Ectoine production through a marine methanotroph-microalgae culture allows complete biogas valorization
- Author
- Patricia Ruiz Ruiz (UGent) , Patricia Mohedano Caballero (UGent) and Jo De Vrieze (UGent)
- Organization
- Project
- Abstract
- Methanotrophs have recently emerged as a promising platform for producing bio-based chemicals, like ectoine, from biogas, offering an economical alternative to glucose. However, most studies have focused solely on CH4 consumption, often overlooking the CO2, which is both produced by methanotrophs and present in biogas, despite its potential as a carbon source for microorganisms, such as microalgae. In this study, marine methanotrophic-microalgal cultures were enriched from environmental samples collected at the North Sea coast to explore ectoine production from both CH4 and CO2 in biogas. The sediment-derived culture exhibited the highest CH4 removal efficiency and CO2 uptake, and was selected for further experiments. The culture was primarily composed of Methylobacter marinus, Methylophaga marina, and the microalga Picochlorum oklahomensis. Gas consumption, growth, and ectoine production were evaluated under varying salinity levels and osmotic stress. The NaCl concentrations above 6% negatively impacted CH4 oxidation and inhibited ectoine synthesis, while osmotic shocks enhanced ectoine accumulation, with a maximum ectoine content of 51.3 mgectoine gVSS 4.5% NaCl. This study is the first to report ectoine production from methanotroph-microalgal cultures, showing its potential for biogas valorization into high-value bio-based chemicals, like ectoine, marking a significant step toward sustainable biogas utilization.
- Keywords
- Biogas, Ectoine, Enrichment, GHG, Methane, Methanotrophs, Microalgae, PICOCHLORUM-OKLAHOMENSIS, METHYLOTROPHIC BACTERIA, METHANE OXIDATION, GROWTH, COCULTURE, EMISSIONS, ALGAE, WATER, STEP
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Citation
Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01JJC8W0BEWBWTZYZTA0E5F08M
- MLA
- Ruiz Ruiz, Patricia, et al. “Ectoine Production through a Marine Methanotroph-Microalgae Culture Allows Complete Biogas Valorization.” JOURNAL OF ENVIRONMENTAL MANAGEMENT, vol. 375, 2025, doi:10.1016/j.jenvman.2025.124223.
- APA
- Ruiz Ruiz, P., Mohedano Caballero, P., & De Vrieze, J. (2025). Ectoine production through a marine methanotroph-microalgae culture allows complete biogas valorization. JOURNAL OF ENVIRONMENTAL MANAGEMENT, 375. https://doi.org/10.1016/j.jenvman.2025.124223
- Chicago author-date
- Ruiz Ruiz, Patricia, Patricia Mohedano Caballero, and Jo De Vrieze. 2025. “Ectoine Production through a Marine Methanotroph-Microalgae Culture Allows Complete Biogas Valorization.” JOURNAL OF ENVIRONMENTAL MANAGEMENT 375. https://doi.org/10.1016/j.jenvman.2025.124223.
- Chicago author-date (all authors)
- Ruiz Ruiz, Patricia, Patricia Mohedano Caballero, and Jo De Vrieze. 2025. “Ectoine Production through a Marine Methanotroph-Microalgae Culture Allows Complete Biogas Valorization.” JOURNAL OF ENVIRONMENTAL MANAGEMENT 375. doi:10.1016/j.jenvman.2025.124223.
- Vancouver
- 1.Ruiz Ruiz P, Mohedano Caballero P, De Vrieze J. Ectoine production through a marine methanotroph-microalgae culture allows complete biogas valorization. JOURNAL OF ENVIRONMENTAL MANAGEMENT. 2025;375.
- IEEE
- [1]P. Ruiz Ruiz, P. Mohedano Caballero, and J. De Vrieze, “Ectoine production through a marine methanotroph-microalgae culture allows complete biogas valorization,” JOURNAL OF ENVIRONMENTAL MANAGEMENT, vol. 375, 2025.
@article{01JJC8W0BEWBWTZYZTA0E5F08M,
abstract = {{Methanotrophs have recently emerged as a promising platform for producing bio-based chemicals, like ectoine, from biogas, offering an economical alternative to glucose. However, most studies have focused solely on CH4 consumption, often overlooking the CO2, which is both produced by methanotrophs and present in biogas, despite its potential as a carbon source for microorganisms, such as microalgae. In this study, marine methanotrophic-microalgal cultures were enriched from environmental samples collected at the North Sea coast to explore ectoine production from both CH4 and CO2 in biogas. The sediment-derived culture exhibited the highest CH4 removal efficiency and CO2 uptake, and was selected for further experiments. The culture was primarily composed of Methylobacter marinus, Methylophaga marina, and the microalga Picochlorum oklahomensis. Gas consumption, growth, and ectoine production were evaluated under varying salinity levels and osmotic stress. The NaCl concentrations above 6% negatively impacted CH4 oxidation and inhibited ectoine synthesis, while osmotic shocks enhanced ectoine accumulation, with a maximum ectoine content of 51.3 mgectoine gVSS 4.5% NaCl. This study is the first to report ectoine production from methanotroph-microalgal cultures, showing its potential for biogas valorization into high-value bio-based chemicals, like ectoine, marking a significant step toward sustainable biogas utilization.}},
articleno = {{124223}},
author = {{Ruiz Ruiz, Patricia and Mohedano Caballero, Patricia and De Vrieze, Jo}},
issn = {{0301-4797}},
journal = {{JOURNAL OF ENVIRONMENTAL MANAGEMENT}},
keywords = {{Biogas,Ectoine,Enrichment,GHG,Methane,Methanotrophs,Microalgae,PICOCHLORUM-OKLAHOMENSIS,METHYLOTROPHIC BACTERIA,METHANE OXIDATION,GROWTH,COCULTURE,EMISSIONS,ALGAE,WATER,STEP}},
language = {{eng}},
pages = {{10}},
title = {{Ectoine production through a marine methanotroph-microalgae culture allows complete biogas valorization}},
url = {{http://doi.org/10.1016/j.jenvman.2025.124223}},
volume = {{375}},
year = {{2025}},
}
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