Characterization and spontaneous mutation of a novel gene, polE, involved in pellicle formation in Acetobacter tropicalis SKU1100

Deeraksa, Arpaporn; Moonmangmee, Somporn; Toyama, Hirohide; Yamada, Mamoru; Adachi, Osao; Matsushita, Kazunobu

doi:10.1099/mic.0.28350-0

Cited by 52 publications

(46 citation statements)

References 26 publications

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“…Strains of A. pasteurianus able to cover the cells with capsular polysaccharides were found to tolerate higher concentrations of acetic acid in comparison with corresponding mutants that were not able to produce this pellicle (Deeraksa et al 2005). This protection against acetic acid appeared at the late exponential and stationary growth phase but was not present during the acetate consumption, indicating that the polysaccharides covering the cells reduce diffusion of acetic acid into the cell during ethanol oxidation phase (Kanchanarach et al 2010).…”

Section: Formation Of Extracellular Polysaccharides or Capsulesmentioning

confidence: 97%

Adaptation and tolerance of bacteria against acetic acid

Trček

Mira

Jarboe

2015

Appl Microbiol Biotechnol

195

100

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Acetic acid is a weak organic acid exerting a toxic effect to most microorganisms at concentrations as low as 0.5 wt%. This toxic effect results mostly from acetic acid dissociation inside microbial cells, causing a decrease of intracellular pH and metabolic disturbance by the anion, among other deleterious effects. These microbial inhibition mechanisms enable acetic acid to be used as a preservative, although its usefulness is limited by the emergence of highly tolerant spoilage strains. Several biotechnological processes are also inhibited by the accumulation of acetic acid in the growth medium including production of bioethanol from lignocellulosics, wine making, and microbe-based production of acetic acid itself. To design better preservation strategies based on acetic acid and to improve the robustness of industrial biotechnological processes limited by this acid's toxicity, it is essential to deepen the understanding of the underlying toxicity mechanisms. In this sense, adaptive responses that improve tolerance to acetic acid have been well studied in Escherichia coli and Saccharomyces cerevisiae. Strains highly tolerant to acetic acid, either isolated from natural environments or specifically engineered for this effect, represent a unique reservoir of information that could increase our understanding of acetic acid tolerance and contribute to the design of additional tolerance mechanisms. In this article, the mechanisms underlying the acetic acid tolerance exhibited by several bacterial strains are reviewed, with emphasis on the knowledge gathered in acetic acid bacteria and E. coli. A comparison of how these bacterial adaptive responses to acetic acid stress fit to those described in the yeast Saccharomyces cerevisiae is also performed. A systematic comparison of the similarities and dissimilarities of the ways by which different microbial systems surpass the deleterious effects of acetic acid toxicity has not been performed so far, although such exchange of knowledge can open the door to the design of novel approaches aiming the development of acetic acid-tolerant strains with increased industrial robustness in a synthetic biology perspective.

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Section: Formation Of Extracellular Polysaccharides or Capsulesmentioning

confidence: 97%

Adaptation and tolerance of bacteria against acetic acid

Trček

Mira

Jarboe

2015

Appl Microbiol Biotechnol

195

100

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“…tropicalis SKU1100 (R) strain and its mutants polE and galE (Deeraksa et al, 2005(Deeraksa et al, , 2006 were used in this study. In polE mutant, the polE gene was disrupted by insertion of Tn10 transposon, while, in galE, the galE gene (UDP-galactose 4-epimerase) was disrupted by insertion of non-polar kanamycin cassette.…”

Section: Bacterial Strains and Culture Conditionsmentioning

confidence: 99%

“…In polE mutant, the polE gene was disrupted by insertion of Tn10 transposon, while, in galE, the galE gene (UDP-galactose 4-epimerase) was disrupted by insertion of non-polar kanamycin cassette. All strains were grown at 30 • C in potato medium (Deeraksa et al, 2005). Antibiotics, kanamycin or tetracycline, were added at the concentration of 50 g/ml, or 12.5 g/ml, respectively.…”

Section: Bacterial Strains and Culture Conditionsmentioning

confidence: 99%

“…The genetic study of polysaccharides in acetic acid bacteria has shown that the acs (Saxena, Kudlicka, Okuda, & Brown, 1994) and the bcs (Wong et al, 1990) operons, in addition to ORF2 gene (Nakai, Nishiyama, Kuga, Sugano, & Shoda, 2002), are involved in cellulose biosynthesis, and the aceRQP operon in acetan biosynthesis in Ga. xylinus (Ishida, Sugano, & Shoda, 2002). Moreover, a gene cluster, polABCDE, required for pellicle formation in the R strain of A. tropicalis SKU1100, has been identified (Deeraksa et al, 2005). In this operon, polABCD showed high similarity to rfbBACD genes which are involved in dTDP-l-rhamnose biosynthesis, while polE, a novel gene downstream of polABCD, had a relatively low similarity to glycosyltransferases.…”

Section: Introductionmentioning

confidence: 99%

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Structural characterization of pellicle polysaccharides of Acetobacter tropicalis SKU1100 wild type and mutant strains

Ali¹,

Akakabe²,

Moonmangmee³

et al. 2011

Carbohydrate Polymers

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“…Therefore, pellicles are considered advantageous to aerobic bacteria for acquiring niches at the air-liquid interface. Pellicles of acetic acid bacteria (2), Bacillus sp. (1,10), and Pseudomonas sp.…”

mentioning

confidence: 99%

Determinative Factors of Competitive Advantage between Aerobic Bacteria for Niches at the Air-Liquid Interface

et al. 2010

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We focused on bacterial interspecies relationships at the air-liquid interface where the formation of pellicles by aerobes was observed. Although an obligate aerobe (Brevibacillus sp. M1-5) was initially dominant in the pellicle population, a facultative aerobe (Pseudoxanthomonas sp. M1-3) emerged and the viability of M1-5 rapidly decreased due to severe competition for oxygen. Supplementation of the medium with carbohydrates allowed the two species to coexist at the air-liquid interface. These results indicate that the population dynamics within pellicles are primarily governed by oxygen utilization which was affected by a combination of carbon sources.Key words: multispecies interaction, resource competition, air-liquid interface, pellicleIt has been widely recognized that most microorganisms have lifestyles specifically adapted to heterogeneous environments, such as solid surfaces and air-liquid interfaces. At these interfacial surfaces, various substances accumulate or are concentrated and consequently serve as biologicallyactive sites where microorganisms are thought to actively compete for space and resources (16,18,21,23). Interspecies relationships within biofilms on solid surfaces have been reported (3,11,15). Although the ubiquity of the airliquid surface in both natural and artificial environments is also well recognized (22), microbiological studies on the airliquid interface have been limited. Microbial aggregation at the air-liquid interface forms what is known as a pellicle, which is a strategy displayed by various aerobic microorganisms as it enables them to acquire oxygen effectively. Therefore, pellicles are considered advantageous to aerobic bacteria for acquiring niches at the air-liquid interface. Pellicles of acetic acid bacteria (2), Bacillus sp. (1, 10), and Pseudomonas sp. (17, 19) have been studied morphologically and physiologically under pure culture conditions. However, microbiological analyses of pellicles composed of multiple bacterial species have not been reported.We have previously demonstrated the stable co-culture of four bacterial species grown under static aerobic conditions in which pellicles were observed (6, 8). Among the members, an obligate aerobe, Brevibacillus sp. strain M1-5 and a facultative aerobe, Pseudoxanthomonas sp. strain M1-3, were both pellicle-forming species and stably coexisted in the four-species mixed culture. However, the growth of M1-5 was inhibited by M1-3 in two-species co-cultures (9). Since the pellicle is the sole niche for M1-5, it is expected that these interspecies interactions at the air-liquid interface determined the microbial population of the pellicle. In this study, we attempted to clarify the competitive relationships for niches at the air-liquid interface. Effects of the composition of the gaseous phase and growth medium on the interaction between the obligate aerobe M1-5 and facultative aerobe M1-3 were investigated by viability testing and microscopic analysis.The two species used in this study were isolated from a cellulose-degradin...

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Characterization and spontaneous mutation of a novel gene, polE, involved in pellicle formation in Acetobacter tropicalis SKU1100

Cited by 52 publications

References 26 publications

Adaptation and tolerance of bacteria against acetic acid

Adaptation and tolerance of bacteria against acetic acid

Structural characterization of pellicle polysaccharides of Acetobacter tropicalis SKU1100 wild type and mutant strains

Determinative Factors of Competitive Advantage between Aerobic Bacteria for Niches at the Air-Liquid Interface

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