BREAKING — Plastic-Eating Fungi Discovered
A strain of fungi researchers found in a rubbish heap can break down plastic as it grows.
Scientists from the Kunming Institute of Botany (KIB), Chinese Academy of Sciences have recently identified a fungus which could help deal with the problem of plastic waste by using enzymes to rapidly break down plastic materials. Their findings have been published in Environmental Pollution.
Plastic is used in the manufacture of an astonishing variety of materials: from the phone or computer on which you’re reading this article, to the car, bus or bike you use to get around, and even in many clothes.
However, the tremendous increase in the production and use of various manmade plastics has become a huge threat to the environment: plastic waste can choke waterways and soils, release harmful chemicals, and even poses a threat to animals which can mistake plastic debris for food.
Plastic polymers take many years to decompose, as due to their xenobiotic nature—meaning that they did not exist before their synthesis by humans—they are not easily broken down by the bacteria, fungi and small creatures that feed on other waste matter. Even when they do somewhat degrade, tiny particles of plastic may persist in the environment, with unknown consequences for human and environmental health.
However, the KIB team believe they may have found an unexpected solution to our growing plastic problem in the form of a humble soil fungus.
“We knew that one way to do this would be to look to solutions which already existed in nature, but finding microorganisms which can do the job isn’t easy,” the authors said.
In the end, the research team found their plastic-eating fungus living in an appropriate venue—a rubbish tip in Islamabad, Pakistan.
Watched by crows and vultures, the researchers took samples of soil and various pieces of rubbish in hopes of finding an organism which could feed on plastic waste in the same way that other fungi feed on dead plant or animal material.
Aspergillus tubingensis is a fungus which ordinarily lives in the soil. In laboratory trials, the researchers found that it also grows on the surface of plastics. It secretes enzymes onto the surface of the plastic, and these break the chemical bonds between the plastic molecules, or polymers.
Using advanced microscopy and spectroscopy techniques, the team found that the fungus also uses the physical strength of its mycelia—the network of root-like filaments grown by fungi—to help break apart the polymers. Plastics which persist in the environment for years can be broken down by A. tubingensis in a matter of weeks, the scientists say.
The fungus’ performance is affected by a number of environmental factors including pH, temperature and the type of culture medium used.
“Our team’s next goal is to determine the ideal conditions for fungal growth and plastic degradation,” said study author Afsar Khan, an assistant professor at the COMSATS Institute of Information Technology in Pakistan.
This could pave the way for large-scale use of the fungus in waste treatment plants or soils already contaminated by plastic waste. The discovery of A. tubingensis’ appetite for plastic joins the growing field of ‘mycoremediation,’ which investigates the use of fungi in removing or degrading waste products including plastic, oil and heavy metals. Mycologists estimate that only a small proportion of all fungi species have yet been described, which means that vast numbers of potentially useful species are still to be found. However, the destruction of habitats such as natural forests means that many fungi species are likely being lost before they can be identified, let alone tested for possible uses. If this continues, we may come to rely more and more on those species we can find in man-made environments—and more scientists may find themselves doing fieldwork in rubbish tips rather than rainforests.
Mycologists estimate that only a small proportion of all fungi species have yet been described, which means that vast numbers of potentially useful species are still to be found. However, the destruction of habitats such as natural forests means that many fungi species are likely being lost before they can be identified, let alone tested for possible uses.
If this continues, we may come to rely more and more on those species we can find in man-made environments—and more scientists may find themselves doing fieldwork in rubbish tips rather than rainforests.
The article can be found at: Khan et al. (2017) Biodegradation of Polyester Polyurethane by Aspergillus tubingensis.
Source: Chinese Academy of Sciences;
Article Source: Asian Scientists Magazine