Carob (Ceratonia siliqua L.) is one of the important crops in terms of nutritional and medicinal value in the countries of Western Asia and North Africa. Despite the fact that some countries have used Carob in traditional medicines, the modern food industry began to discover the great potential of this plant which differentiates with antioxidant capacity as well as other important medicinal activities. Some of very few studies that have been reported on this important plant were published.
In the present study, micropropagation behavior and biochemical constituents of Ceratonia siliqua L. cultured on MS medium supplemented with different types and concentrations of cytokinins (0.0, 0.5, 1.0, or 1.5 mg/l BA, Kin, or TDZ and 0.2 mg/l NAA) under various light qualities ((white, green, blue, red, and yellow) were examined.
MS culture medium supplemented with BA produced the highest shootlets number/explants. For light quality, the data showed that green light increased shootlet number/explants, fresh and dry weights. However, yellow light increased shootlet length and leaves number and also caused significant increase in total phenols, flavonoids, and antioxidant capacity (DPPH) as compared to other lights. HPLC analysis showed that yellow light caused the highest accumulation of total phenolic and catechin that were the highest accumulated compounds (509 μg/ml) followed by that were accumulated under green light (412.68 μg/ml). Shootlets grown under white light (control) gave the highest accumulation of p-coumaric acid, rosmarinic acid, and cinnamic acid. Shootlets grown under blue light gave the highest accumulation of gentisic acid and syringic acid. Red light caused the highest accumulation of vanillic acid. However, white light accumulated the highest amount of flavonoid compounds comparing with other light qualities.
This study had reached to optimize a suitable micropropagation protocol of Ceratonia siliqua L. and characterization of biochemical constituents that can be beneficial for increasing its medical value which will help in food industries for commercial purposes.
Carob tree (Ceration siliqua L.) belongs to family Fabaceae. It is widely cultivated for its edible pod, and as ornamental tree in gardens (Girolamo and Laura 2002). It is used in reforestation action and its cultivation in modern orchards is being undertaken to value marginal lands and substitute for drought sensitive species (Sidina et al. 2009). The economic importance of this species comes from its industrial utilization. Pods and seeds of carob are used as raw material in food, pharmaceutical, and cosmetic industries (Barracosa et al. 2007). Propagation of Ceratonia siliqua by seeds does not ensure either the sex or the genetic characteristics of the ecotype (Barracosa et al. 2007). Using propagation by cutting has failed because rooting is difficult (Lee et al. 1997). So, using in vitro culture allows an alternate option for carob propagation (Romano et al. 2002), and is considered as a technique for the preservation of plant genetic material, the grown plant breeding program, and the fast production of large quantities of propagation materials (Mitrakos 1987). In this respect, many researches of Ceratonia siliqua micropropagation using various explants are available (Thomas and Metha 1983 and Romano et al. 2002). Using type and concentration of cytokinins were the most important factors affecting on shoot multiplication and the best multiple shoot response was obtained with using MS medium (Romano et al. 2002). Light quality was effective by modulated photoreceptors on shoot elongation and lateral branching through changing the concentration of plant hormones (Muir and Zhu 1983; Smith 1982). Plants have evolved a plethora of signal-transducing photoreceptors that regulate their growth and development in relation to the presence, amounts, direction, duration, and quality of light (Smith 1994; Quail 2002). Plant responses do not depend only on the absence or presence of light but also on the variations in light quality (Pedroso et al. 2017). Light quality has important effects on plant growth and development, especially for photosynthesis and photo morphogenesis, the two process that, through signals received by the photoreceptors, regulate plant growth, differentiation, and metabolism (Guo et al. 2007). Plant growth can be affected by endogenous hormone levels interactions with light quality. In this respect, Ou Yang et al. (2015) revealed that red and blue lights are associated with plant growth, development, and phytohormone metabolism. In addition, they reported that blue light promotes IAA accumulation and phenylpropanoid biosynthesis. In contrast, red light affects stem growth by regulating biosynthesis of GAs.
These experiments aimed to establish a micropropagation protocol that can be used in further studies for mass production of shootlets and secondary metabolites from Ceratonia siliqua L. plant.
Materials and methods
This investigation was carried out during the years 2018 and 2019 at Tissue Culture and Germplasm Conservation Research Laboratory, Horticulture Research Institute, Agriculture Research Center (ARC) and Tissue Culture Technique lab., Central laboratories, Department of Ornamental Plants and Woody Trees, National Research Center (NRC), Egypt on Ceratonia siliqua L. to optimize a micropropagation protocol and enhance biochemical synthesis.
Nodal segments of carob were excised from female juvenile suckers which were grown at Horticulture institute farm in March 2018. The explants were sterilized by 0.1% mercuric chloride (MC) for 10 min and cultured on free MS (Murashige and Skoog 1962) medium for 4 weeks (all explants survived and free contaminated).
Cuttings obtained from in vitro propagated shootlets at 2.0 cm long were excised and individually placed on 250 ml/jar containing 25 ml of MS basal medium supplemented with 25 g/l sucrose and solidified with agar (7 g/l). The pH of medium was adjusted to 5.7 ± 0.1 with HCL 0.1 N or NaOH 0.1 N before sterilization by autoclaving at 121 °C for 30 min. Growth regulators: 6-Benzylaminopurine (BAP), Thidizeron (TDZ), Kinetin (Kin), and naphthalene acetic acid (NAA) were added to the culture medium according to the experimental stage as follows:
The explants that survived and free contaminated were cultured on full MS medium supplemented with different types of cytokinins (BA, Kin, or TDZ) at various concentrations (0.0, 0.5, 1.0, or 1.5 mg/l) in combination with 0.2 mg/l NAA. After the third subculture, shootlet number/explants, shootlet length (cm), and leaves number/shootlet were recorded.
Cultures were incubated under 16:8 h photoperiod of cool-white light at 1250 lux during all stages.
The best multiplication medium (0.5 mg/l BA + 0.2 NAA) was used for testing the proliferation ability of in vitro cultures under different light qualities (white, green, blue, red, and yellow) using LED light source.
The shootlet number/explants, shootlet length (cm), leaves number/shootlet, fresh and dry weights (g), and the estimation of biochemical analysis were recorded after 1 month.
Spectrophotometer analysis for total phenolic content (TP), total flavonoid content (TF), and free radical scavenging activity were performed on jenway (6715, UK). For evaluation of TP, TF, and free radical scavenging activity of in vitro shoots, the samples were subjected to extraction according to the protocol described by Gabr et al. (2016). Total phenolic content was performed using Folin-Ciocalteu reagent according to the method reported by Velioglu et al. (1998) and was calculated using the following and expressed in mg gallic acid/I.
Total phenolic production (mg/l) = DW (g/l) × total phenolic content (mg/g).
Total flavonoid content was determined using aluminum chloride (ALCL colorimetric method reported by Chang et al. 2002) and expressed in mg quercetin/I.
For antioxidant activity determination, 2,2-diphenyl-1-picrylhydrazyl (DPPH) was used as described by Gabr et al. (2016).
HPLC analysis for phenolic and flavonoids was performed on an Agilent 1100 liquid chromatography with Zorbax SB-C18 Column. Samples (20 μl) were injected and analyzed at flow rate of 0.4 ml min at 35 °C. A gradient programme was used with 1% (V/V) aqueous phosphoric acid (eluent A) and 40% (V/V) aqueous acetonitrile (eluent B). The eluent was monitored at 254, 290, and 330 mm. The identification and quantification of phenolic acids were done by comparing retention time and area of the peaks in the extracts against that of the standard compounds. All standards were purchased from Sigma-Aldrich.
In all treatments, 25 explants in five replicates were used. The lay-out of the experiment was designed in complete randomized design and test least significant difference (LSD) at p ≤ 0.05 was used for comparison among means according to Steel and Torrie (1980).
Effect of different cytokinin types and concentrations on shooting behavior
Data in Table 1 clearly show the effect of fortified of MS medium with cytokinins different type (BA, Kin, or TDZ) at various concentrations (0.0, 0.5, 1.0, or 1.5 mg/l) with 0.2 mg/l NAA on behavior of shooting. The data clarified that explants cultured on MS medium supplemented with BA produced maximum shootlet number/explants at three concentrations (0.5 , 1.0, or 1.5 mg/l) which gave (2.75, 2.79, or 2.82 shootlet/explant, respectively). On the other hand, MS culture medium free of hormones reduced shootlet number/explants (2.20 shootlet) and led to the longest shootlets (2.35 cm). MS medium supplemented with 1.5 mg/l of TDZ increased leaves number/shootlet (3.60 leaf/shootlet).
Effect of light quality on in vitro growth behavior
Data in Table 2 and Fig. 1 indicated that incubation of cultures under different light qualities showed variations in in vitro growth of shootlets as well as fresh and dry weights of shootlets. Cultures that were incubated under green light produced highest values of shootlet number (3.34) and fresh and dry weights (5.04 and 1.83 g, respectively). On the other hand, cultures that incubated under yellow light produced longest shootlet and highest leaves number (3.82 cm and 5.02 leaf/shooltlet).
Total phenol and total Flavonoids content
Significant variances in total phenol content profile were shown by in vitro Ceratonia siliqua shootlets grown under different light spectrum. Plantlets grown under yellow light present the maximum level (27.59 mg/ml) (Fig. 2). Shootlets grown under yellow light showed the highest total phenol content (25.03 mg/ml), followed by green and red (22.58 and 20.49 mg/ml), respectively. While the lowest total phenol content level was shown with blue lights (16.78 mg/ml). Total flavonoids content showed (Fig. 3) the same as total phenol content, shootlets grown under yellow light presented the maximum level of total flavonoids content (826.069 μg/g DW). Red light accumulated high level of total flavonoids content compared with blue or green lights (626.69, 508.44, and 421.16 μg/g DW, respectively).
Antioxidant capacity DPPH
Shootlets grown under yellow light gave the highest antioxidant capacity (87.37%) compared with other light qualities as well as control (white light). Shootlets grown under red light gave the lowest antioxidant capacity (80.316%). Interestingly, a positive correlation was found between total phenol, total flavonoids, and antioxidant capacity. The different spectrum of lights induced a change in antioxidant activity in similar mode to that of total phenol, total flavonoids content, which signify that most of the phenolic and flavonoids compounds, in extract act as antioxidants.
Effect of light quality on phenolic and flavonoids compounds HPLC analysis
HPLC was used to identify 13 phenolic acids and seven flavonoids under the impact of five different light qualities (Table 3). The obtained results showed highly different amounts of the different identified phenolic acids. Yellow light promoted the accumulation of gallic acid, catechin, chlorogenic acid, and sinapic acid with high accumulation of total phenolic acids. While, white light (control) accumulated a high amounts of p-coumaric acid, rosmarinic acid, and cinnamic acid.
Results of flavonoids as shown in Table 4 showed that the highest value of rutin accumulated in shootlets subjected to blue light (22.16 μg/ml). White light improved the accumulation of all other flavonoids than other spectrum of light.
The present data in Table 1 were in agreement of those found by Saïdi et al. (2016) on carob and Sawsan and Zienab (2014) on Cephalotaxus Harrington; they reported that BAP (0.5 mg/l) with NAA (0.1 mg/l) stimulated better stem formation and those growth.
Data in Table 2 were confirmed by early results found by many reports (Gabryszewska and Rudnicki 1995; Bach and Malik 1999; Bach et al. 2000; Bach and Swiderski 2000; Witomska and Koszewska 2002) who mentioned that light quality significantly affected dry weight, plantlet height, and number of leaves. Red light significantly enhanced adventitious bud formation and shoot elongation in petunia and Gerbera, while blue light increased the number of adventitious buds and fresh weight of shoots on Freesia, Hyacinthus and Cyclamen.
Concerning results of total phenol and total flavonoids content (Figs. 2 and 3), Ardeleana et al. (2018) found that yellow light produced high levels of total phenol and total flavonoids in in vitro seedlings of Ocimum basilicum L. cultivar Aromat de Buzau than red or white lights. Our results indicated that red light is more effective than blue in production of total phenol content as well as total flavonoids content. Similarly, red light enhanced phenolic content in leaf of lettuce and total flavonoid content in Rehmannia glutinosa (Manivannan et al. 2015; Li et al. 2013). On the other hand, Bach et al. (2015) reported that red and blue light treatments did not induce any changes in the content of total phenolics between the studied cultivar sachenalia (Ronina and Rupert). Younas et al. (2018) reported that deviations in total phenolic and flavonoid contents reveal that light quality affect different plant species variably. Shiga et al. (2009) reported that white light enhanced phenolic content and antioxidant activity in Ocimumba silicum.
The results in Table 3 are in agreement with Leal-Costa et al. (2015). They found that yellow light improved the production of phenolic compounds in Phyllanthus tenellus grown in vitro. Likewise, Shiga et al. (2009) reported that white light enhanced accumulation of chicoric acid, romarinic acid, and caffeic acid in Ocimumba silicum. On the other hand, Bach et al. (2015) found that total production of phenolic compounds in Lanchenalia “Ronina” and “Rupert” in vitro cultures subjected to white and blue light varied from 1.1 to 2.0 mg/g dry weight and it was higher than lachenalia exposed to red light (0.5 mg/g dry weight). Szopa and Ekiert (2016) investigated the influenced of lighting conditions (far-red, red, blue, white, and darkness) on lignin and phenolic acids accumulation. They found that blue light was found to be the most effective lighting to the production of both groups of compounds. Their total amounts reached the maximum values of 376.41 mg/100 g dry weight and 46.57 mg/100 g dry weight, and were correspondingly 1.31 and 1.37 times greater than under white light. The amounts of individual compounds from the tested groups increased from 1.51 to 3.38 times (lignin), and from 1.74 to 2.72 times ( phenolic acids), depending on the lighting condition.
The results in Table 4 are in harmony with Pedroso et al. (2017) when studied the impact of five different lights on rutin accumulation in in vitro cultivated Hyptismarrubioides. They demonstrated the blue and white lights promoted the greatest rutin accumulation (0.30 and 0.31 mg g−1 of dry weight) after 30 days of irradiation. In line with these results, Thwe et al. (2014) reported that irradiation with blue light increased polyphenol content in lettuce and induced the production of rutin and cyaniding 3-0-rutinoside in Fagopyrum tataricum.
Investigation of growth regulators and light quality on in vitro culture of Ceratonia siliqua revealed that adding 0.5 mg/l BA with 0.2 mg/l NAA to MS medium produced large shootlet number/explant. For light quality, green light increased shootlet number/explant, fresh and dry weights. Besides that, yellow light increased total phenol, total flavonoids, and antioxidant capacity (DPPH) and increased accumulation of total phenolic acid and catechin.
Availability of data and materials
The datasets generated and/or analyzed during the current study are included in this published.
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The authors are greatly thankful to National Research Center, 33 El Bohouth St. (El Tahrir St.) Doki-Giza-Egypt and Horticulture Research Institute 9 El-Gmaa St. Giza Egypt for supporting this work.
This work was supported and funded by the National Research Centre. Project No. (11030152) under the title “Propagation of economic importance ornamental and woody plants using new applications.” during 2016/2019.
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Sayed, S.S., Gabr, A.M.M., Amin, M.A. et al. Biochemical characterization of micropropagated Ceratonia siliqua L. under effect of growth regulators and light quality. Bull Natl Res Cent 44, 26 (2020). https://doi.org/10.1186/s42269-020-0282-8
- Ceratonia siliqua L.
- In vitro growth