AUTHOR=Liu Bin , Kleinsteuber Sabine , Centler Florian , Harms Hauke , Sträuber Heike 

TITLE=Competition Between Butyrate Fermenters and Chain-Elongating Bacteria Limits the Efficiency of Medium-Chain Carboxylate Production

JOURNAL=Frontiers in Microbiology

VOLUME=11

YEAR=2020

URL=https://www.frontiersin.org/journals/microbiology/articles/10.3389/fmicb.2020.00336

DOI=10.3389/fmicb.2020.00336

ISSN=1664-302X

ABSTRACT=<p>Medium-chain carboxylates such as <italic>n</italic>-caproate and <italic>n</italic>-caprylate are valuable chemicals, which can be produced from renewable feedstock by anaerobic fermentation and lactate-based microbial chain elongation. Acidogenic microbiota involved in lactate-based chain elongation and their interplay with lactic acid bacteria have not been characterized in detail yet. Here, the metabolic and community dynamics were studied in a continuous bioreactor with xylan and lactate as sole carbon sources. Four succession stages were observed during 148 days of operation. After an adaptation period of 36 days, a relatively stable period of 28 days (stage I) was reached with <italic>n-</italic>butyrate, <italic>n-</italic>caproate and <italic>n-</italic>caprylate productivities of 7.2, 8.2 and 1.8 gCOD L<sup>–1</sup> d<sup>–1</sup>, respectively. After a transition period, the process changed to another period (stage II), during which 46% more <italic>n-</italic>butyrate, 51% less <italic>n-</italic>caproate and 67% less <italic>n-</italic>caprylate were produced. Co-occurrence networks of species based on 16S rRNA amplicon sequences and correlations with process parameters were analyzed to infer ecological interactions and potential metabolic functions. Diverse functions including hydrolysis of xylan, primary fermentation of xylose to acids (e.g., to acetate by <italic>Syntrophococcus</italic>, to <italic>n-</italic>butyrate by <italic>Lachnospiraceae</italic>, and to lactate by <italic>Lactobacillus</italic>) and chain-elongation with lactate (by <italic>Ruminiclostridium</italic> 5 and <italic>Pseudoramibacter</italic>) were inferred from the metabolic network. In stage I, the sub-network characterized by strongest positive correlations was mainly related to the production of <italic>n-</italic>caproate and <italic>n-</italic>caprylate. Lactic acid bacteria of the genus <italic>Olsenella</italic> co-occurred with potentially chain-elongating bacteria of the genus <italic>Pseudoramibacter</italic>, and their abundance was positively correlated with <italic>n-</italic>caproate and <italic>n-</italic>caprylate concentrations. A new sub-network appeared in stage II, which was mainly related to <italic>n-</italic>butyrate production and revealed a network of different lactic acid bacteria (<italic>Bifidobacterium</italic>) and potential <italic>n-</italic>butyrate producers (<italic>Clostridium sensu stricto</italic> 12). The synergy effects between lactate-producing and lactate-consuming bacteria constitute a division of labor cooperation of mutual benefit. Besides cooperation, competition between different taxa determined the bacterial community assembly over the four succession stages in this resource-limited system. During long-term reactor operation under constant conditions, chain-elongating bacteria were outcompeted by butyrate-producing bacteria, leading to the increase of <italic>n-</italic>butyrate yield at the cost of medium-chain carboxylate yields in this closed model system.</p>