Neurotransmitter and Intestinal Interactions: Focus on the Microbiota-Gut-Brain Axis in Irritable Bowel Syndrome

5-hydroxytryptophan (5-HT) is a type of indoleamine [3-(b-aminoethyl) -5-hydroxyindole]. It serves as not only a systematic neurotransmitter and a hormone in the body, but also a paracrine messenger in the gastrointestinal system (72). 5-HT in the body is synthesized from the essential amino acid tryptophan (Trp) in both the brain and gut, and the majority of it (approximately 95% of total 5-HT) resides in the digestive tract and is mostly produced and stored in enterochromaffin cells (ECs) (13, 73). ECs are the most characteristic endocrine cells in the intestine,—the largest endocrine organ in the human body, —and can transform tryptophan to 5-HT via Trp hydroxylase 1 (TPH1). Peripheral 5-HT plays an essential role in regulating intestinal sensation, movement, secretion of intestinal glands, and upholding intestinal balance, it does not cross the blood-brain barrier and affects the CNS in healthy conditions. In the human intestine, ECs act as sensors for the gut content. Under certain stimulations, including acetylcholine, increased intracavitary pressure, and low pH (74–76), 5-HT is released from ECs and activates the intrinsic sensory neurons in the intestinal wall to cause secretory reflex and peristalsis in the intestine, while exogenous neurons can also be activated by 5-HT to cause pain, discomfort, nausea, and vomiting (75, 77, 78)

In the gut, 5-HT is responsible for one of the core signaling pathways, especially in modulating intestinal permeability and regulating mucosal inflammation. In particular, intestinal peristalsis and the secretory reflex are regulated by 5-HT released from endothelial cells. They are stimulated by 5-HT₁ and 5-HT₄ receptors on submucosal primary afferent neurons, while 5-HT₃ receptors on primary afferent neurons may also play a part in intestinal reflex activity (13). When the intestinal tract is stimulated, 5-HT increases and binds to 5-HT₃ receptors in the exogenous primary afferent nerve endings, making the enteric nervous system (ENS) and visceral afferent nerve highly sensitive, thus resulting in discomfort, abdominal pain, and diarrhea (16). 5-HT is related to colon inflammation in a DSS-induced murine colitis model, and treatment by inhibiting 5-HT production in colonic mucosa has a therapeutic outcome in ameliorating colitis-associated symptoms and inflammation (79). In addition, it has also been reported that in IBS-D patients, the 5-HT and 5-HT₃ receptors in the intestinal mucosa are significantly higher than those in healthy controls, indicating an impaired 5-HT system in IBS patients (80).

5-HT production in the gut is believed to be regulated by the gut microbiota, although the mechanism by which the gut microbiota acts in modulating intestinal 5-HT synthesis has not yet been fully illustrated. Efforts have been made to understand how the gut microbial community affects Trp metabolism and 5-TH. Alterations in gut microbial composition can lead to changes in the plasma level of Trp along with its metabolites (79). Transplantation of feces from IBS-C patients to healthy mice would cause gut microbiota imbalance by reducing Firmicutes and increasing Bacteroides and Akkermansia. Additionally, the mice showed a reduction in 5-HT in the intestinal tissue, and therefore suffered from constipation and damaged intestinal barrier function (81). Germ-free mice exhibit colon defects in producing 5-HT as well as decreased serum 5-HT levels, and current evidence suggests that SCFAs produced by the gut microbiota may play a role in regulating TPH1 expression (82). Moreover, secondary bile acids oriented from cholate via microbial transformation can influence the synthesis of 5-HT (21). In addition, 5-HT is capable of increasing the abundance of spore-forming bacteria in the gut microbiota (83).

By focusing on 5-HT and the gut microbiota, traditional Chinese medicine has made a breakthrough in treating IBS. Tongxie prescription can effectively rebuild the gut microbiota and gut microecology, reduce colonic 5-HT, and thus relieve the symptoms of IBS-D (84). The oral administration of resveratrol, an effective antioxidant, had a strong therapeutic effect on IBS rats through the 5-HT1A receptor-dependent PKA-CREB-BDNF pathway, and changed the concentration and metabolic rate of 5-HT, as well as the expression of its receptor 5-H1A (23). In a work that reports the beneficial effects of ondansetron, a 5-HT₃ receptor antagonists, on IBS-D patients who showed significant abnormalities in mucosal serotonin metabolism, the therapeutic effect of ondansetron was most obvious in patients with the lowest 5-HT concentration in rectal biopsy tissues (22), and the possible mechanism may be that 5-HT₃ receptor antagonists slow down the intestinal transport. In addition, a meta-analysis reported that 5-HT₃ receptor antagonists are effective in improving symptoms in IBS-D (85, 86). Other studies have proven that blocking the 5-HT₆ receptor can reduce the number of defecations, and the use of 5-HT6 receptor antagonists can relieve symptoms of IBS-D or other forms of diarrhea (17).

Dopamine is a major catecholamine neurotransmitter that regulates reward-motivated behavior, and it is synthesized by both the central and peripheral nervous systems. It is also a precursor of other catecholamines such as NE and epinephrine. Dopamine is pivotal in multiple physiological processes, including attention, motivation, reward, emotion, memory, and appetite (87, 88). Most dopamine originates from tyrosine, phenylalanine hydroxylase can convert L-phenylalanine into tyrosine and it can also indirectly produce dopamine (87, 89). Although dopamine along with its terminal products can be detected in the cerebrospinal fluid and blood, it is difficult to trace its source origin due to its complexity, it can be produced not only by the CNS but also by peripheral organs such as the kidneys and intestines (87).

Interestingly,mutual modulation exists between microorganisms and catecholamines. In the presence of dopamine and NE, pathogenic Escherichia coli O157:H7 (EHEC) displayed higher viability, increased motility, and stronger virulence. Other pathogenic bacteria such as Klebsiella pneumoniae and Staphylococcus aureus were also found to be sensitive to NE, which is possibly caused alterations in iron acquisition. In addition, some strains of gut microorganisms are reported to be capable of producing dopamine or NE, including Proteus vulgaris, Serratia marcescens, Bacillus subtilis, and Bacillus mycoides (90). Meanwhile, dopaminergic circuits have also been proven to be sensitive to gut microbiota alterations. Some studies report that germ-free (GF) and specific pathogen-free (SPF) mice showed anxiety behavior under different stresses, with no significant change in dopamine levels in the hippocampus (45, 91). Diaz Heijtz et al. reported that the ratio of dihyroxy-phenyl acetic acid and dopamine (DOPAC/DA ratio) in the striatum was significantly higher in GF mice. Nishino and his group, found that fecal microbiota transplantation from SPF mice to GF mice could relieve anxiety symptoms in GF mice. Strikingly, the most significant change found in monoamine in GF mice after fecal transplant is the alteration in dopamine and its metabolites.

A study on GF mice also reported that some probiotics have positive influences on anxiety behavior, Lactobacillus Plantarum PS128 showed an anti-anxiety effect, while dopamine and homovanillic acid (one of the catecholamine metabolites) were higher in the striatum, but there were no significant changes in the prefrontal cortex, hippocampus, and striatum (36). Recently, dopamine has been considered to be related to intestinal homeostasis. Dopamine receptors which are distributed in the intestinal wall (D1, D3, and D5 receptors) are present not only in the intestinal mucosa but also in the nerve endings of the intestinal wall. Dopamine D2 receptors are the main mediators of the endogenous effect of dopamine (71, 92), they are found only in nerve endings in the intestinal wall, while the D₄ receptor exists only in the mucosal layer (24).

Dysregulation of the dopaminergic system is associated with anxiety (27), depression (29, 30)and intestinal microbe imbalance (93). Alterations in the dopaminergic system are found in patients with IBS, compared with the healthy cohort, the IBS cohort has lower serum and urinal levels of dopamine (22, 94). However, another clinical study reported that dopamine levels were significantly increased in IBS-C patients, while IBS-D patients did not show any difference (95). These opposite results are unable to reflect the real-world situation of how dopamine and dopamine-related metabolism is changed in IBS patients, but evidence validated that dopamine could contribute to IBS. Some researchers have made efforts to develop dopamine-based therapy for IBS, and they have gained progress on this issue. In restless legs syndrome (RLS) cases associated with IBS, the administration of levodopa and dopamine agonists induced improvement in both IBS and RLS symptoms (96). It has also been reported that metformin, a widely used drug for treating type 2 diabetes, can activate central D₂ dopamine receptors, thus reducing visceral hypersensitivity and increasing intestinal permeability in IBS patients (25),. Similarly, butyrate enema can improve visceral pain and colon permeability in an IBS animal model. Losartan can prevent visceral pain and colonic hyperpermeability in IBS rats, which may be dependent on the PPAR- γ, AMPK, and central dopamine D₂ pathways, or mediated by opioids and nitric oxide (26). Imipramine may also inhibit visceral hypersensitivity and colonic permeability in an IBS animal model through the α-2-adrenoceptor, dopamine D_2, and opioid pathways, and improve the intestinal barrier (37).

Gamma-aminobutyric acid (GABA) is an amino acid derivative of glutamate, which is a major mediator of inhibitory transmission in the mammalian nervous system. A large amount of literature supports the association between changes in GABA neurotransmission and many psychological diseases, including behavioral disorders, insomnia, and pain (40). GABA also plays an important role in homeostasis and disruption of the ENS, such as acid secretion, gastric empties, intestinal motility, and pain perception (39, 90). The sources of GABA in the intestine include neurons containing GABA synthase, and mucosal endocrine-like cells, indicating that GABA is not only a neurotransmitter but also an endocrine agent in the gastrointestinal tract (97). In IBS patients, the GABAergic system is disrupted, and the levels of glutamate decarboxylase 2 (GAD2), GABA, and GABA receptors(including type B1 and B2) are decreased, while GABA transporter-2 (GAT-2) is increased in IBS-D patients (98).

For years, evidence has shown that bacteria are responsible for GABA production as well as consumption. The E. coli strain was found to be capable of taking GABA as the only source of carbon and nitrogen decades ago, while a broad spectrum of bacteria was been identified as GABA producers (90), including Bifidobacterium and Lactobacillus. The gut microbiota has a direct influence on GABA metabolism in the body. Fecal transplantation from schizophrenia patients to GF mice resulted in elevated levels of glutamine and GABA in the hippocampus, and led to schizophrenia-related behaviors, which are similar to other glutamatergic hypofunction murine models (99). Meanwhile, compared to SPF mice, GABA levels in the lumen and serum of GF mice are remarkably reduced, while the cerebral level is intact (100). It is well known that dietary intervention can change the composition and function of the gut microbiota (101), and a ketogenic diet has been shown to increase the level of GABA in the cerebrospinal fluid of children with refractory epilepsy (102). In a recent fecal transplant study, it was found that GABA was the most variable metabolite in obese patients receiving allosteric fecal transplants from lean donors (103). Unfortunately, how GABA is produced by gut microorganisms and how it is involved in the disease are still underunderstood.

GABA receptors in the mammalian CNS enable GABA to act as a depressant and influence behavior. GABA-A receptors are the major receptor of inhibitory neurotransmission in the CNS, and are involved in most brain physiological functions (104). Enteric nerve cells exert excitatory effects by increasing intracellular chloride concentrations through sodium-potassium-chloride transporters, thus activating GABA receptors in the ENS, rather than inhibiting neurons in the CNS. The understanding of the GABAergic system in the peripheral nervous system is relatively limited, especially in the ENS. Studies have proven that both ionic (GABA-A and GABA-C) and metabolic (GABA-B) receptors of GABA exist in both nerve cells and nonnerve cells in the GI system (105, 106). The mRNA level of the GABA-A receptor was expressed in intermuscular and submucosal neurons and intestinal epithelial cells (105). Seifi et al. demonstrated immunolocalization of GABA subunits (α1-5 and γ2) on mouse colon ENS cells (107). Other studies have also shown that a nonspecific GABA-A receptor ligand affects intestinal contraction (108, 109).

The fact that the GABA-B receptor changed in IBS patients and the evidence that mice exposed to stress had higher levels of GABA-A receptor α3 in their colons indicated that stress may be the reason for the change in GABA in IBS (110). Therefore, GABA analogs and agonists may be effective in the treatment of IBS. It has been reported that pregabalin may improve IBS symptoms because it binds to calcium channels in ileum neurons (43). In recent years, the US FDA has approved pregabalin for the treatment of fibromyalgia and neuropathic pain because of its analgesic and anxiety-relieving effects. And Clinical studies have proven that pregabalin has a positive effect on IBS symptoms, especially IBS-M and IBS-D. Although pregabalin can improve abdominal distention, abdominal pain, and diarrhea, it does not affect IBS symptoms such as depression and anxiety (111). In addition, gabapentin and baclofen are effective and helpful for relieving visceral hypersensitivity. The pharmacological effects of gabapentin on IBS were limited due to hepatotoxicity and neurotoxicity, but it still improved pain and anxiety-like behavior in mice (112), moreover, baclofen did not show significant efficacy in reducing the visceral motor response (113). CGP7930 is another GABA-BR agonist, and due to its mechanism of action, it reduces visceral pain without the same number of side effects as baclofen and promotes endogenous GABA release (39). Although the GABA receptor is considered to be a potential target in therapies for IBS, it also shows significant side effects. Notably, the influence of GABA on host cells could be enhanced by the microbiota. Oral supplementation with Bifidobacterium brevis NCIMB8807pESHgadB, a strain that produces GABA through overexpression of glutamate decarboxylase B, reduced visceral sensitivity in a rat model (44).

Histamine is produced from the amino acid L-histidine by catalyzed oxidation decarboxylation of histidine decarboxylase, which exists in many mammalian cells (87). Most of them are expressed in mast cells and basophils, but can also be detected in lymph nodes, thymus, and gastrointestinal chromaffin cells (45). Histamine is an important regulator in various immune responses, such as allergies and inflammation, and it can also modulate the motility of the gastrointestinal tract, increase the permeability of the intestinal mucosa, and affect mucosal ion secretion. Based on this, histamine is speculated to be involved in IBS pathogenesis. Several clinics and animal studies have found that the histamine level in the colon was increased in IBS cases (114).

The metabolism of histamine mainly depends on histamine-N-methyltransferase (HNMT) and diamine oxidase (DAO) (115, 116). According to its location, histamine in vivo is deaminated or methylated by DAO and HNMT enzymes, respectively (117). DAO is an extracellular secretion enzyme that oxidizes and deaminates histamine to produce imidazole acetaldehyde. Animal studies have shown that DAO forms the main hurdles for histamine absorption (118). HNMT is a cytoplasmic enzyme that forms N4-methylhistamine by methylation of inactivated histamine imidazole rings, requiring receptor-mediated endocytosis or specific transporters to transport histamine into cells (119). Furthermore, histamine is synthesized by neurons in the posterior hypothalamus, which extends from axons to the entire brain and acts as a neurotransmitter (120). Apart from host cells, histamine can also be produced by some strains of microorganisms, such as E. coli and Morganell morganii. Interestingly, certain bacteria are capable of regulating the synthesis of histamine by producing histidine decarboxylase (HDC), an enzyme that transforms histidine to histamine (114).

It was recently proposed that histamine receptor agonists for treating allergies, can also reduce visceral hypersensitivity, immune activation, and symptoms in IBS patients (121). Urinary histamine levels in IBS patients are related to the disease severity of IBS, especially abdominalgia (94). Some studies have shown that histamine-tolerant patients can reduce the α diversity of gut microbiota, change the abundance of Proteus and Bifidobacteria, and elevate the fecal zonulin level (122). Preclinical and clinical results suggest that pain in some patients with IBS may be caused by fungus-induced mast cell-derived histamine release, which in turn activates sensitization of sensory-afferent expressed histamine-1 receptors and associated nociceptive transient reporting potential channel V1(TRPV1) (123).

Histamine can activate its 7-transmembrane G-protein coupled receptors, including H1, H2, H3, and H4 (45), which are expressed on both presynaptic and postsynaptic nerve membranes (124). Presynaptic histamine receptors, as autologous or heterologous receptors, regulate neurotransmitter release from the axon terminal to synaptic cleft via different responses (125). Histamine receptors are distributed in various places of the nervous system, and their specificity of localization depends on their physiological correlation (126). Studies have shown that H1 and H4 are the main histamine receptors involved in the gastrointestinal process, and H2 is associated with the production of gastric acid (46).

IBS patients who respond well to H1 antagonists differ from others, hinting that the histaminergic system of IBS patients may be overstimulated (127). Recent evidence has shown that histamine increases the sensitivity of mouse dorsal root ganglion and human rectal submucosal neurons to TRPV₁ by activating the H₁ receptor (HRH₁). In addition, the supernatant of IBS biopsy tissue also enhanced the sensitization of mouse dorsal root ganglion neurons through HRH₁. Based on these findings, 51 IBS patients were given ebastin, a nonsedative HRH1 antagonist,and after treatment, ebastin reduced IBS symptoms and abdominalgia in patients (49). Since the expression was increased in the colonic mucosa of colitis-infected, H1 and H4 receptors may have an important effect on the pathogenesis of colitis and visceral hypersensitivity. In a model of postinflammatory colitis, an H₄ antagonist can improved abdominal pain (128). New interventions to block H₁ receptors are being proposed because ebastin improved IBS clinical signs such as abdominalgia and visceral allergy (49), while ketotifen can upregulate the pain threshold and improve the quality of life of IBS patients (50).

The abovementioned neurotransmitters involved in IBS via the microbiota-gut-brain axis were intriguing, and other neurotransmitters have also attracted attention for understanding the etiology and pathogenesis of IBS. Many researchers have proven that NE and glutamate are responsible for the occurrence of IBS. For example, one study pointed out that NE levels in IBS patients changed after taking the α-2 receptor antagonist yohimbine and agonist clonidine. IBS patients have increased anxiety and altered yohimbine and NE levels in plasma, whereas plasma NE levels are positively related to increased brain arousal in these cases (129). Targeting corticotropin-releasing factor receptor type 1 (CRF-R₁) was also an option for treating active IBS patients. The NE pathway of the locus ceruleus complex is changed in patients with IBS, and CRF-R₁ may reduce the responsiveness to stress (130).

At the same time, tryptophan metabolism is also related to depression in patients with IBS (131). The immune-sensitive enzyme indoleamine 2,3-dioxygenase (IDO), which is responsible for the degradation of tryptophan was increased in IBS, however, the level of neuroprotective kynurenic acid (KynA) and the ratio of KynA/Kyn were reduced (132). Riluzole is a glutamate uptake activator that modifies visceral hypersensitivity in adult stressed animals, but it does not influence adolescent animals (133). The results from clinical and animal experiments suggest that N-methyl-D-aspartate (NMDA) receptors play an important role due to their blockade, which reduces the negative effects of stress and anxiety (134, 135). These findings suggested that regulation of the Kyn/tryptophan pathway may affect the receptors of NMDA in the CNS, might be involved in the progression of depression and may be a therapeutic target against the psychotic syndrome of the IBS patients (136, 137). Another study has also shown that microinjection of different doses of glutamate into the hypothalamic paraventricular nucleus (PVN) can not only reduce visceral sensitivity but also reduce the frequency of vagus nerve discharge (138). In addition, it has been reported that compared to the control sample, mGluR7 gene and protein expression levels in the colonic mucosa of rats with visceral hypersensitivity were upregulated. However, the administration of AMN082 (an mGluR7 agonist) can reduce visceral hypersensitivity, which indicates that targeting mGluR7 may be useful for relieving IBS (139).