Name: Cupriavidus necator pHG1
Creator: BacDive
License: https://creativecommons.org/licenses/by/4.0/

Strain identifier

BacDive ID: 2008

Type strain:

Species: Cupriavidus necator

Strain Designation: pHG1, H 16, H16, Wilde H16, strain S-10-1, Schlegel H16

Culture col. no.: DSM 428, ATCC 17699, KCTC 22496, NCIB 10442, JCM 20644, ATCC 23440, IAM 12567, NCIMB 10442, CCUG 13797, LMG 1201, CECT 4635, Stanier 337, LMAU A145, CCTM La 2802, CCRC 13036, CCM 3726

Strain history: IAM 12567 <-- NCIB 10442 <-- H. G. Schlegel H16.

NCBI tax ID(s): 381666 (strain), 106590 (species)

SI-ID 13563

LMG 1201, ATCC 17699, ATCC 23440, CCUG 13797, DSM 428, NCIB 10442, NCIMB 10442, IAM12567, CCM 3726, CECT 4635, CCRC 13036, KCTC 1006, KCTC 2660, NCCB 82042, LMD 82.42, BCRC 13036, CCT 2489, CCUG 52967, JCM 20644

Special Collections

Other strains from Cupriavidus necator

Section

Cupriavidus necator pHG1 is a mesophilic, Gram-negative bacterium that was isolated from sludge.

Gram-negative
mesophilic
16S sequence
Bacteria
genome sequence

Information on the name and the taxonomic classification. Name and taxonomic classification

	Last LPSN update	09-12-2024 (DD-MM-YYYY)
	Domain	*Bacteria*
	Phylum	*Pseudomonadota*
	Class	*Betaproteobacteria*
	Order	*Burkholderiales*
	Family	*Burkholderiaceae*
	Genus	*Cupriavidus*
	Species	**Cupriavidus necator**
	Full Scientific Name (LPSN)	Cupriavidus necator Makkar and Casida 1987

Information on morphological and physiological properties Morphology

[Ref.: #69480]	Gram stain	negative Confidence in %97.5

Information on culture and growth conditions Culture and growth conditions

[Ref.: #197]

Culture medium

MINERAL MEDIUM FOR CHEMOLITHOTROPHIC GROWTH (H-3) (DSMZ Medium 81)

[Ref.: #197]

Culture medium growth

[Ref.: #197]

Culture medium link

Medium recipe at MediaDive

[Ref.: #197]

Culture medium composition

expand / minimize

[Ref.: #197]

Culture medium

NUTRIENT AGAR (DSMZ Medium 1)

[Ref.: #197]

Culture medium growth

[Ref.: #197]

Culture medium link

Medium recipe at MediaDive

[Ref.: #197]

Culture medium composition

expand / minimize

	Temperatures	Kind of temperature		Temperature
[Ref.: #197]			growth	30 °C
[Ref.: #67770]			growth	25 °C

Information on physiology and metabolism Physiology and metabolism

[Ref.: #69481]

Ability of spore formation

no Confidence in %100

[Ref.: #197]	Name of produced compound	PHB
[Ref.: #197]	Name of produced compound	hydrogenase
[Ref.: #197]	Name of produced compound	phenylalanine, hydroxylation of
[Ref.: #197]	Name of produced compound	single cell protein

	Pathway	Enzyme coverage	Annotated reactions
	Pathway annotation	Computationally determined by
[Ref.: #66794]	biotin biosynthesis	100	4 of 4
[Ref.: #66794]	methylglyoxal degradation	100	5 of 5
[Ref.: #66794]	palmitate biosynthesis	100	22 of 22
[Ref.: #66794]	photosynthesis	100	14 of 14
[Ref.: #66794]	3-chlorocatechol degradation	100	5 of 5
[Ref.: #66794]	glycogen metabolism	100	5 of 5
[Ref.: #66794]	acetate fermentation	100	4 of 4
[Ref.: #66794]	ethanol fermentation	100	2 of 2
[Ref.: #66794]	threonine metabolism	100	10 of 10
[Ref.: #66794]	gallate degradation	100	5 of 5
[Ref.: #66794]	adipate degradation	100	2 of 2
[Ref.: #66794]	aspartate and asparagine metabolism	100	9 of 9
[Ref.: #66794]	hydrogen production	100	5 of 5
[Ref.: #66794]	lipoate biosynthesis	100	5 of 5
[Ref.: #66794]	quinate degradation	100	2 of 2
[Ref.: #66794]	valine metabolism	100	9 of 9
[Ref.: #66794]	resorcinol degradation	100	2 of 2
[Ref.: #66794]	butanoate fermentation	100	4 of 4
[Ref.: #66794]	L-lactaldehyde degradation	100	3 of 3
[Ref.: #66794]	cardiolipin biosynthesis	100	7 of 7
[Ref.: #66794]	Entner Doudoroff pathway	100	10 of 10
[Ref.: #66794]	cis-vaccenate biosynthesis	100	2 of 2
[Ref.: #66794]	denitrification	100	2 of 2
[Ref.: #66794]	CDP-diacylglycerol biosynthesis	100	2 of 2
[Ref.: #66794]	UDP-GlcNAc biosynthesis	100	3 of 3
[Ref.: #66794]	suberin monomers biosynthesis	100	2 of 2
[Ref.: #66794]	taurine degradation	100	1 of 1
[Ref.: #66794]	folate polyglutamylation	100	1 of 1
[Ref.: #66794]	aerobactin biosynthesis	100	1 of 1
[Ref.: #66794]	anapleurotic synthesis of oxalacetate	100	1 of 1
[Ref.: #66794]	CO2 fixation in Crenarchaeota	100	9 of 9
[Ref.: #66794]	sulfopterin metabolism	100	4 of 4
[Ref.: #66794]	ubiquinone biosynthesis	100	7 of 7
[Ref.: #66794]	ppGpp biosynthesis	100	4 of 4
[Ref.: #66794]	allantoin degradation	100	9 of 9
[Ref.: #66794]	phenylacetate degradation (aerobic)	100	5 of 5
[Ref.: #66794]	reductive acetyl coenzyme A pathway	100	7 of 7
[Ref.: #66794]	ribulose monophosphate pathway	100	2 of 2
[Ref.: #66794]	cyanate degradation	100	3 of 3
[Ref.: #66794]	formaldehyde oxidation	100	3 of 3
[Ref.: #66794]	coenzyme A metabolism	100	4 of 4
[Ref.: #66794]	3-phenylpropionate degradation	93.33	14 of 15
[Ref.: #66794]	citric acid cycle	92.86	13 of 14
[Ref.: #66794]	glutathione metabolism	92.86	13 of 14
[Ref.: #66794]	tetrahydrofolate metabolism	92.86	13 of 14
[Ref.: #66794]	phenylalanine metabolism	92.31	12 of 13
[Ref.: #66794]	sulfate reduction	92.31	12 of 13
[Ref.: #66794]	leucine metabolism	92.31	12 of 13
[Ref.: #66794]	pentose phosphate pathway	90.91	10 of 11
[Ref.: #66794]	phenol degradation	90	18 of 20
[Ref.: #66794]	starch degradation	90	9 of 10
[Ref.: #66794]	propionate fermentation	90	9 of 10
[Ref.: #66794]	molybdenum cofactor biosynthesis	88.89	8 of 9
[Ref.: #66794]	NAD metabolism	88.89	16 of 18
[Ref.: #66794]	4-hydroxymandelate degradation	88.89	8 of 9
[Ref.: #66794]	lipid A biosynthesis	88.89	8 of 9
[Ref.: #66794]	serine metabolism	88.89	8 of 9
[Ref.: #66794]	chorismate metabolism	88.89	8 of 9
[Ref.: #66794]	d-mannose degradation	88.89	8 of 9
[Ref.: #66794]	isoleucine metabolism	87.5	7 of 8
[Ref.: #66794]	gluconeogenesis	87.5	7 of 8
[Ref.: #66794]	alanine metabolism	86.21	25 of 29
[Ref.: #66794]	vitamin B1 metabolism	84.62	11 of 13
[Ref.: #66794]	glycolate and glyoxylate degradation	83.33	5 of 6
[Ref.: #66794]	purine metabolism	82.98	78 of 94
[Ref.: #66794]	histidine metabolism	82.76	24 of 29
[Ref.: #66794]	glutamate and glutamine metabolism	82.14	23 of 28
[Ref.: #66794]	proline metabolism	81.82	9 of 11
[Ref.: #66794]	vitamin B6 metabolism	81.82	9 of 11
[Ref.: #66794]	tryptophan metabolism	81.58	31 of 38
[Ref.: #66794]	vitamin K metabolism	80	4 of 5
[Ref.: #66794]	ethylmalonyl-CoA pathway	80	4 of 5
[Ref.: #66794]	peptidoglycan biosynthesis	80	12 of 15
[Ref.: #66794]	heme metabolism	78.57	11 of 14
[Ref.: #66794]	lysine metabolism	78.57	33 of 42
[Ref.: #66794]	tyrosine metabolism	78.57	11 of 14
[Ref.: #66794]	non-pathway related	76.32	29 of 38
[Ref.: #66794]	pyrimidine metabolism	75.56	34 of 45
[Ref.: #66794]	C4 and CAM-carbon fixation	75	6 of 8
[Ref.: #66794]	degradation of aromatic, nitrogen containing compounds	75	9 of 12
[Ref.: #66794]	CMP-KDO biosynthesis	75	3 of 4
[Ref.: #66794]	glycogen biosynthesis	75	3 of 4
[Ref.: #66794]	6-hydroxymethyl-dihydropterin diphosphate biosynthesis	75	6 of 8
[Ref.: #66794]	ketogluconate metabolism	75	6 of 8
[Ref.: #66794]	lactate fermentation	75	3 of 4
[Ref.: #66794]	oxidative phosphorylation	74.73	68 of 91
[Ref.: #66794]	flavin biosynthesis	73.33	11 of 15
[Ref.: #66794]	methionine metabolism	73.08	19 of 26
[Ref.: #66794]	cysteine metabolism	72.22	13 of 18
[Ref.: #66794]	propanol degradation	71.43	5 of 7
[Ref.: #66794]	glycolysis	70.59	12 of 17
[Ref.: #66794]	urea cycle	69.23	9 of 13
[Ref.: #66794]	androgen and estrogen metabolism	68.75	11 of 16
[Ref.: #66794]	degradation of sugar acids	68	17 of 25
[Ref.: #66794]	lipid metabolism	67.74	21 of 31
[Ref.: #66794]	acetyl CoA biosynthesis	66.67	2 of 3
[Ref.: #66794]	nitrate assimilation	66.67	6 of 9
[Ref.: #66794]	acetoin degradation	66.67	2 of 3
[Ref.: #66794]	octane oxidation	66.67	2 of 3
[Ref.: #66794]	metabolism of disaccharids	63.64	7 of 11
[Ref.: #66794]	degradation of sugar alcohols	62.5	10 of 16
[Ref.: #66794]	arginine metabolism	62.5	15 of 24
[Ref.: #66794]	isoprenoid biosynthesis	61.54	16 of 26
[Ref.: #66794]	creatinine degradation	60	3 of 5
[Ref.: #66794]	4-hydroxyphenylacetate degradation	60	6 of 10
[Ref.: #66794]	metabolism of amino sugars and derivatives	60	3 of 5
[Ref.: #66794]	degradation of pentoses	57.14	16 of 28
[Ref.: #66794]	benzoyl-CoA degradation	57.14	4 of 7
[Ref.: #66794]	glycine metabolism	50	5 of 10
[Ref.: #66794]	selenocysteine biosynthesis	50	3 of 6
[Ref.: #66794]	toluene degradation	50	2 of 4
[Ref.: #66794]	aminopropanol phosphate biosynthesis	50	1 of 2
[Ref.: #66794]	pantothenate biosynthesis	50	3 of 6
[Ref.: #66794]	mannosylglycerate biosynthesis	50	1 of 2
[Ref.: #66794]	kanosamine biosynthesis II	50	1 of 2
[Ref.: #66794]	cyclohexanol degradation	50	2 of 4
[Ref.: #66794]	phenylmercury acetate degradation	50	1 of 2
[Ref.: #66794]	dTDPLrhamnose biosynthesis	50	4 of 8
[Ref.: #66794]	coenzyme M biosynthesis	50	5 of 10
[Ref.: #66794]	polyamine pathway	47.83	11 of 23
[Ref.: #66794]	vitamin B12 metabolism	47.06	16 of 34
[Ref.: #66794]	cholesterol biosynthesis	45.45	5 of 11
[Ref.: #66794]	degradation of hexoses	44.44	8 of 18
[Ref.: #66794]	bile acid biosynthesis, neutral pathway	41.18	7 of 17
[Ref.: #66794]	carotenoid biosynthesis	40.91	9 of 22
[Ref.: #66794]	glycine betaine biosynthesis	40	2 of 5
[Ref.: #66794]	arachidonate biosynthesis	40	2 of 5
[Ref.: #66794]	factor 420 biosynthesis	40	2 of 5
[Ref.: #66794]	arachidonic acid metabolism	38.89	7 of 18
[Ref.: #66794]	carnitine metabolism	37.5	3 of 8
[Ref.: #66794]	ascorbate metabolism	36.36	8 of 22
[Ref.: #66794]	enterobactin biosynthesis	33.33	1 of 3
[Ref.: #66794]	methane metabolism	33.33	1 of 3
[Ref.: #66794]	IAA biosynthesis	33.33	1 of 3
[Ref.: #66794]	sulfoquinovose degradation	33.33	1 of 3
[Ref.: #66794]	methanogenesis from CO2	33.33	4 of 12
[Ref.: #66794]	sphingosine metabolism	33.33	2 of 6
[Ref.: #66794]	(5R)-carbapenem carboxylate biosynthesis	33.33	1 of 3
[Ref.: #66794]	phosphatidylethanolamine bioynthesis	30.77	4 of 13
[Ref.: #66794]	aclacinomycin biosynthesis	28.57	2 of 7
[Ref.: #66794]	chlorophyll metabolism	27.78	5 of 18
[Ref.: #66794]	dolichyl-diphosphooligosaccharide biosynthesis	27.27	3 of 11
[Ref.: #66794]	alginate biosynthesis	25	1 of 4
[Ref.: #66794]	catecholamine biosynthesis	25	1 of 4
		Only first 10 entries are displayed. Click here to see all.

Information on isolation source, the sampling and environmental conditions Isolation, sampling and environmental information

[Ref.: #197]	Sample type/isolated from	sludge
[Ref.: #197]	Geographic location (country and/or sea, region)	Göttingen, Weende-Quelle
[Ref.: #197]	Country	Germany
[Ref.: #197]	Country ISO 3 Code	DEU
[Ref.: #197]	Continent	Europe

[Ref.: #67770]	Sample type/isolated from	Sludge
[Ref.: #67770]	Geographic location (country and/or sea, region)	Göttingen
[Ref.: #67770]	Country	Germany
[Ref.: #67770]	Country ISO 3 Code	DEU
[Ref.: #67770]	Continent	Europe
* marker position based on {}

Isolation sources categories

#Environmental

#Terrestrial

#Mud (Sludge)

What are isolation sources categories?

Information on possible application of the strain and its possible interaction with e.g. potential hosts Safety information

[Ref.: #197]

Biosafety level

Risk group (German classification)
According to TRBA 466

Information on genomic background e.g. entries in nucleic sequence databass Sequence information

16S Sequence information:

	Sequence accession description	Seq. accession number	Sequence length (bp)	Sequence database	Associated NCBI tax ID
[Ref.: #67770]	Ralstonia eutropha DNA for 16S ribosomal RNA	D88002	1468	GenBank ENA	106590 tax ID

Genome sequence information:

Only first 5 entries are displayed. Click here to see all.

	Sequence accession description	Seq. accession number	Assembly level	Sequence database	Associated NCBI tax ID
[Ref.: #66792]	Cupriavidus necator H16	GCA_004798725	complete	GenBank ENA	381666 tax ID	*
[Ref.: #66792]	Cupriavidus necator H16	GCA_000009285	complete	GenBank ENA	381666 tax ID	*
[Ref.: #66792]	Cupriavidus necator H16 strain DSM 428	381666.45	complete	PATRIC	381666 tax ID	*
[Ref.: #66792]	Ralstonia eutropha H16	381666.6	complete	PATRIC	381666 tax ID	*
[Ref.: #66792]	Ralstonia eutropha H16	381666.42	plasmid	PATRIC	381666 tax ID	*
[Ref.: #66792]	Cupriavidus necator H16	640427136	complete	JGI IMG/M	381666 tax ID	*

Data predicted using genome information as a basis Genome-based predictions

	Trait	Model	Prediction	Confidence in %	In training data
	Predictions from GenomeNet Sporulation v. 1 based on: Cupriavidus necator H16 strain DSM 428 PATRIC: 381666.45
[Ref.: #69481]	spore-forming	spore-formingⓘ	no	100	no

	Trait	Model	Prediction	Confidence in %	In training data
	Predictions from Diaspora project based on: Cupriavidus necator H16 H16 NCBI: GCA_004798725.1
[Ref.: #69480]	gram-positive	gram-positiveⓘ	no	97.5	no
[Ref.: #69480]	anaerobic	anaerobicⓘ	no	94.707	no
[Ref.: #69480]	aerobic	aerobicⓘ	yes	82.225	no
[Ref.: #69480]	spore-forming	spore-formingⓘ	no	88.788	no
[Ref.: #69480]	thermophilic	thermophileⓘ	no	98.485	no
[Ref.: #69480]	flagellated	motile2+ⓘ	yes	83.921	no

Availability in culture collections External links

[Ref.: #197]

Culture collection no.

DSM 428, ATCC 17699, KCTC 22496, NCIB 10442, JCM 20644, ATCC 23440, IAM 12567, NCIMB 10442, CCUG 13797, LMG 1201, CECT 4635, Stanier 337, LMAU A145, CCTM La 2802, CCRC 13036, CCM 3726

[Ref.: #71655]

SI-ID 13563

Literature:

Only first 10 entries are displayed. Click here to see all.

Topic	Title	Authors	Journal	DOI	Year
Biotechnology	Developing Microbial Co-Culture System for Enhanced Polyhydroxyalkanoates (PHA) Production Using Acid Pretreated Lignocellulosic Biomass.	Saratale RG, Cho SK, Kadam AA, Ghodake GS, Kumar M, Bharagava RN, Varjani S, Nair S, Kim DS, Shin HS, Saratale GD	Polymers (Basel)	10.3390/polym14040726	2022	*
Biotechnology	Utilization of Noxious Weed Water Hyacinth Biomass as a Potential Feedstock for Biopolymers Production: A Novel Approach.	Saratale RG, Cho SK, Ghodake GS, Shin HS, Saratale GD, Park Y, Lee HS, Bharagava RN, Kim DS	Polymers (Basel)	10.3390/polym12081704	2020	*
Metabolism	Characterization of an l-Ascorbate Catabolic Pathway with Unprecedented Enzymatic Transformations.	Stack TMM, Morrison KN, Dettmer TM, Wille B, Kim C, Joyce R, Jermain M, Naing YT, Bhatti K, Francisco BS, Carter MS, Gerlt JA	J Am Chem Soc	10.1021/jacs.9b09863	2020	*
Genetics	Complete Genome Sequence of Cupriavidus necator H16 (DSM 428).	Little GT, Ehsaan M, Arenas-Lopez C, Jawed K, Winzer K, Kovacs K, Minton NP	Microbiol Resour Announc	10.1128/MRA.00814-19	2019	*
Metabolism	Characterization of poly-3-hydroxybutyrate (PHB) produced from Ralstonia eutropha using an alkali-pretreated biomass feedstock.	Saratale GD, Oh MK	Int J Biol Macromol	10.1016/j.ijbiomac.2015.07.034	2015	*
Pathogenicity	Sophorolipid biosurfactants: Possible uses as antibacterial and antibiofilm agent.	Diaz De Rienzo MA, Banat IM, Dolman B, Winterburn J, Martin PJ	N Biotechnol	10.1016/j.nbt.2015.02.009	2015	*
Metabolism	Recovery of amorphous polyhydroxybutyrate granules from Cupriavidus necator cells grown on used cooking oil.	Martino L, Cruz MV, Scoma A, Freitas F, Bertin L, Scandola M, Reis MA	Int J Biol Macromol	10.1016/j.ijbiomac.2014.04.016	2014	*
Biotechnology	Production of polyhydroxyalkanoates from spent coffee grounds oil obtained by supercritical fluid extraction technology.	Cruz MV, Paiva A, Lisboa P, Freitas F, Alves VD, Simoes P, Barreiros S, Reis MA	Bioresour Technol	10.1016/j.biortech.2014.02.013	2014	*
Metabolism	Molecular genetics and biochemistry of N-acetyltaurine degradation by Cupriavidus necator H16.	Denger K, Lehmann S, Cook AM	Microbiology (Reading)	10.1099/mic.0.048462-0	2011	*
Metabolism	Reaction engineering studies for the production of 2-hydroxyisobutyric acid with recombinant Cupriavidus necator H 16.	Hoefel T, Wittmann E, Reinecke L, Weuster-Botz D	Appl Microbiol Biotechnol	10.1007/s00253-010-2739-4	2010	*
Metabolism	Biosynthesis of polyhydroxybutyrate (PHB) and extracellular polymeric substances (EPS) by Ralstonia eutropha ATCC 17699 in batch cultures.	Wang J, Yu HQ	Appl Microbiol Biotechnol	10.1007/s00253-007-0870-7	2007	*
Metabolism	Identification of oxalotrophic bacteria by neural network analysis of numerical phenetic data.	Sahin N, Aydin S	Folia Microbiol (Praha)	10.1007/BF02932161	2006	*
Enzymology	Stability and activity of hydrogenases of Methanobacterium thermoautotrophicum and Alcaligenes eutrophus in reversed micellar systems.	Hoppert M, Braks I, Mayer F	FEMS Microbiol Lett	10.1111/j.1574-6968.1994.tb06836.x	1994	*
Enzymology	Rhein as an electron acceptor for various flavoproteins and for electron transport particles.	Egerer P, Buhler M, Simon H	Hoppe Seylers Z Physiol Chem	10.1515/bchm2.1982.363.1.627	1982	*
Phylogeny	Isolation and characterization of polysheaths, phage tail-like defective bacteriophages of Alcaligenes eutrophus H 16.	Walther-Mauruschat A, Mayer F	J Gen Virol	10.1099/0022-1317-41-2-239	1978	*
Metabolism	Mutants of Alcaligenes eutrophus defective in autotrophic metabolism.	Schink B, Schlegel HG	Arch Microbiol	10.1007/BF00402299	1978	*
Enzymology	Alpha-isopropylmalate synthase from Alcaligenes eutrophus H 16. III. Endproduct inhibition and its relief by valine and isoleucine.	Wiegel J, Schlegel HG	Arch Microbiol	10.1007/BF00446863	1977	*
Enzymology	alpha-Isopropylmalate synthase from Alcaligenes eutrophus H 16. II. Substrate specificity and kinetics.	Wiegel J, Schlegel HG	Arch Microbiol	10.1007/BF00413088	1977	*
Enzymology	Localization and stability of hydrogenases from aerobic hydrogen bacteria.	Schneider K, Schlegel HG	Arch Microbiol	10.1007/BF00413086	1977	*
Enzymology	Alpha-Isopropylmalate synthase from Alcaligenes eutrophus H 16 I. Purification and general properties.	Wiegel J, Schlegel HG	Arch Microbiol	10.1007/BF00413087	1977	*
Enzymology	Purification and properties of soluble hydrogenase from Alcaligenes eutrophus H 16.	Schneider K, Schlegel HG	Biochim Biophys Acta	10.1016/0005-2744(76)90058-9	1976	*
Metabolism	Regulation of Chorismate mutase-prephenate dehydratase and prephenate dehydrogenase from alcaligenes eutrophus.	Friedrich CG, Friedrich B, Schlegel HG	J Bacteriol	10.1128/jb.126.2.723-732.1976	1976	*
Enzymology	Aromatic amino acid biosynthesis in Alcaligenes eutrophus H 16 III. Properites and regulation of anthranilate synthase.	Friedrich CG, Friedrich B, Schlegel HG	Arch Microbiol	10.1007/BF00446831	1976	*
Metabolism	[Adenosine-dependent death of Hydrogenomonas eutropha (Alcaligenes eutrophus) H 16 (author's transl)].	Kaltwasser H, Glaeser H	Zentralbl Bakteriol Parasitenkd Infektionskr Hyg	10.1016/s0044-4057(76)80055-x	1976	*
Enzymology	Regulation of the pyruvate kinase from Alcaligenes eutrophus H 16 in vitro and in vivo.	Wilke D, Schlegel HG	Arch Microbiol	10.1007/BF00447123	1975	*
Metabolism	Aromatic amino acid biosynthesis in Alcaligenes eutrophus H16. II. The isolation and characterization of mutants auxotrophic for phenylalanine and tyrosine.	Friedrich B, Schlegel HG	Arch Microbiol	10.1007/BF00436341	1975	*
Enzymology	Kinetics and properties of beta-ketothiolase from Clostridium pasteurianum.	Berndt H, Schlegel HG	Arch Microbiol	10.1007/BF00436325	1975	*
Biotechnology	Monitoring poly(3-hydroxybutyrate) production in cupriavidus necator DSM 428 (H16) with raman spectroscopy.	Gelder JD, Willemse-Erix D, Scholtes MJ, Sanchez JI, Maquelin K, Vandenabeele P, Boever PD, Puppels GJ, Moens L, Vos PD	Anal Chem	10.1021/ac702185d	2008	*
	Upcycling Biodegradable PVA/Starch Film to a Bacterial Biopigment and Biopolymer.	Pantelic B, Ponjavic M, Jankovic V, Aleksic I, Stevanovic S, Murray J, Fournet MB, Nikodinovic-Runic J	Polymers (Basel)	10.3390/polym13213692	2021	*
	Preparation and Characterization of Films Based on a Natural P(3HB)/mcl-PHA Blend Obtained through the Co-culture of Cupriavidus Necator and Pseudomonas Citronellolis in Apple Pulp Waste.	Rebocho AT, Pereira JR, Neves LA, Alves VD, Sevrin C, Grandfils C, Freitas F, Reis MAM	Bioengineering (Basel)	10.3390/bioengineering7020034	2020	*

References

#197	Leibniz Institut DSMZ-Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH ; Curators of the DSMZ; DSM 428

#20215

Parte, A.C., Sardà Carbasse, J., Meier-Kolthoff, J.P., Reimer, L.C. and Göker, M.: List of Prokaryotic names with Standing in Nomenclature (LPSN) moves to the DSMZ. IJSEM ( DOI 10.1099/ijsem.0.004332 )

#66792

Julia Koblitz, Joaquim Sardà, Lorenz Christian Reimer, Boyke Bunk, Jörg Overmann: Automatically annotated for the DiASPora project (Digital Approaches for the Synthesis of Poorly Accessible Biodiversity Information) .

#66794

Antje Chang, Lisa Jeske, Sandra Ulbrich, Julia Hofmann, Julia Koblitz, Ida Schomburg, Meina Neumann-Schaal, Dieter Jahn, Dietmar Schomburg: BRENDA, the ELIXIR core data resource in 2021: new developments and updates. Nucleic Acids Res. 49: D498 - D508 2020 ( DOI 10.1093/nar/gkaa1025 , PubMed 33211880 )

#67770 Japan Collection of Microorganism (JCM) ; Curators of the JCM;

#69480

Julia Koblitz, Joaquim Sardà, Lorenz Christian Reimer, Boyke Bunk, Jörg Overmann: Predictions based on genome sequence made in the Diaspora project (Digital Approaches for the Synthesis of Poorly Accessible Biodiversity Information) .

#69481

Xiao-Yin To, René Mreches, Martin Binder, Alice C. McHardy, Philipp C. Münch: Predictions based on the model GenomeNet Sporulation v. 1 . ( DOI 10.21203/rs.3.rs-2527258/v1 )

#71655

Reimer, L.C., Lissin, A.,Schober, I., Witte,J.F., Podstawka, A., Lüken, H., Bunk, B.,Overmann, J.: StrainInfo: A central database for resolving microbial strain identifiers . ( DOI 10.60712/SI-ID13563.1 )

* These data were automatically processed and therefore are not curated

Change proposal

You found an error in BacDive? Please tell us about it!

Note that changes will be reviewed and judged. If your changes are legitimate, changes will occur within the next BacDive update. Only proposed changes supported by the according reference will be reviewed. The BacDive team reserves the right to reject proposed changes.

Search for species Cupriavidus necator in external resources:
SILVA
BRENDA
PANGAEA
GBIF

Cupriavidus necator H16 strain DSM 428

Cupriavidus necator H16 H16

Change proposal

Change proposal