Comparative Bioremediation of Tetradecane, Cyclohexanone and Cyclohexane by Filamentous Fungi from Polluted Habitats in Kazakhstan-Reference-Cited by-同舟云学术

Comparative Bioremediation of Tetradecane, Cyclohexanone and Cyclohexane by Filamentous Fungi from Polluted Habitats in Kazakhstan

Published:2024-06-19 Issue:6 Volume:10 Page:436
ISSN:2309-608X
Container-title:Journal of Fungi
language:en
Short-container-title:JoF

Author:

Gaid Mariam¹^ORCID,Jentzsch Wiebke¹,Beermann Hannah¹,Reinhard Anne¹,Meister Mareike²,Berzhanova Ramza³,Mukasheva Togzhan³,Urich Tim¹^ORCID,Mikolasch Annett¹^ORCID

Affiliation:

1. Institute of Microbiology, University Greifswald, Felix-Hausdorff-Straße 8, 17489 Greifswald, Germany

2. Leibniz Institute for Plasma Science and Technology (INP), Felix-Hausdorff-Str. 2, 17489 Greifswald, Germany

3. Department of Biology and Biotechnology, Al-Farabi Kazakh National University, Al-Farabi Ave 71, Almaty 050040, Kazakhstan

Abstract

Studying the fates of oil components and their interactions with ecological systems is essential for developing comprehensive management strategies and enhancing restoration following oil spill incidents. The potential expansion of Kazakhstan’s role in the global oil market necessitates the existence of land-specific studies that contribute to the field of bioremediation. In this study, a set of experiments was designed to assess the growth and biodegradation capacities of eight fungal strains sourced from Kazakhstan soil when exposed to the hydrocarbon substrates from which they were initially isolated. The strains were identified as Aspergillus sp. SBUG-M1743, Penicillium javanicum SBUG-M1744, SBUG-M1770, Trichoderma harzianum SBUG-M1750 and Fusarium oxysporum SBUG-1746, SBUG-M1748, SBUG-M1768 and SBUG-M1769 using the internal transcribed spacer (ITS) region. Furthermore, microscopic and macroscopic evaluations agreed with the sequence-based identification. Aspergillus sp. SBUG-M1743 and P. javanicum SBUG-M1744 displayed remarkable biodegradation capabilities in the presence of tetradecane with up to a 9-fold biomass increase in the static cultures. T. harzianum SBUG-M1750 exhibited poor growth, which was a consequence of its low efficiency of tetradecane degradation. Monocarboxylic acids were the main degradation products by SBUG-M1743, SBUG-M1744, SBUG-M1750, and SBUG-M1770 indicating the monoterminal degradation pathway through β-oxidation, while the additional detection of dicarboxylic acid in SBUG-M1768 and SBUG-M1769 cultures was indicative of the fungus’ ability to undertake both monoterminal and diterminal degradation pathways. F. oxysporum SBUG-M1746 and SBUG-M1748 in the presence of cyclohexanone showed a doubling of the biomass with the ability to degrade the substrate almost completely in shake cultures. F. oxysporum SBUG-M1746 was also able to degrade cyclohexane completely and excreted all possible metabolites of the degradation pathway. Understanding the degradation potential of these fungal isolates to different hydrocarbon substrates will help in developing effective bioremediation strategies tailored to local conditions.

Publisher

MDPI AG

Link

https://www.mdpi.com/2309-608X/10/6/436/pdf

Reference77 articles.

1. Satubaldina, A. (2023, November 30). Bringing Kazakhstan to the World: Strategic Partnership, Energy Security: Macron’s Visit to Kazakhstan Redefines Bilateral Ties. Available online: https://astanatimes.com/2023/11/strategic-partnership-energy-security-macrons-visit-to-kazakhstan-redefines-bilateral-ties/.

2. Zabanova, Y., Williams, S., Andresh, M., Melnikov, Y., and Tumysheva, A. EU-Kazakhstan Green Hydrogen Partnership, Mapping Barriers and Establishing a Roadmap. EPICO KlimaInnovation (Energy and Climate Policy and Innovation Council e.V.). Available online: https://www.kas.de/documents/d/guest/eu-kazakhstan-green-hydrogen-partnership.

3. Statista (2023, November 30). Primary Energy Consumption Worldwide from 2019 to 2022, by Fuel Type. Available online: https://www.statista.com/statistics/265619/primary-energy-consumption-worldwide-by-fuel/.

4. Papita, D., Suvendu, M., and Jitendra, K.P. (2022). Chapter 7—Impact of oil exploration and spillage on marine environments. Advances in Oil-Water Separation, Elsevier.

5. Zhuang, J., Zhang, R., Zeng, Y., Dai, T., Ye, Z., Gao, Q., Yang, Y., Guo, X., Li, G., and Zhou, J. (2023). Petroleum pollution changes microbial diversity and network complexity of soil profile in an oil refinery. Front. Microbiol., 14.