key: cord-0760529-rz8lgisl
authors: Ryu, Bomi; Kim, Young-Sang; Jeon, You-Jin
title: Seaweeds and Their Natural Products for Preventing Cardiovascular Associated Dysfunction
date: 2021-09-07
journal: Mar Drugs
DOI: 10.3390/md19090507
sha: 60675d5738f84694ad49623e6b784d7910c4e115
doc_id: 760529
cord_uid: rz8lgisl

Cardiovascular disease (CVD), which involves the onset and exacerbation of various conditions including dyslipidemia, activation of the renin–angiotensin system, vascular endothelial cell damage, and oxidative stress, is a leading cause of high mortality rates and accounts for one-third of deaths worldwide. Accordingly, as dietary changes in daily life are thought to greatly reduce the prevalence of CVD, numerous studies have been conducted to examine the potential use of foods and their bioactive components for preventing and treating CVD. In particular, seaweeds contain unique bioactive metabolites that are not found in terrestrial plants because of the harsh environment in which they survive, leading to in vitro and in vivo studies of their prevention and treatment effects. This review summarizes studies that focused on the beneficial effects of seaweeds and their natural products targeting markers involved in a cascade of mechanisms related to CVD pathogenesis. The purpose of this review is to describe the potential of seaweeds and their natural products for preventing and treating CVD based on in vivo and in vitro studies. This review provides a basis for future research in the field of marine drugs.

According to the National Health and Nutrition Examination Survey, from 2015 to 2018, the prevalence of cardiovascular disease (CVD) including coronary heart disease (CHD), heart failure (HF), and hypertension in adults over 20 years of age is 49.2% (126.9 million people in 2018), whereas the CVD prevalence excluding hypertension (CHD, HF, and stroke only) is 9.3% (26.1 million in 2018) [1] . In another study, the overall prevalence of lipitension, hypertension alone, and hypercholesterolemia alone was found to be 30%, 47%, and 18%, respectively [2] . CVD is the leading cause of global mortality and a major contributor to disability, representing 17.8 million deaths, which accounts for 32% of all global deaths according to the statistics update in 2019 from the World Health Organization [3] . A large proportion of CVD cases is directly related to dietary risks, high systolic blood pressure (BP), high body mass index, high total cholesterol level, high fasting plasma glucose level, tobacco smoking, and low levels of physical activity [3] .

Particularly, several medical studies across diverse hospitals and patient populations have revealed that patients with coronavirus disease 2019 (COVID-19) and underlying CVD are at an increased risk for developing severe symptoms, poor prognosis, and high mortality rates [4] [5] [6] . Although the relationship between COVID-19 and CVD remains unclear, approximately 30-35% of COVID-related deaths are known to be associated with underlying CVD, supporting the close relationship between these conditions [5, 7] . Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the etiologic agent of COVID-19, targets the angiotensin-converting enzyme 2 (ACE2) receptor on the host cell receptor by recognizing the viral spike protein; after entering the cells, the virus can cause infections in With changes in lifestyle and improvements in living standards, consumption of a high-fat diet has become common, gradually increasing the prevalence of hyperlipidemia. Hyperlipidemia is typically caused by increases in serum total cholesterol (TC), triglyceride (TG), and low-density lipoprotein cholesterol (LDL-C) levels and decreased levels of highdensity lipoprotein cholesterol (HDL-C). This condition is reported to be closely correlated with atherosclerosis and is a common cause of CVD [8, 20] . Adults in their 40s and 50s with hyperlipidemia have an increased risk of coronary heart disease, including those with a low cardiovascular risk [21] . In addition, it has been reported that long-term use of lipid-lowering agents improves the survival of patients with coronary heart disease to improve patient prognosis [22] .

As controlling blood lipid levels is important for preventing and improving CVD, many studies are being conducted to identify active components with lipid-lowering activities. Specifically, the prevalence of obesity-related diseases in people who consume marine products was shown to be low, suggesting that marine products and their active components have lipid-lowering effects [17, 23] . Based on this information, various marine products, including seaweed with lipid-lowering effects, have been evaluated to promote the development and utilization of related bioactive components. Table 1 shows the lipid-lowering effects of seaweed extracts observed in in vivo models. Table 1 . Lipid-lowering effect of seaweed and its components in in vitro and in vivo models.

Experimental Models Effects (% or mmol/L) Ref.

Himanthalia elongate, B Hypercholesterolaemic wistar rats : 21% in diets for four weeks ↓: TG by 28% ↑: HDL-C by 20% [24] Gigartina pistillata, R Hypercholesterolaemic wistar rats : 23% in diets for four weeks ↓: TG by 30%, TC by 18%, LDL-C by 16% [24] Derbesia tenuissima, G High-Fat Fed Rats : 5% in diets for eight weeks ↓: TG by 38% and TC by 17% [25] Gracilaria changii, R Supplementing the diets of hypercholesterolemic Wistar rats with 21% or 23% of Himanthalia elongata or Gigartina pistillata, which is equivalent to 8% dietary fiber for four weeks, improved the serum lipid profile as compared to in hypercholesterolemic Wistar rats without dietary intervention [24] . The Himanthalia diet significantly reduced the TG content by 28% and increased the HDL-C content by 20%. The diet containing Gigartina improved the lipid profile by decreasing TG, TC, or LDL-C levels by 30%, 18%, and 16%, respectively. Villanueva et al. also found that seaweed intake improved the lipid profile [24] . Kumar et al. reported that intake of Derbesia tenuissima for eight weeks decreased plasma TG and TC levels by 38% and 17%, respectively, in rats fed a high-fat diet because of the insoluble fiber content (23.4%) [25] . Chan et al. also found that Gracilaria changii, which has a high dietary fiber content of 61.29%, significantly improved the lipid profile of high-cholesterol/high-fat Sprague Dawley rats [26] . Rats fed a HF diet supplemented with 5% or 10% G. changii exhibited significantly reduced plasma TC, LDL-C, and TG contents. In addition, changes in the lipid profile were observed even in rats given normal feed supplemented with G. changii during the experimental period, but the authors explained that the lipid changes were caused by the normal growth process of the experimental model and were not related to the feed supplement. However, a change in the lipid profile of a normal animal model following seaweed intake was reported by Kim et al. [27] and Ruqqia et al. [29] . Kim et al. observed that Ecklonia cava had lipid-lowering effects in both normal mice and streptozotocin-diabetic mice, demonstrating the potential of this supplement to prevent the progression of coronary heart disease. Jung et al. [28] further evaluated the properties of phlorotannins from Ecklonia stolonifera in vitro. In addition, various seaweeds, including Rhizoclonium implexum, Dictyota indica, Padina pavonia, Stoechospermum marginatum, Stokeyia indica, Jolyna laminarioides, Sargassum binderi, and Melanothamnus afaqhusainii showed lipid-lowering effects by reducing TC, TC and LDL-C and increasing HDL-C in normal rats according to Ruqqia et al. [28] . The authors emphasized the medical importance of seaweed, as consumption of seaweed not only inhibited the progression of CVD, but also regulated the accumulation of lipids in daily life and may play an important role in improving the survival of humans. Based on the lipid-lowering effect in normal rats, Ruqqia et al. further investigated J. laminarioides, S. binderi, and M. afaqhusainii for their antihyperlipidemic effects in Triton-induced hyperlipidemic rats and in high-fat diet-induced hyperlipidemic rats. They found that the brown seaweeds J. laminarioides and S. binderi significantly decreased TG levels by 31.6% and 33% in high-fat diet-induced hyperlipidemic rats. Jimenez-Escrig and Sanchez-Muniz reported that alginic acid and alginic acid isolated from brown algae play important roles in lowering blood cholesterol levels in rats by decreasing intestinal cholesterol absorption [38] . Patil et al. noted that sulfated polysaccharides in brown algae delay the intestinal absorption of cholesterol or promote cholesterol excretion [39] . Cuong et al. produced fucoidan, a sulfated polysaccha-ride from the brown seaweed S. henslowianum, and found that it lowered cholesterol, TG, and LDL-C levels when administered orally at 100 mg/kgP/day to obese rats [30] . The red seaweed M. afaqhusainii, which contains 0.46 ± 0.01% sterols, also exerted lipid-lowering effects. In the 1970s, Bhakuni and Silva reported that cholesterol is the most commonly occurring sterol in red seaweed and can reduce blood cholesterol levels [40] . In addition, Ruqqia et al. found that the non-toxic sterols of red algae can lower blood cholesterol and fat accumulation in the heart and liver [29] . In a clinical study, carrageenans from red seaweed significantly decreased cholesterol levels (16.5%) and LDL-C levels (33.5%), leading to a reduced atherosclerotic index [31] . Dousip et al. compared the cholesterollowering properties of the red seaweed Kappaphycus alvarezii and brown seaweed Sargassum polycystum [32] . Kappaphycus alvarezii contains 42.09 ± 0.97% carrageenan and S. polycystum contains 8.98 ± 0.33% alginate. Sargassum polycystum consumption significantly decreased the plasma cholesterol level by 37.52% over an eight-week treatment period compared to K. alvarezii. Jiménez-Escrig and Sánchez-Muniz reported that the antihyperlipidemic activity of alginate in brown algae is affected by the degree of polymerization [38] . Accordingly, Dousip et al. explained that the cholesterol-lowering effect was lowered as the alginate of S. polycystum contained a high-molecular weight alginate polymer [32] . In addition, the beneficial effects of polysaccharides and ulvans in green seaweed extracted from Ulva fasciata, Ulva lactuca, and Monostroma nitidum were suggested to improve lipid profiles [33] [34] [35] . Marine-derived active components such as fucoidan and fucoxanthin have also been evaluated and shown to have beneficial effects on lipid profiles in in vivo models [36, 37] .

Atherosclerosis, mainly caused by hypertension and dyslipidemia, begins with dysfunction of vascular endothelial cells and develops into CVD via plaque accumulation and related lesion formation in the blood vessels [12] .

Vascular endothelial dysfunction is caused by (1) decreased eNOS activation by reduced intracellular Ca 2+ level in the endothelium, (2) decreased bioavailability of nitric oxide produced from eNOS, (3) increased production of endothelial-derived vasoconstrictor factors, and (4) increased levels of oxidative stress and inflammation-inducing cytokines [41] (Figure 1 ). Table 2 shows the effects of various seaweed components on endothelial dysfunction in in vitro and in vivo models. cholesterol or promote cholesterol excretion [39] . Cuong et al. produced fucoidan, a sulfated polysaccharide from the brown seaweed S. henslowianum, and found that it lowered cholesterol, TG, and LDL-C levels when administered orally at 100 mg/kgP/day to obese rats [30] . The red seaweed M. afaqhusainii, which contains 0.46 ± 0.01% sterols, also exerted lipid-lowering effects. In the 1970s, Bhakuni and Silva reported that cholesterol is the most commonly occurring sterol in red seaweed and can reduce blood cholesterol levels [40] . In addition, Ruqqia et al. found that the non-toxic sterols of red algae can lower blood cholesterol and fat accumulation in the heart and liver [29] . In a clinical study, carrageenans from red seaweed significantly decreased cholesterol levels (16.5%) and LDL-C levels (33.5%), leading to a reduced atherosclerotic index [31] . Dousip et al. compared the cholesterol-lowering properties of the red seaweed Kappaphycus alvarezii and brown seaweed Sargassum polycystum [32] . Kappaphycus alvarezii contains 42.09 ± 0.97% carrageenan and S. polycystum contains 8.98 ± 0.33% alginate. Sargassum polycystum consumption significantly decreased the plasma cholesterol level by 37.52% over an eight-week treatment period compared to K. alvarezii. Jiménez-Escrig and Sánchez-Muniz reported that the antihyperlipidemic activity of alginate in brown algae is affected by the degree of polymerization [38] . Accordingly, Dousip et al. explained that the cholesterol-lowering effect was lowered as the alginate of S. polycystum contained a high-molecular weight alginate polymer [32] . In addition, the beneficial effects of polysaccharides and ulvans in green seaweed extracted from Ulva fasciata, Ulva lactuca, and Monostroma nitidum were suggested to improve lipid profiles [33] [34] [35] . Marine-derived active components such as fucoidan and fucoxanthin have also been evaluated and shown to have beneficial effects on lipid profiles in in vivo models [36, 37] .

Atherosclerosis, mainly caused by hypertension and dyslipidemia, begins with dysfunction of vascular endothelial cells and develops into CVD via plaque accumulation and related lesion formation in the blood vessels [12] .

Vascular endothelial dysfunction is caused by (1) decreased eNOS activation by reduced intracellular Ca 2+ level in the endothelium, (2) decreased bioavailability of nitric oxide produced from eNOS, (3) increased production of endothelial-derived vasoconstrictor factors, and (4) increased levels of oxidative stress and inflammation-inducing cytokines [41] (Figure 1 ). Table 2 shows the effects of various seaweed components on endothelial dysfunction in in vitro and in vivo models. Alam et al. reported that the natural carotenoid astaxanthin extracted from microalgae Haematococcus pluvialis can penetrate the endothelial cell membrane and significantly inhibit ROS, thereby inhibiting oxidative stress in ISO-induced myocardial infarction and cardiac hypertrophy in rats, suggesting its cardioprotective action [42] . Zhao et al. found that astaxanthin protects against endothelial dysfunction of the aorta in diabetic rats and predicted the molecular mechanism involved in their effects [43] . They suggested that astaxanthin can attenuate blunted endothelium-dependent vasodilator responses to acetylcholine, upregulate endothelial nitric oxide synthase expression, and decrease excessive oxidative stress and endothelial dysfunction. Lee et al. isolated dieckol from the brown seaweed E. cava and found that it protected human umbilical vein endothelial cells damaged by high glucose via its antioxidant properties [44] . In addition, the positive effects of eckol and its derivatives, including dieckol from the brown seaweed Ecklonia bicyclis, were investigated in both human umbilical vein endothelial cells and mice [45] . They suggested that the abundance of hydroxyl groups of eckol and its derivatives contribute to their vascular barrier protective functions. Another phlorotannin, diphlorethohydroxycarmalol (DPHC) isolated from Ishige okamurae, was observed to have vasodilatory effects by increasing nitric oxide production and Ca 2+ release in endothelial cells via stimulating the Ach receptor and VEGF-receptor 2 [46] . The author further demonstrated the vasodilatory ability of DPHC in Tg(flk:EGFP) transgenic zebrafish. In addition, another crucial components in brown seaweed, the sulfated polysaccharides extracted from Padina tetrastromatica, were investigated for their effect on ISO-induced myocardial infarction in a rat model [47] . ISO-induced hyperlipidemia, endothelial dysfunction, and inflammatory reactions were significantly reduced by the sulfated polysaccharides. Specifically, the authors emphasized that sulfated polysaccharides can be used as a new functional food ingredient for CVD, as they showed therapeutic ability similar to that of aspirin, a reference drug.

Hypertension occurs in 25-30% of the population in developed countries and is used as a biomarker for increased cardiovascular risk [1] . Blood pressure monitoring is the most commonly used procedure for diagnosing hypertension. In normal individuals, the systolic and diastolic blood pressure values are less than 120 and 80 mmHg, respectively. The renin-angiotensin-aldosterone system regulates blood pressure [48] . Angiotensinogen is produced by the liver and circulates continuously in the plasma. Renin produced by the kidneys is responsible for cleaving angiotensinogen into angiotensin I in response to reduced blood flow. The produced angiotensin 1 (ACE-1) is cleaved by angiotensinconverting enzyme (ACE), which in turn produces angiotensin II (ACE-2) [48] . In addition, ACE-2 is typically associated with vasoconstriction and hypertension by modulating blood pressure and is involved in hyperplasia and hypertrophy of vascular smooth muscle cells in CVD progression ( Figure 2) . Thus, inhibition of ACE-I is a well-established approach for treating hypertension, and many authors have used seaweed extract and its components to screen for components in seaweed that inhibit this enzyme (Table 3) . drug.

Hypertension occurs in 25-30% of the population in developed countries and is used as a biomarker for increased cardiovascular risk [1] . Blood pressure monitoring is the most commonly used procedure for diagnosing hypertension. In normal individuals, the systolic and diastolic blood pressure values are less than 120 and 80 mmHg, respectively. The renin-angiotensin-aldosterone system regulates blood pressure [48] . Angiotensinogen is produced by the liver and circulates continuously in the plasma. Renin produced by the kidneys is responsible for cleaving angiotensinogen into angiotensin I in response to reduced blood flow. The produced angiotensin 1 (ACE-1) is cleaved by angiotensin-converting enzyme (ACE), which in turn produces angiotensin II (ACE-2) [48] . In addition, ACE-2 is typically associated with vasoconstriction and hypertension by modulating blood pressure and is involved in hyperplasia and hypertrophy of vascular smooth muscle cells in CVD progression ( Figure 2) . Thus, inhibition of ACE-I is a well-established approach for treating hypertension, and many authors have used seaweed extract and its components to screen for components in seaweed that inhibit this enzyme (Table 3 ). Cha et al. investigated the ACE-I inhibitory activities of red seaweeds (26 species) and found that Lomentaria catenate and Lithophyllum okamurae exhibited the strongest ACE inhibitory activity with IC 50 (µg/mL) values of 13.78 and 12.21, respectively, indicating their potential as ACE-I inhibitors [49] . In addition, the extracts of E. cava and their phlorotannin polyphenol compounds phloroglucinol, triphlorethol-A, phlorofucofuroeckol A, dieckol, eckol, eckstolonol, and 6,6-bieckol, which were isolated from the brown seaweed Ecklonia sp., were compared for their ACE inhibitory activity [50] [51] [52] . The authors suggested that E. cava is a promising agent for ACE-1 inhibition and that its phlorotannin can contribute to these inhibitory effects. Additionally, Ko et al. demonstrated that 6,6-bieckol, which has been shown to inhibit ACE, contributes to the stabilization of the ACE active site. The author analyzed the antihypertensive efficacy of 6,6-bieckol in a hypertensive rat model by measuring the systolic blood pressure and analyzing the binding affinity of each phlorotannin to the active site of the targeting ACE-1 protein [52] . As a result, they suggested that 6,6'-bieckol induced nitric oxide in vascular endothelial cells and effectively reduced systolic blood pressure in the spontaneous hypertension model, suggesting that this agent can be used to treat hypertension. Other studies conducted by Vijayan et al. [53] and Nagappan et al. [54] reported the beneficial effects of polyphenols in seaweed by Sargassum wightii and Sargassum siliquosum on inhibiting ACE-1. Another study analyzed the potential of total phenolic and carbohydrate contents of seaweeds, Lessonia nigrescens, Macrocystis pyrifera, and Durvillaea antarctica as ACE-1 inhibitors [55] . The authors reported that the total phenolic and carbohydrate contents in these brown seaweeds after enzymatic extraction compared to the conventional method (maceration) may be responsible for their superior ACE inhibitory activity. Zhu et al. reported that D-polymannuronic sulfate, a type of sulfated polysaccharide obtained from brown alga, significantly reduced systolic blood pressure and diastolic blood pressure by increasing the serum nitric oxide content in hypertensive animals and significantly lowering the plasma concentrations of Ang II and endothelin-1 [56] . In addition, sulfated polygalactans from the red seaweeds K. alvarezii and Gracilaria opuntia were shown to have ACE-1 inhibitory activity, demonstrating their potential as therapeutic candidates for preventing hypertensive disorders [57] .

As COVID-related mortality rates are high in patients with underlying CVD, many studies are underway to find new targeted drugs to prevent the uncontrolled spread of SARS-CoV-2 [5, 7] . Recent studies have suggested that SARS-CoV-2 uses ACE2, a component of the renin-angiotensin-aldosterone system, as an entry receptor in cells [58] . Accordingly, many studies are being conducted to identify new target drugs to inhibit the ACE2-binding affinity of the SARS-CoV-2 spike. Table 4 lists reports of components derived from seaweeds that can modulate ACE2 to prevent SARS-CoV-2 infection. Syahputra et al. screened secondary metabolites against SARS-CoV-2 isolated from 36 marine organisms with high biodiversity from Indonesia [59] . Molecular docking was used to screen the potential of each drug component for targeting a protein molecule. They suggested that inhibiting the enzymatic activity of ACE2 could prevent spike proteins from binding to ACE2. Accordingly, among the marine derived natural products dieckol, phlorofucofuroeckol A, fucoidan, thalassodendrone, and thalassiolin D were selected as competitors and protective agents against SARS-CoV-2 infection, as they form stable complexes with ACE2. In addition, Salih et al. reported that sulfated polysaccharides from brown seaweeds evaluated by molecular docking and dynamic simulation experiments revealed potential interactions with the spike protein of SARS-CoV-2, and the receptor binding domain of ACE2 was suggested as a potential target of SARS-CoV-2 inhibitors [60] . Youssef described the potential of alkaloids derived from the genus Aspergillus, a marinederived fungi, based on the structural stability of ACE2 bound to alkaloids in an in silico study [61] . They reported that fumigatoside E and aspergicin as introduced alkaloids were the most suitable active sites for ACE2, and they predicted a positive effect in preventing and eradicating SARS-CoV-2 infection that should be further studied. ACE2-binding affinity of the SARS-CoV-2 spike. Table 4 lists reports of components derived from seaweeds that can modulate ACE2 to prevent SARS-CoV-2 infection. ACE2-binding affinity of the SARS-CoV-2 spike. Table 4 lists reports of components derived from seaweeds that can modulate ACE2 to prevent SARS-CoV-2 infection. ACE2-binding affinity of the SARS-CoV-2 spike. Table 4 lists reports of components derived from seaweeds that can modulate ACE2 to prevent SARS-CoV-2 infection. ACE2-binding affinity of the SARS-CoV-2 spike. Table 4 lists reports of components derived from seaweeds that can modulate ACE2 to prevent SARS-CoV-2 infection. ACE2-binding affinity of the SARS-CoV-2 spike. Table 4 lists reports of components derived from seaweeds that can modulate ACE2 to prevent SARS-CoV-2 infection. ACE2-binding affinity of the SARS-CoV-2 spike. Table 4 lists reports of components derived from seaweeds that can modulate ACE2 to prevent SARS-CoV-2 infection. Syahputra et al. screened secondary metabolites against SARS-CoV-2 isolated from 36 marine organisms with high biodiversity from Indonesia [59] . Molecular docking was used to screen the potential of each drug component for targeting a protein molecule. They suggested that inhibiting the enzymatic activity of ACE2 could prevent spike proteins from binding to ACE2. Accordingly, among the marine derived natural products Syahputra et al. screened secondary metabolites against SARS-CoV-2 isolated from 36 marine organisms with high biodiversity from Indonesia [59] . Molecular docking was used to screen the potential of each drug component for targeting a protein molecule. They suggested that inhibiting the enzymatic activity of ACE2 could prevent spike proteins from binding to ACE2. Accordingly, among the marine derived natural products Note a : human ACE 2 receptor (PDB ID: 1R42); b : human ACE 2 receptor (PDB code: 1R42); C : human ACE 2 receptor (PDB code: 1R4L).

Seaweed is a valuable source of compounds with various uses, including improving cardiovascular health. In this review, the prevention of CVD by consuming seaweed was described, and the effects of seaweed and its components on the pathogenesis of CVD were evaluated. In addition, various studies including in vitro, in vivo, and related clinical evidence have shown that the onset and progression of CVD were improved through dietary supplementation with seaweed. However, to use seaweed and related ingredients as medical or functional foods, additional studies of their effects on the mechanism of CVD and their clinical relevance are required. These studies can be utilized to develop functional foods and pharmaceuticals for preventing and improving CVD. 

The authors declare no conflict of interest.

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