Effect of exogenous electron shuttles on growth and fermentative metabolism in Clostridium sp. BC1.

In this study, the influence exogenous electron shuttles on the growth and glucose fermentative metabolism of Clostridium sp. BC1 was investigated. Bicarbonate addition to mineral salts (MS) medium accelerated growth and glucose fermentation which shifted acidogenesis (acetic- and butyric-acids) towards solventogenesis (ethanol and butanol). Addition of ferrihydrite, anthraquinone disulfonate, and nicotinamide adenine dinucleotide in bicarbonate to growing culture showed no significant influence on fermentative metabolism. In contrast, methyl viologen (MV) enhanced ethanol- and butanol-production by 28- and 12-fold, respectively with concomitant decrease in hydrogen, acetic- and butyric-acids compared to MS medium. The results show that MV addition affects hydrogenase activity with a significant reduction in hydrogen production and a shift in the direction of electron flow towards enhanced production of ethanol and butanol.

Rapid establishment of p-nitrophenol biodegradation in acetate-fed aerobic granular sludge.

The aim of the study was to investigate the acclimation of precultivated acetate-fed aerobic granular sludge to a toxic xenobiotic biodegradation. Establishment of p-nitrophenol (PNP) biodegradation in acetate-fed aerobic granular sludge and concomitant changes in the microstructure and bacterial community were determined. Rapid establishment of PNP utilization was observed in the granular sludge when fed with PNP as the sole carbon source. The specific PNP removal was 36-mg h(-1) g(-1) granular biomass at an initial PNP concentration of 50 mg L(-1). The presence of PNP resulted in significant membrane damage in a subpopulation of the bacterial consortium, as shown by BacLight viability staining. This was coincided with a significant decrease in the culturable bacterial diversity of the granular biomass. PCR-DGGE analysis revealed a shift and decrease in number of bands during the establishment of PNP biodegradation. Scanning electron microscopy showed the dominance of rod-shaped bacteria in the PNP-utilizing microbial granules. Our results suggest that acetate-fed granular sludge could be quickly adapted for PNP biodegradation.