“The focus of our work is on how the gut microbiota-the trillions of bacteria that inhabit the gut-affects the immune system,” said Associate Professor from the University’s and
“Our ultimate aim is to understand how we can manipulate the bacteria to optimise health, and we know that one of the easiest ways to change the microbiota is to change the diet.”
Traditionally, however, scientists have focused on the role of dietary fibre in maintaining a healthy gut.
In this first-of-its-kind study, published in , the team from the Charles Perkins Centre used sophisticated modelling to explore the impact of 10 diets with a different makeup of macronutrients – protein, fats and carbohydrate in mice.
They discovered that a high-protein diet changed the composition and activity of the gut microbiota.
Mice fed a high protein diet increased their production of bacterial extracellular vesicles, complex cargo containing bacterial information such as DNA and protein. The body subsequently viewed this activity as a threat and triggered a sequence of events where immune cells travelled into the gut wall.
“Here we found protein had a huge impact on the gut microbiota and it was not so much about the type of bacteria that were there, but the type of activity. In essence, we discovered a new way of communication between the gut bacteria and the host which was mediated by protein,” said Associate Professor Macia.
While it is too early to say if this research might translate in humans, the researchers say activation of the immune system can prove either good or bad news.
“By increasing antibodies in the gut you may see strong protection against potential pathogens, for example salmonella, but on the downside, an activated immune system could mean you are at increased risk of colitis, an inflammatory bowel disease, or autoimmune conditions like Crohn’s,” said lead author and post-doctoral researcher Jian Tan.
The results appear consistent with the population impacts of modern-day diets, with the Western world seeing lower rates of gastrointestinal infection but higher rates of chronic disease.
This advancement in knowledge was made possible by the merging of academic disciplines for which the Charles Perkins Centre has become well known.
The study utilised the developed by Professor and Professor , arising from the study of ecology.
“The ‘nutritional geometry’ framework enables us to plot foods, meals, diets and dietary patterns together based on their nutrient composition, and this helps researchers to observe otherwise overlooked patterns in the links between certain diets, health and disease,” said Professor Simpson, Academic Director of the Charles Perkins Centre.
“This is the first time this model has been applied in immunology and it could only have happened here at the Charles Perkins Centre. We are excited about what could come next,” Associate Professor Macia said.
Declaration: This project was funded by Australian Research Council grants (APP160100627 and APP210102943) and by the Sydney Medical School MCR BioMed-Connect Grants. The authors declare no competing interests. All experiments were performed in accordance with protocols approved by the University of Sydney Animal Ethics Committee (Protocol 2017/1280, 2019/1493, and 2019/1688).
Banner image courtesy of Shutterstock.