Secondary metabolites of Hypericum orientale L. growing in Turkey: variation among populations and plant parts

The present study was conducted to determine the variation in the content of several plant chemicals, namely hyperforin, hypericin, pseudohypericin, chlorogenic acid, rutin, hyperoside, isoquercetine, kaempferol, quercitrine and quercetine among ten Hypericum orientale L. populations from Northern Turkey. The aerial parts representing a total of 30 individuals were collected at full flowering and dissected into floral, leaf and stem tissues. After dried at room temperature, the plant materials were assayed for chemical contents by HPLC. The populations varied significantly in chemical contents. Among different plant parts, the flowers were found to be the principle organ for hyperforin, hypericin, pseudohypericin and rutin accumulations while the rest of the chemicals were accumulated mainly in leaves in all growing localities. The chemical variation among the populations and plant parts is discussed as being possibly the result of different genetic, environmental and morphological factors.     

Impact of pre-culture on short- and long-term in vitro recovery of the biosynthetic potential and enzymatic and non-enzymatic antioxidant defense of Hypericum rumeliacum Boiss. after cryostorage

Due to its high hypericin and pseudohypericin in vitro biosynthetic capacity, the Balkan endemic Hypericum rumeliacum was selected as a prospective candidate for long-term preservation of valuable medicinal plant germplasm. Initial cryopreservation experiments were previously conducted based on the successful protocol established and reported for the widely studied H. perforatum. This is the first report on the impact of pre-culture duration on the short- and long-term in vitro recovery of the biosynthetic potential and antioxidant defense system of H. rumeliacum cryopreserved by vitrification. Cryopreservation did not impair the phenolics and flavonoids production of the regenerated plants. Moreover, hypericin and pseudohypericin levels even increased substantially in one of the regenerated lines, reaching yields from 0.107 and 0.752?mg?g^?1?DW in the control up to 0.277 and 1.112?mg?g^?1?DW for hypericin and pseudohypericin, respectively. However, the physical injury stress of the pre-culture treatment manipulations affected the physiological status of regenerants in a time dependent manner. Within 6?months after thawing, regenerants with the highest oxidative stress after pre-culture, were characterized with an augmentation of antioxidant metabolites such as phenolics, flavonoids, glutathione and ascorbic acid as well as increased antioxidant enzymatic activities in comparison with both the non-frozen control and the regenerants with the lowest pre-culture oxidative stress. Then, after 18?months of recovery, the same first H. rumeliacum group displayed a marked drop of enzymatic antioxidant activity as compared with the other groups of plants. Further research is needed to target oxidative stress alleviation to optimize H. rumeliacum cryopreservation protocol.     

Pseudohypericin and hyperforin in Hypericum perforatum from Northern Turkey: variation among populations, plant parts and phenological stages

Hypericum perforatum is a perennial medicinal plant known as "St. John's wort" in Western Europe and has been used in the treatment of several diseases for centuries. In the present study, morphologic, phenologic and population variability in pseudohypericin and hyperforin concentrations among H. perforatum populations from Northern Turkey was investigated for the first time. The aerial parts of H. perforatum plants representing a total of 30 individuals were collected at full flowering from 10 sites of Northern Turkey to search the regional variation in the secondary metabolits concentrations. For morphologic and phenologic sampling, plants from one site were gathered in five phenological stages vegetative,floral budding, full flowering, fresh fruiting and mature fruiting. The plant materials were air-dried at room temperature and subsequently assayed for chemical concentrations by high performance liquid chromatography. Secondary metabolite concentrations ranged from traces to 2.94mg/g dry weight (DW) for pseudohypedcin and traces -6.29mg/g DW for hyperforin. The differences in the secondary metabolite concentrations among populations of H. perforatum were found to be significant. The populations varied greatly in hyperforin concentrations, whereas they produced a similar amount of pseudohypericin. Concentrations of both secondary metabolites in all tissues increased with advancing of plant development and higher accumulation levels were reached at flowering. Among different tissues, full opened flowers were found to be superior to stems, leaves and the other reproductive parts with regard to pseudohypericin and hyperforin accumulations. The present findings might be useful to optimize the processing methodology of wild-harvested plant material and obtain Increased concentrations of these secondary metabolites.     

Variation in the contents of pseudohypericin and hypericin in Hypericum perforatum from Lithuania

Hypericin and hypericin-like substances are considered the main active compounds in Hypericum perforatum L. (Hypericaceae). In this work pseudohypericin and hypericin of H. perforatum collected in Lithuania were quantified. Studies on accumulation dynamics and between-accession variation of the contents of these secondary metabolites were carried out by high performance liquid chromatography (HPLC). The data were statistically processed with ANOVA and PCA. Significant difference between pseudohypericin and hypericin content in floral budding and full flowering stages was detected. The highest amounts of the secondary metabolites were observed in the flowering stage. The study revealed evident within population variations in H. perforatum. Mean concentrations of pseudohypericin and hypericin among accessions varied from 3.45 to 6.82 mg/g and from 1.17 to 2.59 mg/g, respectively. Accessions of H. perforatum showed remarkable differences in chemical composition depending on the provenance of plants.     

Differences in hypericin synthesis between experimentally induced seedling shoot cultures of Hypericum hookerianum Wight & Arn.

During seed germination trials of Hypericum hookerianum, seedlings of Lake View accession from Palni hills of Southern India segregated into green- (97.44 %) and red-pigmented (2.56 %) types. Seedlings cultured in Murashige and Skoog (1962) basal medium developed into fast growing green and slow growing red plant types in 6 weeks, the latter showing increased concentrations of total phenols, anthocyanins and flavonoids and 19-fold higher concentration of hypericin. Hypocotyls/cotyledons of red seedlings cultured using 2.325 μM kinetin (KIN) produced hypericin-rich (4.38 ± 0.18 mg/g DW), stunted (0.5–1.2 cm) shoots which ceased to grow in 8 weeks. Segments (4–6 mm) of these shoots sub-cultured in the dark for 4 weeks followed by 2-week light exposure and repeated subculture enabled mass multiplication of productive (3.93 ± 0.06 mg hypericin/g DW) shoots. Green hypocotyls and cotyledons subjected to 4 + 2 weak dark–light treatment also produced 9.18 ± 2.44 and 4.25 ± 0.96 comparable hypericin-rich (3.73 ± 0.21 mg/g DW) shoots. Red and green seedling explants cultured in basal medium in the dark produced 6.82 ± 0.75 cm etiolated shoots with reduced leaves which synthesized 2.27 ± 0.15 mg hypericin/g DW on illumination. Green cotyledons cultured in the dark using 2.45 μM indole-3 butyric acid (IBA) formed calluses which on illumination formed 12.64 ± 3.8 productive (3.86 ± 0.31 mg hypericin/g DW) 0.5- to 1.5-cm-long shoot clusters. Phenotypic segregation of seedlings, the ability of both red and green seedling explants to multiply in the dark and produce hypericin on illumination, and IBA-induced indirect shoots producing significant amounts of metabolite compared to wild plants (0.35 ± 0.09 mg/g DW) and green shoot cultures (0.91 ± 0.03 mg/g DW) are new to Hypericum.     

The production of hypericins in two selected Hypericum perforatum shoot cultures is related to differences in black gland structure.

In vitro shoot cultures of Hypericum perforatum derived from wild populations grown in Armenia have a wide variation of hypericin and pseudohypericin metabolite content. We found that a germ line denoted as HP3 produces six times more hypericin and fourteen times more pseudohypericin than a second line labeled HP1. We undertook a structural comparison of the two lines (HP1 and HP3) in order to see if there are any anatomical or morphological differences that could explain the differences in production of these economically important metabolites. Analysis by LM (light microscopy), SEM (scanning electron microscopy), and TEM (transmission electron microscopy) reveals that the hypericin/pseudohypericin-containing black glands located along the margins of the leaves consist of a peripheral sheath of flattened cells surrounding a core of interior cells that are typically dead at maturity. The peripheral cells of the HP3 glands appear less flattened than those of the HP1 glands. This may indicate that the peripheral cells are involved in hypericin/pseudohypericin production. Furthermore, we find that these peripheral cells undergo a developmental transition into the gland's interior cells. The fact that the size of the peripheral cells may correlate with metabolite production adds a new hypothesis for the actual site of hypericin synthesis.     

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.     

Light-induced production of antidepressant compounds in etiolated shoot cultures of Hypericum hookerianum Wight & Arn. (Hypericaceae)

Hypericum hookerianum is a lesser known ethnomedicinal plant having wound healing, antitumor and anti-HSV-1 properties. Isolated nodes of in vitro shoots sub-cultured in the dark for 4 weeks on half strength Murashige and Skoog medium solidified with Gelzan (1.5 g l^?1), and supplemented with 2.325 μM kinetin produced 8.0 ± 0.40 etiolated shoots of 5.0 ± 0.62 cm length at 74 % efficiency versus 9.2 ± 0.6 healthy shoots of 4.4 ± 0.5 cm obtained from nodes in light at 96 % efficiency. Low concentrations of hypericin were found in wild plant [0.35 ± 0.09 mg g^?1 dry weight (DW)] and control green shoot cultures (0.91 ± 0.03 mg g^?1 DW). Etiolated shoots exposed to a 12 h photoperiod (50 μmol m^?2 s^?1) through 1–25 days turned red incrementally due to synthesis and accumulation of 0.1–3.83 mg g^?1 DW hypericin in sub-epidermal cortical cells of the stem and varied shaped cells of the distorted mesophyll. Flavonoid and anthocyanin concentrations of the etiolated shoots subjected to the 12 h photoperiod were 3–5 fold higher than the control shoot cultures while total chlorophylls [1.97 ± 0.05 mg g^?1 fresh weight (FW)] of the light exposed shoots were significantly less compared to the control (2.86 ± 0.18 mg g^?1 FW) and natural plant (6.82 ± 0.29 mg g^?1 FW). HPLC analysis of shoot extracts revealed the presence of 0.14 ± 0.03, 0.16 ± 0.02 and 1.45 ± 0.16 mg g^?1 DW hyperforin in wild plant, control shoot cultures and etiolated shoot cultures illuminated for 25 days, respectively. Despite a reasonable presence in etiolated shoots (0.61 ± 0.15 g^?1 FW), total phenols did not increase significantly during illumination. The results indicate light induced synthesis of anti-depressant phenolic derivatives (hypericin, hyperforin and flavonoids) in etiolated shoot cultures of H. hookerianum.     

Pseudohypericin and hyperforin in two Turkish Hypericum species: Variation among plant parts and phenological stages

The genus Hypericum has received considerable interest from scientists, as it contains the variety of structurally diverse natural products which possess a wide array of biological properties, mainly hypericins and hyperforin. In the present study, variations of pseudohypericin and hyperforin were investigated in two Turkish species of Hypericum, namely Hypericum perfoliatum and Hypericum origanifolium. Wild growing plants were harvested at vegetative, floral budding, flowering, fresh fruiting and mature fruiting stages, and dissected into stem, leaf and reproductive tissues and assayed for chemical contents by high performance liquid chromatography method. Content of pseudohypericin and hyperforin in samples of the whole plant increased during the course of ontogenesis in both species. The highest levels of the chemicals were reached at full flowering (2.62 mg/g dry weight (DW) pseudohypericin and 1.84 mg/g DW hyperforin for H. perfoliatum; 0.93 mg/g DW pseudohypericin and 1.63 mg/g DW hyperforin for H. origanifolium). Among different reproductive parts, full opened flowers produced the highest amount of pseudohypericin (1.18 mg/g DW) and hyperforin (4.36 mg/g DW) in H. origanifolium. Similarly, the highest pseudohypericin accumulation was observed in full opened flowers in H. perfoliatum (7.41 mg/g DW) while floral buds of this species produced the highest amount of hyperforin (7.80 mg/g DW). These data can be useful when elucidating the medicinal properties of the species and the chemosystematic significance of hyperforin and pseudohypericin in the relationships among species of Hypericum.     

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.     

Seasonal variation in hypericin content of Hypericum perforatum L. (St. John's Wort)

Hypericin and pseudohypericin, bioactive constituents in St. John's Wort (Hypericum perforatum), have been determined in the soft tops of the plant that are most likely to be browsed by foraging livestock. In two consecutive seasons, the hypericin/pseudohypericin concentration in a broad leaf biotype varied from a winter minimum of less than 100 ppm to a summer maximum approaching 3000 ppm. In contrast the narrow leaf biotype increased from similar winter values to summer maxima approaching 5000 ppm. The latter biotype was slower in returning to low levels of hypericin/pseudohypericin.     

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.     

A high-performance liquid chromatography with electrochemical detection for the determination of total hypericin in extracts of St. John's Wort

An HPLC method for the quantitation of hypericin using a new and sensitive amperometric detection is presented. Hypericin was eluted isocratically using a mobile phase consisting of ammonium acetate, methanol and acetonitrile. The oxidation was carried out with a glassy carbon electrode at a potential of + 1.1 V vs. an Ag-AgCl-KCl reference electrode. Under the conditions described, hypericin was separated at a retention time (Rt) of 12 min. Linearity was obtained over the range 0.035-1.30 microg/mL (r = 0.9994). The limit of detection was determined to be 0.010 ng on-column for hypericin. The method was applied to the determination of total hypericin (hypericin, pseudohypericin, protohypericin and protopseudohypericin) in extracts of St. John's wort using hypericin as an external standard. The protoforms were converted into hypericin and pseudohypericin by subjecting the sample to artificial light prior to chromatographic analysis. For the evaluation of total hypericin, the peak areas of pseudohypericin (Rt 3.7 min) and hypericin (Rt 12.0 min) were combined. The relative standard deviation in analysing samples containing Hypericum ranged from 2.5 to 5.4%.     

Stimulation of the production of hypericins by mannan in Hypericum perforatum shoot cultures

Shoot organ cultures were established from callus derived from anthers of Hypericum perforatum flowers and the effect of elicitors on hypericin and pseudohypericin production in shoot organ cultures was investigated. Mannan stimulated pseudohypericin production up to four fold (0.82 mg/g dry wt) and hypericin production up to two fold (0.04 mg/g dry wt.) beta-1,3-glucan and pectin slightly stimulated pseudohypericin production (ca. two fold), but had no effect on hypericin production. On the other hand, yeast extract showed no stimulatory effect, on either hypericin or pseudohypericin production.     

Phenolic constituents and genetic profile of Hypericum perforatum L. from India

The content of hypericins (hypericin and pseudohypericin), hyperforin, and flavonoids (rutin, hyperoside, quercitrin, and quercetin) and genetic profiles of eight accessions of Hypericum perforatum L., collected from different locations in India, have been determined. The secondary metabolite content was determined using a highly selective LC/MS/MS method. Pearson and Spearman's correlation coefficient were used to investigate the relationships between the secondary metabolites and a significant positive correlation was found between hypericin and pseudohypericin contents. Genetic profiling was undertaken using the random amplification of polymorphic DNA (RAPD) and single sequence repeat (SSR) methods. Among the 49 random primers used for the initial screening, only nine yielded polymorphic RAPD profiles. The SSR analysis shows that seven out of the 11 primers were polymorphic. There exists only a partial correlation between the chemical content and genetic profiling data among the accessions under study.     

Hypericin and pseudohypericin in some Hypericum species

Hypericin and pseudohypericin were found in 27 of the 36 evaluated species from Hypericum L., belonging to 17 sections of the genus. Pseudohypericin is reported by us in 15 taxa for the first time. Most of the species contained both components and the amount of pseudohypericin usually exceeded that of hypericin. In H. hirsutum and H. empetrifolium only hypericin was found, whereas H. formosissimum yielded pseudohypericin only. The total content of hypericins varied widely from 0.009% in H. empetrifolium to 0.512% in H. boissieri and the largest amounts were established in taxa of sections Drosocarpium, Hypericum and Thasia. The distribution of hypericin and pseudohypericin in Hypericum species has an important taxonomic value for infrageneric classification of the genus. These components were not found in the primitive sections Ascyreia, Androsaemum, Inodora, Roscyna, Bupleuroides and Spachium but occur widely in Hypericum, Adenosepalum and the sections from Olympia group. Although the genera of subfamily Hypericoideae are characterized by the presence of anthrone derivatives, condensed anthrones such as hypericin and pseudohypericin have not been found in these genera and the remaining subfamilies of the Guttiferae.     

Variation of Bioactive Compounds in Hypericum perforatum Growing in Turkey During Its Phenological Cycle

The present study was conducted to determine phenologic and morphogeneUc variation of hyperlcln, chlorogenlc acid and flavonoids, as rutin, hyperoside, apigenin-7-O-glucoside, quercitrin, quercetin content of Hypericum perforatum L. growing in Turkey. Wild growing plants were harvested at vegetative, floral budding, full flowering, fresh frulUng and mature fruiting stages and dissected into stem, leaf and reproductive tissues and assayed for bioacUve compounds by the High performance liquid chromatography （HPLC） method. Hypericin concentration ranged between 0 and 2.73 mg/g DW, chlorogenic acid 0.00-3.64 mg/g DW, rutin 0.00-3.36 mg/g DW, hyperoside 0.04- 22.42 mg/g DW, quercitrin 0.03-3.46 mg/g DW and quercetin 0.04-1.02 mg/g DW depending on ontogenetic and morphogenetic sampling. Leaves were found to be superior to stems and reproductive parts with regard to phenolic accumulation for all compounds tested while flowers accumulated the highest levels of hypericln. Quercltrln, quercetln and hypericin content in all tissues increased with advancing of developmental stages and reached their highest level during flower ontogenesis. Similarly, chlorogenic acid, hyperoside and apigenin-7-O-glucoside content in different plant parts increased during plant development, however, the highest level was observed at different stages of plant phenology for each tissue. Chlorogenic acid was not detected in stems, leaves and reproductive parts in several stages of plant phenology and its variation during plant growth showed inconsistent manner. In contrast to the other compounds examined, rutin content of stems and leaves decreased with advanc- ing of plant development and the highest level for both tissues was observed at the vegetative stage. However, content of the same compound in reproductive parts was the highest at mature fruiting. The present findings might be useful to obtain increased concentration of these natural compounds.     

Morphogenetic and diurnal variation of hypericin in some Hypericum species from Turkey during the course of ontogenesis

The genus Hypericum has received considerable interest from scientists, as it is a source of a variety of biologically active compounds including the hypericins. The present study was conducted to determine ontogenetic, morphogenetic and diurnal variation of the total hypericins content in some species of Hypericum growing in Turkey namely, Hypericum aviculariifolium subsp. depilatum var. depilatum (endemic), Hypericum perforatum and Hypericum pruinatum. The Hypericum plants were harvested from wild populations at vegetative, floral budding, full flowering, fresh fruiting and mature fruiting stages four times a day. Plants were dissected into stem, leaf and reproductive tissues, which were dried separately, and subsequently assayed for total hypericin content. The density of dark glands on leaves at full flowering plants was determined for each species. Floral parts had the highest hypericin content in all species tested. But diurnal fluctuation in the hypericin content of whole plant during the course of ontogenesis varied among the species. It reached the highest level at floral budding and tended to increase at night in H. aviculariifolium subsp. depilatum var. depilatum and H. pruinatum, whereas in H. perforatum hypericin content was the highest at full flowering and no diurnal fluctuation was observed. In general, hypericin content of leaves and whole plant was higher in H. aviculariifolium subsp. depilatum var. depilatum whose leaves had more numerous dark glands than those of the two other species.     

Determination of enantiomerization barriers of hypericin and pseudohypericin by dynamic high‐performance liquid chromatography on immobilized polysaccharide‐type chiral stationary phases and off‐column racemization experiments

Direct enantiomer separation of hypericin, pseudohypericin, and protohypericin was accomplished by high‐performance liquid chromatography (HPLC) using immobilized polysaccharide‐type chiral stationary phases (CSPs). Enantioselectivities up to 1.30 were obtained in the polar‐organic elution mode whereby for hypericin and pseudohypericin Chiralpak IC [chiral selector being cellulose tris(3,5‐dichlorophenylcarbamate)] and for protohypericin Chiralpak IA (chiral selector being the 3,5‐dimethylphenylcarbamate of amylose) gave favorable results. Enantiomers were distinguished by on‐line electronic circular dichroism detection. Optimized enantioselective chromatographic conditions were the basis for determining stereodynamic parameters of the enantiomer interconversion process of hypericin and pseudohypericin. Rate constants delivered by computational simulation of dynamic HPLC elution profiles (stochastic model, consideration of peak tailing) were used to calculate averaged enantiomerization barriers (ΔG) of 97.6–99.6 kJ/mol for both compounds (investigated temperature range 25–45°C). Complementary variable temperature off‐column (i.e., in solution) racemization experiments delivered ΔG = 97.1–98.0 kJ/mol (27–45°C) for hypericin and ΔG = 98.9–101.4 kJ/mol (25–55°C) for pseudohypericin. An activation enthalpy of ΔH^# = 86.0 kJ/mol and an activation entropy of ΔS^# = ?37.7 J/(K mol) were calculated from hypericin racemization kinetics in solution, whereas for pseudohypericin these figures amounted to 74.1 kJ/mol and ?82.6 J/(K mol), respectively. Although the natural phenanthroperylene quinone pigments hypericin and pseudohypericin as well as their biological precursor protohypericin are chiral and can be separated by enantioselective HPLC low enantiomerization barriers seem to prevent the occurrence of an excess of one enantiomer under typical physiological conditions—at least as long as stereoselective intermolecular interactions with other chiral entities are absent. Chirality 2010. © 2009 Wiley‐Liss, Inc.