Stratified Microbial Structure and Activity in Sulfide- and Methane-Producing Anaerobic Sewer Biofilms

Sun, Jing; Hu, Shihu; Sharma, Keshab; Ni, Bing‐Jie; Yuan, Zhiguo

doi:10.1128/aem.02146-14

Cited by 103 publications

(50 citation statements)

References 66 publications

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“…200-500 mg COD/L) for both SRB and MA to co-exist in sewer biofilms, thereby allowing simultaneous methane and sulfide production despite their competition for substrates (Conrad et al, 1987, Raskin et al, 1996, Robinson and Tiedje, 1984. This co-existence is due to stratification of these anaerobic microorganisms in the biofilm (Guisasola et al, 2008, Sun et al, 2014. SRB are found to dominate the microbial community in the top layers of the biofilms where the sulfate concentration is relatively high ( Fig.…”

Section: Methanobaceriales Methanococcales Methanomicrobiales Methmentioning

confidence: 99%

“…MA of the Methanosataceae, Methanomicrobiales, Methanosarcinaceae, Methanococcales and Methanocaldococcaceae are detected in rising main sewer biofilms while Methanobacteriales is absent (Mohanakrishnan et al, 2009b). In a recent study of a sewer rising main biofilm it was found that 90% of the MA population belonged to the genus Methanosaeta, and these are obligate acetoclastic methanogens (Sun et al, 2014). MA that use other substrates such as hydrogen only accounted for less than 10% of the total MA population in the sewer biofilm.…”

Section: Methanobaceriales Methanococcales Methanomicrobiales Methmentioning

confidence: 99%

“…2.2). However, MA require low-sulfate conditions, and absence of sulfate in the deeper layers of biofilms due to the diffusional limitation of sulfate combined with an adequate supply of methanogenesis precursors promotes its growth (Guisasola et al, 2008, Sun et al, 2014. …”

Section: Methanobaceriales Methanococcales Methanomicrobiales Methmentioning

confidence: 99%

“…Over the years, most of the studies on sulfide and methane production in sewers have focused on sewer biofilms, particularly those in rising mains , Sun et al, 2014. These studies demonstrated that both sulfide and methane are generated in significant amounts from biofilms in anaerobic rising main sewers due to the biological sulfate reduction process mediated by sulfate reducing bacteria (SRB) and methanogenesis mediated by methanogenic archaea (MA) within the sewer biofilms that are attached to the walls of rising mains.…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies have identified rising main sewers as a source of hydrogen sulfide and methane (Boon, 1995, Guisasola et al, 2008. Sulfate-reducing bacteria (SRB) and methanogenic archaea (MA) that grow in the biofilm attached to the inner surfaces of sewer walls are primarily responsible for sulfide and methane production in rising main sewers (Foley et al, 2009, Guisasola et al, 2008, Sun et al, 2014. Sediment in gravity sewers is also believed to be biologically active (Schmitt and Seyfried, 1992), and thus could contribute to sulfide and methane production.…”

Section: Introductionmentioning

confidence: 99%

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Measurement and understanding of methane emission from sewers

Liu¹

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Sewer emissions are a notorious problem that water utilities have to deal with. The production and emission of hydrogen sulfide is a well-known problem for decades, which is the primary cause of sewer odors and corrosion. However, hydrogen sulfide is not the only harmful emission from sewer networks. Methane can also be generated in sewers through methanogenesis. Methane is a highly potent greenhouse gas, which is significantly contributing to climate change. Over a 100-year horizon, 1 ton of CH 4 will induce a warming effect equivalent to 34 tons of CO 2 . It is also explosive with a lower explosive limit (LEL) of approximately 5% by volume, and thus poses a serious safety issue. Currently, very little attention has been paid to methane formation in sewer networks.Therefore, the overall aim of this thesis is to measure and understand methane emission from sewers.The limited studies conducted so far on methane measurement in both gas and liquid phases in sewers have relied on manual sampling followed by off-line laboratory-based chromatography analysis. These methods are labor-intensive when measuring methane emissions from a large number of sewers, and do not capture the dynamic variations in methane production.Therefore, the suitability of infrared (IR) spectroscopy-based online methane gas sensors for measuring methane in humid sewer air was investigated in both laboratory and field conditions. Under certain circumstances, humidity could become an issue, however, this can be solved by removing the humidity on the sensor probe surface. Also, IR sensors exhibit excellent linearity and can be applied with factory calibration. Furthermore, the detection limit of sensors is suitable for measuring methane gas in sewers. Field application of the sensors revealed that methane concentrations in sewer air are 3 -4 orders of magnitude higher than in the atmosphere, confirming that sewers are a source of methane. The continuous measurement also revealed that methane concentrations in sewer are highly dynamic.Complementary to the gas phase sensors, a new dissolved methane sensor was developed in this thesis. This device uses an online IR gas-phase methane sensor to measure methane under equilibrium conditions in a stripping chamber. The measured gaseous methane levels were then II converted to liquid-phase methane concentrations according to Henry's Law. The detection limit and range was noted to be suitable for sewer applications. Good linearity was also obtained during Contributions of sediments in gravity sewers to overall sewer emissions are poorly understood at present. Sediments collected from a gravity sewer were cultivated in a laboratory reactor fed with real wastewater for more than one year to obtain intact sediments for the study. Batch test results clearly showed significant sulfide and methane production from sewer sediments. Microsensor and pore water measurements of sulfide, sulfate and methane in the sediments, microbial community profiling along the depth of the sediments and mathematical modelli...

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Section: Methanobaceriales Methanococcales Methanomicrobiales Methmentioning

confidence: 99%

Section: Methanobaceriales Methanococcales Methanomicrobiales Methmentioning

confidence: 99%

Section: Methanobaceriales Methanococcales Methanomicrobiales Methmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Measurement and understanding of methane emission from sewers

Liu¹

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D esulfatiferula

Galushko¹,

Kuever²

2019

Bergey's Manual of Systematics of Archaea and Bacteria

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De.sul.fa.ti.fe'ru.la. L. pref. de , from; N.L. n. sulfas ‐atis , sulfate; L. fem. n. ferula , a staff, a small rod; N.L. fem. n. Desulfatiferula , a rod‐shaped sulfate‐reducer. Desulfobacterota / Desulfobacteria / Desulfobacterales / Desulforegulaceae / Desulfatiferula Curved rods, 0.45–0.6 µm × 0.8–5.0 µm. Occur singly or in pairs. Spore formation is not observed. Gram‐stain‐negative. Motile. Strictly anaerobic, having a respiratory and sometimes fermentative type of metabolism. Chemoorganoheterotrophs, using short and long straight‐chain fatty acids and alkenes as carbon sources and electron donors. Long straight‐chain organic electron donors with even number of carbon atons are incompletely oxidized to acetate. One species can grow chemolithoautotrophically on H 2 + CO 2 without acetate. Sulfate serves as terminal electron acceptor for all species and is reduced to H 2 S. Fermentative growth on pyruvate might occur. Mesophilic. Neutrophilic. Optimal growth temperature 30–32°C. Media containing a reductant are necessary for growth. Vitamins are required for growth of one species. The genus Desulfatiferula contains two described species. Desulfatiferula species occur in anoxic sediments of freshwater, brackish, and marine habitats. DNA G + C content (mol%) : 45.5–50.2 (LC). Type species : Desulfatiferula olefinivorans Cravo‐Laureau, Labat, Joulian, Matheron and Hirschler‐Rea 2007, 2701 VP .

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D esulforegula

Galushko¹,

Kuever²

2019

Bergey's Manual of Systematics of Archaea and Bacteria

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De.sul.fo.re'gu.la. L. pref. de from; L. neut. n. sulfur sulfur; N.L. pref. desulfo ‐, desulfuricating (prefix used to characterize a dissimilatory sulfate‐reducing procaryote); L. fem. n. regula a straight piece of wood or ruler; N.L. fem. n. Desulforegula a sulfate‐reducing bacterium shaped like a ruler. Desulfobacterota / Desulfobacteria / Desulfobacterales / Desulforegulaceae / Desulforegula Rod‐shaped cells, 1–1.3 µm × 2.6–3.0 µm. Occur singly or in pairs. Spore formation is not observed. Gram‐stain‐negative. Motile. Strictly anaerobic, having a respiratory type of metabolism. Chemoorganoheterotrophs, using C 4 –C 17 straight‐chain fatty acids as carbon sources and electron donors; the ones with an even number of carbon atoms were oxidized to acetate and electron donors with an odd number of carbon atoms were oxidized to acetate and propionate. No other substrates known. Sulfate serves as terminal electron acceptor and is reduced to H 2 S. Sulfite, thiosulfate, and nitrate are not used as a terminal electron acceptors. Mesophilic. Neutrophilic. Optimal growth temperature, 25–30°C. Media containing a reductant and vitamins are necessary for growth. The genus Desulforegula contains one described species and occurs in anoxic freshwater sediments. DNA G + C content (mol%) : 42.4 (genome). Type species : Desulforegula conservatrix Rees and Patel 2001, 1915 VP .

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Stratified Microbial Structure and Activity in Sulfide- and Methane-Producing Anaerobic Sewer Biofilms

Cited by 103 publications

References 66 publications

Measurement and understanding of methane emission from sewers

Measurement and understanding of methane emission from sewers

D esulfatiferula

D esulforegula

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