Name: Mesorhizobium japonicum MAFF 303099
Creator: BacDive
License: http://creativecommons.org/licenses/by-nc/4.0/

Strain identifier

BacDive ID: 133271

Type strain:

Species: Mesorhizobium japonicum

Culture col. no.: MAFF 303099, LMG 29417, CECT 9101, JCM 21590, IAM 15132

Strain history: IAM 15132 <-- MAFF 303099.

NCBI tax ID(s): 266835 (strain), 2066070 (species)

Section

Mesorhizobium japonicum MAFF 303099 is an aerobe, Gram-negative, rod-shaped bacterium that forms circular colonies and was isolated from root nodules of Lotus japonicum.

colony-forming
Gram-negative
rod-shaped
aerobe
Bacteria
genome sequence

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

	Last LPSN update	14-12-2023 (DD-MM-YYYY)
	Domain	"Bacteria"
	Phylum	*Pseudomonadota*
	Class	*Alphaproteobacteria*
	Order	*Hyphomicrobiales*
	Family	*Phyllobacteriaceae*
	Genus	*Mesorhizobium*
	Species	**Mesorhizobium japonicum**
	Full Scientific Name (LPSN)	Mesorhizobium japonicum Martínez-Hidalgo et al. 2016

Information on morphological and physiological properties Morphology

[Ref.: #25130]	Gram stain	negative
[Ref.: #69480]	Gram stain	negative Confidence in %99.984

[Ref.: #25130]	Cell shape	rod-shaped

[Ref.: #69480]	Motility	yes Confidence in %92.538

[Ref.: #25130]	Colony size	1.0-2.0 mm
[Ref.: #25130]	Colony color	white
[Ref.: #25130]	Colony shape	circular
[Ref.: #25130]	Incubation period	4-5 days
[Ref.: #25130]	Cultivation medium used	YMA (yeast mannitol agar)

Information on culture and growth conditions Culture and growth conditions

[Ref.: #25130]

Culture medium

YMA (yeast mannitol agar)

[Ref.: #25130]

Culture medium growth

	Kind of temperature		Temperature
[Ref.: #25130]		growth	15.0-34.0 °C
[Ref.: #25130]		optimum	28 °C
[Ref.: #25130]	no	growth	10 °C
[Ref.: #25130]		growth	37 °C
[Ref.: #67770]		growth	28 °C

[Ref.: #25130]	Temperature range	mesophilic
[Ref.: #25130]	Temperature range	psychrophilic
[Ref.: #25130]	Temperature range	mesophilic
[Ref.: #67770]	Temperature range	mesophilic

	pH	Kind of pH		pH
[Ref.: #25130]			optimum	7
[Ref.: #25130]			growth	6.0-8.0

Information on physiology and metabolism Physiology and metabolism

[Ref.: #25130]

Oxygen tolerance

aerobe

[Ref.: #69481]	Ability of spore formation	no Confidence in %100
[Ref.: #69480]	Ability of spore formation	no Confidence in %99.993

	Halophily	Salt	Tested relation		Salt conc.
[Ref.: #25130]		NaCl		maximum	5	%
[Ref.: #25130]		NaCl	no	growth	1	%

	Metabolite	Utilization activity	Kind of utilization tested
[Ref.: #25130]	2-dehydro-D-gluconate ChEBI	-	assimilation
[Ref.: #25130]	2-dehydro-D-gluconate ChEBI	-	builds base from
[Ref.: #25130]	3-hydroxybenzoate ChEBI	-	assimilation
[Ref.: #25130]	3-hydroxybutyrate ChEBI	+	assimilation
[Ref.: #25130]	4-hydroxybenzoate ChEBI	+	assimilation
[Ref.: #25130]	5-dehydro-D-gluconate ChEBI	-	assimilation
[Ref.: #25130]	5-dehydro-D-gluconate ChEBI	-	builds base from
[Ref.: #25130]	acetate ChEBI	+	assimilation
[Ref.: #25130]	adipate ChEBI	+	assimilation
[Ref.: #25130]	amygdalin ChEBI	-	builds acid from
[Ref.: #25130]	arbutin ChEBI	+	assimilation
[Ref.: #25130]	butyrate ChEBI	-	assimilation
[Ref.: #25130]	cellobiose ChEBI	-	builds acid from
[Ref.: #25130]	citrate ChEBI	-	assimilation
[Ref.: #25130]	D-arabinose ChEBI	+	builds acid from
[Ref.: #25130]	D-arabitol ChEBI	+	builds acid from
[Ref.: #25130]	D-fructose ChEBI	+	builds acid from
[Ref.: #25130]	D-fucose ChEBI	+	builds acid from
[Ref.: #25130]	D-galactose ChEBI	+	builds acid from
[Ref.: #25130]	D-glucose ChEBI	+	builds acid from
[Ref.: #25130]	D-lyxose ChEBI	+	builds acid from
[Ref.: #25130]	D-mannitol ChEBI	+	builds acid from
[Ref.: #25130]	D-mannose ChEBI	+	builds acid from
[Ref.: #25130]	D-ribose ChEBI	+	assimilation
[Ref.: #25130]	D-ribose ChEBI	+	builds acid from
[Ref.: #25130]	D-sorbitol ChEBI	+	assimilation
[Ref.: #25130]	D-sorbitol ChEBI	+	builds acid from
[Ref.: #25130]	D-tagatose ChEBI	-	builds acid from
[Ref.: #25130]	D-xylose ChEBI	+	builds acid from
[Ref.: #25130]	erythritol ChEBI	-	builds acid from
[Ref.: #25130]	esculin ChEBI	+	hydrolysis
[Ref.: #25130]	esculin ChEBI	+	assimilation
[Ref.: #25130]	galactitol ChEBI	-	builds acid from
[Ref.: #25130]	gentiobiose ChEBI	-	builds acid from
[Ref.: #25130]	gluconate ChEBI	+	assimilation
[Ref.: #25130]	glucose ChEBI	+	assimilation
[Ref.: #25130]	glycerol ChEBI	+	builds acid from
[Ref.: #25130]	glycogen ChEBI	-	assimilation
[Ref.: #25130]	glycogen ChEBI	-	builds acid from
[Ref.: #25130]	inulin ChEBI	-	builds acid from
[Ref.: #25130]	itaconate ChEBI	-	assimilation
[Ref.: #25130]	L-alanine ChEBI	-	assimilation
[Ref.: #25130]	L-arabinose ChEBI	+	assimilation
[Ref.: #25130]	L-arabinose ChEBI	+	builds acid from
[Ref.: #25130]	L-arabitol ChEBI	-	builds acid from
[Ref.: #25130]	L-fucose ChEBI	+	assimilation
[Ref.: #25130]	L-fucose ChEBI	+	builds acid from
[Ref.: #25130]	L-histidine ChEBI	+	assimilation
[Ref.: #25130]	L-proline ChEBI	+	assimilation
[Ref.: #25130]	L-rhamnose ChEBI	+	assimilation
[Ref.: #25130]	L-rhamnose ChEBI	+	builds acid from
[Ref.: #25130]	L-serine ChEBI	-	assimilation
[Ref.: #25130]	L-sorbose ChEBI	-	builds acid from
[Ref.: #25130]	L-xylose ChEBI	+	builds acid from
[Ref.: #25130]	lactate ChEBI	+	assimilation
[Ref.: #25130]	lactose ChEBI	-	builds acid from
[Ref.: #25130]	malate ChEBI	+	assimilation
[Ref.: #25130]	malonate ChEBI	-	assimilation
[Ref.: #25130]	maltose ChEBI	-	builds acid from
[Ref.: #25130]	maltose ChEBI	+	assimilation
[Ref.: #25130]	mannitol ChEBI	+	assimilation
[Ref.: #25130]	mannose ChEBI	+	assimilation
[Ref.: #25130]	melezitose ChEBI	-	builds acid from
[Ref.: #25130]	melibiose ChEBI	+	assimilation
[Ref.: #25130]	melibiose ChEBI	+	builds acid from
[Ref.: #25130]	methyl alpha-D-mannoside ChEBI	-	builds acid from
[Ref.: #25130]	methyl alpha-D-xylopyranoside	-	builds acid from
[Ref.: #25130]	methyl D-glucoside ChEBI	-	builds acid from
[Ref.: #25130]	myo-inositol ChEBI	-	builds acid from
[Ref.: #25130]	myo-inositol ChEBI	+	assimilation
[Ref.: #25130]	N-acetylglucosamine ChEBI	+	assimilation
[Ref.: #25130]	N-acetylglucosamine ChEBI	+	builds acid from
[Ref.: #25130]	nitrate ChEBI	-	reduction
[Ref.: #25130]	phenylacetate ChEBI	-	assimilation
[Ref.: #25130]	potassium gluconate ChEBI	-	builds base from
[Ref.: #25130]	propionate ChEBI	+	assimilation
[Ref.: #25130]	raffinose ChEBI	-	builds acid from
[Ref.: #25130]	ribitol ChEBI	+	builds acid from
[Ref.: #25130]	salicin ChEBI	-	builds acid from
[Ref.: #25130]	salicin ChEBI	+	assimilation
[Ref.: #25130]	starch ChEBI	-	builds acid from
[Ref.: #25130]	suberic acid ChEBI	-	assimilation
[Ref.: #25130]	sucrose ChEBI	+	assimilation
[Ref.: #25130]	sucrose ChEBI	+	builds acid from
[Ref.: #25130]	trehalose ChEBI	+	builds acid from
[Ref.: #25130]	turanose ChEBI	-	builds acid from
[Ref.: #25130]	valerate ChEBI	-	assimilation
[Ref.: #25130]	xylitol ChEBI	-	builds acid from
	Only first 10 entries are displayed. Click here to see all.

	Metabolite	Antibiotic sensitivity	Antibiotic resistance
[Ref.: #25130]	ampicillin ChEBI	yes
[Ref.: #25130]	cefuroxime ChEBI	yes
[Ref.: #25130]	ciprofloxacin ChEBI	yes
[Ref.: #25130]	cloxacillin ChEBI		yes
[Ref.: #25130]	erythromycin ChEBI		yes
[Ref.: #25130]	gentamicin ChEBI	yes
[Ref.: #25130]	neomycin ChEBI	yes
[Ref.: #25130]	penicillin ChEBI	yes
[Ref.: #25130]	polymyxin b ChEBI	yes
[Ref.: #25130]	tetracycline ChEBI	yes

	Enzyme	Enzyme activity	EC number
[Ref.: #25130]	arginine dihydrolase	-	3.5.3.6
[Ref.: #25130]	beta-galactosidase	+	3.2.1.23
[Ref.: #25130]	gelatinase	-
[Ref.: #25130]	urease	+	3.5.1.5

	Pathway	Enzyme coverage	Annotated reactions
	Pathway annotation	Computationally determined by
[Ref.: #66794]	4-hydroxymandelate degradation	100	9 of 9
[Ref.: #66794]	biotin biosynthesis	100	4 of 4
[Ref.: #66794]	ribulose monophosphate pathway	100	2 of 2
[Ref.: #66794]	allantoin degradation	100	9 of 9
[Ref.: #66794]	formaldehyde oxidation	100	3 of 3
[Ref.: #66794]	molybdenum cofactor biosynthesis	100	9 of 9
[Ref.: #66794]	coenzyme A metabolism	100	4 of 4
[Ref.: #66794]	sulfopterin metabolism	100	4 of 4
[Ref.: #66794]	adipate degradation	100	2 of 2
[Ref.: #66794]	CDP-diacylglycerol biosynthesis	100	2 of 2
[Ref.: #66794]	UDP-GlcNAc biosynthesis	100	3 of 3
[Ref.: #66794]	methane metabolism	100	3 of 3
[Ref.: #66794]	aminopropanol phosphate biosynthesis	100	2 of 2
[Ref.: #66794]	pentose phosphate pathway	100	11 of 11
[Ref.: #66794]	kanosamine biosynthesis II	100	2 of 2
[Ref.: #66794]	ethanol fermentation	100	2 of 2
[Ref.: #66794]	threonine metabolism	100	10 of 10
[Ref.: #66794]	palmitate biosynthesis	100	22 of 22
[Ref.: #66794]	ppGpp biosynthesis	100	4 of 4
[Ref.: #66794]	cardiolipin biosynthesis	100	7 of 7
[Ref.: #66794]	methylglyoxal degradation	100	5 of 5
[Ref.: #66794]	butanoate fermentation	100	4 of 4
[Ref.: #66794]	valine metabolism	100	9 of 9
[Ref.: #66794]	quinate degradation	100	2 of 2
[Ref.: #66794]	Entner Doudoroff pathway	100	10 of 10
[Ref.: #66794]	cis-vaccenate biosynthesis	100	2 of 2
[Ref.: #66794]	lactate fermentation	100	4 of 4
[Ref.: #66794]	creatinine degradation	100	5 of 5
[Ref.: #66794]	glycogen metabolism	100	5 of 5
[Ref.: #66794]	aspartate and asparagine metabolism	100	9 of 9
[Ref.: #66794]	C4 and CAM-carbon fixation	100	8 of 8
[Ref.: #66794]	anapleurotic synthesis of oxalacetate	100	1 of 1
[Ref.: #66794]	aerobactin biosynthesis	100	1 of 1
[Ref.: #66794]	gluconeogenesis	100	8 of 8
[Ref.: #66794]	ceramide biosynthesis	100	1 of 1
[Ref.: #66794]	glutamate and glutamine metabolism	100	28 of 28
[Ref.: #66794]	folate polyglutamylation	100	1 of 1
[Ref.: #66794]	taurine degradation	100	1 of 1
[Ref.: #66794]	suberin monomers biosynthesis	100	2 of 2
[Ref.: #66794]	vitamin B12 metabolism	94.12	32 of 34
[Ref.: #66794]	pyrimidine metabolism	93.33	42 of 45
[Ref.: #66794]	flavin biosynthesis	93.33	14 of 15
[Ref.: #66794]	citric acid cycle	92.86	13 of 14
[Ref.: #66794]	photosynthesis	92.86	13 of 14
[Ref.: #66794]	phenylalanine metabolism	92.31	12 of 13
[Ref.: #66794]	leucine metabolism	92.31	12 of 13
[Ref.: #66794]	proline metabolism	90.91	10 of 11
[Ref.: #66794]	propionate fermentation	90	9 of 10
[Ref.: #66794]	alanine metabolism	89.66	26 of 29
[Ref.: #66794]	serine metabolism	88.89	8 of 9
[Ref.: #66794]	NAD metabolism	88.89	16 of 18
[Ref.: #66794]	lipid A biosynthesis	88.89	8 of 9
[Ref.: #66794]	chorismate metabolism	88.89	8 of 9
[Ref.: #66794]	CO2 fixation in Crenarchaeota	88.89	8 of 9
[Ref.: #66794]	ketogluconate metabolism	87.5	7 of 8
[Ref.: #66794]	isoleucine metabolism	87.5	7 of 8
[Ref.: #66794]	reductive acetyl coenzyme A pathway	85.71	6 of 7
[Ref.: #66794]	propanol degradation	85.71	6 of 7
[Ref.: #66794]	tetrahydrofolate metabolism	85.71	12 of 14
[Ref.: #66794]	heme metabolism	85.71	12 of 14
[Ref.: #66794]	purine metabolism	85.11	80 of 94
[Ref.: #66794]	urea cycle	84.62	11 of 13
[Ref.: #66794]	methionine metabolism	84.62	22 of 26
[Ref.: #66794]	degradation of sugar acids	84	21 of 25
[Ref.: #66794]	glycolate and glyoxylate degradation	83.33	5 of 6
[Ref.: #66794]	histidine metabolism	82.76	24 of 29
[Ref.: #66794]	glycolysis	82.35	14 of 17
[Ref.: #66794]	vitamin B6 metabolism	81.82	9 of 11
[Ref.: #66794]	tryptophan metabolism	81.58	31 of 38
[Ref.: #66794]	lysine metabolism	80.95	34 of 42
[Ref.: #66794]	3-chlorocatechol degradation	80	4 of 5
[Ref.: #66794]	hydrogen production	80	4 of 5
[Ref.: #66794]	glycine betaine biosynthesis	80	4 of 5
[Ref.: #66794]	peptidoglycan biosynthesis	80	12 of 15
[Ref.: #66794]	ethylmalonyl-CoA pathway	80	4 of 5
[Ref.: #66794]	phenylacetate degradation (aerobic)	80	4 of 5
[Ref.: #66794]	tyrosine metabolism	78.57	11 of 14
[Ref.: #66794]	degradation of pentoses	78.57	22 of 28
[Ref.: #66794]	glutathione metabolism	78.57	11 of 14
[Ref.: #66794]	d-mannose degradation	77.78	7 of 9
[Ref.: #66794]	vitamin B1 metabolism	76.92	10 of 13
[Ref.: #66794]	degradation of sugar alcohols	75	12 of 16
[Ref.: #66794]	acetate fermentation	75	3 of 4
[Ref.: #66794]	glycogen biosynthesis	75	3 of 4
[Ref.: #66794]	dTDPLrhamnose biosynthesis	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]	carnitine metabolism	75	6 of 8
[Ref.: #66794]	arginine metabolism	75	18 of 24
[Ref.: #66794]	oxidative phosphorylation	73.63	67 of 91
[Ref.: #66794]	degradation of hexoses	72.22	13 of 18
[Ref.: #66794]	ubiquinone biosynthesis	71.43	5 of 7
[Ref.: #66794]	non-pathway related	71.05	27 of 38
[Ref.: #66794]	lipid metabolism	70.97	22 of 31
[Ref.: #66794]	cyanate degradation	66.67	2 of 3
[Ref.: #66794]	octane oxidation	66.67	2 of 3
[Ref.: #66794]	cysteine metabolism	66.67	12 of 18
[Ref.: #66794]	acetoin degradation	66.67	2 of 3
[Ref.: #66794]	selenocysteine biosynthesis	66.67	4 of 6
[Ref.: #66794]	3-phenylpropionate degradation	66.67	10 of 15
[Ref.: #66794]	L-lactaldehyde degradation	66.67	2 of 3
[Ref.: #66794]	IAA biosynthesis	66.67	2 of 3
[Ref.: #66794]	bile acid biosynthesis, neutral pathway	64.71	11 of 17
[Ref.: #66794]	6-hydroxymethyl-dihydropterin diphosphate biosynthesis	62.5	5 of 8
[Ref.: #66794]	sulfate reduction	61.54	8 of 13
[Ref.: #66794]	phosphatidylethanolamine bioynthesis	61.54	8 of 13
[Ref.: #66794]	D-cycloserine biosynthesis	60	3 of 5
[Ref.: #66794]	phenol degradation	60	12 of 20
[Ref.: #66794]	lipoate biosynthesis	60	3 of 5
[Ref.: #66794]	cellulose degradation	60	3 of 5
[Ref.: #66794]	metabolism of amino sugars and derivatives	60	3 of 5
[Ref.: #66794]	myo-inositol biosynthesis	60	6 of 10
[Ref.: #66794]	isoprenoid biosynthesis	57.69	15 of 26
[Ref.: #66794]	nitrate assimilation	55.56	5 of 9
[Ref.: #66794]	metabolism of disaccharids	54.55	6 of 11
[Ref.: #66794]	polyamine pathway	52.17	12 of 23
[Ref.: #66794]	phenylmercury acetate degradation	50	1 of 2
[Ref.: #66794]	mannosylglycerate biosynthesis	50	1 of 2
[Ref.: #66794]	cyclohexanol degradation	50	2 of 4
[Ref.: #66794]	glycine metabolism	50	5 of 10
[Ref.: #66794]	pantothenate biosynthesis	50	3 of 6
[Ref.: #66794]	alginate biosynthesis	50	2 of 4
[Ref.: #66794]	androgen and estrogen metabolism	50	8 of 16
[Ref.: #66794]	d-xylose degradation	45.45	5 of 11
[Ref.: #66794]	ascorbate metabolism	45.45	10 of 22
[Ref.: #66794]	arachidonic acid metabolism	44.44	8 of 18
[Ref.: #66794]	carotenoid biosynthesis	40.91	9 of 22
[Ref.: #66794]	coenzyme M biosynthesis	40	4 of 10
[Ref.: #66794]	O-antigen biosynthesis	40	2 of 5
[Ref.: #66794]	arachidonate biosynthesis	40	2 of 5
[Ref.: #66794]	gallate degradation	40	2 of 5
[Ref.: #66794]	factor 420 biosynthesis	40	2 of 5
[Ref.: #66794]	starch degradation	40	4 of 10
[Ref.: #66794]	bacilysin biosynthesis	40	2 of 5
[Ref.: #66794]	cholesterol biosynthesis	36.36	4 of 11
[Ref.: #66794]	acetyl CoA biosynthesis	33.33	1 of 3
[Ref.: #66794]	sphingosine metabolism	33.33	2 of 6
[Ref.: #66794]	sulfoquinovose degradation	33.33	1 of 3
[Ref.: #66794]	(5R)-carbapenem carboxylate biosynthesis	33.33	1 of 3
[Ref.: #66794]	enterobactin biosynthesis	33.33	1 of 3
[Ref.: #66794]	phenylpropanoid biosynthesis	30.77	4 of 13
[Ref.: #66794]	4-hydroxyphenylacetate degradation	30	3 of 10
[Ref.: #66794]	aclacinomycin biosynthesis	28.57	2 of 7
[Ref.: #66794]	benzoyl-CoA degradation	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]	toluene degradation	25	1 of 4
[Ref.: #66794]	catecholamine biosynthesis	25	1 of 4
[Ref.: #66794]	vitamin E metabolism	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.: #25130]	Sample type/isolated from	root nodules of Lotus japonicum
[Ref.: #25130]	Country	Japan
[Ref.: #25130]	Country ISO 3 Code	JPN
[Ref.: #25130]	Continent	Asia

[Ref.: #67770]	Sample type/isolated from	Lotus corniculatus
[Ref.: #67770]	Host species	Lotus corniculatus
[Ref.: #67770]	Geographic location (country and/or sea, region)	Tochigi
[Ref.: #67770]	Country	Japan
[Ref.: #67770]	Country ISO 3 Code	JPN
[Ref.: #67770]	Continent	Asia
* marker position based on {}

Isolation sources categories

#Host	#Plants	#Herbaceous plants (Grass,Crops)
#Host Body-Site	#Plant	#Root nodule

What are isolation sources categories?

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

Genome sequence information:

	Sequence accession description	Seq. accession number	Assembly level	Sequence database	Associated NCBI tax ID
[Ref.: #66792]	Mesorhizobium japonicum MAFF 303099	GCA_000009625	complete	GenBank	266835 tax ID	*
[Ref.: #66792]	Mesorhizobium loti MAFF303099	266835.9	complete	PATRIC	266835 tax ID	*
[Ref.: #66792]	Mesorhizobium loti MAFF303099	266835.36	plasmid	PATRIC	266835 tax ID	*
[Ref.: #66792]	Mesorhizobium loti MAFF303099	266835.37	plasmid	PATRIC	266835 tax ID	*
[Ref.: #66792]	Mesorhizobium japonicum MAFF 303099	637000159	complete	JGI IMG/M	266835 tax ID	*

[Ref.: #25130]

GC-content

62.9 mol%

genome sequence analysis

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

	Trait	Prediction	Confidence in %	In training data
	Predictions from GenomeNet Sporulation v. 1 based on: Mesorhizobium japonicum MAFF 303099 MAFF 303099 NCBI: GCA_000009625.1
[Ref.: #69481]	spore-forming	no	100	no

	Trait	Prediction	Confidence in %	In training data
	Predictions from Diaspora project based on: Mesorhizobium japonicum MAFF 303099 MAFF 303099 NCBI: GCA_000009625.1
[Ref.: #69480]	motile	yes	89.32	no
[Ref.: #69480]	flagellated	no	81.331	no
[Ref.: #69480]	gram-positive	no	98.174	yes
[Ref.: #69480]	anaerobic	no	98.596	yes
[Ref.: #69480]	halophile	no	94.229	no
[Ref.: #69480]	spore-forming	no	93.911	no
[Ref.: #69480]	thermophile	no	99.517	no
[Ref.: #69480]	glucose-util	yes	92.575	no
[Ref.: #69480]	aerobic	yes	92.865	yes
[Ref.: #69480]	glucose-ferment	no	90.556	no

Availability in culture collections External links

[Ref.: #25130]

Culture collection no.

MAFF 303099, LMG 29417, CECT 9101, JCM 21590, IAM 15132

Literature:

Topic	Title	Authors	Journal	DOI	Year
Phylogeny	Mesorhizobium carmichaelinearum sp. nov., isolated from Carmichaelineae spp. root nodules.	De Meyer SE, Andrews M, James EK, Willems A	Int J Syst Evol Microbiol	10.1099/ijsem.0.003120	2018	*
Phylogeny	Reclassification of strains MAFF 303099T and R7A into Mesorhizobiumjaponicum sp. nov.	Martinez-Hidalgo P, Ramirez-Bahena MH, Flores-Felix JD, Igual JM, Sanjuan J, Leon-Barrios M, Peix A, Velazquez E	Int J Syst Evol Microbiol	10.1099/ijsem.0.001448	2016	*
Biotechnology	Phenolic Acids Induce Nod Factor Production in Lotus japonicus-Mesorhizobium Symbiosis.	Shimamura M, Kumaki T, Hashimoto S, Saeki K, Ayabe SI, Higashitani A, Akashi T, Sato S, Aoki T	Microbes Environ	10.1264/jsme2.ME21094	2022	*
Phylogeny	Two Broad Host Range Rhizobial Strains Isolated From Relict Legumes Have Various Complementary Effects on Symbiotic Parameters of Co-inoculated Plants.	Safronova V, Belimov A, Sazanova A, Chirak E, Kuznetsova I, Andronov E, Pinaev A, Tsyganova A, Seliverstova E, Kitaeva A, Tsyganov V, Tikhonovich I	Front Microbiol	10.3389/fmicb.2019.00514	2019	*
Phylogeny	traG Gene Is Conserved across Mesorhizobium spp. Able to Nodulate the Same Host Plant and Expressed in Response to Root Exudates.	Paco A, da-Silva JR, Eliziario F, Brigido C, Oliveira S, Alexandre A	Biomed Res Int	10.1155/2019/3715271	2019	*

References

#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 )

#25130

P. R.-B. Martínez-Hidalgo, M. H.,Flores-Félix, J. D.,Igual, J. M.,Sanjuán, J.,León-Barrios, M.,Peix, A.,Velázquez, E.: Reclassification of strains MAFF 303099T and R7A into Mesorhizobium japonicum sp. nov. IJSEM 66: 4936 - 4941 2016 ( DOI 10.1099/ijsem.0.001448 , PubMed 27565417 )

#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 )

* These data were automatically processed and therefore are not curated

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Search for species Mesorhizobium japonicum in external resources:
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Mesorhizobium japonicum MAFF 303099 MAFF 303099

Mesorhizobium japonicum MAFF 303099 MAFF 303099

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