Literature DB >> 15812037

Accumulation of polyhydroxyalkanoate from styrene and phenylacetic acid by Pseudomonas putida CA-3.

Patrick G Ward1, Guy de Roo, Kevin E O'Connor.   

Abstract

Pseudomonas putida CA-3 is capable of converting the aromatic hydrocarbon styrene, its metabolite phenylacetic acid, and glucose into polyhydroxyalkanoate (PHA) when a limiting concentration of nitrogen (as sodium ammonium phosphate) is supplied to the growth medium. PHA accumulation occurs to a low level when the nitrogen concentration drops below 26.8 mg/liter and increases rapidly once the nitrogen is no longer detectable in the growth medium. The depletion of nitrogen and the onset of PHA accumulation coincided with a decrease in the rate of substrate utilization and biochemical activity of whole cells grown on styrene, phenylacetic acid, and glucose. However, the efficiency of carbon conversion to PHA dramatically increased once the nitrogen concentration dropped below 26.8 mg/liter in the growth medium. When supplied with 67 mg of nitrogen/liter, the carbon-to-nitrogen (C:N) ratios that result in a maximum yield of PHA (grams of PHA per gram of carbon) for styrene, phenylacetic acid, and glucose are 28:1, 21:1, and 18:1, respectively. In cells grown on styrene and phenylacetic acid, decreasing the carbon-to-nitrogen ratio below 28:1 and 21:1, respectively, by increasing the nitrogen concentration and using a fixed carbon concentration leads to lower levels of PHA per cell and lower levels of PHA per batch of cells. Increasing the carbon-to-nitrogen ratio above 28:1 and 21:1 for cells grown on styrene and phenylacetic acid, respectively, by decreasing the nitrogen concentration and using a fixed carbon concentration increases the level of PHA per cell but results in a lower level of PHA per batch of cells. Increasing the carbon and nitrogen concentrations but maintaining the carbon-to-nitrogen ratio of 28:1 and 21:1 for cells grown on styrene and phenylacetic acid, respectively, results in an increase in the total PHA per batch of cells. The maximum yields for PHA from styrene, phenylacetic acid, and glucose are 0.11, 0.17, and 0.22 g of PHA per g of carbon, respectively.

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Year:  2005        PMID: 15812037      PMCID: PMC1082534          DOI: 10.1128/AEM.71.4.2046-2052.2005

Source DB:  PubMed          Journal:  Appl Environ Microbiol        ISSN: 0099-2240            Impact factor:   4.792


  25 in total

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Authors:  S F Williams; D P Martin; D M Horowitz; O P Peoples
Journal:  Int J Biol Macromol       Date:  1999 Jun-Jul       Impact factor: 6.953

2.  Acetylornithinase of Escherichia coli: partial purification and some properties.

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Review 3.  Polyhydroxyalkanoates, biopolyesters from renewable resources: physiological and engineering aspects.

Authors:  G Braunegg; G Lefebvre; K F Genser
Journal:  J Biotechnol       Date:  1998-10-27       Impact factor: 3.307

4.  Microbial synthesis of poly(beta-hydroxyalkanoates) bearing phenyl groups from pseudomonas putida: chemical structure and characterization.

Authors:  G A Abraham; A Gallardo; J San Roman; E R Olivera; R Jodra; B García; B Miñambres; J L García; J M Luengo
Journal:  Biomacromolecules       Date:  2001       Impact factor: 6.988

5.  Induction and repression of the sty operon in Pseudomonas putida CA-3 during growth on phenylacetic acid under organic and inorganic nutrient-limiting continuous culture conditions.

Authors:  Niall D O'Leary; Wouter A Duetz; Alan D W Dobson; Kevin E O'Connor
Journal:  FEMS Microbiol Lett       Date:  2002-03-05       Impact factor: 2.742

6.  Development of environmentally friendly coatings and paints using medium-chain-length poly(3-hydroxyalkanoates) as the polymer binder.

Authors:  G A van der Walle; G J Buisman; R A Weusthuis; G Eggink
Journal:  Int J Biol Macromol       Date:  1999 Jun-Jul       Impact factor: 6.953

Review 7.  Metabolic engineering of poly(3-hydroxyalkanoates): from DNA to plastic.

Authors:  L L Madison; G W Huisman
Journal:  Microbiol Mol Biol Rev       Date:  1999-03       Impact factor: 11.056

8.  Bacterial polyhydroxyalkanoates.

Authors:  S Y Lee
Journal:  Biotechnol Bioeng       Date:  1996-01-05       Impact factor: 4.530

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Authors:  Charlotte Westblad; Yiannis A Levendis; Henning Richter; Jack B Howard; Joel Carlson
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10.  13C nuclear magnetic resonance studies of Pseudomonas putida fatty acid metabolic routes involved in poly(3-hydroxyalkanoate) synthesis.

Authors:  G N Huijberts; T C de Rijk; P de Waard; G Eggink
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  15 in total

1.  Genetic characterization of accumulation of polyhydroxyalkanoate from styrene in Pseudomonas putida CA-3.

Authors:  Niall D O'Leary; Kevin E O'Connor; Patrick Ward; Miriam Goff; Alan D W Dobson
Journal:  Appl Environ Microbiol       Date:  2005-08       Impact factor: 4.792

2.  GacS-dependent regulation of polyhydroxyalkanoate synthesis in Pseudomonas putida CA-3.

Authors:  William J Ryan; Niall D O'Leary; Mark O'Mahony; Alan D W Dobson
Journal:  Appl Environ Microbiol       Date:  2013-01-04       Impact factor: 4.792

3.  Polyphosphate accumulation by Pseudomonas putida CA-3 and other medium-chain-length polyhydroxyalkanoate-accumulating bacteria under aerobic growth conditions.

Authors:  Karen M Tobin; John W McGrath; Alan Mullan; John P Quinn; Kevin E O'Connor
Journal:  Appl Environ Microbiol       Date:  2006-12-08       Impact factor: 4.792

4.  Lessons From Insect Fungiculture: From Microbial Ecology to Plastics Degradation.

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5.  Synthesis Gas (Syngas)-Derived Medium-Chain-Length Polyhydroxyalkanoate Synthesis in Engineered Rhodospirillum rubrum.

Authors:  Daniel Heinrich; Matthias Raberg; Philipp Fricke; Shane T Kenny; Laura Morales-Gamez; Ramesh P Babu; Kevin E O'Connor; Alexander Steinbüchel
Journal:  Appl Environ Microbiol       Date:  2016-09-30       Impact factor: 4.792

6.  Computational prediction of the Crc regulon identifies genus-wide and species-specific targets of catabolite repression control in Pseudomonas bacteria.

Authors:  Patrick Browne; Matthieu Barret; Fergal O'Gara; John P Morrissey
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7.  Regulation of phenylacetic acid uptake is σ54 dependent in Pseudomonas putida CA-3.

Authors:  Niall D O' Leary; Mark M O' Mahony; Alan D W Dobson
Journal:  BMC Microbiol       Date:  2011-10-13       Impact factor: 3.605

8.  Bioconversion of styrene to poly(hydroxyalkanoate) (PHA) by the new bacterial strain Pseudomonas putida NBUS12.

Authors:  Giin-Yu Amy Tan; Chia-Lung Chen; Liya Ge; Ling Li; Swee Ngin Tan; Jing-Yuan Wang
Journal:  Microbes Environ       Date:  2015-02-14       Impact factor: 2.912

9.  A genome-scale metabolic reconstruction of Pseudomonas putida KT2440: iJN746 as a cell factory.

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10.  Pseudomonas pseudoalcaligenes CECT5344, a cyanide-degrading bacterium with by-product (polyhydroxyalkanoates) formation capacity.

Authors:  Isabel Manso Cobos; María Isabel Ibáñez García; Fernando de la Peña Moreno; Lara Paloma Sáez Melero; Víctor Manuel Luque-Almagro; Francisco Castillo Rodríguez; María Dolores Roldán Ruiz; María Auxiliadora Prieto Jiménez; Conrado Moreno Vivián
Journal:  Microb Cell Fact       Date:  2015-06-10       Impact factor: 5.328
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