Caldicellulosiruptor owensensis OL is an anaerobe, chemoorganotroph, thermophilic prokaryote that forms circular colonies and was isolated from freshwater sediment.
colony-forming anaerobe chemoorganotroph thermophilic genome sequence 16S sequence
SI-ID 43803
| @ref 20215 |
|
Last LPSN update
2025-12-16 09:51:14 |
| Domain Bacillati |
| Phylum Bacillota |
| Class Clostridia |
| Order Caldicellulosiruptorales |
| Family Caldicellulosiruptoraceae |
| Genus Caldicellulosiruptor |
| Species Caldicellulosiruptor owensensis |
| Full scientific name Caldicellulosiruptor owensensis Huang et al. 1998 |
| Synonyms (1) |
| @ref | Name | Growth | Medium link | Composition | |
|---|---|---|---|---|---|
| 4904 | CALDICELLULOSIRUPTOR OWENSIS MEDIUM (DSMZ Medium 144b) | Medium recipe at MediaDive  | Name: CALDICELLULOSIRUPTOR OWENSIS MEDIUM (DSMZ Medium 144b) Composition: Trypticase peptone 10.0 g/l D-Glucose 5.0 g/l Yeast extract 3.0 g/l Na2CO3 2.0 g/l Na2S x 9 H2O 1.0 g/l NaCl 0.9 g/l NH4Cl 0.9 g/l K2HPO4 0.4 g/l MgCl2 x 6 H2O 0.1 g/l CaCl2 x 2 H2O 0.05 g/l Na2-EDTA x 2 H2O 0.005 g/l CoCl2 x 6 H2O 0.0015 g/l MnCl2 x 4 H2O 0.001 g/l FeSO4 x 7 H2O 0.001 g/l ZnCl2 0.001 g/l Sodium resazurin 0.0005 g/l AlCl3 x 6 H2O 0.0004 g/l Na2WO4 x 2 H2O 0.0004 g/l Na2SeO3 x 5 H2O 0.0003 g/l NiCl2 x 6 H2O 0.0002 g/l CuCl2 x 2 H2O 0.0002 g/l Na2MoO4 x 2 H2O 0.0001 g/l H3BO3 0.0001 g/l Pyridoxine hydrochloride 5e-05 g/l Riboflavin 2.5e-05 g/l (DL)-alpha-Lipoic acid 2.5e-05 g/l p-Aminobenzoic acid 2.5e-05 g/l Calcium D-(+)-pantothenate 2.5e-05 g/l Thiamine HCl 2.5e-05 g/l Nicotinic acid 2.5e-05 g/l Biotin 1e-05 g/l Folic acid 1e-05 g/l Vitamin B12 5e-07 g/l Distilled water | ||
| 43370 | CBM medium | 1g/L Yeast extract, 5g/L xylan, 1g/L NH4Cl, 0.1g/L NaCl, 0.1 g/L MgCl*6 H2O, 0.05g/L CaCl2*2 H2O, 0.4 g/L K2HPO4, 0.0005g/L resazurin, 1mL/L vitamin solution and 10 mL/l trace mineral solution. 3g NaHCO3 was added wafter boiling. The vitamin solution consists of 2 mg/L biotin, 2mg/L folic acid, 10 mg/L pyridoxine hydrochloride, 5 mg/L thiamine hydrochloride, 5 mg/L riboflavine, 5 mg/L nicotinic acid, 5 mg/L DL- calcium panthothenate, 0.1 mg/L Vitamin B12, 5 mg/L p-amino-benzoic acid and 5 mg/L lipoic acid. the trace mineral solution consisted of 0.01g/L H2SeO3, 0.01g MnCl2*4 H2O, 0.1g/L FeSO4*7 H2O, 0.15g/L CoCl2*6 H2O, 0.1g/L ZnCl2, 0.01g/L H3BO3, 0.01g/L Na2MoO4*2 H2O, 0.02g/L CuCl2*2 H2O, 0.02g/L NiSO4*6 H2O, 0.04g/L AlCl3*6 H2O, 0.03g/L NaWO4, and 0.5g/L disodium EDTA. |
| 43370 | Typechemoorganotroph |
| 43370 | Spore formationno |
| @ref | Chebi-ID | Metabolite | Utilization activity | Kind of utilization tested | |
|---|---|---|---|---|---|
| 43370 | 30089 ChEBI | acetate | - | growth | |
| 43370 | 27613 ChEBI | amygdalin | - | growth | |
| 43370 | 22599 ChEBI | arabinose | + | growth | |
| 43370 | 18305 ChEBI | arbutin | - | growth | |
| 43370 | 17057 ChEBI | cellobiose | + | growth | |
| 43370 | 62968 ChEBI | cellulose | + | degradation | |
| 43370 | 62968 ChEBI | cellulose | + | growth | |
| 43370 | 23652 ChEBI | dextrin | + | growth | |
| 43370 | 17113 ChEBI | erythritol | - | growth | |
| 43370 | 28757 ChEBI | fructose | + | growth | |
| 43370 | 28260 ChEBI | galactose | + | growth | |
| 43370 | 17234 ChEBI | glucose | + | growth | |
| 43370 | 17754 ChEBI | glycerol | - | growth | |
| 43370 | 28087 ChEBI | glycogen | + | growth | |
| 43370 | 24996 ChEBI | lactate | - | growth | |
| 43370 | 17716 ChEBI | lactose | + | growth | |
| 43370 | 17306 ChEBI | maltose | + | growth | |
| 43370 | 29864 ChEBI | mannitol | + | growth | |
| 43370 | 37684 ChEBI | mannose | + | growth | |
| 43370 | 6731 ChEBI | melezitose | - | growth | |
| 43370 | 28053 ChEBI | melibiose | - | growth | |
| 43370 | 17790 ChEBI | methanol | - | growth | |
| 43370 | 17268 ChEBI | myo-inositol | + | growth | |
| 43370 | 17632 ChEBI | nitrate | - | reduction | |
| 43370 | 17309 ChEBI | pectin | + | growth | |
| 43370 | peptone | - | growth | ||
| 43370 | 15361 ChEBI | pyruvate | - | growth | |
| 43370 | 16634 ChEBI | raffinose | + | growth | |
| 43370 | 26546 ChEBI | rhamnose | + | growth | |
| 43370 | 33942 ChEBI | ribose | + | growth | |
| 43370 | 30911 ChEBI | sorbitol | - | growth | |
| 43370 | 28017 ChEBI | starch | + | growth | |
| 43370 | 17992 ChEBI | sucrose | + | growth | |
| 43370 | 33954 ChEBI | tagatose | + | growth | |
| 43370 | 27082 ChEBI | trehalose | - | growth | |
| 43370 | 37166 ChEBI | xylan | + | growth | |
| 43370 | 18222 ChEBI | xylose | + | growth | |
| 43370 | yeast extract (0.01 %, w/v) | + | growth |
| @ref | pathway | enzyme coverage | annotated reactions | external links | |
|---|---|---|---|---|---|
| 66794 | cellulose degradation | 100 | 5 of 5 |   |
|
| 66794 | starch degradation | 100 | 10 of 10 | |
|
| 66794 | glycogen metabolism | 100 | 5 of 5 | |
|
| 66794 | biotin biosynthesis | 100 | 4 of 4 | |
|
| 66794 | coenzyme A metabolism | 100 | 4 of 4 | |
|
| 66794 | sulfopterin metabolism | 100 | 4 of 4 | |
|
| 66794 | teichoic acid biosynthesis | 100 | 1 of 1 | |
|
| 66794 | CDP-diacylglycerol biosynthesis | 100 | 2 of 2 | |
|
| 66794 | UDP-GlcNAc biosynthesis | 100 | 3 of 3 | |
|
| 66794 | folate polyglutamylation | 100 | 1 of 1 | |
|
| 66794 | anapleurotic synthesis of oxalacetate | 100 | 1 of 1 | |
|
| 66794 | chorismate metabolism | 88.89 | 8 of 9 | |
|
| 66794 | aspartate and asparagine metabolism | 88.89 | 8 of 9 | |
|
| 66794 | isoleucine metabolism | 87.5 | 7 of 8 | |
|
| 66794 | degradation of sugar alcohols | 87.5 | 14 of 16 | |
|
| 66794 | palmitate biosynthesis | 86.36 | 19 of 22 | |
|
| 66794 | vitamin B1 metabolism | 84.62 | 11 of 13 | |
|
| 66794 | threonine metabolism | 80 | 8 of 10 | |
|
| 66794 | peptidoglycan biosynthesis | 80 | 12 of 15 | |
|
| 66794 | tetrahydrofolate metabolism | 78.57 | 11 of 14 | |
|
| 66794 | valine metabolism | 77.78 | 7 of 9 | |
|
| 66794 | glycolysis | 76.47 | 13 of 17 | |
|
| 66794 | gluconeogenesis | 75 | 6 of 8 | |
|
| 66794 | ketogluconate metabolism | 75 | 6 of 8 | |
|
| 66794 | ppGpp biosynthesis | 75 | 3 of 4 | |
|
| 66794 | glycogen biosynthesis | 75 | 3 of 4 | |
|
| 66794 | acetate fermentation | 75 | 3 of 4 | |
|
| 66794 | photosynthesis | 71.43 | 10 of 14 | |
|
| 66794 | cardiolipin biosynthesis | 71.43 | 5 of 7 | |
|
| 66794 | reductive acetyl coenzyme A pathway | 71.43 | 5 of 7 | |
|
| 66794 | glutamate and glutamine metabolism | 71.43 | 20 of 28 | |
|
| 66794 | Entner Doudoroff pathway | 70 | 7 of 10 | |
|
| 66794 | phenylalanine metabolism | 69.23 | 9 of 13 | |
|
| 66794 | purine metabolism | 68.09 | 64 of 94 | |
|
| 66794 | acetoin degradation | 66.67 | 2 of 3 | |
|
| 66794 | formaldehyde oxidation | 66.67 | 2 of 3 | |
|
| 66794 | serine metabolism | 66.67 | 6 of 9 | |
|
| 66794 | flavin biosynthesis | 66.67 | 10 of 15 | |
|
| 66794 | octane oxidation | 66.67 | 2 of 3 | |
|
| 66794 | NAD metabolism | 66.67 | 12 of 18 | |
|
| 66794 | molybdenum cofactor biosynthesis | 66.67 | 6 of 9 | |
|
| 66794 | d-mannose degradation | 66.67 | 6 of 9 | |
|
| 66794 | L-lactaldehyde degradation | 66.67 | 2 of 3 | |
|
| 66794 | d-xylose degradation | 63.64 | 7 of 11 | |
|
| 66794 | C4 and CAM-carbon fixation | 62.5 | 5 of 8 | |
|
| 66794 | 6-hydroxymethyl-dihydropterin diphosphate biosynthesis | 62.5 | 5 of 8 | |
|
| 66794 | pyrimidine metabolism | 62.22 | 28 of 45 | |
|
| 66794 | leucine metabolism | 61.54 | 8 of 13 | |
|
| 66794 | degradation of hexoses | 61.11 | 11 of 18 | |
|
| 66794 | hydrogen production | 60 | 3 of 5 | |
|
| 66794 | propionate fermentation | 60 | 6 of 10 | |
|
| 66794 | lipoate biosynthesis | 60 | 3 of 5 | |
|
| 66794 | oxidative phosphorylation | 58.24 | 53 of 91 | |
|
| 66794 | glutathione metabolism | 57.14 | 8 of 14 | |
|
| 66794 | CO2 fixation in Crenarchaeota | 55.56 | 5 of 9 | |
|
| 66794 | tryptophan metabolism | 55.26 | 21 of 38 | |
|
| 66794 | histidine metabolism | 55.17 | 16 of 29 | |
|
| 66794 | alanine metabolism | 55.17 | 16 of 29 | |
|
| 66794 | degradation of pentoses | 53.57 | 15 of 28 | |
|
| 66794 | non-pathway related | 52.63 | 20 of 38 | |
|
| 66794 | ethanol fermentation | 50 | 1 of 2 | |
|
| 66794 | cis-vaccenate biosynthesis | 50 | 1 of 2 | |
|
| 66794 | glycine metabolism | 50 | 5 of 10 | |
|
| 66794 | selenocysteine biosynthesis | 50 | 3 of 6 | |
|
| 66794 | suberin monomers biosynthesis | 50 | 1 of 2 | |
|
| 66794 | myo-inositol biosynthesis | 50 | 5 of 10 | |
|
| 66794 | adipate degradation | 50 | 1 of 2 | |
|
| 66794 | butanoate fermentation | 50 | 2 of 4 | |
|
| 66794 | quinate degradation | 50 | 1 of 2 | |
|
| 66794 | CMP-KDO biosynthesis | 50 | 2 of 4 | |
|
| 66794 | kanosamine biosynthesis II | 50 | 1 of 2 | |
|
| 66794 | glycolate and glyoxylate degradation | 50 | 3 of 6 | |
|
| 66794 | isoprenoid biosynthesis | 50 | 13 of 26 | |
|
| 66794 | methionine metabolism | 50 | 13 of 26 | |
|
| 66794 | degradation of sugar acids | 48 | 12 of 25 | |
|
| 66794 | polyamine pathway | 47.83 | 11 of 23 | |
|
| 66794 | metabolism of disaccharids | 45.45 | 5 of 11 | |
|
| 66794 | lysine metabolism | 45.24 | 19 of 42 | |
|
| 66794 | lipid A biosynthesis | 44.44 | 4 of 9 | |
|
| 66794 | cysteine metabolism | 44.44 | 8 of 18 | |
|
| 66794 | citric acid cycle | 42.86 | 6 of 14 | |
|
| 66794 | arginine metabolism | 41.67 | 10 of 24 | |
|
| 66794 | coenzyme M biosynthesis | 40 | 4 of 10 | |
|
| 66794 | metabolism of amino sugars and derivatives | 40 | 2 of 5 | |
|
| 66794 | urea cycle | 38.46 | 5 of 13 | |
|
| 66794 | proline metabolism | 36.36 | 4 of 11 | |
|
| 66794 | dolichyl-diphosphooligosaccharide biosynthesis | 36.36 | 4 of 11 | |
|
| 66794 | tyrosine metabolism | 35.71 | 5 of 14 | |
|
| 66794 | pantothenate biosynthesis | 33.33 | 2 of 6 | |
|
| 66794 | IAA biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | acetyl CoA biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | sulfate reduction | 30.77 | 4 of 13 | |
|
| 66794 | phenylpropanoid biosynthesis | 30.77 | 4 of 13 | |
|
| 66794 | 4-hydroxyphenylacetate degradation | 30 | 3 of 10 | |
|
| 66794 | ubiquinone biosynthesis | 28.57 | 2 of 7 | |
|
| 66794 | propanol degradation | 28.57 | 2 of 7 | |
|
| 66794 | vitamin B6 metabolism | 27.27 | 3 of 11 | |
|
| 66794 | pentose phosphate pathway | 27.27 | 3 of 11 | |
|
| 66794 | lipid metabolism | 25.81 | 8 of 31 | |
|
| 66794 | dTDPLrhamnose biosynthesis | 25 | 2 of 8 | |
|
| 66794 | lactate fermentation | 25 | 1 of 4 | |
|
| 66794 | cyclohexanol degradation | 25 | 1 of 4 | |
|
| 66794 | toluene degradation | 25 | 1 of 4 | |
|
| 66794 | degradation of aromatic, nitrogen containing compounds | 25 | 3 of 12 | |
|
| 66794 | heme metabolism | 21.43 | 3 of 14 | |
| Cat1 | Cat2 | Cat3 | |
|---|---|---|---|
| #Environmental | #Aquatic | #Sediment | |
| #Environmental | #Aquatic | #Freshwater |
Global distribution of 16S sequence U80596 (>99% sequence identity) for Caldicellulosiruptor owensensis subclade from Microbeatlas 
 Aquatic Samples |
11 |
 Soil Samples |
|
 Animal Samples |
10 |
 Plant Samples |
|
| Total Samples | 21 |
| @ref | Description | Assembly level | INSDC accession | BV-BRC accession | IMG accession | NCBI tax ID | Score | |
|---|---|---|---|---|---|---|---|---|
| 66792 | ASM16633v1 assembly for Caldicellulosiruptor owensensis OL | complete | GCA_000166335   | 632518.3  | 649633025  | 632518 | 99.01 |  |
| @ref | Description | Accession | Length | Database | NCBI tax ID | |
|---|---|---|---|---|---|---|
| 4904 | Caldicellulosiruptor owensense 16S ribosomal RNA gene, partial sequence | U80596 | 1539 |  | 632518 |
| @ref | GC-content (mol%) | Method | |
|---|---|---|---|
| 4904 | 36.6 | Buoyant density centrifugation (BD) |
| Topic | Title | Authors | Journal | DOI | Year | |
|---|---|---|---|---|---|---|
| Metabolism | Structural Insights into the Thermophilic Adaption Mechanism of Endo-1,4-beta-Xylanase from Caldicellulosiruptor owensensis. | Liu X, Liu T, Zhang Y, Xin F, Mi S, Wen B, Gu T, Shi X, Wang F, Sun L. | J Agric Food Chem | 10.1021/acs.jafc.7b03607 | 2018 | |
| Immobilization techniques improve volumetric hydrogen productivity of Caldicellulosiruptor species in a modified continuous stirred tank reactor. | Vongkampang T, Sreenivas K, Grey C, van Niel EWJ. | Biotechnol Biofuels Bioprod | 10.1186/s13068-023-02273-8 | 2023 | | |
| Molecular Cloning and Functional Characterization of a beta-Glucosidase Gene to Produce Platycodin D in Platycodon grandiflorus. | Su X, Meng F, Liu Y, Jiang W, Wang Z, Wu L, Guo X, Yao X, Wu J, Sun Z, Zha L, Gui S, Peng D, Xing S. | Front Plant Sci | 10.3389/fpls.2022.955628 | 2022 | | |
| Metabolism | [Heterologous expression and characterization of a thermostable acylCoA synthetase]. | Dong S, Wang Y, Ji J, Zheng J. | Wei Sheng Wu Xue Bao | 2016 | | |
| Production of Deglucose-Apiose-Xylosylated Platycosides from Glycosylated Platycosides by Crude Enzyme from Aspergillus tubingensis. | Shin KC, Kil TG, Kang SH, Oh DK. | J Microbiol Biotechnol | 10.4014/jmb.2112.12020 | 2022 | | |
| Characterization and adaptation of Caldicellulosiruptor strains to higher sugar concentrations, targeting enhanced hydrogen production from lignocellulosic hydrolysates. | Byrne E, Bjorkmalm J, Bostick JP, Sreenivas K, Willquist K, van Niel EWJ. | Biotechnol Biofuels | 10.1186/s13068-021-02058-x | 2021 | | |
| Enzymology | A novel SfaNI-like restriction-modification system in Caldicellulosiruptor extents the genetic engineering toolbox for this genus. | Swinnen S, Zurek C, Kramer M, Heger RM, Domeyer JE, Ziegler J, Svetlitchnyi VA, Laufer A. | PLoS One | 10.1371/journal.pone.0279562 | 2022 | |
| Metabolic engineering of Caldicellulosiruptor bescii for 2,3-butanediol production from unpretreated lignocellulosic biomass and metabolic strategies for improving yields and titers. | Tanwee TNN, Lipscomb GL, Vailionis JL, Zhang K, Bing RG, O'Quinn HC, Poole FL, Zhang Y, Kelly RM, Adams MWW. | Appl Environ Microbiol | 10.1128/aem.01951-23 | 2024 | | |
| Multispecies Bacterial Biofilms and Their Evaluation Using Bioreactors. | Prabhukhot GS, Eggleton CD, Patel J. | Foods | 10.3390/foods12244495 | 2023 | | |
| A multifunctional thermophilic glycoside hydrolase from Caldicellulosiruptor owensensis with potential applications in production of biofuels and biochemicals. | Peng X, Su H, Mi S, Han Y. | Biotechnol Biofuels | 10.1186/s13068-016-0509-y | 2016 | | |
| Two-Step Saccharification of the Xylan Portion of Sugarcane Waste by Recombinant Xylanolytic Enzymes for Enhanced Xylose Production. | Thakur A, Sharma A, Khaire KC, Moholkar VS, Pathak P, Bhardwaj NK, Goyal A. | ACS Omega | 10.1021/acsomega.1c01262 | 2021 | | |
| Enzymology | Biochemical characterization of two thermostable xylanolytic enzymes encoded by a gene cluster of Caldicellulosiruptor owensensis. | Mi S, Jia X, Wang J, Qiao W, Peng X, Han Y. | PLoS One | 10.1371/journal.pone.0105264 | 2014 | |
| Improved production of deglucosylated platycodin D from saponins from balloon flower leaf by a food-grade enzyme using high hydrostatic pressure. | Shin KC, Kim DW, Oh YJ, Seo MJ, Na CS, Kim YS. | Heliyon | 10.1016/j.heliyon.2021.e08104 | 2021 | | |
| Metabolism | Conversion of Glycosylated Platycoside E to Deapiose-Xylosylated Platycodin D by Cytolase PCL5. | Shin KC, Kim DW, Woo HS, Oh DK, Kim YS. | Int J Mol Sci | 10.3390/ijms21041207 | 2020 | |
| Characterization of hemicellulase and cellulase from the extremely thermophilic bacterium Caldicellulosiruptor owensensis and their potential application for bioconversion of lignocellulosic biomass without pretreatment. | Peng X, Qiao W, Mi S, Jia X, Su H, Han Y. | Biotechnol Biofuels | 10.1186/s13068-015-0313-0 | 2015 | | |
| Metabolism | Transglycosylation, a new role for multifunctional cellulase in overcoming product inhibition during the cellulose hydrolysis. | Wang X, Wu Y, Zhou Y. | Bioengineered | 10.1080/21655979.2016.1215787 | 2017 | |
| Genetics | Complete genome sequences for the anaerobic, extremely thermophilic plant biomass-degrading bacteria Caldicellulosiruptor hydrothermalis, Caldicellulosiruptor kristjanssonii, Caldicellulosiruptor kronotskyensis, Caldicellulosiruptor owensensis, and Caldicellulosiruptor lactoaceticus. | Blumer-Schuette SE, Ozdemir I, Mistry D, Lucas S, Lapidus A, Cheng JF, Goodwin LA, Pitluck S, Land ML, Hauser LJ, Woyke T, Mikhailova N, Pati A, Kyrpides NC, Ivanova N, Detter JC, Walston-Davenport K, Han S, Adams MW, Adams MW, Kelly RM. | J Bacteriol | 10.1128/jb.01515-10 | 2011 | |
| Metabolism | A thermophilic cell-free cascade enzymatic reaction for acetoin synthesis from pyruvate. | Jia X, Liu Y, Han Y. | Sci Rep | 10.1038/s41598-017-04684-8 | 2017 | |
| Phylogenetic, functional and structural characterization of a GH10 xylanase active at extreme conditions of temperature and alkalinity. | Talens-Perales D, Jimenez-Ortega E, Sanchez-Torres P, Sanz-Aparicio J, Polaina J. | Comput Struct Biotechnol J | 10.1016/j.csbj.2021.05.004 | 2021 | | |
| Metabolism | Preparation of a whole cell catalyst overexpressing acetohydroxyacid synthase of Thermotoga maritima and its application in the syntheses of alpha-hydroxyketones. | Liang YF, Yan LT, Yue Q, Zhao JK, Luo CY, Gao F, Li H, Gao WY. | Sci Rep | 10.1038/s41598-020-72416-6 | 2020 | |
| Biofilm formation by designed co-cultures of Caldicellulosiruptor species as a means to improve hydrogen productivity. | Pawar SS, Vongkumpeang T, Grey C, van Niel EW. | Biotechnol Biofuels | 10.1186/s13068-015-0201-7 | 2015 | | |
| Exploring the Molecular Basis for Substrate Affinity and Structural Stability in Bacterial GH39 beta-Xylosidases. | de Morais MAB, Polo CC, Domingues MN, Persinoti GF, Pirolla RAS, de Souza FHM, Correa JBL, Dos Santos CR, Murakami MT. | Front Bioeng Biotechnol | 10.3389/fbioe.2020.00419 | 2020 | | |
| Enzymology | Polyamines of the thermophilic eubacteria belonging to the genera Thermosipho, Thermaerobacter and Caldicellulosiruptor. | Hamana K, Niitsu M, Samejima K, Itoh T. | Microbios | 2001 | | |
| Metabolism | A comprehensive and quantitative review of dark fermentative biohydrogen production. | Rittmann S, Herwig C. | Microb Cell Fact | 10.1186/1475-2859-11-115 | 2012 | |
| Metabolism | The genes of the sulphoquinovose catabolism in Escherichia coli are also associated with a previously unknown pathway of lactose degradation. | Kaznadzey A, Shelyakin P, Belousova E, Eremina A, Shvyreva U, Bykova D, Emelianenko V, Korosteleva A, Tutukina M, Gelfand MS. | Sci Rep | 10.1038/s41598-018-21534-3 | 2018 | |
| Thermostable Xylanase Production by Geobacillus sp. Strain DUSELR13, and Its Application in Ethanol Production with Lignocellulosic Biomass. | Bibra M, Kunreddy VR, Sani RK. | Microorganisms | 10.3390/microorganisms6030093 | 2018 | | |
| Metabolism | Multidomain, Surface Layer-associated Glycoside Hydrolases Contribute to Plant Polysaccharide Degradation by Caldicellulosiruptor Species. | Conway JM, Pierce WS, Le JH, Harper GW, Wright JH, Tucker AL, Zurawski JV, Lee LL, Blumer-Schuette SE, Kelly RM. | J Biol Chem | 10.1074/jbc.m115.707810 | 2016 | |
| Metabolism | Reconstitution of a thermostable xylan-degrading enzyme mixture from the bacterium Caldicellulosiruptor bescii. | Su X, Han Y, Dodd D, Moon YH, Yoshida S, Mackie RI, Cann IK. | Appl Environ Microbiol | 10.1128/aem.03265-12 | 2013 | |
| Genetics | Mycobacteriophage Marvin: a new singleton phage with an unusual genome organization. | Mageeney C, Pope WH, Harrison M, Moran D, Cross T, Jacobs-Sera D, Hendrix RW, Dunbar D, Hatfull GF. | J Virol | 10.1128/jvi.00075-12 | 2012 | |
| Enzymology | Caldicellulosiruptor obsidiansis sp. nov., an anaerobic, extremely thermophilic, cellulolytic bacterium isolated from Obsidian Pool, Yellowstone National Park. | Hamilton-Brehm SD, Mosher JJ, Vishnivetskaya T, Podar M, Carroll S, Allman S, Phelps TJ, Keller M, Elkins JG. | Appl Environ Microbiol | 10.1128/aem.01903-09 | 2010 | |
| Phylogeny | Caldicellulosiruptor owensensis sp. nov., an anaerobic, extremely thermophilic, xylanolytic bacterium. | Huang CY, Patel BK, Mah RA, Baresi L | Int J Syst Bacteriol | 10.1099/00207713-48-1-91 | 1998 | |
How to citeIf you want to cite this particular strain cite the following doi:
https://doi.org/10.13145/bacdive18027.20251217.10
When using BacDive for research please cite the following paper
BacDive in 2025: the core database for prokaryotic strain data
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