Camptotheca acuminata plants contain camptothecin which is a secondary metabolite with strong anti-tumor activity. The induction of callus and cell suspension cultures from Camptotheca acuminata stem parts on different media is described. Growth in the original media and in media with different salts and/or vitamins was followed by measuring several growth parameters. Camptothecin was detected and identified by means of TLC, HPLC and GC-MS. The production of camptothecin in cell suspension cultures was followed and compared to the original plant material. Results indicate that high density cultures could be easily established, producing ca I mg 1-1 of camptothecin.
Alginate-entrapped cells of Mucuna pruriens L. hydroxylate L-tyrosine, tyramine, para-hydroxyphenylpropionic acid, and para-hydroxyphenylacetic acid to their corresponding catechols, which were released into the incubation medium. Michaëlis-Menten kinetics was applied for each bioconversion. The apparent affinity constants were comparable with the affinity constants obtained with a homogenate directly prepared from the cells used for entrapment and with a derived partly purified phenoloxidase. The values found for the apparent maximum rates of bioconversion of the entrapped cells were ca. 50% of the values of the maximum rates of bioconversion of the cell homogenate, indicating that the entrapped cell system was not operating optimally. The effective diffusivities of the substrates and products were measured with alginate-entrapped, inactivated cells. From the five inactivation methods tested, glutaric aldehyde treatment was chosen as the general procedure. Calculated effective diffusivities for the monophenols and catechols demonstrated that these compounds could diffuse freely into and out of the beads. For each bioconversion, the observable modulus was calculated from the initial rate of bioconversion and the effective diffusivity of the substrate. The resulting values indicated that the diffusional supply rate of the substrates was not the limiting factor, except for the conversion of tyramine for which a modulus higher than one was obtained. Analogously, the observable moduli were calculated for oxygen, which was utilized for bioconversion and cell respiration, and these values pointed towards strong oxygen limitation in all cases. The bioconversion rates of the entrapped cells increased with decreasing cell aggregate size. Therefore, it was concluded that direct cell-matrix contact determined the amount of phenoloxidase involved in the bioconversions. The bioconversion rate on a protein basis was constant with enhancement of the bead charge and thus, in spite of limitations, the mixing conditions as such were relatively optimal. In conclusion, the nonoptimal efficiency of the plant cell system studied was caused by oxygen limitation and a partial phenoloxidase participation, but not by mass transfer limitations for substrates and products with the exception of the conversion of tyramine into dopamine.
Plant cells of Mucuna pruriens L. entrapped In calcium alginate, calcium pectinate, agarose, or gelatine were able to convert L-tyrosine to L-DOPA, which was released Into the medium. Michaelis-Menten kinetics could be applied on the entrapped cells, based on the measurement of initial rates of L-DOPA production. The calculated apparent affinity constants were comparable with the affinity constants obtained with enzyme preparations. Comparison of the apparent maximum rate of bioconversion of the entrapped cells and the maximum rate of bioconversion of a derived cell homogenate indicated that the systems were not operating optimally. Measurement of the effective diffusion coefficients of L-tyrosine pointed out that this substrate could diffuse freely into the matrices. From the initial rates of bioconversion and the effective diffusion coefficients, the observable modulus was calculated for each system. The obtained values confirmed that the diffusional supply rate of L-tyrosine was not the limiting factor. For oxygen, which was utilized for byconversion as well as for cell respiration, the calculated observable moduli was directed toward strong oxygen transfer limitations. The values found for the oxygen consumption indicated that the entrapped cells remained partly or totally viable in the four matrices tested. Based on the highest viability and the highest rates of bioconversion, it was concluded that alginate-entrapped cells of M. pruriens formed the most suitable biocatalytic system for the production of L-DOPA from L-tyrosinre.
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