The Role of the Gut Microbiome Dysbiosis in Metabolic Dysfunction: A Mini Review

Various neurotransmitters, such as acetylcholine, noradrenaline, serotonin, and dopamine, are synthesized by numerous bacterial species residing in the gastrointestinal tract [22,23,42,43], contribute to the intricate communication network between the gut and the brain [44]. Gamma-aminobutyric acid (GABA) is synthesized by Bifidobacterium and Lactobacillus species; Noradrenaline is synthesized by the species Bacillus, Escherichia, and Saccharomyces; serotonin by Streptococcus, Escherichia, Candida, and Enterococcus species, while acetylcholine is synthesized by Lactobacillus, and dopamine by Bacillus [23]. These microbiota-generated neurotransmitters cross the intestinal mucosal barrier; however, their effects on brain function are thought to be mediated indirectly via interactions with the enteric nervous system (ENS) [4,45].

Bacterial metabolites interact with the gut epithelium, prompting EECs to create active amines through the intracellular decarboxylation of active amine precursors. These are subsequently deposited in secretory vesicles [46]. EECs are considered crucial sensors of gut microbiota and/or microbial metabolites, playing a vital role in maintaining mucosal immunity and gut barrier function, as well as in visceral hyperalgesia and gastrointestinal (GI) motility in health and disease [41,47,48,49].

The brain controls the functions of intestinal effector cells, including enteric neurons, interstitial cells of Cajal, immune cells, epithelial cells, smooth muscle cells, and enterochromaffin cells, through a combination of neural and hormonal signaling. On the other hand, the gut microbiota, which is involved in the gut–brain reciprocal connections, also influences these same cells. It is currently emerging that a microbiome GBA exists [35].

The gut microbiota produces a remarkably diverse array of metabolites derived from the anaerobic fermentation of dietary components and endogenous chemicals produced by both the host and microbes [50]. Many of these resulting compounds hinder the growth of their rivals, thus maintaining the diversity of commensal species and eliminating pathogenic bacteria [51]. Furthermore, these gut microbiota metabolites play roles in a variety of key physiological processes, including host energy metabolism and immunology, as well as other unknown activities, which together compose the human metabolome [52].

Colonic bacteria enzymatically break down complex carbohydrates, producing SCFAs (e.g., for most common SCFAs are propionate, butyrate, and acetate with a 1:1:3 ratio [17,18]. SCFAs, quickly absorbed by epithelial cells, regulate cellular processes (e.g., gene expression, chemotaxis, differentiation, proliferation, and cell death) [19].

The intestinal barrier has multiple layers: (1) an outer layer of mucus, commensal gut flora, and defense molecules, including secretory immunoglobulin A (sIgA) and antimicrobial proteins (AMPs), (2) an intermediate layer of intestinal epithelial cells (IECs), and (3) an inner sterile layer of innate and adaptive immune cells [55]. The inner layer protects IECs through physical separation and innate immune mechanisms [56].

The mucus layer includes (1) a loose outer layer (lumen-facing) and (2) an interior dense layer anchored to the epithelium. Commensal microorganisms inhabit the outer layer, where they form a biofilm and utilize glycans in the absence of dietary fiber [57]. Gut-microorganisms-induced SCFAs play an essential role in preserving intestinal structural integrity by maintaining tight cell junctions and limiting the activation of gut-associated immune cells [58].

Low-fiber Western diets or chronic stress thin/shrink the mucus layer, thereby increasing intestinal permeability to microorganisms [59,60]. Commensal bacteria cell wall components activate TLRs on dendritic cell extensions, inducing cytokine release and stimulating gut-associated immune system. These cytokines may weaken IEC's tight connections, allowing microorganisms to cross the intestinal barrier, via microfold cells, and enter systemic circulation, leading to metabolic endotoxemia [61].

The BBB controls the transport of substances from the circulatory system to the cerebrospinal fluid [62]. The BBB is composed of capillary endothelial cells, astrocytes, and pericytes. Tight junction proteins, which limit the paracellular transport of water-soluble compounds from the blood to the brain [63], are primarily composed of transmembrane proteins such as claudins, tricellulin, and occludin [64].

The gut microbiota, which modulates the intestinal barrier, may affect BBB permeability. The gut microbiome enhances the synthesis of tight junction proteins such as Claudin-5 and occludin, thereby reducing BBB permeability [65]. The SCFA-producing bacteria colonizing the gut also reduces the permeability of the BBB, indicating that SCFAs play a crucial role in the development and maintenance of the BBB [66]—Figure 1.

LPS, or endotoxin, is a bacterial cell wall component primarily found in Gram-negative bacteria that triggers an inflammatory response by activating TLR-4 and transforming growth factor (TGF)-mediated pathways [97,98]. Increases in systemic LPS or lipoprotein binding protein have been linked to low-grade, chronic inflammation in obesity [99], metabolic syndrome [100], and type 2 diabetes [101].

Several potential routes by which the gut microbiota may influence circulating LPS levels. These include: (1) Changes in the balance and types of intestinal bacteria can affect LPS bioavailability. For example, in diabetes, dysbiosis is characterized by a reduction in butyrate-producing, LPS-lacking, Gram-positive Clostridial species, and an increase in LPS-containing, Gram-negative opportunistic pathogens, including certain Bacteroidetes and Proteobacteria species [6,102,103]. (2) Increased intestinal permeability, often referred to as "leaky gut," can enable LPS to move through intercellular pathways. The gut microbiome plays a key role in regulating gut permeability by supporting the health of intestinal cells, maintaining their tight junctions, and preserving a protective mucous layer. This regulation is partly achieved by supplying nutrients, such as SCFAs, to the epithelial cells [104,105,106].

Probiotics, such as Streptococcus thermophilus and Lactobacillus acidophilus, have been shown to prevent TNF-α and Interferon Gamma (IFγ)-induced increase in human intestinal epithelial cells' permeability in vitro. This highlights the vital role certain bacteria play in maintaining a healthy intestinal barrier [28,29].

The gut microbiome plays a key role in bile acid metabolism. In the liver, bile acids are synthesized from cholesterol. Glycine or taurine-conjugated bile acids form bile salts, which are secreted into the small intestine. While 95% of bile salts become reabsorbed and transported back to the liver via the enterohepatic circulation, 400–600 mg reach the colon, to be converted by anaerobic bacteria to secondary bile acids, which exert widespread effects, including on the brain [26,107].

Secondary bile acids activate the ileal farnesoid X receptor (FXR) [108,109], which stimulates the production of fibroblast growth factor 19 (FGF19). FGF19 then enters the bloodstream, crosses the BBB, and activates the arcuate nucleus of the hypothalamus [110]. This hypothalamic activation enhances glucose metabolism regulation and reduces HPA axis activity. Vertical sleeve gastrectomy, a type of bariatric surgery, has been shown to rely on FXR signaling for its anti-diabetic effects [111]. Similarly, an intestinal FXR agonist has been demonstrated to improve insulin sensitivity [112]. In the pancreas, FXR activation influences insulin transport and secretion [113] and may also protect islets against lipotoxicity [114].

Ileal L cells express Takeda G protein-coupled receptor 5 (TGR5), which is activated by secondary bile acids. These secondary bile acids are exclusively produced by intestinal bacteria, and their levels are influenced by the composition of the gut microbiota [115]. Activation of TGR5 enhances glucose homeostasis by stimulating L cells to release glucagon-like peptide-1 (GLP-1). This increase in GLP-1 regulates ingestive behavior and food intake [27].

Nondigestible carbohydrates are fermented by bacteria in the colon to produce SCFAs, with butyrate, acetate, and propionate being the main products. Dietary fiber content, microbiota, and SCFAs interact because diets high in oligosaccharides change the makeup of microorganisms, produce more SCFAs, and lower the pH of the luminal fluid [24,70].

Preclinical and clinical research have demonstrated that the synthesis of SCFAs induces the ileum's L cells to release the satiety hormone GLP-1, resulting in behavioral changes and altered satiety perceptions [116]. Additionally, SCFAs influence the synthesis of 5-HT (serotonin) in ECCs [117]. By stimulating AMP kinase and free fatty acid receptors 2 and 3 (FFAR2 and 3), sometimes referred to as G-protein coupled receptors 43 and 41 [118], SCFAs behave as signaling molecules. SCFAs were shown to prevent de novo development of non-alcoholic fatty liver disease by stimulating fatty acid oxidation [25].

More attention has been paid to butyrate as a possible helpful intermediary; in people with diabetes, butyrate-producing bacteria are less prevalent [119,120]. Supplementing mice with butyrate increased their insulin sensitivity.

The release of gut hormones like GLP-1 and peptide YY (PYY), which regulate energy balance and glucose metabolism, is linked to SCFAs [91]. In response to dietary intake, proglucagon undergoes tissue-specific processing to produce GLP-1, which enhances insulin secretion from pancreatic β-cells. Both GLP-1 and PYY act in the hypothalamus to suppress food intake [121]. These hormones are also thought to contribute to the metabolic benefits observed after gastric bypass surgery, with GLP-1 playing a role in metformin's glucose-lowering effect [122,123].

PYY, like GLP-1, is synthesized by L-cells in the ileum and colon and regulates satiety by activating Agouti-related peptide (AgRP) neurons in the hypothalamus and Y2 receptors on neuropeptide Y (NPY). This suppresses appetite by disinhibiting the satiety-inducing proopiomelanocortin/alpha-melanocyte-stimulating hormone (POMC/α-MSH) pathway [124]. The gut microbiota's influence on PYY secretion is significant for understanding obesity and metabolic diseases [125]. Additionally, secondary bile acids stimulate PYY secretion via pathways like those for GLP-1 [126].

Human microbes participate in amino acid synthesis and affect serum amino acid levels [127]. Bacteria may serve as a source of branched-chain amino acids (BCAAs), as they are more abundant in bacterial cells than in eukaryotic cells. Notably, bacteria can synthesize all 20 amino acids required for protein production. Various lines of evidence suggest that gut microbiota influence the levels of amino acids absorbed by the host and the composition of the host's amino acid pool. Circulating amino acids help maintain glucose homeostasis by promoting the release of insulin and glucagon. BCAAs, in particular, appear to have a distinct role in glucose regulation, which may be linked to an increased risk of diabetes. In fact, plasma concentrations of five branched-chain and aromatic amino acids (isoleucine, leucine, valine, tyrosine, and phenylalanine) were shown to predict the development of diabetes, independent of traditional risk factors [128].

Metformin primarily acts by activating AMP-activated kinase (AMPK), which influences various cellular processes [136]. It lowers hepatic glucose production and improves insulin sensitivity [137]. Additionally, metformin exhibits strong anti-inflammatory and neuroprotective properties, potentially mediated by its effects on gut microbiota [138,139].

One of metformin's key actions is maintaining intestinal barrier integrity, thereby reducing serum LPS levels and enhancing glucose metabolism by preventing the migration of pro-inflammatory factors. The drug also promotes SCFAs production, improving insulin sensitivity by modulating substrate metabolism in peripheral tissues. This mechanism entails an increase in the population of SCFAs-producing bacteria, reinforcing Metformin's role in regulating glucose levels. Additionally, metformin regulates bile acid levels, thereby improving glucose metabolism. Studies have shown that it elevates plasma bile acid while altering gut microbiota to enhance metabolic outcomes. Its effect on gut microbiota composition, particularly by promoting beneficial bacteria such as Akkermansia muciniphila, plays a significant role in glucose homeostasis and overall metabolic health [32,140]. Metformin may influence glucose transfer from the intestinal lumen to the bloodstream and enhance glucose sensing in the gut. This highlights an additional mechanism by which metformin contributes to its glucose-lowering effects.

Metformin's modulation of gut microbiota may have implications for brain health, potentially addressing cognitive disorders [138]. Through the GBA, metformin's influence on gut microbiota opens the door to microbiome-targeted therapies that could offer cognitive benefits. These findings underline the importance of exploring metformin's broader effects beyond its traditional role in metabolic regulation. Figure 3 shows the role of Metformin in modulating the gut microbiome to improve human brain health.

Metformin has been associated with considerably reduced risk of dementia and neurodegenerative disorders, as well as enhancements in three cognitive domains: memory, semantic memory, and executive function [141,142]. Such neuroprotective benefits may occur via improving neuronal AMPK-induced energy homeostasis.

Metformin treatment also effectively counteracted amyloid-beta-induced effects on human neural stem cells (hNSCs) by suppressing caspase activity and reducing cytosolic cytochrome c levels. Furthermore, co-treatment with metformin played a key role in restoring mitochondrial structure in affected stem cells, bringing it closer to normal morphology [30]. AMPK activation induced by metformin protected the stem cells against cytotoxicity caused by advanced glycation end products [143].

Metformin reduced Alzheimer's disease-associated alterations in differentiated mouse neuroblastoma cell lines, such as Neuro-2a [144]. It also inhibited tau phosphorylation in cultured neurons and in mouse brains. Metformin was additionally shown to prevent apoptotic cell death in primary cortical neurons [145] and restore the type 2 diabetes-induced decrease in cell proliferation and neuroblast differentiation in the dentate gyrus of the rat hippocampus [146].

Metformin also reduced the incidence rate of dementia in humans compared to those treated with sulfonylureas and thiazolidinediones. Combination therapy with metformin and thiazolidinedione lowered the risk of all-cause dementia. Combination therapy with metformin and sulfonylureas protected against all types of dementia over 2 years [147]. It has been suggested that accurate assessment of mitochondrial pathways as biomarkers would help in disease-stage-specific-metformin-targeted therapy, since mitochondrial dysfunction and related pathway disruptions contribute to the pathogenesis of neurological degenerative diseases [10].