AI Article Synopsis
- The study explores the use of industrial microorganisms to convert lignocellulose into valuable chemicals, which supports carbon neutrality and a sustainable bioeconomy.
- Researchers tested a specific microorganism's tolerance to high sugar concentrations, salt, and temperature variations to determine its effectiveness for fermentation in seawater.
- Results showed that the microorganism is highly adaptable, achieving a significantly improved glycerol yield when fermenting the enzymatic hydrolysate in seawater compared to using freshwater, suggesting its potential for producing bio-based chemicals efficiently.
Article Abstract
The utilization of industrial microorganisms for the conversion of lignocellulose into high value-added chemicals is an essential pathway towards achieving carbon neutrality and promoting sustainable bioeconomy. However, the pretreated lignocellulase hydrolysate often contains various sugars, salts, phenols/aldehydes and other substances, which requires microorganisms to possess strong tolerance for direct fermentation. This study aims to investigate the tolerance of to substrate, salt, and high temperature shock, in order to validate its potential for utilizing the enzymatic hydrolysate of in seawater for fermentation. The experimental results showed that the adaptively domesticated . exhibited tolerance to glucose at a concentration of 200 g/L and became a hypertonic strain. When seawater was used instead of freshwater without sterilization, the yield of glycerol in fermentation was 109% higher than that in freshwater with sterilization. Moreover, the combined thermal shock at 32 hours of fermentation and addition of 10 NaSO at 48 hours resulted in a yield of glycerol to glucose 0.37 g/g, which was 225% higher than the control group. By fermenting the enzymatic hydrolysate of . pretreated in seawater, the total conversion rate of glucose into glycerol and ethanol reached 0.45 g/g. This study indicates that hypertonic . exhibits remarkable adaptability to substrate, salt, and temperature. It not only can directly utilize complex lignocellulosic hydrolysates, but also exhibits strong tolerance to them. Therefore, it provides a potential candidate strain for the production of bio-based chemicals using lignocellulosic processes.
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| http://dx.doi.org/10.13345/j.cjb.230432 | DOI Listing |
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