Molecular Farming in Artemisia annua, a Promising Approach to Improve Anti-malarial Drug Production

Pulice, Giuseppe; Pelaz, Soraya; Matías‐Hernández, Luis

doi:10.3389/fpls.2016.00329

Cited by 39 publications

(37 citation statements)

References 176 publications

(231 reference statements)

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“…The results showed that AaWRKY1 increased the artemisinin content through ADS and CYP regulation (27). As far as AN molecule in Artemisia is in low concentration, it is quite expensive, and different genetic manipulation approaches are difficult to do; thus, regulation of AN genetic pathway and other biological processes is costly (28). Artemisinin and total flavonoids levels were higher in samples obtained from high land areas (western and south western region) compared to those obtained from lowland regions.…”

Section: Resultsmentioning

confidence: 99%

A Systematic Review of Anti-malarial Properties, Immunosuppressive Properties, Anti-inflammatory Properties, and Anti-cancer Properties of Artemisia Annua

Alesaeidi¹,

Miraj²

2016

Electron physician

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Artemisia annua belongs to the asteraceae family, indigenous to the mild climate of Asia. The aim of this study was to overview its anti-malarial properties, immunosuppressive properties, anti-inflammatory properties and anti-cancer properties. This systematic review was carried out by searching studies in PubMed, Medline, Web of Science, and IranMedex databases. The initial search strategy identified approximately ninety eight references. In this study, forty six studies were accepted for further screening and met all of our inclusion. The search terms were “Artemisia annua”, “therapeutic properties”, “and pharmacological effects”. Artemisia annua is commonly used for its anti-malarial, immunosuppressive anti-inflammatory properties. Artemisia annua contributes to the treatment of various diseases such as diabetes, heart diseases, arthritis and eczema and possesses various effects such as antibacterial, antioxidant, anticoccidial, and antiviral effects. Furthermore, it was said to be good for cancer treatment. In this study, anti-malarial, immunosuppressive, anti-inflammatory properties of this plant are presented using published articles in scientific sites.

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Section: Resultsmentioning

confidence: 99%

A Systematic Review of Anti-malarial Properties, Immunosuppressive Properties, Anti-inflammatory Properties, and Anti-cancer Properties of Artemisia Annua

Alesaeidi¹,

Miraj²

2016

Electron physician

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“…Artesunate (ARS) is a semi‐synthetic derivative of artemisinin, a sesquiterpene lactone compound that is naturally produced by Artemisia annua L. (Pulice, Pelaz, & Matías‐hernández, ; Zuo, Li, Liu, Feng, & Chen, ). Over the past several years, ARS has been used as an outstanding antimalarial drug, and an increasing number of further pharmacological actions have been reported (Noubiap, ).…”

Section: Introductionmentioning

confidence: 99%

Markers of oxidative‐nitrosative stress induced by artesunate are followed by clastogenic and aneugenic effects and apoptosis in human lymphocytes

Mota

Garcia

Bonfim

et al. 2019

J of Applied Toxicology

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Artesunate (ARS) is a semi‐synthetic derivative of artemisinin, used as an outstanding antimalarial drug, which also displays antitumor, anti‐inflammatory and immunosuppressive effects. In spite of the numerous reports showing the antitumor activity of ARS, the particular mechanisms associated with its cytotoxicity and genotoxicity in non‐neoplastic human cells remain unclear. Here we aimed to verify the specific chromosome damages and the changes in markers of oxidative‐nitrosative stress and apoptosis triggered by ARS exposure in human peripheral blood lymphocytes. Cultures were incubated in the presence of ARS and the number of binucleated cells was determined. To discriminate between micronuclei (MN) containing a whole chromosome or an acentric chromosome, the MN test was employed in combination with the fluorescence in situ hybridization assay. Alterations in the levels of superoxide anion (O2−) and nitric oxide (NO) were measured by the nitroblue tetrazolium and Griess assay, respectively. Changes in the expression of the apoptotic markers were assessed by immunocytochemistry. We found that ARS induced a significant formation of both centromere‐positive MN (C+ MN) and centromere‐negative MN (C– MN). These alterations were accompanied by an increase in both cellular levels of O2− and total NO production, and a remarkable enhancement in the expression of the apoptotic markers cytochrome c and caspases 8 and 9. Together these findings reveal that ARS induces changes in the oxidative‐nitrosative status of human lymphocytes, which are followed by apoptosis and clastogenic and aneugenic effects.

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“…Given the economic importance of artemisinin, the sole dependency on plant-based production periodically fails to meet the global demand due to irregular agricultural supply, which then renders fluctuations in the market and reductions in artemisinin inventory [9, 10]. To mitigate supply uncertainties and price volatility, biotechnological alternatives such as genetic modification, crop breeding and semi-synthetic production were considered with the latter far more successful [11]. The semi-synthesis approach has the production capacity to yield approximately 60 tonnes of artemisinin annually, but it also involves the trade-off between efficiency and profitability.…”

Section: Introductionmentioning

confidence: 99%

“…Naturally, artemisinin biosynthesis occurs in glandular secretory trichomes that are present on foliage, stems and inflorescences of the A. annua plant [15, 16]. Due to its compartmentalized synthesis and influence by physiological, seasonal and environmental factors, artemisinin concentration is highly variable with reported values of 0.1 – 10 mg g -1 dry weight (DW) [11, 17]. With the biosynthetic pathway of artemisinin formation fully elucidated over the past decade, it was learnt that within the species A. annua two contrasting chemotypes can be distinguished, which are characterized by the differing contents of artemisinin and its precursor (Fig 1).…”

Section: Introductionmentioning

confidence: 99%

Successes of artemisinin elicitation in low-artemisinin producing Artemisia annua cell cultures constrained by repression of biosynthetic genes

Yee

Ping

2019

Preprint

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10The sesquiterpene phytolactone derived from Artemisia annua, artemisinin is 11 associated with a variety of novel biological properties, such as immunoregulatory and 12 anticancer effects, and therapeutic applications, apart from its main function as an 13 4 57 Naturally, artemisinin biosynthesis occurs in glandular secretory trichomes that are 58 present on foliage, stems and inflorescences of the A. annua plant [15, 16]. Due to its 59 compartmentalized synthesis and influence by physiological, seasonal and environmental 60 factors, artemisinin concentration is highly variable with reported values of 0.1 -10 mg g -1 61 dry weight (DW) [11, 17]. With the biosynthetic pathway of artemisinin formation fully 62 elucidated over the past decade, it was learnt that within the species A. annua two contrasting 63 chemotypes can be distinguished, which are characterized by the differing contents of 64 artemisinin and its precursor (Fig 1). While both possess artemisinin, the high-artemisinin 65 producing (HAP) chemotype contains relatively higher levels of dihydroartemisinic acid 66 (DHAA) and artemisinin, and the low-artemisinin producing (LAP) chemotype has higher 67 contents of artemisinic acid and arteannuin B (a non-antimalarial product) [18, 19]. Despite 68 the difference in biochemical phenotype which is attributed to the differential expression of 69 one artemisinin biosynthesis specific gene artemisinic aldehyde Δ11(13) reductase (DBR2), 70 both chemotypes undergo similar spontaneous photooxidation reactions to produce 71 artemisinin or arteannuin B from its direct precursors [20-23]. 72 Fig 1. Schematic representation of artemisinin biosynthesis. 73 Synthesis occurs in the glandular trichome secretory cells of A. annua and sequestration of 74 artemisinin takes place in the subcuticular space. The two branching pathways leading to 75 artemisinin and arteannuin B of the artemisinin biosynthetic pathway (dashed line box) are 76 depicted and the final non-enzymatic photo-oxidation reaction is shown in red. MEP, 77 methylerythritol 4-phosphate; MVA, mevalonate; GST, glandular secretory trichome; ADS, 78 amorpha-4,11-diene synthase; CYP71AV1, cytochrome P450 monooxygenase; DBR2, 79 artemisinic aldehyde Δ11(13) reductase; ALDH1, aldehyde dehydrogenase 1. 80 As a secondary metabolite used mainly in defence mechanisms, production of 81 artemisinin would naturally be induced and enhanced under environmental stresses. Under 5 82 such adverse conditions the elevation of secondary oxidative stress, which is a consequence 83 of primary biotic/abiotic stress, is in a direct synergistic relationship with artemisinin 84 production [24-27]. On such basis, the biotechnological method elicitation which mimics the 85 natural induction of plant stress is the method of choice to enhance the production of 86 artemisinin. The positive effects of UV-B and DMSO on the production of artemisinin had 87 been verified by previous studies on A. annua seedlings [28, 29], in vitro propagated plantlets 88 [30] and shoot cultures [31]. Former st...

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Molecular Farming in Artemisia annua, a Promising Approach to Improve Anti-malarial Drug Production

Cited by 39 publications

References 176 publications

A Systematic Review of Anti-malarial Properties, Immunosuppressive Properties, Anti-inflammatory Properties, and Anti-cancer Properties of Artemisia Annua

A Systematic Review of Anti-malarial Properties, Immunosuppressive Properties, Anti-inflammatory Properties, and Anti-cancer Properties of Artemisia Annua

Markers of oxidative‐nitrosative stress induced by artesunate are followed by clastogenic and aneugenic effects and apoptosis in human lymphocytes

Successes of artemisinin elicitation in low-artemisinin producing Artemisia annua cell cultures constrained by repression of biosynthetic genes

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