis of myocardial infarction in the animal model. We observed that miR-30b level was reduced in response to I/R injury (Figure 3c). To better understand the function of miR-30b in the heart, we generated transgenic mice with cardiac-specific overexpression of miR-30b. Analysis of adult mice generated from five stable independent transgenic mice founder lines showed that their miR-30b expression was about three to six times as high as that of the WT hearts (Supplementary Figure S1B). The miR-30b transgenic mice generated from Line#1 were used for this study (Supplementary Figure S1C). All five transgenic mice founder lines developed normally to adulthood, without significant alterations in terms of phenotype and cardiac function (Supplementary Figure S1D) under physiological condition. Next, we used myosin antibody injection technique to assess myocardial necrosis. miR-30b transgenic mice showed less myosin antibody incorporation than the WT group upon I/R, which indicated a reduction in myocardial necrosis (Figures 3d and e). Myocardial infarct size also reduced in miR-30b transgenic mice, compared with WT group upon I/R (Figure 3f). The cardiac function was ameliorated in miR-30b transgenic mice group after I/R (Figure 3g). Thus, our results strongly suggest a possible contribution of miR-30b in inhibiting necrosis in the I/R-injured heart.
In addition to Line#1, we also conducted experiments using transgenic mice generated from Line#4, which have the highest miR-30b expression level among all five lines. In comparison with transgenic mice Line#1, the hearts of transgenic mice Line#4 showed an even more reduced CypD expression level (Supplementary Figure S2A) and a smaller infarct size (Supplementary Figure S2B), indicating that the functional effect of miR-30b is dependent upon the level of transgene expression.
miR-30b regulates necrosis through targeting CypD
We then explored how miR-30b exerts its effect on necrotic program. As miR-30b is able to suppress CypD expression, we thus tested whether CypD is a mediator of miR-30b. Although miR-30b could inhibit CypD expression and necrotic cell death, this inhibitory effect was significantly abolished by CypD with mutated 3′UTR but not the CypD with WT 3′UTR (Figures 4a and b). To confirm the relationship between miR-30b and CypD in necrosis program machinery, we employed the target protector (TP) technology in which a TP is able to disrupt the specific interaction of miRNA–mRNA pairs. To this end, we produced CypD TP and observed that the inhibitory effect of miR-30b on CypD expression and necrotic cell death was reduced in the presence of CypD TP (Figures 4c and d). These data suggest that miR-30b specifically targets CypD in the signal transduction cascades of necrotic program.
miR-30b is negatively regulated by E2F1 in transcriptional level
We asked how miR-30b expression is regulated under the pathological condition. It has recently been reported that NF-κB positively regulates miR-30b expression in Ang II-induced cardiomyocyte apoptosis, and Bcl-2 is a direct target of miR-30b.35 Thus we analyzed the expression levels of NF-κB and BCL-2 to explore whether they are also involved in the necrotic pathway induced by H2O2. The results showed that there is no detectable change in the expression levels of NF-κB and BCL-2 in response to H2O2 treatment (Supplementary Figure S3A), suggesting that NF-κB and BCL-2 are not involved in H2O2-induced necrotic pathway.
We then analyzed the promoter region of mouse miR-30b and observed that there was a potential binding site of E2F1 (Figure 5a). Enforced expression of E2F1 led to a decrease of miR-30b precursor (pre-miR-30b) and miR-30b levels (Supplementary Figure S3B and Figure 5b), whereas E2F1 knockout mice exhibited an increased expression levels of pre-miR-30b and miR-30b (Supplementary Figure S3C and Figure 5c), suggesting that miR-30b may be a potential transcriptional target of E2F1. Thus we tested whether E2F1 can bind to the promoter region of miR-30b. The ChIP assay revealed that E2F1 bound to the miR-30b promoter under the physiological condition. H2O2 treatment enhanced the association of E2F1 with the miR-30b promoter (Figure 5d). We further tested whether E2F1 could influence miR-30b promoter activity. WT miR-30b promoter (wt) represented a low activity in the presence of E2F1. And mutations in the E2F1-binding site could abolish the inhibitory effect of E2F1 on miR-30b promoter activity (Figure 5e). These data suggest that E2F1 can negatively regulate the expression of miR-30b. H2O2 induced a reduction in miR-30b promoter activity in cardiomyocyte (Figure 5f). Concomitantly, knockdown of E2F1 could attenuate the decrease of miR-30b promoter activity induced by H2O2 (Figure 5f). These data indicate that miR-30b can be transcriptionally repressed by E2F1.
Our data have shown that CypD acts as a specific downstream target of miR-30b, and miR-30b transcription, in turn, is regulated by E2F1. Thus we explored whether there is a direct interaction between E2F1 and CypD. We cloned the promoter region of mouse CypD and constructed the luciferase reporter vector. Luciferase activity analysis showed that E2F1 did not influence the CypD promoter activity (Supplementary Figure S3D), suggesting that CypD can not be directly regulated by E2F1 at the transcriptional level. Thus our results indicate that there is no direct interaction between E2F1 and CypD.
E2F1 regulates necrosis through miR-30b and CypD
We investigated the role of E2F1 in cardiomyocyte necrosis and myocardial infarction. H2O2 induced an elevation in E2F1 expression level (Figure 6a). Knockdown of E2F1 was able to attenuate necrotic cell death upon H2O2 treatment in cardiomyocytes (Figure 6b). I/R also led to an increase in E2F1 expression level in response to I/R injury. Furthermore, E2F1 knockout mice demonstrated reduced necrotic cell death revealed by myosin antibody incorporation (Figure 6d) and myocardial infarction size (Figure 6e) upon I/R. These data indicate that E2F1 participates in mediating the signal for necrotic cell death in the heart.
We further explored whether miR-30b and CypD could act as the downstream targets of E2F1 in necrotic signal pathway. We observed that the TP of CypD attenuated the inhibitory effect of E2F1 knockdown on CypD expression (Figure 6f) and necrotic cell death (Figure 6g). Thus it appears that E2F1 targets miR-30b/CypD axis in the necrotic cascades.
Besides cardiomyocytes, many different types of cells exist in the heart, such as macrophages, monocytes, neutrophils and so on, which are also important for a properly functioning heart. It has been reported that cells other than cardiomycoytes also contribute to I/R injury.36 In consideration of the extra-cardiomyocyte effects, we examined whether other cells in turn have an important role in I/R. Our results revealed that the anti-apoptotic effect of E2F1 KO mice is not dependent on endothelium effect (Supplementary Figure S4A and Supplementary Figure S4B). Also, E2F1 KO mice do not affect miR-30b and CypD expression levels in macrophages (Supplementary Figure S5A and Supplementary Figure S5B), hence excluding the effect of these two kinds of cells in our animal models. Our results do not completely rule out the possibility of the effect of other cells, such as monocytes and neutrophils. And these cells might be promising targets for ameliorating I/R injury. In the future, we intend to carry out more rigorous studies on the effects of other inflammatory cells on cardiac I/R injury. Future studies may clarify the most promising molecules and cell types to be investigated as targets for cardiovascular diseases, providing valuable suggestions for an effective all-round treatment and a better understanding of the molecular mechanisms in a wider setting.
Discussion
Heart failure is one of the leading causes of hospitalization and death worldwide. Cardiac myocyte necrosis is an important component of myocardial infarction and heart failure. Antagonizing the myocardial necrosis is considered to be a therapeutic target for treating heart failure. So it is necessary to elucidate the molecular mechanisms of myocardial necrosis and discover potential therapeutic targets for inhibiting myocardial necrosis and the consequent heart failure. Our present work demonstrated that knockdown of CypD attenuates necrotic cell death in cardiomyocytes and reduces myocardial infarction in the animal model. miR-30b could inhibit myocardial necrosis through targeting CypD. miR-30b transgenic mice exhibit attenuated necrotic cell death and myocardial infarction size. We further identified that knockdown of E2F1 inhibits myocardial necrosis through negatively regulating miR-30b at the transcriptional level. Our study reveals a novel molecular mechanism of myocardial necrosis and provides the therapeutic targets for treating myocardial infarction and heart failure.
Necrosis is characterized by marked swelling of cell, rupture of the plasma membrane and severe inflammation followed by the spill of intracellular contents. Traditionally, necrosis is regarded as a form of accidental and unregulated cell death, while apoptosis has long been considered as the sole form of programmed cell death. However, it is clear now that a portion of necrosis is also programmed and can be actively regulated.2 Recent reports have described that two signaling pathways, including death receptor pathway3, 4, 5, 6 and mitochondrial pathway,7,8 could mediate programmed necrosis. However, there is no doubt that the study of necrosis signaling is just beginning. The molecular mechanisms of necrosis need to be further elucidated. Our present work reveals a novel programmed necrotic pathway composed of E2F1, miR-30b and CypD. The results not only expand our knowledge of the molecular mechanism of programmed necrosis but also provide new insights for understanding the programmed necrosis pathogenesis of myocardial necrosis.
mPTP has an important role in necrotic regulation. CypD knockout mice is resistant to I/R and represents reduced infarct size. Knockout of CypD mainly preserves the cardiac function through inhibiting of myocardial necrosis.22,23 The above evidences showed that CypD is an important effector in regulating necrosis. However, the underlying upstream regulator of CypD in necrosis remains unknown. Our research discovers a signaling pathway composed of E2F1, miR-30b and CypD. E2F1 and miR-30b are the upstream regulators of CypD. Thus the discovering of the upstream signaling pathway of CypD will shed new light on the regulation of programmed necrosis and will unveil novel therapeutic targets for myocardial infarction at the same time.
miRNAs participates in various biological and pathological processes, such as apoptosis, development and proliferation. Many studies have focused on the inhibitory effect of miR-30b in apoptosis in various cancerous diseases, such as lung cancer, glioma and breast cancer. miR-30b is upregulated in many cancer cells that is resistant to apoptosis. For example, miR-30b expression level is upregulated in the TRAIL-resistant cancer cells and inhibits apoptosis by targeting caspase-3.37 miR-30b targets p53 and inhibits mitochondrial fission during apoptosis.38 However, few studies reported the function of miR-30b in necrosis, which is another important regulated form of cell death in I/R injury. Our results identified that miR-30b inhibits necrotic program by inhibiting CypD expression in cardiomyocytes. And miR-30b cardiac-specific transgenic mice represent reduced myocardial necrosis and infarction size upon I/R injury. Our study has provided important evidences about the function of microRNAs in the programmed necrosis pathway, a step toward better understanding the miRNA based therapy for I/R injury and heart failure.
Necrosis and apoptosis both exist during I/R.39 In the early stage of ischemia, apoptosis is the major form of cell death, whereas in the later period of ischemia necrosis causes the majority of cardiomyocyte death. It is reported that E2F1 expression is increased upon I/R injury, and I/R injury is attenuated in E2F1 null hearts.40 The mechanism of E2F1 in inducing apoptosis has been widely studied.41 However, few studies have been focused on the E2F1 function in cell necrosis. In the present work, we investigated the role of E2F1 in necrosis upon myocardial I/R injury. E2F1 knockout mice demonstrated reduced necrotic cell death and myocardial infarction size upon I/R injury. E2F1 participates in the necrotic pathway by regulating the expression of miR-30b. Modulation of their levels may provide a new approach for tackling necrotic cell death and myocardial infarction.
Materials and Methods
Cardiomyocyte culture and treatment
Cardiomyocytes were isolated from 1 to 2 days old mice as described by us.42 Briefly, after dissection, the hearts were washed and minced in HEPES-buffered saline solution. Tissues were then dispersed in a series of incubations at 37 °C in HEPES-buffered saline solution containing 1.2 mg/ml pancreatin and 0.14 mg/ml collagenase (Worthington, Lakewood, NJ, USA). After centrifugation, cells were re-suspended in Dulbecco’s modified Eagle medium/F-12 (GIBCO, Grand Island, NY, USA) containing 5% heat-inactivated horse serum, 0.1 mM ascorbate, insulin-transferring-sodium selenite media supplement (Sigma, St Louis, MO, USA), 100 U/ml penicillin, 100 μg/ml streptomycin and 0.1 mM bromodeoxyuridine. The dissociated cells were pre-plated at 37 °C for 1 h. The cells were then diluted to 1 × 106 cells/ml and plated in 10 μg/ml laminin-coated different culture dishes according to the specific experimental requirements. Cells were treated with 750 μM H2O2 except as otherwise indicated elsewhere.
Generation of cardiac-specific miR-30b transgenic mice
For creating miR-30b transgenic mice, a 471-bp DNA fragment containing murine miR-30b was cloned to the vector, pαMHC-clone26 (kindly provided by Dr Zhong Zhou Yang), under the control of the α-myosin heavy chain (α-MHC) promoter. The primers used to generate miR-30b transgenic mice include forward primer 5′-TGAAAGAGAGAACGATAAATGTT-3′ and reverse primer: 5′-ACTTCTGAATCAAAATATTGGTA-3′. Microinjection was performed following the standard protocols.
Generation of E2F1 knockout mice
E2F1 knockout (KO) mice were purchased from Mutant Mouse Regional Resource Center (University of California, Davis, CA, USA). E2F1+/− mice were interbred to give knockout mice (E2F1−/−), which were used for further studies. Mice were genotyped by multiplex PCR (primers and conditions are available from Mutant Mouse Regional Resource Center). All experiments were performed on E2F1−/− mice and their WT littermates (E2F1+/+). The animal experiments were performed according to the protocols approved by the Institute Animal Care Committee and were approved by government authorities.
Cell death assays
Necrotic cell death was assessed by propidium iodide (PI) exclusion.
Isolation of macrophages
Mice were killed on day 7 after myocardial infarction. The heart was dissected out and perfused with cold phosphate-buffered saline. Then the heart was dissociated into a single-cell suspension as previously described.43 Briefly, the heart was minced and digested with a cocktail composed of collagenase and DNase I for 30 min at 37 °C with rotation. BSA was added to the digested samples. Cells were centrifuged and resuspended with RMPI-1640 cell culture medium, supplemented with 10% FBS and incubated in a plastic dish at 37 °C. Two hours later, adherent cells were collected and stained with F4/80-PE and cd11b-PE-cy5 for FACS analysis. F4/80 and CD11b double-positive macrophages were sorted and collected. RNA was extracted from the sorted macrophage using the microElute total RNA kit (Omega, Norcross, GA, USA).
Transfection of antagomir
miR-30b antagomir and the antagomir negative control (antagomir-NC) were purchased from GenePharma Co. Ltd (Shanghai, China). The antagomir sequence is 5′-GACGUAAACAUCCACAUCCCAG-3′. All the bases were 2′-OMe modified, and the 3′-end was conjugated to cholesterol. Chemically modified oligonucleotides 5′-CAGUACUUUUGUGUAGUACAA-3′ were used as a negative control (antagomir-NC). Cells were transfected with the antagomir or antagomir-NC at 50 nM. The transfection was performed using Lipofectamine 2000 (Invitrogen, GrandIsland, NY, USA) according to the manufacturer’s instruction.
Target protector preparation and transfection
Target protector was designed and named as described by others and us.44 In brief, CypD-TPmiR-30b sequence is 5′-CTGGGTGAATCAAGACATGGATGCCT-3′ and CypD-TPcontrol sequence is 5′-TGACAAATGAGACTCTCTCCTCTCC-3′. They were synthesized by Gene Tools and transfected into the cells using the Endo-Porter kit (Gene Tools, Philomath, OR, USA) according to the kit’s instructions.
Preparations of the luciferase construct of CypD 3′UTR and luciferase activity assay
CypD 3′UTR was amplified by PCR. The forward primer was 5′-CAAGGTGCTAGGACAGCAGCA-3′; the reverse primer was 5′-CCCTGAGTGATGTCTCAGAAG-3′. To produce mutated 3′UTR, the mutations were generated using the QuikChange II XL Site-Directed Mutagenesis Kit (Stratagene, La Jolla, CA, USA). The constructs were sequence verified. WT and mutated 3′UTRs were subcloned into the pGL3 vector (Promega, Madison, WI, USA) immediately downstream of the stop codon of the luciferase gene.
Luciferase activity assay was performed using the Dual-Luciferase Reporter Assay System (Promega) according to the manufacturer’s instructions. Cells were co-transfected with the plasmid constructs of 150 ng/well of pGL3-CypD-3′UTR or pGL3-CypD-3′UTR-mut using Lipofectamine 2000 (Invitrogen) and then were infected with adenovirus miR-30b or β-gal at an MOI of 80. At 48 h after infection, luciferase activity was measured.
Adenoviral constructions and infection
Mouse CypD cDNA was amplified by RT-PCR from total RNA of mouse heart and then cloned into pcDNA3.1. The adenoviruses harboring CypD-3′UTR-wt were constructed using the Adeno-X expression system (Clontech, Otsu, Japan). CypD 3′UTR mutants were generated using the QuikChange II XL Site-Directed Mutagenesis Kit (Stratagene). Mouse E2F1 cDNA was from Origene (Rockville, MD, USA). The adenoviruses harboring E2F1 was constructed using the Adeno-X expression system (Clontech). To construct adenovirus encoding miR-30b, the mature miR-30b sequence was cloned into the adenovirus system according to the manufacturer’s instructions.
Constructions of adenoviruses harboring mouse CypD RNAi and E2F1-siRNA
The mouse CypD RNAi target sequence is 5′-GTCTTCCTCCTTGCAATAATT-3′. A non-related, scrambled RNAi without any other match in the mouse genomic sequence was used as a control (5′-GTTTCAACTTCCTGTACTACT-3′). E2F1 siRNA sequence is 5′-ATCTGACCACCAAACGCTT-3′; the scramble E2F1 siRNA sequence is 5′-CACTCACGACTACGATCTA-3′. The adenoviruses harboring these RNAi constructs were generated using the pSilencer adeno 1.0-CMV System (Ambion, GrandIsland, NY, USA) according to the Kit’s instructions.
Constructions of mouse miR-30b promoter and its mutant
The miR-30b promoter was amplified from mouse genome using PCR. The forward primer was 5′-GCTTCTAATGTTGGGAGCTGA-3′. The reverse primer was 5′-TGGGAGCCAAGCAATAACCTA-3′. The promoter fragment was finally cloned into the vector pGL4.17 (Promega). The introduction of mutations in the putative E2F1-binding site was performed with the QuikChange II XL Site-Directed Mutagenesis Kit (Stratagene) using the WT vector as a template. The construct was sequenced to check that only the desired mutations had been introduced.
Chromatin immunoprecipitation (ChIP) assay
ChIP assay was performed as described by us.44 In brief, cells were washed with PBS and incubated for 10 min with 1% formaldehyde at room temperature. The cross-linking was quenched with 0.1 M glycine for 5 min. Cells were washed twice with PBS and lysed for 1 h at 4 °C in a lysis buffer. The cell lysates were sonicated into chromatin fragments with an average length of 500–800 bp as assessed by agarose gel electrophoresis. The samples were precleared with Protein-A agarose (Roche, Hamburg, Germany) for 1 h at 4 °C on a rocking platform, and 5 μg specific antibodies were added and rocked for overnight at 4 °C. Immunoprecipitates were captured with 10% (vol/vol) Protein-A agarose for 4 h. Before use, Protein-A agarose was blocked twice at 4 °C with salmon sperm DNA (2 μg/ml) overnight. DNA fragments were purified with a QIAquick Spin Kit (Qiagen). The purified DNA was used as a template and amplified with the following primer sets: For the analysis of E2F1-binding to the promoter region of miR-30b, the oligonucleotides were as follows: forward: 5′-GCTTCTAATGTTGGGAGCTGA-3′; and reverse: 5′-GTAGACATGAATAACCTACAGAG-3′.
Immunoblot
Immunoblot was performed as we described.45 The anti-CypD antibody was from Santa Cruz Biotechnology, Inc (Santa Cruz, CA, USA). The anti-E2F1 antibody, anti-Bcl-2 antibody and the anti-GAPDH antibody were from Abcam (GrandIsland, NY, USA). Anti-PECAM-1 (CD31) antibody was from Millipore (Billerica, MA, USA), and anti-p65 antibody was from Cell Signaling Technology (Danvers, MA, USA). The horseradish peroxidase-conjugated secondary antibodies were purchased from Santa Cruz Biotechnology, Inc.
Quantitative reverse transcription-PCR
Stem-loop qRT-PCR for mature miR-30b was performed as described46 on a CFX96 Real-Time PCR Detection System (Bio-Rad, Hercules, CA, USA). Total RNA was extracted using the Trizol reagent. After DNAse I (Takara, Otsu, Japan) treatment, RNA was reverse transcribed with reverse transcriptase (ReverTra Ace, Toyobo, Japan). The levels of miR-30b analyzed by qRT-PCR were normalized to that of U6. U6 primers were forward: 5′-GCTTCGGCAGCACATATACTAA-3′; and reverse: 5′-AACGCTTCACGAATTTGCGT-3′.
Northern blot analysis
Northern blot was performed as described.47 In brief, the samples were run on a 15% polyacrylamide-urea gel, transferred to positively charged nylon membranes (Millipore) followed by cross-linking through UV irradiation. The membranes were subjected to hybridization with 100 pmol 3′-digoxigenin (DIG)-labeled probes for miR-30b overnight at 42 °C. miR-30b probes were labeled with DIG using a 3′-End DIG Labeling Kit (Roche). The detection was performed using a DIG luminescent detection kit (MyLab) according to the manufacturer’s instructions. The probe sequence for miR-30b was 5′-GACGTAAACATCCACATCCCAG-3′. DIG-labeled U6 probe was used as an internal control, and its sequence was 5′-TGGAACGCTTCACGAATTTG-3′.
Transmission electron microscopy
Conventional electron microscopy was performed as described previously.48 In brief, cells were fixed with 2.5% glutaraldehyde and then postfixed with 1% osmium tetraoxide, dehydrated in a graded series of ethanol concentrations and embedded in Embed812 resin. The ultrathin sections were mounted on copper grids and then double-stained with uranyl acetate and lead citrate. The samples were examined and photographed with a FEI Tecnai spirit transmission electron microscope (Hillsboro, OR, USA).
I/R, preparations of area-at-risk (ARR) and histology
Male adult C57BL/6 mice (8-weeks old) were obtained from the Institute of Laboratory Animal Science of Chinese Academy of Medical Sciences (Beijing, China). For intracoronary delivery of adenoviruses, the mice were anesthetized and ventilated with a HX-300S animal ventilator (Chengdu, China). The entry to the chest was through a small left anterior thoracotomy, the pericardial sac was then removed and 2 × 1010 MOI adenoviruses of CypD-siRNA or 2 × 1010 MOI adenoviruses of CypD-sc were injected with a catheter from the apex of the left ventricle into the aortic root while the aorta and pulmonary arteries were cross-clamped. The clamp was maintained for 20 s when the heart pumped against a closed system. After removal of air and blood, the chest was then closed, and the mice were returned back to cage for recovery. Five days after the injection of adenoviruses, the mice were subjected to I/R surgery.
For I/R injury model, mice were subjected to 60 min ischemia, then 3-h or 1-week reperfusion as described.49 Sham-operated group experienced the same procedure except the snare was left untied. miR-30b transgenic mice, E2F1 knockout mice and WT mice were subjected to I/R. The treatment with Evans blue dye was as described.49 The areas of infarction (INF), AAR and non-ischemic left ventricle (LV) were assessed with the computer-assisted planimetry (NIH Image 1.57, Bethesda, MD, USA) by an observer blinded to the sample identity. The ratio of AAR/LV and INF/AAR were calculated as described.49 All experiments were performed according to the protocols approved by the Institute Animal Care Committee.
Immunohistochemistry
CD31/TUNEL double staining was performed on 7-μm frozen sections. TUNEL staining was used to visualize apoptotic cell, while CD31 was used to identify endothelial cells in the mouse heart. Briefly, TUNEL staining was performed using the In situ Cell Death Detection Kit, FITC (Roche Applied Science, Mannheim, Germany) according to the manufacturer’s instructions. Anti-CD31/PECAM1 (Millipore, MA) was used as a primary antibody, followed by an anti-rabbit secondary antibody (TRITC). And slides were coverslipped using a mounting medium with DAPI to identify cell nuclei. Images were captured and processed using a laser-scanning confocal microscope (Zeiss LSM510 META, Oberkochen, Germany). Double-positive cells for CD31 and TUNEL were counted, and assessment was blinded to the treatment assignment.
Echocardiographic assessment
Transthoracic echocardiographic analysis was performed on mice after the sham or I/R surgery as we described.44 Echocardiographic parameters such as systolic left ventricular internal diameters (LVIDs) and diastolic left ventricular internal diameters (LVIDd) were measured. Fractional shortening of left ventricular diameter was calculated as ((LVIDd−LVIDs)/LVIDd) × 100. After in vivo evaluation of the cardiac function, the mice were euthanized, and the hearts were harvested, weighted and used for histological examination.
Statistical analysis
Data are expressed as the mean±S.E.M. of at least three independent experiments. We used a one-way analysis of variance for multiple comparisons. A value of P<0.05 was considered significant.
Abbreviations
- miRNA:
-
microRNA
- H2O2:
-
hydrogen peroxide
- PI:
-
propidium iodide
- CypD:
-
Cyclophilin D
- mPTP:
-
mitochondrial permeability transition pore
- I/R:
-
ischemia/reperfusion
- qRT-PCR:
-
quantitative reverse transcription-PCR
- TP:
-
target protector
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Acknowledgements
This work was supported by the National Natural Science Foundation of China (81270160) and the Beijing Natural Science Foundation (7142103).
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Wang, K., An, T., Zhou, LY. et al. E2F1-regulated miR-30b suppresses Cyclophilin D and protects heart from ischemia/reperfusion injury and necrotic cell death. Cell Death Differ 22, 743–754 (2015). https://doi.org/10.1038/cdd.2014.165
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DOI: https://doi.org/10.1038/cdd.2014.165
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