Edible Microalgae and Their Bioactive Compounds in the Prevention and Treatment of Metabolic Alterations

Dietary fiber is believed to prevent IR through maintaining balanced gut microbiota (prebiotic effect) and its direct action on epithelial and immune cells that regulate the intestinal barrier and immune function [35]. Spirulina (A. platensis) biomass has been shown to promote the growth of putatively beneficial microorganisms (e.g., Lactobacillus casei, L. acidophilus, Saccharomyces thermophilus, and Bifidobacterium spp.) and to reduce the populations of putatively harmful bacteria in vitro [36,37,38]. In healthy male mice, spirulina (1.5–3.0 g of spray-dried A. platensis powder/kg body weight daily for 24 days) was found to modify the cecal populations of microbiota at the genus level (Clostridium XIVa, Desulfovibrio, Eubacterium, Barnesiella, Bacteroides, and Flavonifractor). These changes correlated with markers of oxidative stress and with blood lipid levels [39,40]. A polysaccharide isolated from spirulina was effective at lowering blood glucose and increasing superoxide dismutase (SOD) in STZ-induced diabetic Sprague-Dawley rats (100–200 mg/kg body weight by intragastric administration for 8 weeks) [41]. Whether the effects of spirulina are partially mediated by its fiber components (e.g., oligo and polysaccharides) remains to be clarified.

Hydrolysates from seaweeds and microalgae contain bioactive peptides with putative applications in the food industry [42,43,44]. Peptides from spirulina biomass may make a decisive contribution to its antidiabetic effects. Proteins in A. platensis mainly consist of two phycobiliproteins (PBP): C-phycocyanin (C-PC) and allophycocyanin (APC) [45]. Tripsin hydrolysates of PBP yield fragments with dipeptidyl peptidase-IV (DPP-IV) inhibitory activity [46]. DPP-IV is a serine exopeptidase that is considered a promising target for the management of T2DM, because it plays a key role in glucose metabolism via N-terminal truncation and subsequent inactivation of the incretins glucagon-like peptide 1 (GLP-1) and gastrointestinal insulinotropic peptide (GIP), which are responsible for most postprandial insulin secretion [47]. The peptide Leu-Arg-Ser-Glu-Leu-Ala-Ala-Trp-Ser-Arg obtained from A. platensis by ultrasound treatment and subcritical water extraction exhibited inhibition of DPP-IV (IC₅₀ 167.3 μg/mL). This peptide also showed further activity that would contribute to the protective effects of A. platensis against hyperglycemia: inhibition of α-amylase (IC₅₀ 313.6 μg/mL) and α-glucosidase (IC₅₀ 134.2 μg/mL) [48]. These two activities are important because they delay the digestion of starch and, consequently, lower post-prandial glycaemia [49]. While the potency of this decapeptide against these three enzymes is modest, the combined effect of these and other activities (e.g., the prebiotic effects of dietary fiber) may result in an efficient overall effect for the whole biomass. Enzymatic hydrolysates of spirulina biomass also contain angiotensin I-converting enzyme (ACE-I) inhibitors [50]. ACE-I is a dipeptidyl carboxypeptidase that catalyzes the conversion of angiotensin I to angiotensin II, a process that increases blood pressure. ACE-I inhibitors reduce the concentration of angiotensin II and consequently lower blood pressure [51]. This antihypertensive effect of peptidic fractions (200 mg/kg body weight) in spontaneously hypertensive rats has been attributed to the active peptides in A. platensis: Ile-Ala-Glu (IC₅₀ 34.7 µM), Phe-Ala-Leu, Ala-Glu-Leu, Ile-Ala-Pro-Gly (11.4 µM), and Val-Ala-Phe (35.8 µM) [52]. Furthermore, the decapeptide Gly-Ile-Val-Ala-Gly-Asp-Val-Thr-Pro-Ile from A. platensis has been found to exert direct endothelium-dependent vasodilation ex vivo via a PI3K (phosphoinositide-3-kinase)/AKT (serine/threonine kinase Akt) pathway, resulting in NO release [53].

The ethanolic (95% ethanol) fraction of A. platensis biomass contains a mixture of unsaturated fatty acids that have a hypolipidemic effect in Wistar rats fed an HF diet [54]. This effect is mediated via upregulation of the AMPK-α pathway and downregulation of the SREBP-1c and the 3-hydroxy-3-methyl glutaryl coenzyme A reductase, acetyl CoA (HMG-CoA) pathways in the liver. The extract was found to increase the populations of putatively beneficial bacteria, such as Prevotella, Alloprevotella, Porphyromonadaceae, Barnesiella, and Paraprevotella, while reducing the populations of Turicibacter, Romboutsia, Phascolarctobacterium, Olsenella, and Clostridium XVIII, which correlated positively with serum TAG, total cholesterol (TC), and low-density lipoprotein cholesterol levels, but negatively with serum high-density-lipoprotein TC levels [54]. The ethanolic (55% ethanol) fraction (SP55) extracted from A. platensis showed antihyperglycemic activity in male rats fed an HF diet, as assessed by the oral glucose tolerance test (OGTT) [55]. The extract contained both saturated and unsaturated fatty acids. Other active components, such as polyphenols and peptides, may also have been extracted under the conditions used. The SP55 fraction appears to increase the gut populations of Oscillibacter, Parasutterella, and Alloprevotella and to decrease the abundance of Turicibacter [55].

Phlorotannins (phloroglucinol-based polyphenols) and bromophenols (brominated phenolic derivatives) are both families of polyphenols that are abundant in algae [43]. Algal polyphenols have shown small-to-medium positive effects on fasting blood glucose, TC, and low-density lipoprotein (LDL) cholesterol levels in humans [43]. Little is known about the possible role of polyphenolic components in Arthrospyra in its antidiabetic effect. A polyphenol-rich butanol extract was found to have quite potent α-glucosidase inhibitory activity (IC₅₀ 23 μg/mL) [56]. Inhibitors of intestinal α-glucosidases are instrumental in the management of diabetes, because they lower postprandial blood glucose levels. The total phenolic and flavonoid contents were estimated to be 121 mg gallic acid equivalents/100 g and 27 mg rutin equivalents/100 g A. platensis biomass, respectively, but no more information was provided on the structure of the putative phenolics [56]. Another ethanolic extract of spirulina biomass obtained after hydrolysis showed α-amylase inhibitory activity [57]. Although the possible structures of the active polyphenols were not revealed, the authors showed evidence that chlorogenic acid is a major component in the extract.

Phycobilins are secondary pigments in microalgae that capture light energy while protecting microalgae from harmful radiation [58]. Phycocyanin, a blue pigment biosynthesized by Arthrospyra, was found to protect insulin-producing pancreatic islets from alloxan injury in mice at doses of 100 and 200 mg/kg body weight [59]. It also reduced fasting blood glucose and glycosylated serum protein (GSP) levels, maintained the total antioxidative capacity, reduced TC levels and TAG levels in the serum and liver, increased the level of hepatic glycogen, and maintained glucokinase (GK) expression in the liver. The authors suggested that inhibition of the p53 pathway could be one of the mechanisms responsible for the protection provided by phycocyanin, as it decreased p53 expression in the pancreas at the mRNA level [59]. Phycocyanin may also exert its antidiabetic effect via the inhibition of both α-amylase and α-glucosidase, as suggested by molecular docking and in vitro testing [60]. Moreover, phycocyanin from A. platensis reduced plasma TC and LDL cholesterol as well as oxidative stress and NADPH oxidase expression induced by an atherogenic diet in hamsters, particularly when administered together with selenium [61]. The authors suggested that phycocyanin might prevent atherosclerosis.

β-Carotene extract obtained from A. platensis biomass presented antihyperglycemic activity in STZ-induced diabetic mice when given at a dose of 100 mg/kg body weight after 10 days of treatment [62].

The ethanolic (55% ethanol) fraction (CP55) extracted from C. pyrenoidosa showed antihyperglycemic activity in male rats fed an HF diet, as assessed by the OGTT. CP55 was found to be more effective than the 55% ethanol fraction extracted from S. platensis [55]. The former extract contained both saturated and unsaturated fatty acids. Other active components, such as polyphenols and peptides, may have been extracted under the conditions used. CP55 increased the abundance of Ruminococcus, Parasutterella, and Erysipelotrichacea and decreased the abundance of Lactobacillus, Turicibacter, and Blautia [55].

Polysaccharides may be partially responsible for the antihyperlipidemic and antihyperglycemic activity of chlorella biomass via the promotion of gut eubiosis (balanced microbiota populations). Chlorella spp. contain β-glucans (polymers of β-D-glucose linked through 1–3 β-glycosidic bonds, 6–9% of dry weight) [80], which may very well contribute to the overall effects of Chlorella products. Microbial exopolysaccharides (e.g., curdlan, dextran, gellan, glucans, hyaluronic acid, levan, and pullulan) can reduce inflammatory responses by promoting gut microbiota balance, strengthening intestinal barrier function, enhancing antioxidant activities, promoting short-chain fatty acid (SCFA) production, and reducing the concentrations of pro-inflammatory mediators [81]. β-Glucans promote the growth of probiotic Lactobacillus and Bifidobacterium as well as the SCFAs propionic and butyric acid, which has been related to protection against IR and other risk factors [82]. Phosphoric acid hydrolysates of chlorella and spirulina generate oligosaccharides with potential prebiotic activity, as they promote the growth of Bifidobacterium animalis and Lactobacillus casei in vitro [83,84]. Arabinomannans (oligomers of arabinose and mannose) are components of the cell wall of C. vulgaris that may show potential as prebiotics [85]. A polysaccharide from C. pyrenoidosa increased the populations of Coprococcus, Lactobacillus, and Turicibacter, whereas it reduced those of the Ruminococcus gauvreauii group in HF-fed Wistar rats at doses of 150 and 300 mg/kg body weight. The monomer constituents are mannose, rhamnose, glucose, fucose, xylose, and arabinose in the molar ratio 14.95:13.75:11.42:10.35:4.95:3.63. This polysaccharide also contains glucuronic acid (5.5%) and has a hypolipidemic effect [86].

Some peptides released from the microalgae by hydrolytic treatments are free radical scavengers with antioxidant properties. These peptides include Val-Glu-Cys-Tyr-Gly-Pro-Asn-Arg-Pro-Gln-Phe (chlorella-11) from C. vulgaris [87] and Leu-Asn-Gly-Asp-Val-Trp from C. ellpsiodea [88]. Chlorella-11 may be partially responsible for this anti-inflammatory activity as it has been found to reduce serum TNF-α levels and prostaglandin E2 (PGE2) production after lipopolysaccharide (LPS) activation in rats [89]. As IR is associated with low-grade inflammation, the anti-inflammatory activity of peptides and other components in Chlorella products may contribute to their antidiabetic effects. Meanwhile, the antihypertensive effects of peptidic fractions from C. vulgaris (200 mg/kg body weight) in spontaneously hypertensive rats has been attributed to oligopeptides such as the ACE inhibitors Ile-Val-Val-Glu (IC₅₀ 315.3 µM), Ala-Phe-Leu (63.8 µM), Phe-Ala-Leu (26.3 µM), Ala-Glu-Leu (57.1 µM), and Val-Val-Pro-Pro-Ala (79.5 µM) [52].

It has been suggested that phenolics in Chlorella preparations are partly responsible for their antidiabetic effects. It has been shown that C. vulgaris contains 5 mg rutin equivalents/g. The extracted phenolic fraction was shown to have α-amylase inhibitory activity (63.1% at 20 mg/L) [90]. A hydrophilic fraction obtained from fermented C. vulgaris biomass presented free radical scavenging activity (1,1-diphenyl-2-picrylhydrazyl free radical (DPPH) assay), antibacterial activity (against Escherichia coli, Lactobacillus plantarum, Staphylococcus aureus, and Staphylococcus epidermidis), and antifungal activity (against Aspergillus niger, Candida albicans, and Saccharomyces cerevisiae). The extract was shown to putatively contain polyphenols, as it was reactive in the Folin–Ciocalteu assay [91].

Chlorella products contain vitamins B1, B2, B6, B12, niacin, folate (B9), biotin, pantothenic acid, C, D2, E, and K [16]. Of these, vitamins D2 and B12 are not found in plants.

Chlorella (C. vulgaris) contains high concentrations of folate (approximately 1.69–2.45 mg/100 g dry weight) [92]. Folate (vitamin B9) is a crucial nutrient involved in the synthesis of amino acids and nucleotides. There is some evidence that folate reduces the blood insulin levels in subjects with IR who are at risk of suffering from T2DM [93]. The capacity of folate to reduce the levels of T2DM-related homocysteine would explain this protection [94,95]. The main folate compounds in Chlorella products are 5-CHO-H₄ folate (60–62%) and 5-CH₃-H₄ folate (24–26%), while the minor ones are 10-CHO-folate (5–7%), H₄ folate (4%), and fully oxidized folate (3–6%) [92].

C. stigmatophora is particularly rich in the antioxidant vitamin E (669 mg/kg dry weight), whose antioxidant potential may contribute to protection against T2DM [96].

The high contents of minerals such as selenium in Chlorella in collaboration with its anti-inflammatory and antioxidative capacity may reduce fasting blood glucose and improve glycemia in view of the association between serum selenium and diabetes [97].

C. zofingiensis is a source of astaxanthin, a xanthophyll carotenoid with health-promoting properties including, among others, the amelioration of chronic inflammatory diseases, MS, diabetes, diabetic nephropathy, and CVD [98,99]. In clinical studies, oral administration of astaxanthin (8 mg/day for 8 weeks) to patients with T2DM significantly reduced plasma glucose concentrations [100]. It is believed that the antidiabetic effect of astaxanthin is mainly mediated by its antioxidant activity, as reactive oxygen species (ROS) are key factors in the inducement of pancreatic β-cell damage by hyperglycemia [101]. The radical scavenging capacity of astaxanthin is common among unsaturated lipids and comes from its conjugated double bonds.

Compared with other carotenoids, astaxanthin is particularly well incorporated into the lipid bilayer of cellular membranes, where it prevents lipid oxidation without altering the lipid bilayer [102]. Astaxanthin has also been found to regulate intracellular oxidative stress by activating the MAPK, PI3K/Akt, and nuclear factor erythroid 2-related factor 2 (Nrf2)/antioxidant response element (ARE) signaling pathways in STZ-induced diabetic rats [103]. Astaxanthin also modulates the inflammatory response by inhibiting the release of pro-inflammatory cytokines such as interleukin-1B (IL-1B), interleukin-6 (IL-6), intercellular adhesion molecule-1 (ICAM-1), TNF-α, and monocyte chemoattractant protein-1 (MCP-1) [104]. Furthermore, astaxanthin appears to protect pancreatic β-cells from deterioration and death in both types of diabetes through a combination of interrelated antioxidant and anti-inflammatory effects [101]. The major source of astaxanthin is Haematococcus pluvialis (4–5% of cell dry weight) [105]. C. zofingiensis is an alternative source of carotenoids including astaxanthin (0.1–1% of cell dry weight) [99].

Tetraselmis contains flagellated species that form motile colonies found around the globe in both marine and water ecosystems [10]. An initial assessment report by Agencia Española de Seguridad Alimentaria y Nutrición (AESAN) for marketing dried Tetraselmis chuii was acknowledged by the EC in 2014 (https://ec.europa.eu/food/sites/food/files/safety/docs/novel-food_authorisation_2014_auth-letter_tetraselmis_chuii_en.pdf↗, accessed on 1 September 2020). This is an important step towards diversifying the list of approved microalgae for human nutrition. Tetraselmis species are sources of PUFAs, vitamin E, carotenoids, chlorophyll, tocopherols, and polyphenols [106] and can be used as probiotics in aquaculture [107]. T. suecica contains 74 g PUFAs, 70 g α-tocopherol, 3 g β-carotenoid, and 4 g polyphenols per kg biomass [106]. The possible application of Tetraselmis species in the prevention of diabetes has not been documented in the scientific literature; however, a patent application describes the activity of T. suecica in the prevention of obesity and diabetes via promoting the absorption of glucose into cells [108].

Isochrysis galbana is a marine-based microalga pertaining to the family Isochrysidaceae within the phylum Haptophyta, which typically uses oil droplets for energy storage [10]. Isochrysis galbana is composed of 27% protein, 34% carbohydrates, and 11% fat [109]. It is a rich source of chlorophyll, carotenoids (fucoxanthin, β-carotene, diadinoxantin and diatoxantin), and chrysolaminarin (a polysaccharide made from glucose moieties linked by type β-1,3 and type β-1,6 glycosidic bonds) [109]. A total of 1.35% of the fat is alpha-linolenic acid and 37.1% is oleic acid (18:1 n-9), which is more than that present in soybean oil [109]. According to other reports, the oleic acid content is lower (15%) and the DHA content is 9–13% of the total fatty acid content [110,111]. Other studies have reported higher concentrations of EPA than DHA [11]. The proportions of EPA and DHA in Isochrysis preparations may vary considerably between species or strains, depending on the growing conditions [112]. The general consensus in the literature is that Isochrysis spp. and strains contain particularly large amounts of ω-3 PUFAs. One gram of I. galbana biomass may contain as much as 40 mg EPA + DHA [111].

I. galbana, as with Tetraselmis suecica and C. stigmatophora, is particularly rich in lipid-soluble (A and E) and B-group vitamins (including vitamins B1, B2 (riboflavin), B6 (pyridoxal), and B12) [96]. I. galbana also contains mono and digalactosyldiacylglycerols with highly unsaturated acyl chains that exhibit anti-inflammatory activity in vitro [113]. The differences in fatty acid composition between reports may be due to differences in the preparation of the I. galbana biomass analyzed, which is not always detailed in the literature. Apart from chrysolaminaran-like polymers [114], I. galbana contains other complex unspecified polysaccharides. The total phenolic content of I. galbana T-ISO was found to be 3 mg gallic acid equivalents per gram microalgae biomass [111].

A concentrated preparation of I. galbana biomass (50 mg/day) had an effect on alloxan monohydrate-treated male Sprague-Dawley rats. It decreased glucose, TAG, and TC levels and increased lactic acid bacteria (LAB) populations, resulting in minor signs of intestinal inflammation [115]. The effects on body mass were attributed to polysaccharides, which affect satiety and, consequently, energy intake and body composition. Cell wall polysaccharides are also believed to be involved in the blood glucose lowering effect. Again, the overall trend of lower TC and TAG and TC levels in the I. galbana diabetic group may be due to reductions in intestinal absorption caused by the polysaccharides acting as dietary fiber and lowering energy intake [116]. A histology exam showed that I. galbana had no negative effects on the gastrointestinal tract, in contrast to the alterations triggered by other microalgal species. The effects on microbiota were attributed to the constituent polysaccharides, as laminaran increased cecal weight, cecal SCFAs (acetic acid and propionic acid), and the ratio of bifidobacteria to total viable cells [117]. I. galbana has shown no adverse effects in rats [115,118].

Nanochloropsis spp. are mostly marine microalgae pertaining to the phylum Ochrophyta. Like Isochrysis, they have the capacity to store energy in the form of lipid droplets [10]. Nannochloropsis spp are also rich sources of high-quality protein (30%), carbohydrates (10%), and fat (22%) [119]. The level of fat in Nannochloropsis biomass may be as high as 39% [57]. Nannochloropsis contains EPA as the major PUFA [120,121].

N. gaditana was shown to reduce blood insulin and HbA1c and attenuate oxidative stress and inflammation in STZ-induced diabetic male Wistar rats (10% in feed) [122]. In the same animal model of T1DM, N. oculata reduced blood glucose and concentrations of glucose, TC, TAG, and LDL cholesterol while increasing the concentrations of insulin and HDL cholesterol [123]. These results are in contrast with a previous study cited above that examined the effects of I. galbana and N. oculata on alloxan-induced diabetic male Sprague-Dawley rats [115]. In that study, N. oculata did not modify the altered concentrations of blood glucose, TC, or TAG [115]. The differences between I. galbana and N. oculata in that model may be related to differences in the polysaccharide content of the biomasses, as the effects of the former have been attributed to the prebiotic function of its cell wall components [115]. The hypoglycemic effect of Nannochloropsis in the STZ model might be related to its insulin increasing action. N. oculata was not found to have any adverse effects in rats [115]. A lipid extract from Nannochloropsis biomass was found to reduce plasma and liver cholesterol in rats fed a high-cholesterol diet [124].

Protein hydrolysates of N. oculata contain ACE inhibitory peptides (Leu-Glu-Gln and Gly-Met-Asn-Asn-Leu-Thr-Pro) with antihypertensive activity. The chemical composition of the crude hydrolysate is 31.0% protein, 1.3% lipids, 17.8% carbohydrates, and 4.4% fiber [125].

N. gaditana also contains a large amount of folate (2080 μg/100 g dry biomass), comparable to that of Chlorella and much higher than that of Arthrospyra [92]. As commented on before, folate offers protection against T2DM [93].

Nannochloropsis spp. contain phenolic acids (chlorogenic, caffeic, gallic, protocatechuic, hydroxybenzoic, syringic, vanillic, and ferulic acids) with free radical scavenging capacity, antifungal activity, and other in vitro activities [57,126]. These phenolics may contribute to the putative protective effects of the whole biomass against diabetes risk factors.

Polysaccharides of the -glucan type have been quantified (4.2% dry weight) in N. salina [80]. Thus, Nannochloropsis may be a good source of saccharides with prebiotic potential against IR.

Other emerging microalgae species may prove to be introduced as foodstuffs with functional properties. Euglena gracilis is also a rich source of protein, vitamins, lipids and paramylon, which is a β-1,3-glucan with immunostimulant activity that is only found in euglenoids [127]. A powdered preparation of Euglena gracilis was shown to reduce hyperglycemia and decrease food intake, body weight gain, and abdominal fat in Otsuka Long–Evans Tokushima fatty (OLETF) rats, which are another model of T2DM. Paramylon did not show any effect in this model [128].