A Nitrate-Blind P. putida Strain Boosts PHA Production in a Synthetic Mixed Culture

One of the major challenges for the present and future generations is to find suitable substitutes for the fossil resources we rely on today. In this context, cyanobacterial carbohydrates have been discussed as an emerging renewable feedstock in industrial biotechnology for the production of fuels a...

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Bibliographic Details
Published in:Frontiers in bioengineering and biotechnology 2020-05, Vol.8, p.486-486
Main Authors: Hobmeier, Karina, Löwe, Hannes, Liefeldt, Stephan, Kremling, Andreas, Pflüger-Grau, Katharina
Format: Article
Language:English
Subjects:
artificial nitrogen limitation
Bioengineering and Biotechnology
co-cultivation
genetic engineering
polyhydroxyalkanoates
Pseudomonas putida
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Summary:One of the major challenges for the present and future generations is to find suitable substitutes for the fossil resources we rely on today. In this context, cyanobacterial carbohydrates have been discussed as an emerging renewable feedstock in industrial biotechnology for the production of fuels and chemicals. Based on this, we recently presented a synthetic bacterial co-culture for the production of medium-chain-length polyhydroxyalkanoates (PHAs) from CO 2 . This co-cultivation system is composed of two partner strains: Synechococcus elongatus cscB which fixes CO 2 , converts it to sucrose and exports it into the culture supernatant, and a Pseudomonas putida strain that metabolizes this sugar and accumulates PHAs in the cytoplasm. However, these biopolymers are preferably accumulated under conditions of nitrogen limitation, a situation difficult to achieve in a co-culture as the other partner, at best, should not perceive any limitation. In this article, we will present an approach to overcome this dilemma by uncoupling the PHA production from the presence of nitrate in the medium. This is achieved by the construction of a P. putida strain that is no longer able to grow with nitrate as nitrogen source -is thus nitrate blind, and able to grow with sucrose as carbon source. The deletion of the nasT gene encoding the response regulator of the NasS/NasT two-component system resulted in such a strain that has lost the ability use nitrate, but growth with ammonium was not affected. Subsequently, the nasT deletion was implemented in P. putida cscRABY , an efficient sucrose consuming strain. This genetic engineering approach introduced an artificial unilateral nitrogen limitation in the co-cultivation process, and the amount of PHA produced from light and CO 2 was 8.8 fold increased to 14.8% of its CDW compared to the nitrate consuming reference strain. This nitrate blind strain, P. putida Δ nasT attTn7:cscRABY , is not only a valuable partner in the co-cultivation but additionally enables the use of other nitrate containing substrates for medium-chain-length PHA production, like for example waste-water.
ISSN:2296-4185
2296-4185
DOI:10.3389/fbioe.2020.00486