Strictosidine Synthase Coding Gene Expression towards Quinine Biosynthesis and Accumulation: Inconsistency in Cultured Cells and Fresh Tissues of Cinchona ledgeriana

Q2 Agricultural and Biological Sciences
D. Ratnadewi, M. H. Fendiyanto, R. Satrio, M. Miftahudin, A. N. Laily
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引用次数: 3

Abstract

Strictosidine synthase, encoded by the gene STR, facilitates the regeneration of strictosidine, a critical intermediate for the synthesis of many plant alkaloids. The gene has, however, never been studied in Cinchona spp. The plants produce quinine alkaloid used for malaria medication, SARS-CoV-2 treatment and other industrial purposes. Cultured cells can produce the alkaloid but only at a much lower yield than the natural tree. This study describes STR expression and quinine content in various plant materials. Bioinformatic analyses were conducted on nine species of Rubiaceae to obtain reference sequences to design conservative primers for Cinchona ledgeriana STR (ClSTR). ClSTR expression was analyzed using qRT-PCR and quinine content was determined using HPLC. A complete coding sequence (CDS) of ClSTR was deposited in NCBI GenBank under the accession number MK422544.1. ClSTR was expressed in cultured cells, young and mature leaves, and stem bark. The elicited cells have higher expression than the control and they performed since the fourth week. However, the quinine content was greater in older cells. The gene expression in young leaves was superior, but quinine was most abundant in the stem bark. Every cell of C. ledgeriana, in culture or in the plant, expressed ClSTR and was capable of synthesizing the alkaloid quinine. The alkaloid from the leaves of the plant might be translocated and accumulated in the bark. No efflux of alkaloids from the confined cultured cells might contribute in triggering feedback inhibition in the biosynthetic pathway. This study revealed a critical obstacle in cell culture as a means of secondary metabolites production that needs further development of metabolic engineering. © 2021 Friends Science Publishers
Quinine生物合成和积累的Strictosidine合成酶编码基因表达:在金鸡纳培养细胞和新鲜组织中的不一致性
由STR基因编码的Strictosidine合成酶促进Strictosiding的再生,Strictosidine是合成许多植物生物碱的关键中间体。然而,该基因从未在金鸡纳属植物中进行过研究。这些植物产生奎宁生物碱,用于疟疾药物、严重急性呼吸系统综合征冠状病毒2型治疗和其他工业用途。培养的细胞可以产生生物碱,但产量远低于天然树。本研究描述了STR在各种植物材料中的表达和奎宁含量。对9种茜草科植物进行了生物信息学分析,以获得参考序列,设计了一个用于分类的Cinchona ledgeriana STR(ClSTR)保守引物。使用qRT-PCR分析ClSTR的表达,并使用HPLC测定奎宁的含量。ClSTR的完整编码序列(CDS)以登录号MK422544.1保藏在NCBI GenBank中。ClSTR在培养细胞、幼叶和成熟叶以及茎皮中表达。引发的细胞比对照具有更高的表达,并且它们从第四周开始表现。然而,在老年细胞中奎宁的含量更高。幼叶中的基因表达较高,但奎宁在茎皮中含量最高。在培养基或植物中,C.ledgeriana的每个细胞都表达ClSTR,并能够合成生物碱奎宁。植物叶子中的生物碱可能在树皮中转移和积累。生物碱从限制培养的细胞中没有流出可能有助于触发生物合成途径中的反馈抑制。这项研究揭示了细胞培养作为次级代谢产物产生手段的一个关键障碍,需要进一步发展代谢工程。©2021 Friends Science出版社
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来源期刊
International Journal of Agriculture and Biology
International Journal of Agriculture and Biology AGRICULTURE, MULTIDISCIPLINARY-
CiteScore
1.70
自引率
0.00%
发文量
40
审稿时长
5 months
期刊介绍: Information not localized
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