Microbial responses to solvent and alcohol stress

Taylor, Mark Paul; Tuffin, Marla; Burton, Stephanie G.; Eley, Kirstin L.; Cowan, Don A.

doi:10.1002/biot.200800158

Cited by 20 publications

(10 citation statements)

References 116 publications

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“…On the one hand, styrene represents a carbon source that can be metabolized to yield carbon and energy for growth. On the other hand, with an octanol/water partition coefficient [log(P OW )] of 3, styrene falls into a category of organic solvents extremely toxic to microorganisms, due to their ability to bind to the cells, disturbing membranes by removing lipids and proteins and causing cell lysis (Ramos et al, 2001;Taylor et al, 2008). It is well documented that solvent-tolerant pseudomonads possess three membrane-associated solvent tolerance mechanisms: (A) active efflux of organic solvents, (B) outer membrane changes and (C) cytoplasmic membrane changes (Volkers et al, 2006).…”

Section: Mclpha Synthesis Occurs Only Under N Limitationmentioning

confidence: 99%

Analysis of the Pseudomonas putida CA-3 proteome during growth on styrene under nitrogen-limiting and non-limiting conditions

et al. 2009

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Pseudomonas putida CA-3 is a styrene-degrading bacterium capable of accumulating mediumchain-length polyhydroxyalkanoate (mclPHA) when exposed to limiting concentrations of a nitrogen source in the growth medium. Using shotgun proteomics we analysed global proteome expression in P. putida CA-3 supplied with styrene as the sole carbon and energy source under N-limiting (condition permissive for mclPHA synthesis) and non-limiting (condition non-permissive for mclPHA accumulation) growth conditions in order to provide insight into the molecular response of P. putida CA-3 to limitation of nitrogen when grown on styrene. A total of 1761 proteins were identified with high confidence and the detected proteins could be assigned to functional groups including styrene degradation, energy, nucleotide metabolism, protein synthesis, transport, stress response and motility. Proteins involved in the upper and lower styrene degradation pathway were expressed throughout the 48 h growth period under both nitrogen limitation and excess. Proteins involved in polyhydroxyalkanoate (PHA) biosynthesis, nitrogen assimilation and amino acid transport, and outer membrane proteins were upregulated under nitrogen limitation. PHA accumulation and biosynthesis were only expressed under nitrogen limitation. Nitrogen assimilation proteins were detected on average at twofold higher amounts under nitrogen limitation. Expression of the branched-chain amino acid ABC transporter was up to 16-fold higher under nitrogen-limiting conditions. Branched chain amino acid uptake by nitrogenlimited cultures was also higher than that by non-limited cultures. Outer membrane lipoproteins were expressed at twofold higher levels under nitrogen limitation. This was confirmed by Western blotting (immunochemical detection) of cells grown under nitrogen limitation. Our study provides the first global description of protein expression changes during growth of any organism on styrene and accumulating mclPHA (nitrogen-limited growth). INTRODUCTIONPseudomonas putida CA-3 has been reported to utilize styrene as a sole source of carbon and energy and to accumulate the biodegradable polymer medium-chainlength polyhydroxyalkanoate (mclPHA) when nitrogen (N) becomes limited in the growth medium (O'Connor et al., 1996;. These two abilities have been employed in the two-step chemo-biotechnological conversion of polystyrene, a non-biodegradable polymer, to mclPHA at laboratory scale (Ward et al., 2006). The process has been improved through the controlled feeding of N to the growth medium, which results in a twofold increase in biomass and a 1.4-fold increase in mclPHA accumulation (Goff et al., 2007).Molecular investigations of the styrene degradation pathway in this organism have been reported (Mooney et al., 2006b;O'Connor et al., 2001). Styrene metabolism in P. putida CA-3 proceeds via initial side chain oxidation and involves an upper pathway converting styrene to phenylacetic acid (PA) (O'Connor et al., 1995), and a lower pathway initiated via activation of PA to phenylace...

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Section: Mclpha Synthesis Occurs Only Under N Limitationmentioning

confidence: 99%

Analysis of the Pseudomonas putida CA-3 proteome during growth on styrene under nitrogen-limiting and non-limiting conditions

et al. 2009

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“…However, catabolically versatile engineered strains and novel isolates engineered with ethanologenic pathways have subsequently been shown to exhibit limitations in ethanol tolerance, hindering their full potential as economically viable production strains [15]. Also, the overall metabolic energy burden of both ethanol fermentation and cellulase production in an energy-frugal anaerobe is just beginning to be evaluated [16,17].…”

mentioning

confidence: 99%

Optimization of Growth Medium and Enzyme Assay Conditions for Crude Cellulases Produced by a Novel Thermophilic and Cellulolytic Bacterium, Anoxybacillus sp. 527

Liang

Feng

Yesuf

et al. 2009

Appl Biochem Biotechnol

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A newly isolated Anoxybacillus sp. 527 was found to grow on crystalline cellulose as sole carbon and energy sources. Cellulases secreted by strain 527 were better induced by cellobiose, followed by glucose, lactose, sucrose, and cellulose. Cellulase secretion was enhanced by an optimized medium. Cellulase activity was increased by the addition of Ca(2+) and NH (4) (+) and achieved maximum as 7.0 FPU ml(-1) at 70 degrees C and pH 6.0. Even at 100 degrees C, the enzymes were still active, which implies their potential application in large-scale cellulose conversion process.

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“…Industrial strains produce solvent products through fermentation, however they can be sensitive to their own solvent products (Taylor et al, 2008), which reduce cell vitality, impair membrane integrity, inhibit enzymes and/or perturb intracellular pH balance (Taylor et al, 2008;Timmons et al, 2009). Interestingly, the sensitivity to solvent stress is likely linked to temperature, as thermophiles can be less tolerant to a high-level of solvents such as ethanol than the mesophilic ethanologen such as Z. mobilis and S. cerevisiae (Timmons et al, 2009).…”

Section: The Thermophiles Are Sensitive To Solvent Stressmentioning

confidence: 99%

“…In mesophiles, the general solvent responses involve increased membrane fluidity, solvent exclusion systems, energy-dependent efflux pumps of the resistancenodulation-cell division (RND) family, stress-response genes (soxS, marA and robA encoding DNA-binding proteins/transcriptional activators), mannose transporter of the phosphotransferase system (manXYZ), ATPase, heat shock proteins (GroESL) and redox balance maintenance (Ma and Liu, 2010;Okochi et al, 2007;Ramos et al, 2002;Rutherford et al, 2010;Taylor et al, 2008;Tomas et al, 2004). In thermophilic bacteria, however, the modes of solvent-induced membrane alterations are different from those of the mesophiles.…”

Section: The Thermophiles Are Sensitive To Solvent Stressmentioning

confidence: 99%

Dissecting and engineering metabolic and regulatory networks of thermophilic bacteria for biofuel production

Lin

2013

Biotechnology Advances

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Interest in thermophilic bacteria as live-cell catalysts in biofuel and biochemical industry has surged in recent years, due to their tolerance of high temperature and wide spectrum of carbon-sources that include cellulose. However their direct employment as microbial cellular factories in the highly demanding industrial conditions has been hindered by uncompetitive biofuel productivity, relatively low tolerance to solvent and osmic stresses, and limitation in genome engineering tools. In this work we review recent advances in dissecting and engineering the metabolic and regulatory networks of thermophilic bacteria for improving the traits of key interest in biofuel industry: cellulose degradation, pentose-hexose co-utilization, and tolerance of thermal, osmotic, and solvent stresses. Moreover, new technologies enabling more efficient genetic engineering of thermophiles were discussed, such as improved electroporation, ultrasound-mediated DNA delivery, as well as thermo-stable plasmids and functional selection systems. Expanded applications of such technological advancements in thermophilic microbes promise to substantiate a synthetic biology perspective, where functional parts, module, chassis, cells and consortia were modularly designed and rationally assembled for the many missions at industry and nature that demand the extraordinary talents of these extremophiles.

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Microbial responses to solvent and alcohol stress

Cited by 20 publications

References 116 publications

Analysis of the Pseudomonas putida CA-3 proteome during growth on styrene under nitrogen-limiting and non-limiting conditions

Analysis of the Pseudomonas putida CA-3 proteome during growth on styrene under nitrogen-limiting and non-limiting conditions

Optimization of Growth Medium and Enzyme Assay Conditions for Crude Cellulases Produced by a Novel Thermophilic and Cellulolytic Bacterium, Anoxybacillus sp. 527

Dissecting and engineering metabolic and regulatory networks of thermophilic bacteria for biofuel production

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