1. Measurement of minimum substrate concentration (Smin) in a recycling fermentor and its prediction from the kinetic parameters of Pseudomonas strain B13 from batch and chemostat cultures
- Author
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Gosse Schraa, A.J.B. Zehnder, T.N.P. Bosma, and M.E. Tros
- Subjects
Conservation of Natural Resources ,Chromatography ,Ecology ,Strain (chemistry) ,Chemistry ,Kinetics ,Substrate (chemistry) ,Industrial fermentation ,Chemostat ,Acetates ,Biodegradation ,equipment and supplies ,Applied Microbiology and Biotechnology ,Chlorobenzoates ,Biodegradation, Environmental ,Pseudomonas ,Fermentation ,Bioreactor ,Research Article ,Food Science ,Biotechnology - Abstract
The minimum substrate concentration required for growth, Smin, was measured for Pseudomonas sp. strain B13 with 3-chlorobenzoate (3CB) and acetate in a recycling fermentor. The substrates were provided alone or in a mixture. Smin values predicted with kinetic parameters from resting-cell batches and chemostat cultures differed clearly from the values measured in the recycling fermentor. When 3CB and acetate were fed as single substrates, the measured Smin values were higher than the individual Smin values in the mixture. The Smin in the mixture reflected the relative energy contributions of the two substrates in the fermentor feed. The energy-based maintenance coefficients during zero growth in the recycling fermentor were comparable for all influent compositions (mean +/- standard deviation, 0.34 +/- 0.07 J mg [dry weight]-1 h-1). Maintenance coefficient values for acetate were significantly higher in chemostat experiments than in recycling-fermentor experiments. 3CB maintenance coefficients were comparable in both experimental systems. The parameters for 3CB consumption kinetics varied remarkably with the experimental growth conditions in batch, chemostat, and recycling-fermentor environments. The results demonstrate that the determination of kinetic parameters in the laboratory for prediction of microbial activity in complex natural systems should be done under conditions which best mimic the system under consideration.
- Published
- 1996