New pathways found for biotechnological degradation of industrial waste
Microorganism breaks down phenol under extreme conditions
Foto-Rabe, pixabay.com
Phenol degradation by Saccharolobus solfataricus
S. solfataricus is classified as archaea, a group of microorganisms that together with the better known group of bacteria constitute the so-called prokaryotes. Saccharolobus solfataricus prefers extreme environmental conditions with temperatures of 80°C and acidic surroundings with a pH of 3.5. The researchers’ experiments showed that S. solfataricus is able to survive on phenol as sole carbon source. To this end, the microorganism breaks down the toxic organic compound and uses the now available carbon to build up biomass. Until now, the metabolic pathway to achieve this purpose had not been described in detail. Based on their findings, Dr Neumann-Schaal and her team could not only determine the sought-after metabolic pathway, but were also able to postulate enzymes involved in the various reaction steps necessary for the degradation of phenol.
Toxic agent phenol
The organic compound phenol is a chemical agent that commonly occurs as waste product in various industries, for instance the textile industry or fuel production from fossil raw materials such as carbon. Phenol is a pollutant that causes massive damage in humans and animals. In nature, phenol is for example released in low quantities in the degradation of plant material and animals.
It is already known that various bacteria and yeasts are able to break down phenol. These microorganisms occur in mesophilic environments, that is to say they live in temperatures between 20 and 45°C. However, since industrial phenol waste commonly develops under high temperatures and low pH-values, it requires a cost- and energy-intensive treatment in the sense of a cool-down and/or neutralisation process to allow the microbial degradation of phenol to begin. In addition, most phenol-degrading bacteria belong to the Pseudomonas family and are often pathogenic, i.e. harmful, to humans and the environment. And this is where the great potential of archaea comes in, explains biochemist Dr Meina Neumann-Schaal. “Using archaea such as Saccharolobus solfataricus could circumvent the problems of re-processing industrial phenol-waste and therefore save costs. We now know which enzymes and proteins are involved in phenol degradation and can therefore specifically look for these in other archaea. There might be other groups that can break down phenol even more efficiently. This is only the beginning of research in this area.”