Marsupials low-methane footprint could help fight climate change

© Pat Whelan via Pexels.

© Pat Whelan via Pexels.

Researchers are aiming to unlock the microbial secrets of native Australian animals’ low-methane digestive footprint and how environmental changes might disrupt this relationship.

A kangaroo stands in an enclosure with his head looking to the right.

Low methane-producing archaea is found in some native Australian herbivores, including kangaroos © The University of Queensland.

Low methane-producing archaea is found in some native Australian herbivores, including kangaroos © The University of Queensland.

A kangaroo stands in an enclosure with his head between his two paws.

© The University of Queensland.

© The University of Queensland.

Findings from this University of Queensland-led project could translate to a better understanding of food digestion in people and livestock.

UQ scientists Professor Mark Morrison, Dr Rochelle Soo and Dr Paul Evans will begin studying methane-producing microorganisms called ‘archaea’ from herbivores including kangaroos, wombats, and koalas, and compare their behaviour with similar microbes from livestock and humans.

“Archaea live in the digestive tracts of many animals, but we don’t yet know the reasons why some of these animals appear to release less methane during food digestion than others,” Professor Morrison said.

"A better understanding of this relationship could potentially help scientists find ways to reduce methane emissions in livestock, decrease greenhouse gas emissions from the agricultural sector and positively impact climate change.

“The methane-producing archaea found in some native Australian herbivores appear to be quite different to those found in other animal hosts, like cattle, sheep and humans.”

Professor Morrison and his team will use molecular and genomic sequencing methods to investigate what features make the archaea from the different host animals unique.

Gram negative image of Methanobrevibacter smithii archeaon in the human gut.

Methanobrevibacter smithii isolated from a healthy human faecal sample. This is the predominant archaea in the microbiota of the human gut. © PhD candidate, James Volmer from the Morrison Group.

Gram negative slide showing archaeon sample from a common wombat.

Methanocorpusculum sp from the faecal sample of a common wombat. © James Volmer and Ana Laura Astorga Alsina from the Morrison group.

Methanobrevibacter smithii isolated from a healthy human faecal sample. This is the predominant archaea in the microbiota of the human gut. © PhD candidate, James Volmer from the Morrison Group.

Methanocorpusculum sp from the faecal sample of a common wombat. © James Volmer and Ana Laura Astorga Alsina from the Morrison group.

“We believe these differences can be defined and will ultimately provide new opportunities to monitor and manage these methane-producing populations in animals, and their impacts on the environment and society,” he said.

“For instance, the presence of methane-producing archaea is not uncommon in humans, and their presence has been linked with some digestive symptoms, like constipation.

“Interestingly, some types of methane-producing archaea from other animal species may use materials that are considered to be risk factors for cardiovascular disease in humans.

“While not the focus of our project, we do hope our discoveries in the biology of methane-producing archaea from native Australian herbivores might ultimately be useful to understand and manage host-microbe relationships in people and livestock.”      

This research is a collaboration between UQ’s Diamantina Institute, School of Chemistry and Molecular Biosciences, and the Australian Centre for Ecogenomics.

The research grant is one of 47 UQ projects awarded an Australian Research Council Discovery Project for 2021.

Baby koala in a tree.

Media:
communications@uq.edu.au, +61 7 3365 1120, +61 424 002 566.