Methane oxidising bacteria to upcycle effluent streams from anaerobic digestion of municipal biowaste

Panagiotis Tsapekos; Benyamin Khoshnevisan; Xinyu Zhu; Xiao Zha; Irini Angelidaki

doi:10.1016/j.jenvman.2019.109590

Methane oxidising bacteria to upcycle effluent streams from anaerobic digestion of municipal biowaste

Panagiotis Tsapekos, Benyamin Khoshnevisan, Xinyu Zhu, Xiao Zha, Irini Angelidaki^*

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

Conventional microbial protein production relies on the usage of pure chemicals and gases. Natural gas, which is a fossil resource, is the common input gas for bacterial protein production. Alternative sources for gas feedstock and nutrients can sufficiently decrease the operational cost and environmental impact of microbial protein production processes. In the present study, the effluents streams of municipal biowaste anaerobic digestion, were used to grow methane oxidising bacteria which can be used as protein source. Results demonstrated that a 40:60 CH₄:O₂ (v/v) gas feeding resulted in microbial biomass production of 0.95 g-DM/L by a Methylophilus dominated community. When raw biogas was used as input for methane corresponding to the same initial methane partial pressure as before, instead of pure methane, the growth was partially hindered (0.61 g-DM/L) due to the presence of H₂S (IC₅₀: 1376 ppm). Hence, desulfurization is suggested before using biogas for microbial protein production. At semi-continuous mode, results showed that the produced biomass had relatively high protein content (>40% of dry weight) and the essential amino acids lysine, valine, leucine and histidine were detected at high levels.

Original language	English
Article number	109590
Journal	Journal of Environmental Management
Volume	251
ISSN	0301-4797
DOIs	https://doi.org/10.1016/j.jenvman.2019.109590
Publication status	Published - 1. Dec 2019
Externally published	Yes

Bibliographical note

Funding Information:
We acknowledge support from FUBAF project financed by the Danish EPA - MUDP (J.nr. Mst-11700508). The authors thank Esben Frimann Jensen and Jacob Gavnholt Dueholm for assistance with experimental works conducted in the study.

Funding Information:
We acknowledge support from FUBAF project financed by the Danish EPA - MUDP (J.nr. Mst-11700508 ). The authors thank Esben Frimann Jensen and Jacob Gavnholt Dueholm for assistance with experimental works conducted in the study.

Publisher Copyright:
© 2019 Elsevier Ltd

Keywords

16S rRNA
Digestate
Methanotrophs
Mixed culture
Municipal biowaste

Documents & Links

10.1016/j.jenvman.2019.109590

Cite this

@article{7e84988434c94455acc090f33545ef06,

title = "Methane oxidising bacteria to upcycle effluent streams from anaerobic digestion of municipal biowaste",

abstract = "Conventional microbial protein production relies on the usage of pure chemicals and gases. Natural gas, which is a fossil resource, is the common input gas for bacterial protein production. Alternative sources for gas feedstock and nutrients can sufficiently decrease the operational cost and environmental impact of microbial protein production processes. In the present study, the effluents streams of municipal biowaste anaerobic digestion, were used to grow methane oxidising bacteria which can be used as protein source. Results demonstrated that a 40:60 CH4:O2 (v/v) gas feeding resulted in microbial biomass production of 0.95 g-DM/L by a Methylophilus dominated community. When raw biogas was used as input for methane corresponding to the same initial methane partial pressure as before, instead of pure methane, the growth was partially hindered (0.61 g-DM/L) due to the presence of H2S (IC50: 1376 ppm). Hence, desulfurization is suggested before using biogas for microbial protein production. At semi-continuous mode, results showed that the produced biomass had relatively high protein content (>40% of dry weight) and the essential amino acids lysine, valine, leucine and histidine were detected at high levels.",

keywords = "16S rRNA, Digestate, Methanotrophs, Mixed culture, Municipal biowaste",

author = "Panagiotis Tsapekos and Benyamin Khoshnevisan and Xinyu Zhu and Xiao Zha and Irini Angelidaki",

note = "Funding Information: We acknowledge support from FUBAF project financed by the Danish EPA - MUDP (J.nr. Mst-11700508). The authors thank Esben Frimann Jensen and Jacob Gavnholt Dueholm for assistance with experimental works conducted in the study. Funding Information: We acknowledge support from FUBAF project financed by the Danish EPA - MUDP (J.nr. Mst-11700508 ). The authors thank Esben Frimann Jensen and Jacob Gavnholt Dueholm for assistance with experimental works conducted in the study. Publisher Copyright: {\textcopyright} 2019 Elsevier Ltd",

year = "2019",

month = dec,

day = "1",

doi = "10.1016/j.jenvman.2019.109590",

language = "English",

volume = "251",

journal = "Journal of Environmental Management",

issn = "0301-4797",

publisher = "Heinemann",

}

TY - JOUR

T1 - Methane oxidising bacteria to upcycle effluent streams from anaerobic digestion of municipal biowaste

AU - Tsapekos, Panagiotis

AU - Khoshnevisan, Benyamin

AU - Zhu, Xinyu

AU - Zha, Xiao

AU - Angelidaki, Irini

N1 - Funding Information: We acknowledge support from FUBAF project financed by the Danish EPA - MUDP (J.nr. Mst-11700508). The authors thank Esben Frimann Jensen and Jacob Gavnholt Dueholm for assistance with experimental works conducted in the study. Funding Information: We acknowledge support from FUBAF project financed by the Danish EPA - MUDP (J.nr. Mst-11700508 ). The authors thank Esben Frimann Jensen and Jacob Gavnholt Dueholm for assistance with experimental works conducted in the study. Publisher Copyright: © 2019 Elsevier Ltd

PY - 2019/12/1

Y1 - 2019/12/1

N2 - Conventional microbial protein production relies on the usage of pure chemicals and gases. Natural gas, which is a fossil resource, is the common input gas for bacterial protein production. Alternative sources for gas feedstock and nutrients can sufficiently decrease the operational cost and environmental impact of microbial protein production processes. In the present study, the effluents streams of municipal biowaste anaerobic digestion, were used to grow methane oxidising bacteria which can be used as protein source. Results demonstrated that a 40:60 CH4:O2 (v/v) gas feeding resulted in microbial biomass production of 0.95 g-DM/L by a Methylophilus dominated community. When raw biogas was used as input for methane corresponding to the same initial methane partial pressure as before, instead of pure methane, the growth was partially hindered (0.61 g-DM/L) due to the presence of H2S (IC50: 1376 ppm). Hence, desulfurization is suggested before using biogas for microbial protein production. At semi-continuous mode, results showed that the produced biomass had relatively high protein content (>40% of dry weight) and the essential amino acids lysine, valine, leucine and histidine were detected at high levels.

AB - Conventional microbial protein production relies on the usage of pure chemicals and gases. Natural gas, which is a fossil resource, is the common input gas for bacterial protein production. Alternative sources for gas feedstock and nutrients can sufficiently decrease the operational cost and environmental impact of microbial protein production processes. In the present study, the effluents streams of municipal biowaste anaerobic digestion, were used to grow methane oxidising bacteria which can be used as protein source. Results demonstrated that a 40:60 CH4:O2 (v/v) gas feeding resulted in microbial biomass production of 0.95 g-DM/L by a Methylophilus dominated community. When raw biogas was used as input for methane corresponding to the same initial methane partial pressure as before, instead of pure methane, the growth was partially hindered (0.61 g-DM/L) due to the presence of H2S (IC50: 1376 ppm). Hence, desulfurization is suggested before using biogas for microbial protein production. At semi-continuous mode, results showed that the produced biomass had relatively high protein content (>40% of dry weight) and the essential amino acids lysine, valine, leucine and histidine were detected at high levels.

KW - 16S rRNA

KW - Digestate

KW - Methanotrophs

KW - Mixed culture

KW - Municipal biowaste

U2 - 10.1016/j.jenvman.2019.109590

DO - 10.1016/j.jenvman.2019.109590

M3 - Journal article

C2 - 31550605

AN - SCOPUS:85072312820

SN - 0301-4797

VL - 251

JO - Journal of Environmental Management

JF - Journal of Environmental Management

M1 - 109590

ER -

Methane oxidising bacteria to upcycle effluent streams from anaerobic digestion of municipal biowaste

Abstract

Bibliographical note

Keywords

Documents & Links

Fingerprint

Cite this