The study by a team of researchers at USC Dornsife, UCLA and the University of Georgia, Athens, finds a direct connection between particular bacteria in the gut and impaired brain function.
New research shows how drinking sugary beverages early in life may lead to impaired memory in adulthood.
The study, published March 31 in Translational Psychiatry, also is the first to show how a specific change to the gut microbiome — the bacteria and other microorganisms growing in the stomach and intestines — can alter the function of a particular region of the brain.
According to the Centers for Disease Control and Prevention, sugar-sweetened beverages are a leading source of added sugars in Americans’ diets. Nearly two-thirds of young people in the United States consume at least one sugary drink each day.
Neuroscientist Scott Kanoski, associate professor of biological sciences at the USC Dornsife College of Letters, Arts and Sciences, has studied the link between diet and brain function for years. His research has shown that consumption of sugary beverages impairs memory function in rats and that those same drinks change the gut microbiome.
In the current study, Kanoski and researchers at UCLA and the University of Georgia, Athens, sought to find out if a direct link exists between changes to the microbiome and memory function.
The scientists gave adolescent rats free access to a sugar-sweetened beverage similar to those that humans drink.
When the rats grew to be adults after about a month, the researchers tested their memories using two different methods. One method tested memory associated with a region of the brain called the hippocampus. The other method tested memory function controlled by a region called the perirhinal cortex.
The researchers found that, compared to rats that drank just water, the rats that consumed high levels of sugary drink had more difficulty with memory that uses the hippocampus. Sugar consumption did not affect memories made by the perirhinal cortex.
“Early life sugar consumption seems to selectively impair their hippocampal learning and memory,” said study lead author Emily Noble, assistant professor in the UGA College of Family and Consumer Sciences and a former postdoctoral fellow at USC Dornsife.
The scientists then checked the rats’ gut microbiomes and found differences between those that drank the sweet beverage and those that drank water. The sugar drinkers had larger populations of two particular species of gut bacteria: Parabacteroides distasonis and Parabacteroides johnsonii.
The researchers then asked if the Parabacteroides bacteria could, without the help of sugar, affect the rats’ memory function. They transplanted Parabacteroides bacteria that were grown in the lab into the guts of adolescent rats that drank just water. The rats receiving the bacteria showed memory impairment in the hippocampus when they grew to adulthood much the same as the sugar-drinking rats.
The scientists also found that, unlike the sugar-drinking rats, the transplanted rats also showed memory impairment in the perirhinal cortex. This difference provides further evidence that altered brain function associated with diet may actually be rooted in changes to the gut microbiome.
Previous studies have transplanted the entire gut microbiome from one group of animals to another, producing similar changes to brain function. However, this study is among the first to do so with just two specific species.
“It was surprising to us that we were able to essentially replicate the memory impairments associated with sugar consumption not by transferring the whole microbiome, but simply by enriching a single bacterial population in the gut,” said Kanoski, who is a corresponding author on the study.
Finally, the scientists examined the activity of genes in the hippocampus, comparing rats that drank the sugary beverage to those that drank just water and comparing water drinkers to those transplanted with Parabacteroides.
Gene activity did, in fact, change in both the rats that consumed the sugar-sweetened beverages and the rats transplanted with Parabacteroides. The genes that were affected control how nerve cells transmit electrical signals to other nerve cells and how they send molecular signals internally.
The results of this study confirm a direct link, on a molecular level, between the gut microbiome and brain function.
In future studies, Kanoski and the researchers hope to determine if changing habits, such as eating a healthier diet or increasing exercise, can reverse the harm to memory caused by elevated sugar consumption earlier in life.
About the study
In addition to Kanoski and Noble, study authors include Elizabeth Davis, Linda Tsan, Clarissa Liu, Andrea Suarez and Roshonda Jones from USC Dornsife; Christine Olson, Yen-Wei Chen, Xia Yang and Elaine Y. Hsiao UCLA; and Claire de La Serre and Ruth Schade from UGA.
The research was supported by National Institute of Diabetes and Digestive and Kidney Diseases grants DK116942, DK104897, DK118000, DK111158, DK116558, DK 118944 and DK104363; National Institute on Aging award F31 AG064844; and Department of Defense ARO MURI award W911NF-17-1-0402.