Tree bark microbiome has important overlooked role in climate
Tree bark has a total surface area similar to all of the land area on Earth. It is home to a wide range of microbial species unknown to science, and they can either take up or emit gases that have a warming effect on the climate
Melaleuca wetland forests in New South Wales, Australia, are hotspots for tree microbial life
Luke Jeffrey / Southern Cross University
The bark of a single tree can be home to trillions of bacteria, and these microbes may have an important but neglected role in controlling greenhouse gases in Earth’s atmosphere.
The total surface area of tree bark on the planet is thought to be around 143 million square kilometres, nearly as much as the world’s total land surface area. This surface makes up an immense microbial habitat known as the caulosphere, but the microbes that live there have received little attention from scientists.
“In a way it’s so obvious, but we have always overlooked tree bark,” says Bob Leung at Monash University in Melbourne, Australia. “We never thought of microbes on tree bark, but it makes sense, because bacteria are everywhere, and if we can find microbes in soils, on tree leaves, then most likely there will be microbes on bark.”
Leung and his colleagues began by studying a wetland species commonly known as paperbark (Melaleuca quinquenervia). They found that there were more than 6 trillion bacteria living in or on each square metre of bark, comparable to the volumes found in soil.
Genetic analysis of 114 of these bacteria showed that they mostly came from three bacterial families – Acidobacteriaceae, Mycobacteriaceae and Acetobacteraceae – but all of the species were completely unknown to science.
Remarkably, these microbes have one thing in common: they can use hydrogen, carbon monoxide and methane as fuel to survive. Hydrogen (H2) isn’t itself a greenhouse gas, but through reactions with other molecules it can increase the warming effect of methane in the atmosphere.
The researchers then looked at the bark of another seven Australian tree species from a range of habitats, including casuarinas, gum trees and banksias, measuring, both in the field and in lab conditions, whether the bark of the different species absorbed or emitted greenhouse gases.
They found that all barks consumed hydrogen, carbon monoxide and methane in aerobic conditions when oxygen is available. But when trees are submerged in water and oxygen is limited, such as in swamps, bark microbes switched to producing the same gases.
