Abstract
Paraburkholderia sp. SOS3 is a plant growth-promoting bacterium (PGPB) that displays pleiotropic effects and has the potential to be applied at a large scale across several agronomically important crops. The use of SOS3 is a suitable option to reduce the use of chemical fertilisers. While the benefits of SOS3 have been demonstrated in vitro, its potential applications at large scale are limited due to low biomass yield in current batch culture systems. Here, we developed a strategy for high-cell density cultivation of SOS3 in instrumented bioreactors, moving from low-biomass yield in a complex medium to high-biomass yield in a semi-defined medium. We achieved a 40-fold increase in biomass production, achieving cell densities of up to 11 g/L (OD600 = 40). This result was achieved when SOS3 was cultivated using a fed-batch strategy. Biomass productivity, initially 0.02 g/L/h in batch cultures, was improved 12-fold, reaching 0.24 g/L/h during fed-batch cultures. The biomass yield was also improved 10-fold from 0.07 to 0.71 gbiomass/gsolids. Analysis of the fermentation profile of SOS3 indicated minimal production of by-products and accumulation of polyhydroxybutyrate (PHB) during the exponential growth phase associated with nitrogen limitation in the medium. By implementing proteomics analysis in fed-batch cultures, we identified the expression of four metabolic pathways associated with growth-promoting effects, which may be used as a qualitative parameter to guarantee the efficacy of SOS3 when used as a bioinoculant. Ultimately, we confirmed that the high-cell density cultures maintained their plant growth-promoting capacity when tested in sorghum and maize under glasshouse conditions.
Highlights
The agriculture sector faces significant new challenges associated with climate change, resistance to biopesticides and soil degradation
SOS3 was cultivated in the nutrient broth medium [13]
We evaluated the growth of SOS3 in mannitol minimal salts medium (MMS), a semi-defined medium containing 0.1% yeast extract
Summary
The agriculture sector faces significant new challenges associated with climate change, resistance to biopesticides and soil degradation. An emerging solution towards sustainable agricultural practices is the use of cost-effective, environmentally friendly biofertilisers. Biofertilisers are a suitable alternative to chemical fertilisers and exploit native microorganisms present in the soil, known as plant growth-promoting bacteria (PGPB). Such products are termed ‘bioinoculants’, as they induce rhizospheric colonisation with the target bacterium rather than merely supplying nutrients to the soil as chemical fertilisers do. The use of PGPB in sustainable agriculture has gained importance in the past decade due to their beneficial effects on soil and crop productivity. PGPB exhibit different mechanisms of action in their interactions with plants, leading to improved productivity through
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