Abstract
Tinospora cordifolia is a prioritized medicinal plant and having an immense medicinal importance especially in Indian medicinal system. But this plant needs a regeneration protocol for its rapid propagation. An efficient regeneration protocol was developed for T. cordifolia using nodal explants. High frequency of multiple shoot formation was induced when the nodal segments were cultured on MS medium supplemented with BAP (1.0 mg L−1) and 2-iP (0.5 mg L−1). The highest mean number of shoots per nodal explant (7.9 ± 0.45) with highest shoot length (9.3 ± 0.48 cm) and 86% response were achieved on this media and hormonal concentration. The optimum rooting was obtained on ½ strength of MS medium augmented with IBA (0.5 mg L−1) with 8.3 ± 0.46 cm root length and 89% response. Micropropagated plantlets were found to be identical with the mother plant when clonal fidelity of these plantlets were analyzed with inter simple sequence repeat (ISSR) marker. The berberine content was analyzed through LCMS QToF and the highest amount was found in in vitro callus (19.8 µg/gm) followed by stem (9.3 µg/gm) and leaves of field-grown plants (8.4 µg/gm). Further, presence of berberine was confirmed by ESI–MS spectra with protonated molecular ions ([M + H]+) at m/z 336. Furthermore, MS–MS fragmentation pattern confirmed for the presence of berberine in both the samples. Both the spectra (standard and samples) showed common peaks for berberine in the form of protonated molecular ions ([M + H]+) at m/z 320, m/z 304, m/z 292, m/z 278 in MS/MS mode. The study revealed that developed protocol is potent for rapid mass propagation of this plant species with high accumulation of important secondary metabolite berberine.
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Introduction
Tinospora cordifolia (Willd.) Miers ex Hook. F. & Thoms is an important medicinal climber, found in tropical regions of India, China, Sri Lanka, and Bangladesh (Mittal et al. 2014). Besides, it is rich with a variety of natural chemical constituent’s viz., tinosporin, cordifolioside, magnoflorine, palmetine, isocolumbin, tinocordiside, glycoside, cordifolioside syringing (Nagarkar et al. 2013; Choudhry et al. 2014) and cures a number of ailments such as viral infections, cancer, diabetes, inflammation, neurological disorders, psychiatric problems, microbial infection, hyper tension and HIV aids (Jayaganthan et al. 2013; Nagarkar et al. 2013; Joladarash et al. 2014; Mittal et al. 2014). Recently, this plant species is extensively using to cure chikungunya and dengue. Many ayurvedic pharmaceutical industries are producing medicines using Giloy to cure these diseases.
Further, medicinal plants are becoming endangered at an increasing rate owing to urbanization, deforestation and uprooting of complete plants to procure plant extract for the production of medicines by pharmaceutical companies (Mohammed and Kumar 2012). Consequently, medicinal flora is decreasing at a faster rate from their natural habitat. Similarly, Tinospora cordifolia is an overexploited plant and listed in prioritized medicinal plant list by national medicinal plant board (NMPB) Govt. of India (Raghu et al. 2006; Kala and Sajwan 2007). Overexploitation of this plant species has led to its acute scarcity to meet the present-day demand. Plant tissue culture fulfills one of this demand and conserve this NMPB prioritized plant. Previously, few reports are available regarding the micropropagation of T. cordifolia through nodal segments but the produced regeneration protocols revealed comparatively less number of shoots and are unreliable due to less number of in vitro shoot propagation (Kumar et al. 2003; Raghu et al. 2006; Gururaj et al. 2007; Khanapurkar et al. 2012; Sivakumar et al. 2014).
In this research work, we have reported a competent, reliable and reproducible protocol for the in vitro regeneration of T. cordifolia using mature nodal explants. To date, none of the reported micropropagation protocols has assessed the genetic fidelity of tissue culture raised plants through Inter Simple Sequence Repeat (ISSR) marker. This study revealed that the tissue culture raised plants were identical with the donor mother plant. Besides, the berberine analysis has also been done to compare the produced amount of berberine in the in vivo leaf, stem, aerial roots and in in vitro regenerated calli of T. cordifolia by using LC–MS QToF technology.
Result and discussion
Micropropagation
In vitro regeneration was successfully achieved using mature in vivo nodal explant (1.0–1.5 cm long) of T. cordifolia through direct method of tissue culture (Fig. 1a–l). During the investigation, maximum numbers of shoots (3.9 ± 0.25) with 5.2 ± 0.41 cm shoot length were obtained on MS medium supplemented with BAP (1.0 mg L−1) (Table 1; Fig. 1a, b). Number of shoots as well as shoot length decreased as the concentration of BAP decreased/increased beyond 1.0 mg L−1 (Table 1). The multiplication of shoots using BAP has also been reported in T. cordifolia (Raghu et al. 2006) as well as in other medicinal plants such as Portulaca oleracea, Asparagus racemosus and Cedrela fissilis (Sharma et al. 2011; Thakur et al. 2015; Aragão et al. 2016) which supports the present results. In contrast to the above results, Faisal and Anis (2003) reported that Kn was optimum for in vitro shooting in Tylophora indica.
However, in addition to BAP, Kn, TDZ and 2-iP at their varied concentrations revealed variable shooting response (Table 1; Fig. 1b–g). The reports from Lindiro et al. (2013) in Chrysanthemum cinerariaefolium and Kher et al. (2014) in Pluchea lanceolata supported this result. In divergence to the reports on TDZ and 2-iP, Kn in Matthiola incana (Hesar et al. 2011) and BAP with NAA in Vigna subterranea (Kone et al. 2013) have also proved better for the multiplication of shoots.
Optimized concentration of BAP (1.0 mg L−1) when combined with optimized concentration of 2-iP (0.5 mg L−1) gave maximum number of shoots (7.9 ± 0.45) (Table 1; Fig. 1h, i). Moreover, the length of shoots was higher on the same medium with hormones utilized for the multiplication of shoots in previous experiment (Fig. 1h). Similar response of BAP in combination with 2-iP for shoot multiplication has also been reported in Croton scabiosus (Salamma and Rao 2014). On contrary to the above result, optimum shoot multiplication was obtained on MS medium fortified with a combination of BAP and Kn in Momordica balsamina and T. cordifolia (Thakur et al. 2011; Sivakumar et al. 2014), TDZ and NAA in Melastoma malabatricum (Ghimire et al. 2016). In vitro raised elongated shoots (9.3 ± 0.48 cm) were transferred onto root induction medium composed of full, ½ and ¼ strength of MS salts. Only half strength of MS medium fortified with IBA (0.5 mg L−1) gave optimum rooting (Table 2; Fig. 1j, k). IAA (0.1–1.0 mg L−1) did not produce positive response for rooting. In vitro rooting on ½ MS medium supplemented with IBA is also supported by the earlier workers on the same hormone and medium in various plants T. cordifolia, Dioscorea remotiflora and Leptadenia reticulate (Gururaj et al. 2007; Bernabe-Antonio et al. 2012; Rathore and Shekhawat 2013). Higher concentration of IBA beyond 0.5 mg L−1 induced callusing at the lower end of stem and inhibited root growth in the culture. In contrast, IAA has also been reported for in vitro root formation in T. cordifolia, Lathyrus sativus and Bacopa monneri (Raghu et al. 2006; Barpete et al. 2014; Kapil and Sharma 2014).
After 3 weeks of sub-culturing onto rooting medium, lateral roots were produced. The complete plantlets were transplanted ex vitro and raised in earthen pots (Fig. 1l) containing sterilized garden soil, and cocopeat (2:1). The hardening and acclimatization was done by the procedure mentioned in “Materials and methods”. Approximately, 70% of plantlets survived well when transferred in natural environment.
Callus culture
Callus initiation was observed when inter nodal segments were inoculated on MS basal medium supplemented with various concentrations (0.5–8.0 mg L−1) of IBA, IAA, NAA, 2,4-D separately. Inter nodal segments when cultured horizontally on to MS medium supplemented with IBA at (0.5, 1.0, 2.0 mg L−1) started swelling followed by callus formation after 2 weeks of inoculation (Fig. 2a–d). The callus was green and fragile initially but after 1 week leaching of phenolic compounds was also observed, the secreted phenolic compounds retarded further growth of callus. This problem problem was overcome when the explants as well as the medium was treated with various adjuvant (PVP, activated charcoal, citric acid and ascorbic acid). When 3 weeks old callus was subcultured on MS medium fortified with IBA mg L−1 and PVP 0.1% (w/v) gave optimum results to control leaching and produced stock callus.
Green callus sub cultured on BAP (1.0 mg L−1) in combination with different cytokinin Kn (0.5–2.0 mg L−1), 2iP (0.5–2.0 mg L−1) and TDZ (0.5–2.0 mg L−1) and BAP (1.0 mg L−1) in combination with different auxin IAA (0.5–2.0 mg L−1) and (0.5–2.0 mg L−1) for indirect shoot induction from callus. No positive response revealed for indirect shoot induction from callus using any combination of hormones tested. Many combinations of cytokinins–cytokinins and auxin–cytokinins tested did not exhibited shoot.
Callus was reported from inter nodal segments in a number of plant species viz., Tectona grandis (Widiyanto et al. 2005), Mentha arvensis (Johnson et al. 2011), Dandrocalamus asper (Shroti et al. 2012), Satureja hortensis (Navroski et al. 2012), which are in favour of present results.
However, in contrast to our findings, Haque et al. (2008) reported callus induction through nodal explant in Cucurbita maxima and Benincasa hispida on MS medium supplemented with BAP + 2,4-D and BAP + NAA, respectively.
Histology
Histological changes during shoot bud differentiation from nodal segments cultured on BAP and 2-iP was studied in detail. Direct differentiation of shoot buds from nodal explants was observed on BAP (1.0 mg L−1) supplemented in MS medium. During the first week of culture, no apparent histological changes were observed. Well-developed shoot buds with subjacent leaf primordial started appearing in the 3rd–4th week of inoculation (Fig. 3a). The origin of shoot buds was direct as indicated by the presence of vascular connections with the mother tissue. Completely developed shoot buds were connected to the nodal segments. In the cultured nodes, at a later stage of development, vertical and lateral expansion of the meristematic zone occurred (Fig. 3b). A ring of multiple shoot primordia could be observed arising directly from the base of cultured nodal segments (Fig. 3a, b).
Molecular analysis
It is known that micropropagated tissues are easily exposed to somaclonal variations, especially during long-term cultures (Larkin and Scowcroft 1981). ISSR is the favored method used to determine the genetic stability of regenerated plants of T. cordifolia. The obtained band patterns were compared between randomly-selected in vitro regenerated and mother plants.
Among 20 ISSR primers selected for the PCR amplification, 9 produced distinct and scorable bands. A total of 774 amplicons were obtained and primer UBC 808 produced highly reproducible banding pattern with 6 bands (Table 3; Fig. 4). The number of bands amplified in each ISSR primer ranged from 4 to 6.
The ISSR analyses revealed that the in vitro derived plants of T. cordifolia exhibited same banding patterns as that of mother plants, confirming that no genetic variation occurred in the DNA of in vitro regenerated plantlets. Similarly, no genetic differences were reported in regenerated plantlets of Tylophora indica (Sharma et al. 2014).
Biochemical analysis
TLC of different extracts (leaf, stem, aerial roots and callus) revealed that berberine was biosynthesized in different plant parts of T. cordifolia (Fig. 5). The concentration of berberine was higher in the methanolic extract of in vitro raised callus of T. cordifolia as the intensity of the bands in TLC was higher than that of the methanolic extract of leaves and stem of field-grown plants. The berberine bands were absent in the methanolic extract of aerial roots.
Further confirmation and quantification of the berberine in the various plant parts was performed by UPLC-ESI/MS positive mode. Standard sample of berberine was used to construct a calibration curve by plotting peak areas versus the amount of berberine over a range of 50–1000 ng μL−1 (Fig. 6). The co-elution of other components of a complex biological sample matrix with the targeted compound can be checked by means of DAD spectral data acquisition.
The identification of berberine was confirmed on the basis of retention time and absorption spectra on UV-DAD (2.20 ± 0.1 min, 266 nm) (Fig. 7). The response was linear over the tested concentration range (Table 4) with the R 2 value of 0.9937 (Fig. 6). On the basis of the retention time and absorbance spectrum, berberine was detected in the plant extracts. Quantitative UPLC analysis of the callus extract showed that maximum berberine 19.8 µg/gm dry weight was produced in in vitro callus developed by inter nodal segments (Table 4; Fig. 7b). The concentration of berberine in stem (in vivo growing) was 9.3 µg/gm while in leaf (in vivo growing) it was 8.4 µg/gm (Table 4; Fig. 7c). Similar results of plant metabolites also reported earlier by Chaodhary et al. (2015) and Jain et al. (2016).
For further confirmation, standard berberine and plant samples were injected into ESI–MS in continuation with UPLC for their mass spectra. LC–ESI/MS is an ideal analytical method for alkaloid analysis (Gu et al. 2002; Wu and Prior 2005) as it can distinguish between monomers and oligomers (Gu et al. 2003; Kilambi et al. 2016; Nakata et al. 2016). The berberine content of T. cordifolia was determined by generating reconstructed ion chromatograms (RIC) (Fig. 8). RICs were obtained by filtering data for m/z ratios corresponding to singly charged [M + H]+. The MS study of the ions allowed the detection of berberine, in T. cordifolia, with protonated molecular ions ([M + H]+) at m/z 336 (Fig. 8). These compounds showed similar fragmentation patterns as compared to standard berberine compound. Based on the MS data, compound was considered to be berberine composed of C20H18NO4 + elements. Both the spectra (standard and samples) showed common peaks of fragments of berberine in the form of protonated molecular ions ([M + H]+) at m/z 320, m/z 304, m/z 292, m/z 278 in MS/MS mode (Fig. 9). Peak at m/z 320, 304, 292 and 278 are the characteristic fragments of berberine which confirms presence of berberine. Berberine has already been detected in T. cordifolia (Srinivasan et al. 2008) and other plant species viz., Berberis asiatica, Berberis aristata, Berberis lycium (Andola et al. 2010), Jeffersonia dubia (Jeong and Sivanesan 2016) by using different techniques like HPLC, HPTLC etc. This is the first report of analysis of berberine from T. cordifolia through LCMS to the best of our knowledge.
Materials and methods
Plant material
Stem cuttings were collected from Nursery, University of Rajasthan, Jaipur and established in Manipal University Jaipur campus garden for regular procurement of explants for tissue culture.
Different explants viz., nodal segments having axillary bud and inter nodal segments were collected from one year old plant. All explants were surface sterilized through standard surface sterilization method.
Culture media and growth conditions
Basal Murashige and Skoog (MS) medium was used for the study. Stock solutions of macro nutrients at 20× and 100× for micronutrients (Mo, Co, Co and Vitamins) were prepared. Beside MS salts, 3% sucrose as a carbon source and 0.8% agar–agar as a gelling agent were added. Subsequently, the nutrient medium was sterilized in autoclave at 121 °C and 15 psi pressure for 20 min.
The culture vials after inoculation were incubated at 25 ± 2 °C temperature under 16 h photoperiod with cool, white fluorescent lights (Philips India Ltd, Mumbai) of 25 μmol m−2 s−1 light intensity and 8 h dark cycle with 55 ± 5% relative humidity. All experiments were set with eight replicates and repeated at least thrice. Cultures were observed daily for the assessment of any morphological changes, if occurred in the cultures.
Micropropagation
Mature nodal segments (1.0–1.5 cm long) were inoculated vertically on MS medium augmented with different concentration of cytokinins viz., BAP, Kn, 2-iP and TDZ (0.5–8.0 mg L−1) separately to proliferate axillary buds to micro shoots. 3 weeks old in vitro raised shoots developed on MS medium fortified with BAP (1.0 mg L−1) singly were subcultured on MS medium supplemented with BAP (1.0 mg L−1) in combination with Kn (0.5–2.0 mg L−1), 2iP (0.5–2.0 mg L−1) and TDZ (0.5–2.0 mg L−1) for maximizing the number of shoots and length as well.
8–9 cm long in vitro shoots with three to four leaves were separated from shoot cluster and transferred on varied strength of MS salt medium (¼, ½ and full) fortified with IBA, IAA and NAA (0.1–2.5 mg L−1) singly for in vitro root development. Phytagel (0.3%) instead of agar–agar was used as gelling agent to get quality photographs of in vitro rooting. The complete plantlets were carefully taken out from culture vials and thoroughly washed with autoclaved distilled water and planted in earthen pots having a mixture of autoclaved garden soil and cocopeat (2:1). These plantlets were covered with inverted glass beakers to maintain high humidity. The plantlets were nourished by providing few drops of MS salt solution with water and kept in plant growth chamber for hardening. Gradually, these plants were acclimatized and transferred in natural environment. The 15 days old hardened plantlets were transplanted to field.
Callus culture
Inter nodal segments were inoculated on MS medium supplemented with various concentrations of different plant growth hormones including IBA, IAA, NAA and 2,4-D (0.5–8.0 mg L−1) separately for callus initiation. After one week of inoculation, explants showed swelling, curling from the cut ends and then the margins of explants turned into cluster of cells. 3–4 weeks old callus was subcultured on MS medium fortified with BAP (1.0 mg L−1) in combination with Kn (0.5–2.0 mg L−1), 2-iP (0.5–2.0 mg L−1) and TDZ (0.5–2.0 mg L−1) in combination for further organogenesis.
Leaching of phenolics
At the time of in vitro culture, growth of culture stopped due to leaching. Explant and medium both turned brown. To reduce it explants were socked in liquid mixture of adjuvant (PVP, activated charcoal, citric acid and ascorbic acid) and were cultured on MS medium containing adjuvant (PVP 0.1% w/w). These explants gave better results than untreated explants.
Histology
Histological changes were recorded for direct organogenesis in T. cordifolia. For which shoots at different developmental stages were used for histological studies. Shoots were preserved in FAA for 48 h for killing the microbes followed by fixation of the material in 70% alcohol. The fixed material was passed through dehydration and TBA-xylol series (Johanson 1940). Infiltration, embedding and blocks were prepared in paraffin wax. Serial Sections (10 μm) were cut with the help of a rotary microtome (Yorco, India) and these were fixed on the slides with the help of 4% formalin and Haupt's adhesive. The slides were dipped in pure xylene for dissolution of wax and were passed through an alcohol series. These slides were stained with 1% (w/v) safranine (Himedia, India) and again passed through an alcohol series for destaining. Finally, the sections were mounted in DPX (Merck, India) and observed under a photographic microscope (Olympus, India).
Analysis of clonal fidelity
To assess the genetic fidelity of the regenerated plantlets of T. cordifolia, DNA was extracted from the leaves of 17 randomly selected in vitro regenerated plants and from the leaves of 2-year-old mother plant (MUJ campus) by CTAB method (Doyle and Doyle 1990). The quantity and quality of extracted DNA samples were estimated by comparing with uncut lambda DNA of known concentration on agarose gel (molecular biology grade, Himedia, India).
For the optimization of ISSR reactions, DNA extracted from randomly selected in vitro plants and 20 oligonucleotide primers for ISSR analysis were used for PCR amplification reaction. The optimal annealing temperature was found to vary according to base composition of the primers. 20 ISSR primers (University of British Columbia, primer set no. 9, Vancouver, Canada) were initially screened to assess clonal fidelity of T. cordifolia. Amplification was carried out in 20 µL reaction volume containing 2.5 µg genomic DNA as template, 2.5 µL MgCl2, 0.5 µL of 100 µM dNTP, 2 µL of Taq buffer B (Exclude MgCl2), 2.5 µL of ISSR primer, 0.35 µL of Taq Nova DNA polymerase and MilliQ water to make up the final volume. PCR amplifications were performed with initial denaturation at 94 °C for 5.0 min followed by 35 cycles of denaturation at 92 °C for 1.0 min, annealing at temperature (depending on the primer Tm) for 1.0 min, extension at 72 °C for 2.0 min with a final extension at 72 °C for 7.0 min using DNA Engine (BioRad, Germany). The PCR products were separated on 1.5% agarose gel (Himedia, India) using 100 bp and 1 kb markers (Bangalore Genei, India) as the band size standard and photographed in a gel documentation system (Bio-Rad, Germany).
Biochemical analysis
Isolation of secondary metabolites from various plant parts (leaves, stem, aerial roots and callus) was performed using the method described by Sangwan et al. (2007). 2.0 g fresh harvested plant material (leaf, stem, aerial roots, callus) was extracted with 20 ml water and methanol in the proportion of 1:1 (v/v) in 100 ml Erlenmeyer flask on a orbital shaker at 20–30 rpm for 8 h and repeated thrice. The extracts in the solvent composition were recovered by filtration. All the three filtrates were pooled and subjected to liquid–liquid partition chromatography. The extract was treated with equal volume of n-hexane for 2 h in a separating funnel (250 ml) to remove the pigments and fatty acids. Meanwhile, solvents in separating funnel were mixed by vigorously stirring in every 20 min. The upper n-hexane layer was discarded and the process was repeated thrice. The defatted and depigmented extract was then pooled and evaporated to dryness at room temperature. The residue was dissolved in known volume (1 ml) of LCMS grade methanol and filtered through 0.22 μm filter (Millipore, India) prior to LCMS.
TLC
For TLC, 10 μL of each plant extract (leaves, stem, aerial roots and callus) and standard berberine was loaded on precoated silica gel G-60 plates using automated TLC sample injector (Linomat 5, Camag) and run in a solvent system consisting of Toluene: Formic acid: Water: Ethyl Acetate (5:1:1:3). Dry the plates and visualized under TLC visualizer (Camag) at 254 and 366 nm. The development of TLC plate was done with Dragandroff reagent (Bismuth sub-nitrate 1.7 g, glacial acetic acid 20 ml, water 80 ml and 50% solution of Potassium iodide in water 100 ml. mix together and store as stock solution. 10 ml of stock, 20 ml Glacial Acetic Acid and make up to 100 ml with water gives the working solution) followed by heating at 110 °C. After derivatization TLC plate was again visualized under TLC visualizer (Camag) at 366 nm and white light. Authentic berberine in the form of berberine chloride was used as marker.
LCMS
Chromatographic separation was performed on an Acquity UPLC system (Waters Corp., Milford, MA, USA) equipped with a PDA detector and HSS T3 column (50 mm × 1.0 mm, particle size 1.8 mm; Waters Corp.) applying the following binary gradient at a flow rate of 400 µL/min: 0–2 min, isocratic 90% A (water: formic acid, 99.9:0.1, v/v), 10% B (acetonitrile: formic acid, 99.9:0.1, v/v); 2 to 4 min, linear from 10 to 50% B; 4 to 5 min, isocratic 90% B; 5 to 6 min, isocratic 10% B. The injection volume was 10 µL (full loop injection). Eluted compounds were detected from m/z 100 to 1000 using a quadrupole time-of-flight (QTOF) mass spectrometer full scan (Waters Corp., Milford, MA, USA) equipped with an electron spray ion source (ESI) in positive ion modes using the following instrument settings: nebulizer gas, nitrogen, 1.6 bar; dry gas, nitrogen, 6 L/min, 190 °C; capillary, −5500 V (+4000 V); end-plate offset, −500 V; funnel 1 RF, 200 Vpp; funnel 2 RF, 200 Vpp; in-source CID energy, 0 V; hexapole RF, 100 Vpp; quadrupole ion energy, 5 eV; collision gas, argon; collision energy, 10 eV; collision RF 200/400 Vpp (timing 50/50); transfer time, 70 ms; pre-pulse storage, 5 ms; pulser frequency, 10 kHz; spectra rate, 3 Hz. Internal mass calibration of each analysis was performed by the infusion of 10 µL 10 mM Leucine Enkephalin in isopropanol: water, 1:1 (v/v), at a gradient time of 18 min using a diverter valve.
Berberine compound was characterized by UV–Vis spectra (266 nm), retention time relative to external standards, peak spiking, mass spectra, MS fragmentation patterns and spectra of isolated compounds from an in-house database and reference literature.
Data obtained from all experiments were presented as the mean ± standard error of three replications. Statistically significant differences were determined by analysis of variance (ANOVA) and the Duncan multiple range test (DMRT) at a P < 0.05 level of significance using SPPS.
Conclusion
In this study, high efficiency shoot regeneration was achieved from nodal segments of T. cordifolia. An average 7.9 ± 0.45 shoots with highest shoot length 9.3 ± 0.48 cm and 86% response were produced. The plants were successfully grown in the field. The ISSR analysis revealed that in vitro propagation did not induce any genetic changes in the regenerated plantlets. Besides, LCMS-QToF quantification of berberine showed that relatively high concentration of berberine is evaluated in the callus, which indicates that callus can be used as potential sources of the berberine instead of wild plants.
Abbreviations
- BAP:
-
6-Benzylaminopurine
- Kn:
-
6-Fufurylaminopurine
- 2-Ip:
-
N6-2-Iso-pentenyl adenine
- TDZ:
-
Thidiazuron
- 2,4-D:
-
Dichloroacetic acid
- IAA:
-
Indole-3-acetic acid
- IBA:
-
Indole-3-butyric acid
- NAA:
-
1-Naphtalenacetic acid
- ISSR:
-
Inter simple sequence repeat
References
Andola HC, Rawal RS, Rawat MSM, Bhatt ID, Purohit VK (2010) Analysis of Berberine content using HPTLC fingerprinting of root and bark of three Himalayan Berberis species. Asian J Biotechnol 2(4):239–245
Aragão VPM, de Souza Ribeiro YRD, Reis RS, Macedo AF, Floh EIS, Silveira V, Santa-Catarina C (2016) In vitro organogenesis of Cedrela fissilis Vell. (Meliaceae): the involvement of endogenous polyamines and carbohydrates on shoot development. Plant Cell Tissue Organ Cult 124:611–620
Barpete S, Khawar KM, Özcan S (2014) Differential competence for in vitro adventitous rooting of grass pea (Lathyrus sativus L.). Plant Cell Tissue Organ Cult 119(1):39–50
Bernabe-Antonio A, Santacruz-Ruvalcaba F, Cruz-Sosa F (2012) Effect of plant growth regulators on plant regeneration of Dioscorea remotiflora (Kunth) through nodal explants. Plant Growth Regul 68:293–301
Chaodhary B, Harit K, Mittal J, Jain R (2015) Analysis of steroidal lactones in Withania somnifera leaf and roots. Inte J Inst Pharma Life Sci 5(4):1–6
Choudhry N, Singh S, Siddiqui MB, Khatoon S (2014) Impact of seasons and dioecy on therapeutic phytoconstituents of Tinospora cordifolia, a Rasayana drug. Biomed Res Int 2014:1–11
Doyle JJ, Doyle JL (1990) Isolation of plant DNA from fresh tissue. Focus 12:13–15
Faisal M, Anis M (2003) Rapid mass propagation of Tylophora indica Merrill via leaf callus culture. Plant Cell Tissue Organ Cult 75:125–129
Ghimire BK, Seong ES, Nguyen TX, Yu CY, Kim SH, Chung Ill-Min (2016) In vitro regeneration of Melastoma malabatricum Linn. through organogenesis and assessment of clonal and biochemical fidelity using RAPD and HPLC. Plant Cell Tissue Organ Cult 124:517–529
Gu L, Kelm MA, Hammerstone JF, Beecher G, Cunningham D, Vannozzi S, Prior RL (2002) Fractionation of polymeric procyanidins from lowbush blueberry and quantification of procyanidins in selected foods with an optimized normalphase HPLC–MS fluorescent detection method. J Agric Food Chem 50:4852–4860
Gu L, Kelm MA, Hammerstone JF, Beecher G, Holden J, Haytowitz D, Prior RL (2003) Screening of foods containing proanthocyanidins and their structural characterization using LCMS/MS and thiolytic degradation. J Agric Food Chem 51:7513–7521
Gururaj HB, Giridhar P, Ravishankar GA (2007) Micropropagation of Tinospora cordifolia (Willd.) Miers ex Hook. F and Thoms-a multipurpose medicinal plant. Curr Sci 92:23–26
Haque ME, Sarkar MAR, Mahmud MA, Rezwana D, Sikdar B (2008) In vitro propagation of pumpkin and ash gourd through nodal segments. J Bio-sci 16:67–71
Hesar AA, Kaviani B, Tarang A, Zanjani SB (2011) Effect of different concentrations of kinetin on regeneration of ten weeks (Matthiola incana). POJ 4:236–238
Jain R, Kachhwaha S, Kothari SL (2016) In Vitro Shoot Cultures and Analysis of Steroidal Lactones in Withania coagulans (Stocks) Dunal. Protocols for In Vitro Cultures and Secondary Metabolite Analysis of Aromatic and Medicinal Plants, 2nd edn. Springer, New York, pp 259–273
Jayaganthan P, Perumal P, Balamurugan TC, Verma RP, Singh LP, Pattanaik AK (2013) Effects of Tinospora cordifolia supplementation on semen quality and hormonal profile in rams. Anim Reprod Sci 140:47–53
Jeong BR, Sivanesan I (2016) Micropropagation, berberine content and antitumor activity of Jeffersonia dubia (Maxim.) Benth et Hook. Plant Cell Tissue Org Cult 124:453–458
Johanson DA (1940) Plant microtechnique. MacGraw Hill, New York
Johnson M, Wesely EG, Kavitha MS, Uma V (2011) Antibacterial activity of leaves and inter-nodal callus extracts of Mentha arvensis L. Asian Pac J Trop Med 4(3):196–200
Joladarash D, Chilkunda ND, Salimath PV (2014) Glucose uptake-stimulatory activity of Tinospora cordifolia stem extracts in Ehrlich ascites tumor cell model system. J Food Sci Technol 51:178–182
Kala CP, Sajwan BS (2007) Revitalizing Indian systems of herbal medicine by the National Medicinal Plants Board through institutional networking and capacity building. Curr Sci 93:797–806
Kapil SS, Sharma V (2014) In vitro propagation of Bacopa monneri: an important medicinal plant. Int J Curr Biotechnol 2:7–10
Khanapurkar RS, Paul NS, Desai DM, Raut MR, Gangawane AK (2012) In vitro propagation of Tinospora cordifolia (Wild.) Miers ex Hook. F. Thoms. J Bot Res 3:17–20
Kher MM, Joshi D, Nekkala SK, Nataraj M, Raykundaliya DP (2014) Micropropagation of Pluchea lanceolata (oliver & hiern.) using nodal explant. J Hortic Res 22:35–39
Kilambi HV, Manda K, Sanivarapu H, Maurya VK, Sharma R, Sreelakshmi Y (2016) Shotgun Proteomics of Tomato Fruits: Evaluation, Optimization and Validation of Sample Preparation Methods and Mass Spectrometric Parameters. Plant Sci 7:969
Kone M, Kone T, Kouakou HT, Ochatt LS (2013) Plant regeneration via direct shoot organogenesis from cotyledon explants of Bambara groundnut, Vigna subterranea (L.) Verde. Biotechnol Agronom Soc Environ 7(4):584–592
Kumar S, Narula A, Sharma MP, Srivastava PS (2003) Effect of copper and zinc on growth secondary metabolites content and micropropagation of Tinospora cordifolia: a medicinal plant. Phytomorphology 53:79–91
Larkin PJ, Scowcroft WR (1981) Somaclonal variations—a novel source of variability from cell cultures for plant improvement. Theor Appl Genet 60:197–214
Lindiro C, Kahia J, Asiimwe T, Mushimiyimana I, Waweru B, Kouassi M, Koffi E, Kone S, Sallah YP (2013) In vitro regeneration of pyrethrum (Chrysanthemum cinerariaefolium) plantlets from nodal explants of in vitro raised plantlets. IJAIEM 2:207–213
Mittal J, Sharma MM, Batra A (2014) Tinospora cordifolia: a multipurpose medicinal plant: a review. J Med Plants Stud 2:32–47
Mohammed SM, Kumar BV (2012) Over exploitation of medicinal plants a setback to gene pool. Int J Life Sci Pharma Res 4:177–180
Nagarkar B, Kulkarni R, Bhondave P, Kasote D, Kulkarni O, Harsulkar A, Jagtap S (2013) Comparative hepatoprotective potential of Tinospora cordifolia, Tinospora sinensis and Neem-guduchi. Br J Pharma Res 3:906–916
Nakata R, Kimura Y, Aoki K, Yoshinaga N, Teraishi M, Okumoto Y, Huffaker A, Schmelz EA, Mori N (2016) Inducible De Novo Biosynthesis of Isoflavonoids in Soybean Leaves by Spodoptera litura Derived Elicitors: Tracer Techniques Aided by High Resolution LCMS. J Chem Ecol. doi:10.1007/s10886-016-0786-8
Navroski MC, Waldow DAG, Pereira MO, Pereira AD (2012) Callus formation in vitro and internodal stem apices in savory = Calogênese in vitro de segmentos apicais caulinarese internodais em segurelha (Satureja hortensis L.). Revista Agro@Mbiente On-Line 6(3): 228–234
Raghu AV, Geetha SP, Martin G, Balachandran I, Ravindran PN (2006) In vitro clonal propagation through mature nodes of Tinospora cordifolia (WILLD.) HOOK. F. and THOMS: an important ayurvedic medicinal plant. In vitro Cell Dev Bio Plant 42:584–588
Rathore MS, Shekhawat NS (2013) Ex vivo implications of phytohormones on various in vitro responses in Leptadenia reticulata (Retz.) Wight. & Arn.—An endangered plant. Environ Exp Bot 86:86–93
Salamma S, Rao BRP (2014) In Vitro Propagation of Croton scabiosus Bedd. (Euphorbiaceae), an Endemic and Vulnerable Tree Species. J Adv Biotechnol 3:229–240
Sangwan RS, Chaurasiya ND, Lal P, Misra L, Uniyal GC, Tuli R, Sangwan NS (2007) Withanolide A biogeneration in in vitro shoot cultures of ashwagandha (Withania somnifera Dunal): a main medicinal plant in ayurveda. Chem Pharma Bull 55:1371–1375
Sharma MM, Singh A, Verma RN, Ali DZ, Batra A (2011) Influence of PGRS for the in vitro plant regeneration and flowering in Portulaca oleracea (L.): a medicinal and ornamental plant. Int J Bot 7:552–557
Sharma MM, Verma RN, Singh A, Batra A (2014) Assessment of clonal fidelity of Tylophora indica (Burm. f.) Merrill “in vitro” plantlets by ISSR molecular markers. SpringerPlus 3:2–9
Shroti RK, Upadhyay R, Niratkar C, Singh M (2012) Micropropagation of Dandrocalamus asper through inter nodal segment. BEPLS 1(4):58–60
Sivakumar V, Ranjan MSD, Sadiq AM, Jayanthi M (2014) In vitro micropropagation of Tinospora cordifolia (Willd.) Miers ex Hook. F. & Thoms-An important medicinal plant. J Pharmacog Phytochem 3:5–10
Srinivasan GV, Unnikrishnan KB, Shree ABR, Balachandran I (2008) HPLC estimation of berberine in Tinospora cordifolia and Tinospora sinensis. Indian J Pharm Sci 70(1):96–99
Thakur GS, Pandey M, Sharma R, Sanodiya BS, Prasad GBKS, Bisen PS (2011) Factors affecting in vitro propagation of Momordica balsamina: a medicinal and nutritional climber. Physiol Mol Biol Plants 17:193–197
Thakur S, Tiwari KL, Jadhav SK (2015) In vitro approaches for conservation of Asparagus racemosus Willd. In Vitro Cell Dev Biol Plant 51:619–625
Widiyanto SN, Erytrina D, Rahmania H (2005) Adventitious shoot formation on Teak (Tectona grandis L.f.) callus cultures derived from internodal segments. Acta Hort 692:153–157
Wu X, Prior RL (2005) Systematic identification and characterization of anthocyanins by HPLC-ESI-MS/MS in common foods in the United States: fruits and berries. J Agric Food Chem 53:2589–2599
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The authors are grateful to Prof. Sandeep Sancheti, President, Dean, FOS&RI and Director, School of Basic Sciences, Manipal University Jaipur, for providing necessary infrastructural facilities to carry out this research work.
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Mittal, J., Sharma, M.M. Enhanced production of berberine in In vitro regenerated cell of Tinospora cordifolia and its analysis through LCMS QToF. 3 Biotech 7, 25 (2017). https://doi.org/10.1007/s13205-016-0592-6
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DOI: https://doi.org/10.1007/s13205-016-0592-6