Jasmonic acid-induced hypericin production in cell suspension cultures of Hypericum perforatum L. (St. John's wort)

Hypericum perforatum L. (St. John's wort) is an herbal remedy widely used in the treatment of mild to moderate depression. Hypericin, a photosensitive napthodianthrone, is believed to be the compound responsible for reversing the depression symptoms. In this study, novel in vitro cell culture systems of H. perforatum were used to monitor the effect of elicitation on cell growth and production of hypericin. A dramatic increase in cell growth and hypericin production was observed after exposure to jasmonic acid (JA). However, other elicitors such as salicylic acid (SA) and fungal cell wall elicitors failed to show any stimulatory effect on either cell growth or hypericin production. Cell cultures treated with JA and incubated in the dark showed increased growth and hypericin production as compared to the cultures grown under light conditions. Jasmonate induction in dark conditions played an important role in growth and hypericin production in cell suspension cultures, to our knowledge an undocumented observation.     

Stress-induced expression and structure of the putative gene hyp-1 for hypericin biosynthesis

The phenolic oxidative coupling protein (Hyp-1) with proposed activity in the biosynthesis of hypericin in Hypericum perforatum shares about 50 % sequence similarity with Bet.v.1-like/PR-10 proteins. In our previous study, we showed that this protein is not a limiting factor in hypericin biosynthesis. To ascertain the role of Hyp-1 in defense mechanisms, we have analyzed some structural features of the hyp-1 gene in 14 Hypericum species with different abilities to synthesise hypericin. We show that the hyp-1 gene possesses characteristics typical for genes encoding plant PR-10 proteins. The coding sequence of the hyp-1 gene is interrupted by a single 86- to 125-bp intron localised strictly in codon 62, which is a typical feature of the dicot PR-10 subfamily. The localisation of the intron is conserved in all 14 tested Hypericum species indicating a common evolutionary history with genes encoding PR-10 proteins. In addition, we report that the hyp-1 gene exhibits a similar response to stress conditions as the PR-10 proteins encoding genes. Following either wounding or infection by Agrobacterium tumefaciens, all analysed Hypericum species exhibited rapid and significant upregulation of hyp-1 gene expression; this was particularly observed in hypericin-producing species. On the other hand, in the presence of high levels of abscisic acid, different levels of gene expression were observed.     

Factors affecting growth of cell suspension cultures of hypericum perforatum L. (St. John's wort) and production of hypericin

Summary Use of Hypericum perforatum L., commonly known as St. John's wort, has increased recently due to the pharmaceutical potential of hypericin, found in its leaves. Hypericin has been reported to effect a natural treatment for mild and moderate depression by increasing the concentration of neurotransmitters in the central nervous system. We have developed a novel cell culture system for in vitro growth and production of this species, suggesting a possible technology for large-scale production of hypericin. Leaf explants grown in Murashige and Skoog salts supplemented with 2,4-dichlorophenoxyacetic acid (0.90 μM) and kinetin (0.11 μM) gave maximum percentage callus formation compared to other medium treatments evaluated. Hypericin localization in cell phase and leaves was found to vary, with cell phase accumulating hypericin in special organelles and leaves accumulating it in vacuoles. Light and dark conditions, with cell aggregate size, played important roles in growth and hypericin production in cell suspension cultures.     

Crystal structure of Hyp-1, a St. John’s wort protein implicated in the biosynthesis of hypericin

Hypericin, a red-colored naphtodianthrone, is a natural product synthesized in the medicinal plant Hypericum perforatum, widely known as St. John’s wort. Hypericin has been attracting a growing attention of the pharmaceutical industry because of its potential application in various therapies, including the treatment of depression. In vivo, hypericin is synthesized by dimerization of emodin in a complicated multistep reaction that is reportedly catalyzed by a small (17.8 kDa) protein, Hyp-1. Based on relatively low sequence similarity (～50%), Hyp-1 has been tentatively classified as a plant PR-10 (pathogenesis-related class 10) protein. Members of the PR-10 family are ubiquitous plant proteins associated with stress control and tissue differentiation but with no clearly understood molecular mechanism. They have, however, a well-defined folding canon, consisting of an extended antiparallel β-sheet wrapped around a C-terminal α-helix, enclosing in the protein interior a huge cavity, in which various hydrophobic ligands can be bound. Apart from Hyp-1, only two other PR-10 members have been found to possess enzymatic activity (S-norcoclaurine synthase and TcmN aromatase/cyclase). In this paper, we report a high-resolution crystal structure of Hyp-1, confirming that it indeed has a PR-10 fold. The protein binds multiple polyethylene glycol molecules, some of which occupy the hydrophobic cavity. The crystallographic model illustrates a high degree of conformational adaptability of both interacting partners for efficient binding. We have been unable, however, to dimerize emodin to hypericin using Hyp-1 as biocatalyst. This puzzling result does not have a clear explanation at this time.     

The influence of some elicitors on growth and morphogenesis of Hypericum perforatum callus cultures

We studied the effects of elicitors, such as mannan, beta-1,3-glucan, ancymidol, and cork crumbs, on morphogenetic and biosynthetic potencies of shoot cultures of Hypericum perforatum L. In the presence of these elicitors, different morphogenetic structures of H. perforatum callus cultures were formed. A correlation was found between the morphogenetic processes and induction of hypericin and pseudohypericin biosynthesis in the callus cultures.     

NO对金丝桃悬浮细胞生长及金丝桃素生物合成的促进作用研究

一氧化氮 (NO)是近年来发现的一种新型植物信号分子。以硝普钠 (Sodiumnitroprusside ,SNP)为一氧化氮 (NO)的供体 ,研究外源NO对金丝桃悬浮细胞生长及金丝桃素生物合成的影响。试验结果表明 ,金丝桃悬浮细胞在含 0 5和 15 0mmol LSNP的培养基中培养 2 0d后 ,细胞的干重分别为对照组的 140%和50% ;细胞中金丝桃素的含量分别为对照组的 98%和210%。试验结果表明 ,低浓度SNP处理有利于金丝桃悬浮细胞生长 ,而高浓度SNP可以促进金丝桃素的合成。在细胞培养初期 (0d)加入 0.5mmol LSNP并在指数生长后期 (14d)加入15.0mmol LSNP的金丝桃悬浮细胞在培养 2.5d后 ,细胞的干重和金丝桃素的含量分别为对照组的1.4和1.8倍 ,金丝桃素的产量达15.2mg/L ,比对照高3.2倍。SNP对金丝桃悬浮细胞生长及金丝桃素含量的影响可以被NO专一性淬灭剂CPITO(2-4-carboxyphenyl-4 ,4 ,5 ,5-tetramethylimidazoline-1-oxyl-3-oxide)所抑制,说明SNP是通过其分解产物NO影响细胞生长和金丝桃素的合成。试验结果同时表明,在15.0mmol/L的SNP处理下,金丝桃悬浮细胞中的苯丙氨酸解氨酶(PAL)的活性显著升高,推测NO可能通过触发金丝桃悬浮细胞的防卫反应,激活了细胞中金丝桃素的生物合成途径。     

Nitric oxide mediates the fungal elicitor-induced hypericin production of Hypericum perforatum cell suspension cultures through a jasmonic-acid-dependent signal pathway

Fungal elicitor prepared from the cell walls of Aspergillum niger induces multiple responses of Hypericum perforatum cells, including nitric oxide (NO) generation, jasmonic acid (JA) biosynthesis, and hypericin production. To determine the role of NO and JA in elicitor-induced hypericin production, we study the effects of NO scavenger 2- to 4-carboxyphenyl-4,4, 5,5-tetramethylimidazoline-1-oxyl-3-oxide (cPITO), nitric oxide synthase inhibitor S,S'-1,3-phenylene-bis(1,2-ethanediyl)-bis-isothiourea, and inhibitors of the octadecanoid pathway on elicitor-induced NO generation, JA biosynthesis, and hypericin production. Pretreatment of the cells with cPITO and JA biosynthesis inhibitors suppresses not only the elicitor-induced NO generation and JA accumulation but also the elicitor-induced hypericin production, which suggests that both NO and JA are involved in elicitor-induced hypericin biosynthesis. S,S'-1,3-phenylene-bis(1,2-ethanediyl)-bis-isothiourea and cPITO inhibit both elicitor-induced NO generation and JA biosynthesis, while JA biosynthesis inhibitors do not affect the elicitor-induced NO generation, indicating that JA acts downstream of NO generation and that its biosynthesis is regulated by NO. External application of NO via its donor sodium nitroprusside induces hypericin production in the absence of fungal elicitor. Sodium-nitroprusside-induced hypericin production is blocked by JA biosynthesis inhibitors, showing that JA biosynthesis is essential for NO-induced hypericin production. The results demonstrate a causal relationship between elicitor-induced NO generation, JA biosynthesis, and hypericin production in H. perforatum cells and indicate a sequence of signaling events from NO to hypericin production, within which NO mediates the elicitor-induced hypericin biosynthesis at least partially via a JA-dependent signaling pathway.     

贯叶连翘野生转家化前后生物学性状特征观察

野生贯叶连翘 (HypericumperforatumL .)在江苏经过了 3a的引种栽培 ,其生物学特性检测结果表明 ,栽培贯叶连翘的生物量、开花的一致性和生长的适应性等明显优于野生贯叶连翘 ;良好的繁殖方式使贯叶连翘的收获期提前了 1a ;成熟后 3个月采收的种子萌发率较高 ,不同浓度赤霉素处理能明显提高其种子的萌发率 ;贯叶连翘的黑色腺体即分泌细胞球数量与金丝桃素间也基本存在着正相关关系 ,贵州贵阳居群和陕西丹凤居群黑色腺体明显多于其他居群 ,其金丝桃素含量在所有居群中为最高 ,而甘肃武都居群黑色腺体最少 ,其金丝桃素含量在 6个居群中最低。 6个野生居群栽培后生物量相近 ,在 4个不同土壤pH的基地大田中均能良好生长 ,说明江苏地区环境条件完全适合贯叶连翘引种栽培。     

Positive correlations between hypericin and putative precursors detected in the quantitative secondary metabolite spectrum of Hypericum

A spectrum of eight pharmacologically important secondary compounds, all putatively belonging to the polyketide pathway (hypericin, pseudohypericin, emodin, hyperforin, hyperoside, rutin, quercetin, and quercitrin) were analyzed in several hypericin-producing species of Hypericum by LC–MS/MS. Different organs such as leaves, stems and roots of wild-grown plants of Hypericum hirsutum L., Hypericum maculatum Crantz s. l., Hypericum montanum L., Hypericum tetrapterum Fr. collected in Slovakia and of Hypericum perforatum L. collected in India were examined individually. Highest contents of hypericin, pseudohypericin, and emodin were found in H. montanum, suggesting that there are alternative species to H. perforatum with high pharmaceutical value. Amounts of hyperforin and quercetin were highest in H. perforatum, whereas highest contents of hyperoside and quercitrin were found in H. maculatum. A significant positive correlation between hypericin and pseudohypericin as well as between hypericin and emodin was observed by Kruskal’s multidimensional scaling (MDS), indicating a parallel enhancement of emodin as a common precursor in the biosynthetic pathways of hypericin and pseudohypericin. Furthermore, MDS combined with principal component analysis (PCA) revealed strong correlations in the occurrence of pseudohypericin and emodin, pseudohypericin and quercitrin, hypericin and quercitrin, emodin and quercitrin, hyperoside and quercitrin, rutin and quercetin, and, hyperforin and quercetin. On the other hand, rutin showed a negative correlation with emodin as well as with quercitrin. Furthermore, hierarchical agglomerative cluster analysis (HACA) clustered hypericin and pseudohypericin, grouping emodin at equal distance from both. Considerable infraspecific variability in secondary compound spectrum and load of different populations of H. maculatum from Slovakia underscores the need for detailed studies of genotypic variation and environmental factors in relation to polyketide biosynthesis and accumulation.     

Optimization of Protein Extraction from <Emphasis Type="Italic">Hypericum perforatum</Emphasis> Tissues and Immunoblotting Detection of Hyp-1 at Different Stages of Leaf Development

Sample preparation is crucial for obtaining high-quality proteins for the purpose of electrophoretic separation and further analysis from tissues that contain high levels of interfering compounds. Hypericum perforatum is a medicinal plant that contains high amounts of phenolic compounds, of which hypericins, hyperforins, and flavonoids contribute to the antidepressant activities of the plant. This study focuses on obtaining optimized amounts of high-quality proteins from H. perforatum, which are suitable for electrophoretic analyses. From the tested protein extraction solutions, sodium borate buffers at pH 9 and 10 gave the best protein yields from mature H. perforatum leaves. With these buffers, relatively high protein yields could also be obtained from roots, stems, and flower buds. The protein extracts of all organs were well resolved in SDS-PAGE after an efficient removal of non-protein contaminants with PVPP, phenol extraction, and methanolic ammonium acetate precipitation. The method was suitable for high-quality protein extraction also from other tested species of genus Hypericum. The applicability of the protocol for immunoblotting was demonstrated by detecting Hyp-1 in H. perforatum leaves at different stages of development. Hyp-1, which has been suggested to attend to the biosynthesis of hypericin, accumulated in high amounts in H. perforatum leaves at mature stage.     

Signal interaction between nitric oxide and hydrogen peroxide in heat shock-induced hypericin production of Hypericum perforatum suspension cells

Heat shock(HS, 40℃, 10 min) induces hypericin production, nitric oxide(NO) generation, and hydrogen peroxide(H2O2) accumulation of Hypericum perforatum suspension cells.Catalase(CAT) and NO spe-cific scavenger 2-4-carboxyphenyl-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide(cPTIO) suppress not only the HS-induced H2O2 generation and NO burst, but also the HS-triggered hypericin produc-tion.Hypericin contents of the cells treated with both NO and H2O2 are significantly higher than those of the cells treated with NO alone, although H2O2 per se has no effects on hypericin production of the cells, which suggests the synergistic action between H2O2 and NO on hypericin production.NO treatment enhances H2O2 levels of H.perforatum cells, while external application of H2O2 induces NO generation of cells.Thus, the results reveal a mutually amplifying action between H2O2 and NO in H.perforatum cells.CAT treatment inhibits both HS-induced H2O2 accumulation and NO generation, while cPTIO can also suppress H2O2 levels of the heat shocked cells.The results imply that H2O2 and NO may enhance each other's levels by their mutually amplifying action in the heat shocked cells.Membrane NAD(P)H oxidase inhibitor diphenylene iodonium(DPI) and nitric oxide synthase(NOS) inhibitor S,S′-1,3-phenylene-bis(1,2-ethanediyl)-bis-isothiourea(PBITU) not only inhibit the mutually amplifying action between H2O2 and NO but also abolish the synergistic effects of H2O2 and NO on hypericin production, showing that the synergism of H2O2 and NO on secondary metabolite biosynthesis might be dependent on their mutual amplification.Taken together, data of the present work demonstrate that both H2O2 and NO are essential for HS-induced hypericin production of H.perforatum suspension cells.Furthermore, the results reveal a special interaction between the two signal molecules in mediating HS-triggered secondary metabolite biosynthesis of the cells.     

Plant-environment interactions: Accumulation of hypericin in dark glands of Hypericum perforatum

BACKGROUND AND AIMS: Hypericum perforatum is a perennial herbaceous plant and an extract from this plant has a significant antidepressant effect when administered to humans. The plant is characterized by its secretory glands, also known as dark glands, which are mainly visible on leaves and flowers. The current study evaluates the influence of several environmental factors and developmental stages of the plant on the accumulation and synthesis of hypericin and pseudohypericin (Hy-G), the major bioactive constituents, in H. perforatum plants. METHODS: The appearance of dark glands on different parts of the plant, under several environmental conditions, was monitored by microscopy. Hy-G concentrations were quantified by high-performance liquid chromatography. KEY RESULTS: A significant presence of dark glands accompanying the highest concentrations of Hy-G was observed in the stamen tissues more than in any other organ of H. perforatum. A linear relationship between the number of dark glands and net photosynthetic rate of the leaf and Hy-G concentration in the leaf tissue was also established. A very high concentration of Hy-G was measured in the dark-gland tissues, but in the tissues without any dark glands it was almost absent. The presence of emodin, a precursor of Hy-G, at a high concentration in the dark-gland tissues, and its absence in the surrounding tissues was also observed, suggesting that the site of biosynthesis of Hy-G is in the dark-gland cells. A significantly low concentration of Hy-G (occasionally non-detectable) was measured in the xylem sap of the stem tissues. The dark-gland tissues collected from leaves, stems or flowers contained similar concentrations of Hy-G. CONCLUSIONS: The concentration of Hy-G in various organs of H. perforatum plants is dependent on the number of dark glands, their size or area, not on the location of the dark glands on the plant. The study provides the first experimental evidence that Hy-G is synthesized and accumulates in dark glands.     

Identification and quantification of hypericin and pseudohypericin in different Hypericum perforatum L. in vitro cultures.

Investigations have been made to develop an efficient protocol for micropropagation allowing to improve hypericin and pseudohypericin productions in Hypericum perforatum L. in vitro cultures. The role of growth regulator treatments has been particularly studied. Three in vitro culture lines with different morphological characteristics were obtained during H. perforatum micropropagation and referred to shoots, calli and plantlets according to their appearance. Multiplication and callogenesis from apical segments from sterile germinated seedlings were obtained on solid MS/B5 culture medium in the presence of N6-benzyladenine (BA) (0.1-5.0 mg/l BA). Regenerative potential of shoots was assessed on medium supplemented with auxins (0.05-1.0 mg/l), indole-3-acetic acid (IAA) or indole-3-butyric acid (IBA). The main goal of the research was to summarize the influence of plant growth regulators on hypericin and pseudohypericin productions in in vitro cultures of Hypericum. A rapid method for naphtodianthrone quantification was developed. The use of a reversed-phase high performance liquid chromatography (HPLC) method with fluorescence detection was used. Identification of the compounds was confirmed by electrospray ionization-mass spectrometry (ESI-MS) with electrospray in negative ion mode [M-H] . Calli, shoots and plantlets of H. perforatum produced hypericin and pseudohypericin. The concentration range of BA from 0.1 to 2.0 mg/l improved the production of hypericin (25-50 microg/g dry mass (DM)) and pseudohypericin (170-350 microg/g DM) in shoots. In callus cultures, BA (4.0-5.0 mg/l) did not changed hypericin contents (15-20 microg/g DM) but influenced pseudohypericin productions (120-180 microg/g DM). In the presence of auxins (IAA and IBA), Hypericum plantlets produced hypericin (30-100 microg/g DM) and pseudohypericin (120-400 microg/g DM). The presence of IAA did not influence naphtodianthrone productions in plantlets, but IBA decreased hypericin and pseudohypericin amounts in plantlets. The specific accumulation of the naphtodianthrones in in vitro cultures was influenced by phytohormonal supplementation of the medium. Results indicated that the production of hypericin and pseudohypericin could be increased by carefully adapted in vitro cultures. Hypericum in vitro cultures represent promising systems for hypericin and pseudohypericin productions.     

The influence of salicylic acid elicitation of shoots, callus, and cell suspension cultures on production of naphtodianthrones and phenylpropanoids in Hypericum perforatum L.

Hypericum perforatum is a well known medicinal plant. The main pharmacological properties are due to the presence of naphtodianthrones such as hypericin and pseudohypericin. Unfortunately the levels of these compounds vary under different environmental conditions. Elicitation of in vitro cultures is a useful approach to enhance and extend production of desirable products. Therefore, the effects of salicylic acid were characterized on different explants of H. perforatum L. (cells, calli and shoots) cultured in vitro. It appears at first that salicylic acid did not affect growth and development of these explants. In addition, the production of both hypericin and pseudohypericin has doubled in elicited cell suspension cultures but not in the two other cultures. Furthermore, phenylpropanoids that are among the most frequently observed metabolites affected upon treatment of in vitro culture material with elicitors, were produced and the enzymatic activities of phenylalanine ammonia lyase and of chalcone isomerase were stimulated upon elicitation. These effects were dependant of the type of in vitro culture, the concentration of salicylic acid and the duration post-elicitation. The H. perforatum cells were globally more sensitive to salicylic acid elicitation when maintained in an undifferentiated state and particularly in cell suspension cultures. In the absence of glands considered as the sites of naphtodianthrones biosynthesis, cells and calli were capable of producing these compounds. This implies that salicylic acid could act at biosynthesis level but not for the accumulation of both hypericin and pseudohypericin. Consequently, the regulation of this process is more complex than cited in the literature involving the responsibility of only Hyp-1 gene, encoding a hypericin biosynthetic enzyme, cloned and characterized from H. perforatum.     

贯叶连翘中金丝桃素的合成与积累研究进展

金丝桃素是贯叶连翘的主要药理活性成分。本文概述了金丝桃素的化学与生物合成途径,介绍了金丝桃素在贯叶连翘个体发育过程中的积累以及利用贯叶连翘的细胞和组织培养技术生产与积累金丝桃素的研究进展。最后,指出分子生物学和电子显微镜技术的发展为深入研究金丝桃素的产生和积累提供了有利工具。