The Brain-Gut-Microbiome System: Pathways and Implications for Autism Spectrum Disorder

Gut microbiota development during the first 1000 days of life (including prenatal life) is critical for establishing a healthy and protective microbiome (Figure 2) [9]. Data indicate that one’s microbiome begins to develop rapidly following birth, with influencing factors such as the delivery method, infant feeding practices, antibiotics, and the environment [10]. Early life dysbiosis may be especially impactful in early neurodevelopment with the potential to alter the integrity of the blood-brain barrier and alter brain-gut signaling, both of which can lead to adverse health outcomes later in life [11,12]. In addition, prenatal maternal factors, including psychosocial stress, infections, obesity, and metabolic syndrome, can result in maternal dysbiosis and dysregulated maternal immune activation, posing significant risks to offspring neurodevelopment [13]. Throughout early life and childhood, microbiota continue to play major roles in modulating immune system functioning, as well as the maturation of the brain and body of the host [11,14,15,16].

Similarly, in early neural development, the developing microbiome appears to be particularly sensitive during early life and its profile can be altered by external stimuli, including stress, adversity, diet, environmental microbes, and antibiotics, with both immediate and long-term negative effects on the integrity of the immune system, metabolism, and overall health [17,18,19]. Such perturbations during sensitive periods of development have also been linked to negative cognitive outcomes [20,21,22], socioemotional functioning [23,24,25,26], and internalizing and externalizing problem behaviors [21,22], all of which have serious implications for various neurodevelopmental disorders.

Previous research has shown an association between gut microbiota and various neuropsychiatric disorders, including attention deficit hyperactivity disorder (ADHD), depression, and obsessive-compulsive disorder [27], which often co-occur with ASD [28]. ASD symptomatology has also been directly associated with gut microbiota [29]. Based on these reported associations and the multitude of potential therapeutic targets, new therapeutic interventions targeting the BGM system have been proposed and evaluated [30,31]. Below, we focus on current research that informs our understanding of gut microbiota and ASD, including GI disorders, social deficits, disruptions in neurochemical mechanisms, and abnormal brain structure and function.

GI symptoms—abdominal pain, constipation, and diarrhea, in particular—have been reported in 46–84% of individuals with ASD [32], which has led to the hypothesis that gut dysbiosis may be especially relevant to ASD patients with GI distress. Studies investigating the gut microbiome of children with ASD have found abnormal gut-derived metabolite patterns as well as certain taxa that significantly differ in relative abundance from healthy controls (e.g., Clostridia, Desulfovibrio, Bifidobacteria, Bacteroides) and are strongly associated with GI symptoms [33,34,35,36,37,38,39]. To date, the exact microbial composition associated with ASD has yet to be determined, with contradictory findings existing at the phylum, genus, and species levels, as well as in alpha and beta diversity; for a review, see [34]. It is important to note that this lack of consensus may be due to several factors, including study-wide differences in collection methods, preprocessing, statistical analysis, age, sex, participant diet, specimen type, ASD heterogeneity, and presence of GI disorders, all of which demonstrate a need for more homogenous samples and standardized collection and analysis procedures [40].

It has been theorized that a long history of coevolution has closely linked social behavior and gut microbiota across the animal kingdom [41]. A bidirectional relationship has been observed in animal models in which the gut microbiome influences social behavior, while social interactions and social structures also shape the composition and function of the microbiome [41,42,43]. Much of the work tying gut microbiota to social behavior has been conducted in rodent models [44], including germ-free rodents [45,46,47] and mouse models known for their phenotypic similarities to humans with ASD (e.g., repetitive movements, low reciprocal social interactions) [48,49]. These studies have utilized both bottom-up (e.g., manipulating the presence of bacteria by colonizing germ-free mice) [47] and top-down (e.g., starting with a genetic mouse model and investigating their gut microbiome) [48] approaches.

In experiments conducted by Desbonnet et al. [47], male mice under germ-free rearing conditions engaged in social avoidant and repetitive behaviors and displayed a lack of interest in social novelty and social motivation, all of which are considered ASD-like behaviors. When the microbiome of a second set of germ-free mice was colonized with fecal bacteria from neurotypical, normally behaving mice, many of these behavioral deficits were reversed, demonstrating the significance of healthy microbiota for typical social functioning in mouse models. These data support the notion that gut bacteria modulate ASD-like symptoms. Using a top-down approach, Golubeva and colleagues [48] investigated the interaction between GI physiology, microbiota composition, and social behavior in BTBR T+Itpr3tf/J (BTBR) mice, which are well-validated models known to exhibit ASD-like behaviors. They found that BTBR mice displayed altered relative abundance levels in 18 out of 44 identified gut bacterial genera, which have been linked to physiological and behavioral impairments. Specifically, the mice showed significantly reduced amounts of Bifidobacteria and Blautia species, both of which play vital roles in optimal GI and metabolic functioning and social interactions within the BTBR mouse strain. This finding is consistent with those of Wang et al. [50], who compared the fecal samples of children with ASD and neurotypical controls and observed reduced abundances of Bifidobacterium in the ASD group. Additional bacterial taxa, including Akkermansia, Bacteroides, Desulfovibrio, and Lactobacillus, were found to have abnormal abundances in the gut of BTBR mice [48]. These taxa have also been associated with ASD symptomatology, including social, repetitive, and anxious behaviors in both animal and human studies [29,35,50,51,52,53].

In both human subjects and mouse models of ASD, gut microbiota-associated metabolites have been linked to ASD symptoms and co-occurring GI abnormalities [33,34,35,36]. Needham et al. [36], however, reported significant differences between the fecal and plasma metabolomes of typically developing (TD) and ASD children regardless of the presence of GI symptoms in the ASD group, demonstrating that microbial abnormalities and their influence on behavior may not be unique to ASD patients with GI dysfunction. Interestingly, metabolite levels were correlated with clinical behaviors, as measured by two clinical ASD assessments (Autism Diagnostic Observation Schedule [ADOS] and Autism Diagnostic Interview-Revised [ADI-R]), demonstrating significant relationships between metabolites, GI function, and behavior [36]. In another notable human-mouse microbiome study, Sharon and colleagues [54] transferred gut microbiota from ASD and TD hosts into germ-free wild-type mice. After the colonization of ASD microbiota, the mice displayed various hallmark ASD-like behaviors, such as increased repetitive behavior and decreased locomotion and communication, as well as different metabolome profiles compared to offspring mice colonized with microbiota from TD controls [54]. In addition to these behaviors, more recent studies have found decreased sociability, decreased sensitivity to social odors, and dysregulated metabolic pathways and metabolites in germ-free mice colonized with ASD bacteria [36,55]. Taken together, the studies above suggest that altered gut microbiota and some of their metabolites influence ASD-like behaviors in rodent models and ASD symptoms in patients.

Dietary tryptophan is metabolized through three main pathways: the serotonin, kynurenine (KYN), and indole metabolic pathways. Over 95% of tryptophan is oxidized and degraded to yield metabolites along the KYN pathway [69]. Importantly, tryptophan is also the sole precursor to the neurotransmitter serotonin (5-HT) in the brain and gut (synthesized by action of enzyme tryptophan hydroxylase [TPH]) [69]. Whereas gut microbiota play a modulatory role in the balance between serotonin and KYN production, the biosynthesis of indoles and indole derivatives (e.g., indole-3-aldehyde, indole-3-acetic acid, indole-3-propionic acid) from tryptophan is fully dependent on the enzyme tryptophanase, only found in select microbes [70]. How changes in the relative abundance of certain gut microbiota contribute to modifications of these pathways, central tryptophan metabolism, and ultimately brain function and behavior, is a crucial and ongoing area of research [71]. Many of these findings also require analysis of how this relationship modulates clinical symptoms characteristic of neurodevelopmental disorders, such as ASD.

Several functional neuroimaging studies indicate that the microbiota-modulated serotonergic system affects neural functioning in ASD. For example, positron emission tomography (PET) ligand studies have observed atypical serotonin functioning throughout the brain that was associated with greater social deficits in individuals with ASD [104,105]. One study found that ASD participants had significantly less binding of thalamic serotonin receptors than age-matched controls and that binding potential in the ASD group was negatively associated with social communication impairments [104]. Another PET study found a global reduction in SERT binding in adults with ASD [103]. Moreover, reduced SERT binding in the anterior and posterior cingulate cortices (ACC; PCC) was associated with impaired social cognition and reduced binding in the thalamus was associated with repetitive behaviors [105]. A more recent PET study found lower serotonin transporter availability in the total gray matter and brainstem of adults with ASD, relative to matched controls [106]. Serotonin transporter availability in the nucleus accumbens, ACC, and putamen was positively correlated with social cognition, indicating that the serotonin transporter may be a marker that can be targeted in pharmacological interventions [106].

Additionally, a polymorphism of the serotonin transporter gene (serotonin-transporter-linked-promoter region; 5-HTTLPR) has been shown to affect brain function in ASD. Short variants of 5-HTTLPR, which reduce serotonin transporter expression [107], are associated with impairments in social communication and interactions in individuals with ASD [108,109]. This is in line with other findings that have linked 5-HTTLPR to the default mode network (DMN), a neural network engaged during passive self-referential cognitive processing and associated with social cognition [110]. Wiggins et al. [111] found that while youth with ASD who had low expressing 5-HTTLPR alleles had stronger posterior-anterior DMN connectivity than those with high expressing genotypes, the opposite was true for TD controls. Thus, resting-state connectivity was shown to be influenced by 5-HTTLPR in a different pattern in ASD than typical controls, suggesting that individuals with low expressing 5-HTTLPR genotypes may comprise a subtype of ASD.

The same researchers showed that ASD youth with low expressing 5-HTTLPR genotypes also had atypical amygdala functioning while performing social tasks [112,113]. During an observational face-processing task, youth with low expressing 5-HTTLPR genotypes failed to show amygdala habituation to repeated observation of sad faces compared to TD controls and ASD youth with high expressing genotypes. Building on these findings, Velasquez et al. [112] showed that when viewing happy faces, the ASD group with the low expressing genotypes had abnormally high rates of functional connectivity between the amygdala and subgenual ACC than ASD individuals with higher expressing genotypes and TD groups of higher and lower expressing genotypes. ASD participants with greater amygdala-subgenual ACC connectivity, key regions involved in emotion arousal and regulation, also showed higher expressing genotypes of 5-HTTLPR and less social dysfunction. Together, these findings indicate that, in ASD, it is possible that some socioemotional functioning during rest and social processing may be influenced by atypicalities in the serotonergic system [112,113]. These results further support the importance of the 5-HTTLPR genotype in examining the heterogeneity of social function in ASD. Nevertheless, a recent meta-analysis found no support for a direct effect of 5-HTTLPR polymorphism on risk of ASD, indicating that patterns across studies may be difficult to find given the heterogeneity of the disorder. Further analyses in larger sample sizes with more homogeneous subgroups of ASD participants may be necessary [114].

Research also suggests that there are group differences between ASD and TD neural responses to serotonin availability. One fMRI study found that increased serotonin (via a selective serotonin reuptake inhibitor) was associated with sustained neural activation in emotion-related brain regions during a negative facial emotion-processing task in ASD adults compared to neurotypical controls, which exhibited an expected habituation response [115]. The authors concluded that homoeostatic control of these regions is altered by serotonin in ASD. Two other fMRI studies found that acute tryptophan depletion (which lowers serotonin levels) was associated with deficits in facial affect [116] and inhibitory processing [117] in ASD. These findings may help explain some of the social and restricted/repetitive behaviors that are hallmarks of the disorder [116,117]. Further, many of the brain regions found to be modulated by the tryptophan depletion have previously been reported to have serotonergic abnormalities in people with ASD (e.g., synthesis differences, lower numbers of receptors and transporters) [116].

Despite the extensive evidence showing alterations in the tryptophan pathway and the serotonergic system in ASD, there is no consensus in current literature on tryptophan availability and its influence on behavior in patients with ASD. While studies have suggested that reduced levels of tryptophan [118,119,120] and decreased tryptophan metabolism are prominent features of ASD [121], a recent study showed both increased and decreased levels of tryptophan in ASD youth [122], which, again, may be related to ASD heterogeneity and marks the need for ASD sub-grouping. The potential roles of oxytocin and other upstream markers in ASD have also been discussed [123] and it is likely that interactions between oxytocin and serotonin may further influence the pathophysiological processes of ASD [124]. More research is necessary to fully understand the complex neurochemical processes underlying the relationship between the BGM system, tryptophan metabolism, and ASD. Below, we discuss specific findings in BGM connections at the structural and functional levels and how changes in the microbiome impact neural networks.

The amygdalae are bilateral nuclei primarily involved in high-level information processing, emotional processes and behaviors (e.g., fear, aggression), decision making, and social interaction [145]. Newly emerging research has begun to focus specifically on how gut microbiota modulate amygdala function and the possible implications for treating psychiatric disorders associated with amygdala dysregulation, including the reduction of symptom severity in ASD [146]. Numerous genetic, epigenetic, and environmental changes in early development have been linked to gut microbial alterations, which may in turn alter amygdala development and white matter connections to other brain regions; for a review, see [147]. Rodent studies have found microbial status to influence amygdala volume, dendritic morphology, and spine density [148], as well as gene expression and neural development of the amygdala during critical time windows [149,150]. Another recent study demonstrated that the presence of microbiota is necessary for socially induced gene expression regulation in the amygdalae [151]. Moreover, Lobzhanidze et al. [152] recently showed that the microbial metabolite propionic acid, which in excess has been associated with ASD symptomatology [153,154], significantly reduces social motivation and alters amygdalae structure in rodents. At the functional level, microbiome diversity has been negatively associated with functional connectivity of the amygdala during early brain development in humans [155]. Since the developmental trajectory of the functional connectivity of amygdalae during the first two years of life has been shown to be a significant predictor of cognitive and emotional outcomes [155,156], the potential impact of gut microbiota on emotion-related brain region connectivity and growth patterns in an early critical period may have long-term implications for mental health, including ASD symptomatology.

Given the strong relationship between the amygdala’s impairments in ASD [157,158,159,160] and current research demonstrating gut microbiota’s relationship to the amygdala, understanding how gut microbiota interact with amygdala structure and function in ASD may elucidate underlying neural correlates of social and emotional processing deficits. Further research examining sociality and gut microbiota in individuals with ASD may help inform treatment targeting amygdala-dependent behaviors related to ASD via the BGM system.

Subregions of the insular cortex play important roles in the processing of sensory, autonomic, and interoceptive information from the viscera and are thought to be involved in socioemotional processing [161]. The anterior insula, specifically, serves as a crucial hub of a network involved in detecting salient events and integrating internal physiological signals (including gut signals) [162] and external sensory stimuli to guide behavior [163]. Reduced connectivity in the anterior insula and dysfunction of this network have been consistently implicated in ASD [138]. It has also been proposed that modulations to this network may play an important role in regulating immune function and GI symptoms in IBS [164].

To date, no studies have examined the relationship between the insula and the microbiome in individuals with ASD; however, there is evidence from healthy individuals and those with irritable bowel syndrome (IBS) to suggest that insular structure is indeed modulated by changes in the microbiome, which contribute to the pathophysiology of IBS [165,166]. Structurally, cortical thickness of the insula has been found to be related to both IBS [167,168,169] and microbiota composition. Tillisch et al. [170] found a positive association between cortical thickness in the insula and Bacteroides abundance in healthy adult women. The same group investigated the gut microbial composition and structural brain signatures of individuals with IBS and discovered a greater volume in the mid and posterior insula in IBS patients, relative to healthy controls [171]. In a subgroup of patients with a distinct microbial makeup, Labus et al. [171] found that the anterior insula had a larger surface area and smaller cortical thickness relative to healthy controls. Additionally, functional alterations of the insula have been reported by several fMRI studies in patients with IBS [172,173,174,175,176].

In a recent study directly investigating the relationship between gut microbiota and neuronal activity in the insula, Curtis and colleagues [177] observed that microbiota diversity was positively associated with resting-state functional connectivity between the middle insular cortices and frontal and cerebellar areas. Furthermore, when controlling for smoking status (previously shown to influence gut microbiota [178]), the connections between anterior and inferior regions of the insula and various brain regions were also related to microbiota diversity. Notably, they reported correlations between anterior and inferior insula connectivity and Bacteroides and Prevotella, two genera with well-established abnormalities in individuals with ASD [53,179,180]. Moreover, levels of fecal microbiota-derived indole metabolites (i.e., indole, skatole, indoleacetic acid) have been positively associated with the anatomical and functional connectivity of the amygdala-anterior insula circuit in healthy individuals [181]. Taken together, these findings indicate that microbiome differences in individuals can be observed at the cortical level. Thus, there is a need for research on how microbiome diversity and regulation may influence brain activity and help treat neuropsychiatric disorders associated with insular abnormalities, including ASD.

Several neuroimaging studies have reported strong relationships between gut microbiota and functioning of emotion-related brain regions, in addition to the amygdala and insula. For example, in an fMRI study utilizing an emotional faces attention task, consumption of a fermented milk product with probiotic was related to reductions in activity of a widely distributed functional network containing brain areas that control processing of emotion, sensation, attention, and interoception in healthy women [182]. In addition to the insula and amygdala, this network included a range of midbrain regions centered on the periaqueductal gray [182]. A similar connection was suggested when treatment with Bifidobacterium was found to be associated with both decreased depression and reduced activity in the amygdala and fronto-limbic regions in IBS patients [183].

More recently, Gao and colleagues [155] investigated the microbiome’s potential relationship with emotion-related brain circuits in infants through fecal analyses and resting-state fMRI data. Strong negative associations were found among alpha diversity and connectivity between the amygdala and thalamus as well as the right anterior insula and ACC, suggesting that higher levels of microbiome diversity may be related to less efficient mechanisms for emotion and threat processing. The researchers also observed a positive correlation between alpha diversity and sensorimotor-parietal connectivity, which allows for interactions between auditory, visual, and somatosensory cortices and has been linked to cognitive ability at two years of age [155]. These results provide initial evidence for microbiome-associated changes in functional neural circuits during early human development [155]. Future studies may explore the relationships between connectivity and ASD-related symptomatology, particularly the emotion and sensory processing atypicalities common in individuals with ASD [184,185].

Microbiota have also been related to white matter microstructure and cortical thickness in other emotion- and cognition-related brain regions. One study on obese and non-obese participants found significant positive associations between fecal microbiota diversity and fractional anisotropy (FA; a measure of white matter connectivity) of the hypothalamus, caudate nucleus, and hippocampus [186]. Additionally, abundance of Actinobacteria was positively associated with executive functioning and structural microstructure, as measured by FA in the amygdala and thalamus, supporting the link between the microbiome and emotion processing [186]. Tillisch and colleagues [170] found further evidence that gut microbiota may impact brain structure in addition to functional connectivity, mood, and behavior. Specifically, greater Prevotella abundance was related to increased connections between emotion-, attention-, and sensory-processing brain regions and lower cortical thickness in the anterior insula, while higher Bacteroides was associated with greater cortical thickness in the frontal cortex and anterior insula [170].

In summary, evidence from neuroimaging studies indicates that gut microbial parameters may be associated with social and emotional brain structure and function across a variety of populations, especially individuals with IBS. Researchers have also begun to use the functional brain-gut approach to gain a better understanding of neuropsychiatric disorders, including ADHD, anxiety, depression, and schizophrenia [183,187,188,189]. Given the increased prevalence of IBS and GI-related comorbidities in individuals with ASD, studies that explicitly investigate how gut microbiota are related to neural functioning in ASD are warranted.