Community and Proteomic Analysis of Methanogenic Consortia Degrading Terephthalate

Wu, Jer Horng; Wu, Feng yau; Chuang, Hui Ping; Chen, Wei yu; Huang, Hung Jen; Chen, Shu hui; Liu, Wen Tso

doi:10.1128/aem.02327-12

Cited by 40 publications

(40 citation statements)

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“…These Pelotomaculum indeed encode and express genes for syntrophic energy conservation (Hdr-Ifo and ECHyd) and a previously observed pathway for TA degradation to acetate, CO 2 and H 2 (Figure 2 and Supplementary Table S4) (McInerney et al, 2007;Lykidis et al, 2011). In addition, we newly identify expression of a clostridial electron-bifurcating butyryl-CoA dehydrogenase in TAPelo3 that may facilitate the previously hypothesized Sporotomaculum-like energy-conserving butyrate generation from aromatic compound degradation (Qiu et al, 2003;Buckel and Thauer, 2013;Wu et al, 2013;Nobu et al, 2014), albeit refuting the involvement of previously identified non-energy-conserving acylCoA dehydrogenase (Lykidis et al, 2011;Wu et al, 2013). Although butyrate-fermenting TA degradation is thermodynamically more favorable, it sacrifices precious adenosine triphosphate from substrate-level phosphorylation.…”

Section: Metatranscriptomicsmentioning

confidence: 86%

“…Our recent metagenomic and proteomic studies proposed that Pelotomaculum may produce acetate, H 2 and butyrate as by-products and that uncultivated taxa (Caldiserica and 'Ca. Cloacimonetes', formerly OP5 and WWE1) may further metabolize H 2 and butyrate (Lykidis et al, 2011;Wu et al, 2013). This provided evidence that non-methanogen community members may serve as syntrophic partners (secondary degraders) to metabolize TA degradation by-products alongside aceticlastic and hydrogenotrophic methanogens.…”

Section: Introductionmentioning

confidence: 86%

“…Syntrophic TA degradation by Pelotomaculum and Syntrophorhabdus with methanogens Organisms of the genus Pelotomaculum and family Syntrophorhabdaceae are thought to be responsible for syntrophic TA degradation in reactor systems (Lykidis et al, 2011;Wu et al, 2013). We identify diverse Pelotomaculum (bins TAPelo1-TAPelo4) predominate the community, accounting for 16.8% and 31.7% of the bacterial community and metratranscriptome.…”

Section: Metatranscriptomicsmentioning

confidence: 99%

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Microbial dark matter ecogenomics reveals complex synergistic networks in a methanogenic bioreactor

et al. 2015

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Ecogenomic investigation of a methanogenic bioreactor degrading terephthalate (TA) allowed elucidation of complex synergistic networks of uncultivated microorganisms, including those from candidate phyla with no cultivated representatives. Our previous metagenomic investigation proposed that Pelotomaculum and methanogens may interact with uncultivated organisms to degrade TA; however, many members of the community remained unaddressed because of past technological limitations. In further pursuit, this study employed state-of-the-art omics tools to generate draft genomes and transcriptomes for uncultivated organisms spanning 15 phyla and reports the first genomic insight into candidate phyla Atribacteria, Hydrogenedentes and Marinimicrobia in methanogenic environments. Metabolic reconstruction revealed that these organisms perform fermentative, syntrophic and acetogenic catabolism facilitated by energy conservation revolving around H 2 metabolism. Several of these organisms could degrade TA catabolism by-products (acetate, butyrate and H 2 ) and syntrophically support Pelotomaculum. Other taxa could scavenge anabolic products (protein and lipids) presumably derived from detrital biomass produced by the TA-degrading community. The protein scavengers expressed complementary metabolic pathways indicating syntrophic and fermentative step-wise protein degradation through amino acids, branched-chain fatty acids and propionate. Thus, the uncultivated organisms may interact to form an intricate syntrophy-supported food web with Pelotomaculum and methanogens to metabolize catabolic by-products and detritus, whereby facilitating holistic TA mineralization to CO 2 and CH 4 .

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Section: Metatranscriptomicsmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 86%

Section: Metatranscriptomicsmentioning

confidence: 99%

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Microbial dark matter ecogenomics reveals complex synergistic networks in a methanogenic bioreactor

et al. 2015

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“…Later, the rapidly decreasing sequencing cost and the prevalence of NGS technologies other than 454 pyrosequencing allowed for more extensive applications of HTS-based metagenomics approaches, including 16S rRNA gene amplicons sequencing and metagenome for novel microbial insights into the anaerobic digestion processes operated for bioenergy production (e.g., methane, biohydrogen, bioethanol, fatty acids) and/or pollution control (e.g., refractory compounds, bacterial pathogens, antibiotics resistance genes). A few pioneering studies even applied metatranscriptome (Xia et al 2014;Zakrzewski et al 2012) or metaproteome (Lü et al 2013;Kohrs et al 2013;Hanreich et al 2013;Hanreich et al 2012;Abram et al 2011;Heyer et al 2013;Wu et al 2013) to gain some preliminary insights into the gene expression and active enzymes in anaerobic digestion processes.…”

Section: Applications Of Metagenomics In Anaerobic Technology Studiesmentioning

confidence: 99%

Application of Metagenomics in Environmental Anaerobic Technology

Ju¹,

Fang²,

Zhang³

2015

Anaerobic Biotechnology

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Anaerobic technology has been applied for the treatment of solid wastes and wastewater since the 1880s. This chapter reviews the most recent advance in molecular microbial characterization techniques, i.e., metagenomics, as well as its applications in anaerobic technology, from the exploration of the intriguing science of anaerobes to industrial engineering applications. With the rapidly decreasing cost of high-throughput sequencing technologies and timely updating of state-of-the-art bioinformatics analysis tools, metagenomics has revolutionized the study of microbiology and demonstrated the great potential of the development of novel microbial resources (e.g., industrial biomolecules and enzymes and biodegradation genes), as it discloses unprecedented genetic information of uncultivated microorganisms at an amazingly fast rate. This chapter gives a detailed introduction to the technical procedures of metagenomics, from preliminary molecular experiments to high-throughput sequencing, as well as its application in environmental anaerobic technology.

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“…As shown in Table 1, granule samples 1 and 2 were collected from full-scale up-flow anaerobic sludge bed (UASB) reactors treating purified terephthalic acid (PTA) wastewater, in which acetate, benzoate, terephthalate, and p-toluate account for the major components in the wastewater stream (23). The terephthalate-degrading biofilm sample (sample 3) was taken from a thermophilic (50°C) fixed film reactor (24), and the p-toluate-degrading granule sample (sample 4) was obtained from a mesophilic (35°C) fed-batch reactor in the laboratory. Both reactors inoculated with sludge sample 2 were operated for at least 6 months.…”

Section: Methodsmentioning

confidence: 99%

Use of a Hierarchical Oligonucleotide Primer Extension Approach for Multiplexed Relative Abundance Analysis of Methanogens in Anaerobic Digestion Systems

Chuang

Hsu

et al. 2013

Appl Environ Microbiol

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In this study, we established a rapid multiplex method to detect the relative abundances of amplified 16S rRNA genes from known cultivatable methanogens at hierarchical specificities in anaerobic digestion systems treating industrial wastewater and sewage sludge. The method was based on the hierarchical oligonucleotide primer extension (HOPE) technique and combined with a set of 27 primers designed to target the total archaeal populations and methanogens from 22 genera within 4 taxonomic orders. After optimization for their specificities and detection sensitivity under the conditions of multiple single-nucleotide primer extension reactions, the HOPE approach was applied to analyze the methanogens in 19 consortium samples from 7 anaerobic treatment systems (i.e., 513 reactions). Among the samples, the methanogen populations detected with order-level primers accounted for >77.2% of the PCR-amplified 16S rRNA genes detected using an Archaea-specific primer. The archaeal communities typically consisted of 2 to 7 known methanogen genera within the Methanobacteriales, Methanomicrobiales, and Methanosarcinales and displayed population dynamic and spatial distributions in anaerobic reactor operations. Principal component analysis of the HOPE data further showed that the methanogen communities could be clustered into 3 distinctive groups, in accordance with the distribution of the Methanosaeta, Methanolinea, and Methanomethylovorans, respectively. This finding suggested that in addition to acetotrophic and hydrogenotrophic methanogens, the methylotrophic methanogens might play a key role in the anaerobic treatment of industrial wastewater. Overall, the results demonstrated that the HOPE approach is a specific, rapid, and multiplexing platform to determine the relative abundances of targeted methanogens in PCR-amplified 16S rRNA gene products.

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Community and Proteomic Analysis of Methanogenic Consortia Degrading Terephthalate

Cited by 40 publications

References 41 publications

Microbial dark matter ecogenomics reveals complex synergistic networks in a methanogenic bioreactor

Microbial dark matter ecogenomics reveals complex synergistic networks in a methanogenic bioreactor

Application of Metagenomics in Environmental Anaerobic Technology

Use of a Hierarchical Oligonucleotide Primer Extension Approach for Multiplexed Relative Abundance Analysis of Methanogens in Anaerobic Digestion Systems

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