A model for Arabidopsis thaliana cell suspension growth and sugar uptake kinetics

Arabidopsis thaliana (A. thaliana) is a small weed which is related to the cabbage and mustard family. This flowering plant has been used widely as a model plant in genetics and molecular biology research since it is the first plant the full sequenced genome. Thus, A. thaliana literature provides pl...

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Bibliographic Details
Main Authors: Mohamad Puad, Noor Illi, Abd-Karim, Khairiah, Mavituna, Ferda
Format: Article
Language:English
English
Published: Penerbit UTM Pres 2017
Subjects:
Online Access:http://irep.iium.edu.my/57696/1/Published%20Manuscript.pdf
http://irep.iium.edu.my/57696/7/57696_A%20model%20for%20Arabidopsis%20thaliana%20cell_SCOPUS.pdf
http://irep.iium.edu.my/57696/
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Summary:Arabidopsis thaliana (A. thaliana) is a small weed which is related to the cabbage and mustard family. This flowering plant has been used widely as a model plant in genetics and molecular biology research since it is the first plant the full sequenced genome. Thus, A. thaliana literature provides plentiful information from genomics and transcriptomics point of view. However, there is still a lack of physiological information regarding its cell suspension cultures which can be powerful research tools in Plant Biotechnology and especially in Plant Systems and Synthetic Biology. In this study, cell growth and sugar uptake of A. thaliana Col ecotype grown in the continuous dark condition were modelled using the modified Monod and Michelis-menten equations. The model included sucrose hydrolysis by the cell-wall invertase enzyme into hexoses (glucose and fructose) and consumption of these hexoses at different rates to support cell growth. All kinetic model parameters were obtained from a control experiment where Col cells were grown on 30 gL-1 sucrose as well as other independent experiments where Col cells were supplied with different concentrations and combinations of sugars. The model adequately described and predicted the growth and sugars profile of A. thaliana cells. This model can also be applied for larger scale of growth with extended expressions for oxygen uptake rate, carbon dioxide production rate etc.