Responses of mixed methanotrophic consortia to variable Cu2+/Fe2+ ratios

Chidambarampadmavathy, Karthigeyan, Obulisamy, Karthigeyan, Huerlimann, Roger, Maes, Gregory. E., and Heimann, Kirsten (2017) Responses of mixed methanotrophic consortia to variable Cu2+/Fe2+ ratios. Journal of Environmental Management, 197. pp. 159-166.

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Abstract

Methane mitigation in landfill top cover soils is mediated by methanotrophs whose optimal methane (CH4) oxidation capacity is governed by environmental and complex microbial community interactions. Optimization of CH4 remediating bio-filters need to take microbial responses into account. Divalent copper (Cu2+) and iron (Fe2+) are present in landfills at variable ratios and play a vital role in methane oxidation capacity and growth of methanotrophs. This study, as a first of its kind, therefore quantified effects of variable Cu2+ and Fe2+ (5:5, 5:25 and 5:50 mu M) ratios on mixed methanotrophic communities enriched from landfill top cover (LB) and compost soils (CB). CH4 oxidation capacity, CH4 removal efficiencies, fatty acids content/profiles and polyhydroxybutyrate (PHB; a biopolymer) contents were also analysed to quantify performance and potential co-product development. Mixed methanotroph cultures were raised in 10 L continuous stirred tank reactors (CSTRs, Bioflo (R) & Celligen (R) 310 Fermentor/Bioreactor; John Morris Scientific, Chatswood, NSW, Australia). Community structure was determined by amplifying the V3-V4 region of 16s rRNA gene. Community structure and, consequently, fatty acid profiles changed significantly with increasing Cu2+/Fe2+ ratios, and responses were different for LB and CB. Effects on methane oxidation capacities and PHB content were similar in the LB-and CB-CSTR, decreasing with increasing Cu2+/Fe2+ ratios, while biomass growth was unaffected. In general, high Fe2+ concentration favored growth of the type-II methanotroph Methylosinus in the CB-CSTR, but methanotroph abundances decreased in the LB-CSTR. Increase in Cu2+/Fe2+ ratio increased the growth of Sphingopyxis in both systems, while Azospirlium was co-dominant in the LB-but absent in the CB-CSTR. After 13 days, methane oxidation capacities and PHB content decreased by similar to 50% and more in response to increasing Fe2+ concentrations. Although methanotroph abundance was similar to 2% in the LB-(compared to >50% in CB-CSTR), methane oxidation capacities were comparable in the two systems, suggesting that methane oxidation capacity was maintained by the dominant Azospirllum and Sphingopyxis in the LBCSTR. Despite similar methanotroph inoculum community composition and controlled environmental variables, increasing Cu2+/Fe2+ ratios resulted in significantly different microbial community, structures in the LB-and CB-CSTR, indicative of complex microbial interactions. In summary, our results suggest that a detailed understanding of allelopathic interactions in mixed methanotrophic consortia is vital for constructing robust bio-filters for CH4 emission abatement.

Item ID: 50586
Item Type: Article (Research - C1)
ISSN: 1095-4797
Keywords: methane, methanotrophs, biopolymers, heavy metal, bioreactor, microbial community
Funders: Advanced Manufacturing Cooperative Research Centre (AMCRC)
Projects and Grants: AMCRC grant number 2.3.4
Date Deposited: 20 Sep 2017 10:13
FoR Codes: 31 BIOLOGICAL SCIENCES > 3107 Microbiology > 310704 Microbial genetics @ 50%
31 BIOLOGICAL SCIENCES > 3107 Microbiology > 310703 Microbial ecology @ 50%
SEO Codes: 96 ENVIRONMENT > 9606 Environmental and Natural Resource Evaluation > 960699 Environmental and Natural Resource Evaluation not elsewhere classified @ 100%
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