Copper-induced changes in the growth, oxidative metabolism, and saponin production in suspension culture roots of Panax ginseng in bioreactors

Roots of Panax ginseng exposed to various concentrations of Cu (0.0, 5, 10.0, 25.0, and 50.0 μM) accumulated high amounts of Cu in a concentration-dependent and duration-dependent manner. Roots treated with 50 μM Cu resulted in 52% and 89% growth inhibition after 20 and 40 days, respectively. Saponin synthesis was stimulated at a Cu concentration between 5 and 25 μM but decreased at 50 μM Cu. Malondialdehyde content (MDA), lipoxygenase activity (LOX), superoxide ion (O₂ ^•−) accumulation, and H₂O₂ content at 5 and 10 μM Cu-treated roots were not increased but strongly increased at 50 μM Cu resulting in the oxidation of ascorbate (ASC) and glutathione (GSH) to dehydroascorbate (DHA) and glutathione disulfide (GSSG), respectively indicating a clear oxidative stress. Seven well-resolved bands of superoxide dismutase (SOD) were detected in the gel and an increase in SOD activity seemed to be mainly due to the induction of Fe-SOD 3. Five to 10 μM Cu slightly induced activity of ascorbate peroxidase (APX) and dehydroascorbate reductase (DHAR), guaiacol peroxidase (G-POD) but inhibited monodehydroascorbate reductase (MDHAR) and glutathione reductase (GR) enzyme activities. No changes in catalase (CAT) activity and in activity gel were found up to 25 μM Cu, but both G-POD and CAT activities were inhibited at 50 μM Cu. Glutathione metabolism enzymes such as γ-glutamylcysteine synthetase (γ-GCS), glutathione-S-transferase (GST), and glutathione peroxidase activities (GPx) were activated at 5 and 10 μM Cu but were strongly inhibited at 50 μM Cu due to the Cu accumulation in root tissues. The strong depletion of GSH at 50 μM Cu was associated to the strong induction of γ-glutamyltranspeptidase (γ-GGT) activity. These results indicate that plant could grow under Cu stress (5–25 μM) by modulating the antioxidant defense mechanism for combating Cu induced oxidative stress.     

Methyl jasmonate and salicylic acid elicitation induces ginsenosides accumulation, enzymatic and non-enzymatic antioxidant in suspension culture Panax ginseng roots in bioreactors

The effects of methyl jasmonate (MJ) and salicylic acid (SA) on changes of the activities of major antioxidant enzymes, superoxide anion accumulation (O₂ ⁻), ascorbate, total glutathione (TG), malondialdehyde (MDA) content and ginsenoside accumulation were investigated in ginseng roots (Panax ginseng L.) in 4 l (working volume) air lift bioreactors. Single treatment of 200 μM MJ and SA to P. ginseng roots enhanced ginsenoside accumulation compared to the control and harvested 3, 5, 7 and 9 days after treatment. MJ and SA treatment induced an oxidative stress in P. ginseng roots, as shown by an increase in lipid peroxidation due to rise in O₂ ⁻ accumulation. Activity of superoxide dismutase (SOD) was inhibited in MJ-treated roots, while the activities of monodehydroascorbate reductase (MDHAR), dehydroascorbate reductase (DHAR), SOD, guaiacol peroxidase (G-POD), glutathione peroxidase (GPx) and glutathione reductase (GR) were induced in SA-treated roots. A strong decrease in the activity of catalase (CAT) was obtained in both MJ- and SA-treated roots. Activities of ascorbate peroxidase (APX) and glutathione S transferase (GST) were higher in MJ than SA while the contents of reduced ascorbate (ASC), redox state (ASC/(ASC+DHA)) and TG were higher in SA- than MJ-treated roots while oxidized ascorbate (DHA) decreased in both cases. The result of these analyses suggests that roots are better protected against the O₂ ⁻ stress, thus mitigating MJ and SA stress. The information obtained in this work is useful for efficient large-scale production of ginsenoside by plant-root cultures.     

Production of ginsenoside saponins by culturing ginseng (Panax ginseng) embryogenic tissues in bioreactors

Summary Ginseng (Panax ginseng) embryogenic tissues were cultured in three types of reactors and the ginsenoside productivities in these tissues were compared. As a result, the saponin productivity was the best when an airlift reactor was used, and more than twice of that when a paddle or internal turbine reactor was used. The tissues grew 9 fold during 42 days, and the ginsenoside pattern resembled that of ginseng leaves.Part 98 in the series Studies on Plant Tissue Cultures For Part 97 see Orihara, Y., and Furuya, T., (1993) submitted for publication.     

Methyl jasmonate elicitation enhanced synthesis of ginsenoside by cell suspension cultures of Panax ginseng in 5-l balloon type bubble bioreactors

The effects of methyl jasmonate (MJ) elicitation on the cell growth and accumulation of ginsenoside in 5-l bioreactor suspension cultures of Panax ginseng were investigated. Ginsenoside accumulation was enhanced by elicitation by MJ (in the range 50–400 M); however, fresh weight, dry weight and growth ratio of the cells was strongly inhibited by increasing MJ concentration. The highest ginsenoside yield was obtained at 200 M MJ. In the second experiment, 200 M MJ was added on day 15 during the cultivation. The ginsenoside, Rb group, and Rg group ginsenoside content increased 2.9, 3.7, and 1.6 times, respectively, after 8 days of MJ treatment. Rb group gisnsenosides accumulated more than Rg group ginsenosides. Among Rb group ginsenosides, Rb1 content increased significantly by four times but the contents of Rb2, Rc and Rd increased only slightly. Among Rg group ginsenosides, Rg1 and Re showed 2.3-fold and 3.0-fold increments, respectively, whereas there was only a slight increment in Rf group ginsenosides. These results suggest that MJ elicitation is beneficial for ginsenoside production using 5-l bioreactor cell suspension cultures.     

Formation of active oxygen species and lipid peroxidation induced by hypochlorite.

Hypochlorite or its acid, hypochlorous acid, may exert both beneficial and toxic effects in vivo. In order to understand the role and action of hypochlorite, the formation of active oxygen species and its kinetics were studied in the reactions of hypochlorite with peroxides and amino acids. It was found that tert-butyl hydroperoxide and methyl linoleate hydroperoxide reacted with hypochlorite to give peroxyl and/or alkoxyl radicals with little formation of singlet oxygen in contrast to hydrogen peroxide, which gave singlet oxygen exclusively. Amino acids and ascorbate reacted with hypochlorite much faster than peroxides. Free radical-mediated lipid peroxidation of micelles and membranes in aqueous suspensions was induced by hypochlorite, the chain initiation being the decomposition of hydroperoxides by hypochlorite. It was suppressed efficiently by ebselen which reduced hydroperoxides and by alpha-tocopherol, which broke chain propagation, but less effectively by hydrophilic antioxidants present in the aqueous phase. Cysteine suppressed the oxidation, but it was poorer antioxidant than alpha-tocopherol. Ascorbate also exerted moderate antioxidant capacity, but it acted as a synergist with alpha-tocopherol. Taken together, it was suggested that the primary target of hypochlorite must be sulfhydryl and amino groups in proteins and that the lipid peroxidation may proceed as the secondary reaction, which is induced by radicals generated from sulfenyl chlorides and chloramines.     

Growth and biosynthetic characteristics of ginseng (Panax japonicus var. repens) deep-tank cell culture in bioreactors

The aim of the work was to study the growth characteristics of cultured cells of Panax japonicus var. repens, an endemic plant of the Primorski Krai of Russia, grown in laboratory bioreactors and to determine the content of basic ginsenosides under these conditions. An increase of the inoculum size of the culture produced higher biomass accumulation and economic coefficient but slightly reduced the specific growth rate. An increase in the auxin concentration in a medium by adding 2,4-D practically did not affect growth characteristics of the culture but significantly reduced the size of cell aggregates. In all treatments tested, all major ginsenosides (Rb₁, Rc, Rb₂, Rd, Rf, Rg₁, and Re) were found in the culture. The total ginsenoside content was 2–3% per biomass dry weight. Meantime, ginsenosides of the Rg-series with protopanaxatriol as aglycone prevailed (70% of the total ginsenoside content). The culture conditions considerably affected the ratio of individual ginsenosides. In 2,4-D-containing medium, the preferential synthesis of Re ginsenoside was observed while both Rg₁ and Re were synthesized in other treatments.     

Improvement of Panax notoginseng cell culture for production of ginseng saponin and polysaccharide by high density cultivation in pneumatically agitated bioreactors

A Panax notoginseng cell culture was successfully scaled up from shake flask to 1.0-L bubble column reactor and concentric-tube airlift reactor. High-density bioreactor batch cultivation was carried out using a modified MS medium. The maximum cell density in batch cultures reached 20.1, 21.0 and 24.1 g/L in the shake flask, bubble column and airlift reactors, respectively, and their corresponding biomass productivity was 950, 1140 and 1350 mg/(L x d) for each. The productivity of ginseng saponin was 70, 96 and 99 mg/(L x d) in the flask, bubble column and airlift reactors, respectively; and the polysaccharide productivity reached 104, 119 and 151 mg/(L x d) for each. Furthermore, a fed-batch cultivation strategy was developed on the basis of specific oxygen uptake rate (SOUR), i.e., sucrose feeding before a sharp decrease of SOUR, and the highest cell density of 29.7 g/L was successfully achieved in the airlift bioreactor on day 17 with a very high biomass productivity of 1520 mg/(L x d). The concentrations of ginseng saponin and polysaccharide reached about 2.1 and 3.0 g/L, respectively, and their productivity was 106 (saponin) and 158 mg/(L x d) (polysaccharide). This work successfully demonstrated the high-density bioreactor cultivation of P. notoginseng cells in pneumatically agitated bioreactors and the reproduction of the shake flask culture results in bioreactors. The cell density, biomass productivity, production titer and productivity of both ginseng saponin and polysaccharide obtained here were the highest that have been reported on a reactor scale for all the ginseng species.     

Identification of ginsenosides in roots of Panax ginseng by HPLC-APCI/MS

A new HPLC-APCI/MS method for the identification of ginsenosides has been developed. The analyses were performed on a reversed-phase C18 column using a binary eluent (acetonitrile and water) under gradient conditions. Although APCI is a high-temperature evaporative process, HPLC-APCI/MS could effectively identify thermo-labile ginsenosides. The [M-H]- ions and the thermal degradation ions of ginsenosides could be clearly observed under negative and positive ion conditions, respectively, and these were used to identify the molecular masses, the aglycone structures and the sugar groups of ginsenosides. APCI/MS can provide more explicit information than ESI/MS for identifying and distinguishing ginsenosides. Using the HPLC-APCI/MS method, 35 ginsenosides were identified in Panax ginseng.     

Effect of short- and long-term salinity on the activities of antioxidative enzymes and lipid peroxidation in tomato roots

Changes in the antioxidative enzyme activities (SOD, CuZnSOD, GSH-Px, GST), as well as TBARS content in 5-week-old tomato (Lycopersicon esculentum Mill. cv “Perkoz”) roots were examined 1, 3 h (short-term stress) and 1–14 days (long-term stress) after a single application of 50 mM (mild stress) and 150 mM NaCl (severe stress). The severe stress caused an increase in GST, GSH-Px and SODs activities from the beginning of the experiment while mild stress induced enhancement of GST activity from the second day of experiment. The maximum increase in SODs after both NaCl solutions were applied and in GST activity after the higher NaCl dose on the second day of the experiment was observed. Moreover, after 1 h of NaCl treatment with both tested NaCl solutions, the highest induction of GSH-Px activity appeared. TBARS content was elevated from the first hour of salt stress and decreased only 14 days after 50 mM NaCl application which was accompanied by high induction of GSH-Px activity. In conclusion, enhanced activities of tested enzymes indicate their involvement in early and late defence systems under salinity stress. Moreover, the dynamics of the changes in the antioxidant enzymes suggests that the second day following NaCl application is a crucial moment of the experiment with regard to salt-mediated oxidative stress.     

Silicon effects on antioxidative enzymes and lipid peroxidation in leaves and roots of peanut under aluminum stress

Silicon (Si) can enhance plant defense against biotic and abiotic stresses, but little is known of its possible alleviation of aluminum (Al) stress. In this study, we find out how Si may mediate Al stress based on changes in root morphological parameters, biomass, physiological attributes and concentrations of Al and Si in peanut (Arachis hypogaea L., cv. Zhongkaihua 99). The peanut was raised with (80 mg L^?1) or without Si in the growth chamber under 0 and toxic Al (160 mg L^?1) levels. Aluminum stress reduced the root dry weight by 52.4 %, shoot dry weight by 33.9 % and root-to-shoot ratio (R/S) by 28.8 %. However, it increased the activities of catalase in leaves and roots by as much as 161.6 and 149.0 %, superoxide dismutase by 141.7 and 147.0 %, and peroxidases by 62.0 and 64.1 %. The Si-treated peanut suffered less from Al stress through improvements in photosynthesis, biomass and R/S. The malondialdehyde, an index of membrane damage decreased significantly by 26.0 and 28.2 % in peanut leaf and root with silicon application under Al toxicity. For the peanut treated with Al, tissue concentration of Al increased by 371.5 % in the root, 20.9 % in the stem and 37.8 % in the leaf, much of the uptake was partitioned to the root. These concentrations decreased by 40.7, 5.3 and 25.6 %, respectively, following Si application.     

Ginsenoside production in different phenotypes of Panax ginseng transformed roots

Transformed roots were obtained after the inoculation of sterile root discs of Panax ginseng C.A. Meyer with Agrobacterium rhizogenes A4. The established hairy root lines displayed three morphological phenotypes when cultured on hormone-free liquid Schenk and Hildebrandt medium. Most of the cultures showed the characteristic traits of hairy roots (HR-M), while others were either callus-like (C-M) or thin (T-M) without branching. The growth rate of the transformed root lines was always higher than that of untransformed roots, showing that the genetic changes caused by the A. rhizogenes transformation conditioned a higher biomass formation. When considering the different transformed root phenotypes, we can observe that the highest ginsenoside production was achieved by HR-M root lines, closely followed by C-M ones, whereas the lowest yield was reached by T-M root phenotype. The study of the integration of the TL-DNA and TR-DNA fragments of the pRiA4 in the root genome showed that the aux1 gene was always detected in HR-M and C-M root phenotypes which presented the highest biomass and ginsenoside productions. This fact suggests a significant role of aux genes in the morphology of Panax ginseng transformed roots. The ginsenoside pattern of transformed roots varied according to their morphology, although the ginsenoside contents of the Rg group was always higher than that of the Rb group. From our results, we can infer the potential of some root phenotypes of Panax ginseng hairy root cultures for an improved ginsenoside production.     

Growth pattern and ginsenoside production of Agrobacterium-transformed Panax ginseng roots

Panax ginseng roots transformed by Agrobacterium rhizogenes grew rapidly in a hormone-free medium. The transformed roots showed biphasic growth: rapid during the first two weeks and slower thereafter. Sucrose in the medium was almost all converted to glucose and fructose during the first two weeks, and the root growth slowed down after the depletion of sucrose in the medium. Periodic changes of the medium maintained the high growth rate, and the dry weight increased by 31 times in 32 days, which is the highest growth rate so far reported for cultured tissues of ginseng. The medium exchange also increased the ginsenoside content in the roots. Effective scale-up of the root culture was achieved in a turbine-blade type bioreactor.     

Regulation of fungal elicitors on the cell growth and biosynthesis of saponin of Panax ginseng cell suspension culture]

Adding fungal elicitors to the Panax ginseng cell suspension cultures, the biosynthesis of saponin was obviously induced, the total productivity of saponin in cultures could increase more than 30% of the control. During elicitation, the accumulation patterns of saponin in suspension cultured cells were changed, the culture time for maximum biosynthesis of saponin was shortened 2-4 days comparing with that of the control, and about 80% of biosynthetic saponin in elicited cells was secreted into medium, meanwhile the uptake for sucrose in medium of cells was enhanced, and the disturbing of pH in medium was observed, which predicated that an ion exchange occurred between elicited cells and medium.     

Explant preparation affects culture initiation and regeneration of Panax ginseng and Panax quinquefolius

The influence of explant preparation on culture initiation and regeneration was investigated. Explant preparation was defined as the application of surface disinfection and homogenization to ginseng roots and embryos. Surface disinfection significantly affected culture initiation and subsequent embryogenesis. A high success rate (80–97%) in culture initiation was associated with explants from non-surface disinfected root tissue. The cumulative contamination rate after 8 months was below 4%; in contrast, a contamination rate of 85% was observed in disinfected root explants. For non-disinfected explants, visible callus was induced in 1 week, adventitious root and somatic embryos were formed in 2 and 6 months, respectively. Explants from disinfected roots required 1 month to induce visible callus, 5–7 months for adventitious roots and 10 months for somatic embryogenesis. For germinating embryos, disinfected embryos required double the time for embryogenesis than non-disinfected ones. It was considered that surface disinfection imposed a stress and subsequently a carry-over effect on explants.     

Traits of Panax ginseng hairy roots after cold storage and cryopreservation

Summary Panax ginseng hairy root cultures were established by infecting petiole segments with Agrobacterium rhizogenes strain 15834. Hairy root segments including root tips placed onto phytohormone-free 1/2 Murashige and Skoog solid medium and stored at 4 °C in the dark for 4 months, resumed elongation when the temperature was raised to 25 °C in the dark. For cryopreservation, a vitrification method was applied. Root tips precultured with 0.1 mg/l 2,4-D for 3 days and dehydrated with PVS2 solution for 8 minutes prior to immersion into liquid nitrogen had a survival rate of 60 % and could regenerate. The hairy roots regenerated from cryopreserved root tips grew well and showed the same ginsenoside productivity and patterns as those of the control hairy roots cultured continuously at 25 °C. The conservation of T-DNAs in the regenerated hairy roots was proved by PCR analysis.Abbreviations 1/2 MS a half strength Murashige and Skoog (1962) - B5 Gamborg B5 (Gamborg et al. 1968) - WP woody plant (Lloyd and McCown 1980) - RC root culture (Thomas and Davey 1982) - RCI root culture medium containing 100 mg/l myoinositol - HF phytohormone-free - IAA indole-3-acetic acid - IBA indole-3-butyric acid - 2,4-D 2,4-dichlorophenoxyacetic acid - TIBA 2,3,5-triiodobenzoic acid - PCR polymerase chain reaction - PVS2 plant vitrification solution 2 (Sakai et al., 1990) - FDA fluorecein diacetate     

Cadmium induces reactive oxygen species generation and lipid peroxidation in cortical neurons in culture

Cadmium is a toxic agent that it is also an environmental contaminant. Cadmium exposure may be implicated in some humans disorders related to hyperactivity and increased aggressiveness. This study presents data indicating that cadmium induces cellular death in cortical neurons in culture. This death could be mediated by an apoptotic and a necrotic mechanism. The apoptotic death may be mediated by oxidative stress with reactive oxygen species (ROS) formation which could be induced by mitochondrial membrane dysfunction since this cation produces: (a) depletion of mitochondrial membrane potential and (b) diminution of ATP levels with ATP release. Necrotic death could be mediated by lipid peroxidation induced by cadmium through an indirect mechanism (ROS formation). On the other hand, 40% of the cells survive cadmium action. This survival seems to be mediated by the ability of these cells to activate antioxidant defense systems, since cadmium reduced the intracellular glutathione levels and induced catalase and SOD activation in these cells.     

Induction of lipid peroxidation by oxalate in experimental rat urolithiasis

The function of lipid peroxidation and the antiperoxidative enzymes of rat liver and kidney were studied in stone formation induced by intraperitoneal administration of sodium oxalate (7 mg/100 g body weight). The animals sacrificed 3 and 12 h after administration of sodium oxalate had higher level of malondialdehyde in liver and kidney than control animals. A significantly pronounced release of malondialdehyde was observed in treated liver and kidney homogenates when incubated with either ferrous sulphate or hydrogen peroxide compared to control liver and kidney. Superoxide dismutase activity was increased only in liver and not in kidney in treated animals compared to the control. A highly significant decrease in catalase activity was observed in both liver and kidney of treated animals.     

Inhibition of lipoxygenase-dependent lipid peroxidation by quercetin: Mechanism of antioxidative function

Quercetin inhibited soybean lipoxygenase-1-dependent linoleic acid peroxidation. Two to three μM quercetin was required for 50% inhibition. During the inhibition, quercetin was oxidized. The oxidation was observed as an absorbance decrease at about 380 nm and an absorbance increase at about 335 nm. Inhibition of linoleic acid peroxidation by quercetin seems to be due to reduction by the reagent of the linoleic acid radical formed as an intermediate during lipoxygenation. Quercetin oxidation was suppressed by ascorbate under conditions when ascorbate did not affect lipoxygenase-dependent linoleic acid peroxidation. The results suggest that ascorbate can reduce the quercetin oxidized by the linoleic acid radical back to quercetin. Based on the results, the significance of a redox reaction between oxidized quercetin and ascorbate is discussed.