Cryopreservation of basal stem buds of in vitro-grown mat rush (Juncus spp.) by vitrification

An optimal protocol for the cryopreservation of in vitro-grown mat rush (igusa) buds by vitrification has been successfully developed. Established multiple stemmed cultures, which were induced in liquid MS medium containing 8.9 microM BA by roller culture, were cut into small clumps, plated on solid MS medium and cultured for three weeks at 25 degree C. Clumps that grew many buds were cold-hardened at 5 degrees C, with an 8 h photoperiod, for more than 30 d. The basal stem bud (1 to 2 mm long) was dissected from the clumps and precultured at 5 degrees C for 2 d on solid MS medium containing 0.3 M sucrose. The precultured buds were placed in 2 ml plastic cryotubes and osmoprotected with 1 ml loading solution containing 2 M glycerol and 0.6 M sucrose for 30 min at 25 degree C. Then they were dehydrated in 1 ml PVS2 solution at 25 degree C for 30 min and immersed in liquid nitrogen. Using this protocol, the survival level of cryopreserved igusa 'NZ219' buds reached 87 percent. This protocol was successfully applied to 42 different lines from three Juncus species, which had relatively high survival levels ranging from 30 to 90 percent and an average of 63 percent.     

Cryopreservation of lateral buds of in vitro-grown innala plants (Solemostemon rotundifolius) by vitrification

We succeeded in cryopreserving of innala (Solenostemon rotundifolius) in vitro-grown young lateral buds by vitrification. Nodal segments from in vitro-grown shoots (2-4 mm in length) were cultured on MS medium containing 0.1M sucrose in Petri dishes for 3 weeks under 16-h photoperiod at 25 degree C. This pre-growth induced a large number of uniform young lateral buds. Nodal segments (0.5 to 1.0 mm in length) with two lateral buds were dissected from the shoots and precultured with 0.3 M sucrose for 2 days at 25 degree C. They were then treated with loading solution containing 2 M glycerol and 0.4 M sucrose (LS solution) for 20 min at 25 degree C and dehydrated with the PVS2 vitrification solution for 18 min at 25(C prior to either rapid immersion in liquid nitrogen. Surviving lateral buds resumed growth within 3 days and developed shoots without intermediary callus formation. The average growth recovery after cryopreservation amounted to 85%.     

Cryopreservation of in vitro grown shoots of ginger (Zingiber officinale Rosc.)

An efficient cryopreservation technique for in vitro grown shoots of ginger (Zingiber officinale Rosc) was developed based on encapsulation dehydration, encapsulation vitrification and vitrification procedures. Pregrowth and serial preculture were needed to obtain the best regrowth for all techniques. The vitrification procedure resulted in higher regrowth (80%) when compared to encapsulation vitrification (66%) and encapsulation dehydration (41%). In the vitrification procedure shoots were: precultured in liquid Murashige-Skoog medium containing 0.3 M sucrose for 3 days; cryoprotected with a mixture of 5% DMSO and 5% glycerol for 20 min at room temperature; osmoprotected with a mixture of 2 M glycerol and 0.4 m sucrose for 20 min at 25 degrees C; before being dehydrated with a highly concentrated vitrification solution (PVS2) for 40 min at 25 degrees C. The dehydrated shoots were transferred to 2 ml cryotubes, suspended in 1 ml PVS2 and plunged directly into liquid nitrogen. In all the three cryopreservation procedures tested, shoots grew from cryopreserved shoot tips without intermediary callus formation. The genetic stability of cryopreserved ginger shoot buds were confirmed using ISSR and RAPD profiling.     

Cryopreservation of Citrus madurensis embryonic axes by vitrification: importance of loading and treatment with vitrification solution

This paper investigates the importance of loading and treatment with a vitrification solution on the survival of Citrus madurensis embryonic axes cryopreserved using a vitrification protocol. Among the seven different loading solutions tested, the solution containing 2 M glycerol + 0.4 M sucrose was the most efficient. Of the six vitrification solutions tested, the PVS2 vitrification solution, applied for 20 min at 25 degree C or for 60 min at 0 degree C, ensured the highest survival. A three-step vitrification protocol, involving the treatment of embryonic axes at 0 degree C with half strength PVS2 solution for 20 min then with full strength PVS2 for an additional 40 min was more efficient than a two-step protocol that involved treatment of axes directly with full strength PVS2 solution for 60 min. After rapid immersion in liquid nitrogen, rapid rewarming, unloading in a 1.2 M sucrose solution for 20 min, culture on solid medium with 0.3 M sucrose for 1 day and growth recovery for 4 weeks on standard medium, survival of C. madurensis embryonic axes reached 85 % following the three-step process, compared with 70 % for the two-step process.     

Cryopreservation of hairy roots of Rubia akane (Nakai) using a droplet-vitrification procedure

An efficient protocol for the cryopreservation of madder (Rubia akane Nakai) hairy root cultures was developed using droplet-vitrification and alternative loading and vitrification solutions formulated previously in our laboratory. Among eight preculture treatments tested, the highest post-cryopreservation regeneration was obtained for explants incubated in liquid half-strength MS medium with progressively increased sucrose concentration (0.3 M for 54 h, then 0.5 M for 16 h). Loading of precultured explants improved their post-cryopreservation regeneration by 50-75% compared with non-loaded control. Combining loading solution C4 (35% PVS3) and vitrification solution B5 (80% PVS3) was the most effective, while applying six PVS2-based solutions at room temperature resulted in low post-cryo regeneration. Treatment duration was optimized to 30 min for loading and to 10-20 min for vitrification solution. Apices of primary and secondary hairy roots showed similar post-cryo regeneration (88 and 95%, respectively), which was significantly higher than regeneration of root sections without apices (65%). Droplet-vitrification produced higher post-cryo regeneration than 'classical' vitrification in cryovials. Our results suggest that droplet-vitrification using alternative loading and vitrification solutions is an efficient method for cryopreservation of R. akane hairy root cultures.     

Cryopreservation of in vitro shoot tips of Dioscorea deltoidea Wall., an endangered medicinal plant: effect of cryogenic procedure and storage duration

In vitro shoot tips of Dioscorea deltoidea Wall., an endangered medicinal plant, were successfully cryopreserved using the vitrification and the encapsulation-dehydration techniques with subsequent high frequency plant regeneration. Using vitrification, post-liquid nitrogen (LN) shoot regeneration up to 83% was recorded when excised shoot tips were pretreated overnight on MS medium containing 0.3 M sucrose followed by loading with MS containing 2 M glycerol plus 0.4 M sucrose for 20 min at 25 degree C, dehydration with PVS2 for 90 min at 0 degree C and quenching in LN. After 1 h of storage in LN, the shoot tips were rewarmed in a water-bath at 40 degrees C, unloaded with 1.2 M sucrose solution for 20 min and cultured on recovery growth medium. While using encapsulation-dehydration, the highest regeneration frequency recorded was 76% when sucrose-pretreated shoot tips were encapsulated with 3% calcium alginate, precultured in 0.75 M sucrose for 3 days, dehydrated to 25% moisture content (FW basis) under the laminar air flow, stored in LN for 1h and rewarmed at 40 degree C. The cryopreserved shoot tips maintained their viability and an unaltered level of regeneration capability after up to one year of storage in LN.     

V-cryo-plate procedure as an effective protocol for cryobanks: case study of mint cryopreservation

A vitrification procedure using aluminium cryo-plates (V-Cryo-plate procedure) was successfully developed and adjusted for in vitro-grown mint (Mentha spp.) shoot tips. Shoots were cultured at 25°C on MS medium containing 0.088 M sucrose for 7 to 14 days after the last subculture. Shoot tips with a basal part (1-1.5 mm × 1 mm) were dissected from the shoots and precultured at 25°C for 1 day on the same medium. Precultured shoot tips were placed on aluminium cryo-plates with 10 wells and embedded in alginate gel. Osmoprotection was performed by immersing the cryo-plates for 30 min at 25 degree C in 25 ml pipetting reservoirs filled with loading solution (2 M glycerol + 0.8 M sucrose). For dehydration, the cryo-plates were transferred and immersed in 25 ml pipetting reservoirs filled with PVS2 for 20 min at 25 degree C. Then the cryo-plates were transferred in uncapped 2 ml cryotubes and directly plunged into liquid nitrogen. For rewarming, shoot tips attached to the cryo-plates were immersed in cryotubes containing 2 ml 1 M sucrose solution at room temperature. Using this procedure, regrowth of cryopreserved shoot tips of line 'Fukuyamajisei' reached over 90 percent. This protocol was successfully applied to 16 additional Mentha lines, with regrowth ranging from 73 percent to 100 percent. This V-Cryo-plate method will facilitate the cryostorage of mint germplasm in our genebank.     

Geneticallly enginereed trehalose accumulation improves cryopreservation tolerance of chrysanthemum (Dendranthema grandiflorum kitam.) shoot-tips

Shoot-tips isolated from two transgenic lines of chrysanthemum (Dendranthema grandiflorum Kitam.) var. Indianapolis in vitro plantlets with induced capacity to biosynthesize trehalose, and from a non-transformed line, were subjected to cryopreservation using a vitrification procedure. After dissection, apices were precultured on semi-solid MS medium with 0.3 M sucrose for 4 days, loaded in a 0.4 M sucrose + 2 M glycerol solution for 20-30 min and exposed to PVS2 or PVS3 vitrification solutions for 0, 20, 40 or 60 min at room temperature prior to rapid immersion in liquid nitrogen. The highest shoot regeneration after cryopreservation was obtained with exposure to either PVS solution for 40 min. Plant regeneration from cryopreserved shoot-tips ranged between 48 percent and 67 percent for transgenic lines and between 33 percent and 36 percent for non-transgenic lines. No polymorphic loci were detected in plantlets regenerated from cryopreserved and non-cryopreserved shoot-tips with RAPD techniques using eight primers that amplified 101 monomorphic loci.     

An improved cryopreservation protocol for pineapple apices using encapsulation-vitrification

Several modifications to the cryogenic protocols previously described for pineapple apices were performed using vitrification and encapsulation-vitrification. Pregrowth of apices in sucrose-proline before loading significantly reduced the exposure duration to PVS2 and PVS3 required for successful cryopreservation. Encapsulation and treatments with PVS3 at 0 degree C gave the highest survival before and after cooling. Optimal conditions involved the encapsulation of pineapple apices in calcium alginate (3 percent) followed by a 2-d preculture in liquid medium with 0.16 M sucrose + 0.3 M proline for 24 h and then transfer to 0.3 M sucrose + 0.3 M proline for an additional 24 h. After preculture, samples were loaded in 0.75 M sucrose + 1 M glycerol solution at room temperature (25 min) and dehydrated with PVS3 at 0 degree C for 60 min before immersion into liquid nitrogen. Following this procedure 54 percent and 83 percent of apices from MD-2 and Puerto Rico varieties respectively survived.     

Cryopreservation of sugarcane somatic embryos

In this paper, we compared three vitrification-based cryopreservation techniques, viz. vitrification, encapsulation-vitrification and droplet-vitrification for cryopreserving sugarcane somatic embryos. Viability of somatic embryos was evaluated by measuring electrolyte leakage and by regrowth on recovery medium. Droplet-vitrification was the most efficient technique. Optimal conditions included loading with a solution containing 1.5 M glycerol and 0.3 M sucrose for 30 min at 25 degree C, treatment with the PVS2 solution for 20-40 min at 0 degree C followed by rapid immersion in liquid nitrogen of clumps of somatic embryos placed in microdroplets of cryoprotectant solution. Under such conditions, viability of cryopreserved somatic embryos reached 55 percent.     

Cryopreservation of zygotic embryo axes and somatic embryos of European chestnut

This work describes experiments demonstrating the feasibility of long-term conservation of Castanea sativa germplasm through cryopreservation of embryonic axes or somatic embryo clumps. Between 93 % and 100 % of excised embryonic axes of recalcitrant chestnut seeds survived storage in liquid nitrogen (LN) following desiccation in a laminar flow cabinet to moisture contents of 20-24 % (on a fresh weight basis), and some 63 % subsequently developed as whole plants. Desiccation to moisture contents less than 19 % produced damage resulting in loss of organized plant development after cryostorage, allowing only root growth. When 6-8 mg clumps of globular or heart-shaped somatic embryos were precultured for 7 days on high-sucrose medium and then desiccated to a moisture content of 25 % before storage in LN, the embryogenesis resumption level after thawing was 33 %. When the embryo clumps were precultured for 3 days on high-sucrose medium followed by 60 min application of PVS2 vitrification solution before cryostorage, the post-storage embryogenesis resumption level was 68 %.     

Cryopreservation of seeds of a Thai orchid (Doritis pulcherrima lindl. ) by vitrification

Seeds from selfing of a Thai orchid (Doritis pulcherrima Lindl.) were successfully cryopreserved in liquid nitrogen (LN) using the vitrification method. Seeds from 3-month-old pods were sufficiently dehydrated in 2 ml cryotubes filled with highly concentrated vitrification solution (PVS2) at 25 +/- 2 degree C for 50 min. The seeds were then rapidly plunged into LN. After rapid warming, the PVS2 solution was replaced with 0.5 ml of 1.2M sucrose in modified Vacin and Went (1949) (VW) solution and kept at 25 +/- 2 degree C for 20 min prior to transfer on VW agar medium. About 62% of cryopreserved seeds treated with PVS2 solution were able to develop into normal seedlings while without that treatment there was no survival. This vitrification protocol appears to be a promising technique for the cryopreservation of some Thai orchid germplasm     

Development of a vitrification-based cryopreservation protocol for the storage of saltcedar (Tamarix boveana Bunge)

We cryopreserved in vitro shoot tips of saltcedar (Tamarix boveana Bunge) using the vitrification technique. The success of the cryopreservation protocol was strongly affected by preculture, loading duration, dehydration duration in plant vitrification solution 2 (PVS2), and medium composition during post-warming regrowth. The highest explant regrowth (50 percent) occurred when the following conditions were employed: preculture in 0.4 M glycerol; treatment with a loading solution (LS) consisting of 2 M glycerol + 0.4 M sucrose in culture medium for 40 min at room temperature; and dehydration in PVS2 at 0 degree C for 45 min before rapid immersion in liquid nitrogen (LN). Rewarming was performed in a water-bath at 40 degree C for 2 min. Explants were then immersed in unloading solution for 10 min before plating on recovery medium supplemented with 0.01 mg per liter thidiazuron (TDZ). TDZ was progressively eliminated from the medium over a period of 6 weeks. Plantlets were transferred to a double-layer medium to enhance rooting. This protocol was successfully applied to three individuals of T. boveana harvested from the wild.     

Development of a shoot-tip vitrification protocol and comparison with encapsulation-based procedures for plum (Prunus domestica L.) cryopreservation

Cryopreservation of plum (Prunus domestica L.), cv Regina Claudia, was obtained by a vitrification/one-step cooling procedure of shoot tips from cold-hardened in vitro-grown plants. Best survival (57%) was obtained when the shoot tips were precultured at 4 degree C for 2 days on 0.09 M sucrose-containing Quoirin and Le Poivre medium, loaded for 30 min with a cryoprotectant (2 M glycerol and 0.4 M sucrose), incubated with the PVS2 solution at 0 C for 90 min, and directly plunged into liquid nitrogen. After re-warming in a waterbath at 40 degree C, the shoot tips were washed in a 1.2 M-sucrose MS solution for 20 min and finally plated on a regrowth medium. In comparison with the one-step cooling procedure, both the slow cooling (-0.5 degree C/min up to -45 degree C), and the two-step cooling (-160 degree C for 25 min, then -196 degree C) gave lower percentages of shoot-tip survival. Among the other cryogenic procedures tested, the performance of the encapsulation-vitrification method was similar to the vitrification protocol in terms of shoot-tip regrowth (47.5%), while encapsulation-dehydration was unsatisfactory.     

Vitrification, encapsulation-vitrification and droplet-vitrification: a review

This paper discusses the importance of the successive steps of the vitrification technique and reviews the current development and use of vitrification and of the two derived protocols, encapsulation-vitrification and droplet-vitrification. Vitrification refers to the physical process by which a highly concentrated cryoprotective solution supercools to very low temperatures and finally solidifies into a metastable glass, without undergoing crystallization at a practical cooling rate. Samples are thus cryopreserved without detrimental intracellular ice formation. In a standard vitrification protocol, excised explants are precultured on medium enriched with sucrose, treated (loaded) with a loading solution composed of 2 M glycerol + 0.4 M sucrose, dehydrated with a highly concentrated vitrification solution [e.g. the PVS2 vitrification solution, which contains 30 percent (w/v) glycerol, 15 percent (w/v) ethylene glycol and 15 percent (w/v) DMSO and 0.4 M sucrose], frozen and rewarmed rapidly, unloaded with basal culture medium supplemented with 1.2 M sucrose, and then transferred to standard culture conditions. In the encapsulation-vitrification technique, the explants are encapsulated in alginate beads, loaded and dehydrated with a vitrification solution before rapid immersion in liquid nitrogen. In the droplet-freezing technique, excised explants are loaded, treated with the vitrification solution and frozen in individual microdroplets of vitrification solution placed on aluminium foils, which are immersed rapidly in liquid nitrogen. These three techniques have been applied to different tissues of over 100 plant species from temperate and tropical origins and the number of cases where they are being tested on a large scale or applied routinely is increasing.     

Cryopreservation of garlic bulbil primordia by the droplet-vitrification procedure

The droplet-vitrification protocol, a combination of droplet-freezing and solution-based vitrification was applied for cryopreserving garlic bulbil primordia. The highest survival and regeneration percentages of cryopreserved primordia (90.1 to 95.0 percent and 82.7 to 85.0 percent, respectively) were achieved after preculture for 2-4 days at 10 degree C on solid medium with 0.1 - 0.3 M sucrose, loading for 50 minutes in liquid medium with 2 M glycerol + 0.5 M sucrose, dehydration with PVS3 vitrification solution for 90-150 min, cooling primordia in 5 microl droplets of PVS3 vitrification solution placed on aluminum foil strips by dipping these strips in liquid nitrogen, warming them by plunging the foil strips into pre-heated (40 degree C) 0.8 M sucrose solution for 30 s and further incubation in the same solution for 30 minutes. The optimized droplet-vitrification protocol was successfully applied to bulbil primordia of five garlic varieties originating from various countries and to immature bulbils of two vegetatively propagated Allium species, with regeneration percentages ranging between 77.4 - 95.4 percent.     

Characteristics of Atropa belladonna hairy roots cryopreserved by vitrification method

Atropa belladonna hairy roots (clone M8) were successfully cryopreserved by using the vitrification method. A. belladonna hairy root tips were precultured on a half strength of Murashige and Skoog (MS) solid medium with 0.1 mg per L 2,4-D or without phytohormone for 1 day, and then dehydrated with PVS2 solution for 15 minutes prior to immersion into liquid nitrogen for 1 day, 1 week, 1 month and 3 months. Hairy root tips kept in liquid nitrogen were rapidly thawed at 36 degree C in a water bath. The root tips were recultured on half strength MS medium. The hairy root tips, precultured with 2,4-D before cryopreservation, showed a higher survival rate than those precultured without phytohormone. The hairy root tips, precultured with 2,4-D, showed an average survival rate of 83 percent. There was no significant difference in the viability of the hairy roots cryopreserved for different periods. The regrowth of cryopreserved hairy roots was similar to that of untreated hairy roots and tropane alkaloid productivity became stable after 4th subculture. PCR analysis of hairy roots demonstrated the conservation of the T-DNA in cryopreserved hairy roots. These results indicate that cryopreservation by vitrification method is useful to preserve A.belladonna hairy root clone M8.     

Comparison of cryopreservation techniques for long-term storage of ash (Fraxinus excelsior L.)

The main purpose of this study was to develop a cryopreservation protocol for ash and to highlight the importance of testing different clones and plant material of different ontogenetic states. In vitro-grown ash (Fraxinus excelsior L.) shoot tips were successfully cryopreserved following optimization of the PVS2-vitrification protocol. Pretreatment conditions were optimized and three cryopreservation techniques (encapsulation/dehydration, PVS2-vitrification and encapsulation-vitrification) were tested one after another. PVS2-vitrification proved to be the most suitable technique. In vitro-grown shoot tips of ash were successfully cryopreserved with a mean regrowth of 73% for juvenile clones and 67% for selected mature trees. The optimum preculture conditions and the initial protocol were: 10 days cold hardening, preculture for 2 days on medium with 0.8 M glycerol, incubation in 2 M glycerol solution for 20 min at 22 degrees C followed by PVS2 for 25 min at 0 degrees C on ice and direct immersion in liquid nitrogen. Warming was carried out in 43 degree C water for 1 min followed by 22 degree C water for 10 sec. The encapsulation/dehydration method was not successful for shoot tips of F. excelsior because the shoots were sensitive to osmotic dehydration. The encapsulation/vitrification method resulted in a mean regrowth of only 16%. PVS2 vitrification can now be used to store important ash germplasm of either juvenile or mature trees.     

Cryopreservation of in vitro-grown shoot-tips of tropical taro (Colocasia esculenta var. esculenta) by vitrification

In vitro shoot-tips of three cultivars of tropical taro (Colocasia esculenta var. esculenta (L.) Schott) were successfully cryopreserved by vitrification. Different conditioning treatments were required for each of the cultivars, while the vitrification protocol was constant for all. For the cultivars E399 and CPUK, shoot-tips from three-month-old in vitro plants grown on solidified MS were preconditioned on MS with 0.3 M sucrose in the dark for 16 h at 25 degree C. For the cultivar TNS, donor plants were preconditioned on solid MS with 90 g per liter sucrose for seven weeks before cryopreservation. For vitrification, the shoot-tips were loaded with a solution of 2 M glycerol plus 0.4 M sucrose for 20 min at 25 degree C, dehydrated with PVS2 for 12 min at 25 degree C and plunged in liquid nitrogen. Vials were warmed by rapid shaking in a water bath at 40 degree C for 1 min 30. Shoot-tips were rehydrated in liquid MS with 1.2 M sucrose for 15 min at 25 degree C then plated on recovery medium. Shoot-tips resumed growth within a week and developed into plantlets six to eight weeks later without any callus formation. The best mean recoveries for the three cultivars were 21, 29 and 30 percent for E399, CPUK and TNS, respectively. This protocol was evaluated with five other taro cultivars with no success. However, this study has shown that vitrification has potential for cryopreserving tropical taro.     

Effect of preculture, pvs2 and vitamin C on survival of recalcitrant Nephelium ramboutan-ake shoot tips after cryopreservation by vitrification

This paper reports the cryopreservation of Nephelium ramboutan-ake shoot tips derived from in vitro shoot multiplication and in vitro seed germination using vitrification. Preculture with either 0.5 M sucrose for 2 days or a combination of 0.3 M sucrose and 0.5 M glycerol for 3 days enhanced dehydration tolerance and resulted in the highest survival of shoot tips; however, none of the shoot tips withstood liquid nitrogen (LN) exposure. The use of a lower temperature (0 degree C) during exposure to plant vitrification solution (PVS2) led to higher survival of shoot tips, compared to exposure at 25 degree C. The survival percentage of shoot tips exposed to PVS2 for up to 20 min at 0°C was 83.3 percent. It was only 53.3 percent when shoot tips were exposed to PVS2 at 25 degree C for 5 min. The importance of vitamin C for reducing oxidative stress in shoots tips was demonstrated. The addition of 0.28 mM vitamin C during critical steps of the vitrification process resulted in a high survival (96.7 percent) without LN exposure, compared to 73.3 percent for shoot tips not treated with vitamin C. Moreover, 3.3 percent shoot tips withstood LN exposure when vitamin C was added during the loading step. This result suggests that cryopreservation is possible for this tropical, recalcitrant seeded tree species.