Showing papers by "Pauline M. Doran published in 1994"

Production of steroidal alkaloids by hairy roots of Solanum aviculare and the effect of gibberellic acid

Abstract: Cultures of Solanum aviculare hairy roots were established after transformation with Agrobacterium rhizogenes A4. High levels of steroidal alkaloids measured as solasodine equivalents were produced in shake-flasks and bioreactor, even though relatively low concentrations are found in roots in vivo. In shake flasks the maximum alkaloid yield was 32 mg g-1 dry weight; in a 3-1 air-driven bioreactor the yield was 29 mg g-1. These yields represent a 5-fold increase over previous reports for in vitro production, and are comparable with levels found in the aerial parts of intact S. aviculare plants. Production of steroidal alkaloids was growth-associated. High sugar levels at stationary phase and insensitivity to increased levels of medium components suggest that root cultures were limited by oxygen mass-transfer. In Petri-dish culture with and without exogenous gibberellic acid, root length and number of root tips increased exponentially; growth proceeded with a constant length per root tip of about 35 mm. Addition of gibberellic acid enhanced growth but reduced the specific steroidal-alkaloid level. Taking into account both growth and alkaloid yield, accumulation of steroidal alkaloids was improved by about 40% at gibberellic-acid concentrations of 10 and 100 µg l-1.

Foaming and cell flotation in suspended plant cell cultures and the effect of chemical antifoams.

Abstract: Foam development and stability in Atropa belladonna suspensions were investigated as a function of culture conditions. Foaming was due mainly to properties of the cell-free broth and was correlated with protein content; effects due to presence of cells increased towards the end of batch culture. Highest foam levels were measured 11 days after inoculation. Air flow rate was of major importance in determining foam volume; foam volume and stability were also strongly dependent on pH. Foam flotation of plant cells was very effective. After 30 min foaming, ca. 55% of cells were found in the foam; this increased to ca. 75% after 90 min. Polypropylene glycol 1025 and 2025, Pluronic PE 6100, and Antifoam-C emulsion were tested as chemical antifoams. Polypropylene glycol 1025 and Antifoam C at concentrations up to 600 ppm had no adverse effect on growth in shake flasks; Pluronic PE 6100 has an inhibitory effect at all levels tested. Concentrations of polypropylene glycol 2025 and Pluronic PE 6100 as low as 20 ppm reduced foam volumes by a factor of ca. 10. Addition of antifoam reduced k(L)a values in bubble-column and stirred-tank bioreactors. After operation of a stirred reactor for 2 days using Antifoam C for foam control, cell production was limited by oxygen due to the effect of antifoam on mass transfer. Theoretical analysis showed that maximum cell concentrations and biomass levels decline with increasing reactors working volume due to greater consumption of antifoam to prevent foam overflow. The results indicate that when chemical foam control is used in plant cell cultures, head-space volume and tolerable foam levels must be considered to optimize biomass production. (c) 1994 John Wiley & Sons, Inc.