In vitro and ex vitro evaluation of long-term micropropagated turmeric as analyzed through cytophotometry,phytoconstituents, biochemical and molecular markers

Turmeric (Curcuma longa L.), a high valued medicinal plant, was micropropagated through induction of multiple shoots using latent axillary buds of rhizome. Cytophotometric and random amplified polymorphic DNA (RAPD) as well as inter simple sequence repeats (ISSR) analysis were used to periodically monitor the genetic stability of micropropagated clones of Curcuma longa conserved in vitro up to 7 years at every 6 months interval. A total of eighteen RAPD and eight ISSR primers gave 45,537 distinct and reproducible bands, monomorphic across all 353 plants analyzed. Micropropagated turmeric after being conserved for 7 years in vitro was transplanted into soil in field. Drug yielding potential of tissue culture derived plants was evaluated in field through estimation of phytoconstituents like curcumin and essential oil contents. The result of 2 years of field trial showed that micropropagated turmeric retained stability in all the characteristics examined when compared with the field performance of conventionally propagated plants. Thus long term conservation of an elite genotype of turmeric with epigenetic and genetic stability is significant for stable supply of drug i.e., curcumin and essential oil to the market.     

Chemical composition of turmeric oil--a byproduct from turmeric oleoresin industry and its inhibitory activity against different fungi

Curcumin, the yellow coloring pigment of turmeric is produced industrially from turmeric oleoresin. The mother liquor after isolation of curcumin from oleoresin known as curcumin removed turmeric oleoresin (CRTO) was extracted three times with n-hexane at room temperature for 30 min to obtain turmeric oil. The turmeric oil was subjected to fractional distillation under vacuum to get two fractions. These fractions were tested for antifugal activity against Aspergillus flavus, A. parasiticus, Fusarium moniliforme and Penicillium digitatum by spore germination method. Fraction II was found to be more active. The chemical constituents of turmeric oil, fraction I and fraction II were determined by GC and identified by GC-MS. Aromatic turmerone, turmerone and curlone were major compounds present in fraction II along with other oxygenated compounds.     

Boron Deficiency Induced Changes in Translocation of 14CO2-Photosynthate Into Primary Metabolites in Relation to Essential Oil and Curcumin Accumulation in Turmeric (Curcuma longa L.)

Changes in leaf growth, net photosynthetic rate (P _N), incorporation pattern of photosynthetically fixed ¹⁴CO₂ in leaves 1–4 from top, roots, and rhizome, and in essential oil and curcumin contents were studied in turmeric plants grown in nutrient solution at boron (B) concentrations of 0 and 0.5 g m^-3. B deficiency resulted in decrease in leaf area, fresh and dry mass, chlorophyll (Chl) content, and P _N and total ¹⁴CO₂ incorporated at all leaf positions, the maximum effect being in young growing leaves. The incorporation of ¹⁴CO₂ declined with leaf position being maximal in the youngest leaf. B deficiency resulted in reduced accumulation of sugars, amino acids, and organic acids at all leaf positions. Translocation of the metabolites towards rhizome and roots decreased. In rhizome, the amount of amino acids increased but content of organic acids did not show any change, whereas in roots there was decrease in contents of these metabolites as a result of B deficiency. Photoassimilate partitioning to essential oil in leaf and to curcumin in rhizome decreased. Although the curcumin content of rhizome increased due to B deficiency, the overall rhizome yield and curcumin yield decreased. The influence of B deficiency on leaf area, fresh and dry masses, CO₂ exchange rate, oil content, and rhizome and curcumin yields can be ascribed to reduced photosynthate formation and translocation.     

In vitro induction, screening and detection of high essential oil yielding somaclones in turmeric (Curcuma longa L.)

Leaf of turmeric contains an essential oil used extensively in perfumery, pharmaceuticals and aromatherapy. Five somaclones were induced in turmeric on MS media with varying amounts of plant growth regulators. All somaclones were subsequently transferred to the field. Essential oil was extracted from leaves of in vitro and ex vitro grown plants and subjected to quantitative and qualitative evaluation. A positive correlation was established between the leaf oil content and oil constituent of in vitro grown and field transferred somaclones. Somaclones (C2, C4, C5) containing 0.16–0.18 % oil in vitro retained normal oil content (0.48–0.5 %) in the field. Similarly in vitro grown somaclones C3 and C7 with 0.36 and 0.25 % oil content retained proportionately increased oil yields of 1 % and 0.76 under ex vitro condition. GC–MS analysis of the oil revealed similar spectrum of constituents both among in vitro and ex vitro grown plants with alpha-phellandrene as major one. Thus the novel method of in vitro screening could be applied for rapid identification of high essential oil yielding turmeric genotypes thereby reducing labour, cost and time required in conventional ex vitro screening of somaclones.     

Polymeric nanoparticle-encapsulated curcumin ("nanocurcumin"): a novel strategy for human cancer therapy

Background  

Curcumin, a yellow polyphenol extracted from the rhizome of turmeric (Curcuma longa), has potent anti-cancer properties as demonstrated in a plethora of human cancer cell line and animal carcinogenesis models. Nevertheless, widespread clinical application of this relatively efficacious agent in cancer and other diseases has been limited due to poor aqueous solubility, and consequently, minimal systemic bioavailability. Nanoparticle-based drug delivery approaches have the potential for rendering hydrophobic agents like curcumin dispersible in aqueous media, thus circumventing the pitfalls of poor solubility.     

Fungal endophytes of turmeric (<Emphasis Type="Italic">Curcuma longa</Emphasis> L.) and their biocontrol potential against pathogens <Emphasis Type="Italic">Pythium aphanidermatum</Emphasis> and <Emphasis Type="Italic">Rhizoctonia solani</Emphasis>

Endophytic fungi have been isolated from the healthy turmeric (Curcuma longa L.) rhizomes from South India. Thirty-one endophytes were identified based on morphological and ITS–rDNA sequence analysis. The isolated endophytes were screened for antagonistic activity against Pythium aphanidermatum (Edson) Fitzp., and Rhizoctonia solani Kuhn., causing rhizome rot and leaf blight diseases in turmeric respectively. Results revealed that only six endophytes showed >?70% suppression of test pathogens in antagonistic dual culture assays. The endophyte T. harzianum TharDOB-31 showed significant in vitro mycelial growth inhibition of P. aphanidermatum (76.0%) and R. solani (76.9%) when tested by dual culture method. The SEM studies of interaction zone showed morphological abnormalities like parasitism, shriveling, breakage and lysis of hyphae of the pathogens by endophyte TharDOB-31. Selected endophytic isolates recorded multiple plant growth promoting traits in in vitro studies. The rhizome bacterization followed by soil application of endophyte TharDOB-31 showed lowest Percent Disease Incidence of rhizome rot and leaf blight, 13.8 and 11.6% respectively. The treatment of TharDOB-31 exhibited significant increase in plant height (85 cm) and fresh rhizome yield/plant (425 g) in comparison with untreated control under greenhouse condition. The confocal microscopy validates the colonization of the TharDOB-31 in turmeric rhizomes. The secondary metabolites in ethyl acetate extract of TharDOB-31 were found to contain higher number of antifungal compounds by high resolution liquid chromatograph mass spectrometer analysis. Thereby, endophyte T. harzianum isolate can be exploited as a potential biocontrol agent for suppressing rhizome rot and leaf blight diseases in turmeric.     

Partitioning of 14C-Photosynthate of Leaves in Roots,Rhizome, and in Essential Oil and Curcumin in Turmeric (Curcuma longa L.)

Incorporation of photosynthetically fixed ¹⁴C was studied at different time intervals of 12, 24, and 36 h in various plant parts—leaf 1 to 4 from apex, roots, and rhizome—into primary metabolites—sugars, amino acids, and organic acids, and secondary metabolites—essential oil and curcumin—in turmeric. The youngest leaves were most active in fixing ¹⁴C at 24 h. Fixation capacity into primary metabolites decreased with leaf position and time. The primary metabolite levels in leaves were maximal in sugars and organic acids and lowest in amino acids. Roots as well as rhizome received maximum photoassimilate from leaves at 24 h; this declined with time. The maximum metabolite concentrations in the roots and rhizome were high in sugars and organic acids and least in amino acids. ¹⁴C incorporation into oil in leaf and into curcumin in rhizome was maximal at 24 h and declined with time. These studies highlight importance of time-dependent translocation of ¹⁴C-primary metabolites from leaves to roots and rhizome and their subsequent biosynthesis into secondary metabolite, curcumin, in rhizome. This might be one of factors regulating the secondary metabolite accumulation and rhizome development.     

High-frequency clonal propagation of <Emphasis Type="Italic">Curcuma angustifolia</Emphasis> ensuring genetic fidelity of micropropagated plants

A high-frequency clonal propagation protocol was developed for Curcuma angustifolia Roxb., a high valued traditional medicinal plant. Axillary bud explants of C. angustifolia were explanted on Murashige and Skoog (MS) medium fortified with 4.4–22.2 µM 6-benzyladenine (BA), 2.9–5.7 µM indole-3-acetic acid (IAA), 2.3–23.2 µM kinetin (Kin), 2.7–5.4 µM naphthalene acetic acid (NAA) and 67.8-271.5 µM adenine sulphate (Ads) in different combinations. The maximum number of shoots per explants (14.1?±?0.55) and roots per shoot (7.6?±?0.47) was achieved on media containing 13.3 µM BA, 5.7 µM IAA and 135.7 µM Ads. Stability in phytomedicinal yield potential of micropropagated plants was assessed through GC–MS and HPTLC. Gas chromatogram of essential oil of conventional and micropropagated plants of C. angustifolia had similar essential oil profile. HPTLC analysis of rhizome extracts of in vitro and field grown plants revealed no significant differences in the fingerprint pattern and in curcumin content. Genetic integrity of in vitro and field grown derived plants were evaluated with inter-simple sequence repeat (ISSR) primers and flow cytometry using Glycine max as an internal standard. A total of 1260 well resolved bands were generated by 12 ISSR primers showing monomorphic banding patterns across all plants analyzed. The mean 2C DNA content of conventionally and micropropagated plant was estimated to be 2.26 pg and 2.31 pg, respectively. As no somaclonal variations were detected in tissue culture plantlets, the present micropropagation protocol could be applied for in vitro conservation and large-scale production of C. angustifolia.     

Direct shoot regeneration from nodal,internodal and petiolar segments of <Emphasis Type="Italic">Piper longum</Emphasis> L. and in vitro conservation of indexed plantlets

Three explants namely, nodal, internodal and petiolar segments were used to establish in vitro cultures of Piper longum. Multiple shoots were induced on semi-solid Murashige and Skoog (MS) medium supplemented with 1 mg/l 6-benzyladenine (BA). Addition of ascorbic acid (40 mg/l) considerably reduced browning of tissue and medium. Best shoot regeneration was observed from petiolar explants and was, therefore, used for all further studies. An indexing method was introduced for checking bacterial contamination in well established shoot multiplication cultures. It was found that bacterial infection was quite high in shoots derived from nodal and internodal explants while it was least in those obtained from petiolar segments. Only shoots that indexed negative for endogenous bacteria were used for proliferation and in vitro conservation studies. At the end of 4 weeks in proliferation medium which consisted of MS supplemented with 0.5 mg/l BA and 40 mg/l ascorbic acid as many as 22 shoot buds of 41 mm length could be obtained. Shoot buds developed into clusters for ease of further proliferation. A step of shoot elongation for 2 weeks in liquid MS basal medium was found to be beneficial for getting long and healthy shoots for rooting. Single shoots were rooted in 0.25 mg/l indole butyric acid that could be successfully acclimatized under nethouse conditions. A conservation strategy was also developed. The shoot cultures could be maintained without subculturing for as long as 8 weeks in MS medium supplemented with 1 mg/l paclobutrazol (PBZ) and 40 mg/l ascorbic acid.     

Syntheses of Curcumin Bioconjugates and Study of Their Antibacterial Activities against beta-Lactamase-Producing Microorganisms.

In the present study curcumin bioconjugates, viz. di-O-glycinoylcurcumin (I), di-O-glycinoyl-C(4)-glycylcurcumin (II), 5'-deoxy-5'-curcuminylthymidine (5'-cur-T) (IV), and 2'-deoxy-2'-curcuminyluridine (2'-cur-U) (V) have been synthesized and characterized by elemental analysis and (1)H NMR. The turmeric peptide (Tp) was isolated from the aqueous turmeric extract of the turmeric rhizome. The antibacterial activity of these four bioconjugates and also of the turmeric peptide and sodium salt of curcumin (III) have been tested particularly for beta-lactamase-producing microorganisms.     

Micropropagation of <Emphasis Type="Italic">Swertia chirata</Emphasis> Buch.-Hams. ex Wall.: a critically endangered medicinal herb

An efficient in vitro plant regeneration protocol for Swertia chirata Buch.-Ham. ex Wall (Gentianaceae), a critically endangered Himalayan medicinal herb, was developed using shoot tip explants derived from in vitro grown seedlings. Media with 2% sucrose and various types of hormones markedly influenced in vitro propagation of S. chirata. An in vitro shootlet production system using Murashige and Skoog (MS) medium with various hormones such as BAP, KN and TDZ was established. BAP at 1.0 mg/l and KN, 0.1 mg/l induced highest number of multiple shoots (42.16 ± 1.05) per explant. Micro-proliferated shoots were transferred to elongation medium amended with GA₃ (0.1 mg/l) and hormone free basal medium, after which they were transferred to rooting medium. The highest frequency of rooting (22.48 ± 1.08) was obtained in half-strength MS medium supplemented with NAA, 0.1 mg/l after testing with different auxins at various concentrations within 4 weeks of transfer to the rooting medium. Hardening was successfully attained under controlled conditions inside the plant tissue culture room. This method could effectively be applied for the conservation and clonal propagation to meet the pharmaceutical demands.     

Micropropagation of an elite Darjeeling tea clone

Shoot cultures of Camellia sinensis (L.) O. Kuntz var. T-78, an elite Darjeeling tea clone, were established from cotyledonary nodes and shoot tips of germinated seedlings as well as from nodal explants of field grown plants. Shoot multiplication rate ranged from 4x in nodal explants to 35x in cotyledonary nodes after 18 weeks of culture. Rooting was achieved in 80–90% micro-shoots by either placing them on an inductive medium for 10 d and then transferring shoots to hormone-free medium, or by treating micro-shoots with a chronic dose of IBA (500 mg/l) for 30–40 min. Rooted plants were established in soil under glasshouse condition at 60% frequency after hardening phase of 4–6 weeks. The regenerated plants show a constant chromosome number of 2n=30 and are morphologically true to type. This procedure can be applied for conservation and utilisation of an elite clone of Darjeeling tea.     

In vitro conservation of oil palm somatic embryos for 20 years on a hormone-free culture medium: characteristics of the embryogenic cultures, derived plantlets and adult palms

This study was conducted over a period of 20 years, to assess the problems involved in developing subcultures over a very long period, of oil palm (Elaeis guineensis Jacq.) somatic embryos which were maintained in vitro on a Murashige and Skoog mineral-based culture medium, without growth regulators. Analysis of the proliferation rate of the embryogenic cultures, along with the survivability of the regenerated plantlets after their transfer into soil and of the flowering of the derived adult palms has been conducted for cultures maintained in vitro during 1 to 20 years. From the ninth year of maintenance, the tissue quality of the somatic embryos gradually began to decline. However, after more than 20 years, 30% of the 20 clones tested still continued to proliferate satisfactorily on the same maintenance medium, keeping their multiplication potential intact. Even though a depressive effect of the age of the lines has been observed on the survival capacity of plants under natural conditions, it is noteworthy that among the clones originating from 20-year-old cultures only eight of them (40%) have exhibited the “mantled” floral abnormality. Different hypotheses concerning the origin of the disruptions observed on the in vitro cultures, plantlets and adult palms that occur over a very long period of in vitro conservation are discussed.     

Substitution of benzyladenine with meta-topolin during shoot multiplication increases acclimatization of difficult- and easy-to-acclimatize sea oats (Uniola paniculata L.) genotypes

Benzyladenine (BA) is the only cytokinin to effectively induce shoot multiplication in vitro between genotypes of the important dune grass species Uniola paniculata (sea oats). However, a significant genotype-specific negative carryover effect of BA on ex vitro acclimatization has been observed. In the present study, the effects of multiplication media supplemented with meta-topolin (mT), a BA-analog, BA or no plant growth regulator, were compared on in vitro multiplication, rooting and ex vitro acclimatization using easy- and difficult-to-acclimatize sea oats genotypes. Both genotypes exhibited similar in vitro shoot dry weight, number of harvestable shoots and percent rooting when cultured under standard conditions (with 2.2 μM BA) or with an equimolar concentration of mT. In addition, both genotypes exhibited similar ex vitro leaf length and shoot production under these two culture conditions. However, ex vitro acclimatization of rooted microcuttings of the difficult-to-acclimatize genotype significantly increased when produced on shoot multiplication medium containing mT rather than BA. Meta-topolin concentrations 10 μM or greater were inhibitory to in vitro rooting and acclimatization ex vitro of both genotypes. Nevertheless, survival of the difficult-to-acclimatize genotype was significantly greater when cultured in the presence of 2.2 μM–30 μM mT, compared to 2.2 μM BA. Therefore, a potential solution to overcome the detrimental BA carryover effect on ex vitro survival in sea oats is the substitution of BA with 2.2 μM mT for Stage II shoot multiplication. Use of mT may provide an efficient method to ensure in vitro propagation of a large number of diverse sea oats genotypes for dune restoration.     

Cryopreservation of embryogenic cell suspensions of <Emphasis Type="Italic">Catharanthus roseus</Emphasis> L. (G) Don.

The present study describes the potential of in vitro grown adventitious roots of Hypericum perforatum L. commonly known as St. John’s wort at low nutrient and auxin levels in the liquid medium for micropropagation. Roots were regenerated from shoot-derived callus on MS medium containing 4.0 mg l⁻¹ Indole-3 acetic acid (IAA). IAA and Indole-3 butyric acid (IBA) were equally effective for the induction of roots from shoot cultures. Half strength MS medium containing 1.0 mg l⁻¹ IAA was most found suitable for culturing roots in liquid medium. A total biomass of 4.13 ± 0.67 g comprising 226 ± 34.4 shoots and shoot buds along with roots was obtained per culture starting with 200 mg roots inoculum. Pretreatment with kinetin (2.0 mg l⁻¹) enhanced the shoot multiplication. Shoots proliferated profusely from excised roots in static liquid medium supported with glass bead matrix. Growtek^™ vessel was found suitable and cost effective system for high throughput plantlet production. In vitro grown roots regardless of their source of origin were an excellent and easy to handle source of explant for aseptic production of plantlets without loosing the morphogenetic potential over the generations. The plants exhibited 84–99% similarity among themselves through RAPD. The in vitro shoots produced can either be multiplied or rooted perpetually, and alternatively they can also be explored for the in vitro production of hypericin and hyperforin.     

In vitro propagation and rhizome formation in Curcuma longa Linn

Turmeric (Curcuma longa Linn.) which is cultivated by underground rhizomes is a slow propagating species. Multiplication and callus induction starting from the rhizome buds and shoot tips of C. longa in MS medium was carried out. A combination of naphthalene acetic acid (NAA; 1.0 mg/l) with kinetin (Kn; 1.0 mg/l) or NAA (1.0 mg/l) with 6-benzylaminopurine (BAP; 2.0 mg/l) was optimum for rapid clonal propagation of turmeric. A concentration of 2.5-3.0 mg/l of 2,4-dichlorophenoxy-acetic acid (2,4-D) was found to be optimum for callus induction. Regeneration of plantlets from a callus was successfully conducted in MS medium supplemented with standard growth hormones for multiplication at 25 +/- 2 degrees C under a 16 h photoperiod. These plantlets were successfully transferred to the field. Plantlets (4-month-old) were incubated in a medium containing different concentrations of sucrose supplemented with NAA (0.1 mg/l) and Kn (1.0 mg/l) at 27 +/- 2 degrees C under an 8 h photoperiod for induction of rhizomes. In vitro rhizome formation was observed in media containing 6 and 8% sucrose.     

Effects of temperature,illumination and node position on stem propagation of Miscanthus × giganteus

The sterile triploid Miscanthus × giganteus is capable of yielding more biomass per unit land area than most other temperate crops. Although the yield potential of M. × giganteus is high, sterility requires all propagation of the plant to be done vegetatively. The traditional rhizome propagation system achieves relatively low multiplication rates, i.e. the number of new plants generated from a single‐parent plant, and requires tillage that leaves soil vulnerable to CO₂ and erosion losses. A stem‐based propagation system is used in related crops like sugarcane, and may prove a viable alternative, but the environmental conditions required for shoot initiation from stems of M. × giganteus are unknown. A study was conducted to investigate the effect of temperature, illumination and node position on emergence of M. × giganteus shoots. Stems of M. × giganteus were cut into segments with a single node each, placed in controlled environments under varied soil temperature or light regimes and the number of emerged shoots were evaluated daily for 21 days. At temperatures of 20 and 25 °C, rhizomes produced significantly more shoots than did stem segments (P = 0.0105 and 0.0594, respectively), but the difference was not significant at 30 °C, where 63% of stems produced shoots compared to 80% of rhizomes (P = 0.2037). There was a strong positive effect (P = 0.0086) of soil temperature on emergence in the range of temperatures studied here (15–30 °C). Node positions higher on the stem were less likely to emerge (P < 0.0001) with a significant interaction between illumination and node position. Planting the lowest five nodes from stems of M. × giganteus in 30 °C soil in the light resulted in 75% emergence, which represents a potential multiplication rate 10–12 times greater than that of the current rhizome‐based system.     

‘Collar propagation’ as an alternative propagation method for rhizomatous miscanthus

The demand for perennial nonfood crops, such as miscanthus, is increasing steadily, as fossil resources are replaced by biomass. However, as the establishment of miscanthus is very expensive, its cultivation area in Europe is still small. The most common propagation method for miscanthus is via rhizomes, the harvesting of which is very labour‐intensive. Seed propagation is promising, but not suitable for sterile genotypes. In this study, a new vegetative propagation method, ‘collar propagation’, was tested in field and controlled environment studies. Collars are built at the junction between rhizome and stem. They can be harvested in a less destructive way than rhizomes by pulling out the stems from winter‐dormant miscanthus plants. One genotype of each of the species M. sacchariflorus, M. × giganteus, M. sinensis in combination with three fragment types (collars, rhizomes, collars + rhizomes) were tested for establishment success and plant performance. The performance (e.g. dry matter yield) of collar‐propagated plants was either better than or not significantly different from rhizome‐propagated plants. Pregrown plantlets transplanted into the field showed no significant differences in establishment success between the fragments within a genotype. When directly planted into the field however, the fragment ‘rhizome+collar’ had a significantly better establishment success than the other two. The winter survival rate of the fragment ‘rhizome+collar’ was 70% for M. sacchariflorus and 75% for M. × giganteus. Emergence success from collar‐derived plants was not affected by harvest date (harvested monthly from November to February). This study showed that miscanthus propagation via collars is feasible and a promising alternative to rhizome propagation, as the multiplication rate of collars is comparable to that of rhizome propagation. Collar propagation is the more suitable method for the tested genotypes of the species M. sachariflorus and M. × giganteus, but not for M. sinensis genotypes, which may be better propagated by seeds.