Physiological and Metabolic Modifications in Response to Nanocarbon in Callus of Indica Rice Cultivar

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Published: Oct 2, 2019
Keywords:
callus; growth; metabolite; nanocarbon; rice

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Thanawat Sutjaritvorakul
Faculty of Science and Technology, Pathumwan Institute of Technology, Bangkok, Thailand
Sutee Chutipaijit*
College of Nanotechnology, King Mongkut’s Institute of Technology Ladkrabang, Bangkok, Thailand

Abstract

Nanocarbon has been shown to be implicated in the response of plants to an assortment of positive or negative impacts. In the present research, the effects of nanocarbon on cell growth and secondary metabolite production on rice callus were studied. Different concentrations of nanocarbon (0-1000 mg l−1) were added into callus induction media to investigate the effects on the growth of callus, and secondary metabolite production in indica rice callus (Oryza sativa L. cv. Pathumthani1). The growth of callus was measured in terms of the size and weight of callus, and secondary metabolite production was determined based on the levels of total phenolic compounds and flavonoid production. The results showed that the callus induction, the callus growth and the secondary metabolite production in rice callus after treatment with nanocarbon were significantly different when compared to control (without treatment with nanocarbon). The rice callus treated with low (100 and 200 mg l-1) and moderate (400 and 600 mg l-1) level of nanocarbon displayed an enhancement in callus growth, total phenolic compounds and flavonoid production. However, the induction of callus, cell growth, and secondary metabolite production were decreased when rice callus was treated with high concentrations of nanocarbon (800 and 1000 mg l-1). The results of this research showed that the nanocarbon application of 400-600 mg l-1 had potential to induce the cell growth and secondary metabolite production. This research suggests further investigation in using different concentrations of nanocarbon on other plant species for potential pharmaceutical application.
Keywords: callus; growth; metabolite; nanocarbon; rice

*Corresponding author: Tel.: +668-6667-7036 Fax: +662-329-8265


                                           E-mail: [email protected]

Article Details

Issue
Vol. 20 No. 1 (2020)
Section
Original Research Articles

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