Streptoalloteichus hindustanus Bristol Labs C 677-91 is a spore-forming, mesophilic prokaryote that builds an aerial mycelium and produces antibiotic compounds.
antibiotic compound production spore-forming mesophilic genome sequence 16S sequence
SI-ID 308588
| @ref 20215 |
|
Last LPSN update
2025-12-16 09:50:06 |
| Domain Bacillati |
| Phylum Actinomycetota |
| Class Actinomycetes |
| Order Pseudonocardiales |
| Family Pseudonocardiaceae |
| Genus Streptoalloteichus |
| Species Streptoalloteichus hindustanus |
| Full scientific name Streptoalloteichus hindustanus (ex Tomita et al. 1978) Tomita et al. 1987 |
| Synonyms (1) |
| BacDive ID | Other strains from Streptoalloteichus hindustanus (1) | Type strain |
|---|---|---|
| 164330 | S. hindustanus JCM 3269, ATCC 31158 |
| @ref | Name | Growth | Medium link | Composition | |
|---|---|---|---|---|---|
| 11730 | GYM STREPTOMYCES MEDIUM (DSMZ Medium 65) | Medium recipe at MediaDive  | Name: GYM STREPTOMYCES MEDIUM (DSMZ Medium 65) Composition: Agar 18.0 g/l Malt extract 10.0 g/l Yeast extract 4.0 g/l Glucose 4.0 g/l CaCO3 2.0 g/l Distilled water | ||
| 19673 | ISP 2 | Name: ISP 2 / Yeast Malt Agar (5265); 5265 Composition Malt extract 10.0 g/l Yeast extract 4.0 g/l Glucose 4.0 g/l Agar 15.0 g/l Preparation: Sterilisation: 20 minutes at 121°C pH before sterilisation: 7.0 Usage: Maintenance and Taxonomy Organisms: All Actinomycetes | |||
| 19673 | ISP 3 | Name: ISP 3; 5315 Composition Dog oat flakes 20.0 g/l Trace element solution (5314) 2.5 ml/l Agar 18.0 g/l Preparation: Oat flakes are cooked for 20 minutes, trace element solution and agar are added (in the case of non rolled oat flakes the suspension has to bee filtrated). Sterilisation: 20 minutes at 121°C pH before sterilisation: 7.8 Usage: Maintenance and taxonomy (e.g. SEM As liquid medium for metabolite production) Organisms: All Actinomycetes Trace element solution 5314 Name: Trace element solution 5314; 5314 Composition CaCl2 x H2O 3.0 g/l Fe-III-citrate 1.0 g/l MnSO4 0.2 g/l ZnCl2 0.1 g/l CuSO4 x 5 H2O 0.025 g/l Sodium tetra borate 0.2 g/l CoCl2 x 6 H2O 0.004 g/l Sodium molybdate 0.01 g/l Preparation: Use double destillated water. Sterilisation: 20 minutes at 121°C pH before sterilisation: Usage: Trace element solution for different media Organisms: | |||
| 19673 | ISP 4 | Name: ISP 4; DSM 547 Solution I: Difco soluble starch, 10.0 g. Make a paste of the starch with a small amount of cold distilled water and bring to a volume of 500 ml. Solution II: CaCO3 2.0 g K2HPO4 (anhydrous) 1.0 g MgSO4 x 7 H2O 1.0 g NaCl 1.0 g (NH4)2SO4 2.0 g Distilled water 500.0 ml Trace salt solution (see below) 1.0 ml The pH should be between 7.0 and 7.4. Do not adjust if it is within this range. Mix solutions I and II together. Add 20.0 g agar. Liquify agar by steaming at 100°C for 10 to 20 min. Trace element solution: FeSO4 x 7 H2O 0.1 g MnCl2 x 4 H2O 0.1 g ZnSO4 x 7 H2O 0.1 g Distilled water 100.0 ml | |||
| 19673 | ISP 5 | Name: ISP 5 (5323) Composition L-Asparagine 1.0 g/l Glycerol 10.0 g/l K2HPO4 1.0 g/l Salt solution (see preparation) 1.0 ml/l Agar 20.0 g/l Preparation: Salt solution 1.0 g FeSO4 x 7 H2O 1.0 g MnCl2 x 4 H2O 1.0 g ZNSO4 x 7 H2O in 100 ml water Sterilisation: 20 minutes at 121°C pH before sterilisation: 7.2 Usage: Maintenance and taxonomy Organisms: All Actinomycetes | |||
| 19673 | ISP 6 | Name: ISP 6 (5318) Composition Peptone 15.0 g/l Proteose peptose 5.0 g/l Ferric ammonium citrate 0.5 g/l Sodium glycerophosphate 1.0 g/l Sodium thiosulfate 0.08 g/l Yeast extract 1.0 g/l Agar 15.0 g/l Sterilisation: 20 minutes at 121°C pH before sterilisation: Usage: Production of melanoid pigments Organisms: All Actinomycetes | |||
| 19673 | ISP 7 | Name: ISP 7 (5322) Composition Glycerol 15.0 g/l L-Tyrosine 0.5 g/l L-Asparagine 1.0 g/l K2HPO4 0.5 g/l NaCl 0.5 g/l FeSO4 x 7 H2O 0.01 g/l Trace element solution 5343 1.0 ml/l Agar 20.0 Sterilisation: 20 minutes at 121°C pH before sterilisation: 7.3 Usage: Production of melanoid pigments Organisms: All Actinomycetes |
| @ref | Oxygen tolerance | Confidence | |
|---|---|---|---|
| 125439 | obligate aerobe | 98.1 |
| @ref | Salt | Growth | Tested relation | Concentration | |
|---|---|---|---|---|---|
| 19673 | NaCl | positive | maximum | 2.5 % |
| 67770 | Observationquinones: MK-9(H6), MK-10(H6) |
| @ref | Chebi-ID | Metabolite | Utilization activity | Kind of utilization tested | |
|---|---|---|---|---|---|
| 19673 | 22599 ChEBI | arabinose | - | ||
| 68368 | 29016 ChEBI | arginine | + | hydrolysis | from API 20E |
| 19673 | 62968 ChEBI | cellulose | - | ||
| 68368 | 16947 ChEBI | citrate | + | assimilation | from API 20E |
| 19673 | 28757 ChEBI | fructose | + | ||
| 68368 | 5291 ChEBI | gelatin | + | hydrolysis | from API 20E |
| 19673 | 17234 ChEBI | glucose | + | ||
| 68368 | 25094 ChEBI | lysine | + | degradation | from API 20E |
| 19673 | 29864 ChEBI | mannitol | - | ||
| 19673 | 17268 ChEBI | myo-inositol | - | ||
| 68368 | 18257 ChEBI | ornithine | + | degradation | from API 20E |
| 19673 | 16634 ChEBI | raffinose | - | ||
| 19673 | 26546 ChEBI | rhamnose | + | ||
| 19673 | 17992 ChEBI | sucrose | + | ||
| 68368 | 27897 ChEBI | tryptophan | - | energy source | from API 20E |
| 68368 | 16199 ChEBI | urea | - | hydrolysis | from API 20E |
| 19673 | 18222 ChEBI | xylose | + |
| @ref | Value | Activity | Ec | |
|---|---|---|---|---|
| 68382 | acid phosphatase | + | 3.1.3.2 | from API zym |
| 68382 | alkaline phosphatase | + | 3.1.3.1 | from API zym |
| 68382 | alpha-chymotrypsin | + | 3.4.21.1 | 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 |
| 68382 | alpha-mannosidase | - | 3.2.1.24 | from API zym |
| 68368 | arginine dihydrolase | + | 3.5.3.6 | from API 20E |
| 68382 | beta-galactosidase | + | 3.2.1.23 | from API zym |
| 68368 | beta-galactosidase | - | 3.2.1.23 | from API 20E |
| 68382 | beta-glucosidase | - | 3.2.1.21 | from API zym |
| 68382 | beta-glucuronidase | - | 3.2.1.31 | from API zym |
| 68382 | cystine arylamidase | + | 3.4.11.3 | from API zym |
| 68382 | esterase (C 4) | - | from API zym | |
| 68382 | esterase lipase (C 8) | + | from API zym | |
| 68368 | gelatinase | + | from API 20E | |
| 68382 | leucine arylamidase | + | 3.4.11.1 | from API zym |
| 68382 | lipase (C 14) | - | from API zym | |
| 68368 | lysine decarboxylase | + | 4.1.1.18 | from API 20E |
| 68382 | N-acetyl-beta-glucosaminidase | + | 3.2.1.52 | from API zym |
| 68382 | naphthol-AS-BI-phosphohydrolase | + | from API zym | |
| 68368 | ornithine decarboxylase | + | 4.1.1.17 | from API 20E |
| 68382 | trypsin | + | 3.4.21.4 | from API zym |
| 68368 | tryptophan deaminase | - | 4.1.99.1 | from API 20E |
| 68368 | urease | - | 3.5.1.5 | from API 20E |
| 68382 | valine arylamidase | + | from API zym |
| @ref | pathway | enzyme coverage | annotated reactions | external links | |
|---|---|---|---|---|---|
| 66794 | starch degradation | 100 | 10 of 10 |   |
|
| 66794 | cis-vaccenate biosynthesis | 100 | 2 of 2 | |
|
| 66794 | Entner Doudoroff pathway | 100 | 10 of 10 | |
|
| 66794 | daunorubicin biosynthesis | 100 | 9 of 9 | |
|
| 66794 | cardiolipin biosynthesis | 100 | 7 of 7 | |
|
| 66794 | threonine metabolism | 100 | 10 of 10 | |
|
| 66794 | ethanol fermentation | 100 | 2 of 2 | |
|
| 66794 | enterobactin biosynthesis | 100 | 3 of 3 | |
|
| 66794 | adipate degradation | 100 | 2 of 2 | |
|
| 66794 | acetate fermentation | 100 | 4 of 4 | |
|
| 66794 | 3-chlorocatechol degradation | 100 | 5 of 5 | |
|
| 66794 | palmitate biosynthesis | 100 | 22 of 22 | |
|
| 66794 | ppGpp biosynthesis | 100 | 4 of 4 | |
|
| 66794 | biotin biosynthesis | 100 | 4 of 4 | |
|
| 66794 | methylglyoxal degradation | 100 | 5 of 5 | |
|
| 66794 | valine metabolism | 100 | 9 of 9 | |
|
| 66794 | vitamin K metabolism | 100 | 5 of 5 | |
|
| 66794 | taurine degradation | 100 | 1 of 1 | |
|
| 66794 | formaldehyde oxidation | 100 | 3 of 3 | |
|
| 66794 | folate polyglutamylation | 100 | 1 of 1 | |
|
| 66794 | CDP-diacylglycerol biosynthesis | 100 | 2 of 2 | |
|
| 66794 | glycine betaine biosynthesis | 100 | 5 of 5 | |
|
| 66794 | aerobactin biosynthesis | 100 | 1 of 1 | |
|
| 66794 | UDP-GlcNAc biosynthesis | 100 | 3 of 3 | |
|
| 66794 | glycolate and glyoxylate degradation | 100 | 6 of 6 | |
|
| 66794 | phenylacetate degradation (aerobic) | 100 | 5 of 5 | |
|
| 66794 | anapleurotic synthesis of oxalacetate | 100 | 1 of 1 | |
|
| 66794 | suberin monomers biosynthesis | 100 | 2 of 2 | |
|
| 66794 | cellulose degradation | 100 | 5 of 5 | |
|
| 66794 | aminopropanol phosphate biosynthesis | 100 | 2 of 2 | |
|
| 66794 | coenzyme A metabolism | 100 | 4 of 4 | |
|
| 66794 | tetrahydrofolate metabolism | 92.86 | 13 of 14 | |
|
| 66794 | phenylalanine metabolism | 92.31 | 12 of 13 | |
|
| 66794 | myo-inositol biosynthesis | 90 | 9 of 10 | |
|
| 66794 | molybdenum cofactor biosynthesis | 88.89 | 8 of 9 | |
|
| 66794 | serine metabolism | 88.89 | 8 of 9 | |
|
| 66794 | chorismate metabolism | 88.89 | 8 of 9 | |
|
| 66794 | aspartate and asparagine metabolism | 88.89 | 8 of 9 | |
|
| 66794 | CO2 fixation in Crenarchaeota | 88.89 | 8 of 9 | |
|
| 66794 | isoleucine metabolism | 87.5 | 7 of 8 | |
|
| 66794 | dTDPLrhamnose biosynthesis | 87.5 | 7 of 8 | |
|
| 66794 | polyamine pathway | 86.96 | 20 of 23 | |
|
| 66794 | heme metabolism | 85.71 | 12 of 14 | |
|
| 66794 | reductive acetyl coenzyme A pathway | 85.71 | 6 of 7 | |
|
| 66794 | aclacinomycin biosynthesis | 85.71 | 6 of 7 | |
|
| 66794 | purine metabolism | 85.11 | 80 of 94 | |
|
| 66794 | urea cycle | 84.62 | 11 of 13 | |
|
| 66794 | pyrimidine metabolism | 84.44 | 38 of 45 | |
|
| 66794 | NAD metabolism | 83.33 | 15 of 18 | |
|
| 66794 | glycolysis | 82.35 | 14 of 17 | |
|
| 66794 | pentose phosphate pathway | 81.82 | 9 of 11 | |
|
| 66794 | glycogen metabolism | 80 | 4 of 5 | |
|
| 66794 | hydrogen production | 80 | 4 of 5 | |
|
| 66794 | flavin biosynthesis | 80 | 12 of 15 | |
|
| 66794 | metabolism of amino sugars and derivatives | 80 | 4 of 5 | |
|
| 66794 | ethylmalonyl-CoA pathway | 80 | 4 of 5 | |
|
| 66794 | factor 420 biosynthesis | 80 | 4 of 5 | |
|
| 66794 | propionate fermentation | 80 | 8 of 10 | |
|
| 66794 | peptidoglycan biosynthesis | 80 | 12 of 15 | |
|
| 66794 | alanine metabolism | 79.31 | 23 of 29 | |
|
| 66794 | glutathione metabolism | 78.57 | 11 of 14 | |
|
| 66794 | tyrosine metabolism | 78.57 | 11 of 14 | |
|
| 66794 | photosynthesis | 78.57 | 11 of 14 | |
|
| 66794 | glutamate and glutamine metabolism | 78.57 | 22 of 28 | |
|
| 66794 | d-mannose degradation | 77.78 | 7 of 9 | |
|
| 66794 | allantoin degradation | 77.78 | 7 of 9 | |
|
| 66794 | leucine metabolism | 76.92 | 10 of 13 | |
|
| 66794 | non-pathway related | 76.32 | 29 of 38 | |
|
| 66794 | tryptophan metabolism | 76.32 | 29 of 38 | |
|
| 66794 | histidine metabolism | 75.86 | 22 of 29 | |
|
| 66794 | sulfopterin metabolism | 75 | 3 of 4 | |
|
| 66794 | glycogen biosynthesis | 75 | 3 of 4 | |
|
| 66794 | C4 and CAM-carbon fixation | 75 | 6 of 8 | |
|
| 66794 | butanoate fermentation | 75 | 3 of 4 | |
|
| 66794 | ketogluconate metabolism | 75 | 6 of 8 | |
|
| 66794 | CMP-KDO biosynthesis | 75 | 3 of 4 | |
|
| 66794 | 6-hydroxymethyl-dihydropterin diphosphate biosynthesis | 75 | 6 of 8 | |
|
| 66794 | gluconeogenesis | 75 | 6 of 8 | |
|
| 66794 | vitamin B12 metabolism | 73.53 | 25 of 34 | |
|
| 66794 | methionine metabolism | 73.08 | 19 of 26 | |
|
| 66794 | proline metabolism | 72.73 | 8 of 11 | |
|
| 66794 | metabolism of disaccharids | 72.73 | 8 of 11 | |
|
| 66794 | citric acid cycle | 71.43 | 10 of 14 | |
|
| 66794 | lysine metabolism | 71.43 | 30 of 42 | |
|
| 66794 | lipid metabolism | 70.97 | 22 of 31 | |
|
| 66794 | oxidative phosphorylation | 70.33 | 64 of 91 | |
|
| 66794 | glycine metabolism | 70 | 7 of 10 | |
|
| 66794 | acetyl CoA biosynthesis | 66.67 | 2 of 3 | |
|
| 66794 | octane oxidation | 66.67 | 2 of 3 | |
|
| 66794 | selenocysteine biosynthesis | 66.67 | 4 of 6 | |
|
| 66794 | L-lactaldehyde degradation | 66.67 | 2 of 3 | |
|
| 66794 | acetoin degradation | 66.67 | 2 of 3 | |
|
| 66794 | arginine metabolism | 66.67 | 16 of 24 | |
|
| 66794 | 4-hydroxymandelate degradation | 66.67 | 6 of 9 | |
|
| 66794 | cyanate degradation | 66.67 | 2 of 3 | |
|
| 66794 | isoprenoid biosynthesis | 65.38 | 17 of 26 | |
|
| 66794 | d-xylose degradation | 63.64 | 7 of 11 | |
|
| 66794 | degradation of sugar alcohols | 62.5 | 10 of 16 | |
|
| 66794 | cysteine metabolism | 61.11 | 11 of 18 | |
|
| 66794 | lipoate biosynthesis | 60 | 3 of 5 | |
|
| 66794 | bile acid biosynthesis, neutral pathway | 58.82 | 10 of 17 | |
|
| 66794 | ubiquinone biosynthesis | 57.14 | 4 of 7 | |
|
| 66794 | nitrate assimilation | 55.56 | 5 of 9 | |
|
| 66794 | phenol degradation | 55 | 11 of 20 | |
|
| 66794 | sulfate reduction | 53.85 | 7 of 13 | |
|
| 66794 | toluene degradation | 50 | 2 of 4 | |
|
| 66794 | mannosylglycerate biosynthesis | 50 | 1 of 2 | |
|
| 66794 | kanosamine biosynthesis II | 50 | 1 of 2 | |
|
| 66794 | catecholamine biosynthesis | 50 | 2 of 4 | |
|
| 66794 | degradation of aromatic, nitrogen containing compounds | 50 | 6 of 12 | |
|
| 66794 | degradation of hexoses | 50 | 9 of 18 | |
|
| 66794 | resorcinol degradation | 50 | 1 of 2 | |
|
| 66794 | sphingosine metabolism | 50 | 3 of 6 | |
|
| 66794 | vitamin E metabolism | 50 | 2 of 4 | |
|
| 66794 | phenylmercury acetate degradation | 50 | 1 of 2 | |
|
| 66794 | phenylpropanoid biosynthesis | 46.15 | 6 of 13 | |
|
| 66794 | phosphatidylethanolamine bioynthesis | 46.15 | 6 of 13 | |
|
| 66794 | vitamin B1 metabolism | 46.15 | 6 of 13 | |
|
| 66794 | carotenoid biosynthesis | 45.45 | 10 of 22 | |
|
| 66794 | ascorbate metabolism | 45.45 | 10 of 22 | |
|
| 66794 | lipid A biosynthesis | 44.44 | 4 of 9 | |
|
| 66794 | androgen and estrogen metabolism | 43.75 | 7 of 16 | |
|
| 66794 | propanol degradation | 42.86 | 3 of 7 | |
|
| 66794 | coenzyme M biosynthesis | 40 | 4 of 10 | |
|
| 66794 | arachidonate biosynthesis | 40 | 2 of 5 | |
|
| 66794 | bacilysin biosynthesis | 40 | 2 of 5 | |
|
| 66794 | creatinine degradation | 40 | 2 of 5 | |
|
| 66794 | D-cycloserine biosynthesis | 40 | 2 of 5 | |
|
| 66794 | degradation of pentoses | 39.29 | 11 of 28 | |
|
| 66794 | carnitine metabolism | 37.5 | 3 of 8 | |
|
| 66794 | IAA biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | chlorophyll metabolism | 33.33 | 6 of 18 | |
|
| 66794 | (5R)-carbapenem carboxylate biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | sulfoquinovose degradation | 33.33 | 1 of 3 | |
|
| 66794 | pantothenate biosynthesis | 33.33 | 2 of 6 | |
|
| 66794 | 3-phenylpropionate degradation | 33.33 | 5 of 15 | |
|
| 66794 | mevalonate metabolism | 28.57 | 2 of 7 | |
|
| 66794 | benzoyl-CoA degradation | 28.57 | 2 of 7 | |
|
| 66794 | degradation of sugar acids | 28 | 7 of 25 | |
|
| 66794 | cholesterol biosynthesis | 27.27 | 3 of 11 | |
|
| 66794 | cyclohexanol degradation | 25 | 1 of 4 | |
|
| 66794 | methanogenesis from CO2 | 25 | 3 of 12 | |
|
| 66794 | lactate fermentation | 25 | 1 of 4 | |
|
| 66794 | arachidonic acid metabolism | 22.22 | 4 of 18 | |
| @ref | Description | Assembly level | INSDC accession | BV-BRC accession | IMG accession | NCBI tax ID | Score | |
|---|---|---|---|---|---|---|---|---|
| 66792 | Streptoalloteichus hindustanus JCM 3268 | complete | 2563366685  | 2017 | 95.2 | | ||
| 66792 | Streptoalloteichus hindustanus DSM 44523 | complete | 2563366684 | 2017 | 94.84 | | ||
| 67770 | IMG-taxon 2695420942 annotated assembly for Streptoalloteichus hindustanus DSM 44523 | contig | GCA_900129375  | 2017.4  | 2695420942 | 2017 | 71 |
| @ref | Description | Accession | Length | Database | NCBI tax ID | |
|---|---|---|---|---|---|---|
| 20218 | Streptoalloteichus hindustanus gene for 16S ribosomal RNA, partial sequence | D85497 | 1474 |  | 2017 | |
| @ref | GC-content (mol%) | Method | |
|---|---|---|---|
| 67770 | 72.6 | genome sequence analysis |
| Topic | Title | Authors | Journal | DOI | Year | |
|---|---|---|---|---|---|---|
| Enzymology | The Discovery of Imine Reductases and their Utilisation for the Synthesis of Tetrahydroisoquinolines. | Cardenas-Fernandez M, Roddan R, Carter EM, Hailes HC, Ward JM. | ChemCatChem | 10.1002/cctc.202201126 | 2023 | |
| Metabolism | Use of direct-infusion electrospray mass spectrometry to guide empirical development of improved conditions for expression of secondary metabolites from actinomycetes. | Zahn JA, Higgs RE, Hilton MD. | Appl Environ Microbiol | 10.1128/aem.67.1.377-386.2001 | 2001 | |
| Phylogeny | Distribution and phylogenetic analysis of family 19 chitinases in Actinobacteria. | Kawase T, Saito A, Sato T, Kanai R, Fujii T, Nikaidou N, Miyashita K, Watanabe T. | Appl Environ Microbiol | 10.1128/aem.70.2.1135-1144.2004 | 2004 | |
| Genome Mining for New Enzyme Chemistry. | Nguyen DT, Mitchell DA, van der Donk WA. | ACS Catal | 10.1021/acscatal.3c06322 | 2024 | | |
| Broad Spectrum Enantioselective Amide Bond Synthetase from Streptoalloteichus hindustanus. | Tang Q, Petchey M, Rowlinson B, Burden TJ, Fairlamb IJS, Grogan G. | ACS Catal | 10.1021/acscatal.3c05656 | 2024 | | |
| Oral Immunization with Yeast-Surface Display of SARS-CoV-2 Antigens in Pichia pastoris Induces Humoral Responses in BALB/C Mice. | de Macedo LS, Espinoza BCF, Invencao MDCV, Pinho SS, Leal LRS, Silva MEDS, Bandeira BMA, Novis PVS, Souza THDS, Maux JML, Silva Neto JDC, de Freitas AC, Silva AJD. | Infect Dis Rep | 10.3390/idr17050104 | 2025 | | |
| Enhancing the production of chlorophyll f in the cyanobacterium Synechocystis sp. PCC 6803. | Qi M, Taunt HN, Beckova M, Xia Z, Trinugroho JP, Komenda J, Nixon PJ. | Physiol Plant | 10.1111/ppl.70169 | 2025 | | |
| Genetics | Ultra-high field strength electroporation enables efficient DNA transformation and genome editing in nontuberculous mycobacteria. | Tang D, Wang M, Wang D, Yang D, Cai Y, Luo T, He J, Wang Q. | Microbiol Spectr | 10.1128/spectrum.01944-25 | 2025 | |
| Identification of a novel promoter for driving antibiotic-resistant genes to reduce the metabolic burden during protein expression and effectively select multiple integrations in Pichia Pastoris. | Shen Q, Yu Z, Zhou XT, Zhang SJ, Zou SP, Xiong N, Xue YP, Liu ZQ, Zheng YG. | Appl Microbiol Biotechnol | 10.1007/s00253-021-11195-0 | 2021 | | |
| Metabolism | Molecular basis for the P450-catalyzed C-N bond formation in indolactam biosynthesis. | He F, Mori T, Morita I, Nakamura H, Alblova M, Hoshino S, Awakawa T, Abe I. | Nat Chem Biol | 10.1038/s41589-019-0380-9 | 2019 | |
| Hinduchelins A-D, Noncytotoxic Catechol Derivatives from Streptoalloteichus hindustanus. | He F, Nakamura H, Hoshino S, Fong Chin JS, Yang L, Zhang H, Hayashi F, Abe I. | J Nat Prod | 10.1021/acs.jnatprod.8b00049 | 2018 | | |
| An efficient synthesis and bioactivity evaluation of oxazole-containing natural hinduchelins A-D and their derivatives. | Ke S, Zhang Z, Shi L, Liu M, Fang W, Zhang Y, Wu Z, Wan Z, Long T, Wang K. | Org Biomol Chem | 10.1039/c9ob00352e | 2019 | | |
| Microbial survival strategies in desiccated roots of Myrothamnus flabellifolia. | Tebele SM, Marks RA, Farrant JM. | Front Microbiol | 10.3389/fmicb.2025.1560114 | 2025 | | |
| Engineered production and evaluation of 6'-deoxy-tallysomycin H-1 revealing new insights into the structure-activity relationship of the anticancer drug bleomycin. | Yang D, Hindra, Dong LB, Crnovcic I, Shen B. | J Antibiot (Tokyo) | 10.1038/ja.2017.93 | 2017 | | |
| Transformation of Ulva mutabilis (Chlorophyta) by vector plasmids integrating into the genome | Oertel W, Wichard T, Weissgerber A, Cock M. | Journal of Phycology. | 2015 | | ||
| Transformation of Ulva mutabilis (Chlorophyta) by vector plasmids integrating into the genome. | Oertel W, Wichard T, Weissgerber A. | J Phycol | 10.1111/jpy.12336 | 2015 | | |
| Bleomycin reduces Vairimorpha (Nosema) ceranae infection in honey bees with some evident host toxicity. | Parrella P, Elikan AB, Kogan HV, Wague F, Marshalleck CA, Snow JW. | Microbiol Spectr | 10.1128/spectrum.03349-23 | 2024 | | |
| Carbon-nitrogen bond formation to construct novel polyketide-indole hybrids from the indole-3-carbinol exposed culture of Daldinia eschscholzii. | Lin LP, Wu M, Jiang N, Wang W, Tan RX. | Synth Syst Biotechnol | 10.1016/j.synbio.2022.02.004 | 2022 | | |
| Molecular and Mechanistic Characterization of PddB, the First PLP-Independent 2,4-Diaminobutyric Acid Racemase Discovered in an Actinobacterial D-Amino Acid Homopolymer Biosynthesis. | Yamanaka K, Ozaki R, Hamano Y, Oikawa T. | Front Microbiol | 10.3389/fmicb.2021.686023 | 2021 | | |
| Total Synthesis of Hinduchelins A-D, Stereochemical Revision of Hinduchelin A, and Biological Evaluation of Natural and Unnatural Analogues. | Childress ES, Garrison AT, Sheldon JR, Skaar EP, Lindsley CW. | J Org Chem | 10.1021/acs.joc.9b00391 | 2019 | | |
| Complete In Vitro Reconstitution of the Apramycin Biosynthetic Pathway Demonstrates the Unusual Incorporation of a beta-d-Sugar Nucleotide in the Final Glycosylation Step. | Sato S, Fan PH, Yeh YC, Liu HW. | J Am Chem Soc | 10.1021/jacs.4c01233 | 2024 | | |
| Validation of a New Multicistronic Plasmid for the Efficient and Stable Expression of Transgenes in Microalgae. | Molina-Marquez A, Vila M, Rengel R, Fernandez E, Garcia-Maroto F, Vigara J, Leon R. | Int J Mol Sci | 10.3390/ijms21030718 | 2020 | | |
| Improving the production of carbamoyltobramycin by an industrial Streptoalloteichus tenebrarius through metabolic engineering. | Feng Y, Jiang Y, Chen X, Zhu L, Xue H, Wu M, Yang L, Yu H, Lin J. | Appl Microbiol Biotechnol | 10.1007/s00253-024-13141-2 | 2024 | | |
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| Enzymology | Expression of hygromycin phosphotransferase alters virulence of Histoplasma capsulatum. | Smulian AG, Gibbons RS, Demland JA, Spaulding DT, Deepe GS. | Eukaryot Cell | 10.1128/ec.00139-07 | 2007 | |
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| Metabolism | Determination of the target nucleosides for members of two families of 16S rRNA methyltransferases that confer resistance to partially overlapping groups of aminoglycoside antibiotics. | Savic M, Lovric J, Tomic TI, Vasiljevic B, Conn GL. | Nucleic Acids Res | 10.1093/nar/gkp575 | 2009 | |
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| Metabolism | Functional analysis of the Trichoderma harzianum nox1 gene, encoding an NADPH oxidase, relates production of reactive oxygen species to specific biocontrol activity against Pythium ultimum. | Montero-Barrientos M, Hermosa R, Cardoza RE, Gutierrez S, Monte E. | Appl Environ Microbiol | 10.1128/aem.02486-10 | 2011 | |
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| Enzymology | Stepwise engineering of a Pichia pastoris D-amino acid oxidase whole cell catalyst. | Abad S, Nahalka J, Bergler G, Arnold SA, Speight R, Fotheringham I, Nidetzky B, Glieder A. | Microb Cell Fact | 10.1186/1475-2859-9-24 | 2010 | |
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| Metabolism | Unexpected link between metal ion deficiency and autophagy in Aspergillus fumigatus. | Richie DL, Fuller KK, Fortwendel J, Miley MD, McCarthy JW, Feldmesser M, Rhodes JC, Askew DS. | Eukaryot Cell | 10.1128/ec.00224-07 | 2007 | |
| Metabolism | The Histoplasma capsulatum vacuolar ATPase is required for iron homeostasis, intracellular replication in macrophages and virulence in a murine model of histoplasmosis. | Hilty J, Smulian AG, Newman SL. | Mol Microbiol | 10.1111/j.1365-2958.2008.06395.x | 2008 | |
| Metabolism | Recruitment of the inhibitor Cand1 to the cullin substrate adaptor site mediates interaction to the neddylation site. | Helmstaedt K, Schwier EU, Christmann M, Nahlik K, Westermann M, Harting R, Grond S, Busch S, Braus GH. | Mol Biol Cell | 10.1091/mbc.e10-08-0732 | 2011 | |
| Pathogenicity | Doxycycline-regulated gene expression in the opportunistic fungal pathogen Aspergillus fumigatus. | Vogt K, Bhabhra R, Rhodes JC, Askew DS. | BMC Microbiol | 10.1186/1471-2180-5-1 | 2005 | |
| A comparative study of the inhibitory effects of interleukin-1 receptor antagonist following administration as a recombinant protein or by gene transfer. | Gouze JN, Gouze E, Palmer GD, Liew VS, Pascher A, Betz OB, Thornhill TS, Evans CH, Grodzinsky AJ, Ghivizzani SC. | Arthritis Res Ther | 10.1186/ar795 | 2003 | | |
| Metabolism | Inactivation of the lys7 gene, encoding saccharopine reductase in Penicillium chrysogenum, leads to accumulation of the secondary metabolite precursors piperideine-6-carboxylic acid and pipecolic acid from alpha-aminoadipic acid. | Naranjo L, Martin de Valmaseda E, Casqueiro J, Ullan RV, Lamas-Maceiras M, Banuelos O, Martin JF. | Appl Environ Microbiol | 10.1128/aem.70.2.1031-1039.2004 | 2004 | |
| Enzymology | Increased production of xylanase by expression of a truncated version of the xyn11A gene from Nonomuraea flexuosa in Trichoderma reesei. | Paloheimo M, Mantyla A, Kallio J, Puranen T, Suominen P. | Appl Environ Microbiol | 10.1128/aem.02967-06 | 2007 | |
| Metabolism | Enhanced production of Trichoderma reesei endoglucanases and use of the new cellulase preparations in producing the stonewashed effect on denim fabric. | Miettinen-Oinonen A, Suominen P. | Appl Environ Microbiol | 10.1128/aem.68.8.3956-3964.2002 | 2002 | |
| Stress | Disruption of the Aspergillus fumigatus gene encoding nucleolar protein CgrA impairs thermotolerant growth and reduces virulence. | Bhabhra R, Miley MD, Mylonakis E, Boettner D, Fortwendel J, Panepinto JC, Postow M, Rhodes JC, Askew DS. | Infect Immun | 10.1128/iai.72.8.4731-4740.2004 | 2004 | |
| Metabolism | Lon-mediated proteolysis of the Escherichia coli UmuD mutagenesis protein: in vitro degradation and identification of residues required for proteolysis. | Gonzalez M, Frank EG, Levine AS, Woodgate R. | Genes Dev | 10.1101/gad.12.24.3889 | 1998 | |
| Metabolism | The Aspergillus fumigatus transcriptional regulator AfYap1 represents the major regulator for defense against reactive oxygen intermediates but is dispensable for pathogenicity in an intranasal mouse infection model. | Lessing F, Kniemeyer O, Wozniok I, Loeffler J, Kurzai O, Haertl A, Brakhage AA. | Eukaryot Cell | 10.1128/ec.00267-07 | 2007 | |
| Metabolism | Escherichia coli DNA polymerase III can replicate efficiently past a T-T cis-syn cyclobutane dimer if DNA polymerase V and the 3' to 5' exonuclease proofreading function encoded by dnaQ are inactivated. | Borden A, O'Grady PI, Vandewiele D, Fernandez de Henestrosa AR, Lawrence CW, Woodgate R. | J Bacteriol | 10.1128/jb.184.10.2674-2681.2002 | 2002 | |
| Genetic tools for select-agent-compliant manipulation of Burkholderia pseudomallei. | Choi KH, Mima T, Casart Y, Rholl D, Kumar A, Beacham IR, Schweizer HP. | Appl Environ Microbiol | 10.1128/aem.02430-07 | 2008 | | |
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| Stable nuclear transformation of Gonium pectorale. | Lerche K, Hallmann A. | BMC Biotechnol | 10.1186/1472-6750-9-64 | 2009 | | |
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| Metabolism | Transcriptional autoregulation and inhibition of mRNA translation of amino acid regulator gene cpcA of filamentous fungus Aspergillus nidulans. | Hoffmann B, Valerius O, Andermann M, Braus GH. | Mol Biol Cell | 10.1091/mbc.12.9.2846 | 2001 | |
| Metabolism | Interaction of the coronavirus nucleoprotein with nucleolar antigens and the host cell. | Chen H, Wurm T, Britton P, Brooks G, Hiscox JA. | J Virol | 10.1128/jvi.76.10.5233-5250.2002 | 2002 | |
| 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 | |
| Pathogenicity | Discovery of a Polyamino Acid Antibiotic Solely Comprising l-beta-Lysine by Potential Producer Prioritization-Guided Genome Mining. | Yamanaka K, Fukumoto H, Yoshimura N, Arakawa K, Kato Y, Hamano Y, Oikawa T | ACS Chem Biol | 10.1021/acschembio.1c00832 | 2021 | |
| Metabolism | The Stereocontrolled Biosynthesis of Mirror-Symmetric 2,4-Diaminobutyric Acid Homopolymers Is Critically Governed by Adenylation Activations. | Yamanaka K, Fukumoto H, Takehara M, Hamano Y, Oikawa T | ACS Chem Biol | 10.1021/acschembio.0c00321 | 2020 | |
| Metabolism | Biosynthesis of 2-deoxystreptamine-containing antibiotics in Streptoalloteichus hindustanus JCM 3268: characterization of 2-deoxy-scyllo-inosose synthase. | Hirayama T, Tamegai H, Kudo F, Kojima K, Kakinuma K, Eguchi T | J Antibiot (Tokyo) | 10.1038/ja.2006.51 | 2006 | |
| Cultivation | Streptoalloteichus, a new genus of the family Actinoplanaceae. | Tomita K, Uenoyama Y, Numata EI, Sasahira T, Hoshino Y, Fujisawa KI, Tsukiura H, Kawaguchi H | J Antibiot (Tokyo) | 10.7164/antibiotics.31.497 | 1978 | |
How to citeIf you want to cite this particular strain cite the following doi:
https://doi.org/10.13145/bacdive13492.20251217.10
When using BacDive for research please cite the following paper
BacDive in 2025: the core database for prokaryotic strain data
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