Biomass production of carbohydrate-rich filamentous microalgae coupled with treatment and nutrients recovery from acrylonitrile butadiene styrene based wastewater: Synergistic enhancement with low carbon dioxide supply strategy.

This study attempted to remove acrylonitrile and acetophenone from simulated acrylonitrile butadiene styrene (ABS) based wastewater while recovering nitrogen and phosphorus using the carbohydrate-rich filamentous microalgae Tribonema sp.. Results showed that typical acetophenone and acrylonitrile presented significant inhibitory effect on Tribonema sp. growth and co-metabolism of CO2 improved the tolerance of Tribonema sp. to toxic pollutants. The microalgae biomass increased by 34.47% (3.16 g/L) and 58.17% (3.97 g/L) via supplementing 2% CO2 in the 100 mg/L acrylonitrile and acetophenone groups, respectively. The filamentous microalga was rich in carbohydrates and its productivity was further enhanced by 32.52% and 70.34%, respectively, in 100 mg/L acrylonitrile and acetophenone groups with 2% CO2 supplement. The synergistic CO2 supply strategy effectively enhanced the biomass production of filamentous microalgae, and moreover, improved the treatment efficiency of ABS based wastewater simulated by acetophenone or acrylonitrile addition, while at same time enhanced the recovery of nitrogen and phosphorus nutrients.

ARTP mutation and adaptive laboratory evolution improve probiotic performance of Bacillus coagulans.

Bacillus coagulans is a thermophilic, facultative anaerobic, spore-forming Gram-positive bacterium, which is used as a probiotic in animal feed and human dietary supplements. In the present study, a bile-resistant thermophilic B. coagulans WT-03 strain was isolated and genetically identified. Atmospheric pressure room temperature plasma (ARTP)-induced mutation combined with adaptive laboratory evolution (ALE) was used to improve the probiotic performance of B. coagulans WT-03. After 15 s of ARTP mutation and 40 days of ALE culture, a mutant artp-aleBC15 was obtained and showed the improved tolerance to pH 2.5 and 0.3% bile salt with a survival rate of 22.4%. Further studies showed that the artp-aleBC15 mutant exhibited a relatively stable morphology, lower permeability, and higher hydrophobicity of cell membrane compared with the parent strain of B. coagulans. Additionally, artp-aleBC15 could maintain homeostasis with an intracellular pH of over 4.5 and had the altered contents of saturated fatty acids/unsaturated fatty acids in the cell membrane at pH 2.5. Our study proved that ARTP mutation combined with ALE is an efficient mutagenesis strategy to improve the probiotic performance of B. coagulans for potential industrial use.Key Points• A B. coagulans strain that can grow at 80 °C and 0.3% bile salt was screened.• ARTP combined with ALE effectively mutated B. coagulans WT-03.• B. coagulans artp-aleBC15 mutant showed an improved probiotic performance.• The mutant exhibited the lower permeability and altered fatty acid contents in the cell membrane.

Effects of twenty standard amino acids on biochemical constituents, docosahexaenoic acid production and metabolic activity changes of Crypthecodinium cohnii.

The influence of 20 standard amino acids was investigated on growth, lipid accumulation, docosahexaenoic acid (DHA) production and cell biochemical composition of Crypthecodinium cohnii. C. cohnii efficiently utilize organic nitrogen (predominantly threonine and to a lesser extent tyrosine and serine) as compared to inorganic nitrogen (NH4)2SO4. However, No significant effect was observed on major biochemical composition of C. cohnii (lipids, carbohydrates and proteins) under N limitation or supplementation with different N-sources. Key lipogenic enzymes glucose-6-phosphate dehydrogenase, ATP-citrate lyase, fatty acid synthase, malic enzyme, citrate synthase (CS), NAD+ and NADP+ dependent isocitrate dehydrogenase were shown to be vital in lipogenesis of C. cohnii. Our results indicated that the process of lipid accumulation in C. cohnii is growth-associated and does not depend upon the trigger of nitrogen depletion. This unusual behavior would suggest that the metabolism of the cells may not be entirely the same as in other lipid-accumulating microorganisms.