Mycobacterium thermoresistibile 14 131 0001 is an obligate aerobe, rod-shaped bacterium that was isolated from soil.
rod-shaped obligate aerobe genome sequence 16S sequence Bacteria
SI-ID 36991
| @ref 20215 |
|
Last LPSN update
2026-02-09 11:19:42 |
| Domain Bacteria |
| Phylum Actinomycetota |
| Class Actinomycetes |
| Order Mycobacteriales |
| Family Mycobacteriaceae |
| Genus Mycobacterium |
| Species Mycobacterium thermoresistibile |
| Full scientific name Mycobacterium thermoresistibile Tsukamura 1966 (Approved Lists 1980) |
| Synonyms (1) |
| BacDive ID | Other strains from Mycobacterium thermoresistibile (2) | Type strain |
|---|---|---|
| 8424 | M. thermoresistibile DSM 44018 | |
| 150151 | M. thermoresistibile CCUG 39116 |
| @ref | Name | Growth | Medium link | Composition | |
|---|---|---|---|---|---|
| 11565 | LÖWENSTEIN-JENSEN MEDIUM (DSMZ Medium 354) | Medium recipe at MediaDive  | Name: LÖWENSTEIN-JENSEN MEDIUM (DSMZ Medium 354) Composition: Potato flour 18.6104 g/l L-Asparagin 2.23325 g/l KH2PO4 1.55087 g/l Mg-citrate 0.372208 g/l Malachite green 0.248139 g/l MgSO4 0.148883 g/l Glycerol Fresh egg mixture Distilled water | ||
| 11565 | MIDDLEBROOK MEDIUM (DSMZ Medium 645) | Medium recipe at MediaDive | Name: MIDDLEBROOK MEDIUM (DSMZ Medium 645) Composition: Bacto Middlebrook 7H10 agar 20.9945 g/l Glycerol Distilled water | ||
| 20011 | MB7H10 | Name: Middlebrook 7H10 (MB7H10) Broth Base Composition: amount in percent Middlebrook 7H10 Agar 1.9% Glycerol 0.5% OADC-Enrichment in ml (NL5633) 10ml Comments: Add broth base and glycerol to ddh2O. Adjust volumes. Autoclave. Cool to 42°C. Add OADC-stock. Sterilisation: 20 minutes Temperature:121°C PH before: PH after: Biological details Culture type: suitable for: Mycobacteria OADC stock solution old broth-name: OADC-Stock Composition: Bovine Serum Albumin, fraction V 5 % 1% Oleic Acid in 0.2N NaOH 5ml Glucose 2 % NaCl 0.85 % Comments: Melt 1% Oleic Acid in 65°C water bath. Dissolve all ingredients in 700ml of ddH2O. Adjust volume to 1L. Filter sterilize and store at 4°C. -To make 1% Oleic Acid in 0.2N NaOH: Dissolve 5g oleic acid (ampule) in 500ml 0.2N NaOH (300ml ddH2O + 20ml NaOH + adjust volume to 500ml). Heat solution to 55°C for oleic acid to melt. Store at -20°C in 50ml aliquots. There is no need to sterilize this. Sterilisation: 20 minutes Temperature:121°C PH before: PH after: Biological details Culture type: suitable for: Mycobacteria | |||
| 20011 | MB7H11 | Name: Middlebrook 7H11 (MB7H11) Broth Base Composition: Middlebrook 7H11 Agar 2% Glycerol 0.5% OADC-Enrichment 10ml Comments: Add broth base and glycerol to ddH2O. Adjust volumes. Autoclave. Cool to 42°C. Add OADC-Stock. Sterilisation: 20 minutes Temperature:121°C PH before: PH after: Biological details Culture type: suitable for: Mycobacteria OADC stock solution old broth-name: OADC-Stock Composition: Bovine Serum Albumin, fraction V 5 % 1% Oleic Acid in 0.2N NaOH 5ml Glucose 2 % NaCl 0.85 % Comments: Melt 1% Oleic Acid in 65°C water bath. Dissolve all ingredients in 700ml of ddH2O. Adjust volume to 1L. Filter sterilize and store at 4°C. -To make 1% Oleic Acid in 0.2N NaOH: Dissolve 5g oleic acid (ampule) in 500ml 0.2N NaOH (300ml ddH2O + 20ml NaOH + adjust volume to 500ml). Heat solution to 55°C for oleic acid to melt. Store at -20°C in 50ml aliquots. There is no need to sterilize this. Sterilisation: 20 minutes Temperature:121°C PH before: PH after: Biological details Culture type: suitable for: Mycobacteria | |||
| 20011 | 5006 | Medium: 5006 Name: Composition (g/l) Sucrose 3,0 Dextrin 15,0 Meat extract 1,0 Yeast extract 2,0 Tryptone soy broth (Oxoid) 5,0 NaCl 0,5 K2HPO4 0,5 MgSO4 x 7 H2O 0,5 FeSO4 x 7 H2O 0,01 Agar 20,0 Preparation: Sterilisation: 20 minutes at 121°C pH before sterilisation: 7,3 Usage: Maintenance Organisms: All Actinomycetes | |||
| 36375 | MEDIUM 55 - for Mycobacterium | ||||
| 123512 | CIP Medium 55 | Medium recipe at CIP |
| 67770 | Observationquinones: MK-9(H2) |
| @ref | Chebi-ID | Metabolite | Utilization activity | Kind of utilization tested | |
|---|---|---|---|---|---|
| 68379 | 17634 ChEBI | D-glucose | - | fermentation | from API Coryne |
| 68379 | 16899 ChEBI | D-mannitol | - | fermentation | from API Coryne |
| 68379 | 16988 ChEBI | D-ribose | - | fermentation | from API Coryne |
| 68379 | 65327 ChEBI | D-xylose | - | fermentation | from API Coryne |
| 68379 | 4853 ChEBI | esculin | - | hydrolysis | from API Coryne |
| 68379 | 5291 ChEBI | gelatin | - | hydrolysis | from API Coryne |
| 68379 | 28087 ChEBI | glycogen | - | fermentation | from API Coryne |
| 123512 | 606565 ChEBI | hippurate | - | hydrolysis | |
| 68379 | 17716 ChEBI | lactose | - | fermentation | from API Coryne |
| 68379 | 17306 ChEBI | maltose | - | fermentation | from API Coryne |
| 68379 | 17632 ChEBI | nitrate | - | reduction | from API Coryne |
| 123512 | 17632 ChEBI | nitrate | + | reduction | |
| 123512 | 17632 ChEBI | nitrate | - | respiration | |
| 123512 | 16301 ChEBI | nitrite | - | reduction | |
| 68379 | 17992 ChEBI | sucrose | + | fermentation | from API Coryne |
| 68379 | 16199 ChEBI | urea | - | hydrolysis | from API Coryne |
| @ref | Value | Activity | Ec | |
|---|---|---|---|---|
| 68382 | acid phosphatase | + | 3.1.3.2 | from API zym |
| 68382 | alpha-fucosidase | - | 3.2.1.51 | from API zym |
| 68382 | alpha-galactosidase | - | 3.2.1.22 | from API zym |
| 68382 | alpha-glucosidase | - | 3.2.1.20 | from API zym |
| 68379 | alpha-glucosidase | - | 3.2.1.20 | from API Coryne |
| 68382 | alpha-mannosidase | - | 3.2.1.24 | from API zym |
| 123512 | amylase | - | ||
| 68382 | beta-galactosidase | - | 3.2.1.23 | from API zym |
| 123512 | beta-galactosidase | - | 3.2.1.23 | |
| 68379 | beta-galactosidase | - | 3.2.1.23 | from API Coryne |
| 68382 | beta-glucosidase | - | 3.2.1.21 | from API zym |
| 68379 | beta-glucosidase | - | 3.2.1.21 | from API Coryne |
| 68382 | beta-glucuronidase | - | 3.2.1.31 | from API zym |
| 68379 | beta-glucuronidase | - | 3.2.1.31 | from API Coryne |
| 123512 | caseinase | - | 3.4.21.50 | |
| 123512 | catalase | + | 1.11.1.6 | |
| 123512 | DNase | - | ||
| 123512 | gamma-glutamyltransferase | - | 2.3.2.2 | |
| 123512 | gelatinase | - | ||
| 68379 | gelatinase | - | from API Coryne | |
| 123512 | lecithinase | - | ||
| 68382 | leucine arylamidase | + | 3.4.11.1 | from API zym |
| 123512 | lipase | - | ||
| 68382 | lipase (C 14) | - | from API zym | |
| 68382 | N-acetyl-beta-glucosaminidase | - | 3.2.1.52 | from API zym |
| 68379 | N-acetyl-beta-glucosaminidase | - | 3.2.1.52 | from API Coryne |
| 123512 | oxidase | - | ||
| 68379 | pyrazinamidase | + | 3.5.1.B15 | from API Coryne |
| 68379 | pyrrolidonyl arylamidase | + | 3.4.19.3 | from API Coryne |
| 123512 | tween esterase | - | ||
| 123512 | urease | + | 3.5.1.5 | |
| 68379 | urease | - | 3.5.1.5 | from API Coryne |
| @ref | pathway | enzyme coverage | annotated reactions | external links | |
|---|---|---|---|---|---|
| 66794 | taurine degradation | 100 | 1 of 1 |   |
|
| 66794 | CDP-diacylglycerol biosynthesis | 100 | 2 of 2 | |
|
| 66794 | octane oxidation | 100 | 3 of 3 | |
|
| 66794 | cyanate degradation | 100 | 3 of 3 | |
|
| 66794 | biotin biosynthesis | 100 | 4 of 4 | |
|
| 66794 | coenzyme A metabolism | 100 | 4 of 4 | |
|
| 66794 | formaldehyde oxidation | 100 | 3 of 3 | |
|
| 66794 | vitamin K metabolism | 100 | 5 of 5 | |
|
| 66794 | threonine metabolism | 100 | 10 of 10 | |
|
| 66794 | cis-vaccenate biosynthesis | 100 | 2 of 2 | |
|
| 66794 | hydrogen production | 100 | 5 of 5 | |
|
| 66794 | glycolate and glyoxylate degradation | 100 | 6 of 6 | |
|
| 66794 | UDP-GlcNAc biosynthesis | 100 | 3 of 3 | |
|
| 66794 | ethylmalonyl-CoA pathway | 100 | 5 of 5 | |
|
| 66794 | methylglyoxal degradation | 100 | 5 of 5 | |
|
| 66794 | butanoate fermentation | 100 | 4 of 4 | |
|
| 66794 | anapleurotic synthesis of oxalacetate | 100 | 1 of 1 | |
|
| 66794 | folate polyglutamylation | 100 | 1 of 1 | |
|
| 66794 | aerobactin biosynthesis | 100 | 1 of 1 | |
|
| 66794 | valine metabolism | 100 | 9 of 9 | |
|
| 66794 | ketogluconate metabolism | 100 | 8 of 8 | |
|
| 66794 | adipate degradation | 100 | 2 of 2 | |
|
| 66794 | enterobactin biosynthesis | 100 | 3 of 3 | |
|
| 66794 | ppGpp biosynthesis | 100 | 4 of 4 | |
|
| 66794 | palmitate biosynthesis | 100 | 22 of 22 | |
|
| 66794 | phenylalanine metabolism | 92.31 | 12 of 13 | |
|
| 66794 | Entner Doudoroff pathway | 90 | 9 of 10 | |
|
| 66794 | starch degradation | 90 | 9 of 10 | |
|
| 66794 | propionate fermentation | 90 | 9 of 10 | |
|
| 66794 | aspartate and asparagine metabolism | 88.89 | 8 of 9 | |
|
| 66794 | chorismate metabolism | 88.89 | 8 of 9 | |
|
| 66794 | C4 and CAM-carbon fixation | 87.5 | 7 of 8 | |
|
| 66794 | propanol degradation | 85.71 | 6 of 7 | |
|
| 66794 | heme metabolism | 85.71 | 12 of 14 | |
|
| 66794 | citric acid cycle | 85.71 | 12 of 14 | |
|
| 66794 | reductive acetyl coenzyme A pathway | 85.71 | 6 of 7 | |
|
| 66794 | photosynthesis | 85.71 | 12 of 14 | |
|
| 66794 | urea cycle | 84.62 | 11 of 13 | |
|
| 66794 | leucine metabolism | 84.62 | 11 of 13 | |
|
| 66794 | vitamin B1 metabolism | 84.62 | 11 of 13 | |
|
| 66794 | NAD metabolism | 83.33 | 15 of 18 | |
|
| 66794 | vitamin B12 metabolism | 82.35 | 28 of 34 | |
|
| 66794 | glutamate and glutamine metabolism | 82.14 | 23 of 28 | |
|
| 66794 | pentose phosphate pathway | 81.82 | 9 of 11 | |
|
| 66794 | flavin biosynthesis | 80 | 12 of 15 | |
|
| 66794 | cellulose degradation | 80 | 4 of 5 | |
|
| 66794 | glycogen metabolism | 80 | 4 of 5 | |
|
| 66794 | peptidoglycan biosynthesis | 80 | 12 of 15 | |
|
| 66794 | phenylacetate degradation (aerobic) | 80 | 4 of 5 | |
|
| 66794 | factor 420 biosynthesis | 80 | 4 of 5 | |
|
| 66794 | CO2 fixation in Crenarchaeota | 77.78 | 7 of 9 | |
|
| 66794 | molybdenum cofactor biosynthesis | 77.78 | 7 of 9 | |
|
| 66794 | serine metabolism | 77.78 | 7 of 9 | |
|
| 66794 | purine metabolism | 77.66 | 73 of 94 | |
|
| 66794 | lipid metabolism | 77.42 | 24 of 31 | |
|
| 66794 | glycogen biosynthesis | 75 | 3 of 4 | |
|
| 66794 | isoleucine metabolism | 75 | 6 of 8 | |
|
| 66794 | toluene degradation | 75 | 3 of 4 | |
|
| 66794 | dTDPLrhamnose biosynthesis | 75 | 6 of 8 | |
|
| 66794 | acetate fermentation | 75 | 3 of 4 | |
|
| 66794 | gluconeogenesis | 75 | 6 of 8 | |
|
| 66794 | sulfopterin metabolism | 75 | 3 of 4 | |
|
| 66794 | 6-hydroxymethyl-dihydropterin diphosphate biosynthesis | 75 | 6 of 8 | |
|
| 66794 | metabolism of disaccharids | 72.73 | 8 of 11 | |
|
| 66794 | alanine metabolism | 72.41 | 21 of 29 | |
|
| 66794 | cardiolipin biosynthesis | 71.43 | 5 of 7 | |
|
| 66794 | ubiquinone biosynthesis | 71.43 | 5 of 7 | |
|
| 66794 | glutathione metabolism | 71.43 | 10 of 14 | |
|
| 66794 | glycolysis | 70.59 | 12 of 17 | |
|
| 66794 | pyrimidine metabolism | 68.89 | 31 of 45 | |
|
| 66794 | androgen and estrogen metabolism | 68.75 | 11 of 16 | |
|
| 66794 | L-lactaldehyde degradation | 66.67 | 2 of 3 | |
|
| 66794 | acetyl CoA biosynthesis | 66.67 | 2 of 3 | |
|
| 66794 | methane metabolism | 66.67 | 2 of 3 | |
|
| 66794 | acetoin degradation | 66.67 | 2 of 3 | |
|
| 66794 | 3-phenylpropionate degradation | 66.67 | 10 of 15 | |
|
| 66794 | non-pathway related | 65.79 | 25 of 38 | |
|
| 66794 | tryptophan metabolism | 65.79 | 25 of 38 | |
|
| 66794 | isoprenoid biosynthesis | 65.38 | 17 of 26 | |
|
| 66794 | bile acid biosynthesis, neutral pathway | 64.71 | 11 of 17 | |
|
| 66794 | tyrosine metabolism | 64.29 | 9 of 14 | |
|
| 66794 | tetrahydrofolate metabolism | 64.29 | 9 of 14 | |
|
| 66794 | oxidative phosphorylation | 63.74 | 58 of 91 | |
|
| 66794 | cholesterol biosynthesis | 63.64 | 7 of 11 | |
|
| 66794 | arginine metabolism | 62.5 | 15 of 24 | |
|
| 66794 | degradation of sugar alcohols | 62.5 | 10 of 16 | |
|
| 66794 | sulfate reduction | 61.54 | 8 of 13 | |
|
| 66794 | cysteine metabolism | 61.11 | 11 of 18 | |
|
| 66794 | arachidonate biosynthesis | 60 | 3 of 5 | |
|
| 66794 | creatinine degradation | 60 | 3 of 5 | |
|
| 66794 | lipoate biosynthesis | 60 | 3 of 5 | |
|
| 66794 | gallate degradation | 60 | 3 of 5 | |
|
| 66794 | histidine metabolism | 58.62 | 17 of 29 | |
|
| 66794 | degradation of aromatic, nitrogen containing compounds | 58.33 | 7 of 12 | |
|
| 66794 | d-mannose degradation | 55.56 | 5 of 9 | |
|
| 66794 | phenol degradation | 55 | 11 of 20 | |
|
| 66794 | proline metabolism | 54.55 | 6 of 11 | |
|
| 66794 | methionine metabolism | 53.85 | 14 of 26 | |
|
| 66794 | cyclohexanol degradation | 50 | 2 of 4 | |
|
| 66794 | suberin monomers biosynthesis | 50 | 1 of 2 | |
|
| 66794 | kanosamine biosynthesis II | 50 | 1 of 2 | |
|
| 66794 | aminopropanol phosphate biosynthesis | 50 | 1 of 2 | |
|
| 66794 | mannosylglycerate biosynthesis | 50 | 1 of 2 | |
|
| 66794 | phenylmercury acetate degradation | 50 | 1 of 2 | |
|
| 66794 | ethanol fermentation | 50 | 1 of 2 | |
|
| 66794 | pantothenate biosynthesis | 50 | 3 of 6 | |
|
| 66794 | vitamin E metabolism | 50 | 2 of 4 | |
|
| 66794 | lipid A biosynthesis | 44.44 | 4 of 9 | |
|
| 66794 | 4-hydroxymandelate degradation | 44.44 | 4 of 9 | |
|
| 66794 | nitrate assimilation | 44.44 | 4 of 9 | |
|
| 66794 | lysine metabolism | 42.86 | 18 of 42 | |
|
| 66794 | benzoyl-CoA degradation | 42.86 | 3 of 7 | |
|
| 66794 | glycine metabolism | 40 | 4 of 10 | |
|
| 66794 | 4-hydroxyphenylacetate degradation | 40 | 4 of 10 | |
|
| 66794 | 3-chlorocatechol degradation | 40 | 2 of 5 | |
|
| 66794 | carnitine metabolism | 37.5 | 3 of 8 | |
|
| 66794 | vitamin B6 metabolism | 36.36 | 4 of 11 | |
|
| 66794 | ascorbate metabolism | 36.36 | 8 of 22 | |
|
| 66794 | carotenoid biosynthesis | 36.36 | 8 of 22 | |
|
| 66794 | selenocysteine biosynthesis | 33.33 | 2 of 6 | |
|
| 66794 | sphingosine metabolism | 33.33 | 2 of 6 | |
|
| 66794 | IAA biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | chlorophyll metabolism | 33.33 | 6 of 18 | |
|
| 66794 | methanogenesis from CO2 | 33.33 | 4 of 12 | |
|
| 66794 | arachidonic acid metabolism | 33.33 | 6 of 18 | |
|
| 66794 | degradation of pentoses | 32.14 | 9 of 28 | |
|
| 66794 | phenylpropanoid biosynthesis | 30.77 | 4 of 13 | |
|
| 66794 | coenzyme M biosynthesis | 30 | 3 of 10 | |
|
| 66794 | degradation of hexoses | 27.78 | 5 of 18 | |
|
| 66794 | d-xylose degradation | 27.27 | 3 of 11 | |
|
| 66794 | lactate fermentation | 25 | 1 of 4 | |
|
| 66794 | catecholamine biosynthesis | 25 | 1 of 4 | |
|
| 66794 | CMP-KDO biosynthesis | 25 | 1 of 4 | |
|
| 66794 | degradation of sugar acids | 24 | 6 of 25 | |
|
| 66794 | phosphatidylethanolamine bioynthesis | 23.08 | 3 of 13 | |
|
| 66794 | daunorubicin biosynthesis | 22.22 | 2 of 9 | |
|
| 66794 | polyamine pathway | 21.74 | 5 of 23 | |
| @ref | Control | Alkaline phosphatase | Esterase (C 4) | 2-naphtyl caprylateEsterase Lipase (C 8) | Lipase (C 14) | L-leucyl-2-naphthylamideLeucine arylamidase | L-valyl-2-naphthylamideValine arylamidase | L-cystyl-2-naphthylamideCystine arylamidase | Trypsin | alpha- Chymotrypsin | Acid phosphatase | Naphthol-AS-BI-phosphateNaphthol-AS-BI-phosphohydrolase | alpha- Galactosidase | beta- Galactosidase | beta- Glucuronidase | alpha- Glucosidase | beta- Glucosidase | N-acetyl-beta- glucosaminidase | alpha- Mannosidase | alpha- Fucosidase | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 20011 | not determinedn.d. | + | + | + | - | + | + | + | + | + | + | + | - | - | - | - | - | - | - | - | |
| 11565 | - | - | +/- | +/- | - | + | - | +/- | - | - | + | - | - | - | - | - | - | - | - | - | |
| 123512 | - | - | + | + | - | + | - | - | - | - | + | + | - | - | - | - | - | - | - | - |
| @ref | Description | Assembly level | INSDC accession | BV-BRC accession | IMG accession | NCBI tax ID | Score | |
|---|---|---|---|---|---|---|---|---|
| 66792 | 50465_H02 assembly for Mycolicibacterium thermoresistibile NCTC10409 | complete | GCA_900187065   | 1797.4  | 2773858053  | 1797 | 98.99 | |
| 67770 | ASM23458v1 assembly for Mycolicibacterium thermoresistibile ATCC 19527 | contig | GCA_000234585 | 1078020.3 | 2519103087 | 1078020 | 67.99 | |
| 66792 | ASM2582232v1 assembly for Mycolicibacterium thermoresistibile DSM 44167 | scaffold | GCA_025822325 | 1797.10 | 8115280191 | 1797 | 61.56 | |
| 67770 | ASM157050v1 assembly for Mycolicibacterium thermoresistibile JCM6362 | scaffold | GCA_001570505 | 1797.3 | 2724679287 | 1797 | 61.39 |
| @ref | Description | Accession | Length | Database | NCBI tax ID | |
|---|---|---|---|---|---|---|
| 20218 | Mycolicibacterium thermoresistibile 16S ribosomal RNA, complete sequence | M29570 | 1359 |  | 1797 | |
| 20218 | M.thermoresistible 16S ribosomal RNA, part | X55602 | 1464 | | 1797 | |
| 20218 | Mycobacterium thermoresistibile strain CIP 105390 16S ribosomal RNA gene, partial sequence | AF547971 | 547 | | 1797 | |
| @ref | GC-content (mol%) | Method | |
|---|---|---|---|
| 67770 | 69 | genome sequence analysis |
| Topic | Title | Authors | Journal | DOI | Year | |
|---|---|---|---|---|---|---|
| Metabolism | Mycobacterial OtsA Structures Unveil Substrate Preference Mechanism and Allosteric Regulation by 2-Oxoglutarate and 2-Phosphoglycerate. | Mendes V, Acebron-Garcia-de-Eulate M, Verma N, Blaszczyk M, Dias MVB, Blundell TL. | mBio | 10.1128/mbio.02272-19 | 2019 | |
| Enzymology | Structure of Mycobacterium thermoresistibile GlgE defines novel conformational states that contribute to the catalytic mechanism. | Mendes V, Blaszczyk M, Maranha A, Empadinhas N, Blundell TL. | Sci Rep | 10.1038/srep17144 | 2015 | |
| A novel real-time PCR assay for specific detection and quantification of Mycobacterium avium subsp. paratuberculosis in milk with the inherent possibility of differentiation between viable and dead cells. | Dzieciol M, Volgger P, Khol J, Baumgartner W, Wagner M, Hein I. | BMC Res Notes | 10.1186/1756-0500-3-251 | 2010 | | |
| Phylogeny | Phylogenomics and Comparative Genomic Studies Robustly Support Division of the Genus Mycobacterium into an Emended Genus Mycobacterium and Four Novel Genera. | Gupta RS, Lo B, Son J. | Front Microbiol | 10.3389/fmicb.2018.00067 | 2018 | |
| Whole-Genome Sequencing of Alcaligenes faecalis HZ01, with Potential to Inhibit Nontuberculous Mycobacterial Growth. | Fernandes HMZ, Conceicao EC, da Silva SP, Machado E, Sisco MC, Sharma A, Lima KVB, da Conceicao ML, da Silva Carvalho AC, Miranda KR, Silva Duarte R, Alviano DS, da Silva Dias RC. | Microbiol Resour Announc | 10.1128/mra.00521-21 | 2021 | | |
| In Vitro Activity of the Sudapyridine (WX-081) against Non-Tuberculous Mycobacteria Isolated in Beijing, China. | Zhu R, Shang Y, Chen S, Xiao H, Ren R, Wang F, Xue Y, Li L, Li Y, Chu N, Huang H. | Microbiol Spectr | 10.1128/spectrum.01372-22 | 2022 | | |
| In Vitro Antimicrobial Activities of Tigecycline, Eravacycline, Omadacycline, and Sarecycline against Rapidly Growing Mycobacteria. | Zhang T, Du J, Dong L, Wang F, Zhao L, Jia J, Wang C, Cheng M, Yu X, Huang H. | Microbiol Spectr | 10.1128/spectrum.03238-22 | 2023 | | |
| In vitro and intracellular inhibitory activities of nosiheptide against Mycobacterium abscessus. | Zhu R, Yu X, Zhang T, Kong Y, Wang F, Jia J, Xue Y, Huang H. | Front Microbiol | 10.3389/fmicb.2022.926361 | 2022 | | |
| Enzymology | Structural characterization of a hypothetical protein: a potential agent involved in trimethylamine metabolism in Catenulispora acidiphila. | Filippova EV, Luan CH, Dunne SF, Kiryukhina O, Minasov G, Shuvalova L, Anderson WF. | J Struct Funct Genomics | 10.1007/s10969-014-9176-z | 2014 | |
| Pathogenicity | In Vitro Activities of Bedaquiline and Delamanid against Nontuberculous Mycobacteria Isolated in Beijing, China. | Yu X, Gao X, Li C, Luo J, Wen S, Zhang T, Ma Y, Dong L, Wang F, Huang H. | Antimicrob Agents Chemother | 10.1128/aac.00031-19 | 2019 | |
| Pathogenicity | N-Acetylglucosamine-1-Phosphate Transferase, WecA, as a Validated Drug Target in Mycobacterium tuberculosis. | Huszar S, Singh V, Polcicova A, Barath P, Barrio MB, Lagrange S, Leblanc V, Nacy CA, Mizrahi V, Mikusova K. | Antimicrob Agents Chemother | 10.1128/aac.01310-17 | 2017 | |
| Mycobacterium thermoresistibile: extrapulmonary infection in a cat. | Willemse T, Groothuis DG, Koeman JP, Beyer EG. | J Clin Microbiol | 10.1128/jcm.21.5.854-856.1985 | 1985 | | |
| Post-translational environmental switch of RadA activity by extein-intein interactions in protein splicing. | Topilina NI, Novikova O, Stanger M, Banavali NK, Belfort M. | Nucleic Acids Res | 10.1093/nar/gkv612 | 2015 | | |
| Enzymology | Understanding specificity of the mycosin proteases in ESX/type VII secretion by structural and functional analysis. | Wagner JM, Evans TJ, Chen J, Zhu H, Houben EN, Bitter W, Korotkov KV. | J Struct Biol | 10.1016/j.jsb.2013.09.022 | 2013 | |
| Phylogeny | Biochip system for rapid and accurate identification of mycobacterial species from isolates and sputum. | Zhu L, Jiang G, Wang S, Wang C, Li Q, Yu H, Zhou Y, Zhao B, Huang H, Xing W, Mitchelson K, Cheng J, Zhao Y, Guo Y. | J Clin Microbiol | 10.1128/jcm.00158-10 | 2010 | |
| Growth of group IV mycobacteria on medium containing various saturated and unsaturated fatty acids. | Saito H, Tomioka H, Yoneyama T. | Antimicrob Agents Chemother | 10.1128/aac.26.2.164 | 1984 | | |
| Bovine Tuberculosis in Wild Boar (Sus scrofa) in Slovenia. | Pate M, Zajc U, Pirs T, Ocepek M, Krt B. | J Wildl Dis | 10.7589/jwd-d-23-00123 | 2024 | | |
| Diagnostic challenge in veterinary pathology: Does negative Ziehl-Neelsen staining rule out mycobacteriosis? | Huupponen A, Ulmanen S, Gronthal T, Lienemann T, Viitanen S, Syrja P. | Vet Pathol | 10.1177/03009858251331342 | 2025 | | |
| A case of severe Mycobacterium thermoresistibile pneumonia. | Subramaniam S, Kanhere M, Shephard L, Burke A, Saxon S, Geake J. | Respirol Case Rep | 10.1002/rcr2.1308 | 2024 | | |
| Disseminated Mycobacterium thermoresistibile Infection presented with Lymphadenectasis in an AIDS patient: case report and review of literature. | Yu L, Wan H, Shi J, Zhang B, Wang M. | BMC Infect Dis | 10.1186/s12879-023-08785-w | 2023 | | |
| The crystal structure of Mycobacterium thermoresistibile MurE ligase reveals the binding mode of the substrate m-diaminopimelate. | Rossini NO, Silva C, Dias MVB. | J Struct Biol | 10.1016/j.jsb.2023.107957 | 2023 | | |
| Phylogeny | Isolation and identification of nontuberculous mycobacteria from raw milk and traditional cheese based on the 16S rRNA and hsp65 genes, Tehran, Iran. | Solaghani TH, Nazari R, Mosavari N, Tadayon K, Zolfaghari MR. | Folia Microbiol (Praha) | 10.1007/s12223-023-01073-9 | 2024 | |
| Crystal structures of Mycobacterium tuberculosis and Mycobacterium thermoresistibile glycyl-tRNA synthetases in various liganded states. | Fenwick MK, DeRocher AE, Craig JK, Harmon EK, Seibold S, Liu L, Battaile KP, Barrett LK, Van Voorhis WC, Phan IQ, Staker BL, Subramanian S, Lovell S, Myler PJ. | PLoS One | 10.1371/journal.pone.0326500 | 2025 | | |
| Selective inhibition of Mycobacterium tuberculosis GpsI unveils a novel strategy to target the RNA metabolism. | Griesser T, Wang R, Angona IP, Rogenmoser J, Obrist J, Schneider G, Sander P. | Nucleic Acids Res | 10.1093/nar/gkaf529 | 2025 | | |
| Enzymology | Covalent inactivation of Mycobacterium thermoresistibile inosine-5'-monophosphate dehydrogenase (IMPDH). | Trapero A, Pacitto A, Chan DS, Abell C, Blundell TL, Ascher DB, Coyne AG. | Bioorg Med Chem Lett | 10.1016/j.bmcl.2019.126792 | 2020 | |
| The structure of Mycobacterium thermoresistibile MmpS5 reveals a conserved disulfide bond across mycobacteria. | Cuthbert BJ, Mendoza J, de Miranda R, Papavinasasundaram K, Sassetti CM, Goulding CW. | Metallomics | 10.1093/mtomcs/mfae011 | 2024 | | |
| Enzymology | Structural insights into the initiation of free radical formation in the Class Ib ribonucleotide reductases in Mycobacteria. | Yadav LR, Sharma V, Shanmugam M, Mande SC. | Curr Res Struct Biol | 10.1016/j.crstbi.2024.100157 | 2024 | |
| Some aspects of the diagnosis and treatment of eosinophilic granuloma in cats. | Omelchenko H, Avramenko N, Kulynych S, Petrenko M, Volosovets V, Volosovets N, Wozniakowski G. | J Vet Res | 10.2478/jvetres-2023-0060 | 2023 | | |
| Cryo-EM structures for the Mycobacterium tuberculosis iron-loaded siderophore transporter IrtAB. | Sun S, Gao Y, Yang X, Yang X, Hu T, Liang J, Xiong Z, Ran Y, Ren P, Bai F, Guddat LW, Yang H, Rao Z, Zhang B. | Protein Cell | 10.1093/procel/pwac060 | 2023 | | |
| Feline mycobacterial disease in northern California: Epidemiology, clinical features, and antimicrobial susceptibility. | Munro MJL, Byrne BA, Sykes JE. | J Vet Intern Med | 10.1111/jvim.16013 | 2021 | | |
| Conversion of a non-heme iron-dependent sulfoxide synthase into a thiol dioxygenase by a single point mutation. | Goncharenko KV, Seebeck FP. | Chem Commun (Camb) | 10.1039/c5cc07772a | 2016 | | |
| An S=1 Iron(IV) Intermediate Revealed in a Non-Heme Iron Enzyme-Catalyzed Oxidative C-S Bond Formation. | Paris JC, Hu S, Wen A, Weitz AC, Cheng R, Gee LB, Tang Y, Kim H, Vegas A, Chang WC, Elliott SJ, Liu P, Guo Y. | Angew Chem Int Ed Engl | 10.1002/anie.202309362 | 2023 | | |
| Structural insights into the convergent evolution of sulfoxide synthase EgtB-IV, an ergothioneine-biosynthetic homolog of ovothiol synthase OvoA. | Ireland KA, Kayrouz CM, Abbott ML, Seyedsayamdost MR, Davis KM. | Structure | 10.1016/j.str.2024.08.006 | 2024 | | |
| Enzymology | Structure of the sulfoxide synthase EgtB from the ergothioneine biosynthetic pathway. | Goncharenko KV, Vit A, Blankenfeldt W, Seebeck FP. | Angew Chem Int Ed Engl | 10.1002/anie.201410045 | 2015 | |
| Structural and mechanistic analysis of ATPase inhibitors targeting mycobacterial DNA gyrase. | Henderson SR, Stevenson CEM, Malone B, Zholnerovych Y, Mitchenall LA, Pichowicz M, McGarry DH, Cooper IR, Charrier C, Salisbury AM, Lawson DM, Maxwell A. | J Antimicrob Chemother | 10.1093/jac/dkaa286 | 2020 | | |
| Phylogeny | Infection due to Mycobacterium thermoresistibile: a case associated with an orthopedic device. | Suy F, Carricajo A, Grattard F, Cazorla C, Denis C, Girardin P, Lucht F, Botelho-Nevers E. | J Clin Microbiol | 10.1128/jcm.00925-13 | 2013 | |
| Mycobacterial panniculitis caused by Mycobacterium thermoresistibile in a cat. | Vishkautsan P, Reagan KL, Keel MK, Sykes JE. | JFMS Open Rep | 10.1177/2055116916672786 | 2016 | | |
| Prevalence of nontuberculous mycobacteria and high efficacy of d-cycloserine and its synergistic effect with clarithromycin against Mycobacterium fortuitum and Mycobacterium abscessus. | Khosravi AD, Mirsaeidi M, Farahani A, Tabandeh MR, Mohajeri P, Shoja S, Hoseini Lar KhosroShahi SR. | Infect Drug Resist | 10.2147/idr.s187554 | 2018 | | |
| Phylogeny | Mycobacterium thermoresistibile: case report of a rarely isolated mycobacterium from Europe and review of literature. | Neonakis IK, Gitti Z, Kontos F, Baritaki S, Petinaki E, Baritaki M, Zerva L, Spandidos DA. | Indian J Med Microbiol | 10.4103/0255-0857.53214 | 2009 | |
| The Mycobacterium tuberculosis mycothiol S-transferase is divalent metal-dependent for mycothiol binding and transfer. | Jayasinghe YP, Banco MT, Lindenberger JJ, Favrot L, Palcekova Z, Jackson M, Manabe S, Ronning DR. | RSC Med Chem | 10.1039/d2md00401a | 2023 | | |
| The mycobacterial ABC transporter IrtAB employs a membrane-facing crevice for siderophore-mediated iron uptake. | Gonda I, Sorrentino S, Galazzo L, Lichti NP, Arnold FM, Mehdipour AR, Bordignon E, Seeger MA. | Nat Commun | 10.1038/s41467-024-55136-7 | 2025 | | |
| Mycobacterial Epoxide Hydrolase EphD Is Inhibited by Urea and Thiourea Derivatives. | Madacki J, Kopal M, Jackson M, Kordulakova J. | Int J Mol Sci | 10.3390/ijms22062884 | 2021 | | |
| Mycobacterium thermoresistibile as a source of thermostable orthologs of Mycobacterium tuberculosis proteins. | Edwards TE, Liao R, Phan I, Myler PJ, Grundner C. | Protein Sci | 10.1002/pro.2084 | 2012 | | |
| A Single Aspergillus fumigatus Gene Enables Ergothioneine Biosynthesis and Secretion by Saccharomyces cerevisiae. | Doyle S, Cuskelly DD, Conlon N, Fitzpatrick DA, Gilmartin CB, Dix SH, Jones GW. | Int J Mol Sci | 10.3390/ijms231810832 | 2022 | | |
| Enzymology | The crystal structure of mycobacterial epoxide hydrolase A. | Schulz EC, Henderson SR, Illarionov B, Crosskey T, Southall SM, Krichel B, Uetrecht C, Fischer M, Wilmanns M. | Sci Rep | 10.1038/s41598-020-73452-y | 2020 | |
| Genetics | Genomic Degeneration and Reduction in the Fish Pathogen Mycobacterium shottsii. | Gauthier DT, Doss JH, LaGatta M, Gupta T, Karls RK, Quinn FD. | Microbiol Spectr | 10.1128/spectrum.01158-21 | 2022 | |
| Enzymology | Expression and production of soluble Mycobacterium tuberculosis H37Rv mycosin-3. | Fang Z, Schubert WD, Gey van Pittius NC. | Biochem Biophys Rep | 10.1016/j.bbrep.2016.02.005 | 2016 | |
| Mycobacterium gilvum illustrates size-correlated relationships between mycobacteria and Acanthamoeba polyphaga. | Lamrabet O, Drancourt M. | Appl Environ Microbiol | 10.1128/aem.03765-12 | 2013 | | |
| First report of nodular skin lesions caused by Mycobacterium nebraskense in a 9-year-old cat. | Niederhauser S, Klauser L, Bolliger J, Friedel U, Schmitt S, Ruetten M, Greene CE, Ghielmetti G. | JFMS Open Rep | 10.1177/2055116918792685 | 2018 | | |
| Phylogeny | Mycobacterium thermoresistibile infection following knee-replacement surgery. | LaBombardi VJ, Shastry L, Tischler H. | J Clin Microbiol | 10.1128/jcm.43.10.5393-5394.2005 | 2005 | |
| Crystal Structure of the Ergothioneine Sulfoxide Synthase from Candidatus Chloracidobacterium thermophilum and Structure-Guided Engineering To Modulate Its Substrate Selectivity. | Naowarojna N, Irani S, Hu W, Cheng R, Zhang L, Li X, Chen J, Zhang YJ, Liu P. | ACS Catal | 10.1021/acscatal.9b02054 | 2019 | | |
| Comparative genome analyses of mycobacteria give better insights into their evolution. | Wee WY, Dutta A, Choo SW. | PLoS One | 10.1371/journal.pone.0172831 | 2017 | | |
| Metabolism | Temperature-induced changes in the cell-wall components of Mycobacterium thermoresistibile. | Kremer L, Guerardel Y, Gurcha SS, Locht C, Besra GS. | Microbiology (Reading) | 10.1099/00221287-148-10-3145 | 2002 | |
| Phylogeny | Chronic pneumonia caused by Mycobacterium thermoresistibile in a cat. | Foster SF, Martin P, Davis W, Allan GS, Mitchell DH, Malik R. | J Small Anim Pract | 10.1111/j.1748-5827.1999.tb03118.x | 1999 | |
| Metabolism | Nonheme iron-thiolate complexes as structural models of sulfoxide synthase active sites. | Ekanayake DM, Fischer AA, Elwood ME, Guzek AM, Lindeman SV, Popescu CV, Fiedler AT. | Dalton Trans | 10.1039/d0dt03403g | 2020 | |
| Enzymology | Structure of nitrilotriacetate monooxygenase component B from Mycobacterium thermoresistibile. | Zhang Y, Edwards TE, Begley DW, Abramov A, Thompkins KB, Ferrell M, Guo WJ, Phan I, Olsen C, Napuli A, Sankaran B, Stacy R, Van Voorhis WC, Stewart LJ, Myler PJ. | Acta Crystallogr Sect F Struct Biol Cryst Commun | 10.1107/s1744309111012541 | 2011 | |
| Enzymology | Shedding light on ovothiol biosynthesis in marine metazoans. | Castellano I, Migliaccio O, D'Aniello S, Merlino A, Napolitano A, Palumbo A. | Sci Rep | 10.1038/srep21506 | 2016 | |
| Enzymology | Crystallization and preliminary X-ray analysis of the reductase component of p-hydroxyphenylacetate 3-hydroxylase from Acinetobacter baumannii. | Oonanant W, Sucharitakul J, Chaiyen P, Yuvaniyama J. | Acta Crystallogr Sect F Struct Biol Cryst Commun | 10.1107/s1744309112016909 | 2012 | |
| Critical Role of Zur and SmtB in Zinc Homeostasis of Mycobacterium smegmatis. | Goethe E, Laarmann K, Luhrs J, Jarek M, Meens J, Lewin A, Goethe R. | mSystems | 10.1128/msystems.00880-19 | 2020 | | |
| Use of a Tyrosine Analogue To Modulate the Two Activities of a Nonheme Iron Enzyme OvoA in Ovothiol Biosynthesis, Cysteine Oxidation versus Oxidative C-S Bond Formation. | Chen L, Naowarojna N, Song H, Wang S, Wang J, Deng Z, Zhao C, Liu P. | J Am Chem Soc | 10.1021/jacs.7b13628 | 2018 | | |
| Enzymology | Differentiation of Mycobacterium thermoresistibile from Mycobacterium phlei and other rapidly growing mycobacteria. | Levy-Frebault V, Daffe M, Restrepo E, Grimont F, Grimont PA, David HL. | Ann Inst Pasteur Microbiol (1985) | 10.1016/s0769-2609(86)80019-9 | 1986 | |
| Metabolism | Crystal structures of TdsC, a dibenzothiophene monooxygenase from the thermophile Paenibacillus sp. A11-2, reveal potential for expanding its substrate selectivity. | Hino T, Hamamoto H, Suzuki H, Yagi H, Ohshiro T, Nagano S. | J Biol Chem | 10.1074/jbc.m117.788513 | 2017 | |
| Metabolism | Mycobacterium tuberculosis utilizes a unique heterotetrameric structure for dehydrogenation of the cholesterol side chain. | Thomas ST, Sampson NS. | Biochemistry | 10.1021/bi4002979 | 2013 | |
| Metabolism | Camphor pathway redux: functional recombinant expression of 2,5- and 3,6-diketocamphane monooxygenases of Pseudomonas putida ATCC 17453 with their cognate flavin reductase catalyzing Baeyer-Villiger reactions. | Iwaki H, Grosse S, Bergeron H, Leisch H, Morley K, Hasegawa Y, Lau PC. | Appl Environ Microbiol | 10.1128/aem.03958-12 | 2013 | |
| SAD phasing using iodide ions in a high-throughput structural genomics environment. | Abendroth J, Gardberg AS, Robinson JI, Christensen JS, Staker BL, Myler PJ, Stewart LJ, Edwards TE. | J Struct Funct Genomics | 10.1007/s10969-011-9101-7 | 2011 | | |
| Mycobacterium thermoresistibile infection in an immunocompromised host. | Liu F, Andrews D, Wright DN. | J Clin Microbiol | 10.1128/jcm.19.4.546-547.1984 | 1984 | | |
| Genetics | Metagenomic analysis of microbial consortia enriched from compost: new insights into the role of Actinobacteria in lignocellulose decomposition. | Wang C, Dong D, Wang H, Muller K, Qin Y, Wang H, Wu W. | Biotechnol Biofuels | 10.1186/s13068-016-0440-2 | 2016 | |
| Mycobacterium thermoresistibile: a new pathogen for humans. | Weitzman I, Osadczyi D, Corrado ML, Karp D. | J Clin Microbiol | 10.1128/jcm.14.5.593-595.1981 | 1981 | | |
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| Metabolism | Identification of the S-transferase like superfamily bacillithiol transferases encoded by Bacillus subtilis. | Perera VR, Lapek JD, Newton GL, Gonzalez DJ, Pogliano K. | PLoS One | 10.1371/journal.pone.0192977 | 2018 | |
| Enzymology | Ligand-bound Structures and Site-directed Mutagenesis Identify the Acceptor and Secondary Binding Sites of Streptomyces coelicolor Maltosyltransferase GlgE. | Syson K, Stevenson CE, Miah F, Barclay JE, Tang M, Gorelik A, Rashid AM, Lawson DM, Bornemann S. | J Biol Chem | 10.1074/jbc.m116.748160 | 2016 | |
| Metabolism | Mycosins Are Required for the Stabilization of the ESX-1 and ESX-5 Type VII Secretion Membrane Complexes. | van Winden VJ, Ummels R, Piersma SR, Jimenez CR, Korotkov KV, Bitter W, Houben EN. | mBio | 10.1128/mbio.01471-16 | 2016 | |
| Pathogenicity | The Inosine Monophosphate Dehydrogenase, GuaB2, Is a Vulnerable New Bactericidal Drug Target for Tuberculosis. | Singh V, Donini S, Pacitto A, Sala C, Hartkoorn RC, Dhar N, Keri G, Ascher DB, Mondesert G, Vocat A, Lupien A, Sommer R, Vermet H, Lagrange S, Buechler J, Warner DF, McKinney JD, Pato J, Cole ST, Blundell TL, Rizzi M, Mizrahi V. | ACS Infect Dis | 10.1021/acsinfecdis.6b00102 | 2017 | |
| Metabolism | Exposure of mycobacteria to cell wall-inhibitory drugs decreases production of arabinoglycerolipid related to Mycolyl-arabinogalactan-peptidoglycan metabolism. | Rombouts Y, Brust B, Ojha AK, Maes E, Coddeville B, Elass-Rochard E, Kremer L, Guerardel Y. | J Biol Chem | 10.1074/jbc.m111.327387 | 2012 | |
| Enzymology | The C-terminal domain of 4-hydroxyphenylacetate 3-hydroxylase from Acinetobacter baumannii is an autoinhibitory domain. | Phongsak T, Sucharitakul J, Thotsaporn K, Oonanant W, Yuvaniyama J, Svasti J, Ballou DP, Chaiyen P. | J Biol Chem | 10.1074/jbc.m112.354472 | 2012 | |
| Metabolism | Temperature-dependent regulation of mycolic acid cyclopropanation in saprophytic mycobacteria: role of the Mycobacterium smegmatis 1351 gene (MSMEG_1351) in CIS-cyclopropanation of alpha-mycolates. | Alibaud L, Alahari A, Trivelli X, Ojha AK, Hatfull GF, Guerardel Y, Kremer L. | J Biol Chem | 10.1074/jbc.m110.125724 | 2010 | |
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| Specificities and functions of the recA and pps1 intein genes of Mycobacterium tuberculosis and application for diagnosis of tuberculosis. | Saves I, Lewis LA, Westrelin F, Warren R, Daffe M, Masson JM. | J Clin Microbiol | 10.1128/jcm.40.3.943-950.2002 | 2002 | | |
| Metabolism | Characterization of Mycobacterium leprae RecA intein, a LAGLIDADG homing endonuclease, reveals a unique mode of DNA binding, helical distortion, and cleavage compared with a canonical LAGLIDADG homing endonuclease. | Singh P, Tripathi P, Silva GH, Pingoud A, Muniyappa K. | J Biol Chem | 10.1074/jbc.m109.042861 | 2009 | |
| Enzymology | Novel diagnostic algorithm for identification of mycobacteria using genus-specific amplification of the 16S-23S rRNA gene spacer and restriction endonucleases. | Roth A, Reischl U, Streubel A, Naumann L, Kroppenstedt RM, Habicht M, Fischer M, Mauch H. | J Clin Microbiol | 10.1128/jcm.38.3.1094-1104.2000 | 2000 | |
| Genetics | Genome-Based Taxonomic Classification of the Phylum Actinobacteria. | Nouioui I, Carro L, Garcia-Lopez M, Meier-Kolthoff JP, Woyke T, Kyrpides NC, Pukall R, Klenk HP, Goodfellow M, Goker M. | Front Microbiol | 10.3389/fmicb.2018.02007 | 2018 | |
| Genomics Insights into Mycolicibacterium Hassiacum Causing Infection in a Cat with Pyogranulomatous Dermatitis and Panniculitis. | Smedile D, Iurescia M, Carfora V, Cocumelli C, Palmerini T, Diaconu EL, Congiu I, Donati V, Stravino F, Sorbara L, Romano E, Caprioli A, Battisti A. | Pathogens | 10.3390/pathogens13090785 | 2024 | |
How to citeIf you want to cite this particular strain cite the following doi:
https://doi.org/10.13145/bacdive8425.20251217.10
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BacDive in 2025: the core database for prokaryotic strain data
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