Gut Microbes Influence Autism-Related Behaviors

Summary: A new study demonstrates the profound influence of gut microbes on behavior, particularly in the context of autism spectrum disorders (ASD). The study reveals that gut discomfort in mice reduces social behaviors, a phenomenon reversible by specific bacterial introductions.

This groundbreaking work points to the gut microbiome as both a potential source of ASD-related symptoms and a therapeutic target. By modifying the gut microbiome, scientists were able to alleviate not only gastrointestinal symptoms but also behavioral changes, paving the way for microbiome-targeted therapies.

Key Facts:

  1. Gut-Behavior Link: The study provides strong evidence linking gastrointestinal distress with reduced social behaviors in mice, an effect that mirrors social impairments seen in ASD.
  2. Microbial Intervention: Introducing specific bacterial strains into mice’s guts ameliorated both gastrointestinal symptoms and associated behavioral changes, highlighting the therapeutic potential of microbiome manipulation.
  3. Future Therapeutic Directions: The findings suggest that targeted adjustments to the gut microbiome could become a viable strategy for addressing both gastrointestinal and behavioral symptoms in ASD, leading to personalized microbiome therapies.

Source: University of Utah

For people with autism, constipation, diarrhea, and abdominal pain often go along with the social struggles and repetitive behaviors that define the condition. This has prompted many to wonder whether gastrointestinal (GI) problems arise due to autism’s behavioral or sensory features, or whether they might instead contribute to them.

Now, scientists at University of Utah Health have added to mounting evidence showing that microbes that live in our guts influence behavior. Specifically, they found that in mice, frequent gastrointestinal distress can reduce social behaviors—an effect that persists even after GI symptoms have subsided.

They also showed they could alleviate both GI symptoms and the behavioral changes they provoke by introducing specific species of bacteria into the animals’ guts.

The reluctance to socialize that the researchers observed in their mice was reminiscent of the social impairments associated with autism. Credit: Neuroscience News

The new study, published in Nature Communications, demonstrates that it is possible to impact health and behavior by manipulating the gut microbiome in a controlled way.

“I think that this is a really important step therapeutically, because now we can start to assemble a therapy with organisms that we know to be safe,” says June Round, Ph.D., a microbiologist at U of U Health who led the research.

The gut-behavior connection

Because scientists are still trying to untangle the relationship between GI problems and autism-related behaviors, Round and her team began their study by investigating the behavioral impact of GI distress in mice. Graduate student Garrett Brown, Ph.D., studied mice with an inflammatory condition called colitis, which causes pain, diarrhea, and intestinal damage.

After several rounds of colitis, the animals’ symptoms were allowed to subside before behavioral testing. Mice that had experienced colitis moved around normally and showed no signs of anxiety or depression. However, they spent less time interacting with unfamiliar mice than mice that had not experienced colitis.

“It’s not like the mice are under so much pain that they’re not doing anything,” Brown says. “So maybe it is something specific to sociability and not just that the mice feel poorly.”

The reluctance to socialize that the researchers observed in their mice was reminiscent of the social impairments associated with autism. Since their experiments suggested that problems in the gut might drive changes to social behavior, they wondered whether the microbes there—which tend to differ between autistic and neurotypical people—might be involved in both.

To investigate, Brown collected stool samples from people with autism as well as from their neurotypical parents or siblings. Then he delivered the microbe-filled samples to the GI tracts of mice.

When he induced colitis in those animals, mice carrying microbes from individuals with autism had more intestinal damage and lost more weight than mice whose microbes came from neurotypical individuals. It seemed that the mix of microbes collected from neurotypical individuals had a protective effect.

Finding microbial protectors

The microbial community inside the human gut is so complex that the samples the team had used in their experiments could easily have included hundreds of kinds of bacteria, viruses, and fungi. Round and Brown wanted to know which of those community members protected against intestinal problems.

To do that, Brown compared the gut microbes from individuals with autism to those from their neurotypical family members, as well as the microbes living in the guts of mice that had been transplanted with those microbial communities.

He was looking for potentially protective microbes that might be underrepresented in people with autism compared to neurotypical individuals—and he found some.

“We were able to pick out individual microbes that we thought might be playing important roles in resisting severe colitis,” explains Brown, who is now a fellow at the National Institutes of Health Clinical Center.

Two in particular stood out. Certain species of Blautia bacteria were better represented in neurotypical individuals than in their autistic family members.

And among mice colonized with microbes from autistic people, a group called Bacteroides uniformis was more abundant in those whose colitis was less severe. B. uniformis is known to be underrepresented in people with irritable bowel syndrome and Crohn’s disease, suggesting a role in intestinal health.

Once the researchers had zeroed in on these groups of bacteria, Brown delivered them to mice prior to inducing colitis. Both Blautia and Bacteroides uniformis reduced intestinal problems, and the Blautia had a corresponding effect on social behavior. Animals that received the Blautia bacteria were more likely than other mice to engage with unfamiliar mice following colitis.

Toward personalized therapies

Round says the study is one of the first to identify specific organisms within the human microbiota that can ameliorate a behavioral deficit associated with GI stress. “This is an example where we are missing microbes, and missing these beneficial microbes is driving disease,” she says.

Further research will be needed to clarify whether boosting the numbers of Blautia or Bacteroides uniformis bacteria might benefit people with GI disorders, autism, or other conditions. But Round says teasing out their individual effects is an important step toward personalized microbiome-targeted therapies.

“One day,” she says, “we’re going be able to quickly analyze the microbiome and say, “Hey, you’re missing this really important microbe. We’re going to give it back to you.’”

About this microbiome, ASD, and behavioral research news

Author: Jennifer Michalowski
Source: University of Utah
Contact: Jennifer Michalowski – University of Utah
Image: The image is credited to Neuroscience News

Original Research: Open access.
Colitis reduces active social engagement in mice and is ameliorated by supplementation with human microbiota members” by June Round et al. Nature Communications


Abstract

Colitis reduces active social engagement in mice and is ameliorated by supplementation with human microbiota members

Multiple neurological disorders are associated with gastrointestinal (GI) symptoms, including autism spectrum disorder (ASD). However, it is unclear whether GI distress itself can modify aspects of behavior.

Here, we show that mice that experience repeated colitis have impaired active social engagement, as measured by interactions with a foreign mouse, even though signs of colitis were no longer present.

We then tested the hypothesis that individuals with ASD harbor a microbiota that might differentially influence GI health by performing microbiota transplantation studies into male germfree animals, followed by induction of colitis.

Animals that harbor a microbiota from ASD individuals have worsened gut phenotypes when compared to animals colonized with microbiotas from familial neurotypical (NT) controls.

We identify the enrichment of Blautia species in all familial NT controls and observe an association between elevated abundance of Bacteroides uniformis and reductions in intestinal injury. Oral treatment with either of these microbes reduces colon injury in mice.

Finally, provision of a Blautia isolate from a NT control ameliorates gut injury-associated active social engagement in mice. Collectively, our data demonstrate that past intestinal distress is associated with changes in active social behavior in mice that can be ameliorated by supplementation of members of the human microbiota.

Reference

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