Effect of Rutin on the ox-LDL-Induced Vascular Endothelial Cell Injury by Regulating NEXN-AS1/miR-410-3p Pathway
Effect of Rutin on the ox-LDL-Induced Vascular Endothelial Cell Injury by Regulating NEXN-AS1/miR-410-3p Pathway
Feng Xu, Weijing Fan and Guobin Liu*
Department of Peripheral Vascular Diseases, Shuguang Hospital Affiliated to Shanghai University of Traditional Chinese Medicine, Shanghai, 200000, China
ABSTRACT
This study aims to investigate the effect of rutin on ox-LDL-induced vascular endothelial cell injury, and to analyze whether the mechanism is related to the regulation ofNEXN-AS1 and miR-410-3p expression. The CCK-8 method was used to detect the toxicity of rutin of different concentrations (0, 25, 50, 100, 200, 400 μmol/L) on human umbilical vein endothelial cells (HUVECs). HUVECs were treated with 100 mg/L ox-LDL for 24 h for establishing HUVECs injury model, and then treated with rutin in different doses. The cell activity and apoptosis rate of HUVECs were analyzed by CCK-8 method and flow cytometry, respectively. The levels of intracellular catalase (CAT), superoxide dismutase (SOD) and malondialdehyde (MDA) were measured using commercial kit, and expression levels ofNEXN-AS1 and miR-410-3p were detected using real-time quantitative PCR analysis. The dual luciferase experiment was applied to verify the targeted relationship betweenNEXN-AS1 and miR-410-3p. HUVECs were transfected with NEXN-AS1 overexpression vector, and then treated with ox-LDL for 24 h before detecting the activity, apoptosis rate and oxidative stress level of HUVECs. The low concentrations (25, 50, 100 μmol/L) of rutin had no toxic effect on HUVECs, and the activity of HUVECs was significantly reduced after intervention with high concentrations (200, 400 μmol/L) of rutin. ox-LDL treatment significantly reduced HUVECs activity, CAT and SOD levels,NEXN-AS1 expression (P<0.05), and increased apoptosis rate, MDA level, and miR-410-3p expression (P<0.05). Rutin (25, 50, 100 μmol/L) treatment reduced ox-LDL-induced apoptosis and MDA levels (P<0.05), increased cell viability, CAT and SOD levels (P<0.05), and up-regulated NEXN-AS1 Expression (P<0.05), down-regulated miR-410-3p expression (P<0.05). miR-410-3p is the target gene ofNEXN-AS1. Overexpression ofNEXN-AS1 could reduce ox-LDL-induced apoptosis and MDA levels (P<0.05), increase cell viability, CAT and SOD levels (P<0.05), and down-regulate miR-410-3p expression (P<0.05). Interference withNEXN-AS1 could reverse the effects of rutin on ox-LDL-induced proliferation, apoptosis and oxidative stress of vascular endothelial cells. It is concluded that rutin had a protective effect on ox-LDL-induced vascular endothelial apoptosis and oxidative injury, and its mechanism may be related to the up-regulation ofNEXN-AS1/miR-410-3p pathway.
Article Information
Received 09 February 2021
Revised 02 April 2021
Accepted 18 April 2021
Available online 01 December 2021
(early access)
Published 13 June 2022
Authors’ Contribution
FX and GL collected the samples. FX and WF analyzed the data. WF and GL conducted the experiments and analyzed the results. All authors discussed the results and wrote the manuscript.
Key words
Rutin, Vascular endothelial cells, NEXN-AS1, miR-410-3p, Oxidized low-density lipoprotein, Apoptosis, Oxidative stress.
DOI: https://dx.doi.org/10.17582/journal.pjz/20210209190253
* Corresponding author: liuguobin1964@163.com
0030-9923/2022/0005-2277 $ 9.00/0
Copyright 2022 by the authors. Licensee Zoological Society of Pakistan.
This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Introduction
Atherosclerosis (AS) is a progressive arterial inflammatory disease, which is related to the progression of cerebral infarction, peripheral vascular diseases, stroke and other cardiovascular and cerebrovascular diseases. Studies have shown that endothelial injury caused by oxidized low density lipoprotein (ox-LDL) is the initial event and promoting factor of AS, which can destroy the redox balance of vascular endothelial cells and induce apoptosis and injury of endothelial cells (Yan et al., 2019). Therefore, prevention of endothelial injury has become an important strategy to reverse AS. Rutin is a common polyphenol bioflavonoid, widely existing in many foods and traditional medicines. It has antioxidant, anti-inflammatory, antiallergic, anticancer, antibacterial and antiviral effects and cytoprotective activity (Lin, 2009). Studies have shown that rutin can improve the sensory and motor performance, recognition and memory of ischemia-reperfusion rats, reduce infarct size and relief neuron loss (Liu et al., 2018). Rutin can also alleviate nerve degeneration and learning and memory disorder caused by anesthesia by inhibiting neuronal apoptosis (Man et al., 2015). However, it is still unknown whether rutin has beneficial effects on ox-LDL-induced vascular endothelial cell injury. Long-chain non-coding RNA (lncRNA) is an RNA molecule with a length of more than 200 nucleotides. It is involved in many cellular processes such AS cell proliferation, autophagy, aging and apoptosis. Its expression changes are related to vascular cell function, oxidative stress and vascular inflammation. Thus, it is a potential therapeutic target for AS (Bian et al., 2020; Fasolo et al., 2019). The lncRNANEXN-AS1 is located at 1p31.1. Studies indicate that the expression ofNEXN-AS1 is decreased in human as plaque, and overexpression ofNEXN-AS1 can down-regulate the expression of adhesion molecules and inflammatory factors in endothelial cells and inhibit the progression of AS by inhibiting the oligomerization of toll-like receptor 4(TLR4) and the activity of nuclear factor (NF)-κB (Hu et al., 2019). The forecast of target gene shows that miR-410-3p is a potential target gene ofNEXN-AS1. It is pointed out that lncRNA FTX can induce cell proliferation, inhibit apoptosis and alleviate myocardial cell injury caused by hypoxia-reoxygenation by downregulating miR-410-3p (Li et al., 2020). However, it is not clear whetherNEXN-AS1 targets miR-410-3p and participates in ox-LDL-induced vascular endothelial cell injury. Therefore, the purpose of this study was to explore the protective effect of rutin on ox-LDL-induced vascular endothelial cell injury, and to explore its molecular mechanism throughNEXN-AS1/miR-410-3p pathway.
Materials and methods
Experimental materials
HUVECs were purchased from China Type Culture Collection Center. ox-LDL was purchased from Peking Union-Biology Co. Ltd. RPMI-1640 culture medium, fetal bovine serum and streptomycin were purchased from Wuhan Procell Biological Company. Rutin (purity greater than 95%, batch number 20181102) was purchased from Beijing Coolaber Technology Co., Ltd. Over-expression plasmid (pcDNA-NEXN-AS1), small interfering RNA (si-NEXN-AS1), empty vector plasmid (pcDNA), experimental primers and recombinant luciferase reporter gene vector were purchased from Shanghai Sangong Biological Company. Cell counting kit (CCK-8), general SYBR qPCR Master Mix, Annexin-V- FITC apoptosis detection kit were purchased from Nanjing Nuoweizan Biological Company. Rabbit Bcl-2, Bax and GAPDH monoclonal antibodies, sheep anti-rabbit IgG and Ankang can be purchased from Nanjing Vazyme Biological Company. M-MLV reverse transcriptase and miRNA reverse transcription kit were purchased from Beijing Biolab Biological Company. Malondialdehyde (MDA) detection kit, catalase (CAT) activity detection kit and superoxide dismutase (SOD) activity detection kit were purchased from Beijing Solarbio Biological Company.
Cells, transfection and grouping
HUVECs were inoculated in RPMI-1640 culture medium containing 1% streptomycin double antibody and 10% fetal bovine serum, and cultured in a wet incubator at 37°C and 5%CO2. The fluid was changed every 3 days. When the cell fusion degree was 80%, the passage was 1:3. The experiment was carried out on the third generation of logarithmic HUVECs, and the cell injury model was established with 100 mg/l ox-LDL-induced for 24 h (Zhu et al., 2018), which was designated as ox-LDL group. The normal cultured HUVECs were designated as control group (con). To test the effect of rutin on ox-LDL-induced HUVECs, HUVECs were incubated with different concentrations (25,50,100 μmol/L) of ruti in combination with 100 mg/L of ox-LDL for 24h, The HUVECs were marked as ox-LDL+rutin-low dose (L) group and ox-LDL+rutin-high dose group (H) (Yu and Zhou, 2013).
To verify that rutin can protect ox-LDL-induced endothelial cell injury by regulatingNEXN-AS1/miR-410-3p pathway, pcDNA-NEXN-AS1, pcDNA, si-NEXN-AS1 were transfected into HUVECs according to Lipofectamine 2000 instructions, and the cells were harvested after transfection for 48h. pcDNA-transfected cells and pcDNA-NEXN-AS1-transfected cells were divided into ox-LDL+pcDNA group and ox-LDL+pcDNA-NEXN-AS1 group with 100 mg/l ox-LDLinducing for 24h. Transfected si-NEXN-AS1 cells were incubated for 24h with a culture medium containing 100μmol/Lrutin and 100 mg/L ox-LDL, and were classified as ox-LDL+rutin +si-NEXN-AS1group.
CCK-8 assay for cell viability
To test the toxic effect of rutin on HUVECs, 5×103 HUVECs were inoculated into each well of 96-well plate and cultured overnight. Rutin with different concentrations (0, 25, 50, 100, 200, 400 μmol/L) was used to incubate the cells. One plate of cells was taken out at 24 h and 48 h, respectively, and 10μL CCK-8 solution was added to each well to test the effect of rutin on ox-LDL-treated HUVECs. 5×103 untransfected or transfected HUVECs were inoculated into each well of 96-well plate and cultured overnight. Rutin and/or ox-LDL were added to incubate the cells for 24 h according to the experimental grouping, and then the cell proliferation activity was tested according to the above steps.
Detection of apoptosis by flow cytometry
The density of HUVECs was adjusted to 3×106 cells/mL with 1×binding buffer. 5 μL Annexin V-FITC and 5 μL PI solution were added into 300 μL cell suspension, and staining was carried out in black box for 20min. The apoptotic cells were analyzed by flow cytometry.
Detection of Bax and Bcl-2 protein expression by Western blot method
The protein was extracted from HUVECs with RIPA buffer, and quantified by BCA kit. The voltage was set at 100V, and SDS-PAGE electrophoresis was performed for 100 min. The current was set to 20 mA, and the membranetransfer was carried out overnight with a wet membranetransfer instrument. The polyvinylidene fluoride membrane was sealed with 5% skimmed milk at room temperature for 1 h. After combining with primary antibody at room temperature for 2 h, it was then incubated with goat anti-rabbit at room temperature for 1 h. The membranewas incubated with chemiluminescent reagent for 2 min, then fixed in the membraneholder, developed and fixed immediately. The gray value of the target band was analyzed by Image J software.
Real-time quantitative PCR analysis of the expression ofNEXN-AS1 and miR-410-3p
Total RNA was extracted from HUVECs by Trizol reagent. cDNA ofNEXN-AS1 was synthesized by M-MLV reverse transcriptase, and cDNA of miR-410-3p was synthesized by miRNA reverse transcription kit. RT-qPCR was performed by SYBR qPCR Master Mix. The relative expression of NEXN-AS1 and miR-410-3p was calculated by 2−ΔΔCt formula. The upstream primer of miR-410-3p was 5’-CGCGAATATAACACAGATGGCCTGT-3’, and the downstream primer was 5’-CAGTGCGTGTCGT GGAGT-3; the upstream primer of internal reference U6 was 5’-TGCGGGTGCTCGCTTCGGCAGC-3’; the downstream primer was 5’-CCAGT GCAGGGTCCGAGGT-3’; the upstream primer of NEXN-AS1 was 5’-AAGGAATGAGGCTGAAATGG-3’, and the downstream primer was 5’-AGGAAAACTTGGCCAAAGGT-3’; the upstream primer of internal reference GAPDH was 5’-GGAGCGAG ATCCCTCCAAAAT-3’, and the downstream primer was 5’-GGCTGTTGTCATACTTCTCATGG-3’.
Detection of MDA, CAT and SOD levels in cells
HUVECs were collected into a centrifuge tube. After centrifugation, the supernatant was discarded. After adding extractive solution, the cells were crushed with 200W ultrasound (ultrasound of 3 s, interval of 10 s, repeating for 30 times). After centrifugation of 8000×g for 10 min at 4°C, the supernatant was placed on ice. The MDA content, CAT and SOD activities in HUVECs were measured according to the kit procedures.
Dual-luciferase report experiment
DIANA Tools predicted thatNEXN-AS1 and miR-410-3p had specific complementary binding sequences. Wild-type and mutant sequences ofNEXN-AS1 (miR-410-3p andNEXN-AS1 binding sites have been mutated) were cloned into double luciferase reporter vector to construct recombinant reporter plasmids WT-NEXN-AS1 and MUT-NEXN-AS1. The recombinant plasmidswere co-transfected with miR-410-3p mimics and miR-NC into HUVECs, respectively, and the relative luciferase activity of each group of cells after transfection for 48 h was analyzed by dual-luciferase reporter gene detection kit.
Statistical methods
The experimental data were expressed by x̅±s of three independent repeated experiments, and were statistically analyzed by SPSS 23.0. The comparison between two groups was made by independent sample t test, and the comparison between multiple groups was made by one-way ANOVA and SNK-q test. P<0.05 indicated statistically significant difference.
Results
Effects of rutin on proliferation of vascular endothelial cells
After incubation for 24 h, 200/400 μmol/l rutin inhibited the activity of HUVECs. After incubation for 48h, 0/25/50/100μmol/l rutin had no obvious effect on the viability of HUVECs, while 200/400 μmol/l rutin significantly inhibited the viability of HUVECs (P<0.05), indicating that high concentration of rutin had certain cytotoxicity to HUVECs. Therefore, rutin of 25/50/100 μmol/L was selected for the experiment (Table I).
Effects of rutin on proliferation and apoptosis of ox-LDL-induced vascular endothelial cells
Compared with control group, ox-LDL group cell viability,NEXN-AS1 expression and Bcl-2 protein expression decreased significantly (P<0.05), while apoptosis rate, miR-410-3p expression and Bax protein expression increased significantly (P<0.05); compared with ox-LDL group, ox-LDL+rutin-L group, ox-LDL+rutin -M group, ox-LDL+rutin -H group showed significantly higher cell viability, expression of
Table I.- Effects of rutin at different concentrations on HUVECs cell activity (x̅±s, n=3).
|
Time |
Rutin (μmol/L) |
|||||
|
0 |
25 |
50 |
100 |
200 |
400 |
|
|
24 h |
0.53±0.04 |
0.55±0.02 |
0.56±0.03 |
0.58±0.03 |
0.46±0.03* |
0.43±0.04* |
|
48 h |
1.17±0.05 |
1.18±0.07 |
1.17±0.06 |
1.21±0.05 |
0.94±0.05* |
0.80±0.04* |
*P<0.05 compared with group 0.
Table II.- Effects of rutin on the activity and apoptosis of ox-LDL-induced HUVECs cells (x̅±s, n=3).
|
Group |
Control |
ox-LDL |
ox-LDL+rutin -L |
ox-LDL+rutin -M |
ox-LDL+rutin -H |
F |
P |
|
NEXN-AS1 |
1.00±0.00 |
0.23±0.02* |
0.33±0.04# |
0.57±0.04#& |
0.83±0.05#&@ |
260.21 |
0.000 |
|
miR-410-3p |
1.00±0.00 |
4.48±0.15* |
3.98±0.11# |
2.97±0.09#& |
1.80±0.06#&@ |
686.27 |
0.000 |
|
OD value |
1.23±0.08 |
0.61±0.03* |
0.78±0.04# |
0.94±0.06#& |
1.08±0.05#&@ |
59.37 |
0.000 |
|
Apoptosis rate (%) |
6.85±0.49 |
24.49±0.97* |
20.82±0.69# |
17.66±0.56#& |
12.93±0.50#&@ |
320.34 |
0.000 |
|
Bax |
0.15±0.01 |
0.86±0.07 |
0.64±0.06 |
0.44±0.04 |
0.27±0.02 |
114.72 |
0.000 |
|
Bcl-2 |
0.89±0.08 |
0.11±0.01 |
0.32±0.03 |
0.53±0.03 |
0.71±0.06 |
120.02 |
0.000 |
*Compared with control group, p<0.05; #compared with ox-LDL group, p < 0.05; &compared with ox-LDL+rutin -L group; p < 0.05; @compared with ox-LDL+rutin -M group, p<0.05.
Table III.- Effects of rutin on oxidative stress of ox-LDL-induced HUVECs (x̅±s, n=3).
|
Group |
Control |
ox-LDL |
ox-LDL+rutin -L |
ox-LDL+rutin -M |
ox-LDL+rutin -H |
F |
P |
|
CAT (U/mL) |
62.83±3.52 |
20.66±0.97* |
28.17±1.23# |
41.01±1.06#& |
52.66±2.05#&@ |
221.39 |
0.000 |
|
MDA (nmol/L) |
79.13±5.61 |
181.91±11.70* |
154.73±8.97# |
126.52±6.68#& |
102.59±4.15#&@ |
80.08 |
0.000 |
|
SOD (U/mL) |
88.25±7.01 |
20.50±2.65* |
37.76±2.56# |
57.58±3.50#& |
73.93±3.83#&@ |
121.95 |
0.000 |
*compared with control group, p<0.05; #compared with ox-LDL group, P<0.05; &compared with ox-LDL+rutin-L group, p < 0.05; @compared with ox-LDL+rutin -M group, P<0.05.
NEXN-AS1 and Bcl-2 protein (P<0.05), apoptosis rate, miR-410-3p expression, and apoptosis rate. There were significant differences among ox-LDL+rutin -L group, ox-LDL+rutin -M group and ox-LDL+rutin -H group in the above mentioned indexes (P<0.05) (Fig. 1; Table II).
Effect of rutin on oxidative stress of ox-LDL-induced vascular endothelial cells
Compared with control group, the levels of CAT and SOD in ox-LDL group cells decreased significantly (p < 0.05), while the level of MDA increased significantly (p<0.05); compared with ox-LDL group, the levels of CAT and SOD in ox-LDL+rutin-L group, ox-LDL+rutin-M group and ox-LDL+rutin-H group increased significantly (p<0.05), while the level of MDA decreased significantly (p<0.05). There were significant differences among ox-LDL+rutin-L group, ox-LDL+rutin -M group and ox-LDL+rutin-H group (P<0.05) (Table III).
Targeting relationship between NEXN-AS1 and miR-410-3p
The DIANATools prediction results are shown in Figure 2. There are complementary sites betweenNEXN-AS1 and miR-410-3p sequences. The results of dual-luciferase report experiment are shown in Table IV. The relative luciferase activity of WT-NEXN-AS1 in cells transfected with miR-410-3p mimics was significantly lower than that transfected with miR-NC (P<0.05); compared with miR-NC, the relative luciferase activity of MUT-NEXN-AS1 in cells transfected with miR-410-3p mimics did not change significantly.
Table IV.- Dual-luciferase report experiment (x̅±s, n=3).
|
Group |
WT-NEXN-AS1 |
MUT-NEXN-AS1 |
|
miR-NC |
0.96±0.08 |
1.00±0.09 |
|
miR-410-3p |
0.28±002* |
0.97±0.06 |
|
t |
14.283 |
0.480 |
|
P |
0.000 |
0.656 |
*compared with miR-NC, p<0.05.
Table V.- Effects of overexpression of NEXN-AS1 on oxidative stress of proliferation and apoptosis of ox-LDL-induced vascular endothelial cells (x̅±s, n=3).
|
Group |
ox-LDL |
ox-LDL+pcDNA |
ox-LDL+pcDNA-NEXN-AS1 |
F |
P |
|
NEXN-AS1 |
0.24±0.02 |
0.24±0.02 |
0.90±0.05*# |
396.00 |
0.000 |
|
miR-410-3p |
4.51±0.19 |
4.50±0.22 |
1.45±0.07*# |
313.19 |
0.000 |
|
OD value |
0.61±0.03 |
0.58±0.06 |
1.15±0.09*# |
73.50 |
0.000 |
|
Apoptosis rate (%) |
24.52±0.93 |
24.49±0.99 |
9.35±0.47*# |
333.52 |
0.000 |
|
Bax |
0.88±0.07 |
0.85±0.07 |
0.22±0.02 |
122.56 |
0.000 |
|
Bcl-2 |
0.12±0.01 |
0.13±0.01 |
0.82±0.08 |
219.59 |
0.000 |
|
CAT (U/mL) |
20.64±1.01 |
20.75±0.99 |
57.60±3.12*# |
348.19 |
0.000 |
|
MDA (nmol/L) |
182.16±11.55 |
187.28±10.75 |
89.86±4.28*# |
101.22 |
0.000 |
|
SOD (U/mL) |
20.63±2.64 |
20.76±2.54 |
78.79±5.32*# |
242.67 |
0.000 |
*compared with ox-LDL group, p < 0.05; #compared with ox-LDL+pcDNA group, p < 0.05.
Table VI.- Interference with NEXN-AS1 could reverse effects of rutin on oxidative stress of proliferation and apoptosis of ox-LDL-induced vascular endothelial cells (x̅±s, n=3).
|
Group |
ox-LDL |
ox-LDL+rutin |
ox-LDL+si-NEXN-AS1 |
ox-LDL+rutin +si-NEXN-AS1 |
F |
P |
|
NEXN-AS1 |
0.25±0.02 |
0.83±0.05* |
0.09±0.01* |
0.38±0.03# |
311.05 |
0.000 |
|
miR-410-3p |
4.52±0.15 |
1.78±0.05* |
6.92±0.23* |
3.99±0.10# |
607.93 |
0.000 |
|
OD value |
0.61±0.03 |
1.10±0.06* |
0.52±0.02* |
0.74±0.04# |
119.92 |
0.000 |
|
Apoptosis rate (%) |
24.59±1.07 |
13.07±0.48* |
30.24±1.54* |
21.49±0.97# |
131.51 |
0.000 |
|
CAT (U/mL) |
20.63±1.00 |
53.01±2.25* |
14.35±0.68* |
32.18±2.35# |
287.84 |
0.000 |
|
MDA (nmol/L) |
178.90±5.34 |
104.32±6.75* |
234.59±11.99* |
155.76±8.95# |
117.57 |
0.000 |
|
SOD (U/mL) |
20.66±2.58 |
74.72±4.26* |
11.69±0.57* |
35.44±2.35# |
303.45 |
0.000 |
|
Bax |
0.86±0.07 |
0.26±0.02 |
1.19±0.11 |
0.65±0.04 |
95.87 |
0.000 |
|
Bcl-2 |
0.13±0.01 |
0.73±0.06 |
0.02±0.01 |
0.24±0.02 |
280.19 |
0.000 |
*compared with ox-LDL group, p<0.05; #compared with ox-LDL+rutin group, p<0.05.
Effects of overexpression of NEXN-AS1 on proliferation, apoptosis and oxidative stress of ox-LDL-induced vascular endothelial cells
Compared with ox-LDL group and ox-LDL+pcDNA group, the expression of NEXN-AS1, cell viability, Bcl-2 protein, CAT and SOD activities in ox-LDL+pcDNA-NEXN-AS1 group significantly increased, while the expression of miR-410-3p, apoptosis rate, Bax protein and MDA level significantly decreased (P<0.05) (Fig. 3; Table V).
Interference with NEXN-AS1 could reverse the effect of rutin on proliferation, apoptosis and oxidative stress of ox-LDL-induced vascular endothelial cells
Compared with ox-LDL group, the expression of NEXN-AS1, cell viability, Bcl-2 protein, CAT and SOD in ox-LDL+rutin group and ox-LDL+si-NEXN-AS1 group significantly increased (p<0.05), and the expression of mir-410-3p, apoptosis rate, Bax protein and SOD significantly increased. Compared with ox-LDL+rutin group, the expression of NEXN-AS1, cell vitality, Bcl-2 protein, CAT and SOD in ox-LDL+rutin +si-NEXN-AS1 group decreased significantly (P<0.05), while the expression of mir-410-3p, apoptosis rate, Bax protein and MDA level increased significantly (Fig. 4; Table VI).
DISCUSSION
Rutin, as an effective antioxidant, plays a protective role in the study of various cell injuries. Studies have shown that rutin can improve antioxidant enzyme activity in brain tissue of rats with chronic cerebral hypoperfusion, and improve cognitive dysfunction and brain injury in rats (Qu et al., 2016). Rutin inhibits oxidative stress and apoptosis by up-regulating the expression of 1(SIRT1, thus alleviating myocardial injury induced by hypoxia/reoxygenation (Yang et al., 2019). However, up to now, there are few reports on the effect of rutin on the progression and pathogenesis of AS. In this study, we first studied the toxic effects of different concentrations of rutin on HUVECs, and found that high concentrations of rutin inhibited the viability of HUVECs, suggesting that high concentrations of rutin have cytotoxicity. To study the effect of rutin on the progression of AS, HUVECs model treated with ox-LDL was used to detect the cytoprotective effect of aromatin. The results showed that rutin treatment could inhibit the apoptosis of ox-LDL-induced cells and improve the cell viability. Bcl-2 is an anti-apoptotic protein, while Bax is a pro-apoptotic protein. In this study, rutin treatment could reverse the increase of Bax expression of ox-LDL-induced and prevent the decrease of Bcl-2 expression of ox-LDL-induced, indicating that rutin treatment could significantly reduce the apoptosis of ox-LDL-induced HUVECs. Oxidative stress is the key factor to trigger apoptosis. Intracellular antioxidant enzymes such as CAT and SOD are the first line of defense against the toxic effects of reactive oxygen species and play a key role in the antioxidant defense system (Gao et al., 2019). MDA is the final product of the degradation of polyunsaturated fatty acids by reactive oxygen species, and it is a commonly used marker of oxidative stress (Liu and Liu, 2020). Our study showed that ox-LDL treatment increased MDA content and decreased CAT and SOD levels in HUVECs, while rutin treatment weakened the effect of ox-LDL on these enzymes, indicating that rutin could inhibit oxidative stress induced by ox-LDL. The above studies indicated that rutin could inhibit ox-LDL-induced endothelial cell injury.
In recent years, many studies have confirmed that lncRNA is involved in the regulation of endothelial cell function in the pathogenesis of AS. The research shows that ox-LDL can reduce the level of lncRNA-FA2H-2 in HUVECs, and the down-regulation of lncRNA-FA2H-2 can activate inflammation and inhibit autophagy flux, thus accelerating AS lesions. Opa interacting protein 5 antisense transcription 1(OIP5-AS1) targets miR-98-5p to regulate TLR4/ nuclear factor κB(NF-κB) signaling pathway and accelerate ox-LDL-induced endothelial cell injury. Atorvastatin inhibits the scorch of human vascular endothelial cells by up-regulating the expression of lncRNANEXN-AS1 (Gao et al., 2019). In this study, ox-LDL treatment significantly down-regulated the expression of NEXN-AS1 and up-regulated the expression of miR-410-3p in HUVECs, while rutin treatment significantly reversed the expression changes of ox-LDL-induced NEXN-AS1 and miR-410-3p,suggesting that rutin may protect ox-LDL-induced endothelial cell injury by regulating NEXN-AS1 and mir-410-3p. MiR-410-3p has been confirmed to be related to many human diseases. The level of miR-410-3p in synovium and fibroblast-like cells of patients with rheumatoid arthritis decreases. Knocking down rich transcript 1(NEAT1) can inhibit cell proliferation and promote cell apoptosis by up-regulating miR-410-3p, which is a potential therapeutic target for rheumatoid arthritis (Wu et al., 2020; Wang et al., 2019). In osteosarcoma, magnolin can inhibit the malignant phenotype of tumor cells by up-regulating the expression of miR-410-3p, and increase its sensitivity to cisplatin (Wang et al., 2020). Further studies have confirmed that miR-410-3p is the target gene of NEXN-AS1, and overexpression of NEXN-AS1 obviously weakens the promotion of ox-LDL on miR-410-3p expression, suggesting that there is a regulatory pathway of NEXN-AS1/ miR-410-3p in ox-LDL-induced HUVECs. The functional analysis shows that overexpression of NEXN-AS1 significantly weakens the effects of ox-LDL treatment on HUVECs’ activity, apoptosis rate, Bcl-2 and Bax protein expression, MDA level, CAT and SOD activity, and protects HUVECs from ox-LDL-induced apoptosis and oxidative stress, which is similar to the protective effect of rutin on HUVECs. The response experiment shows that interference with the expression of NEXN-AS1 significantly weakens the effects of rutin on the proliferation, apoptosis and oxidative stress of ox-LDL-induced HUVECs. This indicates that the protective effect of rutin on ox-LDL-induced HUVECs may be realized by up-regulating NEXN-AS1/miR-410-3p pathway.
In a word, rutin has protective effect on ox-LDL-induced vascular endothelial cell injury by inhibiting oxidative stress and apoptosis, and its mechanism may be related to up-regulation of NEXN-AS1/miR-410-3p pathway. This preliminarily reveals the possible molecular mechanism of rutin’s protective effect on endothelial cells, and provides an important basis for developing rutin for prevention and treatment of as.
Statement of conflict of interest
The authors have declared no conflict of interests.
Acknowledgement
The research is supported by: The National Natural Science Foundation of China (No. 81774310, No. 81804095, No. 81804096).
References
Bian, W.H., Jing, X.H., Yang, Z.Y., Shi, Z., Chen, R.Y., Xu, A.L., Wang, N., Jiang, J., Yang, C., Zhang, D.L., Li, L., Wang, H.Y., Wang, J., Sun, Y.Y. and Zhang, C.X., 2020. Downregulation of lncrna norad promotes ox-ldl-induced vascular endothelial cell injury and atherosclerosis. Aging (Albany NY), 12: 6385-6400. https://doi.org/10.18632/aging.103034
Fasolo, F., Di Gregoli, K., Maegdefessel, L. and Johnson, J.L., 2019. Non-coding RNAs in cardiovascular cell biology and atherosclerosis. Cardiovasc. Res., 115: 1732-1756. https://doi.org/10.1093/cvr/cvz203
Gao, H.N., Sun, L.N., Chen, S.C. and Yu, X., 2019. Study on the effect and mechanism of liraglutide on HUVECs injury induced by palmitic acid. Chinese J. Diabetes, 27: 777-784.
Guo, F.X., Wu, Q., Li, P., Zheng, L., Ye, S., Dai, X.Y., Kang, C.M., Lu, J.B., Xu, B.M., Xu, Y.J., Xiao, L., Lu, Z.F., Bai, H.L., Hu, Y.W. and Wang, Q., 2019. The role of the lncrna-fa2h-2-mlkl pathway in atherosclerosis by regulation of autophagy flux and inflammation through mtor-dependent signaling. Cell Death Differ., 26: 1670-1687. https://doi.org/10.1038/s41418-018-0235-z
Hu, Y.W., Guo, F.X., Xu, Y.J., Li, P., Lu, Z.F., McVey, D.G., Zheng, L., Wang, Q., Ye, J.H., Kang, C.M., Wu, S.G., Zhao, J.J., Ma, X., Yang, Z., Fang, F.C., Qiu, Y.R., Xu, B.M., Xiao, L., Wu, Q., Wu, L.M., Ding, L., Webb, T.R., Samani, N.J. and Ye, S., 2019. Long noncoding rnanexn-as1 mitigates atherosclerosis by regulating the actin-binding protein nexn. J. Clin. Invest., 129: 1115-1128. https://doi.org/10.1172/JCI98230
Li, L., Zhang, Y.Z., Yang, H.Y. and Wang, Y.Y., 2020. Long non-coding RNA ftx alleviates hypoxia/ reoxygenation-induced cardiomyocyte injury via mir-410-3p/fmr1 axis. Eur. Rev. med. Pharmacol. Sci., 24: 396-408.
Lin, J., 2009. Clinical pharmacological characteristics of rutin. Chinese J. clin. Pharmacol., 25: 65-72.
Liu, F. and Liu, Z.S., 2020. Pachymic acid improves HUVECs injury induced by ox-ldl-induced by activating nrf2/ho-1 signaling pathway. Cell. mol. Immunol., 36: 164-168.
Liu, H., Zhong, L.L., Zhang, Y.W., Liu, X.W. and Li, J., 2018. Rutin attenuates cerebral ischemia-reperfusion injury in ovariectomized rats via estrogen-receptor-mediated bdnf-trkb and ngf-trka signaling. Biochem. Cell. Biol., 96: 672-681. https://doi.org/10.1139/bcb-2017-0209
Man, Y.G., Zhou, R.G. and Zhao, B., 2015. Efficacy of rutin in inhibiting neuronal apoptosis and cognitive disturbances in sevoflurane or propofol exposed neonatal mice. Int. J. clin. exp. Med., 8: 14397-409.
Qu, J., Xi, Y., Zhou, Q., Du, Y., Zhang, W. and Miao, J.T., 2016. Neuroprotective effect of rutin on cognitive dysfunction and brain injury in rats with chronic cerebral hypoperfusion. Progr. Mod. Biomed., 16: 2419-2424.
Wang, Y.J., Jiao, T., Fu, W.Y., Zhao, S., Yang, L.L., Xu, N.L. and Zhang, N., 2019. Mir-410-3p regulates proliferation and apoptosis of fibroblast-like synoviocytes by targeting yy1 in rheumatoid arthritis. Biomed. Pharmacother., 119: 109426-109436. https://doi.org/10.1016/j.biopha.2019.109426
Wang, Y.M., Shang, G.N., Wang, W., Qiu, E.D., Pei, Y. and Zhang, X.J., 2020. Magnoflorine inhibits the malignant phenotypes and increases cisplatin sensitivity of osteosarcoma cells via regulating mir-410-3p/hmgb1/ nf-κb pathway. Life Sci., 256: 117967-117977. https://doi.org/10.1016/j.lfs.2020.117967
Wu, L.M., Wu, S.G., Chen, F., Wu, Q., Wu, C.M., Kang, C.M., He, X., Zhang, R.Y., Lu, Z.F., Li, X.H., Xu, Y.J., Li, L.M., Ding, L., Bai, H.L., Liu, X.H., Hu, Y.W. and Zheng, L., 2020. Atorvastatin inhibits pyroptosis through the lncrnanexn-as1/nexn pathway in human vascular endothelial cells. Atherosclerosis, 293: 26-34. https://doi.org/10.1016/j.atherosclerosis.2019.11.033
Yan, R., Yan, J.F., Chen, X.Z. and Yu, Y.F., 2019. Xanthoangelol prevents ox-ldl-induced endothelial cell injury by activating nrf2/are signaling. J. Cardiovasc. Pharmacol., 4: 162-171. https://doi.org/10.1097/FJC.0000000000000699
Yang, H., Wang, C., Zhang, L.Y., Jun, L. and Ni, H.Z., 2019. Rutin alleviates hypoxia/reoxygenation-induced injury in myocardial cells by up-regulating sirt1 expression. Chem. Biol. Interact., 5: 44-49. https://doi.org/10.1016/j.cbi.2018.10.016
Yu, Y.M. and Zhou, Y.F., 2013. Preliminary study on the protective effect of rutin on oxidative damage and apoptosis of human lens epithelial cells. Acta Univ. Med. Anhui, 48: 379-382.
Zhu, W.Y., Tang, Y.S., Gai, Y.H., Li, Y.F. and Yin, G., 2018. Protective effect of honokiol on ox-ldl-induced vascular endothelial cell injury and its mechanism. Chinese J. Evid. Based Cardiovasc. Med., 10: 1079-1083.
To share on other social networks, click on any share button. What are these?
