UTFacultiesTNWResearchDept MSTMPTResearchCompleted projectsRemoving toxic micropollutants from wastewater with funghi

Removing toxic micropollutants from wastewater with funghi

BRIGIT VAN BRENK (UU/UT)

PhD project

Supervisors: Han Wösten (UU), Walter van der Meer (Oasen/UT)

Duration: 2018-2022

Funded by NWO and Oasen

Micropollutants that are present in surface water bodies have high risk for the environment. These toxic compounds originate from industrial and agricultural activities and activities of individuals. They include heavy metals and polycyclic aromatic hydrocarbons (PAHs) such as industrial chemicals, dyes, pesticides, pharmaceuticals, personal care products, and steroid hormones. Removing micropollutants from waste water helps to protect nature and the human population. Current waste water treatment plants (WWTPs) are not able to degrade these micropollutants effectively. They are therefore removed by reverse osmose filtration (RO) to produce drinking water [1-3]. This results in a waste stream with a 3-5 fold higher concentration of micropollutants and ammonium. This concentrate is returned to WWTPs and finally, is returned to surface water bodies. Here, we aim to purify RO waste water from micropollutants using the mycelium of mushroom forming white rot fungi (WRFs). 

WRF are main contributors of carbon cycling in nature by degrading the highly recalcitrant lignin in plant waste. Lignin, the second most abundant natural polymer after cellulose, consists of complex PAHs that are degraded by WRFs by secreting lignin oxidases (LO family) and lignin-degrading auxiliary enzymes (LDA family). These oxidizing enzymes can also degrade other PAHs, including micropollutants [4-6]. Yet, it is not clear which individual enzymes are responsible for degradation of each PAH. Notably, WRF also adsorb and accumulate heavy metals. The resistance to these toxic compounds differs between species and the underlying mechanism(s) are poorly understood [7-9]. 

Apart from micropollutants, water needs to be purified from ammonium (NH4+). It promotes growth of algae and duckweed and thereby affects biodiversity. Moreover, NH4can dissociate in NHand H+. NHcan be toxic for instance for fish [10]. Since fungi can use ammonium as nitrogen source, detoxification of micropollutants can be combined with conversion of ammonium in biomass. This could thus be a positive side effect of the purification from micropollutants.

In this project, we will systematically assess the degrading and sorbing activities of micropollutants by mushroom forming WRFs and will for the first time study the molecular mechanisms that explain the differences in these activities between these fungi. Knowledge of these mechanisms will enable us to design a water purification system.

The project is funded by the Dutch water company Oasen and Utrecht University.

Defense date: Wednesday, January 10th 2024, 14:15, Academiegebouw, Domplein 29, Utrecht.

Publications

Brigit van Brenk, Han A.B. Wösten, A screening method for decoloration of xenobiotic dyes by fungi, J. Microbiol. Methods, 188 (2021), 106301, https://doi.org/10.1016/j.mimet.2021.106301

References

1.         Richardson, S. D. & Kimura, S. Y., Water Analysis: Emerging Contaminants and Current Issues. (2016).

2.         Radjenovic, J., Petrovic, M., Ventura, F. & Barcelo, D., Rejection of pharmaceuticals in nanofiltration and reverse osmosis membrane drinking water treatment. Water Res. 42, 3601–3610 (2008).

3.         Luo, Y. et al., Science of the Total Environment A review on the occurrence of micropollutants in the aquatic environment and their fate and removal during wastewater treatment. Sci. Total Environ. 473–474, 619–641 (2014).

4.         Kirk, T. K. & Farrell, R. L., Enzymatic ‘ combustion ’: the microbial degradation of lignin. Microbiology 465–505 (1987).

5.         Martínez, Á. T. et al. Biodegradation of lignocellulosics: Microbial, chemical, and enzymatic aspects of the fungal attack of lignin. Int. Microbiol. 8, 195–204 (2005).

6.         Wesenberg, D., Kyriakides, I. & Agathos, S. N., White-rot fungi and their enzymes for the treatment of industrial dye effluents. Biotechnol. Adv. 22, 161–187 (2003).

7.         Sanglimsuwan, S., Yoshida, N., Morinaga, T. & Murooka, Y., Resistance to and uptake of heavy metals in mushrooms. J. Ferment. Bioeng. 75, 112–114 (1993).

8.         Palmans, E., Mares, G., Poppe, J. & Höfte, M., Biodegradation of xenobiotics by heavy metal resistant higher fungi. Ninth Forum Appl. Biotechnol. Proceeding, 2593 (1995).

9.         Wang, J. & Chen, C., Biosorbents for heavy metals removal and their future. Biotechnol. Adv. 27, 195–226 (2009).

10.       Veeningen, R., Is ammoniak een probleem in het oppervlaktewater? Juni, 28–31 (2017).