Startseite Knockdown of TUG1 rescues cardiomyocyte hypertrophy through targeting the miR-497/MEF2C axis
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Knockdown of TUG1 rescues cardiomyocyte hypertrophy through targeting the miR-497/MEF2C axis

  • Guorong Zhang EMAIL logo und Xinghua Ni
Veröffentlicht/Copyright: 16. März 2021
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Open Life Sciences
Aus der Zeitschrift Open Life Sciences Band 16 Heft 1

Abstract

The aim of this study was to investigate the detailed role and molecular mechanism of long noncoding RNA (lncRNA) taurine upregulated gene 1 (TUG1) in cardiac hypertrophy. Cardiac hypertrophy was established by transverse abdominal aortic constriction (TAC) in vivo or angiotensin II (Ang II) treatment in vitro. Levels of lncRNA TUG1, miR-497 and myocyte enhancer factor 2C (MEF2C) mRNA were assessed by quantitative reverse transcriptase PCR (qRT-PCR). Western blot assay was performed to determine the expression of MEF2C protein. The endogenous interactions among TUG1, miR-497 and MEF2C were confirmed by dual-luciferase reporter and RNA immunoprecipitation assays. Our data indicated that TUG1 was upregulated and miR-497 was downregulated in the TAC rat model and Ang II-induced cardiomyocytes. TUG1 knockdown or miR-497 overexpression alleviated the hypertrophy induced by Ang II in cardiomyocytes. Moreover, TUG1 acted as a sponge of miR-497, and MEF2C was directly targeted and repressed by miR-497. miR-497 overexpression mediated the protective role of TUG1 knockdown in Ang II-induced cardiomyocyte hypertrophy. MEF2C was a functional target of miR-497 in regulating Ang II-induced cardiomyocyte hypertrophy. In addition, TUG1 regulated MEF2C expression through sponging miR-497. Knockdown of TUG1 rescued Ang II-induced hypertrophy in cardiomyocytes at least partly through targeting the miR-497/MEF2C axis, highlighting a novel promising therapeutic target for cardiac hypertrophy treatment.

Keywords: cardiac hypertrophy; TUG1; miR-497; myocyte enhancer factor 2C

1 Introduction

Cardiac hypertrophy is a common physiological compensatory response of the heart against a number of stressors to maintain normal cardiac function. However, enlargement of the heart in response to myocardial injury, hypertensive stress or excessive neurohumoral activation is associated with maladaptive remodeling and cardiac dysfunction and is classified as pathological hypertrophy [1]. Pathological cardiac hypertrophy is a major risk factor for diomyopathy, heart failure and sudden cardiac death [2,3]. Despite the improvements of the understanding of pathological regulators in cardiac hypertrophy [4,5], the molecular mechanisms of cardiac hypertrophy remain largely unclear.

Long noncoding RNAs (lncRNAs) are more than 200 nucleotide RNA molecules that perform various functions in a series of important biological processes [6]. They have been discovered to have relevance to human diseases, including cardiac hypertrophy [7]. For example, Wang et al. reported that cardiac hypertrophy-related factor (CHRF) regulated cardiac hypertrophy by acting as a sponge of microRNA (miRNA)-489 [8]. Wang et al. identified that cardiac hypertrophy-associated epigenetic regulator (Chaer) worked as an epigenetic checkpoint in cardiac hypertrophy [9]. A recent study demonstrated that taurine upregulated gene 1 (TUG1) was involved in the pathogenesis of cardiac hypertrophy by sponging miRNA-29b-3p [10]. Herein, we identified the functional role and the underlying mechanisms of TUG1 in cardiac hypertrophy.

miRNAs, a class of endogenous, small noncoding RNAs with 20–22 nucleotides, are known to be present in the RNA-induced silencing complexes (RISCs), where they silence gene expression [11]. Dysregulation of miRNAs is found to have relevance to human diseases, including cardiac hypertrophy [12]. miR-497, a member of the miR-15 family, was identified as a novel regulator of cardiac hypertrophy and fibrosis by the repression of the TGFβ-pathway [13]. A recent study demonstrated that the increased expression of miR-497 ameliorated cardiac hypertrophy in vitro and in vivo via targeting sirtuin 4 (Sirt4) [14]. Previous studies had reported that TUG1 exerted a regulatory function in human disease through the competing endogenous RNA (ceRNA) network via sponging miRNAs [15,16]. However, the effect of interplay between TUG1 and miR-497 in cardiac hypertrophy remains undefined. In the present study, our data supported that TUG1 was upregulated in the TAC rat model and angiotensin II (Ang II)-induced cardiomyocytes. Furthermore, TUG1 knockdown attenuated cardiomyocyte hypertrophy in vitro by targeting the miR-497/myocyte enhancer factor 2C (MEF2C) axis.

2 Materials and methods

2.1 Animal care and use

Female Sprague-Dawley (SD) rats (8 weeks old, 190–220 g) were purchased from Henan Research Center of Laboratory Animal (Zhengzhou, Henan, China) and housed in a specific pathogen-free environment in the animal facility of the Fourth Affiliated Hospital of Nanchang University. All rats were kept at a constant temperature (22 ± 2°C) with 60% humidity and a 12 h light–dark cycle and fed a standard chow diet for at least 1 week before experimentation. All animal experimental procedures were performed in accordance with the Agriculture Guidebook of the Care and Use of Laboratory Animals.

  1. Ethical approval: The research related to animal use has been complied with all the relevant national regulations and institutional policies for the care and use of animals and was approved by the Animal Ethics Committee of the Fourth Affiliated Hospital of Nanchang University.

2.2 Animal model

Experimental rats were divided into two groups: (1) Sham group (n = 8), in which rats underwent exposure of abdominal aorta without ligation, and (2) transverse abdominal aortic constriction (TAC) group (n = 8), in which abdominal aorta of rats was exposed and ligated. The construct of the TAC rat model was performed as described previously [17]. Briefly, a 1.5–2.0 cm longitudinal incision was exposed to the left side of the rat abdomen. Then, a 4-0 suture was used to tie two circles around the abdominal aorta by a 12-gauge needle, after which the needle was eliminated. At 8 weeks after surgery, cardiac dimensions and function were analyzed using a Doppler echocardiography (Philios IE33 ultrasound system, Phillips Medical Systems, Andover, MA, USA) including the left ventricular end-diastolic dimension (LVEDD), the left ventricular end-systolic diameter (LVESD), the left ventricular end-systolic pressure (LVESP), the left ventricular end-diastolic pressure (LVEDP) and fractional shortening (FS). Subsequently, all rats were euthanized; the ratios of heart weight and body weight were determined; and heart tissues were collected for further evaluation.

2.3 Primary cardiomyocyte isolation, culture and treatment

Primary cardiomyocytes were isolated from the hearts of 1- to 3-day-old newborn SD rats as described previously with modification [18]. In brief, newborn rats were euthanized, and the hearts were immediately excised and minced. The heart tissues were digested with 0.1% collagenase type II (Gibco, Rockville, MD, USA) and 0.1% trypsin (Gibco) at 37°C. After centrifugation, cardiomyocytes were harvested and maintained in Dulbecco’s Modified Eagle Medium/Nutrient Mixture F-12 (DMEM/F-12, Gibco) supplemented with 10% fetal bovine serum (FBS, Gibco) and 1% penicillin/streptomycin (Gibco) in an incubator at 37°C with 5% CO2. To establish a cardiomyocyte hypertrophy model in vitro, the cardiomyocytes of ∼70% were treated with 1 mM of Ang II (Sigma-Aldrich, St. Louis, MO, USA) for 48 h.

2.4 Cell transfection

For TUG1 knockdown studies, cardiomyocytes were transiently introduced with siRNA targeting TUG1 (si-TUG1, GenePharma, Shanghai, China) or a nontarget siRNA (si-NC, GenePharma). For miR-497 overexpression, cardiomyocytes were transfected with the mature miR-497 mimic (GenePharma) or a scrambled oligonucleotide sequence (miR-NC mimic, GenePharma). miR-497 silencing was carried out using miR-497 inhibitor (in-miR-497, GenePharma), and in-miR-NC (GenePharma) was used as a negative control. For overexpression experiments, cardiomyocytes were introduced with pcDNA-based TUG1 or a MEF2C overexpression plasmid (pcDNA-TUG1 or pcDNA-MEF2C, GenePharma) or a negative control plasmid (pcDNA-NC, GenePharma). All transfections were performed using Lipofectamine 2000 transfection reagent (Invitrogen, Waltham, MA, USA) following the protocols of manufacturers.

2.5 Quantitative reverse transcriptase PCR

Total RNA was extracted from heart tissues and cardiomyocytes using RNA Purification kit (Invitrogen) in accordance with manufacturer’s instructions. The quality and quantity of RNA extracts were assessed by a NanoDrop ND-2000 Spectrophotometer (NanoDrop Technologies, Wilmington, DE, USA). The levels of atrial natriuretic peptide (ANP), brain natriuretic peptide (BNP), β-myosin heavy chain (β-MHC), TUG1 and MEF2C mRNA were detected by using quantitative reverse transcriptase PCR (qRT-PCR). Total RNA (1 µg) was reverse transcribed into cDNA using M-MLV reverse transcriptase (Invitrogen), and qRT-PCR was carried out using PowerUpTM SYBRTM Green PCR Master Mix (Applied Biosystems) on the ABI 7900HT sequence detector (Applied Biosystems) following the protocols of manufacturers. The indicated gene expression levels were normalized against glyceraldehyde-3-phosphate dehydrogenase (GAPDH). The level of mature miR-497 was determined by qRT-PCR using TaqMan reverse transcription kit (Applied Biosystems, Foster City, CA, USA) and TaqMan MicroRNA assay kit (Applied Biosystems) with snRNA RNU6B as an internal control. The amplification profile was denatured at 95°C for 10 min, followed by 40 cycles of 95°C for 20 s and 60°C for 1 min. Relative gene expression was calculated based on the 2−∆∆Ct method.

2.6 Western blot

Total protein was prepared in ice-cold RIPA buffer (150 mM Tris-HCl, pH = 7.6, 150 mM NaCl, 0.5% Triton X-100, 0.1% SDS, 1 mM phenylmethanesulfonyl fluoride, 1 mM Na3VO4) containing a cocktail of protease inhibitors (Thermo Fisher Scientific, Waltham, MA, USA) and then quantified using a BCA Protein assay kit (Thermo Fisher Scientific). Protein extracts were resolved on a 10% SDS-polyacrylamide gel and electrophoretically transferred onto a polyvinylidene fluoride (PVDF) membrane (Millipore, Bedford, MA, USA). The following primary antibodies were used: anti-ANP (Abcam, Cambridge, UK; dilution 1:1,000), anti-BNP (Abcam; dilution 1:500), anti-β-MHC (Abcam; dilution 1:1,000), anti-MEF2C (Abcam; dilution 1:1,000) and anti-β-actin (Abcam; dilution 1:3,000). The horseradish peroxidase-conjugated anti-rabbit (Abcam; dilution 1:5,000) or anti-mouse (Abcam; dilution 1:5,000) IgG was used as a secondary antibody. Protein bands were detected using the enhanced chemiluminescence (ECL) detection kit (Immobilon Western Chemiluminescent HRP Substrate, Millipore) and analyzed using ImageJ software (National Institutes of Health, Bethesda, MD, USA).

2.7 Bioinformatic analysis and dual-luciferase reporter assay

Online database LncBase Predicted v.2 (http://carolina.imis.athena-innovation.gr/diana_tools/web/index.php?r=lncbasev2%2Findex-predicted) was used to help identify the miRNAs that potentially bind to TUG1. Bioinformatic analysis for the molecular targets of miR-497 was performed using microT-CDS software at http://diana.imis.athena-innovation.gr/DianaTools/index.php?r=microT_CDS/index. TUG1 and MEF2C 3′UTR luciferase reporter plasmids (TUG1-WT and MEF2C 3′UTR-WT) harboring the miR-497-binding sites and the site-directed mutations of the seed region (TUG1-MUT and MEF2C 3′UTR-MUT) were obtained from GenePharma. The cardiomyocytes were cotransfected with each reporter construct and miR-NC mimic or miR-497 mimic. After 48 h transfection, the luciferase activity was determined using a dual-luciferase reporter assay system (Promege, Madison, WI, USA) following manufacturer’s guidance.

2.8 RNA immunoprecipitation assay

RNA immunoprecipitation (RIP) assay was carried out using the Magna RIP RNA Immunoprecipitation kit (Millipore) with anti-Argonaute 2 (anti-Ago2, Abcam) antibody. Briefly, cell lysates were prepared using the ice-cold RIPA buffer and then incubated with anti-Ago2 or negative control IgG antibody at 4°C for 4 h, followed by the incubation with protein A/G agarose for 4 h. Beads were harvested by centrifugation and washed three times using ice-cold PBS. Next, total RNA was extracted, and the enrichment levels of TUG1 and MEF2C mRNA were detected by qRT-PCR.

2.9 Statistical analysis

All data were analyzed using GraphPad Prism 5.0 software (GraphPad Software, Inc., San Diego, CA, USA) and expressed as mean ± standard deviation (SD). All experiments were carried out in triplicate. Differences between groups were compared by Student’s t-test or analysis of variance (ANOVA). A probability value of P < 0.05 was considered to be significant.

3 Results

3.1 TUG1 level was upregulated in the TAC rat model and Ang II-induced cardiomyocytes

To investigate the involvement of TUG1 in cardiac hypertrophy, we first established the cardiac hypertrophy model by TAC in vivo and Ang II treatment in vitro. By contrast, TAC led to a significant increase of LVEDD, LVESD and LVEDP and a striking reduction of LVESP and FS, as well as a strong elevation of the radio of heart weight and body weight (Figure A1a–f). Moreover, TAC caused a remarkable increase in the levels of hypertrophy-related genes ANP, BNP and β-MHC (Figure A1g and h), demonstrating the successful establishment for the TAC rat model. Furthermore, Ang II treatment remarkably increased the levels of ANP, BNP and β-MHC in cardiomyocytes (Figure A1i and j). Interestingly, as shown by qRT-PCR, the TUG1 level was significantly upregulated in the TAC model and Ang II-treated cardiomyocytes (Figure 1a and b).

Figure 1 TUG1 was upregulated in the TAC rat model and Ang II-treated cardiomyocytes. Relative TUG1 level by qRT-PCR in the untreated heart tissues (control), Sham model and TAC model (a), and untreated (Control), Mock-treated (Blank) and Ang II-treated cardiomyocytes (b). *P < 0.05.
Figure 1

TUG1 was upregulated in the TAC rat model and Ang II-treated cardiomyocytes. Relative TUG1 level by qRT-PCR in the untreated heart tissues (control), Sham model and TAC model (a), and untreated (Control), Mock-treated (Blank) and Ang II-treated cardiomyocytes (b). *P < 0.05.

3.2 Knockdown of TUG1 attenuated Ang II-induced cardiomyocyte hypertrophy

To further investigate the functional role of TUG1 in cardiac hypertrophy, we performed loss-of-function experiments with si-TUG1. Transient transfection of si-TUG1, but not a scrambled control sequence, resulted in a significant decrease in the level of TUG1 in Ang II-treated cardiomyocytes (Figure 2a). Subsequent qRT-PCR and western blot assays revealed that in comparison to the negative control, TUG1 knockdown triggered a remarkable reduction in the expression of ANP, BNP and β-MHC at both mRNA and protein levels in Ang II-treated cardiomyocytes (Figure 2b and c).

Figure 2 TUG1 knockdown attenuated Ang II-induced cardiomyocyte hypertrophy. Cardiomyocytes were transfected with si-NC or si-TUG1 for 24 h and then treated with 1 mM of Ang II for 48 h, followed by the determination of TUG1 expression by qRT-PCR (a), the mRNA levels of ANP, BNP and β-MHC by qRT-PCR (b) and their protein levels by western blot (c). *P < 0.05.
Figure 2

TUG1 knockdown attenuated Ang II-induced cardiomyocyte hypertrophy. Cardiomyocytes were transfected with si-NC or si-TUG1 for 24 h and then treated with 1 mM of Ang II for 48 h, followed by the determination of TUG1 expression by qRT-PCR (a), the mRNA levels of ANP, BNP and β-MHC by qRT-PCR (b) and their protein levels by western blot (c). *P < 0.05.

3.3 TUG1 acted as a molecular sponge of miR-497

To further understand the function of TUG1 in cardiac hypertrophy, we used online database LncBase Predicted v.2 to help identify the miRNAs that potentially bind to TUG1. Among these candidates, we selected several miRNAs (miR-93, miR-142-3p, miR-103, miR-631-5p, miR-16-5p and miR-497), which were related to cardiomyocyte hypertrophy and were downregulated in cardiomyocyte hypertrophy. Our results showed that miR-497 was the most significantly upregulated miRNA in TUG1-silencing cardiomyocytes (Figure A2), and thus, we selected miR-497 for further investigation. These data revealed a putative target sequence for miR-497 within TUG1 (Figure 3a). To validate this, we carried out dual-luciferase reporter assays. When we cloned the TUG1 segment harboring the miR-497-binding sequence into a luciferase reporter, the cotransfection of TUG1 wild-type reporter and miR-497 mimic into cardiomyocytes caused lower luciferase activity than cells cotransfected with miR-NC mimic (Figure 3b). However, when the target sites were mutated, no reduction was observed in luciferase in the presence of miR-497 mimic (Figure 3b). Ago2, a core component of the RISC, acts as a crucial regulator in the mature process of miRNA [11]. Thus, RIP experiments were done using anti-Ago2 antibody. The data showed that TUG1 enrichment was significantly elevated by miR-497 overexpression (Figure 3c), eliciting the potential endogenous interaction between TUG1 and miR-497. The data of qRT-PCR also revealed that miR-497 was prominently downregulated in the TAC model and Ang II-treated cardiomyocytes (Figure 3d and e). Furthermore, in comparison to their counterparts, miR-497 expression was significantly decreased by TUG1 overexpression plasmid, and it was remarkably increased in case of TUG1 depletion in cardiomyocytes (Figure 3f).

Figure 3 TUG1 acted as a molecular sponge of miR-497. (a) Schematic of the miR-497-binding sites within TUG1 and mutated miR-497-binding sites. (b) Relative luciferase activity in cardiomyocytes cotransfected with TUG1-WT or TUG1-MUT and miR-NC mimic or miR-497 mimic. (c) TUG1 enrichment in the RISC of cardiomyocytes transfected with miR-NC mimic or miR-497 mimic using anti-Ago2 antibody. TUG1 expression by qRT-PCR in the untreated heart tissues (control), Sham model and TAC model (d), and untreated (control), Mock-treated (Blank) and Ang II-induced cardiomyocytes (e) and cardiomyocytes transfected with pcDNA, pcDNA-TUG1, si-NC or si-TUG1 (f). *P < 0.05.
Figure 3

TUG1 acted as a molecular sponge of miR-497. (a) Schematic of the miR-497-binding sites within TUG1 and mutated miR-497-binding sites. (b) Relative luciferase activity in cardiomyocytes cotransfected with TUG1-WT or TUG1-MUT and miR-NC mimic or miR-497 mimic. (c) TUG1 enrichment in the RISC of cardiomyocytes transfected with miR-NC mimic or miR-497 mimic using anti-Ago2 antibody. TUG1 expression by qRT-PCR in the untreated heart tissues (control), Sham model and TAC model (d), and untreated (control), Mock-treated (Blank) and Ang II-induced cardiomyocytes (e) and cardiomyocytes transfected with pcDNA, pcDNA-TUG1, si-NC or si-TUG1 (f). *P < 0.05.

3.4 miR-497 overexpression mediated the protective role of TUG1 knockdown in Ang II-induced cardiomyocyte hypertrophy

To determine whether TUG1 modulated cardiomyocyte hypertrophy by miR-497, we reduced miR-497 expression in si-TUC1-transfected cardiomyocytes before Ang II treatment. The results of qRT-PCR showed that si-TUG1-mediated miR-497 upregulation was strikingly reversed by in-miR-497 transfection (Figure 4a). Moreover, the reduced effects of TUG1 knockdown on ANP, BNP and β-MHC expression were significantly abolished by miR-497 level restoration in Ang II-treated cardiomyocytes (Figure 4b and c).

Figure 4 miR-497 overexpression mediated the protective role of TUG1 knockdown in Ang II-induced cardiomyocyte hypertrophy. Cardiomyocytes were transfected with si-NC, si-TUG1, si-TUG1 + in-miR-NC or si-TUG1 + in-miR-497 before Ang II exposure, followed by the measurement of miR-497 expression by qRT-PCR (a), the mRNA levels of ANP, BNP and β-MHC by qRT-PCR (b) and their protein levels by western blot (c). *P < 0.05.
Figure 4

miR-497 overexpression mediated the protective role of TUG1 knockdown in Ang II-induced cardiomyocyte hypertrophy. Cardiomyocytes were transfected with si-NC, si-TUG1, si-TUG1 + in-miR-NC or si-TUG1 + in-miR-497 before Ang II exposure, followed by the measurement of miR-497 expression by qRT-PCR (a), the mRNA levels of ANP, BNP and β-MHC by qRT-PCR (b) and their protein levels by western blot (c). *P < 0.05.

3.5 TUG1-regulated MEF2C expression through sponging miR-497

miRNAs exert biological function by regulating their target genes. Herein, to further understand the underlying mechanism by which miR-497 regulated cardiac hypertrophy, we carried out a detailed analysis for its molecular targets. Using microT-CDS software, the predicted data showed a putative complementary sequence for miR-497 within the 3′UTR of MEF2C mRNA (Figure 5a). To confirm whether MEF2C was a direct target of miR-497, dual-luciferase reporter assays were performed using an MEF2C 3′UTR reporter (MEF2C 3′UTR-WT) harboring the miR-497-binding sequence and the site-directed mutation of the seed region (MEF2C 3′UTR-MUT). In contrast to the negative control, the transfection of miR-497 mimic significantly reduced the luciferase activity of MEF2C 3′UTR-WT (Figure 5b). However, the site-directed mutation of the miR-497-binding region strikingly abolished the suppression of miR-497 on reporter gene expression (Figure 5b). RIP assays revealed that compared with the negative control, the enrichment level of MEF2C mRNA was substantially elevated by miR-497 overexpression (Figure 5c). In addition, qRT-PCR assays demonstrated that the expression of MEF2C mRNA was remarkably upregulated in the TAC model and Ang II-treated cardiomyocytes (Figure 5d and e). Moreover, in contrast to their counterparts, MEF2C protein expression was significantly decreased by miR-497 overexpression, and it was highly increased with in-miR-497 transfection (Figure 5f). We further determined whether TUG1 modulated the expression of MEF2C in cardiomyocytes. As expected, the MEF2C level was prominently elevated by TUG1 overexpression, and this effect was strongly abolished by miR-497 mimic transfection (Figure 5g).

Figure 5 TUG1-regulated MEF2C expression through sponging miR-497. (a) Nucleotide resolution of the predicted miR-497-binding sites within the 3′UTR of MEF2C mRNA and the mutant of the seed region. (b) Relative luciferase activity in cardiomyocytes cotransfected with MEF2C 3′UTR-WT or MEF2C 3′UTR-MUT and miR-NC mimic or miR-497 mimic. (c) The enrichment of MEF2C mRNA in the RISC of cardiomyocytes transfected with miR-NC mimic or miR-497 mimic using anti-Ago2 antibody. MEF2C expression by qRT-PCR or western blot in TAC model (d), Ang II-treated cardiomyocytes (e) and cardiomyocytes transfected with miR-NC mimic, miR-497 mimic, in-miR-NC or in-miR-497 (f). (g) MEF2C expression by western blot in cardiomyocytes transfected with pcDNA, pcDNA-TUG1, pcDNA-TUG1 + miR-NC mimic or pcDNA-TUG1 + miR-497 mimic. *P < 0.05.
Figure 5

TUG1-regulated MEF2C expression through sponging miR-497. (a) Nucleotide resolution of the predicted miR-497-binding sites within the 3′UTR of MEF2C mRNA and the mutant of the seed region. (b) Relative luciferase activity in cardiomyocytes cotransfected with MEF2C 3′UTR-WT or MEF2C 3′UTR-MUT and miR-NC mimic or miR-497 mimic. (c) The enrichment of MEF2C mRNA in the RISC of cardiomyocytes transfected with miR-NC mimic or miR-497 mimic using anti-Ago2 antibody. MEF2C expression by qRT-PCR or western blot in TAC model (d), Ang II-treated cardiomyocytes (e) and cardiomyocytes transfected with miR-NC mimic, miR-497 mimic, in-miR-NC or in-miR-497 (f). (g) MEF2C expression by western blot in cardiomyocytes transfected with pcDNA, pcDNA-TUG1, pcDNA-TUG1 + miR-NC mimic or pcDNA-TUG1 + miR-497 mimic. *P < 0.05.

3.6 MEF2C was a functional target of miR-497 in regulating Ang II-induced cardiomyocyte hypertrophy

To provide further mechanistic insight into the link between miR-497 and MEF2C in cardiac hypertrophy, we cotransfected miR-497 mimic and pcDNA-MEF2C into cardiomyocytes before Ang II induction. In contrast to the negative control, the cotransfection of pcDNA-MEF2C significantly reversed the repressive effect of miR-497 overexpression on MEF2C expression (Figure 6a). Moreover, the restored level of MEF2C remarkably abolished the reduction of miR-497 overexpression on ANP, BNP and β-MHC levels in Ang II-treated cardiomyocytes (Figure 6b and c).

Figure 6 Overexpression of miR-497 exerted its antihypertrophic effect in Ang II-treated cardiomyocytes by MEF2C. Cardiomyocytes were transfected with miR-NC mimic, miR-497 mimic, miR-497 mimic + pcDNA-NC or miR-497 mimic + pcDNA-MEF2C before Ang II exposure, followed by the measurement of MEF2C protein expression by western blot (a), the mRNA levels of ANP, BNP and β-MHC by qRT-PCR (b) and their protein levels by western blot (c). *P < 0.05.
Figure 6

Overexpression of miR-497 exerted its antihypertrophic effect in Ang II-treated cardiomyocytes by MEF2C. Cardiomyocytes were transfected with miR-NC mimic, miR-497 mimic, miR-497 mimic + pcDNA-NC or miR-497 mimic + pcDNA-MEF2C before Ang II exposure, followed by the measurement of MEF2C protein expression by western blot (a), the mRNA levels of ANP, BNP and β-MHC by qRT-PCR (b) and their protein levels by western blot (c). *P < 0.05.

4 Discussion

Pathological cardiac hypertrophy has been widely known to cause the deposition of extracellular collagen, the loss of adrenergic responsivity and metabolic disorder, thereby leading to heart failure [19]. It was reported that cardiac hypertrophy could be established by Ang II induction in vitro and TAC surgery in vivo [17,20]. In the present study, we successfully established cardiac hypertrophy in vivo and in vitro, as evidenced by changes of hemodynamic parameters, the radio of heart weight and body weight and levels of ANP, BNP and β-MHC. Up to now, many lncRNAs have been identified as positive or negative regulators in cardiac hypertrophic pathways [21,22,23]. In this study, we first demonstrated that TUG1 alleviated cardiomyocyte hypertrophy in Ang II-induced cardiomyocytes through targeting the miR-497/MEF2C axis.

It was reported that TUG1 enhanced cardiac fibroblast transformation to myofibroblast by sponging miR-29c under hypoxia [24]. TUG1 had been found to play a crucial role in hypoxia-induced myocardial cell damage via regulating B-cell lymphoma 2 interacting protein 3 (Binp3) by sponging miR-145-5p [25]. In the current study, our data demonstrated that TUG1 was upregulated in the TAC rat model and Ang II-induced cardiomyocytes, and TUG1 knockdown attenuated Ang II-induced cardiomyocyte hypertrophy in agreement with the previous study [10].

Then, we used online database LncBase Predicted v.2 to help identify miRNAs that potentially bind to TUG1. Among these candidates, we selected miR-497 for further investigation, and we first verified that TUG1 acted as a miR-497 sponge. miR-497, a member of the miR-15 family, has been identified as a tumor-suppressive miRNA in a variety of human cancers, such as breast cancer [26], non-small cell lung cancer [27] and osteosarcoma [28]. Moreover, miR-497 was uncovered to be involved in the postnatal quiescence of skeletal muscle stem cells and osteoblast differentiation by targeting BMP signaling [29,30]. A previous document reported that miR-497 acted as a crucial regulator in cardiomyocyte mitotic arrest [31]. In the present study, our data revealed that miR-497 expression was downregulated in the TAC rat model and Ang II-induced cardiomyocytes, in accordance with a recent study [14]. Similar with the findings by Xiao et al. [14], we demonstrated that the enforced level of miR-497 rescued cardiomyocyte hypertrophy in vitro. Moreover, we first uncovered that miR-497 was a functional mediator of TUG1 in regulating Ang II-induced cardiomyocyte hypertrophy.

miRNAs are widely accepted to direct posttranscriptional repression of mRNA targets in cellular pathophysiology processes. Therefore, microT-CDS software was used to predict the potential targets of miR-497. Among these candidates, MEF2C was interesting in the present study owing to the crucial involvement of MEF2C in heart development, cardiomyocyte reprogramming and hypertrophic cardiomyopathy [32,33,34]. MEF2C has been emphasized as a signal-responsive mediator of the cardiac transcriptional program and plays a key role in the development of cardiac hypertrophy [35,36]. In addition, MEF2C deficiency alleviated the left ventricular hypertrophy induced by pressure overload through regulating the mTOR/S6K pathway in mice [37]. A previous study identified that MEF2C activation triggered by insulin-like growth factor-1 (IFG-1) mediated the pro-hypertrophic function of IGF-1 on the expression of cardiac gene [38]. In addition, the calcineurin-MEF2C pathway was demonstrated to participate in cardiac hypertrophy induced by endoplasmic reticulum stress in neonatal rat cardiomyocytes [39]. In the present study, we first verified that MEF2C was directly targeted and repressed by miR-497 in cardiomyocytes. Results of this study indicated that MEF2C was a functionally important target of miR-497 in modulating Ang II-induced cardiomyocyte hypertrophy. Similarly, Sato et al. reported that miR-214-3p played a repressive role in cardiac hypertrophy induced by Ang II via targeting MEF2C [29]. Xiao et al. demonstrated that the high level of miR-497 suppressed myocardial hypertrophy in vitro and in vivo through targeting Sirt4 [14]. More interestingly, we were first to validate that TUG1 modulated MEF2C expression through sponging miR-497. In addition, Zhao et al. highlighted that the silencing of TUG1 ameliorated diabetic cardiomyopathy-induced diastolic dysfunction via directly targeting miR-499-5p [40].

5 Conclusion

Our present study suggested that TUG1 knockdown alleviated Ang II-induced hypertrophy in cardiomyocytes at least in part through targeting the miR-497/MEF2C axis. The clinical significance of TUG1 and its potential value as a therapeutic target should be further explored.

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Appendix

Figure A1 The establishment of cardiac hypertrophy model by TAC in vivo and Ang II treatment in vitro. Analysis for LVEDD (a), LVESD (b), LVESP (c), LVEDP (d) and FS (e), heart weight/body weight ratio (f) in the TAC rat model. mRNA levels of ANP, BNP and β-MHC by qRT-PCR (g), and their protein levels by western blot (h) in the TAC rat model. Primary cardiomyocytes were treated with 1 mM of Ang II for 48 h, followed by the detection of ANP, BNP and β-MHC mRNA levels by qRT-PCR (i) and their protein levels by western blot (j). *P < 0.05.
Figure A1

The establishment of cardiac hypertrophy model by TAC in vivo and Ang II treatment in vitro. Analysis for LVEDD (a), LVESD (b), LVESP (c), LVEDP (d) and FS (e), heart weight/body weight ratio (f) in the TAC rat model. mRNA levels of ANP, BNP and β-MHC by qRT-PCR (g), and their protein levels by western blot (h) in the TAC rat model. Primary cardiomyocytes were treated with 1 mM of Ang II for 48 h, followed by the detection of ANP, BNP and β-MHC mRNA levels by qRT-PCR (i) and their protein levels by western blot (j). *P < 0.05.

Figure A2 The effect of TUG1 on the expression of six miRNAs in cardiomyocytes. Relative expression levels of miR-93, miR-142-3p, miR-103, miR-631-5p, miR-16-5p and miR-497 by qRT-PCR in cardiomyocytes transfected with si-NC or si-TUG1. *P < 0.05.
Figure A2

The effect of TUG1 on the expression of six miRNAs in cardiomyocytes. Relative expression levels of miR-93, miR-142-3p, miR-103, miR-631-5p, miR-16-5p and miR-497 by qRT-PCR in cardiomyocytes transfected with si-NC or si-TUG1. *P < 0.05.

  1. Funding: The authors state no funding involved.

  2. Conflict of interest: The authors state no conflict of interest.

  3. Data availability statement: The datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.

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Received: 2020-01-05
Revised: 2020-10-13
Accepted: 2020-10-26
Published Online: 2021-03-16

© 2021 Guorong Zhang and Xinghua Ni, published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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https://doi.org/10.1515/biol-2021-0025
Schlagwörter für diesen Artikel
cardiac hypertrophy; TUG1; miR-497; myocyte enhancer factor 2C
Creative Commons
BY 4.0

Artikel in diesem Heft

  1. Biomedical Sciences
  2. Research progress on the mechanism of orexin in pain regulation in different brain regions
  3. Adriamycin-resistant cells are significantly less fit than adriamycin-sensitive cells in cervical cancer
  4. Exogenous spermidine affects polyamine metabolism in the mouse hypothalamus
  5. Iris metastasis of diffuse large B-cell lymphoma misdiagnosed as primary angle-closure glaucoma: A case report and review of the literature
  6. LncRNA PVT1 promotes cervical cancer progression by sponging miR-503 to upregulate ARL2 expression
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  8. Circ_0091579 enhances the malignancy of hepatocellular carcinoma via miR-1287/PDK2 axis
  9. Silencing XIST mitigated lipopolysaccharide (LPS)-induced inflammatory injury in human lung fibroblast WI-38 cells through modulating miR-30b-5p/CCL16 axis and TLR4/NF-κB signaling pathway
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  28. Blocking circ_UBR4 suppressed proliferation, migration, and cell cycle progression of human vascular smooth muscle cells in atherosclerosis
  29. Gene therapy in PIDs, hemoglobin, ocular, neurodegenerative, and hemophilia B disorders
  30. Downregulation of circ_0037655 impedes glioma formation and metastasis via the regulation of miR-1229-3p/ITGB8 axis
  31. Vitamin D deficiency and cardiovascular risk in type 2 diabetes population
  32. Circ_0013359 facilitates the tumorigenicity of melanoma by regulating miR-136-5p/RAB9A axis
  33. Mechanisms of circular RNA circ_0066147 on pancreatic cancer progression
  34. lncRNA myocardial infarction-associated transcript (MIAT) knockdown alleviates LPS-induced chondrocytes inflammatory injury via regulating miR-488-3p/sex determining region Y-related HMG-box 11 (SOX11) axis
  35. Identification of circRNA circ-CSPP1 as a potent driver of colorectal cancer by directly targeting the miR-431/LASP1 axis
  36. Hyperhomocysteinemia exacerbates ischemia-reperfusion injury-induced acute kidney injury by mediating oxidative stress, DNA damage, JNK pathway, and apoptosis
  37. Potential prognostic markers and significant lncRNA–mRNA co-expression pairs in laryngeal squamous cell carcinoma
  38. Gamma irradiation-mediated inactivation of enveloped viruses with conservation of genome integrity: Potential application for SARS-CoV-2 inactivated vaccine development
  39. ADHFE1 is a correlative factor of patient survival in cancer
  40. The association of transcription factor Prox1 with the proliferation, migration, and invasion of lung cancer
  41. Is there a relationship between the prevalence of autoimmune thyroid disease and diabetic kidney disease?
  42. Immunoregulatory function of Dictyophora echinovolvata spore polysaccharides in immunocompromised mice induced by cyclophosphamide
  43. T cell epitopes of SARS-CoV-2 spike protein and conserved surface protein of Plasmodium malariae share sequence homology
  44. Anti-obesity effect and mechanism of mesenchymal stem cells influence on obese mice
  45. Long noncoding RNA HULC contributes to paclitaxel resistance in ovarian cancer via miR-137/ITGB8 axis
  46. Glucocorticoids protect HEI-OC1 cells from tunicamycin-induced cell damage via inhibiting endoplasmic reticulum stress
  47. Prognostic value of the neutrophil-to-lymphocyte ratio in acute organophosphorus pesticide poisoning
  48. Gastroprotective effects of diosgenin against HCl/ethanol-induced gastric mucosal injury through suppression of NF-κβ and myeloperoxidase activities
  49. Silencing of LINC00707 suppresses cell proliferation, migration, and invasion of osteosarcoma cells by modulating miR-338-3p/AHSA1 axis
  50. Successful extracorporeal membrane oxygenation resuscitation of patient with cardiogenic shock induced by phaeochromocytoma crisis mimicking hyperthyroidism: A case report
  51. Effects of miR-185-5p on replication of hepatitis C virus
  52. Lidocaine has antitumor effect on hepatocellular carcinoma via the circ_DYNC1H1/miR-520a-3p/USP14 axis
  53. Primary localized cutaneous nodular amyloidosis presenting as lymphatic malformation: A case report
  54. Multimodal magnetic resonance imaging analysis in the characteristics of Wilson’s disease: A case report and literature review
  55. Therapeutic potential of anticoagulant therapy in association with cytokine storm inhibition in severe cases of COVID-19: A case report
  56. Neoadjuvant immunotherapy combined with chemotherapy for locally advanced squamous cell lung carcinoma: A case report and literature review
  57. Rufinamide (RUF) suppresses inflammation and maintains the integrity of the blood–brain barrier during kainic acid-induced brain damage
  58. Inhibition of ADAM10 ameliorates doxorubicin-induced cardiac remodeling by suppressing N-cadherin cleavage
  59. Invasive ductal carcinoma and small lymphocytic lymphoma/chronic lymphocytic leukemia manifesting as a collision breast tumor: A case report and literature review
  60. Clonal diversity of the B cell receptor repertoire in patients with coronary in-stent restenosis and type 2 diabetes
  61. CTLA-4 promotes lymphoma progression through tumor stem cell enrichment and immunosuppression
  62. WDR74 promotes proliferation and metastasis in colorectal cancer cells through regulating the Wnt/β-catenin signaling pathway
  63. Down-regulation of IGHG1 enhances Protoporphyrin IX accumulation and inhibits hemin biosynthesis in colorectal cancer by suppressing the MEK-FECH axis
  64. Curcumin suppresses the progression of gastric cancer by regulating circ_0056618/miR-194-5p axis
  65. Scutellarin-induced A549 cell apoptosis depends on activation of the transforming growth factor-β1/smad2/ROS/caspase-3 pathway
  66. lncRNA NEAT1 regulates CYP1A2 and influences steroid-induced necrosis
  67. A two-microRNA signature predicts the progression of male thyroid cancer
  68. Isolation of microglia from retinas of chronic ocular hypertensive rats
  69. Changes of immune cells in patients with hepatocellular carcinoma treated by radiofrequency ablation and hepatectomy, a pilot study
  70. Calcineurin Aβ gene knockdown inhibits transient outward potassium current ion channel remodeling in hypertrophic ventricular myocyte
  71. Aberrant expression of PI3K/AKT signaling is involved in apoptosis resistance of hepatocellular carcinoma
  72. Clinical significance of activated Wnt/β-catenin signaling in apoptosis inhibition of oral cancer
  73. circ_CHFR regulates ox-LDL-mediated cell proliferation, apoptosis, and EndoMT by miR-15a-5p/EGFR axis in human brain microvessel endothelial cells
  74. Resveratrol pretreatment mitigates LPS-induced acute lung injury by regulating conventional dendritic cells’ maturation and function
  75. Ubiquitin-conjugating enzyme E2T promotes tumor stem cell characteristics and migration of cervical cancer cells by regulating the GRP78/FAK pathway
  76. Carriage of HLA-DRB1*11 and 1*12 alleles and risk factors in patients with breast cancer in Burkina Faso
  77. Protective effect of Lactobacillus-containing probiotics on intestinal mucosa of rats experiencing traumatic hemorrhagic shock
  78. Glucocorticoids induce osteonecrosis of the femoral head through the Hippo signaling pathway
  79. Endothelial cell-derived SSAO can increase MLC20 phosphorylation in VSMCs
  80. Downregulation of STOX1 is a novel prognostic biomarker for glioma patients
  81. miR-378a-3p regulates glioma cell chemosensitivity to cisplatin through IGF1R
  82. The molecular mechanisms underlying arecoline-induced cardiac fibrosis in rats
  83. TGF-β1-overexpressing mesenchymal stem cells reciprocally regulate Th17/Treg cells by regulating the expression of IFN-γ
  84. The influence of MTHFR genetic polymorphisms on methotrexate therapy in pediatric acute lymphoblastic leukemia
  85. Red blood cell distribution width-standard deviation but not red blood cell distribution width-coefficient of variation as a potential index for the diagnosis of iron-deficiency anemia in mid-pregnancy women
  86. Small cell neuroendocrine carcinoma expressing alpha fetoprotein in the endometrium
  87. Superoxide dismutase and the sigma1 receptor as key elements of the antioxidant system in human gastrointestinal tract cancers
  88. Molecular characterization and phylogenetic studies of Echinococcus granulosus and Taenia multiceps coenurus cysts in slaughtered sheep in Saudi Arabia
  89. ITGB5 mutation discovered in a Chinese family with blepharophimosis-ptosis-epicanthus inversus syndrome
  90. ACTB and GAPDH appear at multiple SDS-PAGE positions, thus not suitable as reference genes for determining protein loading in techniques like Western blotting
  91. Facilitation of mouse skin-derived precursor growth and yield by optimizing plating density
  92. 3,4-Dihydroxyphenylethanol ameliorates lipopolysaccharide-induced septic cardiac injury in a murine model
  93. Downregulation of PITX2 inhibits the proliferation and migration of liver cancer cells and induces cell apoptosis
  94. Expression of CDK9 in endometrial cancer tissues and its effect on the proliferation of HEC-1B
  95. Novel predictor of the occurrence of DKA in T1DM patients without infection: A combination of neutrophil/lymphocyte ratio and white blood cells
  96. Investigation of molecular regulation mechanism under the pathophysiology of subarachnoid hemorrhage
  97. miR-25-3p protects renal tubular epithelial cells from apoptosis induced by renal IRI by targeting DKK3
  98. Bioengineering and Biotechnology
  99. Green fabrication of Co and Co3O4 nanoparticles and their biomedical applications: A review
  100. Agriculture
  101. Effects of inorganic and organic selenium sources on the growth performance of broilers in China: A meta-analysis
  102. Crop-livestock integration practices, knowledge, and attitudes among smallholder farmers: Hedging against climate change-induced shocks in semi-arid Zimbabwe
  103. Food Science and Nutrition
  104. Effect of food processing on the antioxidant activity of flavones from Polygonatum odoratum (Mill.) Druce
  105. Vitamin D and iodine status was associated with the risk and complication of type 2 diabetes mellitus in China
  106. Diversity of microbiota in Slovak summer ewes’ cheese “Bryndza”
  107. Comparison between voltammetric detection methods for abalone-flavoring liquid
  108. Composition of low-molecular-weight glutenin subunits in common wheat (Triticum aestivum L.) and their effects on the rheological properties of dough
  109. Application of culture, PCR, and PacBio sequencing for determination of microbial composition of milk from subclinical mastitis dairy cows of smallholder farms
  110. Investigating microplastics and potentially toxic elements contamination in canned Tuna, Salmon, and Sardine fishes from Taif markets, KSA
  111. From bench to bar side: Evaluating the red wine storage lesion
  112. Establishment of an iodine model for prevention of iodine-excess-induced thyroid dysfunction in pregnant women
  113. Plant Sciences
  114. Characterization of GMPP from Dendrobium huoshanense yielding GDP-D-mannose
  115. Comparative analysis of the SPL gene family in five Rosaceae species: Fragaria vesca, Malus domestica, Prunus persica, Rubus occidentalis, and Pyrus pyrifolia
  116. Identification of leaf rust resistance genes Lr34 and Lr46 in common wheat (Triticum aestivum L. ssp. aestivum) lines of different origin using multiplex PCR
  117. Investigation of bioactivities of Taxus chinensis, Taxus cuspidata, and Taxus × media by gas chromatography-mass spectrometry
  118. Morphological structures and histochemistry of roots and shoots in Myricaria laxiflora (Tamaricaceae)
  119. Transcriptome analysis of resistance mechanism to potato wart disease
  120. In silico analysis of glycosyltransferase 2 family genes in duckweed (Spirodela polyrhiza) and its role in salt stress tolerance
  121. Comparative study on growth traits and ions regulation of zoysiagrasses under varied salinity treatments
  122. Role of MS1 homolog Ntms1 gene of tobacco infertility
  123. Biological characteristics and fungicide sensitivity of Pyricularia variabilis
  124. In silico/computational analysis of mevalonate pyrophosphate decarboxylase gene families in Campanulids
  125. Identification of novel drought-responsive miRNA regulatory network of drought stress response in common vetch (Vicia sativa)
  126. How photoautotrophy, photomixotrophy, and ventilation affect the stomata and fluorescence emission of pistachios rootstock?
  127. Apoplastic histochemical features of plant root walls that may facilitate ion uptake and retention
  128. Ecology and Environmental Sciences
  129. The impact of sewage sludge on the fungal communities in the rhizosphere and roots of barley and on barley yield
  130. Domestication of wild animals may provide a springboard for rapid variation of coronavirus
  131. Response of benthic invertebrate assemblages to seasonal and habitat condition in the Wewe River, Ashanti region (Ghana)
  132. Molecular record for the first authentication of Isaria cicadae from Vietnam
  133. Twig biomass allocation of Betula platyphylla in different habitats in Wudalianchi Volcano, northeast China
  134. Animal Sciences
  135. Supplementation of probiotics in water beneficial growth performance, carcass traits, immune function, and antioxidant capacity in broiler chickens
  136. Predators of the giant pine scale, Marchalina hellenica (Gennadius 1883; Hemiptera: Marchalinidae), out of its natural range in Turkey
  137. Honey in wound healing: An updated review
  138. NONMMUT140591.1 may serve as a ceRNA to regulate Gata5 in UT-B knockout-induced cardiac conduction block
  139. Radiotherapy for the treatment of pulmonary hydatidosis in sheep
  140. Retraction
  141. Retraction of “Long non-coding RNA TUG1 knockdown hinders the tumorigenesis of multiple myeloma by regulating microRNA-34a-5p/NOTCH1 signaling pathway”
  142. Special Issue on Reuse of Agro-Industrial By-Products
  143. An effect of positional isomerism of benzoic acid derivatives on antibacterial activity against Escherichia coli
  144. Special Issue on Computing and Artificial Techniques for Life Science Applications - Part II
  145. Relationship of Gensini score with retinal vessel diameter and arteriovenous ratio in senile CHD
  146. Effects of different enantiomers of amlodipine on lipid profiles and vasomotor factors in atherosclerotic rabbits
  147. Establishment of the New Zealand white rabbit animal model of fatty keratopathy associated with corneal neovascularization
  148. lncRNA MALAT1/miR-143 axis is a potential biomarker for in-stent restenosis and is involved in the multiplication of vascular smooth muscle cells
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Heruntergeladen am 6.9.2025 von https://www.degruyterbrill.com/document/doi/10.1515/biol-2021-0025/html?lang=de
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