Cryopreservation of shoot apices and callus cultures of globe artichoke using vitrification method
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Cryogenic cooling became a crucial tool for the storage of heterozygous plants such as globe artichoke. This study was carried out to optimize a reliable method for in vitro cryopreservation of shoot apices and callus cultures of globe artichoke using dimethylsulfoxide (DMSO) and Plant Vitrification Solutions 2 (PVS2) as cryoprotectant solutions. Shoot apices were exposed to DMSO or PVS2 for 20, 40, 60, and 80 min prior to plunge in liquid nitrogen (LN).
It was found that using PVS2 as a cryoprotectant in cryopreservation of shoot apices of globe artichoke was more effective compared with using of DMSO alone. Among the exposure time tested, 60 min gave the best results of survival. The highest survival (60%), regeneration (56%), and proliferated shootlets (4.30) were obtained after cryoprotection with PVS2 for 60 min. Regarding callus cultures, the maximum values of fresh weights and subsequently growth value of recovered callus were registered with 40 min followed by 60 min exposure time. Related to the type of the tested cryoprotectants, the best survival and growth parameters of the cryopreserved callus cultures were obtained with PVS2 treatments. Treatment with PVS2 for 40 min registered the highest survival observations of cryopreserved callus. Also, the maximum values of fresh weight (1.30 g) and growth value (4.20) were obtained with 40 min exposure time. Microscopy analysis presented as cell morphology revealed that the treatment of PVS2 40% was the optimum for cell growth of cryopreserved callus of globe artichoke.
The results demonstrated that using PVS2 as a cryoprotectant in cryopreservation of shoot apices and callus cultures of globe artichoke was more effective compared with DMSO.
KeywordsCryopreservation Globe artichoke Tissue culture Vitrification
Plant Vitrification Solutions 2
Globe artichoke (Cynara scolymus L.) plant, the native to the Mediterranean area is cultivated for its nutritional and medicinal values. This species has a complex sexual reproduction. When they have been propagated by seed, the yield of their progeny is frequently different from that of the parental generation. Vegetative propagation using suckers and axillary buds is commonly used for multiplication of globe artichoke plant materials. However, the low rate of multiplication and the potential for disseminating diseases are two major factors that hinder the expansion and development of globe artichoke through vegetative propagation. Biodiversity of globe artichoke represents a valuable genetic resource that needs suitable propagation and conservation methods. At the present, artichoke germplasm is preserved in field as active and base collections which attacked by pests and pathogens, and entail high costs of labor and technical staff . The high variability of seeds, together with difficulties in the distribution and exchange of healthy plant material from field, support tissue culture and cryopreservation as being the best alternative approaches for germplasm conservation of globe artichoke. In vitro culture techniques have been used not only for clonal propagation and but also used for germplasm conservation . Medium-term preservation is achieved by reducing the growth of plant material, thus increasing intervals between subcultures. For long-term conservation, cryopreservation (liquid nitrogen, − 196°C) allows storing plant material without modification or alteration for extended periods and protected from contaminations. At this temperature, all cellular divisions and metabolic processes are stopped. It is worth to mention that cryopreservation of shoot tips is favoring for long-term and high genetic stability germplasm conservation. Otherwise, in vitro preservation of plant cells or callus cultures is a valuable tool not only for the conservation of genetic resources, but also to preserve plant materials in a form ready for further manipulations such as in vitro production of secondary metabolites . Cryogenic cooling is considered an effective option for long term-storage of undifferentiated plant cells as a source of phytochemicals and for other manipulations.
Cryopreservation methods are different and include the older classic methods based on freeze-induced dehydration of cells as well as newer methods based on vitrification. Vitrification involves treatment of plant samples with cryoprotective substances, dehydration with highly concentrated solutions, rapid cooling and rewarming, removal of cryoprotectants, and recovery. This procedure has been developed for shoot apices and somatic of many plant species [4, 5]. However, classical techniques have been applied to undifferentiated cultures, such as cell suspension cultures and calli. In vitrification technique, the cryoprotectant molecules provide the optimum cellular cryoprotection environment of plant cells. In this respect, dimethylsulfoxide (DMSO) is the most common chemical pretreatment. It is used both for pregrowth and during cryoprotection [6, 7]. DMSO reduces the electrolytic concentration in the residual chilled contents in and around of a biological cell, during cryopreservation. Practically, PVS2 (Plant Vitrification Solution n° 2) consists of 30% glycerol, 15% ethylene glycol, 15% dimethylsulfoxide (DMSO) (all v/v), and 0.4 M sucrose is the most applied solution . This solution is more effective for dehydration and less toxic to plant material . For successful vitrification procedures, it is essential to carefully control the cryoprotectant to provide enough dehydration while at the same time preventing injury caused by chemical toxicity and sudden osmotic stress . This study aimed to develop a simple and efficient cryopreservation method for long-term storage of shoot apices and callus cultures of globe artichoke using DMSO and Plant Vitrification Solutions 2 (PVS2) as cryoprotectants.
Establishment in vitro cultures
Shoot apices (1 cm) and callus inocula (250 mg) of globe artichoke taken from in vitro grown cultures (after the third subculture) were used as explants for cryopreservation experiments. The explants were precultured on filter-sterilized loading solution (2 M glycerol and 0.4 M sucrose dissolved in MS medium) using Petri dishes and incubated at 25 °C for 24 h. Shoot apices were directly immersed into the solutions, while callus inocula were wrapped in a small strip of sterilized cotton. After the loading treatment, the explants were transferred into 2 ml polypropylene sterile cryovials and exposed to 10% of dimethylsulfoxide (DMSO) in MS medium or Plant Vitrification Solutions 2 [PVS2; 15% (w/v) ethylene glycol, 15% (w/v) DMSO, 30% (w/v) glycerol, 0.4 M sucrose in MS medium, Sakai et al.  for different exposure times, i.e., 20, 40, 60, or 80 min at 0 °C. For each treatment at least ten cryotubes were employed. The explants were then suspended into cryotubes with 0.5 ml fresh of the two vitrification solutions and the tubes were directly immersed into liquid nitrogen (LN) (at − 196 °C) and kept for at least 48 h.
Thawing and recovery
After cryostorage, cryotubes were taken from liquid nitrogen container (Fig. 1c) and rapidly thawed in a beaker filled with sterile water at 40 °C for about 1.5 to 2 min until most of the ice has melted. After rewarming, the cryoprotection solution was removed from the cryotubes; the explants were rinsed with MS liquid medium for 20 min at room temperature and blotted on filter paper. Then, the explants were transferred onto recovery media [MS medium + 1 mg/l BA for shootlets regeneration (Fig. 1d) and MS medium + 0.1 mg/l NAA, 0.5 mg/l 2,4-D, and 0.5 mg/l kin for callus growth (Fig. 1e)], and then all the cultures were incubated under standard conditions of illumination and temperature.
Survival and regrowth of cryopreserved shoot apices
Assessment of survival percentages and regeneration of the cryopreserved shoot apices were carried out after four weeks of culturing on the recovery medium. The survival was recorded (after 2 weeks) based on visual observation as the formation of green tissue developing from the shoot apices (%, no of green shoot apices/total no of shoot apices in freezing × 100). Regeneration was recorded (after 4 weeks of culturing on recovery medium) when a minimum of two leaves arise from the emerging bud ((%, no of shoot apices that elongated or produced new shoots/total no of shoots × 100). Also, a number of proliferated shootlets was recorded after culturing for 12 weeks on the regeneration medium.
Survival and regrowth of cryopreserved callus cultures
Four weeks after inoculation on callus maintenance medium, survival was evaluated based on visual observation by examining the colors of callus cultures. The creamy ones (with increase of the volume) had survived; the brown ones had died. Also samples for each treatment were subjected to regrowth. Fresh weight and growth value of the survival callus cultures were determined after 8 weeks of inoculation.
To assess the damage caused by the pre-treatment and freezing process, sample of the cryopreserved callus exposed for different times (20, 40, 60, or 80 min) to PVS2 were taken and then fixed in Karnovsky’s solution  at room temperature before being washed in 0·05 m Sörensen phosphate buffer pH 72. Samples were progressively dehydrated through ethanol solutions to a final concentration of 100 % and then photographed under a light microscope (Nicon, Japan Labophot-2 Microscope) equipped with KL 2500 LCD light sources (Nicon, Japan) was used to analyze the cell growth.
Tissue culture medium and incubation conditions
Tissue culture media were solidified with 0.7% agar and supplemented with 30 g/l sucrose, 100 mg/l myo-inositol, 1 mg/l pyridoxine-HCl, 1 mg/l nicotinic acid and 0.2 mg/l thiamine-HCl. The pH was adjusted to 5.8 before autoclaving at 121 °C and 1.5 Ib/M2 for 25 min. In all treatments, the growth regulators were added to the culture medium prior to autoclaving. Cultures were normally maintained at 25 ± 2 °C and 16 h photoperiod provided by white fluorescent tubes (3000 lux light intensity).
Experimental design and statistical analysis
The experiments were set up as a separate completely randomized design and repeated two times using. Data were statistically analyzed using standard error (SE) according to the method described by Snedecor and Cochran . The results are presented as means of 25 replicates.
Cryopreservation of shoot apices
Effect of exposure to dimethylsulfoxide on recovery
Effect of exposure time to dimethylsulfoxide on recovery of cryopreserved shoot apices of globe artichoke.
Exposure time (min)
Number of proliferated shootlets
2.70 ± 0.05
3.50 ± 0.12
3.00 ± 0.10
2.50 ± 0.15
Effect of exposure to PVS2 on recovery
Effect of exposure time to PVS2 on recovery of cryopreserved shoot apices of globe artichoke
Number of proliferated shootlets
3.00 ± 0.10
4.00 ± 0.17
4.30 ± 0.12
3.50 ± 0.20
Cryopreservation of callus cultures
Effect of exposure to dimethylsulfoxide on regrowth
Regrowth of cryopreserved callus of globe artichoke exposed for different time to dimethylsulfoxide
0.80 ± 0.11
1.00 ± 0.15
0.60 ± 0.20
0.25 ± 0.01
Effect of exposure to PVS2 on regrowth
Regrowth of cryopreserved callus of globe artichoke exposed for different time to PVS2.
1.00 ± 0.11
1.30 ± 0.10
1.10 ± 0.15
0.70 ± 0.12
The vitrification protocol can be used for the wide range of species with complex tissue structure such as shoot tips and embryos which contain a variety of cell types . In this technique, tolerance to cryoprotectant solutions is acquired by optimizing the pre-conditioning and loading treatments, as well as the duration of exposure to the solution. In this respect, DMSO alone, at a concentration of 5–10%, is often reported as a cryoprotectant [17, 18, 19]. Other authors prefer combinations of cryoprotectants at lower concentrations, considering this approach more beneficial than a single cryoprotectant at high concentration. Usually, dimethyl sulfoxide is the main penetrating colligative cryoprotectant and it may be combined with non-penetrating osmotically active additives such as sugars, polyethylene glycol, and polyvinylpyrrolidone . The most widely vitrification procedure is the treatment with PVS2 solution for periods ranging from 30 to 90 min . Due to possible toxic effects of the PVS2 solution which can compromise plant cell viability, the exposure time is a fundamental parameter which must always be optimized. In this context, shoot tips, which consist of small and dense cells with low water content, are often chosen as basic plant material for cryopreservation, but they are also widely used due to their high genetic stability.
In the present work, time of exposure to DMSO or PVS2 showed statistical differences in recovery (survival and regeneration percentages as well as number of proliferated shootlets) of cryopreserved shoot apices of globe artichoke. Among all exposure time tested, 60 min resulted in the highest recovery parameters. The results also, demonstrated that using of PVS2 as cryoprotectant in cryopreservation of shoot apices of globe artichoke was more effective comparing with using of DMSO alone. The positive found effect of PVS2 may be due to higher dehydration obtained by the combination of four compounds, glycerol, ethylene glycol, DMSO, and sucrose. The reduction in regeneration compared to survival percentage may be attributed to partial damage of the cells due to osmotic shock or dehydration. It is important to mention that there was no survival following cryopreservation without treatment with cryoprotectants either DMSO alone or PVS2 solution (in primary experiments). It is apparent from the results that, in addition to the type of cryoprotectant, the treatment time also played an important role in survival. The present results are accordance with those obtained by Tavazza et al. . In their study on cryopreservation (based on vitrification) of globe artichoke shoot tips of two spring cultivars “Grato 1” and “Campagnano” they reported that the best survival percentage of cryopreserved shoot tips was 61% for “Grato1” and 55% for “Campagnano.” They added, 30 min exposure time is not effective in protecting the tips during cooling. Recently, Zhang et al.  optimized a method for cryopreservation of four Jerusalem artichoke cultivars using shoot tip explants. However, Sakai and Engelmann  reported that time duration of exposure to PVS2 was found critical for success of cryopreservation by vitrification-based cryogenic protocols and optimal time duration varies from cryogenic procedures and plant species. In this respect, Niino et al.  mentioned that the survival rate of the vitrified shoot tips of cherry cultivar Sendaiya increased gradually with the duration of exposure to PVS2 and reached the maximum value after 90 and 105 min of exposure. However, optimal time durations of exposure to PVS2 for shoot regrowth of cryopreserved buds of potato were 5–7 h .
In order to obtain successful survival callus cultures upon cryopreservation by vitrification, chemical compositions of the cryoprotectant and its exposure time should be optimized to dehydrate the cytoplasm without damaging plant cells. A mixture of cryoprotectants vitrifies easier upon direct immersion in liquid nitrogen compared to solutions with only one cryoprotectant in a higher concentration . In the present study, we measured the post cryopreservation growth presented as fresh weight and growth value to evaluate the morphogenetic capacity of cryopreserved callus cultures of globe artichoke. Our findings show that, with cryopreserved callus regrowth changed with respect to exposure duration to DMSO or PVS2. Exposure for 40 min to DMSO or PVS2 gave the best survival. Further, fresh weight and growth value took same trend. It was found that, exposure to PVS2 registered best survival and growth parameters of the cryopreserved callus cultures of globe artichoke comparing with DMSO. Accordingly, PVS2 appears to be more suitable than DMSO for the cryopreservation of globe artichoke callus. The positive role of PVS2 was also demonstrated on successful regeneration of cryopreserved Thymus moroderi Pau ex Martı´nez after exposure for 60 min  and 30 min . In contrast, Al-Bahrany and Al-Khayri  mentioned that DMSO is more suitable for the cryopreservation of date palm cv. Khalas as assessed by the amount of callus re-growth. In another species, Mathur et al.  reported that survival of cryopreserved embryogenic cultures of Pinus roxburghii was best achieved using 0.3 M sorbitol combined with 5% DMSO. In this respect, it has been demonstrated that embryogenic callus and cell cultures survived after being subjected to a number of cryoconservation treatments including conventional cryoprotection with dimethylsulfoxide (DMSO) followed by slow cooling , vitrification followed by fast cooling [8, 9], as well as other simplified procedures [29, 30]. On the other hand, cryoprotectant solution has been found to have characteristic temperature dependent exposure time. It is 3 min at 25 °C for cultured cells of navel orange , 7.5 min at 0 °C for rice embryogenic cells , and 15 min at 0 °C for meristems of white clove . The morphological data presented as cell shape confirm our quantitative result of the growth value. Such cell morphological and structural parameters were used to determine cell damage of cryopreserved plant tissues .
Our findings revealed that PVS2 solution was more effective for cryoprotection of in vitro grown tissue cultures of globe artichoke. Treatment with PVS2 for 60 min resulting in highest survival and well-developed shootlets of cryopreserved shoot apices. However, 40 min exposure to PVS2 was enough for successful cryopreservation of callus cultures.
Authors gratefully acknowledge National Research Center, Egypt, for support the current study.
SB contributed to the design of the research work and wrote the manuscript. VS analyze and interpreted the data. HME contributed to the microscope analysis and preparation of data. AE helped in the tissue culture and cryopreservation experiments. All authors have read and approved the manuscript and ensure that this is the case.
There were no funding sources to support this work.
Ethics approval and consent to participate
Consent for publication
The authors declare that they have no competing interests.
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