Turneriella parva H is a bacterium that was isolated from contaminated liquid culture medium.
genome sequence 16S sequence Bacteria
SI-ID 100727
| @ref 20215 |
|
Last LPSN update
2026-02-09 11:19:19 |
| Domain Bacteria |
| Phylum Spirochaetota |
| Class Spirochaetia |
| Order Leptospirales |
| Family Leptospiraceae |
| Genus Turneriella |
| Species Turneriella parva |
| Full scientific name Turneriella parva (Hovind-Hougen et al. 1982) Levett et al. 2005 |
| Synonyms (2) |
| @ref | Name | Growth | Medium link | Composition | |
|---|---|---|---|---|---|
| 15763 | LEPTOSPIRA-MEDIUM (DSMZ Medium 1113) | Medium recipe at MediaDive  | Name: LEPTOSPIRA-MEDIUM (DSMZ Medium 1113) Composition: Leptospira Medium Base EMJH 2.3 g/l Agarose 1.5 g/l Leptospira Enrichment EMJH Distilled water |
| @ref | Growth | Type | Temperature (°C) | |
|---|---|---|---|---|
| 15763 | positive | growth | 30 |
| @ref | Oxygen tolerance | Confidence | |
|---|---|---|---|
| 125439 | obligate aerobe | 97.6 |
| @ref | Spore formation | Confidence | |
|---|---|---|---|
| 125439 | 97.8 |
| @ref | pathway | enzyme coverage | annotated reactions | external links | |
|---|---|---|---|---|---|
| 66794 | cellulose degradation | 100 | 5 of 5 |   |
|
| 66794 | formaldehyde oxidation | 100 | 3 of 3 | |
|
| 66794 | sulfopterin metabolism | 100 | 4 of 4 | |
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| 66794 | ppGpp biosynthesis | 100 | 4 of 4 | |
|
| 66794 | coenzyme A metabolism | 100 | 4 of 4 | |
|
| 66794 | adipate degradation | 100 | 2 of 2 | |
|
| 66794 | glycogen metabolism | 100 | 5 of 5 | |
|
| 66794 | palmitate biosynthesis | 100 | 22 of 22 | |
|
| 66794 | cis-vaccenate biosynthesis | 100 | 2 of 2 | |
|
| 66794 | cardiolipin biosynthesis | 100 | 7 of 7 | |
|
| 66794 | biotin biosynthesis | 100 | 4 of 4 | |
|
| 66794 | valine metabolism | 100 | 9 of 9 | |
|
| 66794 | octane oxidation | 100 | 3 of 3 | |
|
| 66794 | lipoate biosynthesis | 100 | 5 of 5 | |
|
| 66794 | teichoic acid biosynthesis | 100 | 1 of 1 | |
|
| 66794 | anapleurotic synthesis of oxalacetate | 100 | 1 of 1 | |
|
| 66794 | folate polyglutamylation | 100 | 1 of 1 | |
|
| 66794 | ceramide biosynthesis | 100 | 1 of 1 | |
|
| 66794 | suberin monomers biosynthesis | 100 | 2 of 2 | |
|
| 66794 | ethanol fermentation | 100 | 2 of 2 | |
|
| 66794 | UDP-GlcNAc biosynthesis | 100 | 3 of 3 | |
|
| 66794 | CDP-diacylglycerol biosynthesis | 100 | 2 of 2 | |
|
| 66794 | methylglyoxal degradation | 100 | 5 of 5 | |
|
| 66794 | denitrification | 100 | 2 of 2 | |
|
| 66794 | chorismate metabolism | 88.89 | 8 of 9 | |
|
| 66794 | NAD metabolism | 88.89 | 16 of 18 | |
|
| 66794 | aspartate and asparagine metabolism | 88.89 | 8 of 9 | |
|
| 66794 | allantoin degradation | 88.89 | 8 of 9 | |
|
| 66794 | lipid A biosynthesis | 88.89 | 8 of 9 | |
|
| 66794 | C4 and CAM-carbon fixation | 87.5 | 7 of 8 | |
|
| 66794 | isoleucine metabolism | 87.5 | 7 of 8 | |
|
| 66794 | ubiquinone biosynthesis | 85.71 | 6 of 7 | |
|
| 66794 | tetrahydrofolate metabolism | 85.71 | 12 of 14 | |
|
| 66794 | reductive acetyl coenzyme A pathway | 85.71 | 6 of 7 | |
|
| 66794 | photosynthesis | 85.71 | 12 of 14 | |
|
| 66794 | methionine metabolism | 80.77 | 21 of 26 | |
|
| 66794 | ethylmalonyl-CoA pathway | 80 | 4 of 5 | |
|
| 66794 | propionate fermentation | 80 | 8 of 10 | |
|
| 66794 | threonine metabolism | 80 | 8 of 10 | |
|
| 66794 | peptidoglycan biosynthesis | 80 | 12 of 15 | |
|
| 66794 | starch degradation | 80 | 8 of 10 | |
|
| 66794 | leucine metabolism | 76.92 | 10 of 13 | |
|
| 66794 | phenylalanine metabolism | 76.92 | 10 of 13 | |
|
| 66794 | vitamin B1 metabolism | 76.92 | 10 of 13 | |
|
| 66794 | purine metabolism | 76.6 | 72 of 94 | |
|
| 66794 | glycolysis | 76.47 | 13 of 17 | |
|
| 66794 | gluconeogenesis | 75 | 6 of 8 | |
|
| 66794 | glycogen biosynthesis | 75 | 3 of 4 | |
|
| 66794 | glutamate and glutamine metabolism | 75 | 21 of 28 | |
|
| 66794 | 6-hydroxymethyl-dihydropterin diphosphate biosynthesis | 75 | 6 of 8 | |
|
| 66794 | CMP-KDO biosynthesis | 75 | 3 of 4 | |
|
| 66794 | acetate fermentation | 75 | 3 of 4 | |
|
| 66794 | flavin biosynthesis | 73.33 | 11 of 15 | |
|
| 66794 | vitamin B6 metabolism | 72.73 | 8 of 11 | |
|
| 66794 | citric acid cycle | 71.43 | 10 of 14 | |
|
| 66794 | heme metabolism | 71.43 | 10 of 14 | |
|
| 66794 | pyrimidine metabolism | 68.89 | 31 of 45 | |
|
| 66794 | d-mannose degradation | 66.67 | 6 of 9 | |
|
| 66794 | L-lactaldehyde degradation | 66.67 | 2 of 3 | |
|
| 66794 | CO2 fixation in Crenarchaeota | 66.67 | 6 of 9 | |
|
| 66794 | acetoin degradation | 66.67 | 2 of 3 | |
|
| 66794 | serine metabolism | 66.67 | 6 of 9 | |
|
| 66794 | methane metabolism | 66.67 | 2 of 3 | |
|
| 66794 | molybdenum cofactor biosynthesis | 66.67 | 6 of 9 | |
|
| 66794 | 1,4-dihydroxy-6-naphthoate biosynthesis | 66.67 | 4 of 6 | |
|
| 66794 | non-pathway related | 65.79 | 25 of 38 | |
|
| 66794 | lipid metabolism | 64.52 | 20 of 31 | |
|
| 66794 | glutathione metabolism | 64.29 | 9 of 14 | |
|
| 66794 | dTDPLrhamnose biosynthesis | 62.5 | 5 of 8 | |
|
| 66794 | ketogluconate metabolism | 62.5 | 5 of 8 | |
|
| 66794 | cysteine metabolism | 61.11 | 11 of 18 | |
|
| 66794 | phenylacetate degradation (aerobic) | 60 | 3 of 5 | |
|
| 66794 | isoprenoid biosynthesis | 57.69 | 15 of 26 | |
|
| 66794 | proline metabolism | 54.55 | 6 of 11 | |
|
| 66794 | metabolism of disaccharids | 54.55 | 6 of 11 | |
|
| 66794 | sulfate reduction | 53.85 | 7 of 13 | |
|
| 66794 | tryptophan metabolism | 52.63 | 20 of 38 | |
|
| 66794 | alanine metabolism | 51.72 | 15 of 29 | |
|
| 66794 | pantothenate biosynthesis | 50 | 3 of 6 | |
|
| 66794 | sphingosine metabolism | 50 | 3 of 6 | |
|
| 66794 | dolichol and dolichyl phosphate biosynthesis | 50 | 1 of 2 | |
|
| 66794 | toluene degradation | 50 | 2 of 4 | |
|
| 66794 | cyclohexanol degradation | 50 | 2 of 4 | |
|
| 66794 | coenzyme M biosynthesis | 50 | 5 of 10 | |
|
| 66794 | kanosamine biosynthesis II | 50 | 1 of 2 | |
|
| 66794 | butanoate fermentation | 50 | 2 of 4 | |
|
| 66794 | phenylmercury acetate degradation | 50 | 1 of 2 | |
|
| 66794 | selenocysteine biosynthesis | 50 | 3 of 6 | |
|
| 66794 | histidine metabolism | 48.28 | 14 of 29 | |
|
| 66794 | phosphatidylethanolamine bioynthesis | 46.15 | 6 of 13 | |
|
| 66794 | arginine metabolism | 45.83 | 11 of 24 | |
|
| 66794 | pentose phosphate pathway | 45.45 | 5 of 11 | |
|
| 66794 | oxidative phosphorylation | 43.96 | 40 of 91 | |
|
| 66794 | tyrosine metabolism | 42.86 | 6 of 14 | |
|
| 66794 | lysine metabolism | 42.86 | 18 of 42 | |
|
| 66794 | propanol degradation | 42.86 | 3 of 7 | |
|
| 66794 | degradation of aromatic, nitrogen containing compounds | 41.67 | 5 of 12 | |
|
| 66794 | glycine betaine biosynthesis | 40 | 2 of 5 | |
|
| 66794 | 3-chlorocatechol degradation | 40 | 2 of 5 | |
|
| 66794 | arachidonate biosynthesis | 40 | 2 of 5 | |
|
| 66794 | factor 420 biosynthesis | 40 | 2 of 5 | |
|
| 66794 | hydrogen production | 40 | 2 of 5 | |
|
| 66794 | arachidonic acid metabolism | 38.89 | 7 of 18 | |
|
| 66794 | carnitine metabolism | 37.5 | 3 of 8 | |
|
| 66794 | degradation of sugar alcohols | 37.5 | 6 of 16 | |
|
| 66794 | nitrate assimilation | 33.33 | 3 of 9 | |
|
| 66794 | IAA biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | 3-phenylpropionate degradation | 33.33 | 5 of 15 | |
|
| 66794 | glycolate and glyoxylate degradation | 33.33 | 2 of 6 | |
|
| 66794 | cyanate degradation | 33.33 | 1 of 3 | |
|
| 66794 | acetyl CoA biosynthesis | 33.33 | 1 of 3 | |
|
| 66794 | degradation of pentoses | 32.14 | 9 of 28 | |
|
| 66794 | androgen and estrogen metabolism | 31.25 | 5 of 16 | |
|
| 66794 | urea cycle | 30.77 | 4 of 13 | |
|
| 66794 | Entner Doudoroff pathway | 30 | 3 of 10 | |
|
| 66794 | phenol degradation | 30 | 6 of 20 | |
|
| 66794 | glycine metabolism | 30 | 3 of 10 | |
|
| 66794 | bile acid biosynthesis, neutral pathway | 29.41 | 5 of 17 | |
|
| 66794 | aclacinomycin biosynthesis | 28.57 | 2 of 7 | |
|
| 66794 | benzoyl-CoA degradation | 28.57 | 2 of 7 | |
|
| 66794 | degradation of hexoses | 27.78 | 5 of 18 | |
|
| 66794 | cholesterol biosynthesis | 27.27 | 3 of 11 | |
|
| 66794 | dolichyl-diphosphooligosaccharide biosynthesis | 27.27 | 3 of 11 | |
|
| 66794 | polyamine pathway | 26.09 | 6 of 23 | |
|
| 66794 | lactate fermentation | 25 | 1 of 4 | |
|
| 66794 | ascorbate metabolism | 22.73 | 5 of 22 | |
|
| 66794 | 4-hydroxymandelate degradation | 22.22 | 2 of 9 | |
|
| 66794 | vitamin B12 metabolism | 20.59 | 7 of 34 | |
| Cat1 | Cat2 | Cat3 | |
|---|---|---|---|
| #Engineered | #Contamination | - | |
| #Engineered | #Laboratory | #Lab enrichment |
| 15763 | Sample typecontaminated liquid culture medium |
Global distribution of 16S sequence AY293856 (>99% sequence identity) for Turneriella parva subclade from Microbeatlas 
 Aquatic Samples |
7757 |
 Soil Samples |
3715 |
 Animal Samples |
702 |
 Plant Samples |
870 |
| Total Samples | 13044 |
| @ref | Description | Assembly level | INSDC accession | BV-BRC accession | IMG accession | NCBI tax ID | Score | |
|---|---|---|---|---|---|---|---|---|
| 66792 | ASM26688v1 assembly for Turneriella parva DSM 21527 | complete | GCA_000266885   | 869212.3  | 2506520013  | 869212 | 86.75 |  |
| @ref | Description | Accession | Length | Database | NCBI tax ID | |
|---|---|---|---|---|---|---|
| 15763 | Turneriella parva serovar Parva strain H 16S ribosomal RNA gene, partial sequence | AY293856 | 1440 |  | 869212 |
| Topic | Title | Authors | Journal | DOI | Year | |
|---|---|---|---|---|---|---|
| Conflict between sea snakes and humans on the coast of West Bengal and Odisha, India: perception, attitudes and incidents. | Patra A, Mahapatra AD, Malhotra A, Santra V, Ghorai SK, Annadurai D. | Trans R Soc Trop Med Hyg | 10.1093/trstmh/trae086 | 2025 | | |
| Genome sequence of the free-living aerobic spirochete Turneriella parva type strain (H(T)), and emendation of the species Turneriella parva. | Stackebrandt E, Chertkov O, Lapidus A, Nolan M, Lucas S, Hammon N, Deshpande S, Cheng JF, Tapia R, Goodwin LA, Pitluck S, Liolios K, Pagani I, Ivanova N, Mavromatis K, Mikhailova N, Huntemann M, Pati A, Chen A, Palaniappan K, Land M, Pan C, Rohde M, Gronow S, Goker M, Detter JC, Bristow J, Eisen JA, Markowitz V, Hugenholtz P, Woyke T, Kyrpides NC, Klenk HP. | Stand Genomic Sci | 10.4056/sigs.3617113 | 2013 | | |
| Pathogenicity | Inhibition of the growth of Bacillus subtilis DSM10 by a newly discovered antibacterial protein from the soil metagenome. | O'Mahony MM, Henneberger R, Selvin J, Kennedy J, Doohan F, Marchesi JR, Dobson AD. | Bioengineered | 10.1080/21655979.2015.1018493 | 2015 | |
| Transcriptome | Novel BRICHOS-Related Antimicrobial Peptides from the Marine Worm Heteromastus filiformis: Transcriptome Mining, Synthesis, Biological Activities, and Therapeutic Potential. | Panteleev PV, Safronova VN, Duan S, Komlev AS, Bolosov IA, Kruglikov RN, Kombarova TI, Korobova OV, Pereskokova ES, Borzilov AI, Dyachenko IA, Shamova OV, Huang Y, Shi Q, Ovchinnikova TV. | Mar Drugs | 10.3390/md21120639 | 2023 | |
| The characteristics of ubiquitous and unique Leptospira strains from the collection of Russian centre for leptospirosis. | Voronina OL, Kunda MS, Aksenova EI, Ryzhova NN, Semenov AN, Petrov EM, Didenko LV, Lunin VG, Ananyina YV, Gintsburg AL. | Biomed Res Int | 10.1155/2014/649034 | 2014 | | |
| Recent advances in understanding of the epigenetic regulation of plant regeneration. | Liu X, Zhu K, Xiao J. | aBIOTECH | 10.1007/s42994-022-00093-2 | 2023 | | |
| Phylogeny | Revisiting the taxonomy and evolution of pathogenicity of the genus Leptospira through the prism of genomics. | Vincent AT, Schiettekatte O, Goarant C, Neela VK, Bernet E, Thibeaux R, Ismail N, Mohd Khalid MKN, Amran F, Masuzawa T, Nakao R, Amara Korba A, Bourhy P, Veyrier FJ, Picardeau M. | PLoS Negl Trop Dis | 10.1371/journal.pntd.0007270 | 2019 | |
| Metabolism | Dynamic interactions within the host-associated microbiota cause tumor formation in the basal metazoan Hydra. | Rathje K, Mortzfeld B, Hoeppner MP, Taubenheim J, Bosch TCG, Klimovich A. | PLoS Pathog | 10.1371/journal.ppat.1008375 | 2020 | |
| Phylogeny | The use of 16S rDNA sequence analysis to investigate the phylogeny of Leptospiraceae and related spirochaetes. | Hookey JV, Bryden J, Gatehouse L. | J Gen Microbiol | 10.1099/00221287-139-11-2585 | 1993 | |
| Enzymology | Origin and Evolution of Flavin-Based Electron Bifurcating Enzymes. | Poudel S, Dunham EC, Lindsay MR, Amenabar MJ, Fones EM, Colman DR, Boyd ES. | Front Microbiol | 10.3389/fmicb.2018.01762 | 2018 | |
| The molecular evolution of the Qo motif. | Kao WC, Hunte C. | Genome Biol Evol | 10.1093/gbe/evu147 | 2014 | | |
| Metabolism | Molecular Evolution of the Oxygen-Binding Hemerythrin Domain. | Alvarez-Carreno C, Becerra A, Lazcano A. | PLoS One | 10.1371/journal.pone.0157904 | 2016 | |
| Ankyrin domains across the Tree of Life. | Jernigan KK, Bordenstein SR. | PeerJ | 10.7717/peerj.264 | 2014 | | |
| Comparative neurobiology of feeding in the opisthobranch sea slug, Aplysia, and the pulmonate snail, Helisoma: evolutionary considerations. | Wentzell MM, Martinez-Rubio C, Miller MW, Murphy AD. | Brain Behav Evol | 10.1159/000258668 | 2009 | | |
| Serological and molecular characteristics of pathogenic Leptospira in rodent populations in Fujian Province, China, 2018-2020. | Xu G, Qiu H, Liu W, Jiang X, Chang YF, Wang J, Li Z, Zhu Y, Zhang C, Xiao F. | BMC Microbiol | 10.1186/s12866-022-02566-2 | 2022 | | |
| Phylogeny | Reclassification of Leptospira parva Hovind-Hougen et al. 1982 as Turneriella parva gen. nov., comb. nov. | Levett PN, Morey RE, Galloway R, Steigerwalt AG, Ellis WA | Int J Syst Evol Microbiol | 10.1099/ijs.0.63088-0 | 2005 | |
How to citeIf you want to cite this particular strain cite the following doi:
https://doi.org/10.13145/bacdive6809.20251217.10
When using BacDive for research please cite the following paper
BacDive in 2025: the core database for prokaryotic strain data
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