格氏地杆菌——种间电子直接转移形成共培养的新电子供体

IF 2.1 Q3 MICROBIOLOGY Microbiology Research Pub Date : 2023-11-02 DOI:10.3390/microbiolres14040122
Panbo Deng, Lulu Wang, Xia Li, Jinshan Zhang, Haiming Jiang
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引用次数: 0

摘要

格氏地杆菌可以通过乙醇的偶联氧化来还原各种形式的可溶性铁(III)和低结晶性铁(III)氧化物,这表明格氏地杆菌可以作为电子供体微生物,通过直接种间电子转移(DIET)形成共培养物。在本报告中,研究了grbiciae和Methanosarcina barkeri 800、G. sulfreducens Δhyb或Methanospirillum hungatei作为电子受体微生物的潜在共培养。G. grbiciae和G.硫还原菌Δhyb在颗粒活性炭(GAC)、磁铁矿或聚酯毡的存在下,以乙醇作为唯一的电子供体物质,富马酸盐作为电子受体物质进行共培养。G. grbiciae和M. barkeri 800(或M. hungatei)共培养条件与G. grbiciae和G.硫还原菌Δhyb相同,但不含富马酸,培养温度不同。所有共培养均为厌氧培养。定期从共培养物中提取样品,通过气相或高效液相色谱法监测甲烷、富马酸盐和琥珀酸盐。G. grbiciae在GAC或磁铁矿存在下与M. barkeri 800形成功能性共培养。没有观察到G. grbiciae与利用H2/甲酸的甲烷菌M. hungatei共培养。此外,在不添加GAC或磁铁矿的情况下,G. grbiciae与H2/甲酸未利用的G. sulphreducens Δhyb形成功能性共培养。这些结果表明G. grbiciae和M. barkeri之间的电子转移量为800/G。硫还原菌Δhyb是通过DIET而不是H2/甲酸,证实G. grbiciae作为电子供体微生物。虽然G. grbiciae和M. barkeri 800共培养通过DIET将乙醇同步转化为甲烷,但未观察到丙酸盐或丁酸盐转化为甲烷。这些发现扩大了微生物的范围,这些微生物可以作为电子供体,通过DIET与其他微生物相互作用。然而,以甲烷为产物的混合微生物群落通过DIET代谢丙酸盐和丁酸盐的情况需要进一步分析。这项研究为寻找新的电子供体微生物提供了一个框架。
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Geobacter grbiciae—A New Electron Donor in the Formation of Co-Cultures via Direct Interspecies Electron Transfer
Geobacter grbiciae can grow via coupling oxidation of ethanol to the reduction of various forms of soluble Fe(III) and poorly crystalline Fe(III) oxide, suggesting that G. grbiciae can act as an electron-donor microbe for forming co-cultures through direct interspecies electron transfer (DIET). In this report, potential co-cultures through DIET of G. grbiciae and Methanosarcina barkeri 800, G. sulfurreducens Δhyb, or Methanospirillum hungatei, as electron-acceptor microbes, were examined. Co-cultures of G. grbiciae and G. sulfurreducens Δhyb were performed with ethanol as the sole electron-donor substance and fumarate as the electron-acceptor substance in the presence of granular activated carbon (GAC), magnetite, or polyester felt. The conditions for co-culturing G. grbiciae and M. barkeri 800 (or M. hungatei) were the same as those for G. grbiciae and G. sulfurreducens Δhyb, except fumarate was absent and different cultivation temperatures were used. All co-cultures were anaerobically cultivated. Samples were regularly withdrawn from the co-cultures to monitor methane, fumarate, and succinate via gas or high-performance liquid chromatography. G. grbiciae formed functional co-cultures with M. barkeri 800 in the presence of GAC or magnetite. No co-culture of G. grbiciae with the H2/formate-utilizing methanogen M. hungatei was observed. Additionally, G. grbiciae formed functional co-cultures with H2/formate-un-utilizing G. sulfurreducens Δhyb without the GAC or magnetite supplement. These findings indicate electron transfer between G. grbiciae and M. barkeri 800/G. sulfurreducens Δhyb is via DIET rather than H2/formate, confirming that G. grbiciae acts as an electron-donor microbe. Although the co-cultures of G. grbiciae and M. barkeri 800 syntrophically converted ethanol to methane through DIET, the conversion of propionate or butyrate to methane was not observed. These findings expand the range of microbes that can act as electron donors for interaction with other microbes through DIET. However, propionate and butyrate metabolism through DIET in mixed microbial communities with methane as a product requires further analysis. This study provides a framework for finding new electron-donor microbes.
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来源期刊
Microbiology Research
Microbiology Research MICROBIOLOGY-
CiteScore
1.90
自引率
6.70%
发文量
62
审稿时长
10 weeks
期刊介绍: Microbiology Research is an international, online-only, open access peer-reviewed journal which publishes original research, review articles, editorials, perspectives, case reports and brief reports to benefit researchers, microbiologists, physicians, veterinarians. Microbiology Research publishes ‘Clinic’ and ‘Research’ papers divided into two different skill and proficiency levels: ‘Junior’ and ‘Professional’. The aim of this four quadrant grid is to encourage younger researchers, physicians and veterinarians to submit their results even if their studies encompass just a limited set of observations or rely on basic statistical approach, yet upholding the customary sound approach of every scientific article.
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