Fungal bioremediation of polyethylene:challenges and perspectives

Plastics have become ubiquitous in both their adoption as materials and as environmental contaminants. Widespread pollution of these versatile, man-made, and largely petroleum-derived polymers has resulted from their long-term mass production, inappropriate disposal, and inadequate end of life management. Polyethylene (PE) is at the forefront of this problem, accounting for one third of plastic demand in Europe in part due to its extensive use in packaging (European Parliament, 2020). Current recycling and incineration processes do not represent sustainable solutions to tackle plastic waste, especially once it becomes littered, and the development of new waste-management and remediation technologies are needed. Mycoremediation (fungal-based biodegradation) of PE has been the topic of several studies over the last two decades. The utility of these studies is limited by an inconclusive definition of biodegradation and a lack of knowledge regarding the biological systems responsible. This review highlights relevant features of fungi as potential bioremediation agents, before discussing the evidence for fungal biodegradation of both high- and low-density PE. An up-to-date perspective on mycoremediation as a future solution to PE waste is provided. [Abstract copyright: This article is protected by copyright. All rights reserved.

The impact of combinatorial stress on the growth dynamics and metabolome of 'Burkholderia mesoacidophila' demonstrates the complexity of tolerance mechanisms

Aims: The recently sequenced Burkholderia mesoacidophila (previously Pseudomonas mesoacidophila) is a soil organism and as such will be exposed to multiple concurrent stresses in the natural environment. The combinatorial stress potentially experienced by microbes in soil has not been investigated in detail. Methods and Results: The impact of combinatorial stress on growth was investigated using tripartite variables—temperature, nutritional environment and either osmotic or oxidative stress. In nutritionally stringent conditions, increasing diamide concentration had no effect on growth while increasing H2O2 concentration reduced both growth rate and maximum density. Metabolomic studies with oxidative stress revealed specific (unidentified) metabolites associated with diamide tolerance, and an overwhelming dominance of sugars and sugar alcohols in nutritionally stringent conditions with and without the additional stressor. Conclusions: Combinatorial stress tolerance is complex. Temperature had the greatest independent impact on growth, while the impact of the nutritional environment played a key role in oxidative stress tolerance. In nutritionally stringent conditions, the metabolome suggested different tolerance mechanisms for different types of oxidative stress. Significance and Impact of the Study: This work demonstrates the specificity of the stress response, and the need to consider multiple environmental factors to meaningfully investigate tolerance. Both environmental and clinical settings subject bacteria to combinatorial stress and this should be considered in the design of further studies

The thermodynamics of and strengthening due to co-clusters: general theory and application to the case of Al-Cu-Mg alloys

Co-clusters in ternary or higher order metallic alloys are metastable structures involving two or more distinct alloying atoms that retain the structure of the host lattice. A thermodynamic model based on a single interaction energy of dissimilar nearest neighbour alloying elements is presented, and a model for the strengthening due to these co-cluster dimers is derived. The model includes a new treatment of (short-) order strengthening relevant to these co-clusters and further encompasses modulus hardening and chemical hardening. The models are tested against data on a wide range of Al-Cu-Mg alloys treated at temperatures between 20 and 220ºC. Both quantitative calorimetry data on the enthalpy change due to co-cluster formation and strengthening due to co-clusters is predicted well. It is shown that in general (short-range) order strengthening will be the main strengthening mechanism