Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
about
Complete Genome Sequences of Two Acetic Acid-Producing Acetobacter pasteurianus Strains (Subsp. ascendens LMG 1590T and Subsp. paradoxus LMG 1591T).Draft Genome Sequence of Acetobacter aceti Strain 1023, a Vinegar Factory Isolate.Effect of aspartic acid and glutamate on metabolism and acid stress resistance of Acetobacter pasteurianus.Transition from positive to neutral in mutation fixation along with continuing rising fitness in thermal adaptive evolution.Complete genome sequence and comparative analysis of Acetobacter pasteurianus 386B, a strain well-adapted to the cocoa bean fermentation ecosystem.Complete genomic DNA sequence of the East Asian spotted fever disease agent Rickettsia japonica.Complete genome sequence of NBRC 3288, a unique cellulose-nonproducing strain of Gluconacetobacter xylinus isolated from vinegar.Comparative Proteome of Acetobacter pasteurianus Ab3 During the High Acidity Rice Vinegar Fermentation.Bacterial Ecology of Fermented Cucumber Rising pH Spoilage as Determined by Nonculture-Based Methods.Comparative Genomics of Acetobacterpasteurianus Ab3, an Acetic Acid Producing Strain Isolated from Chinese Traditional Rice Vinegar Meiguichu.Whole-Genome Sequence Analysis of Bombella intestini LMG 28161T, a Novel Acetic Acid Bacterium Isolated from the Crop of a Red-Tailed Bumble Bee, Bombus lapidarius.Global insights into acetic acid resistance mechanisms and genetic stability of Acetobacter pasteurianus strains by comparative genomics.Genomic Analysis Unravels Reduced Inorganic Sulfur Compound Oxidation of Heterotrophic Acidophilic Acidicaldus sp. Strain DX-1Complete Genome Sequencing and Comparative Genomic Analysis of the Thermotolerant Acetic Acid Bacterium, Acetobacter pasteurianus SKU1108, Provide a New Insight into ThermotoleranceThe role of protein modifications in senescence of freeze-dried Acetobacter senegalensis during storage.Bio-based production of C2-C6 platform chemicals.Acetic Acid bacteria: physiology and carbon sources oxidation.Overview on mechanisms of acetic acid resistance in acetic acid bacteria.Nitrogen fixing bacteria in the family Acetobacteraceae and their role in agriculture.Genomic analyses of thermotolerant microorganisms used for high-temperature fermentations.Characterization of a Novel d-Glycero-d-talo-oct-2-ulosonic acid-substituted Lipid A Moiety in the Lipopolysaccharide Produced by the Acetic Acid Bacterium Acetobacter pasteurianus NBRC 3283.Draft Genome Sequence of Dihydroxyacetone-Producing Gluconobacter thailandicus Strain NBRC 3255Complete genome and gene expression analyses of Asaia bogorensis reveal unique responses to culture with mammalian cells as a potential opportunistic human pathogen.Environmentally triggered genomic plasticity and capsular polysaccharide formation are involved in increased ethanol and acetic acid tolerance in Kozakia baliensis NBRC 16680.Reconstruction of a Genome-scale Metabolic Network of Komagataeibacter nataicola RZS01 for Cellulose Production.The key to acetate: metabolic fluxes of acetic acid bacteria under cocoa pulp fermentation-simulating conditionsIdentification of a five-oxidoreductase-gene cluster from Acetobacter pasteurianus conferring ethanol-dependent acidification in Escherichia coli.Acetic acid bacteria genomes reveal functional traits for adaptation to life in insect guts.Complete sequence and organization of the Sphingobium chungbukense DJ77 pSY2 plasmid.Genome sequences of the high-acetic acid-resistant bacteria Gluconacetobacter europaeus LMG 18890T and G. europaeus LMG 18494 (reference strains), G. europaeus 5P3, and Gluconacetobacter oboediens 174Bp2 (isolated from vinegar).Acetobacter pasteurianus strain AB0220: cultivability and phenotypic stability over 9 years of preservation.SdhE-dependent formation of a functional Acetobacter pasteurianus succinate dehydrogenase in Gluconobacter oxydans--a first step toward a complete tricarboxylic acid cycle.Adaptive mutation related to cellulose producibility in Komagataeibacter medellinensis (Gluconacetobacter xylinus) NBRC 3288.Investigation of vinegar production using a novel shaken repeated batch culture system.Metabolic engineering of Gluconobacter oxydans 621H for increased biomass yield.Acetobacter pasteurianus metabolic change induced by initial acetic acid to adapt to acetic acid fermentation conditions.A single-nucleotide insertion in a drug transporter gene induces a thermotolerant phenotype of Gluconobacter frateurii by increasing the NADPH/NADP+ ratio via metabolic change.Impact of high initial concentrations of acetic acid and ethanol on acetification rate in an internal Venturi injector bioreactor.
P2860
Q33695062-9E01F0A4-25B6-45FE-B470-A81E0460A87BQ33718677-E992DFA1-20E7-4542-BB9B-8A4F63E7DD6DQ33804985-3C695E7A-5259-48BF-9812-CC5867D8ACB1Q34220343-AEB2B6A4-D7C0-466E-9C3D-F6B40618522CQ34883558-7267E28D-4557-4A94-92F1-C0EF1F6E8DCBQ34988242-A537557C-55F1-4E66-9B54-09E0CF0EA357Q35598670-B3A552B3-96FD-4D2B-BA3A-EC06329E2FC7Q35775037-A5EAB244-578E-4646-923A-9CBA2FD7A181Q35852277-CE5C9252-EAAE-45EA-91C1-5D8741DC6E8EQ36128311-405F244E-976E-45D7-9C7C-DB57773AF427Q36193924-0BD59450-1024-4FD5-80E7-A2442BB523D4Q36392796-9C87EA21-B84E-4142-B37E-4841F020621BQ36894142-C6991064-371A-43AF-8E04-1110811F43D0Q37506188-5628D4FD-9CB5-4ADF-9136-8DD05CEEDF34Q37606991-CA9E2B06-98C0-4FD9-B6BD-793343F35DEAQ38024271-076C37D8-E413-40DD-B016-C3796351DBA5Q38178602-4623A7EC-77D1-4A1F-A71E-5A95527DC092Q38313233-6D688B72-36D0-4D76-AB30-7EB3D46066A8Q38367380-80EEFDE6-CBF5-42E5-B1DE-EACE378B6A47Q38632772-FC6CEB6A-3FDD-4A66-8EDB-E10C4046CCA4Q38751142-FC543F4A-EAF3-4C17-AFFE-5235C25C73ABQ39802155-CF5E126C-31A2-4B81-991E-9A586CBA6864Q40551683-0B18E2E4-FBB2-4C6F-9A39-237428C96A1BQ41361504-503315A3-D16E-421B-A03F-BB313BB1C6C9Q41367777-895C84D8-118D-4124-8621-07A75476D9AAQ41768947-01334E93-D21A-4AD1-BE74-A6DA41185589Q41814242-8BEFC895-0D0A-45AC-A793-66457F528377Q42550903-2B567940-9920-4C68-BAA1-307BF6CD3B2CQ42615010-1E5B3F40-4225-4411-876B-345E3444B2CEQ42793107-3BCF30A1-8046-4451-82F2-A0E7D0C912E3Q44285029-AA041896-91F1-4413-901F-C8443BDC66B3Q46665296-DB29ECC8-02FD-4AB9-B974-FE2706BEC22FQ46737511-FC38406F-D632-4BA0-A114-4C64A8248DDBQ47841898-F17A0EF5-8E31-4796-8B0A-D1DCDCCF0232Q48173309-F309306F-4724-4376-8622-679C95A484EFQ50512968-78320DD2-86B6-4C94-BE6A-C22E25020EE6Q51739108-45503395-8162-4652-9F3B-D610E4B764DCQ52994140-9C848FED-EEEE-49E7-9FD5-97FBF56BFD03
P2860
Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 28 July 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
@en
Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
@nl
type
label
Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
@en
Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
@nl
prefLabel
Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
@en
Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
@nl
P2093
P2860
P356
P1476
Whole-genome analyses reveal genetic instability of Acetobacter pasteurianus.
@en
P2093
Akira Hosoyama
Hideki Hirakawa
Hiroshi Horikawa
Kazunobu Matsushita
Minenosuke Matsutani
Mutsunori Shirai
Naoko Furuya
Nobuyuki Fujita
Satoru Kuhara
Takeshi Harada
P2860
P304
P356
10.1093/NAR/GKP612
P407
P577
2009-07-28T00:00:00Z