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Biosystems and Integrative Sciences Institute
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The use of chitosan oligosaccharide to improve artemisinin yield in well-watered and drought-stressed plants
Publication . García-García, Ana L.; Matos, Ana Rita; Feijão, Eduardo; Carvalho, Ricardo Cruz de; Boto, Alicia; Silva, Jorge Marques da; Jiménez-Arias, David
Introduction: Artemisinin is a secondary metabolite well-known for its use in the
treatment of malaria. It also displays other antimicrobial activities which further
increase its interest. At present, Artemisia annua is the sole commercial source of
the substance, and its production is limited, leading to a global deficit in supply.
Furthermore, the cultivation of A. annua is being threatened by climate change.
Specifically, drought stress is a major concern for plant development and
productivity, but, on the other hand, moderate stress levels can elicit the
production of secondary metabolites, with a putative synergistic interaction
with elicitors such as chitosan oligosaccharides (COS). Therefore, the
development of strategies to increase yield has prompted much interest. With
this aim, the effects on artemisinin production under drought stress and
treatment with COS, as well as physiological changes in A. annua plants are
presented in this study.
Methods: Plants were separated into two groups, well-watered (WW) and
drought-stressed (DS) plants, and in each group, four concentrations of COS
were applied (0, 50,100 and 200 mg•L-1). Afterwards, water stress was imposed
by withholding irrigation for 9 days.
Results: Therefore, when A. annua was well watered, COS did not improve plant
growth, and the upregulation of antioxidant enzymes hindered the production of
artemisinin. On the other hand, during drought stress, COS treatment did not
alleviate the decline in growth at any concentration tested. However, higher
doses improved the water status since leaf water potential (YL) improved by
50.64% and relative water content (RWC) by 33.84% compared to DS plants
without COS treatment. Moreover, the combination of COS and drought stress caused damage to the plant’s antioxidant enzyme defence, particularly APX and
GR, and reduced the amount of phenols and flavonoids. This resulted in
increased ROS production and enhanced artemisinin content by 34.40% in DS
plants treated with 200 mg•L-1 COS, compared to control plants.
Conclusion: These findings underscore the critical role of ROS in artemisinin
biosynthesis and suggest that COS treatment may boost artemisinin yield in crop
production, even under drought conditions.
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Funding agency
Fundação para a Ciência e a Tecnologia
Funding programme
6817 - DCRRNI ID
Funding Award Number
UIDB/04046/2020