Cryopreservation of Citrus madurensis embryonic axes encapsulation-dehydration

In this paper, we demonstrate that C. madurensis embryonic axes can withstand cryopreservation using the encapsulation-dehydration technique. Up to 57.5 % survival was achieved using a standard encapsulation-dehydration protocol, which included pregrowth of encapsulated axes for 16 h in medium containing 0.8 M sucrose + 1 M glycerol, desiccation of beads to around 30 % moisture content (fresh weight basis) followed by rapid freezing. A slightly higher survival percentage (65 %) was obtained using a modified encapsulation-dehydration protocol, which included pretreatment of axes with 2 M glycerol + 0.6 M sucrose for 1 h, concomitantly with their encapsulation in 3 % calcium alginate beads, followed by desiccation of the beads to around 30 % moisture content.     

Cryopreservation of 'Nabali' olive (Olea europea l.) somatic embryos by encapsulation-dehydration and encapsulation-vitrification

Olive (Olea europea L.) somatic embryos were successfully cryopreserved using encapsulation-dehydration and encapsulation-vitrification. In the encapsulation-dehydration procedure, a maximum of 48% embryo survival was obtained when bead moisture content was decreased to 21.1% after 4 h dehydration. Preculture of embryos for 4 d in medium containing 0.75 to 1.25 M sucrose produced higher (40 to 34 %, respectively) regrowth after cryopreservation using encapsulation-dehydration procedure. Dehydration of beads for 3 h in PVS2 ensured higher survival (64%) of encapsulated-vitrified and cryopreserved (EVN) somatic embryos. Thermal treatment of embryogenic callus for 1 d at 30 degree C was very effective to increase survival of encapsulated-dehydrated and cryopreserved (EDN) (58%) and EVN (68%) embryos. Plantlets produced from control and cryopreserved embryos were phenotypically similar.     

Cryopreservation of ovules and somatic embryos of citrus using the encapsulation-dehydration technique

Cryopreservation of ovules and somatic embryos from several genotypes of citrus was achieved using the encapsulation-dehydration technique. Survival of cryopreserved ovules was occasional and erratic after different pregrowth conditions in liquid medium with 0.75M, 1M or up to 1.25M sucrose. An efficient cryopreservation protocol was established for somatic embryos derived from two embryogenic sources (ovules and cut thin layer explants from stigma, style and ovaries). High survival rates (75-100%) were consistently obtained after 1 day pregrowth in 0.75M sucrose, desiccation down to 20-25% moisture content in the beads and direct immersion in liquid nitrogen. The histological study showed that embryos subjected to the encapsulation-dehydration, accumulated high sucrose levels which appear to ensure the recovery of the whole embryo after cryopreservation.     

Cryopreservation of black chokeberry in vitro shoot apices

In vitro shoot apices of black chokeberry (Aronia melanocarpa Elliott) were successfully cryopreserved utilizing three methods, namely vitrification, encapsulation-vitrification and encapsulation-dehydration. Encapsulation-dehydration and encapsulation-vitrification, however, seem preferable to vitrification, since the highest respective survival levels of apices (71.1 +/- 2.2 percent and 77.8 +/- 4.4 percent) by both methods were higher than that (60.0 +/- 3.9 percent) by vitrification. In encapsulation-dehydration, the highest survival was achieved when the moisture content of beads was reduced to 19 percent by drying with silica gel for 6 h. In the present study, it was shown that adding 1.0 M glycerol to beads and loading solution during encapsulation-dehydration resulted in high survival (91.7 - 95.0 percent) regardless of lines and polyploids of black chokeberry.     

Effect of benzyladenine on recovery of cryopreserved shoot tips of grapevine and citrus cultured in vitro

The effect of N6-benzyladenine (BA) on the recovery of cryopreserved shoot tips of the LN33 hybrid (Vitis L.) and Troyer citrange [Poncirus trifoliata (L.) Raf. x Citrus sinensis [L.] Osbeck.] cultured in vitro was examined. For the LN33 hybrid, the presence of BA in the recovery medium was essential for survival of control and cryopreserved shoot tips, although the BA concentration did not influence the survival percentage. BA at 5, 2, and 5 microM or higher induced callus formation in control, and shoot tips cryopreserved by vitrification, and by encapsulation-dehydration, respectively. While a BA concentration of 4 microM was found optimal for recovery of control shoot tips, 1 and 2-4 microM produced the best recovery of shoot tips cryopreserved by vitrification and encapsulation-dehydration, respectively. A similar pattern of effect of BA on recovery was found for 'Troyer' citrange. Low survival of control and cryopreserved shoot tips was observed with a BA-free recovery medium. The addition of BA to the recovery medium significantly increased survival. The BA concentration that induced callus formation in shoot tips cryopreserved by encapsulation-vitrification was higher than that which induced it in those cryopreserved by encapsulation-dehydration. Recovery of control shoot tips was best with an addition of 6-10 microM BA to the medium. Optimal recovery of shoot tips cryopreserved by encapsulation-vitrification and encapsulation-dehydration was achieved with 3-4 and 2 microM BA, respectively. Results from the present study suggest that an optimal BA concentration for recovery of control shoot tips may be different from that for cryopreserved shoot tips; furthermore, the optimal BA concentration for recovery of cryopreserved shoot tips may also differ among different cryogenic procedures.     

Thermal analysis of the plant encapsulation-dehydration cryopreservation protocol using silica gel as the desiccant

The encapsulation-dehydration cryopreservation protocol is critically dependent upon the evaporative desiccation step, which must optimise survival with the retention of glass stability on sample cooling and rewarming. Desiccation is usually achieved evaporatively by drying in a sterile airflow. However, chemical desiccation using silica gel has advantages for laboratories that do not have environmental control and/or which are exposed to high relative humidities and risks of microbial contamination. This study characterised thermal profiles of silica gel-desiccated encapsulated shoot-tips of two Ribes species using Differential Scanning Calorimetry. For both species silica gel-desiccation at 16 degrees C for 5 h decreased bead water content from ca. 75 to 28% fresh weight (3.8 to 0.4 g x g(-1) dry weight); further desiccation (for 6 and 7 h) reduced the bead water content to 21% (0.3 g x g(-1) dry weight). These changes in water status altered the thermal properties of beads for both species. After 7 h desiccation over silica gel stable glass transitions were observed on both cooling and rewarming of beads containing meristems. Tg mid-point temperatures ranged from -78 to -51 degrees C (cooling) and from -88 to -54 degrees C (warming) [at cooling and warming rates of 10 and 5 degrees C min(-1), respectively] after 5 to 7 h silica gel-desiccation. Post-cryopreservation viability of both species was ca. 63%. Thermal analysis studies revealed that an encapsulation/dehydration protocol using silica gel as a desiccant should comprise a minimum 5 h drying (at 16 degrees C). This reduces bead moisture content to a critical point (ca. 0.4 g x g(-1) dry weight) at which stable glasses are formed on cooling and rewarming. It is concluded that silica gel has advantages for use as a desiccant for alginate-encapsulated plant meristems by promoting stable vitrification and is useful in laboratories and/or geographical locations where environmental conditions are not under stringent control.     

Cryopreservation of Vanda coerulea protocorms by encapsulation-dehydration

Protocorms of Vanda coerulea were successfully cryopreserved by encapsulation-dehydration in combination with a loading solution. Protocorms were selected 70 days after sowing seeds harvested from 7-month-old fruits. After encapsulation in an alginate matrix composed of 2 percent Na-alginate, 2 M glycerol plus 0.4 M sucrose (loading solution), the protocorms were precultured in modified Vacin and Went (1949) (VW) liquid medium supplemented with 0.7 M sucrose on a shaker (110 rpm) at 25 +/- 3 degree C for 20 h. Encapsulated protocorms were then dehydrated in a sterile air-flow in a laminar air-flow cabinet at 25 +/- 3 degree C for 0-10 h and then directly plunged into liquid nitrogen for 1 d. After thawing at 40 degree C for 2 min, cryopreserved beads were cultured on modified VW agar medium for regrowth. The highest regrowth of 40 percent was observed with cryopreserved beads with 35 percent water content after 8 h dehydration. No morphological variation was detected between non-cryopreserved and cryopreserved plantlets, and ploidy level was unchanged as a result of cryopreservation.     

Cold acclimation improves recovery of cryopreserved grass (Zoysia and Lolium sp.)

Cold acclimation of Lolium L. and Zoysia Willd. Grass cultivars significantly increased regrowth of cryopreserved meristems. One wk of cold acclimation improved recovery following cryopreservation but extended acclimation (4-8 wk) resulted in the best regrowth. Cold acclimation also significantly increased the dehydration tolerance of both Zoysia and Lolium meristems. Lolium apices cold acclimated for 4 wk produced 60-100% regrowth following cryopreservation by slow freezing or encapsulation-dehydration. Cold-acclimated Zoysia had greater than 60% regrowth following encapsulation-dehydration when beads were dehydrated to less than 22% water content. Non-acclimated meristems of both genera had little or no regrowth. Thawed meristems grew quickly without callus formation and the plantlets produced were transplanted to pots in the greenhouse after 4 to 6 wk. Samples of each cultivar were stored in liquid nitrogen as part of the U.S. National Plant Germplasm System.     

Cryopreservation of somatic embryos of paradise tree (Melia azedarach L.)

In paradise tree (Melia azedarach L.), immature zygotic embryos sampled from immature fruits are the starting material for the production of somatic embryos. These somatic embryos are employed for freezing experiments. Immature fruits could be stored at 25 degrees C for up to 80 days without impairing the embryogenic potential of zygotic embryos, which represents a four-fold increase in immature fruit storage duration, compared with previous studies. Among the three cryopreservation techniques tested for freezing paradise tree somatic embryos, namely desiccation, encapsulation-dehydration and pregrowth-dehydration, only encapsulation-dehydration and pregrowth-dehydration led to successful results. The optimal protocol was the following: i) somatic embryos (encapsulated or not) pretreated in liquid Murashige & Skoog medium with daily increasing sucrose concentration (0.5 M/0.75 M/1.0 M); ii) dehydrated with silica gel to 21 - 26% moisture content (fresh weight basis), for encapsulation-dehydration, or to 19% moisture content, for pregrowth-dehydration; iii) frozen at 1 degree C/min from 20 degrees C to -30 degrees C with a programmable freezing apparatus; iv) rapid immersion in liquid nitrogen. The highest recovery achieved was 36% with encapsulation-dehydration and 30% with pregrowth-dehydration. Regrowth of frozen embryos was direct in most cases, as secondary embryogenesis originating from the root pole was observed on only around 10% of cryopreserved somatic embryos. Plants recovered from cryopreserved embryos presented the same phenotypic traits as non-frozen control plants.     

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.     

Cryopreservation of peach palm zygotic embryos

Cryopreservation is a safe and cost-effective option for long-term germplasm conservation of non-orthodox seed species, such as peach palm (Bactris gasipaes). The objective of the present study was to establish a cryopreservation protocol for peach palm zygotic embryos based on the encapsulation-dehydration technique. After excision, zygotic embryos were encapsulated with 3 percent sodium alginate plus 2 M glycerol and 0.4 M sucrose, and pre-treated or not with 1 M sucrose during 24 h, followed by air-drying. Fresh weight water contents of beads decreased from 83 percent and 87 percent to 18 percent and 20 percent for pre-treated or non-pretreated beads, respectively, after 4 h of dehydration. Sucrose pre-treatment at 1 M caused lower zygotic embryo germination and plantlet height in contrast to non-treated beads. All the variables were statistically influenced by dehydration time. Optimal conditions for recovery of cryopreserved zygotic embryos include encapsulation and dehydration for 4 h in a forced air cabinet to 20 percent water content, followed by rapid freezing in liquid nitrogen (-196 degree C) and rapid thawing at 45 degree C. In these conditions 29 percent of the zygotic embryos germinated in vitro. However, plantlets obtained from dehydrated zygotic embryos had stunted haustoria and lower heights. Histological analysis showed that haustorium cells were large, vacuolated, with few protein bodies. In contrast, small cells with high nucleus:cytoplasm ratio formed the shoot apical meristem of the embryos, which were the cell types with favorable characteristics for survival after exposure to liquid nitrogen. Plantlets were successfully acclimatized and showed 41+/-9 percent and 88+/-4 percent survival levels after 12 weeks of acclimatization from cryopreserved and non-cryopreserved treatments, respectively.     

Newly developed encapsulation-dehydration protocol for plantcryopreservation

A simplified and efficient encapsulation-dehydration protocol, which is a compromise between vitrification and encapsulation-dehydration, was presented for plant cryopreservation. In this protocol, during the encapsulation process, the apices precultured with 0.3 M sucrose for 16 h were simultaneously osmoprotected with a mixture of 02 M glycerol plus 0.4 M sucrose for 1 h. These encapsulated apices were directly dehydrated with dry silica gel prior to a plunge into LN without the pretreatment of 0.8M sucrose for 16 h. This protocol produced much higher rates of recovery growth in the three plant species tested (wasabi, chrysanthemum, and mint) than those cryopreserved by the conventional encapsulation-dehydration. This protocol also considerably reduced the time needed for the cryogenic procedure. Thus, this new protocol appears promising for cryopreservation of shoot apices and other explants.     

Cryopreservation of black iris (Iris nigricans) somatic embryos by encapsulation-dehydration

Somatic embryos of black iris (Iris nigricans) were cryopreserved using encapsulation-dehydration. Embryos size of 2-4 mm gave the highest survival after cryopreservation. Preculturing embryos on medium containing 0.75 M sucrose for 3 d at 22 degree C, then at 30 degree C for 1 d ensured maximum survival (60%). Viable embryos were brown in color after cryopreservation and during early recovery while dead ones where light brown or creamy. The first sign of regrowth was noted after 15 d. The final regrowth percentage of living embryo was 90% after 35 d. Only 10% of the embryos in all treatments showed secondary embryogenesis. Direct sowing in vivo of cryopreserved embryos was not successful in achieving germination.     

Deployment of the encapsulation-dehydration protocol to cryopreserve diverse microalgae held at the Institute of Soil Biology, Academy of Sciences of the Czech Republic

Twenty-seven strains of soil algae isolated from highly diverse provenances and habitats were assessed for their capacity to withstand cryopreservation using encapsulation/dehydration. Survival was assessed following the release of algae from alginate beads treated with sodium hexametaphosphate and regrowth was assessed using NAJA Image Analysis. Regrowth occurred in 19 strains, with > 50% survival being observed in 15. Algal tolerance to osmotic dehydration and evaporative desiccation was critical to the success of the method. Recovery in five out of the remaining eight recalcitrant strains was enhanced by substituting sorbitol for the osmotic pretreatment or by combining encapsulation with two-step controlled rate cooling.     

Deployment of the encapsulation-dehydration protocol to cryopreserve polar microalgae held at the Czech Republic Academy of Sciences Institute of Botany

Polar isolates of four chlorococcal microalgae originating from the Arctic and Antarctica withstand cryopreservation using encapsulation-dehydration. Viability assessments, which initially used chloroplhyll fluorescence (Kautsky) induction kinetics, revealed that all strains suffered photosynthetic impairment during early post-cryopreservation recovery. This cryoinjury was reversible, as indicated by cell regrowth in three of the four strains. Lack of growth in the fourth isolate was due to contaminating bacteria rather than cryogenic factors.     

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.     

Regeneration of Dioscorea floribunda plants from cryopreserved encapsulated shoot tips: effect of plant growth regulators

The encapsulation-dehydration protocol for the cryopreservation of in vitro shoot tips of Dioscorea floribunda was optimized. Maximum survival of 87% was obtained when overnight pretreatment with 0.3 M sucrose was followed by encapsulation, preculture in 0.75 M sucrose for 4 d, dehydration in a laminar air flow for 5.5 h, quenching in liquid nitrogen and thawing at 40 degrees C. During recovery growth, 29% shoot formation was obtained when cryopreserved shoot tips were initially cultured for 25 d on a medium with 1.5 mg per liter (-1) BAP, 0.2 mg per liter(-1) NAA and 0.2 mg per liter(-1) GA3 followed by culturing for 15 d on a medium with reduced BAP (1 mg per liter(-1)) but increased NAA (0.5 mg per liter(-1)) and GA3 (0.3 mg per liter(-1)). Finally, transfer on to a medium with further reduced doses of BAP (0.05 mg per liter(-1)) and NAA (0.15 mg per liter(-1)) but without GA3 stimulated production of fully grown plantlets. All plants regenerated without callus formation. Modification of post-thaw culture media with plant growth regulators was essential for regrowth of shoot tips to plantlets.     

Developing cryopreservation for Picea sitchensis (sitka spruce) somatic embryos: a comparison of vitrification protocols

Two vitrification-based cryopreservation protocols, encapsulation/dehydration and PVS2 were applied to Stage 2 (globular) and Stage 4 (torpedo) somatic embryos (SE) from Picea sitchensis. Two recovery responses: partially differentiated embryogenic suspensor masses (ESM) and dedifferentiated non-embryogenic masses (NEM) were observed following exposure to LN. All genotypes tested, proliferated NEM, approximately 10 to 100% of the total SE cryopreserved. A General Linear Model applied to NEM recovery data demonstrated several different factors (developmental state and genotype, treatment, culture age) interacted at a significant level (P less than 0.05) to influence proliferation. One genotype was capable of proliferating ESM after cryopreservation using encapsulation-dehydration, this response was achieved for Stage 4 embryos derived from the youngest ESM tissue.     

Cryopreservation of plant germplasm using the encapsulation-dehydration technique: review and case study on sugarcane

Encapsulation-dehydration is a cryopreservation technique based on the technology developed for producing synthetic seeds, i.e. the encapsulation of explants in calcium alginate beads. Encapsulated explants are then precultured in liquid medium with a high sucrose concentration and partially desiccated before freezing. Encapsulating the explants allows the subsequent application of very drastic treatments including preculture with high sucrose concentrations and desiccation to low moisture contents which would be highly damaging or lethal to non-encapsulated samples. An encapsulation-dehydration protocol comprises the following steps: pretreatment, encapsulation, preculture, desiccation, freezing and storage, thawing and regrowth. Encapsulation-dehydration has been applied to around 40 different plant species. The optimization of the successive steps of the encapsulation-dehydration protocol is illustrated for sugarcane apices.     

Cryopreservation, encapsulation and promotion of shoot production of embryonic axes of a recalcitrant species Ekebergia capensis, Sparrm

A study on zygotic axes of the recalcitrant seeds of Ekebergia capensis compared two cryopreservation methods, partial desiccation, and encapsulation-dehydration, and also investigated a method to promote shoot production. High (80 percent) survival (assessed as root production) was obtained after direct immersion into liquid nitrogen of axes rapidly dehydrated by flash drying for 20 min to a water content about 0.4 g water per g dry mass. In contrast, no survival at all was obtained of axes that were first encapsulated, then desiccated for three hours to the same water concentration as those fast-dried, and then placed in a cryovial and immersed in liquid nitrogen. Axes encapsulated after cryopreservation germinated both in vitro and in soil, and could be stored at room temperatures for several weeks while maintaining germinability, thus producing synseeds capable of distribution. However, shoot production after cryopreservation was seldom observed. The inclusion of the plant growth regulator, N6-benzyl adenine (BA) in the MS-based recovery medium promoted vigorous multiple shoot formation. Microscopical examination of embryos of E. capensis revealed that the cotyledonary insertions were contiguous with the shoot apex, leading to the conclusion that injury to, and ultimate necrosis of, the apical meristem following severing of these connections was a primary cause of the observed lack of, or poor, shoot development in excised axes (whether cryopreserved or not). The study demonstrated that it may be possible to resolve two of the problems facing attempts at cryopreservation of axes of recalcitrant seeds; lack of shoot production and difficulty of distribution of cryopreserved material for re-introduction.