Ultrahigh diterpenoid tanshinone production through repeated osmotic stress and elicitor stimulation in fed-batch culture of <Emphasis Type="Italic">Salvia miltiorrhiza</Emphasis> hairy roots

Hyperosmotic stress (OS, created with 50 g/L sorbitol) and a yeast elicitor (YE, polysaccharide fraction of yeast extract) applied to Salvia miltiorrhiza hairy root cultures had a synergistic effect on the diterpenoid tanshinone production. With a single OS+YE treatment and nutrient feeding, the total tanshinone content of roots was increased by sevenfold (from 0.2 to 1.6 mg/g dry weight (dw)) and the volumetric yield by 13-fold (from 1.95 to 27.4 mg/L) compared to the batch control culture. With repeated feeding of OS and nutrient medium in an extended fed-batch culture process (i.e., 10 mL fresh medium with 50 g/L sorbitol 25 mg/L YE, every 5 days from day 21 to day 60), the total tanshinone content of roots was increased to 18.1 mg/g dw (or 1.8 wt.%) and the volumetric tanshinone yield to 145 mg/L, which were about 100-fold and 70-fold of those, respectively, in the batch control. Another interesting finding was the presence of root fragments (fine particles) with extremely high tanshinone content in the OS+YE treated cultures. It was also possible to reuse the sorbitol medium for the hairy root growth and tanshinone production to reduce the medium expenses.     

Induction and potentiation of diterpenoid tanshinone accumulation in Salvia miltiorrhiza hairy roots by β-aminobutyric acid

The non-protein amino acid -aminobutyric acid (BABA) is a proven inducer of plant defense against pathogens. This work examines its effect on the production of diterpenoid tanshinones in Salvia miltiorrhiza hairy root cultures, both separately and in combination with a yeast elicitor (YE, the carbohydrate fraction of yeast extract). In the absence of YE, BABA at 0.1, 1 and 2 mM caused a dose-dependent enhancement of tanshinone accumulation, with up to a 4.5-fold increase (from 0.24 to 1.09 mg/g DW) in total content of three major tanshinones (cryptotanshinone, tanshinone I and tanshinone IIA) in the hairy roots. The combination of BABA with YE treatment further enhanced tanshinone production, but only when the BABA treatment was applied to the culture a few days before the YE treatment. Compared with methyl jasmonate, BABA was more effective in enhancing tanshinone production. A 3-day pretreatment with 1 mM BABA followed by YE-treatment, increased the total tanshinone content of roots by 9.4 times to 2.26 mg/g cells, and the volumetric tanshinone yield of culture by 6.3 times (from 3.2 to 20.1 mg/l). The results suggest that BABA can strongly potentiate elicitor-induced secondary metabolism in plant tissue cultures.     

The effect of yeast elicitor on the growth and secondary metabolism of hairy root cultures of Salvia miltiorrhiza

Hairy root cultures of Salvia miltiorrhiza transformed with Agrobacterium rhizogenes ATCC 15834 produced a tiny amount of tanshinones and a constituent level of phenolic acids under normal growth conditions. Upon elicitation with yeast elicitor, the production of both phenolic acids and tanshinones was enhanced. For example, the contents of two phenolic acids, rosmarinic acid and lithospermic acid B were elevated from 1.24% and 2.59% to 2.89% and 2.98% of dry wt, respectively while the intracellular content of cryptotanshinone increased from 0.001% to as much as 0.096% of dry wt. Yeast elicitor also improved the growth of hairy roots (from 3.9 g/l to 7.3 g/l on a dry wt basis). Liquid chromatography-mass spectrometry (LC-MS) was developed for simultaneous detection and identification of phenolic acids and tanshinones in the extracts of S. miltiorrhiza. Rosmarinic acid, lithospermic acid B, cryptotanshinone, tanshinone I, tanshinone IIA and tanshinone IIB were identified by comparison with standards available. Dihydrotanshinone I and methylenetanshiquinone were tentatively identified by the molecular weights and the elution comparable with the literature. An unknown compound with a molecular weight of 280 was found in yeast-elicitor treated hairy root cultures, which was one of the major tanshinones induced.     

Metabolic engineering tanshinone biosynthetic pathway in Salvia miltiorrhiza hairy root cultures

Tanshinone is a group of active diterpenes widely used in treatment of cardiovascular diseases. Here, we report the introduction of genes encoding 3-hydroxy-3-methylglutaryl CoA reductase (HMGR), 1-deoxy-D-xylulose-5-phosphate synthase (DXS) and geranylgeranyl diphosphate synthase (GGPPS) involved in tanshinone biosynthesis into Salvia miltiorrhiza hairy roots by Agrobacterium-mediated gene transfer technology. Overexpression of SmGGPPS and/or SmHMGR as well as SmDXS in transgenic hairy root lines can significantly enhance the production of tanshinone to levels higher than that of the control (P<0.05). SmDXS showed much more powerful pushing effect than SmHMGR in tanshinone production, while SmGGPPS plays a more important role in stimulating tanshinone accumulation than the upstream enzyme SmHMGR or SmDXS in S. miltiorrhiza. Co-expression of SmHMGR and SmGGPPS resulted in highest production of tanshinone (about 2.727 mg/g dw) in line HG9, which was about 4.74-fold higher than that of the control (0.475 mg/g dw). All the tested transgenic hairy root lines showed higher antioxidant activity than the control. To our knowledge, this is the first report on enhancement of tanshinone content and antioxidant activity achieved through metabolic engineering of hairy roots by push-pull strategy in S. miltiorrhiza.     

Modeling of tanshinone synthesis and phase distribution under the combined effect of elicitation and in situ adsorption in Salvia miltiorrhiza hairy root cultures

Modeling of tanshinone synthesis and phase distribution under the combined effect of elicitation and adsorption was studied. The simulated results showed that enhancement of tanshinone production was mainly due to the effect of the elicitor and that resin addition resulted in adsorbance of the tanshinones from the root and alteration of tanshinone distribution. Furthermore, parameter sensitivities analysis showed that the rate of transport of tanshinones from the root to the medium was the important factor that influenced tanshinone accumulation in the resin. In conclusion, the modeling of tanshinone synthesis and phase distribution identified the process mechanism under the combined effect of elicitation and adsorption and this modeling can be used in similar plant tissue culture systems.     

Azadirachtin production by hairy root cultivation of Azadirachta indica in a modified stirred tank reactor

Present investigation involves hairy root cultivation of Azadirachta indica in a modified stirred tank reactor under optimized culture conditions for maximum volumetric productivity of azadirachtin. The selected hairy root line (Az-35) was induced via Agrobacterium rhizogenes LBA 920-mediated transformation of A. indica leaf explants (Coimbatore variety, India). Liquid culture of the hairy roots was developed in a modified Murashige and Skoog medium (MM2). To further enhance the productivity of azadirachtin, selected growth regulators (1.0?mg/l IAA and 0.025?mg/l GA₃), permeabilizing agent (0.5?% v/v DNBP), a biotic elicitor (1?% v/v Curvularia (culture filtrate)) and an indirectly linked biosynthetic precursor (50?mg/l cholesterol) were added in the growth medium on 15th day of the hairy root cultivation period in shake flask. Highest azadirachtin production (113?mg/l) was obtained on 25th day of the growth cycle with a biomass of 21?g/l DW. Further, batch cultivation of hairy roots was carried out in a novel liquid-phase bioreactor configuration (modified stirred tank reactor with polyurethane foam as root support) to investigate the possible scale-up of the established A. indica hairy root culture. A biomass production of 15.2?g/l with azadirachtin accumulation in the hairy roots of 6.4?mg/g (97.28?mg/l) could be achieved after 25?days of the batch cultivation period, which was ~27 and ~14?% less biomass and azadirachtin concentration obtained respectively, in shake flasks. An overall volumetric productivity of 3.89?mg/(l?day) of azadirachtin was obtained in the bioreactor.     

Kinetics of cell growth and secondary metabolism of a high-tanshinone-producing line of the Ti transformed Salvia miltiorrhiza cells in suspension culture

When cultivated in 6,7-V medium in suspension culture, Salvia miltiorrhiza, transformed with Agrobacterium tumefaciens C58, grew rapidly, reaching about 9.7 g l^–1 dry wt after 12 days. The cell line produced tanshinones: 150 mg cryptotanshinone, 20 mg tanshinone I and 50 mg tanshinone IIA/l and phenolic acids: 530 mg rosmarinic acid and 216 mg lithospermic acid B/l. The phenolic acids were intracellular while about 1/3 of the tanshinones were extracellular. This is the first report of simultaneous production of both phenolic acids and tanshinones in a single culture system.     

Enhanced secondary metabolite (tanshinone) production of <Emphasis Type="Italic">Salvia miltiorrhiza</Emphasis> hairy roots in a novel root–bacteria coculture process

Salvia miltiorrhiza Bunge (Lamiaceae) hairy root cultures were inoculated (at 0.02 and 0.2% v/v) and co-cultured with Bacillus cereus bacteria. The root biomass growth was inhibited significantly by the bacteria inoculated to the root culture on the first day (day 0) but not by the bacteria inoculated on days 14 or 21 (in a 28-day overall period). On the other hand, the growth of the bacteria in the hairy root culture was also strongly inhibited by the hairy roots, partially because of the antibacterial activity of the secondary compounds produced by the roots. Most interestingly, the tanshinone production was promoted by the inoculation of bacteria at any of these days but more significantly by an earlier bacteria inoculation. With 0.2% bacteria inoculated on day 0, for example, the total tanshinone content of roots was increased by more than 12-fold (from 0.20 to 2.67 mg g⁻¹ dry weight), and the volumetric tanshinone yield increased by more than sixfold (from 1.40 to 10.4 mg l⁻¹). The tanshinone production was also stimulated by bacterial water extract and bacterial culture supernatant but less significantly than by the inoculation of live bacteria. The results suggest that the stimulation of tanshinone production by live bacteria in the root cultures may be attributed to the elicitor compounds originating from the bacteria, and the hairy root–bacteria coculture may be an effective strategy for improving secondary metabolite production in plant tissue cultures.     

内生真菌Colletotrichum sp. B501的寡糖提取物对黄花蒿发根中青蒿素生物合成的诱导

在黄花蒿(Artemisia annua L.)发根液体培养中,黄花蒿内生炭疽菌(Colletotrichum sp. B501)细胞壁寡糖提取物可促进发根青蒿素的合成.经寡糖诱导子(20 mg/L)处理4 d后,发根青蒿素含量达1.15 mg/g, 比对照高出64.29%.诱导作用与诱导子浓度、作用时间相关.诱导处理1 d后,X射线能谱分析表明黄花蒿发根细胞中Ca2+积累量显著增高,电镜观察发现液泡内出现高电子致密物,具活性氧清除作用的过氧化物酶表现出高活性(6.5 unit*min-1*g-1 FW).诱导处理第三天,细胞核DNA呈梯度条带降解,部分细胞出现程序化死亡.内生菌细胞壁寡糖提取物引起的生理反应有利于细胞中青蒿素的生物合成.     

内生真菌Colletotrichum sp. B501的寡糖提取物对黄花蒿发根中青蒿素生物合成的诱导(英文)

在黄花蒿 (ArtemisiaannuaL .)发根液体培养中 ,黄花蒿内生炭疽菌 (Colletotrichumsp .B5 0 1)细胞壁寡糖提取物可促进发根青蒿素的合成。经寡糖诱导子 (2 0mg/L)处理 4d后 ,发根青蒿素含量达 1.15mg/g ,比对照高出6 4 .2 9%。诱导作用与诱导子浓度、作用时间相关。诱导处理 1d后 ,X射线能谱分析表明黄花蒿发根细胞中Ca2 积累量显著增高 ,电镜观察发现液泡内出现高电子致密物 ,具活性氧清除作用的过氧化物酶表现出高活性 (6 .5unit·min-1·g-1FW)。诱导处理第三天 ,细胞核DNA呈梯度条带降解 ,部分细胞出现程序化死亡。内生菌细胞壁寡糖提取物引起的生理反应有利于细胞中青蒿素的生物合成。     

Increased accumulation of the cardio-cerebrovascular disease treatment drug tanshinone in Salvia miltiorrhiza hairy roots by the enzymes 3-hydroxy-3-methylglutaryl CoA reductase and 1-deoxy-d-xylulose 5-phosphate reductoisomerase

Tanshinone is widely used for treatment of cardio-cerebrovascular diseases with increasing demand. Herein, key enzyme genes SmHMGR (3-hydroxy-3-methylglutaryl CoA reductase) and SmDXR (1-deoxy-d-xylulose 5-phosphate reductoisomerase) involved in the tanshinone biosynthetic pathway were introduced into Salvia miltiorrhiza (Sm) hairy roots to enhance tanshinone production. Over-expression of SmHMGR or SmDXR in hairy root lines can significantly enhance the yield of tanshinone. Transgenic hairy root lines co-expressing HMGR and DXR (HD lines) produced evidently higher levels of total tanshinone (TT) compared with the control and single gene transformed lines. The highest tanshinone production was observed in HD42 with the concentration of 3.25 mg g^?1 DW. Furthermore, the transgenic hairy roots showed higher antioxidant activity than control. In addition, transgenic hairy root harboring HMGR and DXR (HD42) exhibited higher tanshinone content after elicitation by yeast extract and/or Ag⁺ than before. Tanshinone can be significantly enhanced to 5.858, 6.716, and 4.426 mg g^?1 DW by YE, Ag⁺, and YE-Ag⁺ treatment compared with non-induced HD42, respectively. The content of cryptotanshinone and dihydrotanshinone was effectively elevated upon elicitor treatments, whereas there was no obvious promotion effect for the other two compounds tanshinone I and tanshinone IIA. Our results provide a useful strategy to improve tanshinone content as well as other natural active products by combination of genetic engineering with elicitors.     

Enhancement of Taxol production and excretion in Taxus chinensis cell culture by fungal elicitation and medium renewal

An endophytic fungus, Aspergillus niger, isolated from the inner bark of a Taxus chinensis tree, was used as an elicitor to stimulate the Taxol (paclitaxel) production in a Taxus chinensis cell suspension culture. Different elicitor doses and elicitation times were tested in a batch culture; and the highest volumetric Taxol yield was achieved when 40 mg of the fungal elicitor (carbohydrate equivalent) l(-1) was added to the culture during the late exponential-growth phase. The elicitation resulted in a more than two-fold increase in the Taxol yield and about a six-fold increase in total secretion. The Taxol yield was further improved substantially by applying medium renewal and re-elicitation to the culture. In particular, with repeated medium renewal (in a way similar to medium perfusion) and a second elicitation of the culture, the volumetric Taxol yield was increased to 67.1+/-7.5 mg l(-1), which was about seven times the amount obtained in the non-elicited batch culture. The Taxol productivity of the perfusion-like culture with repeated fungal elicitation was 1.5 mg l(-1) day(-1), which was about 40% higher than that of the elicitor-treated batch culture and three times the productivity of the non-elicited batch culture.     

Improved cardenolide production in Calotropis gigantea hairy roots using mechanical wounding and elicitation

A hairy root culture system of Calotropis gigantea was established and effects of mechanical wounding (MW) and elicitors [methyl jasmonate (MJ), yeast extract (YE) and chitosan (CS)] on cardenolide production were investigated. All treatments stimulated the production of cardenolide in hairy root cultures of C. gigantea. CS was the most effective elicitor, followed by MJ. YE and MW also improved cardenolide yield in individual treatments. The highest cardenolide yield (1,050 ± 55 mg/l) was obtained after adding 50 mg CS/l for 20 days, which was 2.7-fold higher than the control.     

Pyrethrin accumulation in elicited hairy root cultures of <Emphasis Type="Italic">Chrysanthemum cinerariaefolium</Emphasis>

The flowers of Pyrethrum (Chrysanthemum cinerariaefolium) are known to contain Pyrethrins that are naturally occurring potential insecticide. Hairy roots were induced from leaves of C. cinerariaefolium using Agrobacterium rhizogenes strain A4. The root clones were characterized in to four groups i.e. thick, unbranched (D2 and D5), thin, highly branched (D3), thick, branched (B2) and thick, highly branched (D1, D6). Six established hairy root clones showed the presence of pyrethrin and were selected for elicitation studies. Growth kinetics studies revealed highest growth index in hairy root clone D1 (592.0) followed by D6 and D3 on dry weight basis after 40 days of culture. The maximum pyrethrin content was found in the clone D3 (7.2 mg/g dw) which is comparable to the flowers obtained from the variety “Avadh”. Hairy root clone D2 (5.2 mg/g dw) and D6 (1.3 mg/g dw) contained pyrethrin but in less amount as compared to clone D3. The PCR analysis showed the presence of rol B and rol C genes in all the six hairy root clones while rol A was detected only in D2 clone. The methanolic extract of D3 clone showed antifungal activities against phytopathogenic fungal strains which were found maximum against Curvuleria andropogonis followed by Colletotrichum acutatum and Rhizoctonia solani. Hairy root clones D2, D3 and D6 were elicited with culture filtrate of endophytic fungus (Fusarium oxysporum) and bacteria (Bacillus subtilis). The culture filtrate (4.0?%v/v) of both the fungal and bacterial origin was found to be effective in enhancing the pyrethrin content in all the tested hairy root clones. Clone D3 showed maximum pyrethrin content on elicitation with F. oxysporum (9.7 mg/g dw) and B. subtilis (9.7 mg/g dw) culture filtrate, which is 32?% higher than the non elicited D3 hairy roots (7.2 mg/g dw). F. oxysporum also enhanced the hairy root growth resulting into the higher biomass yield of D3 (50?%) and D2 (76?%) in comparison to control non elicited hairy root clones of D3 and D2, respectively leading to higher pyrethrin yield.     

真菌诱导子对青蒿发根细胞生长和青蒿素积累的影响

３种真菌诱导子（大菌丽花轮枝孢（Ｖｅｒｔｉｃｉｌｌｉｕｍ ｄａｈｉａｅ Ｋｌｅｂ．）、葡枝根霉（Ｒｈｉｚｏｐｕｓ ｓｔｏｌｏｎｉｆｅｒ（Ｅｈｒｅｎｂ．ｅｘＦｒ．）Ｖｕｉｌｌ）和束状刺盘孢（Ｃｏｌｌｅｔｏｒｉｃｈｕｍ ｄｅｍａｔｉｕｍ（Ｐｅｒｓ．）Ｇｒｏｖｅ）处理青蒿（Ａｒｔｅｍｉｓｉａ ａｎｎｕａＬ．）的发根,均能促进发根中青蒿素的积累,其中以大丽花轮枝孢的诱导效果最好;对细胞生长均没有明显影响,     

Tanshinone biosynthesis in Salvia miltiorrhiza and production in plant tissue cultures

Salvia miltiorrhiza Bunge (Lamiaceae) root, generally called Danshen, is an important herb in Chinese medicine widely used for treatment of cardiovascular diseases. Diterpenoid tanshinons are major bioactive constituents of Danshen with notable pharmacological activities and the potential as new drug candidates against some important human diseases. The importance of Danshen for traditional and modern medicines has motivated the research interest over two decades in the biosynthesis and biotechnological production of tanshinones. Although diterpenes in plants are presumably derived from the non-mevalonate (MVA) pathway, tanshinone biosynthesis in S. miltiorrhiza may also depend on the MVA pathway based on some key enzymes and genes detected in the early steps of these pathways. Plant tissue cultures are the major biotechnological processes for rapid production of tanshinones and other bioactive compounds in the herb. Various in vitro cultures of S. miltiorrhiza have been established, including cell suspension, adventitious root, and hairy root cultures, which can accumulate the major tanshinones as in the plant roots. Tanshinone production in cell and hairy root cultures has been dramatically enhanced with various strategies, including medium optimization, elicitor stimulation, and nutrient feeding operations. This review will summarize the above developments and also provide our views on future trends.     

Rosmarinic acid production by <Emphasis Type="Italic">Coleus forskohlii</Emphasis>hairy root cultures

Coleus forskohlii hairy root cultures were found to produce forskolin and rosmarinic acid (RA) as the main metabolites. The growth and RA production by C. forskohlii hairy root cultures in various liquid media were examined. The hairy root cultures showed good growth in hormone-free Murashige and Skoog medium containing 3% (w/v) sucrose (MS medium), and Gamborg B5 medium containing 2% (w/v) sucrose (B5 medium). RA yield reached 4.0 mg (MS medium) and 4.4 mg (B5 medium) after 5 weeks of culture in a 100 ml flask containing 20 ml of each medium. Hairy root growth and RA were also investigated after treatment with various concentrations of yeast extract (YE), salicylic acid (SA) and methyl jasmonic acid (MJA). RA production in a 100 ml flask containing 20 ml B5 medium reached 5.4 mg (1.9 times more than control) with treatment of 0.01 or 1% (w/v) YE, 5.5 mg (2.0 times more than control) with treatment of 0.1 mM SA, and the maximum RA content with 9.5 mg per flask (3.4 times more than control) was obtained in the hairy roots treated with 0.1 mM MJA. These results suggest that MJA is an effective elicitor for production of RA in C. forskohlii hairy root cultures.     

Effects of Fungal Elicitors on Cell Growth and Artemisinin Accumulation in Hairy Root Cultures of Artemisia annua

The artemisinin accumulation in the hairy root cultures of Artemisia annua L. was enhanced via a treatment of three fungal elicitors separately ( Verticillium dahliae Kleb., Rhizopus stolonifer (Ehrenb. ex Fr. ) Vuill and Colletotrichum dematium (Pers.) Grove). Among these three elicitors, V. dahliae had the highest inducing efficiency, but none of them manifests any noticeable effects on the cell growth of the hairy root cultures. The artemisinin content of the hairy root cultures treated with V. dahliae elicitor was 1.12 mg/g DW, which was 45% higher than the control (0.77 mg/g DW). The results showed that elicitation was dependent on the elicitor concentration, the incubation period and the physiological stage at which the hairy root cultures were treated. In addition, the authors found that for V. dahliae, the optimum concentration was 0.4 mg carbohydrate per millilitre medium, the strongest response of A. annua hairy root cultures to the elicitation was at the late exponential growth stage, and the highest artemisinin content of the hairy root cultures was on the 4th day post treatment.     

Tanshinone production in roots of micropropagated Salvia przewalskii Maxim

Production of tanshinones (tanshinone I and IIA) was determined in roots of Salvia przewalskii micropropagated plants. It was found that the total tanshinone content (tashinone I and tashinone IIA) was dependent on the age of the analyzed plants. The roots of 2-year-old in vitro regenerated plants at flowering stage produced highest tanshinone levels (3.8 mg/g dry weight of tanshinone I and 7.6 mg/g dry weight of tanshinone IIA).