Exploring the Gut Microbiome in Myasthenia Gravis

The NMJ of skeletal muscles has nerves innervating from the terminal arborization of α-motor neurons of the ventral horns of the spinal cord and brainstem. The synaptic cleft of the NMJ has AChE and supplementary proteins and proteoglycans, whereas on the postsynaptic membrane, AChR is tightly packed above the deep folds. When a nerve action potential (AP) reaches the synaptic bouton, depolarization occurs, opening voltage-gated calcium channels on the presynaptic membrane. Acetylcholine (ACh) is released into the synaptic cleft and diffuses to reach the postsynaptic membrane, triggering end-plate potential (EPP). Later, AChE present in the synaptic cleft will hydrolyze ACh [3].

In an average individual, the EPP generated in the NMJ is much greater compared to the threshold required to a create postsynaptic potential. However, in MG patients, the “safety factor” is reduced. The decrease in AChR molecules causes EPP to decrease, and when EPP falls below the threshold needed to trigger an AP, especially after repetitive activity, symptoms of muscle weakness occur [3,25].

There are four factors contributing to the pathogenesis of MG: First is the effector mechanism of pathogenic anti-AChR antibodies (Abs), which involves complement binding and activation at the NMJ, the antigenic modulation, and the functional AChR block [26]. The second is the role of CD4+ T cells in MG. The synthesis of pathogenic anti-AChR Abs needs activated CD4+ T cells to interact with and stimulate B cells. The third is the role of CD4+ T cell subtypes and cytokines in MG and experimental autoimmune myasthenia gravis (EAMG). Th1 and Th2 are the two subtypes of CD4+ T cells with very different immune response roles. Th1 cells secrete pro-inflammatory cytokines, whereas Th2 cells secrete anti-inflammatory cytokines [3,27]. High levels of anti-AChR Th1 cells are present in the blood of MG patients. They recognize AChR epitopes and induce B cells to produce anti-AChR Abs [3,28,29]. On the other hand, Th2 cells may be protective, but their cytokines contribute to EAMG [26]. Low levels of functioning Treg cells are present in MG patients. Tregs are CD4+ T cells expressing the CD25 marker and Foxp3 transcription factor and are crucial in maintaining self-tolerance. When combined with natural killer T (NKT) cells, it regulates the anti-AChR response. In mouse models, EAMG development is inhibited upon the stimulation of NKT cells [30]. Besides that, antigen-presenting cells (APC) secrete interleukin (IL) 18, which stimulates natural killer (NK) cells to make interferon-gamma (IFN-γ), which enhances Th1 cells, inducing EAMG. Lastly, other autoantigens, anti-MuSK Abs, are present in MG patients lacking anti-AChR Abs. These anti-MuSK Abs affect the maintenance of agrin-dependent AChR clusters at the NMJ, resulting in AChR reduction [3].

The cause and induction of autoimmune diseases have been linked to microorganisms that carry out an unwanted immunological reaction against the self-antigen. This can be seen in an infection causing local inflammation, which increases molecules related to antigen recognition [8,9].

Patients stated that besides stress and surgery, infections also trigger MG events. In Australia, 33.33% of patients reported that infections exacerbated MG, and 50% said the severity was affected by seasonal changes [31]. The effect of disease on MG can be seen in studies from different countries, such as in a population-based study in Spain; almost one-third of MG events were due to infections giving rise to dysphagia and respiratory impairment in MG. In India, it gave rise to MG exacerbations; in a Chinese cohort, it prompted MG relapse [32,33]. Some case studies have shown the connection between certain infections and the simultaneous occurrence of antibodies against NMJ debuting MG-human immunodeficiency virus (HIV), herpes simplex, and hepatitis B and C [31,34,35,36,37]. Although it has been proposed that bystander activation, cryptic antigens, molecular mimicry, epitope spreading, and polyclonal activation are mechanisms inducing MG by viral agents, their effect on the concentrations of specific autoantibodies against AChR, MuSK, and LRP4 during infection is unknown [1,38]. Besides that, the particular microorganism causing MG exacerbations during infection is also unknown, which is likely a broad activation of the immune system [1].

During infections, the genetic predisposition of autoimmune disorders and thymoma are factors aiding the development of MG [38]. Even though genetic predisposition has been verified and linked to human leukocyte antigen (HLA) genes, less than 50% of the total disease risk is due to genetic factors, as specific HLA associations differ for MG subgroups [39,40].

On the other hand, thymoma has AChR Abs associated with MG with a thymus pathology and is responsible for 10% of MG cases, whereas the additional 90% of MG causes are unknown [1,5,41,42]. Although the risk for some diseases is affected by the gut microbiome, there is no data available for the risk of MG and the composition and load of gut bacteria [43]. However, animal models reported that the immune response against microbes could affect the autoreactive immune response via different mechanisms [44]. Nevertheless, infection is a factor that indirectly induces an autoimmune disease and can induce a polyclonal activation of immunoactive cells, but they are yet to be proven for MG etiology [1].

The disease manifests with varying skeletal muscle weakness, is aggravated when exerted, and improves with rest [10,45]. Although it has overlapping diverse clinical symptoms as with other neurological disorders, the fluctuating feature of MG allows it to be differentiated [46,47]. MG can be categorized into ocular myasthenia gravis (oMG) and generalized myasthenia gravis (gMG) [26]. The oMG symptoms are limited to extrinsic ocular muscles (EOMs), affecting 10% of MG patients. In contrast, in gMG, the most common initial symptom often involves the EOMs, which then spreads involving the bulbar muscle, limb, axial musculature, and respiratory muscles [6,26]. Weakness of the EOMs present as diplopia, blurry vision, and ptosis (unilateral or bilateral). It occurs in 85% of MG patients, in which 50% of them progress to gMG in two years [46]. Around 60% of MG patients presenting bulbar muscle weakness showed fatigable chewing; however, 15% of MG patients showed dysarthria and painless dysphagia as an initial presentation [48,49].

Generally, arms are more affected than the legs in MG patients, and the involvement of facial muscles and the neck extensor and flexor leads to an expressionless face and “dropped head syndrome” [10,50]. Weakness in the respiratory muscles tends to occur only after two years of onset, leading to a life-threatening myasthenic crisis [50].

The gut microbiome could be responsible for triggering diseases in genetically vulnerable individuals [95,96]. MG is an autoimmune disease associated with the dysregulation in the composition and diversity of gut microbiome [97]. Dysregulation of the gut microbiome may be involved in the onset of both central and peripheral autoimmune disorders [98,99]. This is consistent with the recent confirmation demonstrating the relationship of intestinal aberrancies and different autoimmune diseases, for example, Type 1 diabetes [100], IBD [101,102], multiple sclerosis [103,104], and rheumatoid arthritis [103,105], among others. Nonetheless, the pattern of microbial dysbiosis varies for different autoimmune disorders. Thus, microbiota alterations in MG subjects cannot be extrapolated based on other autoimmune diseases. As the microbial diversity and microbial composition of the gut microbiota affects the development of MG, this has resulted in studies using 16S ribosomal RNA (rRNA) gene sequencing and fecal metabolomics being conducted to determine whether the above statement is true and, if so, how it is associated [97].

The gut microbiota is involved in MG development [16]. Alterations to the microbiota affect human physiological functions via the immune system regulation [106]. This is seen in MG disease, where alterations in the gut microbiota affect Foxp3+ CD4+ Treg cells, contributing to MG pathogenesis. MG’s pathogenesis is linked with high levels of circulating AChr Abs. Based on several studies, their production has been linked to Th1, B cells, and Foxp3+ T regulatory (Treg) cells disequilibrium [45,107,108]. The frequency of Foxp3+ CD4+ Treg cells is significantly reduced in MG patients. This has led to more studies focusing on the pathogenesis of MG [109,110,111]. Foxp3+ CD4+ Treg cells are regulatory cells particularly common in the colonic lamina propria [112]. Both Foxp3+ CD4+ Treg cells and the T-cell receptor (TCR) repertoire of Foxp3+ CD4+ Treg cells can be affected by the gut microbiota [113,114,115]. The TCR repertoire plays a role in increasing the Foxp3+ CD4+ Treg cells by recognizing subsets of commensal bacteria, inducing the differentiation of naive CD4+ T cells into antigen-specific Foxp3+ CD4+ Treg cells, resulting in increased Foxp3+ CD4+ Treg cells [114,115]. Foxp3+ CD4+ Treg cells on the other hand, reduce disease severity and progression by affecting the level of autoreactive T cells and suppressing the activity of autoreactive B cells, hence regulating AChR Abs production. Therefore, their function in maintaining self-tolerance and immune homeostasis makes them crucial in preventing MG development [116]. Currently, the interpretation of the pathogenesis of MG is targeted at the inadequate frequency of Foxp3+ CD4+ Treg cells. It is hypothesized that this deficiency in the intestinal bacteria-induced Foxp3+ CD4+ Treg is related to changes in the composition of the gut microbial community [106]. Further details regarding the correlation between probiotics, Foxp3+ CD4+ Treg cells, and MG disease is discussed later in this paper.

The microbial composition in both healthy controls (HCs) and MG subjects can be obtained using 16S rRNA gene sequencing. In contrast, the functional readout of microbial activity can be obtained from fecal metabolomics [117,118]. We can identify the link between gut microbes and their functional metabolites [118]. In terms of the composition of gut microbes of HCs and MG subjects, Zheng et al. [97] was able to show that a notable difference at the Operational Taxonomic Unit (OTU) level was present based on the 3D principal co-ordinates analysis. Furthermore, control analyses showed that MG subjects’ microbial composition was not notably grouped according to disease subtype, medication/treatment history, or AChR Ab status. Age and gender were not factors involved in clustering HCs and MG subjects. Thus, this suggests that these confounding factors do not significantly affect the global microbial phenotype.

The linear discriminant analysis effect size was also conducted to identify phylotypes behind the differences between HCs and MG subjects. Results were presented that some microbes were abundant in HCs, while some were abundant in MG subjects [106,119]. The human gut consists of a high diversity of bacterial taxa, mainly belonging to Firmicutes and Bacteroidetes [120]. Based on the analysis conducted by Zheng et al. [97], 80 differential OTUs were recognized and held accountable for distinguishing MG subjects from HCs. These 80 OTUs mainly belonged to the phyla Firmicutes (59/80), Bacteroidetes (14/80), and Actinobacteria (3/80). In comparison with the HCs, out of the 80 OTUs recognized by Zheng et al. [97], 34 OTUs belonging to the bacterial taxonomic families (Bacteroidaceae, Lachnospiraceae, Prevotellaceae, and Veillonellaceae) increased in abundance, while the remaining 46 OTUs belonging to bacterial families (Lachnospiraceae, Ruminococcaceae, Erysipelotrichaceae, Clostridiaceae, and Peptostreptococcaceae) decreased in abundance in MG subjects. The results from different studies show that the microbes’ level varied according to different bacterial genera and families.

Furthermore, Moris et al. [119] and Zheng et al. [97] agreed that at the phyla level, Firmicutes are the dominant fecal microbes of both HCs and MG subjects and that the level of Actinobacteria is lower in proportion relative to HCs. Notably, the level of Bacteroidetes, on the other hand, was found to be in a higher proportion in MG subjects, and this result was consistent across three studies [97,106,119]. For instance, Moris et al. [119] reported that there were higher counts (p < 0.05) of total bacteria and of the Desulfovibrio- and Bacteroides-groups based on a quantitative polymerase chain reaction (qPCR) analysis [119]. There are also findings stating that Firmicutes and Bacteroidetes are the main bacterial phyla responsible for microbiota alteration. The Firmicutes/Bacteroidetes (F/B) ratio was lower in MG subjects than HCs. The F/B ratio describes a pro-inflammatory environment. These inflammatory microbiotas damage the intestinal epithelium and prompt the immune response, resulting in an immunological imbalance. Thus, this is consistent with the drop in the F/B ratio in other autoimmune diseases, such as Crohn’s disease and IBD [106,121,122], demonstrating a correlation between the Firmicutes and Bacteroidetes level and some autoimmune disorders.

The linear discriminant analysis effect size conducted by Qiu et al. [106] was able to pinpoint 11 discriminative characteristics (genus level, linear discriminant analyses (LDA) score >2) with an altered relative abundance. In HCs, the bacteria of genera Clostridium, Eubacterium, Faecalibacterium, Lactobacillus, etc. were higher in abundance. Conversely, in MG subjects, the bacteria of genera Streptococcus, Parasutterella, Escherichia, etc. were more elevated in abundance. In other words, MG subjects had a significant drop in Clostridium and Lactobacillus levels, with Clostridium (under the phyla Firmicutes) being the most depleted, with an absolute amount up to three-times less than in HCs. Similarly, Zheng et al. [97] also reported that the level of Clostridium (under the phyla Firmicutes) was found to be much greater in the HCs (p < 0.001). MG subjects had a reduced abundance of bacteria belonging to Lachnospiraceae and Ruminococcaceae families from Clostridiales, which are vital for maintaining a healthy gut based on the OTU analysis [97,123,124].

Furthermore, Moris et al. [119] found large inter-individual variability for the Bifidobacterium population using ITS profiling, which could be the cause for the lack of statistically significant (p < 0.05) differences among the HCs. However, there were some obvious differences, as HCs had high populations of Bifidobacterium longum subsp. Longum, followed by Bifidobacterium adolescentis, whereas MG subjects had high relative proportions of Bifidobacterium animalis subsp. lactis, Bifidobacterium breve, and Bifidobacterium dentium [119]. This demonstrates variations in the microbiota profiles and the levels of specific species of bacterium found in both HCs and MG subjects, not just based on a genus level. These Bifidobacterium spp. are classified as actinobacteria at the phylum level and are well-known probiotics living in the stomach and intestine. This shows that dysbiosis of specific species of the bacterium does relate to MG (Table 1). In conclusion, the microbial composition of MG subjects was significantly different from HCs, and it had been correlated to a reduced α diversity in MG subjects. This proposes an unusual microbial status, suggesting an association of gut microbiota dysbiosis with MG [97].

The diet manipulates and shapes the gut microbiota composition and function [64]. Besides supplements, probiotics are readily available through functional foods and drinks. Probiotics are defined as ‘living microorganisms, which, when administered in adequate amounts, confer health benefits on the host’ by the Food and Agricultural Organization of the United Nations and the World Health Organization [156]. Nobel laureate Elie Metchnikoff introduced the concept of probiotics, and now, probiotics are widely marketed as functional foods or dietary supplements [64,157].

A huge variety of food and drink products contains probiotic strains [158]. Dairy products, including cheese, yogurts, and fermented milk, constitute important probiotic sources in humans, with yoghurt having the highest sales [159,160,161]. Non-dairy products, including cereals, soy-based products, nutrition bars, and juices, can be a way for consumers to obtain probiotics [162,163]. However, it is important to consider the product’s compatibility with the microorganism; safety; efficacy; and the maintenance of its viability via product processing, packaging, and storage conditions. One of the factors affecting the growth and survival of the probiotic is pH, which is the reason soft cheeses are better delivery systems than yoghurt for delivering probiotics to the GIT [164,165,166].

Probiotics influence the composition and function of gut microbial communities via the production of growth substrates or inhibitors, competition of nutrients, and modulation of intestinal immunity [167]. Probiotics also affect the patterns of gene expression. In a recent study, duodenal specimens collected before and after a 6-week intervention period from healthy volunteers taking probiotics showed changes in transcriptional networks involving mucosal biology and immunity [168]. The mechanisms of probiotics include suppression of pathogens, manipulation of intestinal microbial communities, immunomodulation, stimulation of epithelial cell proliferation and differentiation, and fortification of the intestinal barrier [169].

Probiotics use different mechanisms in suppressing bacterial pathogen’s proliferation and virulence. They can produce metabolic compounds or microbial agents that halt other microorganisms’ growth or compete for binding sites and receptors with other intestinal microbes on the intestinal mucosa [170,171,172]. They can also produce a wide range of antimicrobial factors, for instance, bacteriocins and non-peptide compounds, which offer therapeutic alternatives in targeting multidrug-resistant pathogens. For example, in lactobacilli, lactic acid and reuterin are the recognized antimicrobial effectors, with certain strains of Lactobacillus reuteri (L. reuteri) secreting bacteriocins, affecting both innate and adaptive immunity [64,173,174].

Probiotics can manipulate the intestinal microbial community by inducing the production of β-defensin and Immunoglobulin A (IgA) [169]. In a study where infants were treated with daily supplements of Lactobacillus casei subsp. Rhamnosus (LGG), there was a rise in the evenness index in the fecal microbiota, which indicates ecological stability [175]. This increase in ecological stability has been linked to the diversity in microbial communities [176]. Thus, this proves that probiotics do manipulate the intestinal microbial communities and stabilize it.

Probiotics could regulate intestinal immunity and change the responsiveness of the intestinal epithelia and immune cells to microbes in the intestinal lumen [169,177]. The role of probiotics in intestinal immunomodulation involves the upregulation of anti-inflammatory factors and the downregulation of pro-inflammatory factors. In contrast, fortification of the intestinal barrier involves inducing mucin production and maintaining tight junctions [169]. Thus, enhancing intestinal barrier integrity leads to greater immune tolerance and less translocation of pathogens across the intestinal mucosa [178]. Probiotics can also use substrates from the diet to produce secreted soluble factors and metabolites, for instance, vitamins and SCFAs, via signaling pathways such as mitogen-activated protein kinase (MAPK) and nuclear factor kappa B (NFκB) [169,179]. These compounds influence the growth and function of the intestinal epithelium and mucosal immune cells, leading to cytokine and related factors and B cell activating factors production [179]. For example, in gnotobiotic pigs, heat-killed L. reuteri 100-23 induces anti-inflammatory cytokine IL-10 production, eliciting an intestinal immune response and regulating the development and recruitment of regulatory T cells to the GIT epithelium [180]. L. reuteri can produce soluble factors to inhibit pro-inflammatory cytokine production and signaling of immune cells [181]. Thus, this proves the ability of probiotics in modulating the intestinal immunity and altering the responsiveness of the intestinal epithelia and immune cells to microbes in the intestinal lumen [169,177].

Probiotics have been recommended as a therapeutic and preventive measure in restoring the gut microbiome, and their effects on specific diseases have been studied [119]. Probiotics can increase the functionality of existing microbial communities and introduce advantageous functions into the GIT [64]. Therefore, disease states are possibly related to the changes in core microbial functions [62]. However, more research using controlled human studies is needed to establish the safety and limitations of probiotics, the strain of probiotics, and the dosage required for the greatest efficacy for a particular group of patients. Besides that, the regulatory status of probiotics as food components needs international verification, particularly regarding the safety, efficacy, and validation of a food label’s health claims [158].

The combined use of prebiotics and probiotics may have a synergistic effect [182]. This combination can improve the survival and implantation of live microbial dietary supplements in the gastrointestinal flora of the host, improve the microbial balance of the GIT, and modify the composition of colonic microflora by selectively stimulating the growth or activating the catabolism of a limited number or one of the health-promoting bacteria in the intestinal tract, leading to the predominance of some of the potentially health-promoting bacteria, particularly, bifidobacteria and lactobacilli [182,183].

A prebiotic is “a nondigestible food ingredient that beneficially affects the host by selectively stimulating the growth and/or activity of one or a limited number of bacteria in the colon” [183]. They can modify the function and composition of the gut microbiota [184]. Gut microbes ferment these prebiotics, and they get their survival energy from degrading indigestible binds of prebiotics [183,185]. Thus, they selectively influence the gut microbiota [186,187]. The two important groups of prebiotics that have advantageous effects on human health are the galacto-oligosaccharides and fructo-oligosaccharides [188]. Currently, inulin-type fructans involving native inulin, synthetic fructooligosaccharides (FOS), and enzymatically hydrolyzed oligofructose or inulin are the only prebiotics with data adequate for possible classification as functional food ingredients [189]. Inulin is defined as a polydisperse carbohydrate material containing largely β-(2-1) fructosyl-fructose links [190]. Both inulin and oligofructose can be found in large amounts in various vegetables and fruits, including leeks, wheat, banana, onion, and garlic [191].

The prebiotic inulin-type fructans have an effect on the GIT, possibly providing a synergistic effect to the use of probiotics. They can avoid digestion in the upper GIT due to the β-configuration of the anomeric C-2 in their fructose monomers, with further evidence that they are not significantly absorbed. Therefore, this allows for the greater survival of bacteria passing through the upper GIT, boosting their effects in the large bowel, and they have been referred to as a colonic food, which is a food acting as a substrate for endogenous bacteria after entering the colon, thus directly supplying the host with metabolic substrates and energy. Many in vivo and in vitro (both microbiological and analytical) studies have supported the proposal that inulin-type fructans are fermented by bacteria colonizing the large bowel and confirming that the end products of fermentation produce SCFAs, including propionic acid, butyric acid, and lactic acid, which have few effects on the body [183,192,193]. For example, SCFAs decrease the colonic pH, leading to alterations in the population and composition of the gut microbiota, affecting acid-sensitive species (Bacteroids) while promoting Firmicutes to produce butyrate (i.e., the butyrogenic effect), whereas propionate influences dendritic cells in the bone marrow and influences T helper 2 cells in the macrophages and airways [192,193,194,195,196,197]. Besides that, peptidoglycan produced from fermentation could stimulate the innate immune system against pathogenic microorganisms [192,198]. On top of that, based on human in vivo studies, this fermentation results in the selective stimulation of growth of the bifidobacteria population. Thus, this makes inulin-type fructans the prototypes of prebiotics [183]. Even though many studies have been conducted on prebiotics’ positive effects on human health, genomic investigations and accurately designed long-term clinical trials need to be carried out to confirm the health claims [188].

The fecal microbiota transplant (FMT) is a translational experimental model that is beneficial in determining if gut microbiome dysbiosis is linked with the development of different diseases [97]. The transplantation of the MG microbiota can affect the outcome of MG. This could be seen in an animal experiment conducted by Zheng et al. using mice under matching immune conditions. The FMT was carried out by colonizing germ-free (GF) mice with an MG microbiome (MMb) or healthy microbiota (HMb) or both MMb and HMb (CMb) and then using classic modeling methods to immunize them [97,199,200]. One month after FMT, an open field test (OFT) was conducted to determine if MMb affects MG-related locomotion. Regardless of the sexes of the mice, the total distance traveled by both MMb and CMb mice dropped more than HMb mice, proving that the colonization of GF mice with MMb, although under identical immune conditions as the HMb colonized mice, resulted in impaired locomotion. Besides that, the level of TNF-α, IFN-γ, and IL-10 in both serum and intestinal tissue were much greater in the MMb group than the HMb group [97]. This is consistent with previous animal and clinical studies showing increased serum TNF-α and IFN-γ [201,202]. As the level of the three cytokines mentioned above in the CMb group were comparable to those in the HMb group, thus, by co-administering HMb into MMb mice, the effect of the increased inflammatory cytokines could be reversed (Table 2) [97]. This is consistent with another finding stating that the interference of the cytokines has demonstrated the ability to alleviate MG severity [203].

Not applicable.