Molecular Mechanisms Linking Omega-3 Fatty Acids and the Gut–Brain Axis

The multifaceted roles of n-3 fatty acids within biological systems include complex interactions with the GBA. They are integral components of phospholipids in the nerve cell membranes, which enhance their structure and are crucial for their optimal fluidity [32]. This fluidity influences neuronal information transfer by affecting neurotransmitter binding and the speed and integrity of cell signaling [33,34,35]. DHA represents approximately 15% of all fatty acids in the gray matter of the prefrontal cortex, while EPA and n-3 docosapentaenoic acid (DPA) account for only ~1% of brain fatty acids [36,37,38]. However, the hydroxy derivative of DHA (2-hydroxydocosahexaenoic acid, OHDHA) has demonstrated therapeutic potential in treating Alzheimer’s disease in a mouse model. Administration of this DHA derivative increased brain DHA levels and reduced Aβ (amyloid-β) levels as well as Aβ-induced tau phosphorylation—key factors in the progression of the disease. These effects supported neuronal cell membranes, preserving proper synaptic function, which is essential for signaling and membrane stability in the CNS [39]. The mechanism through which neuronal fluidity changes is based on the displacement of cholesterol from the membrane as well as the induction of non-lamellar structure formation in the membrane [40,41,42]. Different lipid concentrations in the cell membrane can alter its fluidity as well as the structure and functioning of embedded proteins, such as enzymes, receptors, and ion channels. It is believed that the incorporation of fatty acids into cell membranes also affects the inflammatory cellular responses [43,44,45]. EPA and DHA compete with dihomogammalinolenic acid and AA for incorporation into the phospholipid membrane, sharing enzymes involved in the eicosanoid production process [46,47]. Metabolic transformations of DHA and EPA carried out by cyclooxygenases (COX), lipoxygenases (LOX), and cytochrome P450 enzymes result in the production of numerous eicosanoids and docosanoids [48,49]. These metabolites influence the brain-derived neurotrophic factor (BDNF), increasing synaptic plasticity and enhancing neurotransmission, thus providing neuroprotective effects, as demonstrated in studies conducted on the multipotent human hippocampal progenitor cell line HPC0A07/03C and the human bone marrow neuroblastoma SH-SY5Y cell line (multipotent human hippocampal progenitor cell line) [48,49,50]. Both animal and human studies indicate that the incorporation of EPA and DHA into cell phospholipids during inflammatory processes is dose-dependent and occurs at the expense of AA content [47,51,52,53,54,55,56]. The role of n-3 fatty acids as components of CNS cellular membranes is summarized in Figure 2.

The modulation of inflammation by n-3 fatty acids, mainly through their effects on eicosanoid production, illustrates a critical mechanism by which dietary fats influence both neurological health and systemic inflammatory responses [57,58]. Prostaglandins, thromboxanes, leukotrienes, and hydroxyl and hydroxy fatty acids are enzymatic metabolic products of PUFA, known as eicosanoids. These compounds play a pivotal role in the inflammatory processes and neurological pathways within the GBA [59,60]. The structural differences in eicosanoids derived from EPA and AA affect the biological activity of EPA derivatives, as eicosanoid receptors have a lower affinity for the mediators derived from EPA than ARA [61]. An in vitro study on HEK293 cell lines demonstrated 50–80% lower activity of prostaglandin E3 (PGE3) compared to prostaglandin E2 (PGE2) on prostaglandin E2 receptors 1, 2, 3, and 4 (EP1, EP2, EP3, and EP4), indicating nuanced influence of dietary fats on neuroinflammatory responses [62]. Eicosanoids derived from EPA and DHA have anti-inflammatory properties [47,55,58,63]. EPA competes with AA for the cyclooxygenase enzyme system, effectively inhibiting the production of proinflammatory eicosanoids from AA. Both DHA and EPA reduce the release of proinflammatory cytokines, such as interleukin-1β (IL-1β), -2 (IL-2), and -6 (IL-6), along with IFN-γ and TNF-α [57,63,64,65]. These cytokines can affect the CNS both indirectly and directly by reducing the availability of neurotransmitter precursors, influencing their metabolism, transport, and regulation, as well as impacting the HPA axis and mRNA-encoding proteins involved in neurotransmitter metabolism [66,67,68,69]. Flaxseed oil inhibits the synthesis of proinflammatory cytokines, thereby regulating neurotransmitter production and the HPA axis [70]. Marine-derived n-3 fatty acids lead to the production of pro-resolving lipid mediators, such as EPA-derived resolvins (E series), DHA-derived resolvins (D series), and resolvins derived from DPA n-3 (RvDn-3 DPA), along with protectins (also known as neuroprotectins when produced in the nervous tissue) and maresins derived from DHA. Their synthesis occurs through COX and LOX pathways, acting intercellularly [57,71,72,73,74]. The anti-inflammatory actions of n-3 fatty acids involve binding to peroxisome proliferator-activated receptors (PPARs), G-protein–coupled receptor 40 (GPR40), and free fatty acid receptor 4 (FFA4), also known as GPR120, which promote the production of anti-inflammatory lipids—resolvins and protectins. These lipids play a crucial role in inhibiting the activation of key inflammatory regulators, including transcription factor nuclear factor kappa B (NF-kB), IL-1 β, and TNF-α release [75,76,77,78,79]. Supplementation with EPA and DHA in mice has been shown to increase the number of T lymphocytes [80]. Additionally, DHA and EPA are able to inhibit IL-6 and interleukin 8 (IL-8) production stimulated by lipopolysaccharide (LPS) in human endothelial cells. Moreover, EPA has been observed to inhibit TNF-α production by cultured monocytes [81,82]. LC-PUFAs also reduce LPS-induced proinflammatory cytokine production in human blood monocytes and in murine fetal liver-derived macrophages, leading to a decrease in TNF-α level in serum, NF-kB activation, and IL-1 β production by monocytes [82,83,84]. This reduction can trigger the release of substantial amounts of anti-inflammatory factors, such as interleukin-10 (IL-10), from resident macrophages. LC-PUFAs play a critical role in directly modulating cytokine production and immune cell regulation. They also exert broader anti-inflammatory effects through key intracellular signaling pathways, such as NFκB, that influence overall immune response and inflammatory status mainly due to the increased level of inflammatory cytokines, adhesion molecules, and cyclooxygenase-2 (COX-2) [82,85,86]. NFκB is activated by the signaling cascade triggered by external inflammatory stimuli, including endotoxin binding to toll-like receptor (TLR) 4. Upon activation, the NFκB dimer is translocated to the nucleus, where it upregulates gene expression [87,88,89,90].

The documented anti-inflammatory and regulatory capabilities of EPA and DHA on cytokine dynamics and cellular mediator pathways also help preserve the integrity of cellular barriers, such as the BBB, by reducing inflammation-induced disruption and enhancing barrier functions. Transmembrane proteins, including claudin-5 and occludin, along with scaffold proteins, like ZO-1 and ZO-2, participate in the tight junction complex of endothelial cells in the CNS [91,92]. LC-PUFAs indirectly enhance the integrity of the BBB and reduce its permeability by modulating levels of inflammatory cytokines [93,94]. Systemic administration of IL-1β has been demonstrated to cause prolonged BBB disruption, activate matrix metalloproteinase-9, and induce rearrangement of claudin-5 in cerebral vessels following transient middle cerebral artery occlusion in mice [95]. Therefore, it is suggested that n-3 fatty acids may strengthen the integrity of the BBB by downregulating the expression of proinflammatory cytokines. Interestingly, research indicates that certain anti-inflammatory cytokines, including IL-4, IL-10, and IL-13, can also contribute to damaging the BBB, but the precise mechanisms behind these effects are not yet well understood [96]. However, the disruption kinetics of the barrier via IL-4 seems to be similar to that of n-6 PUFAs, such as di-homo-gamma-linolenic acid (DGLA, C20:3 n-6) and AA. In comparison n-3 PUFAs, including EPA and DHA, support epithelial barrier integrity by enhancing trans-epithelial electrical resistance (TER) and significantly reducing IL-4-induced permeability. This suggests that LC-PUFAs play a crucial role in maintaining barrier function, as demonstrated by Willemsen Le et al. [97]. Tight junction complexes actively control paracellular permeability and are sensitive to soluble barrier-disrupting mediators [98,99]. Proteins such as occludin, ZO-1, and claudins play critical roles in regulating the intestinal barrier, controlled by the perijunctional actomyosin ring and myosin light chain kinase [100,101,102]. LC-PUFAs improve trans-epithelial resistance, but the exact mechanism of its impact on this process is not fully understood. Several mechanisms have been proposed to explain the effects of n-3 LC-PUFAs on BBB integrity, particularly their roles in modulating inflammatory pathways and enhancing antioxidant defense systems. Notably, n-3 PUFAs suppress IFN-γ-induced expression of TNF-α, IL-6, nitric oxide synthase (NOS), and COX-2, while promoting the upregulation of heme oxygenase-1 (HO-1) in BV-2 microglia cells. BBB disruption and “leaky gut” phenomenon increase the transfer of neurotoxins into the brain, leading to elevated production of proinflammatory molecules, reactive oxygen species, and increased bacterial adhesion through receptors, thereby disrupting endothelial connections [103]. n-3 Fatty acids, specifically EPA and DHA, have been shown to enhance basal trans-epithelial resistance (TER), thereby reducing the permeability of the gut barrier in human intestinal epithelial cells (T84) in vitro, indirectly through mechanisms involving IL-4. LCPUFAs, such as dihomo-γ-linolenic acid (DGLA), AA, EPA, and DHA, stimulate basal resistance and mitigate IL-4-induced permeability changes [97,104,105]. Supplementation with EPA in rats has been shown to increase the expression of occludin, a protein playing an important role in the intestinal barrier integrity [106,107,108]. These protective effects are associated with support and protection of the tight junction structure and function. Additionally, n-3 fatty acids have been shown to increase the number of goblet cells, promote the growth of beneficial bacteria, and elevate the expression of mucin 2, all of which contribute to improved intestinal barrier integrity [104,109]. Summarized anti-inflammatory effects of n-3 fatty acids in the gut and the brain are shown in Figure 3.

Omega-3 fatty acids, mainly DHA and EPA, are essential for maintaining neural integrity and improving cognitive functions, as they serve as integral components of neuron membrane structure and play a critical role in neurogenesis, neural signaling, and neuroprotection. DHA also promotes neuron growth by enhancing protein kinase B signaling [110]. This process requires the accumulation of lipids in newly formed membranes and DHA facilitates the incorporation of cholesterol into structures important for myelination and neurite extension, thereby assisting in the organization of the lipid raft domain of the membrane [111,112,113]. Summarized data presenting the effects of n-3 fatty acids on cognitive functions are presented in Table 1.

Neurogenesis is essential for cognitive function, as it supports brain plasticity and adaptability, fundamental for learning and memory retention. This process is most apparent during prenatal development, but it persists in certain parts of the adult brain, most notably in the hippocampus, a structure crucial for learning and memory formation [114,115]. BDNF is a protein that belongs to the neurotrophin family of growth factors, which are vital for the growth, survival, and differentiation of neuron cells. It plays a key role in neuroplasticity, and it is a critical mediator that links neurogenesis to broader brain functions, particularly those related to learning, memory, and overall cognitive health [116,117,118]. n-3 Fatty acids—especially DHA—increase BDNF levels, thereby influencing the growth, differentiation, and viability of neurons in the hippocampus, playing a significant role in the regulation of various neurotransmitter systems [119,120,121,122]. Direct administration of BDNF to the dorsal hippocampus in rats significantly increased the granule cell layer of the hilar region [123]. Deuterated polyunsaturated fatty acids (D-PUFAs) supplementation has been shown to alleviate cognitive decline through its antioxidant activity and reduction in lipid peroxidation in a Huntington’s disease mouse model [124]. In an animal model of spinal cord injury, DHA treatment following injury led to comprehensive functional improvements, evidenced by enhanced fore and hindlimb locomotion and better motor control in the grid exploration and staircase tests. This was accompanied by structural neural adaptations, including increased synaptophysin density around motor neurons, enhanced cortical synaptogenesis, amplified serotonergic innervation, and increased sprouting of corticospinal axons in both rostral and caudal regions of the injured area [125]. DHA also promotes hippocampal neuron development in vitro by supporting neurite growth and branching and also synaptogenesis. Moreover, in vivo DHA depletion in the fetal hippocampus resulted in inhibition of hippocampal neuron development in culture, which can be reversed with DHA supplementation [126].

n-3 Fatty acids increase synaptic plasticity in hippocampal neurons and improve its glutaminergic activity, which is crucial for cognitive function as it mediates synaptic plasticity and neurotransmission, fundamental for learning, memory formation, and overall brain cell connectivity [127,128,129]. A 6-month randomized controlled trial showed that supplementation at a dose of almost 2 g of EPA and DHA decreases depression symptoms in the Geriatric Depression Scale in geriatric patients and DHA improves cognitive function, i.e., verbal fluency tested with Initial Letter Fluency [130]. In a model of accelerated aging with prediabetic status, dietary enrichment with flaxseed and fish oils enhanced spatial learning and working memory performance in the Morris water maze test through reduction in inflammatory markers and toxic metabolites in the CNS of male rats. Elevated n-3 fatty acids levels in the frontal cortex following supplementation were associated with protective effects against cognitive impairment and reduced depressive-like behaviors linked to gray matter atrophy, suggesting a crucial role of EPA in preventing cognitive decline [131].

The cognitive enhancements provided by n-3 fatty acids primarily stem from their profound impact on cellular structures, which leads to the modulation of the physical aspects of brain health, particularly the stabilization of neuronal membranes and ion channels [132,133,134]. In a randomized, double-blind, controlled trial, healthy older adults who consumed 3.7 g per day of flaxseed oil containing 2.2 g of ALA over 12 weeks demonstrated improved verbal fluency. This improvement is believed to result from changes in neuronal cell membrane structure across broad anatomical regions, enhanced membrane fluidity, and improved intercellular connectivity, which typically decline with age [135]. LC-PUFAs influence the integrity of membrane proteins, including enzymes, receptors, and ion channels. They regulate membrane protein integrity, affecting enzymatic activity, receptor function, and ion channel conductance. Administration of DHA demonstrated neuromodulatory effects via ion channel regulation, subsequently reducing the amplitude of epileptiform discharges in experimental rodent models of seizure activity [134,136]. These changes occurred through sodium channel blockade and neuronal membrane stabilization by suppressing calcium-gated membrane tension, thereby blocking synaptic transmission [132,133,134,136,137,138]. Research indicates that n-3 LC-PUFAs play a crucial role in promoting brain health. They enhance neuroprotective capabilities, support neuroplasticity, and reduce neuroinflammation, all of which are essential for sustaining cognitive functions. Short-term exposure to EPA and DHA reversed spatial working memory deficits in older mice by reducing IL-1β expression in inflammation-associated hippocampi [139]. Similarly, a high-fat diet enriched with flaxseed oil improved spatial learning and working memory in male mice during the Morris water maze test by reducing levels of inflammatory markers and toxic metabolites in the CNS [140].

n-3 Fatty acids contribute to brain health by modulating membrane structures and reducing neuronal damage. Additionally, they directly impact cellular mechanisms that eliminate harmful proteins and facilitate cellular repair, highlighting their potential therapeutic roles in neurodegenerative diseases [141]. DHA and EPA stimulate and increase the expression of insulin-degrading enzyme (IDE) genes, which raises the levels of IDE, the main enzyme responsible for degrading amyloid-beta (Aβ) peptide secreted into the extracellular space of neuronal and microglial cells [142]. The accumulation of Aβ peptides is linked to the development of AD, and the effect of n-3 fatty acids may assist in removing these peptides from the brain and modulating inflammation, thereby supporting brain glial cells [143,144]. Additionally, DHA exhibits a protective effect on dopaminergic neurons in a Parkinson’s disease animal model induced by the neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) [142]. Moreover, another study demonstrated that DHA administration significantly increased TH-positive neurons compared to the control group when exposed to MPTP, suggesting changes in dopaminergic activity [145]. It has been suggested that the DHA may delay or slow the progression of Parkinson disease development by blocking the conversion of MPTP to MPP+ (methylpyridinium ion) or by preventing the uptake of MPP+ into dopaminergic terminals. Furthermore, DHA has been shown to influence synaptic plasticity and cognitive functions by activating syntaxin 3, a plasma membrane protein that plays a significant role in membrane expansion [146,147].

As a neuroendocrine factor, cortisol is essential in the stress response and plays a critical role in regulating GBA functions. As a primary stress hormone released by the adrenal glands in response to stress, cortisol forms part of the body’s HPA axis, which is closely connected to the GBA. Dysregulation of this system, particularly HPA axis hyperactivity, has been implicated in the pathophysiology of anxiety, depression, and other stress-related conditions [149,150]. n-3 fatty acids, particularly EPA and DHA, have been shown to regulate the HPA axis by reducing excessive cortisol production. Research has shown a reduced cortisol response to acute mental stress in healthy men who were given 7.2 g/day of fish oil for 3 weeks [151]. Preclinical and clinical data indicate that low plasma levels of n-3 fatty acids are correlated with higher CRH [149] and plasma concentration of cortisol [152,153], while n-3 fatty acid supplementation may decrease CRH expression and corticosterone secretion [154,155]. CRH, crucial in regulating the HPA axis, is produced in neurons within the hypothalamic paraventricular nucleus (PVN), which receives input from the limbic system and the brainstem. This connectivity enables these neurons to respond to both psychological and physical stressors [156]. In vitro studies confirmed that n-3 fatty acid-deficient rats had exaggerated distress behaviours in comparison with rats with the appropriate n-3 fatty acid levels during administration of CRH and were normalized upon restoration of n-3 fatty acid levels [157]. Studies conducted on male Finnish psychiatric patients (with diagnosed depression, alcoholism, or both) and healthy patients without psychiatric disorders have also shown that excessive stress response and HPA hyperactivity may be related to concentrations of brain and plasma neuroactive steroids (NASs) [158]. NASs are produced in the CNS from cholesterol and have the ability to alter neuronal excitability rapidly. In a study carried out on male psychiatric patients from Finland, the authors observed that lower plasma levels of n-3 fatty acids were linked to higher plasma levels of neurosteroids. Specifically, reduced concentrations of DHA and EPA were correlated with increased levels of NASs in healthy control subjects [158]. DHA supplementation reduced stress-related increases in aggression and hostility among Japanese students [159]. The research conducted by Oravcova et al. [160] on patients aged 11–18 confirmed the hypothesis that long-term (12 weeks) supplementation of n-3 fatty acids from fish oil emulsion reduces morning cortisol levels in saliva. These findings are in line with the current understanding of the connection between HPA axis activity and fatty acid metabolism in adults with recurrent depressive disorder [155]. Adults with lower levels of n-3 fatty acids demonstrated HPA axis dysregulation, suggesting that supplementation with these fatty acids could potentially improve both physical and mental health [161]. Notably, dietary supplementation with LC-PUFAs from marine oils has been shown to lower corticosterone levels in rats and to reduce cortisol secretion in both healthy individuals and adults experiencing depression [151,162,163]. Results from a randomized, placebo-controlled trial in midlife adults demonstrated that EPA and DHA supplementation significantly reduced cortisol levels during stress in a dose–response manner. Patients receiving the higher doses of n-3 fatty acids had the lowest overall cortisol levels, while those in the placebo group exhibited the highest levels [164]. Additionally, supplementation with n-3 fatty acids (2400 mg of total omega-3 fatty acids; 1000 mg of EPA and 750 mg of DHA; EPA:DHA ratio of 1.33:1) over a 12-week period was shown to significantly reduce clinical symptoms of depression in older children and adolescents [165]. In adolescent patients, the positive treatment effects from n-3 fatty acid supplementation were also associated with a decrease in various oxidative stress markers, such as 8-isoprostane, advanced oxidation protein products, and nitrotyrosine blood levels, as well as increased Trolox equivalent antioxidant capacity and superoxide dismutase activity [166].

Chronic stress or inflammation can result in the overactivation of the HPA axis. Previous studies have demonstrated increased levels of inflammatory markers, including IL-6 and TNF-α, in numerous chronic diseases such as cardiovascular diseases, obesity, and depression, contributing to their development and progression [167,168,169]. Additionally, HPA axis hyperactivity has been observed in obesity, and increased morning cortisol levels have been reported in individuals with depression [170,171]. Given their anti-inflammatory and immunomodulatory effects, n-3 PUFAs may help mitigate these detrimental processes and thereby potentially alleviate conditions characterized by HPA axis dysregulation [172,173]. n-3 fatty acids can lower HPA axis hyperactivity by decreasing proinflammatory cytokines levels, such as IL-6 and TNF-α, which influence the stress response. By downregulating the proinflammatory cytokine pathways and modulating the stress response, n-3 fatty acids reduce the sensitivity of the HPA axis. This means that the axis is less likely to become overactive in response to minor stressors, potentially lowering the risk of stress-related disorders. In a randomized, double blind, placebo-controlled trial conduced on healthy man, n-3 supplementation in combination with phosphatidylserine significantly improved the functioning of the HPA axis by lowering chronic and acute stress [174]. The authors concluded that individuals experiencing high levels of chronic stress and/or having a dysfunctional HPA axis response could benefit from n-3 phosphatidylserine supplementation. The impact of n-3 fatty acids on regulating the activity of the HPA axis may be related to their anti-inflammatory properties, coupled with the increase in the HPA axis sensitivity to negative feedback [175,176].

The beneficial physiological effects of LC-PUFAs encompass their influence on the composition and function of the gut microbiota, as demonstrated in various studies linking fatty acid intake to microbial diversity and health outcomes. n-3 fatty acids can influence the modulation and abundance of gut bacteria types. At the same time, gut microbiota can affect the absorption and metabolism of these fatty acids. Fish oil, for instance, reduces the growth of Enterobacteria, while increasing that of Bifidobacteria. EPA and DHA are partially metabolized by anaerobic bacteria, such as Bifidobacteria and Lactobacilli, in the distal gut [177]. In a study conducted on gnotobiotic piglets fed with PUFA from seal oil, a significant increase in the number of Lactobacillus paracasei adhering to the jejunal mucosa was shown [178]. Similarly, n-3 fatty acids administered to male transgenic fat-1 mice significantly increased the number and percentage of Bifidobacterium, Akkermansia muciniphila, Lactobacillus, Clostridium clusters IV and XIVa, and Enterococcus faecium in the intestines [179]. The modulatory functions of n-3 fatty acids are also attributed to increased levels of SCFAs. It has been shown that dietary supplementation with DHA and EPA in mice infected with Salmonella increased SCFA fecal content, enhancing resistance against the pathogen [180]. Consuming 3 g per day of DHA and EPA from sardines significantly altered the gut microbiota composition in patients with untreated type 2 diabetes. Specifically, the proportions of Bacteroides/Prevotella increased, while the Firmicutes/Bacteroidetes ratio decreased [181]. In a study of birds, a diet rich in omega-3 PUFA significantly increased the presence of Firmicutes (e.g., Faecalibacterium, Clostridium, and Ruminococcus, all of which are butyrate producers), in the gut microbiota [182]. Additionally, serum levels of omega-3 fatty acids, particularly DHA, were positively correlated with gut microbiome diversity and the abundance of specific bacterial taxa, such as Lachnospiraceae, in a cohort of 876 elderly women, suggesting a potential role for LC-PUFA intake in modulating microbiome composition [183]. A 6-week intervention study further demonstrated that omega-3 supplementation alters gut microbiome composition, increasing the abundance of butyrate-associated Coprococcus spp. and beneficial fermentation products, suggesting a potential prebiotic-like role for omega-3 fatty acids [184].

On the other hand, gut microbiota can both indirectly and directly modulate the absorption, bioavailability, and biotransformation of n-3 fatty acids [185,186,187]. Certain bacterial species, such as Bacillus proteus or Lactobacillus plantarum, convert ALA and linoleic acid (LA) into conjugated linoleic acid (CLA) and conjugated alpha-linolenic acid (CALA), which are then hydrogenated to stearic acid, changing the PUFA content in the brain and heart [188]. A study of mice demonstrated that high tissue levels of n-3 fatty acids were associated with variations in the amounts of Bifidobacterium and Lactobacillus [189]. Conversely, mice fed a diet low in n-3 fatty acids for two generations showed a significant decrease in lactic acid bacteria and an increase in Bifidobacteria in the oral cavity compared to those fed a diet adequate in n-3 fatty acids [190]. While studies suggest that Bifidobacterium can significantly modulate fatty acid metabolism and its absorption by the intestinal epithelium, specific mechanisms underlying this relationship remain unexplained [191,192,193].

n-3 Fatty acids can modulate gut microbiota by either inhibiting the production of proinflammatory mediators or promoting the production of anti-inflammatory mediators. For instance, DHA reduces its activation by lowering IkappaB kinase (IκB) phosphorylation in response to LPS in cultured macrophages and dendritic cells, thereby decreasing NFκB activation [194,195]. Similarly, EPA reduced NFκB activation induced by LPS in human monocytes due to reduced IκB phosphorylation [196]. Furthermore, peroxisome proliferator-activated receptor gamma (PPAR-γ), which functions by inhibiting NFκB translocation to the nucleus, is regulated by the binding of EPA and DHA [197]. This binding interaction significantly influences inflammatory processes [198]. Supplementation with these acids significantly influences changes in the gut microbiota by altering the content of immune cell membranes and influencing proinflammatory signaling pathways. n-3 Fatty acids increase the number of regulatory T lymphocytes (Tregs), thereby reducing inflammatory reactions [199]. n-3 Fatty acids are mainly absorbed in the intestine, where their metabolites can be directly utilized by certain microorganisms. Their protective action on the intestinal mucosa includes increasing its thickness and improving barrier functions [200]. Summarized data presenting the mechanistic effects of LC-PUFAs on gut microbiota, immune function, and intestinal barrier integrity are presented in Table 2.