Lactobacillus rhamnosus DSM 20711 is a mesophilic prokaryote of the family Lactobacillaceae.
mesophilic 16S sequence
SI-ID 35296
| @ref 20215 |
Last LPSN update
2025-12-16 09:48:19 |
| Domain Bacillati |
| Phylum Bacillota |
| Class Bacilli |
| Order Lactobacillales |
| Family Lactobacillaceae |
| Genus Lactobacillus |
| Species Lactobacillus rhamnosus |
| Full scientific name Lactobacillus rhamnosus (Hansen 1968) Collins et al. 1989 |
| Synonyms (2) |
| @ref | Name | Growth | Medium link | Composition | |
|---|---|---|---|---|---|
| 9022 | COLUMBIA BLOOD MEDIUM (DSMZ Medium 693) | Medium recipe at MediaDive  | Name: COLUMBIA BLOOD MEDIUM (DSMZ Medium 693) Composition: Defibrinated sheep blood 50.0 g/l Columbia agar base | ||
| 9022 | MRS MEDIUM (DSMZ Medium 11) | Medium recipe at MediaDive | Name: MRS MEDIUM (DSMZ Medium 11) Composition: Glucose 20.0 g/l Casein peptone 10.0 g/l Meat extract 10.0 g/l Na-acetate 5.0 g/l Yeast extract 5.0 g/l (NH4)3 citrate 2.0 g/l K2HPO4 2.0 g/l Tween 80 1.0 g/l MgSO4 x 7 H2O 0.2 g/l MnSO4 x H2O 0.05 g/l Distilled water |
| @ref | pathway | enzyme coverage | annotated reactions | external links | |
|---|---|---|---|---|---|
| 66794 | gluconeogenesis | 100 | 8 of 8 |   |
|
| 66794 | C4 and CAM-carbon fixation | 100 | 8 of 8 | |
|
| 66794 | acetate fermentation | 100 | 4 of 4 | |
|
| 66794 | ribulose monophosphate pathway | 100 | 2 of 2 | |
|
| 66794 | ppGpp biosynthesis | 100 | 4 of 4 | |
|
| 66794 | coenzyme A metabolism | 100 | 4 of 4 | |
|
| 66794 | CDP-diacylglycerol biosynthesis | 100 | 2 of 2 | |
|
| 66794 | UDP-GlcNAc biosynthesis | 100 | 3 of 3 | |
|
| 66794 | cis-vaccenate biosynthesis | 100 | 2 of 2 | |
|
| 66794 | ceramide biosynthesis | 100 | 1 of 1 | |
|
| 66794 | folate polyglutamylation | 100 | 1 of 1 | |
|
| 66794 | anapleurotic synthesis of oxalacetate | 100 | 1 of 1 | |
|
| 66794 | methylglyoxal degradation | 100 | 5 of 5 | |
|
| 66794 | acetoin degradation | 100 | 3 of 3 | |
|
| 66794 | palmitate biosynthesis | 90.91 | 20 of 22 | |
|
| 66794 | pentose phosphate pathway | 90.91 | 10 of 11 | |
|
| 66794 | aspartate and asparagine metabolism | 88.89 | 8 of 9 | |
|
| 66794 | peptidoglycan biosynthesis | 86.67 | 13 of 15 | |
|
| 66794 | vitamin B1 metabolism | 84.62 | 11 of 13 | |
|
| 66794 | degradation of sugar alcohols | 81.25 | 13 of 16 | |
|
| 66794 | starch degradation | 80 | 8 of 10 | |
|
| 66794 | glycogen metabolism | 80 | 4 of 5 | |
|
| 66794 | threonine metabolism | 80 | 8 of 10 | |
|
| 66794 | pyrimidine metabolism | 75.56 | 34 of 45 | |
|
| 66794 | purine metabolism | 75.53 | 71 of 94 | |
|
| 66794 | glycogen biosynthesis | 75 | 3 of 4 | |
|
| 66794 | NAD metabolism | 72.22 | 13 of 18 | |
|
| 66794 | propanol degradation | 71.43 | 5 of 7 | |
|
| 66794 | cardiolipin biosynthesis | 71.43 | 5 of 7 | |
|
| 66794 | photosynthesis | 71.43 | 10 of 14 | |
|
| 66794 | glycolysis | 70.59 | 12 of 17 | |
|
| 66794 | myo-inositol biosynthesis | 70 | 7 of 10 | |
|
| 66794 | phenylalanine metabolism | 69.23 | 9 of 13 | |
|
| 66794 | methionine metabolism | 69.23 | 18 of 26 | |
|
| 66794 | glutamate and glutamine metabolism | 67.86 | 19 of 28 | |
|
| 66794 | cyanate degradation | 66.67 | 2 of 3 | |
|
| 66794 | formaldehyde oxidation | 66.67 | 2 of 3 | |
|
| 66794 | valine metabolism | 66.67 | 6 of 9 | |
|
| 66794 | degradation of hexoses | 66.67 | 12 of 18 | |
|
| 66794 | L-lactaldehyde degradation | 66.67 | 2 of 3 | |
|
| 66794 | d-xylose degradation | 63.64 | 7 of 11 | |
|
| 66794 | ketogluconate metabolism | 62.5 | 5 of 8 | |
|
| 66794 | dTDPLrhamnose biosynthesis | 62.5 | 5 of 8 | |
|
| 66794 | glycine betaine biosynthesis | 60 | 3 of 5 | |
|
| 66794 | 3-chlorocatechol degradation | 60 | 3 of 5 | |
|
| 66794 | lipoate biosynthesis | 60 | 3 of 5 | |
|
| 66794 | factor 420 biosynthesis | 60 | 3 of 5 | |
|
| 66794 | Entner Doudoroff pathway | 60 | 6 of 10 | |
|
| 66794 | oxidative phosphorylation | 59.34 | 54 of 91 | |
|
| 66794 | non-pathway related | 57.89 | 22 of 38 | |
|
| 66794 | degradation of pentoses | 57.14 | 16 of 28 | |
|
| 66794 | ubiquinone biosynthesis | 57.14 | 4 of 7 | |
|
| 66794 | CO2 fixation in Crenarchaeota | 55.56 | 5 of 9 | |
|
| 66794 | serine metabolism | 55.56 | 5 of 9 | |
|
| 66794 | d-mannose degradation | 55.56 | 5 of 9 | |
|
| 66794 | metabolism of disaccharids | 54.55 | 6 of 11 | |
|
| 66794 | proline metabolism | 54.55 | 6 of 11 | |
|
| 66794 | degradation of sugar acids | 52 | 13 of 25 | |
|
| 66794 | alanine metabolism | 51.72 | 15 of 29 | |
|
| 66794 | histidine metabolism | 51.72 | 15 of 29 | |
|
| 66794 | cyclohexanol degradation | 50 | 2 of 4 | |
|
| 66794 | sulfopterin metabolism | 50 | 2 of 4 | |
|
| 66794 | 6-hydroxymethyl-dihydropterin diphosphate biosynthesis | 50 | 4 of 8 | |
|
| 66794 | tryptophan metabolism | 50 | 19 of 38 | |
|
| 66794 | selenocysteine biosynthesis | 50 | 3 of 6 | |
|
| 66794 | butanoate fermentation | 50 | 2 of 4 | |
|
| 66794 | adipate degradation | 50 | 1 of 2 | |
|
| 66794 | isoleucine metabolism | 50 | 4 of 8 | |
|
| 66794 | ethanol fermentation | 50 | 1 of 2 | |
|
| 66794 | tetrahydrofolate metabolism | 50 | 7 of 14 | |
|
| 66794 | suberin monomers biosynthesis | 50 | 1 of 2 | |
|
| 66794 | glutathione metabolism | 50 | 7 of 14 | |
|
| 66794 | cysteine metabolism | 50 | 9 of 18 | |
|
| 66794 | reductive acetyl coenzyme A pathway | 42.86 | 3 of 7 | |
|
| 66794 | mevalonate metabolism | 42.86 | 3 of 7 | |
|
| 66794 | isoprenoid biosynthesis | 42.31 | 11 of 26 | |
|
| 66794 | degradation of aromatic, nitrogen containing compounds | 41.67 | 5 of 12 | |
|
| 66794 | ascorbate metabolism | 40.91 | 9 of 22 | |
|
| 66794 | lysine metabolism | 40.48 | 17 of 42 | |
|
| 66794 | ethylmalonyl-CoA pathway | 40 | 2 of 5 | |
|
| 66794 | metabolism of amino sugars and derivatives | 40 | 2 of 5 | |
|
| 66794 | glycine metabolism | 40 | 4 of 10 | |
|
| 66794 | cellulose degradation | 40 | 2 of 5 | |
|
| 66794 | arachidonate biosynthesis | 40 | 2 of 5 | |
|
| 66794 | flavin biosynthesis | 40 | 6 of 15 | |
|
| 66794 | vitamin K metabolism | 40 | 2 of 5 | |
|
| 66794 | lipid metabolism | 38.71 | 12 of 31 | |
|
| 66794 | citric acid cycle | 35.71 | 5 of 14 | |
|
| 66794 | glycolate and glyoxylate degradation | 33.33 | 2 of 6 | |
|
| 66794 | chorismate metabolism | 33.33 | 3 of 9 | |
|
| 66794 | acetyl CoA biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | enterobactin biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | IAA biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | lipid A biosynthesis | 33.33 | 3 of 9 | |
|
| 66794 | sphingosine metabolism | 33.33 | 2 of 6 | |
|
| 66794 | octane oxidation | 33.33 | 1 of 3 | |
|
| 66794 | leucine metabolism | 30.77 | 4 of 13 | |
|
| 66794 | urea cycle | 30.77 | 4 of 13 | |
|
| 66794 | phenylpropanoid biosynthesis | 30.77 | 4 of 13 | |
|
| 66794 | propionate fermentation | 30 | 3 of 10 | |
|
| 66794 | arginine metabolism | 29.17 | 7 of 24 | |
|
| 66794 | vitamin B6 metabolism | 27.27 | 3 of 11 | |
|
| 66794 | polyamine pathway | 26.09 | 6 of 23 | |
|
| 66794 | lactate fermentation | 25 | 1 of 4 | |
|
| 66794 | carnitine metabolism | 25 | 2 of 8 | |
|
| 66794 | toluene degradation | 25 | 1 of 4 | |
|
| 66794 | phenol degradation | 25 | 5 of 20 | |
|
| 66794 | CMP-KDO biosynthesis | 25 | 1 of 4 | |
|
| 66794 | vitamin B12 metabolism | 23.53 | 8 of 34 | |
|
| 66794 | sulfate reduction | 23.08 | 3 of 13 | |
|
| 66794 | nitrate assimilation | 22.22 | 2 of 9 | |
|
| 66794 | 4-hydroxymandelate degradation | 22.22 | 2 of 9 | |
|
| 66794 | tyrosine metabolism | 21.43 | 3 of 14 | |
| @ref | Description | Accession | Length | Database | NCBI tax ID | |
|---|---|---|---|---|---|---|
| 124043 | Lacticaseibacillus rhamnosus JCM20300 gene for 16S rRNA, partial sequence. | LC685618 | 1440 |  | 47715 |  |
| Topic | Title | Authors | Journal | DOI | Year | |
|---|---|---|---|---|---|---|
| Metabolism | Eruca sativa might influence the growth, survival under simulated gastrointestinal conditions and some biological features of Lactobacillus acidophilus, Lactobacillus plantarum and Lactobacillus rhamnosus strains. | Fratianni F, Pepe S, Cardinale F, Granese T, Cozzolino A, Coppola R, Nazzaro F. | Int J Mol Sci | 10.3390/ijms151017790 | 2014 | |
| Chemical composition and in vitro antimicrobial and mutagenic activities of seven Lamiaceae essential oils. | De Martino L, De Feo V, Nazzaro F. | Molecules | 10.3390/molecules14104213 | 2009 | | |
| The Potential of Lactiplantibacillus plantarum ATCC 14917 in the Development of Alginate-Based Gel Formulations with Anti-Staphylococcus aureus Properties. | Sodre MTC, Ferraz FA, Alencar AKV, Silva KF, Silva DHDS, Silva LDS, Araujo Carneiro JSDS, Monteiro CA, Silva LCN, Monteiro AS. | Pharmaceuticals (Basel) | 10.3390/ph16081112 | 2023 | | |
| Development and Characterization of Hydroxyethyl Cellulose-Based Gels Containing Lactobacilli Strains: Evaluation of Antimicrobial Effects in In Vitro and Ex Vivo Models. | Sousa MADS, Ferreira AF, da Silva CC, Silva MA, Bazan TAXN, Monteiro CA, Monteiro AS, Sousa JCS, da Silva LCN, Zagmignan A. | Pharmaceuticals (Basel) | 10.3390/ph16030468 | 2023 | | |
| High-throughput characterization of the effect of sodium chloride and potassium chloride on 31 lactic acid bacteria and their co-cultures. | Ndiaye A, Fliss I, Filteau M. | Front Microbiol | 10.3389/fmicb.2024.1328416 | 2024 | | |
| Pathogenicity | Antibacterial effects of silver diamine fluoride on multi-species cariogenic biofilm on caries. | Mei ML, Mei ML, Li QL, Chu CH, Lo EC, Samaranayake LP. | Ann Clin Microbiol Antimicrob | 10.1186/1476-0711-12-4 | 2013 | |
| Impact of environmental and genetic factors on biofilm formation by the probiotic strain Lactobacillus rhamnosus GG. | Lebeer S, Verhoeven TL, Perea Velez M, Vanderleyden J, De Keersmaecker SC. | Appl Environ Microbiol | 10.1128/aem.01393-07 | 2007 | | |
| Metabolism | Biological Control and Mitigation of Aflatoxin Contamination in Commodities. | Peles F, Sipos P, Kovacs S, Gyori Z, Pocsi I, Pusztahelyi T. | Toxins (Basel) | 10.3390/toxins13020104 | 2021 | |
| Metabolism | L-lactic acid production by Lactobacillus rhamnosus ATCC 10863. | Senedese AL, Maciel Filho R, Maciel MR | ScientificWorldJournal | 10.1155/2015/501029 | 2015 | |
How to citeIf you want to cite this particular strain cite the following doi:
https://doi.org/10.13145/bacdive6432.20251217.10
When using BacDive for research please cite the following paper
BacDive in 2025: the core database for prokaryotic strain data
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