Cellulose- and Xylan-Degrading Thermophilic Anaerobic Bacteria from Biocompost

Sizova, Maria V.; Izquierdo, Javier A.; Panikov, N. S.; Lynd, Lee R.

doi:10.1128/aem.01219-10

Cited by 113 publications

(65 citation statements)

References 44 publications

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“…S-2). This phenotype is different from several previously described xylanfermenting thermophiles such as C. thermolacticum (Le Ruyet et al, 1985) and C. clariflavum (Sizova et al, 2011).…”

Section: Identification and Characterization Of A Mesophilic Strain Mcontrasting

confidence: 40%

“…has a great potential for value-added products production from cellulose (Sizova et al, 2011;Yang et al, 2015), while most of the reported studies using hemicellulose compounds of lignocellulosic biomass as a fermentation substrate have been focused on ethanol or hydrogen production rather than on butanol (Tolonen et al, 2011). However, few wild-type strains are known to produce butanol from cellulose or xylan via simultaneous saccharification and fermentation, leaving a need for development of one-step strategies for biobutanol production from lignocellulosic materials.…”

Section: Introductionmentioning

confidence: 99%

“…Another unique feature that distinguishes strain MF28 from other butanol-producing strains is that it produces only butanol without any by-products such as acetone and ethanol, from the fermentation of xylan. Compared with other known xylan-to-acids isolates (Le Ruyet et al, 1985;Sizova et al, 2011), strain MF28 shows great flexibility in utilizing various carbon substrates derived from lignocelulosic biomass (Table S2). In addition to xylan, xylooligosaccharides (XOS) and xylose, strain MF28 was also found to utilize mannose, galactose and arabinose (all derived from lignocelluloses) to produce butanol, and hence has high economical potential for biomass-based butanol production.…”

Section: Identification and Characterization Of A Mesophilic Strain Mmentioning

confidence: 99%

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Simultaneous saccharification and fermentation of hemicellulose to butanol by a non-sporulating Clostridium species

2016

Bioresource Technology

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h i g h l i g h t sSimultaneous saccharification and fermentation of xylan to butanol by new strain MF28. Simultaneous fermentation of glucose and xylose to produce 11.9 g/L butanol. High yields of butanol on xylan and xylooligosaccharide were obtained. No acetone/ethanol byproducts were formed in converting lignocellulose to butanol. Non-sporulating strain MF28 is capable of continuous industrial-scale fermentation. a r t i c l e i n f o t r a c tProduction of lignocellulosic butanol has drawn increasing attention. However, currently few microorganisms can produce biofuels, particularly butanol, from lignocellulosic biomass via simultaneous saccharification and fermentation. Here we report discovery of a wild-type, mesophilic Clostridium sp. strain MF28 that ferments xylan to produce butanol (up to 3.2 g/L) without the addition of saccharolytic enzymes and without any chemical pretreatments. Application of selective pressure from 2-deoxy-Dglucose facilitated isolation of strain MF28, which exhibits inactivation of genes (gid and ccp genes) responsible for carbon catabolite repression, thus allowing strain MF28 to simultaneously ferment a combination of glucose (30 g/L), xylose (15 g/L), and arabinose (15 g/L) to produce 11.9 g/L of butanol. Strain MF28 possesses several unique features: (i) non-sporulating, (ii) no acetone/ethanol, (iii) complete hemicellulose-binding enzymatic domain, and (iv) absence of carbon catabolite repression. These unique characteristics demonstrate the industrial potential of strain MF28 for cost-effective biofuel generation from lignocellulosic biomass.

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“…S-2). This phenotype is different from several previously described xylanfermenting thermophiles such as C. thermolacticum (Le Ruyet et al, 1985) and C. clariflavum (Sizova et al, 2011).…”

Section: Identification and Characterization Of A Mesophilic Strain Mcontrasting

confidence: 40%

Section: Introductionmentioning

confidence: 99%

Section: Identification and Characterization Of A Mesophilic Strain Mmentioning

confidence: 99%

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Simultaneous saccharification and fermentation of hemicellulose to butanol by a non-sporulating Clostridium species

2016

Bioresource Technology

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“…Thermomonospora sp. Cerrena globosum and Aspergillus phoenicus) and bacteria (Bacillus, Bacteroides ovatus, Clostridium clariflavum) are capable of degrading xylans (Sunna and Antranikian, 1997;Abdel-Sater, 2001;Sizova et al, 2011 ). The hemicelluloses are degraded to CO 2 , H 2 O, cell biomass and various small carbohydrate molecules like monomers and dimers.…”

Section: Introductionmentioning

confidence: 99%

Biomethanization of Coal to Obtain Clean Coal Energy: A Review

Singh

2012

Energy Exploration & Exploitation

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This paper entails a review on the possibility of methanization of coal using microbial tool. Biomethanization process of coal begins with biodegradation of coal by specific bacteria and fungi. As a result of this, major polymers present in coal like proteins, polysaccharides, nucleic acids and lipids are hydrolyzed to monomers like aminoacids, sugars, purines, pyrimidines and long chain fatty acids. Their subsequent fermentation forms hydrogen, CO 2 and a number of reduced compounds like alcohols, short chain fatty acids, organic acids and certain aromatics. The oxidation of these reduced compounds further leads to the formation of acetate, hydrogen and CO 2 , methylated compounds and several intermediate compounds. Syntrophic relationship exists between fermenting bacteria and methanogens. The resultant oxidized compounds of fermenting bacteria are gradually utilized by specific methanogens to form methane. Hydrogenotrophic methanogens utilize H 2 and convert CO 2 into methane. Whereas acetate is utilized by acetoclastic methanogens to generate methane. The methylated compounds are utilized for methane formation by methylotrophic methanogens.

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“…This is because there are indications that some of the uncultivated species may be involved in a variety of systemic diseases (4,20,44) and likely play an important role in the function of the oral microbial community. We have shown that some previously uncultivable microorganisms can be isolated by mimicking natural growth conditions, using in vivo incubation devices (25,30,34) or via enrichments (17,46,47), and also developed a method for single-cell long-term incubations (S. Buerger et al, submitted for publication). The main objective of this study was to apply these different approaches to the cultivation of oral microorganisms, assess their relative merits, and isolate new species from the list of presently uncultivated taxa.…”

mentioning

confidence: 99%

New Approaches for Isolation of Previously Uncultivated Oral Bacteria

Sizova

Hohmann

Hazen

et al. 2012

Appl Environ Microbiol

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A significant number of microorganisms from the human oral cavity remain uncultivated. This is a major impediment to the study of human health since some of the uncultivated species may be involved in a variety of systemic diseases. We used a range of innovations previously developed to cultivate microorganisms from the human oral cavity, focusing on anaerobic species. These innovations include (i) in vivo cultivation to specifically enrich for species actively growing in the oral cavity (the "minitrap" method), (ii) single-cell long-term cultivation to minimize the effect of fast-growing microorganisms, and (iii) modifications of conventional enrichment techniques, using media that did not contain sugar, including glucose. To enable cultivation of obligate anaerobes, we maintained strict anaerobic conditions in most of our cultivation experiments. We report that, on a per cell basis, the most successful recovery was achieved using minitrap enrichment (11%), followed by single-cell cultivation (3%) and conventional plating (1%). Taxonomically, the richest collection was obtained using the single-cell cultivation method, followed by minitrap and conventional enrichment, comprising representatives of 13, 9, and 4 genera, respectively. Interestingly, no single species was isolated by all three methods, indicating method complementarity. An important result is the isolation and maintenance in pure culture of 10 strains previously only known by their molecular signatures, as well as representatives of what are likely to be three new microbial genera. We conclude that the ensemble of new methods we introduced will likely help close the gap between cultivated and uncultivated species from the human oral cavity.

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Cellulose- and Xylan-Degrading Thermophilic Anaerobic Bacteria from Biocompost

Cited by 113 publications

References 44 publications

Simultaneous saccharification and fermentation of hemicellulose to butanol by a non-sporulating Clostridium species

Simultaneous saccharification and fermentation of hemicellulose to butanol by a non-sporulating Clostridium species

Biomethanization of Coal to Obtain Clean Coal Energy: A Review

New Approaches for Isolation of Previously Uncultivated Oral Bacteria

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