American Journal of Plant Sciences
Vol.4 No.1(2013), Article ID:27643,12 pages DOI:10.4236/ajps.2013.41016
TDZ-Induced High Frequency Plant Regeneration through Direct Shoot Organogenesis in Stevia rebaudiana Bertoni: An Important Medicinal Plant and a Natural Sweetener
1National Center for Natural Products Research, School of Pharmacy, The University of Mississippi, University, USA; 2Department of Pharmacognosy, School of Pharmacy, The University of Mississippi, University, USA.
Email: *ikhan@olemiss.edu
Received October 20th, 2012; revised November 28th, 2012; accepted December 29th, 2012
Keywords: Asteraceae; Gas and Water Vapour Exchange; In Vitro Propagation; Leaf Anatomy; Rebaudioside A; Stevia rebaudiana; Stevioside; Thidiazuron
ABSTRACT
An efficient high frequency plant regeneration protocol through direct organogenesis was developed for Sevia rebaudiana Bert. Nodal segments containing axillary buds were used as an explant and inoculated on Murashige and Skoog’s (MS) medium containing 3% (w/v) sucrose, 0.8% (w/v) agar supplemented with various concentrations of benzyladenine (BA), kinetin (Kn) and thidiazuron (TDZ) ranging from 1.00 to 9.00 µM. Maximum multiple shoots (96%) were obtained in MS medium supplemented with 1.0 µM TDZ with an average of 60 shoots per culture, having an average shoot length of 6.0 cm. The best in vitro root induction (89%) was achieved on half strength MS medium without any growth regulator with an average of 24 roots per culture and root length of 7 cm. The rooted plantlets were successfully established in soil and grown to maturity at the survival rate of 95% in the indoor grow room. Highperformance liquid chromatography was used to assess the stability in chemical profile and quantification of stevioside and rebaudioside A content of in vitro propagated S. rebaudiana plants and compared with their mother plant at the peak vegetative stage. Our results show no significant differences (p < 0.05) between the mother and in vitro propagated plants. Furthermore, fully developed in vitro propagated S. rebaudiana plants were also compared with mother plant for their gas and water vapour exchange characteristics and leaf anatomy. The results show that in vitro propagated and hardened plants of S. rebaudiana are morphologically as well as functionally comparable to each other and to their mother plant.
1. Introduction
Stevia rebaudiana Bert. (Asteraceae) commonly known as a natural sweetner, is a zero calorie value natural alternative source to traditional sugar (sucrose) obtained from sugarcane, sugarbeet [1]. It is native from Paraguay and Southern Brazil, but is now cultivated on a commercial scale in other countries, particularly Japan, Taiwan, Korea, Thailand and Indonesia [2]. S. rebaudiana has also been used as a medicinal plant to cure many diseases like obesity, hypertension, heartburn, hypogylycemia and to lower the uric acid levels [3]. The S. rebaudiana leaves are a significant source of diterpene steviol glycosides that are about 300 times sweeter than sucrose at their concentration of 4% (w/v) [4].
Recent studies have displayed a high degree of variability in sweetening level and composition due to the heterogenous populations obtained through propagation by seed [5,6]. Vegetative propagation too is limited by the lower number of individuals that can be obtained simultaneously from a single plant due to pathogen accumulation in the tissues [7-9]. Therefore, clonal propagation is ideal to reduce some of these problems and micropropagation using plant tissue culture technology, offers an approach that is capable of producing large numbers of genetically similar, disease free S. rebaudiana plants in a short period of time and limited space. Although, there are several reports of micropropagation of S. rebaudiana [6,8,10-12] available, in all the previous studies involving in vitro regeneration, BA was the choice as plant growth regulator. In addition, the number of shoots regenerated was comparatively low or the time taken for the plantlet formation was long. Therefore, there is a need to develop an improved and efficient protocol for the mass propagation of elite plants of S. rebaudiana.
Besides development of a novel micropropagation system, an efficient growth regulator capable of inducing high organogenesis is necessary. Thidiazuron (TDZ: Nphenyl-N-[1,2,3-thidiazol-5-yl)urea]), a non purine cytokinin compound, has been shown to exhibit a stronger effect than N6-benzyladenine (BA) on in vitro morphogenesis of a large number of plants [13-17]. In the present study, we report an efficient high frequency in vitro regeneration protocol using TDZ. Furthermore, metabolic profiling (HPLC analysis), eco-physiological (photosynthesis, transpiration, stomatal conductance, internal CO2 concentration and water use efficiency) and leaf anatomical (stomatal length, width, frequency and index, leaf transverse section, epidermal cells, palisade cells and spongy parenchyma cells) characteristics were also studied to determine the differences, if any, exists between mother plant and in vitro propagated and hardened S. rebaudiana plants.
2. Material and Methods
2.1. Plant Material
S. rebaudiana plants were generated through vegetative propagation from seed raised high yielding elite S. rebaudiana plant (screened and selected on the basis of its chemical profile using High Pressure Liquid Chromatography, HPLC). These plants were kept in a climatic controlled indoor cultivation facility housed at CoyWaller laboratory at the National Center for Natural Product Research, The University of Mississippi and served as mother plants for the micrpropagation experiments. Nodal segments from a single mother plant containing axillary buds (~1 cm in length) were used as an explant for initiation of shoot cultures.
2.2. Sterilization
Explants were surface disinfected using 0.5% NaOCl (15% v/v bleach) and 0.1% tween 20 for 20 min. The explants were washed in sterile distilled water 3 times for 5 min prior to inoculation on the culture medium.
2.3. Inoculation
Disinfected explants were inoculated on Murashige and Skoog’s (MS) medium (Murashige and Skoog, 1962) containing 3% (w/v) sucrose, 0.8% (w/v) Type E Agar (Sigma Chemical Co., St. Louis) supplemented with various concentrations of cytokinins-benzyladenine (BA), kinetin (Kn) and thidiazuron (TDZ) ranging from 1.0 to 9.0 µM adjusted to pH 5.7. Sterile medium was dispensed (25 ml) in glass culture vessels (4 cm diameter × 9.5 cm high, jars with magenta B caps). Shoots that originated from the explants were subcultured after 30 days. The frequency with which explants produced shoots, the average number of shoots per explant and the shoot length were recorded after 30 days of culture.
Shoots taller than ~5.0 cm were transferred to MS medium without growth regulator, half strength MS medium without growth regulator and MS medium with different auxins-Indole-3-acetic acid (IAA), Indole-3-butyric acid (IBA), Naphthalene acetic acid (NAA) at 0.5, 1.0 and 2.5 µM concentrations for root induction. All cultures were incubated at 25˚C ± 2˚C with 16 h photoperiod under fluorescent light with a photon flux of ~52 µmol m−2·s−1. All experiments were repeated at least 3 times with 9 explants, with one explant per jar. The cultures were observed constantly for any response. Data were recorded on the percentage of rooting, the mean number of roots per shoot and the root length after four weeks of transfer onto the rooting medium.
2.4. Acclimatization
Rooted shoots were carefully taken out of the medium and washed thoroughly in running tap water to remove all traces of medium attached. Plantlets were preincubated in coco natural growth medium (Canna Continental, Los Angeles, CA) in thermocol cups for 10 days. The cups were covered with polythene bags to maintain humidity and kept in a growroom and later acclimatized in sterile potting mixfertilome (Canna Continental) in large pots. All these plantlets were kept under similar environmental conditions grown in an indoor cultivation facility housed at Coy-Waller laboratory at The University of Mississippi. Light was provided with full spectrum 1000 watts HID (high density discharge) lamps (Sun Systems, CA) hung on the top of plants. A hot air suction fan was attached and about 1 meter distance between plants and bulb was maintained to avoid heating due to HID bulbs. Using an automatic electric timer artificial day/night cycle was regulated with a 16 h photoperiod. Growroom temperature and relative humidity was kept nearly 25˚C ± 2˚C and 60%, respectively. Plants were watered regularly and individually to maintain sufficient moisture content in the pots.
2.5. Comparison of in Vitro Propagated Plants with Mother Plant
2.5.1 Chemical Profile, Rebaudioside A and Stevioside Content
Since stevioside concentrations in the S. rebaudiana leaves are reported to be maximum at peak vegetative stage i.e. just before flowering [18], leaf samples from mother plant and fully developed in vitro propagated plants were collected at that stage for the comparison.
Dry powdered samples (0.2 g each) were weighed and sonicated in 2.5 mL of 80% methanol (MeOH/water = 80:20, v/v) at room temperature for 30 min followed by centrifugation for 10 min at 4000 rpm. The supernatant was transferred to a 10 mL volumetric flask. The procedure was repeated three times and respective supernatants combined. The final volume was adjusted to 10 mL with 80% methanol and mixed thoroughly. Prior to injection, an adequate volume (ca. 2 mL) was passed through a 0.45 µm nylon membrane filter. The first 1.0 mL was discarded and the remaining volume was collected in a LC sample vial. Standards rebaudioside A, stevioside and steviolbioside were isolated at NCNPR, the identity and purity was confirmed by chromatographic (TLC, HPLC) methods and by the analysis of the spectroscopic data (IR, 1Dand 2D-NMR, HRESI-MS). All HPLC analyses were applied on Waters Alliance 2695 HPLC system (Waters Corp., Milford, MA, USA) and a computerized data station using Waters Empower 2 software. A reverse phase Gemini C18 column (250 × 4.6 mm i.d., 5 µm particle size) from Phenomenex (Torrance, CA, USA) was used as the stationary phase and the temperature was maintained at 40˚C. The column was equipped with a 2 cm LC-18 guard column (Phenomenex, Torrance, CA, USA). The mobile phase consisted of water (A), acetonitrile/methanol (B), both containing 0.1% phosphoric acid. Analysis was performed using the following linear gradient elution at a flow rate of 0.7 mL/minute: 0 - 15 min, 58% A/42% B to 42% A/52% B; 15 - 20, 42% A/52% B to 100% B; 20 - 25 min, 100% B. The total run time was 25 min. Each run was followed by a 5 min wash with 100% acetonitrile and an equilibration period of 15 min. Ten microliters of sample was injected and detective wavelength was 205 nm. Peaks were assigned by spiking the samples with standard compounds, comparison of UV spectra and the retention times.
2.5.2. Eco-Physiological Parameters
Plants regenerated from tissue culture and their mother plant was compared for their photosynthetic light response characteristics at their peak vegetative stage (just before initiation of flowers). Measurements were carried out on three upper undamaged, fully expanded and healthy leaves of five randomly selected in vitro propagated plants and their mother plant with the help of a closed portable photosynthesis system (Model LI-6400; LI-COR, Lincoln, Nebraska, USA). Leaves were exposed to 200, 400, 600, 800, 1000, 1200, 1400, 1600, 1800 and 2000 mmol m−2·s−1 photon flux densities (PPFD) under controlled temperature (25˚C ± 1˚C), humidity (55% ± 5%) and CO2 (350 ± 5 mmol·mol−1) conditions. Light was provided with the help of an artificial light source (Model LI-6400-02; light emitting silicon diode; LI-COR), fixed on top of the leaf chamber and recorded with the help of quantum sensor kept in the range of 660 - 675 nm, mounted at the leaf level. Temperature of the cuvette was controlled by integrated peltier coolers, which is controlled by the microprocessor. Control CO2 concentration was supplied to the cuvette of climatic unit (LI-6400-01, LI-COR Inc., USA) by mixing pure CO2 with CO2 free air and were measured by infrared gas analyzer. All the measurements for gas and water vapour exchange were first recorded at the lowest light condition and then subsequently to the increasing levels. Air flow rate (500 mmol·s−1), temperature, humidity, CO2 concentration and relative humidity were kept constant throughout the experiment. Since steady state photosynthesis is reached within 30 - 45 min, the leaves were kept for about 45 - 60 min. under each set of light conditions before the observations were recorded. Four gas exchange parameters viz., photosynthetic rate (PN), transpirational water loss (TR), stomatal conductance (gs) and intercellular CO2 concentration (Ci) were measured simultaneously at steady state condition under the each light level. Water use efficiency (WUE) was calculated as a ratio of the rate of photosynthesis and transpiration. Mean values (±SE) of each parameters for mother plant (n = 9) and in vitro propagated plant (n = 18) were used for comparison.
2.5.3. Anatomical Parameters
Fully mature and healthy leaves (third to fifth from top downwards) were collected from in vitro propagated and their mother plant and were fixed in FAA for anatomical observations. Free hand sections of fresh leaf samples and those fixed in FAA were prepared using sharp razor blades. Thin sections were selected and cleared by heating in chloral hydrate, on a glass slide covered with a cover slip, and stained with phloroglucinol + HCl. For epidermal studies, leaf pieces were cut from the mid part of leaf and directly placed on a glass slide. The sample was cut into two and one half turned over and placed next to the other in order to view both the surfaces, covered with chloral hydrate solution and a coverslip, and properly labeled [19]. The slide was then gently heated by passing over a hot air gun till forming of air bubble stopped and the specimen became translucent. For thicker samples, the leaf pieces were taken in a test tube containing chloral hydrate solution and boiled. Peeling of epidermis was done using razor blade and forceps. All the preparations were viewed under and photographed using Olympus BX41 (Japan) microscope equipped with Olympus DP71 digital camera system. Measurements of microscopic parameters were done using the Olympus-DP Controller application. Mean values (±SE) of each parameters (n = 15) for mother plant and in vitro propagated plant were used for comparison.
2.6. Statistical Analysis
Statistical analysis of data on the effect of growth regulators on multiplication, shoot proliferation and root induction, and comparison of in vitro propagated plants with their mother plant in terms of % rebaudioside A and stevioside content, gas and water vapour characteristics and anatomical parameters were done using SYSTAT (Systat Software Inc. San Jose, CA, USA) statistical software.
3. Results and Discussion
An in vitro propagation protocol for rapidly producing S. rebaudiana plantlets from nodal explants was developed (Figure 1). The effect of various concentrations of cytokinins, benzyladenine (BA), kinetin (Kn) and thidiazuron (TDZ) ranging from 1.0 to 9.0 µM was examined. Of the three cytokinins used, TDZ at 1.0 µM concentration was most effective (96%) for shoot proliferation (Table 1). Several reports suggest that TDZ results in shoot regeneration better than other cytokinins [20-23]. According to Capelle et al. [23], TDZ directly promotes growth due to its own biological activities similar to that of an N-substituted cytokinin or it may induce the synthesis and accumulation of an endogenous cytokinin. Our results show that TDZ at higher concentration than 1.0 µM resulted in suppressed shoot formation. The superiority of lower concentration of TDZ has been well documented [24]. Mithila et al. [25] also reported shoot organogenesis at lower concentrations of TDZ in leaf explant cultures of African violet (Saintpaulia ionantha). The effectiveness of TDZ in promoting shoot formation in S. rebaudiana is precisely not known. In all the previous studies involving in vitro shoot regeneration of S. rebaudiana, BA was the choice of plant growth regulator where the shoot regeneration was either low or the time taken for the plantlet formation was rather long. In the present study use of TDZ in MS medium, overall, resulted in improvement in the number of shoots per explant and the average shoot length. Fully developed, healthy shoots were obtained within 4 weeks of initiation. The percent shoot regeneration (60.31 ± 5.42) and average shoot length (6.24 ± 0.52 cm) was significantly higher (p < 0.05) in 1.0 µM TDZ treatment compared to that achieved with other concentrations of TDZ (Table 1).
For root induction, individual shoots or shoot clusters were transferred to full strength MS medium without growth regulators, half strength MS medium without
Figure 1. Micropropagation of Stevia rebaudiana using nodal segment. ((a) bar 6.00 cm) mother plant, ((b) bar 8 cm and (c) bar 2.00 cm) in vitro shoot multiplication, ((d) bar 1.71 cm and (e) bar 2.00 cm) rooting, ((f) bar 2.30 cm) fully rooted plant under acclimatization and hardening condition, ((g) bar 3.00 cm, (h) bar 3.47 cm and (i) bar 5.00 cm) hardened tissue culture raised plant and ((j) bar 6.10 cm) mature tissue culture raised plants.
Table 1. The effect of different concentrations of cytokinins on multiple shoot formation and shoot length of Stevia rebaudiana.
Values are mean ± SE. n = 27. Mean values in each column followed by the same letters (superscript) do not differ statistically at p < 0.05. MS-Murashige and Skoog medium.
growth regulators and full strength MS medium supplemented with different concentrations of IAA, IBA or NAA ranging from 0.5 µM to 2.5 µM (Table 2). The best induction and growth of healthy roots in an optimal number (89% with 24.7 ± 3.54 roots per explant and 6.72 ± 0.81 cm average root length) was obtained in half strength MS medium without any growth regulator whereas, MS supplemented with growth regulators IAA, IBA or NAA, were less productive and the roots were of dawdling growth rate, thin and hairy. The competence of plant growth regulator free MS for in vitro rooting of S. rebaudiana has also been reported by others [12,26]. The regenerants induced from lower levels of TDZ developed roots sooner and grew faster than those obtained from higher concentrations. TDZ can subsititute both the auxin and cytokinin requirement and contribute to different modes of morphogenetic responses as organogenesis and somatic embryogenesis as reported by several authors [27-29]. The rooted plants exhibited 95% survival rate 8 weeks after transfer to the soil. The acclimatized plants exhibited normal development and no gross morphological variation was observed (Figure 1).
Chemical profile and, rebaudioside A and stevioside content of randomly selected few in vitro propagated plants and mother plant is shown in Figures 2 and 3, respectively. Our results show that chemical profiles of in vitro propagated plants were found similar to each other and to that of the mother plant assuring no somatic mutation occurred during the in vitro propagation process. Similarly, stevioside and rebaudioside A content in in vitro propagated plants were also highly comparable to each other and to that of mother plant. Out of seven randomly selected in vitro propagated plants tested, highest level of stevioside was found in plant ID P2 (5.40% ± 0.25%) and P3 (5.40% ± 0.19%) whereas, minimum level of stevioside was found in P7 (4.8 ± 0.21). On the other hand, rebaudioside A content was highest in plant ID P1 (3.42% ± 0.12%) and minimum in P6 (3.12% ± 0.22%). Stevioside and rebaudioside A content in the mother plant was tested 5.10% ± 0.09% and 3.16% ± 0.25%, respectively. These minor differences in stevioside and rebaudioside A content were found statistically significant (p < 0.05), showing a high level of homology in these plants in terms of their major secondary metabolites.
Further, in vitro propagated plants were also compared
Figure 2. Metabolic profiling of mother plant (MP) and few randomly selected tissue culture propagated plants (P1 - P7) of Stevia rebaudiana. SM: Standard mix of rebaudioside A (peak 1), stevioside (peak 2) and steviolbioside (peak 3).
Table 2. The effect of different auxinsconcentrations on root induction from in vitro raised plants of Stevia rebaudiana.
Values are mean ± SE. n = 27. Mean values in each column followed by the same letters (superscript) do not differ statistically at p < 0.05. MS-Murashige and Skoog medium, 1/2 MS: Half strength MS medium, NGR: No growth regulator.
with mother plant for their gas and water vapour exchange characteristics at different light levels (Figure 4). The effect of different photon flux densities on photosynthesis (PN) is shown in Figure 4(a). Photosynthesis increased with increasing light intensity up to 1600 µmolm−2·s−1 in mother plant as well as in vitro propagated plants. Maximum rate of photosynthesis (PN max) was recorded to be 15.01 ± 0.13 µmolm−2·s−1 for the mother plant, whereas it was found to be slightly higher 16.28 ± 0.29 for in vitro propagated plants. Light saturation for PN was recorded in the range of 1600 to 1800 µmolm−2·s−1. CO2 exchange was found to be adversely affected by light intensities 1800 µmolm−2·s−1 in mother plant as well as in vitro propagated plants. The rate of transpiration (TR) increased considerably, with an increase in light intensity (up to 2000 µmolm−2·s−1) in both (the mother and in vitro propagated) types of plants (Figure 4(b)). Contrary to TR, stomatal conductance (gs) was recorded highest at lowest light intensity for both mother (320 ± 23 µmol·mol−1) and in vitro propagated (327 ± 15 µmol·mol−1) plants (Figure 4(c)). A gradual decrease in gs was observed in both types of plants with increasing light levels up to 2000 µmolm−2·s−1. Similarly, intercellular CO2 concentration (Ci, Figure 4(d)) and the ratio of intercellular CO2 concentration to ambient CO2 concentration (Ci/Ca, Figure 4(e)) were recorded highest at lowest light intensity. A sudden decrease in Ci was observed with an increase in light intensity from 200 to 400 µmolm−2·s−1 and then became nearly constant in both types of plant at the light intensities higher than 400 µmolm−2·s−1. On the other hand, a gradual decrease in Ci/Ca was observed in both types of plants with increasing light intensity up to 1000 µmolm−2·s−1 and formed a plateau at the light intensities higher than 1000 µmolm−2·s−1. A gradual increase in water use efficiency (WUE) in the mother plant and in vitro propagated plants was recorded with an increase in the light intensity up to 1400 µmolm−2·s−1 and maximum values (mother plant, 2.74 ± 0.10; in vitro propagated plants, 2.72 ± 0.18) were recorded at this light intensity (Figure 4(f)). A decline in WUE was observed at light intensities higher than 1400 µmolm−2·s−1 in both the sets of plants. Generally, a variation in the gas and water vapour characteristics reflects the adjustment of the plants to their respective growth environment. The data on gas and water vapour exchange for mother and in vitro propagated plants indicate that S. rebaudiana can survive light intensity of ~1600 µmolm−2·s−1 PPFD, generally encountered under outdoor conditions during sunny days. Our results show that PN, TR, Ci, Ci/Ca and WUE of in vitro propagated plants were highly comparable to their mother plant. Thus, in vitro propagated plants would appear to be “normal” in respect of functional characteristics examined. A comparable photosynthetic activity between mother plant and in vitro
(a)(b)
Figure 3. Percent (dry weight) Rebaudioside A (a) and Stevioside (b) content in the leaves of mother plant and fully developed randomly selected (P1 - P7, chemical profile are as shown in Figure 2) tissue culture raised plants of Stevia rebaudiana. n = 3 ± SE. LSD value (p < 0.05) is indicated by vertical bars.
(a)(b)(c)(d)(e)(f)
Figure 4. Comparison of gas and water vapour exchange characteristics of mother plant (MP, n = 9 ± SE) and tissue culture raised plants (TCRP, n = 18 ± SE) of Stevia rebaudiana. (a) PN, net photosynthesis; (b) TR, rate of transpiration; (c) gs, stomatal conductance; (d) Ci, intercellular CO2 concentration; (e) Ci/Ca, inter cellular CO2 concentration to ambient CO2 and (f) WUE, water use efficiency. LSD (p < 0.05) is indicated by the vertical bars.
propagated plants of same age has also been reported by Lata et al. [17], and Bag et al. [30] in Cannabis sativa and Dendrocalamus hamiltonii, respectively.
Comparison of leaf anatomical parameters of in vitro propagated plants and mother plant is shown in Table 3 and Figure 5. Average stomatal length, stomatal frequency, frequency of epidermis cells, stomatal index, width of adaxial epidermal cells, height and width of abaxial epidermal cells and, height and width of spongy parenchyma cells were measured slightly higher in the in vitro propagated plants, whereas, average stomatal width, thickness of leaf lamina, height of adaxial epidermal cells and, height and width of palisade cells were measured slightly higher in the mother plant as compared to the in vitro propagated plants. These differences, however, were not found statistically significant (Table 2, p < 0.05). Similarly, no qualitative differences were observed in leaf stomata, transverse section leaf midrib and leaf lamina between the mother plant and in vitro propagated plants (Figure 5).
Mother plant Tissue culture raised plant
(a)(b)(c)(d)(e)(f)
Figure 5. Leaf anatomical characteristics of mature mother plant (left column) and a representative tissue culture raised plant (right column). (a) and (b) leaf stomata, (c) and (d) transverse section of mature leaf, (e) and (f) transverse section of leaf lamina.
Table 3. A comparison in leaf anatomical parameters of mother plantand randomly selected fully developed tissue culture raised plants. n = 15 ± SE.
In conclusion, this study describes a rapid and highly efficient in vitro propagation protocol for S. rebaudiana. In vitro propagated plants appeared to be “normal” and highly comparable to each other and that of the mother plant in terms of their chemical profile, rebaudioside A and stevioside content, gas and water vapour exchange characteristics and in the leaf anatomy. The method therefore, can be used for mass propagation of S. rebaudiana for the industrial purpose.
4. Acknowledgements
This research was partially funded by a grant from the USDA, Agricultural Research Service Specific Cooperative Agreement No. 58-6408-7-012.
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NOTES
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