Synergistic biodegradation of a compostable film by a marine microbial community

The need for replacing conventional plastics has led to an increase of the use biodegradable plastics. Most biodegradable plastic materials are certified for compostability, and their degradation mechanisms by marine bacterial communities, are still largely unknown.

Bacterial communities that degrade a poly (butylene adipate-co-terephthalate)-based biodegradable film (PF) were enriched from marine samples. DNA, RNA and proteins were extracted simultaneously from the biofilm and free-living bacteria. Genes of hydrolases similar to the ones involved in polyethylene terephthalate (PET) and monoester mono-2-hydroxyethyl terephthalate (MHET) degradation (PETase and MHETases, respectively) were detected. A MHETase-like gene (Mle046) was then recombinantly expressed. The activity of Mle046 was tested against the end product of PET and PF degradation: MHET and 4-(4-hydroxybutoxycarbonyl) benzoic acid (Bte), respectively. The optimal incubation temperature and pH of Mle046 activity was determined.

PETase-like (Ples) and MHETase-like (Mles) hydrolases and other enzymes needed for PF degradation were expressed within the microbial community. Within the biofilm, Ples were abundant and upregulated while Mles and terephthalate dioxygenases were abundant in the free-living fraction. Mle046 was the only Mle produced in this fraction and it was highly expressed. The purified Mle046 could degrade MHET and Bte. The optimum temperature of Mle046 activity was 20°C.

PF degradation is achieved synergistically by labour division among film-attached and free-living bacteria. Understanding the biodegradability of these plastics will facilitate the development of more degradable materials. In addition, the discovery of new PETases- and MHETases-like enzymes will enable their future use in plastic recycling.