Hostname: page-component-78c5997874-s2hrs Total loading time: 0 Render date: 2024-11-17T15:16:28.025Z Has data issue: false hasContentIssue false

Beneficial effects of the active principle component of Korean cabbage kimchi via increasing nitric oxide production and suppressing inflammation in the aorta of apoE knockout mice

Published online by Cambridge University Press:  13 April 2012

Jeong Sook Noh
Affiliation:
Department of Food Science and Nutrition, Kimchi Research Institute, Pusan National University, Busan609-735, Republic of Korea
Yung Hyun Choi
Affiliation:
Department of Biochemistry, College of Oriental Medicine, Dong-Eui University and Research Center for Oriental Medicine, Busan614-052, Republic of Korea
Yeong Ok Song*
Affiliation:
Department of Food Science and Nutrition, Kimchi Research Institute, Pusan National University, Busan609-735, Republic of Korea
*
*Corresponding author: Y. O. Song, fax: +82 51 583 3648, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The present study investigated the effects of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA), the active principle compound of kimchi, on vascular damage in the experimental atherosclerotic animal. HDMPPA was administrated by an intraperitoneal injection of 10 mg/kg per d for 8 weeks to apoE knockout (KO) mice with an atherogenic diet containing 1 % cholesterol, and its effects were compared with vehicle-treated control mice. HDMPPA increased NO content in the aorta, accompanied by a decrease in reactive oxygen species (ROS) concentration. Furthermore, in the HDMPPA-treated group, aortic endothelial NO synthase (eNOS) expression was up-regulated compared with the control group. These results suggested that HDMPPA could maintain NO bioavailability through an increasing eNOS expression and preventing NO degradation by ROS. Furthermore, HDMPPA treatment in apoE KO mice inhibited eNOS uncoupling through an increase in vascular tetrahydrobiopterin content and a decrease in serum asymmetric dimethylarginine levels. Moreover, HDMPPA ameliorates inflammatory-related protein expression in the aorta of apoE KO mice. Therefore, the present study suggests that HDMPPA, the active compound of kimchi, a Korean functional food, may exert its vascular protective effect through the preservation of NO bioavailability and suppression of the inflammatory response.

Type
Full Papers
Copyright
Copyright © The Authors 2012

The progress of atherosclerosis is implicated with the loss of NO bioavailability and increased reactive oxygen species (ROS). In vascular tissue, NO is derived from l-arginine oxidation by endothelial NO synthase (eNOS), and has a central role in cyclic GMP-mediated vasorelaxation. It has been suggested that NO possesses multiple anti-atherosclerotic properties, which include anti-platelet, anti-proliferative and anti-inflammatory effects(Reference Li and Forstermann1, Reference Li, Wallerath and Forstermann2). In atherosclerotic lesions, oxidative stress could be augmented by eNOS uncoupling, which generates superoxide rather than NO. This dysfunction of eNOS activity is caused by an oxidative loss of cofactor, tetrahydrobiopterin (BH4) and an increased production of inhibitor, asymmetric dimethylarginine (ADMA)(Reference Thum, Fraccarollo and Schultheiss3Reference Antoniades, Shirodaria and Leeson5). Because NO has been demonstrated as a critical effector molecule in the maintenance of vascular function(Reference Palmer, Ferrige and Moncada6), it is therefore important to maintain NO bioavailability through prevention of eNOS uncoupling during vascular disease.

Vascular inflammation has been suggested to be an important risk factor in the initiation and development of atherosclerosis(Reference Ross7). Inflammatory response in the endothelium promotes leucocyte adhesion and increases vascular permeability via up-regulation of surface cell adhesion molecules and the release of inflammatory cytokines. Endothelial adhesion molecules such as vascular cellular adhesion molecule-1 (VCAM-1) and intercellular adhesion molecule-1 (ICAM-1) are indicative of inflammatory processes. It has been shown that the signal transduction pathways for the expression of adhesion molecules include the activation and translocation of the redox-sensitive transcriptional factor NF-κB(Reference Pahl8). Additionally, increased ROS and cytokines have been implicated as key mediators of cell signalling pathways that activate and translocate NF-κB to the nucleus, which in turn up-regulates inflammatory gene expression and aggravates further inflammatory response.

Kimchi, a traditional type of Korean fermented vegetable food, was named in the list of top five ‘World Health Foods’ for being abundant in dietary fibre, vitamin C, lactic acid bacteria, minerals and other compounds beneficial to health(Reference Cheigh and Park9). Several scientific trials to identify the potential health benefits of kimchi have been carried out. In our previous studies, plasma cholesterol-lowering effects of kimchi were demonstrated in human subjects(Reference Song10Reference Choi, Kim and Kwon12) and animals(Reference Kwon, Song and Choi13Reference Kim, Kwon and Seo15), as well as an anti-atherogenic effect having been demonstrated in rabbits(Reference Kim, Lee and Chung16). From Korean cabbage kimchi, 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) with a molecular weight of 226 was isolated and identified as an active principle responsible for inhibiting LDL oxidation and 2,2-diphenyl-1-picrylhydrazyl scavenging activity(Reference Lee, Kwon and Kim17). The amount of HDMPPA is approximately 1 mg/100 g kimchi(Reference Kim, Kwon and Seo15). Next, we chemically synthesised HDMPPA which was biologically identical to the HDMPPA isolated from Korean cabbage kimchi(Reference Lee, Kwon and Kim17). The synthesised HDMPPA showed health benefits on atherosclerosis in rabbits(Reference Kim, Lee and Chung16). Furthermore, HDMPPA retarded atherosclerotic lesions and ameliorated oxidative stress through inhibiting NADPH oxidase activity in the aorta of apoE knockout (KO) mice(Reference Noh, Kim and Kwon18). However, the effect of HDMPPA on NO metabolism and inflammatory response in the aorta of the atherosclerotic animal model was not determined. In the present study, we investigated the protective effect of HDMPPA on experimental atherosclerosis through the preservation of NO bioavailability and inhibition of the inflammatory response.

Materials and methods

Materials and reagents

Chemically synthesised HDMPPA that is biologically identical to the component isolated from cabbage kimchi was used(Reference Lee, Kwon and Kim17). Chemical synthesis was carried out at the Department of Chemistry, Pusan National University, Busan, Republic of Korea. Commercially available kits for plasma TAG and cholesterol analysis were used. The primary antibodies cyclo-oxygenase-2 (COX-2) (sc-19 999), inducible NO synthase (iNOS) (sc-7271), eNOS (sc-654), VCAM-1 (sc-1504), ICAM-1 (sc-1511), Iκ-Bα (sc-371), NF-κB p65 (sc-109), β-actin (sc-47 778) and the secondary antibodies of anti-mouse (sc-2005), anti-rabbit (sc-2004) and anti-goat (sc-2020) were purchased from Santa Cruz Biotechnology. Enzymes and other chemicals were purchased from Sigma.

Animals and diets

For the present study, 6-week-old male apoE KO mice were purchased from Central Lab Animal, Inc. and were randomly divided into two dietary groups: atherogenic diet (AD) only (control, n 15) or AD with HDMPPA treatment (HDMPPA, 10 mg/kg of body weight, n 15). Each mouse was housed in a room with controlled temperature and lighting and fed an AD for 8 weeks. The AD for apoE KO mice was prepared based on the American Institute of Nutrition (AIN)-76 diet by adding 1 % cholesterol and 10 % lard to induce atherosclerosis(Reference Nishina, Verstuyft and Paigen19). The diet compositions were as follows (w/w): casein, 20 %; sucrose, 44 %; maize starch, 15 %; cellulose, 5 %; lard, 10 %; AIN-76 mineral mixture, 3·5 %; AIN-76 vitamin mixture, 1 %; dl-methionine, 0·3 %; choline bitartrate, 0·2 %; and cholesterol, 1 %. HDMPPA dissolved in PBS or PBS (as vehicle) was administered every other day by intraperitoneal injection. The dosage for HDMPPA injected into the mice (10 mg/kg of body weight per d) was calculated based on results from a previous study that demonstrated anti-atherogenic effects of HDMPPA (0·33 mg/kg of body weight per d) in rabbits when it was administered via intravenous injection(Reference Kim, Lee and Chung16). PBS (vehicle) was injected into the control animals. Mice had free access to food and water. After an 8-week experimental period, the mice were anaesthetised with diethyl ether after 12 h of fasting. Blood samples were drawn from the inferior vena cava, and plasma was collected immediately after centrifuging (800 g for 10 min). The heart and descending aorta were removed. Of the fifteen aortas, five of them were used for the measurement of ROS and NO, another five for aortic BH4 determination and the remainder for the protein expression study. All samples were stored at − 70°C until further analysis. The animal protocol used in this study was reviewed by the Pusan National University Institutional Animal Care and Use Committee on their procedures and scientific care, and the present study was approved (approval no. PNU-2007-00 031).

Nitric oxide concentration of the aorta

The production of NO in the aorta was measured using cell-permeable diaminofluorescein-2 diacetate (Calbiochem). The aorta was homogenised on ice with 1 mm-EDTA–50 mm-sodium phosphate buffer (pH 7·4), and then 12·5 μm-diaminofluorescein-2 diacetate were added to the homogenate. During the reaction time for 30 min, changes in fluorescence were determined at an excitation wavelength of 485 nm and emission wavelength of 535 nm(Reference Green, Wagner and Glogowski20).

Level of total reactive oxygen species

Total ROS concentration was measured by the method of Ali et al. (Reference Ali, LeBel and Bondy21). In brief, the aorta was homogenised on ice with 1 mm-EDTA–50 mm-sodium phosphate buffer (pH 7·4), and then 25 mm-2′,7′-dichlorofluorescein-diacetate were added to the homogenate, and changes in fluorescence for 30 min were determined at an excitation wavelength of 486 nm and emission wavelength of 530 nm.

Western blotting analysis

Aortic tissues were homogenised with ice-cold lysis buffer containing 5 mm-Tris–HCl (pH 7·5), 2 mm-MgCl2, 15 mm-CaCl2 and 1·5 m-sucrose, and then 0·1 m-dithiothreitol and protease inhibitor cocktail were added. After centrifugation (10 500 g for 20 min at 4°C), the supernatant was used as the Western blotting sample. Protein samples (30 μg) were analysed by SDS-PAGE in 8 % acrylamide gels for the detection of adhesion molecules and in 10 % gels for the detection of inflammation-related protein (NF-κB p65, Iκ-Bα, iNOS, COX-2), and the proteins were then transferred onto nitrocellulose membrane (Whatman GmbH). Non-specific binding was blocked by immersing the membrane in 5 % skimmed milk. The membrane was incubated with first antibodies and preserved overnight at 4°C. After washing with PBS containing 0·1 % Tween 20 three times for 40 min, the membrane was further incubated with horseradish peroxidase-conjugated rabbit anti-goat IgG (Santa Cruz Biotechnology) at a 1:5000 dilution for 1 h at room temperature and detected by enhanced chemiluminescence (Pierce, Life Science).

Detection of tetrahydrobiopterin and total biopterin in the aorta

Freshly isolated whole aortas were homogenised in extraction buffer containing 50 mm-Tris (pH 7·4), 1 mm-dithiotheritol and 1 mm-EDTA at 4°C, and were centrifuged at 12 000 rpm for 15 min at 4°C(Reference d'Uscio and Katusic22). One whole aorta is needed for n 1 experiment. Samples were oxidised under either acidic conditions (with 0·2 m-HCl containing 50 mm-I2) or alkaline conditions (with 0·2 m-NaOH containing 50 mm-I2). Biopterin content was assessed using HPLC (Agilent 110 Series, Agilent Technologies) with fluorescence detection (350 nm excitation, 450 nm emission). BH4 concentration was calculated as pmol/mg protein by subtracting the biopterin peak resulting from alkaline oxidation (accounting for BH2) from the biopterin peak resulting from acidic oxidation (accounting for both BH2 and BH4).

Detection of asymmetric dimethylarginine in plasma

The proteins in the conditioned medium were removed using 5-sulfosalicylic acid. The levels of ADMA were measured by HPLC with some modifications(Reference Chen, Xia and Zhao23). O-Phthaldialdehyde adducts of methylated amino acids and internal standard ADMA were monitored using fluorescence detector which was set the excitation wavelengths of 360 nm and emission of 440 nm on a Gemini C18 column (Agilent 1100 Series, Agilent Technologies). Samples were eluted from the column using a linear gradient containing mobile phase A composed of 0·05 m (pH 6·8) sodium acetate–methanol–tetrahydrofuran (81:18:1, by vol.) and mobile phase B composed of 0·05 mm-sodium acetate–methanol–tetrahydrofuran (22:77:1, by vol.) at a flow-rate of 1 ml/min.

Statistical analysis

All data are presented as means with their standard errors. Student's t test was performed to determine statistical significance, with P <0·05 considered statistically significant.

Results

3′-(4′-Hydroxyl-3′,5′-dimethoxyphenyl)propionic acid prevented the altered nitric oxide bioavailability through inhibition of endothelial nitric oxide synthase uncoupling in the aorta

The induction of eNOS uncoupling generates superoxide rather than NO, consequently enhancing oxidative stress in the atherosclerotic aorta. First, to evaluate the effect of HDMPPA on oxidative stress in the aortas of apoE KO mice, ROS was determined using a fluoro-spectrophotometer (Fig. 1(a)). ROS production was significantly decreased in the aorta treated with HDMPPA (788·7 fluorescence/min per mg protein), compared with control (980·1 fluorescence/min per mg protein). Next, NO concentration in the aorta of apoE KO mice was significantly augmented by HDMPPA treatment (P < 0·05, Fig. 1(b)). Finally, HDMPPA treatment elevated the protein level of eNOS in the aorta of apoE KO mice (P < 0·05, Fig. 1(c)). These results indicate that HDMPPA inhibited eNOS uncoupling through an increase in NO production and a reduction of ROS in the aorta.

Fig. 1 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on (a) reactive oxygen species (ROS) and (b) nitric oxide (NO) generation, and (c, d) endothelial NO synthase (eNOS) protein expression in the aorta of apoE knockout (KO) mice. Control, PBS (vehicle)-treated apoE KO mice; HDMPPA, HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). * Mean values were significantly different from those of the control group (P < 0·05).

3′-(4′-Hydroxyl-3′,5′-dimethoxyphenyl)propionic acid augmented endothelial nitric oxide synthase activity through increased cofactor and decreased inhibitor

To see how HDMPPA works on BH4 stabilisation, we measured the biopterin content in the aorta of apoE KO mice (Fig. 2(a)). HDMPPA increased BH4 contents in the aorta of apoE-deficient mice by 25·9 %, compared to that of the control group (P < 0·05) while, as shown in Fig. 2(b), the plasma level of ADMA in the HDMPPA group was significantly decreased (1·04 v. 1·36 μm, P < 0·05), compared to that of control mice.

Fig. 2 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on (a) aortic tetrahydrobiopterin (BH4) and (b) plasma asymmetric dimethylarginine (ADMA) in apoE knockout (KO) mice. Control, PBS (vehicle)-treated apoE KO mice; HDMPPA, HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). Mean values were significantly different from those of the control group: *P < 0·05, **P < 0·01.

3′-(4′-Hydroxyl-3′,5′-dimethoxyphenyl)propionic acid decreased the adhesion molecules in the aorta

To investigate the anti-inflammatory effect of HDMPPA in the aorta of apoE KO mice, we examined the effect of HDMPPA on protein expression of VCAM-1 and ICAM-1 in the aorta by Western blotting. As shown in Fig. 3, protein levels of VCAM-1 and ICAM-1 in the aorta of the HDMPPA group was significantly reduced compared to the control group (P < 0·05).

Fig. 3 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on protein expression of adhesion molecules in the aorta of apoE knockout (KO) mice. Control (□), PBS (vehicle)-treated apoE KO mice; HDMPPA (■), HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). * Mean values were significantly different from those of the control group (P < 0·05). VCAM-1, vascular cellular adhesion molecule-1; ICAM-1, intercellular adhesion molecule-1.

3′-(4′-Hydroxyl-3′,5′-dimethoxyphenyl)propionic acid reduced the pro-inflammatory enzymes in the aorta

The inhibitory effect of HDMPPA on inflammatory response was examined in terms of determining the protein expressions of COX-2 and iNOS by Western blotting. A marked decrease in COX-2 protein expression was observed in the aorta of apoE KO mice treated with HDMPPA (P < 0·01, Fig. 4). Also, the HDMPPA-treated group showed lower protein level of iNOS than the control group in the aorta of apoE KO mice (P < 0·05, Fig. 4).

Fig. 4 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on protein expression of inducible nitric oxide synthase (iNOS) and cyclo-oxygenase-2 (COX-2) in the aorta of apoE knockout (KO) mice. Control (□), PBS (vehicle)-treated apoE KO mice; HDMPPA (■), HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). Mean values were significantly different from those of the control group: *P < 0·05, **P < 0·01.

In the HDMPPA group, IκBα protein level was significantly increased (P < 0·01), whereas NF-κB p65 protein level was decreased (P < 0·01) in the aortic lysate, compared with the control group (Fig. 5).

Fig. 5 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on protein expression of Iκ-Bα and NF-κB p65 in the aorta of apoE knockout (KO) mice. Control (□), PBS (vehicle)-treated apoE KO mice; HDMPPA (■), HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). * Mean values were significantly different from those of the control group (P < 0·01).

Discussion

The alterations of NO pathway, such as increased NO decomposition by the superoxide anion (formation of peroxynitrite) or altered NO-generating enzyme (mostly eNOS) expression, play a central role in endothelial dysfunction induced by hypercholesterolaemia(Reference Harrison24). Under physiological conditions, endothelial stimulation induces the production and release of NO, which diffuses to surrounding tissue and cells and exerts its cardiovascular protective effect by relaxing media-smooth muscle cells, preventing leucocyte adhesion and migration into the arterial wall, muscle cell proliferation, platelet adhesion and aggregation, and adhesion molecule expression(Reference Li and Forstermann1, Reference Li, Wallerath and Forstermann2). Several reports have determined that eNOS deficiency accelerates plaque formation, confirming the important role of endothelial NO production for atheroprotection(Reference Kuhlencordt, Gyurko and Han25, Reference Chen, Kuhlencordt and Astern26). Therefore, preventing NO breakdown by ROS and/or decreased production by eNOS could be a therapeutic target against the process of vascular disease. Moreover, several studies have shown that some agents used to increase NO production and/or to inhibit the loss of NO bioavailability were helpful to retard the process of vascular disease(Reference Herman and Moncada27). In this study, HDMPPA treatment significantly augmented NO concentration in the aorta of apoE KO mice, accompanied by a reduction of ROS levels. In our previous study, we demonstrated that HDMPPA effectively reduced vascular ROS level through inhibiting NADPH oxidase activity in apoE KO mice(Reference Noh, Kim and Kwon18). Furthermore, the protein expression of eNOS was up-regulated in the aorta of the HDMPPA-treated group. These results suggested that HDMPPA could prevent the loss of NO bioavailability via reduction of ROS level and up-regulation of eNOS.

Another important factor related to the preservation of NO bioactivity is the prevention of eNOS uncoupling, which generates superoxide rather than NO. BH4 is an essential cofactor required for the activity of eNOS. Recent research demonstrated that eNOS activity (to generate NO) can be modestly augmented by increasing BH4 levels even under the normal physiological conditions(Reference Bendall, Alp and Warrick28). BH4 deficiency is believed to lead to eNOS uncoupling, resulting in impaired endothelium-dependent vasodilation and the production of superoxide radicals from the uncoupled enzymatic form. Additionally, an increased oxidation of BH4 is often considered as a mechanism explaining BH4 deficiency in several vascular conditions(Reference Moens and Kass29). Laursen et al. (Reference Laursen, Somers and Kurz30) demonstrated that peroxynitrite was the principal ROS which oxidises BH4. In this study, HDMPPA showed scavenging activity of peroxynitrite in vitro (data not shown) and inhibited ROS generation in the aorta, suggesting that HDMPPA might further prevent the formation of peroxynitrite. Moreover, the HDMPPA-treated group showed higher BH4 concentration than that of the control group, suggesting that HDMPPA could prevent the oxidation of BH4. Therefore, HDMPPA elevated protein expression of eNOS, at least in part, through increased BH4 levels.

In addition, eNOS activity is determined by an endogenous inhibitor, ADMA, which inhibits cellular l-arginine uptake by endothelial cells, leading to the reduction of NO generation from l-arginine. It is postulated that altered NO bioavailability may result from an increase in ADMA, which may be a critical factor for vascular disease(Reference Böger31Reference Cooke33). Circulating ADMA levels have been assessed in a variety of systemic CVD, and are increased in conditions associated with hypercholesterolaemia, atherosclerosis, hypertension, chronic renal failure and chronic heart failure(Reference Siroen, Teerlink and Nijveldt34). Animal studies using the rabbit, rat and mouse have shown that the concentration of ADMA in the plasma was increased under a variety of hypercholesterolaemic conditions(Reference Yu, Li and Xiong35Reference Kang, Yu and Yoo37). Administration of exogenous ADMA for 4 weeks aggravated atherosclerotic lesions both in apoE KO mice and in C57BL/6J mice(Reference Xiao, Yang and Jia36). Other studies have documented that lysophosphatidylcholine or oxidised-LDL elevated the production of ADMA while certain antioxidants such as vitamin E, probucol and xanthines markedly prevented the elevation of ADMA in the plasma(Reference Jiang, Li Ns and Li38, Reference Jiang, Hu and Jiang39). Therefore, plasma ADMA may be involved in the progression of atherosclerosis, and therefore, the reduction of ADMA beneficially influences the process of vascular disease. In the present study, HDMPPA significantly decreased plasma ADMA levels in apoE KO mice. These data suggest that HDMPPA improves reduced NO bioactivity and eNOS expression in the aorta of atherosclerotic mice via decreased plasma ADMA.

Atherosclerosis is a chronic inflammatory process which is involved and interacted with various factors such as immunomodulatory compounds, immune cells and blood lipid profile(Reference Lusis40). Elevated LDL oxidation by ROS as well as a loss of vascular protective effect of NO are strongly associated with the inflammatory process of atherosclerosis(Reference Miller, Choi and Fang41). As an initial event in the pathogenesis of atherosclerosis, expression of adhesion molecules, especially both of ICAM-1 and VCAM-1, plays a central role in the recruitment of circulating monocytes and invasion into the intima. Up-regulation of VCAM-1 and ICAM-1 at the endothelial cell surface initiates pathological leucocyte–endothelial cell interaction, which ultimately exposes the vascular wall and surrounding tissues to the damaging action of activated leucocytes and causes the subsequent development of endothelial dysfunction/atherosclerosis(Reference Davenpeck, Gauthier and Albertine42Reference Nakashima, Raines and Plump44). COX-2 induces the pathogenesis of inflammatory disorders in response to the production of a variety of inflammatory cytokines, many of which are known to be produced during the progression of atherosclerosis(Reference Baker, Hall and Evans45). The elevated expression of iNOS has been observed in atherosclerotic lesions where high amounts of NO are produced and combine with superoxide, which might enhance the progression of atherosclerosis(Reference Buttery, Springall and Chester46, Reference Luoma, Stralin and Marklund47). In addition, the deficiency of iNOS reduced the progression of atherosclerosis(Reference Kuhlencordt, Chen and Han48). Our results showed that HDMPPA treatment markedly reduced the protein expression of VCAM-1 and ICAM-1 in the aorta of apoE KO mice. Moreover, pro-inflammatory iNOS and COX-2 expression in the aorta were decreased by HDMPPA treatment. These results indicate that HDMPPA suppressed the inflammatory responses in the aorta of apoE KO mice.

It has been shown that the activation and translocation of the redox-sensitive transcription factor NF-κB are essential for the signal transduction pathway for the expressions of adhesion molecules and pro-inflammatory enzymes(Reference Bu, Erl and de Martin49, Reference Collins, Read and Neish50). NF-κB has been implicated as a key mediator of inflammatory response in atherosclerosis(Reference Thurberg and Collins51). This transcription factor is a DNA binding protein complex that is usually present in the cytosol as an inactive complex. IκB, an associated protein, renders this complex inactive by shielding the nuclear localisation signal. Upon IκB phosphorylation and its subsequent degradation, the heterodimeric NF-κB complex translocates from the cytosol to the nucleus, where it binds to specific DNA sequences in the promoter region of several genes and up-regulates their transcription. Most inflammatory genes expressed in endothelial cells during the initial phase of lesion formation and in response to inflammatory mediators are dependent on NF-κB activation(Reference De Martin, Hoeth and Hofer-Warbinek52). Genes encoding a variety of inflammatory effectors including cytokines, chemokines, growth factors, leucocyte adhesion molecules and inducible enzymes such as iNOS are NF-κB responsive(Reference Lin, Liu and Peng53Reference Collins and Cybulsky55). From the results of another report, H2O2 or oxygen radicals produced during the inflammatory processes act as a second messenger to activate NF-κB directly or indirectly(Reference Schreck, Rieber and Baeuerle56). However, numerous studies suggest that ROS inhibitors such as flavonoids, α-tocopherol, ascorbate, troglitazone, aspirin, gallate, etc. decrease NF-κB activation induced by IL-1 or TNF-α and suppress the activation of adhesion molecules and chemoattractant which are indispensable molecules for atherogenesis(Reference Weber, Erl and Pietsch57Reference Murase, Kume and Hase61). The present data showed that aortic protein expression of IκB-α was increased but that of NF-κB p65 was reduced in the HDMPPA-treated group, compared with the control group. Although we did not examine the nuclear activation of NF-κB, our experimental results could demonstrate that HDMPPA regulate inflammatory response by the inhibition of NF-κB expression, which results may be due to the antioxidant activity of HDMPPA.

Several studies to identify the potential health benefits of kimchi have demonstrated that kimchi exerted its lipid-lowering activity as in experimental animal(Reference Song10, Reference Kwon, Song and Choi13Reference Kim, Kwon and Seo15) and human studies(Reference Kwon, Chun and Song11, Reference Choi, Kim and Kwon12), and that its active compound, HDMPPA, showed anti-atherosclerotic effect by decreasing the aortic intima thickness and fatty streak size of aortic sinus in hypercholesterolaemic rabbits(Reference Kim, Lee and Chung16) and mice(Reference Noh, Kim and Kwon18), respectively. On the basis of average kimchi consumption (150 g/d) by Korean adults, the physiological amount of HDMPPA is about 1·5 mg/d. Unfortunately, the dose of HDMPPA used in this study is not physiologically relevant to human consumption levels. However, the pharmacological dose of HDMPPA (for example, pill-format) may be more beneficial for therapeutic applications in human atherosclerosis. In Fig. 6, the anti-atherosclerotic effect of HDMPPA in the aorta of apoE KO mice was depicted. HDMPPA increased NO content in the aorta, while reducing ROS concentration. Furthermore, in the HDMPPA-treated group, aortic eNOS expression was up-regulated compared with the control group. These results suggest that HDMPPA could maintain NO bioavailability through increasing eNOS expression and preventing NO degradation by ROS. HDMPPA treatment in apoE KO mice inhibited eNOS uncoupling through an increase in vascular BH4 content and a decrease in serum ADMA levels. Moreover, HDMPPA ameliorated inflammatory response in the aorta of apoE KO mice probably through inhibiting NF-κB expression. Therefore, the present study suggests that HDMPPA, the active compound of kimchi, a Korean functional food, may exert its vascular protective potential through the preservation of NO bioavailability and suppression of the inflammatory response.

Fig. 6 Overall effects of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on nitric oxide (NO) bioavailability and inflammatory response. ROS, reactive oxygen species; eNOS, endothelial NO synthase; BH4, tetrahydrobiopterin; ADMA, asymmetric dimethylarginine; VCAM-1, vascular cellular adhesion molecule-1; ICAM-1, intercellular adhesion molecule-1; COX-2, cyclo-oxygenase-2; iNOS, inducible NO synthase. (A colour version of this figure can be found online at www.journals.cambridge.org/bjn)

Acknowledgements

The present study was supported by a grant (KRF-2005-202-F00058) from the Korea Research Foundation funded by the Korean Government. J. S. N. and Y. H. C. conducted the experimental work. Y. O. S. designed the experiment and wrote the manuscript. The authors declare that they have no competing financial interests in relation to this study.

References

1Li, H & Forstermann, U (2000) Nitric oxide in the pathogenesis of vascular disease. J Pathol 190, 244254.3.0.CO;2-8>CrossRefGoogle ScholarPubMed
2Li, H, Wallerath, T & Forstermann, U (2002) Physiological mechanisms regulating the expression of endothelial-type NO synthase. Nitric Oxide 7, 132147.Google Scholar
3Thum, T, Fraccarollo, D, Schultheiss, M, et al. (2007) Endothelial nitric oxide synthase uncoupling impairs endothelial progenitor cell mobilization and function in diabetes. Diabetes 56, 666674.CrossRefGoogle ScholarPubMed
4Li, H & Forstermann, U (2009) Prevention of atherosclerosis by interference with the vascular nitric oxide system. Curr Pharm Des 15, 31333145.CrossRefGoogle ScholarPubMed
5Antoniades, C, Shirodaria, C, Leeson, P, et al. (2009) Association of plasma asymmetrical dimethylarginine (ADMA) with elevated vascular superoxide production and endothelial nitric oxide synthase uncoupling: implications for endothelial function in human atherosclerosis. Eur Heart J 30, 11421150.CrossRefGoogle ScholarPubMed
6Palmer, RMJ, Ferrige, AG & Moncada, S (1987) Nitric oxide release accounts for the biological activity of endothelium-derived relaxing factor. Nature 327, 524526.CrossRefGoogle ScholarPubMed
7Ross, R (1999) Atherosclerosis – an inflammatory disease. N Eng J Med 340, 115126.Google Scholar
8Pahl, HL (1999) Activators and target genes of Rel/NF-κB transcription factors. Oncogene 18, 68536866.Google Scholar
9Cheigh, HS & Park, KY (1995) Biochemical, microbiological and nutritional aspects of kimchi (Korean fermented vegetable products). Crit Rev Food Sci Nutr 34, 175203.Google Scholar
10Song, YO (2004) The functional properties of Kimchi for the health benefits. Food Ind Nutr 9, 2733.Google Scholar
11Kwon, MJ, Chun, JH, Song, YS, et al. (1999) Daily kimchi consumption and its hypolipidemic effect in middle-aged men. J Korean Soc Food Sci Nutr 28, 11441150.Google Scholar
12Choi, SH, Kim, HJ, Kwon, MJ, et al. (2001) The effect of kimchi pill supplementation on plasma lipid concentration in healthy people. J Korean Soc Food Sci Nutr 30, 913920.Google Scholar
13Kwon, MJ, Song, YS, Choi, MS, et al. (2003) Red pepper attenuates cholesteryl ester transfer protein activity and atherosclerosis in cholesterol-fed rabbits. Clin Chim Acta 332, 3744.Google Scholar
14Kwon, MJ, Song, YS, Choi, MS, et al. (2003) Cholesteryl ester transfer protein activity and atherogenic parameters in rabbits supplemented with cholesterol and garlic powder. Life Sci 72, 29532964.Google Scholar
15Kim, HJ, Kwon, MJ, Seo, JM, et al. (2004) The effect of 3-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid in Chinese cabbage kimchi on lowering hypercholesterolemia. J Korean Soc Food Sci Nutr 33, 5258.Google Scholar
16Kim, HJ, Lee, JS, Chung, HY, et al. (2007) 3-(4′-Hydroxyl-3′,5′-dimethoxyphenyl)propionic acid, an active principle of Kimchi, inhibits development of atherosclerosis in rabbits. J Agric Food Chem 55, 1048610492.Google Scholar
17Lee, YM, Kwon, MJ, Kim, JK, et al. (2004) Isolation and identification of active principle in Chinese cabbage kimchi responsible for antioxidant effect. Korean J Food Sci Technol 36, 129133.Google Scholar
18Noh, JS, Kim, HJ, Kwon, MJ, et al. (2009) Active principle of kimchi, 3-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid, retards fatty streak formation at aortic sinus of apolipoprotein E knockout mice. J Med Food 12, 12061212.Google Scholar
19Nishina, PM, Verstuyft, J & Paigen, B (1990) Synthetic low and high fat diets for the study of atherosclerosis in the mouse. J Lipid Res 31, 859869.CrossRefGoogle Scholar
20Green, LC, Wagner, DA, Glogowski, J, et al. (1982) Analysis of nitrate, nitrite, and [15N]nitrate in biological fluids. Anal Biochem 126, 131138.Google Scholar
21Ali, SF, LeBel, CP & Bondy, SC (1992) Reactive oxygen species formation as a biomarker of methylmercury and trimethyltin neurotoxicity. Neurotoxicology 13, 637648.Google Scholar
22d'Uscio, LV & Katusic, ZS (2006) Increased vascular biosynthesis of tetrahydrobiopterin in apolipoprotein E-deficient mice. Am J Physiol Heart Circ Physiol 290, H2466H2471.Google Scholar
23Chen, BM, Xia, LW & Zhao, dRQ (1997) Determination of N G, N G-dimethylarginine in human plasma by high-performance liquid chromatography. J Chromatogr B Biomed Sci Appl 692, 467471.CrossRefGoogle Scholar
24Harrison, DG (1997) Cellular and molecular mechanisms of endothelial cell dysfunction. J Clin Invest 100, 21532157.Google Scholar
25Kuhlencordt, PJ, Gyurko, R, Han, F, et al. (2001) Accelerated atherosclerosis, aortic aneurysm formation, and ischemic heart disease in apolipoprotein E/endothelial nitric oxide synthase double-knockout mice. Circulation 104, 448454.Google Scholar
26Chen, J, Kuhlencordt, PJ, Astern, J, et al. (2001) Hypertension does not account for the accelerated atherosclerosis and development of aneurysms in male apolipoprotein e/endothelial nitric oxide synthase double knockout mice. Circulation 104, 23912394.CrossRefGoogle Scholar
27Herman, AG & Moncada, S (2005) Therapeutic potential of nitric oxide donors in the prevention and treatment of atherosclerosis. Eur Heart J 26, 19451955.CrossRefGoogle ScholarPubMed
28Bendall, JK, Alp, NJ, Warrick, N, et al. (2005) Stoichiometric relationships between endothelial tetrahydrobiopterin, endothelial NO synthase (eNOS) activity, and eNOS coupling in vivo: insights from transgenic mice with endothelial-targeted GTP cyclohydrolase 1 and eNOS overexpression. Circ Res 97, 864871.Google Scholar
29Moens, AL & Kass, DA (2007) Therapeutic potential of tetrahydrobiopterin for treating vascular and cardiac disease. J Cardiovasc Pharmacol 50, 238246.Google Scholar
30Laursen, JB, Somers, M, Kurz, S, et al. (2001) Endothelial regulation of vasomotion in apoE-deficient mice: implications for interactions between peroxynitrite and tetrahydrobiopterin. Circulation 103, 12821288.Google Scholar
31Böger, RH (2003) Association of asymmetric dimethylarginine and endothelial dysfunction. Clin Chem Lab Med 41, 14671472.Google Scholar
32Lentz, SR, Rodionov, RN & Dayal, S (2003) Hyperhomocysteinemia, endothelial dysfunction, and cardiovascular risk: the potential role of ADMA. Atheroscler Suppl 4, 6165.CrossRefGoogle ScholarPubMed
33Cooke, JP (2000) Does ADMA cause endothelial dysfunction? Arterioscler Thromb Vasc Biol 20, 20322037.CrossRefGoogle ScholarPubMed
34Siroen, MP, Teerlink, T, Nijveldt, RJ, et al. (2006) The clinical significance of asymmetric dimethylarginine. Annu Rev Nutr 26, 203228.Google Scholar
35Yu, XJ, Li, YJ & Xiong, Y (1994) Increase of an endogenous inhibitor of nitric oxide synthesis in serum of high cholesterol fed rabbits. Life Sci 54, 753758.Google Scholar
36Xiao, HB, Yang, ZC, Jia, SJ, et al. (2007) Effect of asymmetric dimethylarginine on atherogenesis and erythrocyte deformability in apolipoprotein E deficient mice. Life Sci 81, 17.Google Scholar
37Kang, KK, Yu, JY, Yoo, M, et al. (2005) The effect of DA-8159, a novel PDE5 inhibitor, on erectile function in the rat model of hypercholesterolemic erectile dysfunction. Int J Impot Res 17, 409416.Google Scholar
38Jiang, JL, Li Ns, NS, Li, YJ, et al. (2002) Probucol preserves endothelial function by reduction of the endogenous nitric oxide synthase inhibitor level. Br J Pharmacol 135, 11751182.Google Scholar
39Jiang, DJ, Hu, GY, Jiang, JL, et al. (2003) Relationship between protective effect of xanthone on endothelial cells and endogenous nitric oxide synthase inhibitors. Bioorg Med Chem 11, 51715177.CrossRefGoogle ScholarPubMed
40Lusis, AJ (2000) Atherosclerosis. Nature 407, 233241.Google Scholar
41Miller, YI, Choi, SH, Fang, L, et al. (2010) Lipoprotein modification and macrophage uptake: role of pathologic cholesterol transport in atherogenesis. Subcell Biochem 51, 229251.Google Scholar
42Davenpeck, KL, Gauthier, TW, Albertine, KH, et al. (1994) Role of P-selectin in microvascular leukocyte-endothelial interaction in splanchnic ischemia-reperfusion. Am J Physiol 267, H622H630.Google Scholar
43Martin, J, Collot-Teixeira, S, McGregor, L, et al. (2007) The dialogue between endothelial cells and monocytes/macrophages in vascular syndromes. Curr Pharm Des 13, 17511759.Google Scholar
44Nakashima, Y, Raines, EW, Plump, AS, et al. (1998) Upregulation of VCAM-1 and ICAM-1 at atherosclerosis-prone sites on the endothelium in the ApoE-deficient mouse. Arterioscler Thromb Vasc Biol 18, 842851.Google Scholar
45Baker, CS, Hall, RJ, Evans, TJ, et al. (1999) Cyclooxygenase-2 is widely expressed in atherosclerotic lesions affecting native and transplanted human coronary arteries and colocalizes with inducible nitric oxide synthase and nitrotyrosine particularly in macrophages. Arterioscler Thromb Vasc Biol 19, 646655.CrossRefGoogle ScholarPubMed
46Buttery, LD, Springall, DR, Chester, AH, et al. (1996) Inducible nitric oxide synthase is present within human atherosclerotic lesions and promotes the formation and activity of peroxynitrite. Lab Invest 75, 7785.Google Scholar
47Luoma, JS, Stralin, P & Marklund, SL (1998) Expression of extracellular SOD and iNOS in macrophages and smooth muscle cells in human and rabbit atherosclerotic lesions. Arterioscler Thromb Vasc Biol 18, 157167.CrossRefGoogle ScholarPubMed
48Kuhlencordt, PJ, Chen, J, Han, F, et al. (2001) Genetic deficiency of inducible nitric oxide synthase reduces atherosclerosis and lowers plasma lipid peroxides in apolipoprotein E-knockout mice. Circulation 103, 30993104.Google Scholar
49Bu, DX, Erl, W, de Martin, R, et al. (2005) Iκ-Kβ-dependent NF-κB pathway controls vascular inflammation and intimal hyperplasia. FASEB J 19, 12931295.Google Scholar
50Collins, T, Read, MA, Neish, AS, et al. (1995) Transcriptional regulation of endothelial cell adhesion molecules: NF-kappa B and cytokine-inducible enhancers. FASEB J 9, 899909.Google Scholar
51Thurberg, BL & Collins, T (1998) The nuclear factor-kappa B/inhibitor of kappa B autoregulatory system and atherosclerosis. Curr Opin Lipidol 9, 387396.Google Scholar
52De Martin, R, Hoeth, M, Hofer-Warbinek, R, et al. (2000) The transcription factor NF-kappa B and the regulation of vascular cell function. Arterioscler Thromb Vasc Biol 20, E83E88.Google Scholar
53Lin, R, Liu, J, Peng, N, et al. (2005) Lovastatin reduces nuclear factor kappaB activation induced by C-reactive protein in human vascular endothelial cells. Biol Pharm Bull 28, 16301634.Google Scholar
54Baldwin, AS (2001) Series introduction: the transcription factor NF-kappaB and human disease. J Clin Invest 107, 36.Google Scholar
55Collins, T & Cybulsky, MI (2001) NF-kappaB: pivotal mediator or innocent bystander in atherogenesis? J Clin Invest 107, 255264.Google Scholar
56Schreck, R, Rieber, P & Baeuerle, PA (1991) Reactive oxygen intermediates as apparently widely used messengers in the activation of the NF-kappa B transcription factor and HIV-1. EMBO J 10, 22472258.Google Scholar
57Weber, C, Erl, W, Pietsch, A, et al. (1994) Antioxidants inhibit monocyte adhesion by suppressing nuclear factor-kappa B mobilization and induction of vascular cell adhesion molecule-1 in endothelial cells stimulated to generate radicals. Arterioscler Thromb 14, 16651673.Google Scholar
58Kharbanda, RK, Walton, B, Allen, M, et al. (2002) Prevention of inflammation-induced endothelial dysfunction: a novel vascular-protective action of aspirin. Circulation 105, 26002604.Google Scholar
59Gerritsen, ME, Carley, WW, Ranges, GE, et al. (1995) Flavonoids inhibit cytokine-induced endothelial cell adhesion protein gene expression. Am J Pathol 147, 278292.Google Scholar
60Cominacini, L, Garbin, U, Pasini, AF, et al. (1999) The expression of adhesion molecules on endothelial cells is inhibited by troglitazone through its antioxidant activity. Cell Adhes Commun 7, 223231.Google Scholar
61Murase, T, Kume, N, Hase, T, et al. (1999) Gallates inhibit cytokine-induced nuclear translocation of NF-kappaB and expression of leukocyte adhesion molecules in vascular endothelial cells. Arterioscler Thromb Vasc Biol 19, 14121420.Google Scholar
Figure 0

Fig. 1 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on (a) reactive oxygen species (ROS) and (b) nitric oxide (NO) generation, and (c, d) endothelial NO synthase (eNOS) protein expression in the aorta of apoE knockout (KO) mice. Control, PBS (vehicle)-treated apoE KO mice; HDMPPA, HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). * Mean values were significantly different from those of the control group (P < 0·05).

Figure 1

Fig. 2 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on (a) aortic tetrahydrobiopterin (BH4) and (b) plasma asymmetric dimethylarginine (ADMA) in apoE knockout (KO) mice. Control, PBS (vehicle)-treated apoE KO mice; HDMPPA, HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). Mean values were significantly different from those of the control group: *P < 0·05, **P < 0·01.

Figure 2

Fig. 3 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on protein expression of adhesion molecules in the aorta of apoE knockout (KO) mice. Control (□), PBS (vehicle)-treated apoE KO mice; HDMPPA (■), HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). * Mean values were significantly different from those of the control group (P < 0·05). VCAM-1, vascular cellular adhesion molecule-1; ICAM-1, intercellular adhesion molecule-1.

Figure 3

Fig. 4 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on protein expression of inducible nitric oxide synthase (iNOS) and cyclo-oxygenase-2 (COX-2) in the aorta of apoE knockout (KO) mice. Control (□), PBS (vehicle)-treated apoE KO mice; HDMPPA (■), HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). Mean values were significantly different from those of the control group: *P < 0·05, **P < 0·01.

Figure 4

Fig. 5 Effect of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on protein expression of Iκ-Bα and NF-κB p65 in the aorta of apoE knockout (KO) mice. Control (□), PBS (vehicle)-treated apoE KO mice; HDMPPA (■), HDMPPA 10 mg/kg of body weight-treated apoE KO mice. Values are means, with their standard errors represented by vertical bars (n 5). * Mean values were significantly different from those of the control group (P < 0·01).

Figure 5

Fig. 6 Overall effects of 3′-(4′-hydroxyl-3′,5′-dimethoxyphenyl)propionic acid (HDMPPA) on nitric oxide (NO) bioavailability and inflammatory response. ROS, reactive oxygen species; eNOS, endothelial NO synthase; BH4, tetrahydrobiopterin; ADMA, asymmetric dimethylarginine; VCAM-1, vascular cellular adhesion molecule-1; ICAM-1, intercellular adhesion molecule-1; COX-2, cyclo-oxygenase-2; iNOS, inducible NO synthase. (A colour version of this figure can be found online at www.journals.cambridge.org/bjn)