Cryopreservation of protocorm-like bodies (PLBs) of <Emphasis Type="Italic">Phalaenopsis bellina</Emphasis> (Rchb.f.) christenson by encapsulation-dehydration

Protocorm-like bodies (PLBs) of Phalaenopsis bellina were successfully cryopreserved by the encapsulation-dehydration approach. Various stages in obtaining successful cryopreservation using this method were optimized. Encapsulated PLBs precultured in half-strength MS medium supplemented with 0.75 M sucrose for 3 days exhibited the highest viability in terms of 2,3,5-triphenyltetrazoliumchloride (TTC) reduction. The amount of sucrose in the PLBs after incubation in different concentrations of sucrose for different periods of time determined by HPLC. The highest sucrose concentration was 7 mg/g of PLBs for the PLBs treated with 0.75 M sucrose for 3 days as compared to the control which had only 1 mg/g sucrose. After sucrose preculture, the PLBs were subjected to desiccation using one of two methods. Desiccation using silica gel was more efficient in reducing PLBs moisture content. After 6 h of desiccation, PLBs desiccated using laminar air flow had 43.5% moisture content while for those desiccated using silica gel had 32% moisture content. PLBs desiccated to different moisture contents were plunged into LN. After storage in LN the encapsulated PLBs were re-warmed. Two weeks after re-warming PLBs viability was determined by TTC reduction and re-growth assessed. Encapsulated PLBs precultured with 0.75 M sucrose for 3 days followed by desiccated using silica gel for 5 h resulting in a moisture content of 39% lead to the highest post re-warming viability in terms of TTC reduction (46.6% of control PLBs) and 30% re-growth.     

Cryopreservation of <Emphasis Type="Italic">Robinia</Emphasis><Emphasis Type="Italic">pseudoacacia</Emphasis>

Cryopreservation of Robinia pseudoacacia explants by vitrification achieved 78% survival following the stepwise preculture of shoot tips in (0.3 + 0.5 + 0.7 M) sucrose with a 80 min incubation in PVS2; compared to 87% survival after desiccation of explants to 30% water content, following 3 days alginate bead (with glycerol and sucrose treatments) preculture in 0.7 M sucrose.     

Cryopreservation of Teucrium polium L. shoot-tips by vitrification and encapsulation-dehydration

Teucrium polium L. with the common name of Felty Germander is one of the plants flora that is widely used in folk medicine in many Middle East countries, it is an endangered plant species and must be highly considered for preservation. Cryopreservation of T. polium by vitrification and encapsulation-dehydration was successfully achieved in this study. Shoot-tips were excised aseptically from in vitro grown plants and incubated for 3?days on solid hormone free-Murashige and Skoog (HF-MS) media supplemented with 0.3?M sucrose under complete darkness at 24?±?1?°C. In vitrification, shoot-tips were loaded in 0.4?M sucrose and 2?M glycerol for 20?min followed by desiccation with different combinations and concentrations of plant vittrification solution 2 (PVS2), before immersion in Liquid Nitrogen (LN). Whereas for the encapsulation-dehydration; shoot-tips were encapsulated in calcium alginate and dehydrated under laminar air flow cabinet for 0, 3, 6, or 9?h. A total of 60?% of the cryopreserved vitrified shoot-tips survived when desiccated in concentrated PVS2 solution for 20?min, whereas, 28?% of the cryopreserved vitrified shoot-tips were regrown after 20?min of desiccation by two step increase in PVS2 concentration. Complete survival were obtained for the non-cryopreserved encapsulated shoot-tips treated for 3?days in 0.5?M sucrose with MS media without or with 3?h of dehydration, whereas, only 20?% of the cryopreserved encapsulated shoot-tips were regrown. The procedures developed in this study are easy to handle and produced a high levels of shoot formation.     

Cryopreservation of African violet (Saintpaulia ionantha Wendl.) shoot tips

Summary Cryopreservation of African violet via encapsulation-dehydration, vitrification, and encapsulation-vitrification of shoot tips was evaluated. Encapsulation-dehydration, pretreatment of shoot tips with 0.3 M sucrose for 2 d followed by air dehydration for 2 and 4 h resulted in complete survival and 75% regrowth, respectively. Dehydration of encapsulated shoot tips with silica gel for 1 h resulted in 80% survival but only 30% regrowth. Higher viability of shoot tips was obtained when using a step-wise dehydration of the material rather than direct exposure to 100% plant vitrification solution (PVS2). Complete survival and 90% regrowth were achieved with a four-step dehydration with PVS2 at 25°C for 20 min prior to freezing. The use of 2M glycerol plus 0.4M sucrose or 10% dimethyl sulfoxide (DMSO) plus 0.5M sucrose as a cryoprotectant resulted in 55% survival of shoots. The greatest survival (80–100%) and regrowth (80%) was obtained when shoot tips were cryoprotected with 10% DMSO plus 0.5M sucrose or 5% DMSO plus 0.75M sucrose followed by dehydration with 100% PVS2. Shoot tips cryoprotected with 2M glycerol plus 0.4M sucrose for 20 min exhibited complete survival (100%) and the highest regrowth (55%). In encapsulation-vitrification, dehydration of encapsulated and cryoprotected shoot tips with 100% PVS2 at 25°C for 5 min resulted in 85% survival and 80% regrowth.     

Cryopreservation of shoot tips from the endangered endemic species Tuberaria major

Tuberaria major is an endangered endemic species from the Algarve, in the south of Portugal. We investigated two techniques for the cryopreservation of T. major shoot tips, namely vitrification and encapsulation-dehydration. Before the cryopreservation trials, shoot tips were precultured for 1 day on liquid Murashige and Skoog (MS) medium containing 0.3 M sucrose. For the vitrification method, shoots tips were exposed for 0, 30, 60, 90 and 120 min to plant vitrification solution 2 (PVS2). As for the encapsulation-dehydration method, shoot tips were dried inside a laminar air flow cabinet for 0, 1, 2, 3, 4, 5 and 6 h at room temperature. The highest regrowth percentages were approximately 60 and 67 % for vitrification and encapsulation-dehydration, respectively. The best times were 60 min exposure to PVS2 for vitrification and 3 h desiccation for encapsulation-dehydration. Though these are preliminary results, the use of the cryopreservation techniques tested here proved to be an important asset in the conservation of this endangered species and will complement the conservation strategies previously developed.     

Multiplication and cryopreservation of vanilla (<Emphasis Type="Italic">Vanilla planifolia</Emphasis> ‘Andrews’)

A simple and efficient method for multiplication of vanilla (Vanilla planifolia) was developed using in vitro fragmented explants (IFEs) as propagules. IFEs were obtained after dissecting apices from in vitro propagated clusters of plantlets, by cutting the remaining base of these plant clusters into segments of about 1 cm in length. After 4 months of culture on multiplication medium, 100% of IFEs produced up to 15 new shoots per explant, providing an efficient additional method for in vitro propagation of vanilla that maximizes the use of available material. Cryopreservation of apices from in vitro grown plants was achieved using the droplet vitrification protocol. Maximum survival (30%) and further regeneration (10%) of new shoots were obtained for apices derived from clusters of in vitro plantlets produced from microcuttings through a three-step droplet vitrification protocol: 1-d preculture of apices on solid MS medium with 0.3 M sucrose; loading with a 0.4 M sucrose + 2 M glycerol solution for 20–30 min; and exposure to plant vitrification solution PVS3 for 30 min at room temperature. Even though the cryogenic protocol needs to be optimized to improve results, this work represents the first successful report of cryopreservation of vanilla apices.     

Cryopreservation of an endangered <Emphasis Type="Italic">Hladnikia pastinacifolia</Emphasis> Rchb. by shoot tip encapsulation-dehydration and encapsulation-vitrification

The objective of the present study was the cryopreservation of monotypic endemic Hladnikia pastinacifolia Rchb. shoot tips from an in vitro culture, via encapsulation-dehydration (ED) or encapsulation-vitrification (EV). For all tested genotypes, the highest rates of shoot regrowth and multiplication were obtained after overnight preculture in 0.4 M sucrose, encapsulation in Murashige and Skoog (MS) medium with 0.4 M sucrose and 1 M glycerol, followed by polymerization in 3% (w/v) Na-alginate in MS with 0.4 M sucrose. Optimal osmoprotection was achieved for ED with 0.4 M sucrose plus 1 M glycerol and for EV with 0.4 M sucrose plus 2 M glycerol. The best dehydration time for ED was 150 min in a desiccation chamber with silica gel, and the best vitrification time for EV was 85 min in plant vitrification solution 2 (PVS2). For ED, dehydration for 150 min resulted in explant water content of 22%. When the encapsulation method was combined with ED, 53% regrowth was achieved, and when it was combined with EV, 64% regrowth was achieved. Both methods could become applicable for the long-term cryopreservation of H. pastinacifolia germplasm, although EV was faster and resulted in better final regrowth success. Genetic stability analysis of cryopreserved plant samples was carried out for two genotypes, using random amplified polymorphic DNA (RAPD) markers to compare the two different cryopreservation protocols. Significant genetic differences between the genotypes were detected and a low level of genomic variation was observed.     

Cryopreservation of grapevine (Vitis vinifera L.) in vitro shoot tips

In this work, we compared the efficiency of encapsulation-dehydration and droplet-vitrification techniques for cryopreserving grapevine (Vitis vinifera L.) cv. Portan shoot tips. Recovery of cryopreserved samples was achieved with both techniques; however, droplet-vitrification, which was used for the first time with grapevine shoot tips, produced higher regrowth. With encapsulationdehydration, encapsulated shoot tips were precultured in liquid medium with progressively increasing sucrose concentrations over a 2-day period (12 h in medium with 0.25, 0.5, 0.75 and 1.0 M sucrose), then dehydrated to 22.28% moisture content (fresh weight). After liquid nitrogen exposure 37.1% regrowth was achieved using 1 mm-long shoot tips and only 16.0% with 2 mm-long shoot tips. With droplet-vitrification, 50% regrowth was obtained following treatment of shoot tips with a loading solution containing 2 M glycerol + 0.4 M sucrose for 20 min, dehydration with half-strength PVS2 vitrification solution (30% (w/v) glycerol, 15% (w/v) ethylene glycol, 15% dimethylsulfoxide and 0.4 M sucrose in basal medium) at room temperature, then with full strength PVS2 solution at 0°C for 50 min before direct immersion in liquid nitrogen. No regrowth was achieved after cryopreservation when shoot tips were dehydrated with PVS3 vitrification solution (50% (w/v) glycerol and 50% (w/v) sucrose in basal medium).     

Cryopreservation of wild Shih (<Emphasis Type="Italic">Artemisia herba</Emphasis>-<Emphasis Type="Italic">alba</Emphasis> Asso.) shoot-tips by encapsulation-dehydration and encapsulation-vitrification

Artemisia herba-alba, called Shih is a medicinal herbal plant found in the wilds. The biodiversity of this plant is heavily subjected to loss because of heavy grazing, land cultivation and collection by people to be used in folk medicine. In the current study, two cryopreservation dependent techniques to conserve the shoot-tips of in vitro grown Shih were evaluated: encapsulation- dehydration and encapsulation- vitrification. Shoot-tips of Shih were encapsulated into sodium-alginate beads. In encapsulation- dehydration, the effect of sucrose concentration (0.5, 0.75 or 1.0 M) and dehydration period (0, 2, 4 or 6 h) under sterile air-flow on survival and regrowth of encapsulated shoot tips were studied. Maximum survival (100%) and regrowth (27%) rates were obtained when encapsulated unfrozen Artemisia herba-alba shoot tips were pretreated with 0.5 M sucrose for 3 days without further air dehydration. After cryopreservation the highest survival (40%) and regrowth (6%) rates were achieved when Artemisia herba-alba shoot tips were pretreated with 1.0 M sucrose for 3 days without further air dehydration. Viability of Artemisia herba-alba shoot tips decreased with increased dehydration period. In encapsulation-vitrification, the effect of dehydration of encapsulated Artemisia herba-alba shoot tips with 100% PVS2 for various dehydration durations (10, 20, 30, 60 or 90 min) prior to freezing was studied. After cryopreservation the dehydration of encapsulated and vitrified shoot tips with 100% PVS2 for 30 min resulted in 68% survival and 12% regrowth rates. Further conservation techniques must be evaluated to increase both survival and regrowth percentages.     

Successful cryopreservation of Quercus robur plumules

Successful cryopreservation of Q. robur germplasm as plumules (i.e. shoot apical meristems of embryos) is described in this paper. After excision from the recalcitrant seeds and preliminary storage in 0.5 M sucrose solution (18 h), the plumules were subjected to cryoprotection (in 0.75 M sucrose, followed by 1.0 M sucrose and 1.5 M glycerol solutions), and next to desiccation (over silica gel or in nitrogen gas) and cooling (in slush at –210°C or in vials filled with liquid nitrogen, LN, −196°C), and were then cryostored for 24 h. High percentage of survival was obtained after cryostorage (21–67%, depending on pretreatment, assessed in vitro by greening plumules that increased in size). Desiccation of plumules over silica gel resulted in significantly higher survival after cryopreservation (58%) in comparison with desiccation in nitrogen gas (29%), with regrowth (shoots with leaves) 5–18%. The extent of plumule desiccation was comparable in both methods, in which drying of plumules for 20 min decreased the water content to 0.5–0.6 g H₂O g⁻¹ dry weight before LN exposure. The type of LN exposure did not significantly influence plumule survival and regrowth after cryostorage. Plumules isolated from acorns of four provenances survived cryostorage after cryoprotection followed by desiccation over silica gel and direct cooling in vials with LN (survival 51–76%, regrowth 8–20%). Normal plants developed from the recovered shoots after rooting. The presented protocol for Q. robur plumule cryopreservation may offer a potential approach for establishing germplasm conservation in gene banks for Quercus species.     

Cryopreservation of sour orange (Citrus aurantium L.) shoot tips

Summary The objective of this study was to establish a cryopreservation protocol for sour orange (Citrus aurantium L.). Cryopreservation was carried out via encapsulation-dehydration, vitrification, and encapsulation-vitrification on shoot tips excised from in vitro cultures. Results indicated that a maximum of 83% survival and 47% regrowth of encapsulated-dehydrated and cryopreserved shoot tips was obtained with 0.5M sucrose in the preculture medium and further dehydration for 6 h to attain 18% moisture content. Dehydration of encapsulated shoot tips with silica gel for 2h resulted in 93% survival but only 37% regrowth of cryopreserved shoot tips. After preculturing with 0.5M sucrose, 80% of the vitrified cryopreserved shoots survived when 2M sucrose plus 10% dimethyl sulfoxide (DMSO) was used as a cryoprotectant for 20 min at 25°C. Survival and regrowth of vitrified cryopreserved shoot tips were 67% and 43%, respectively, when 0.4M sucrose plus 2M glycerol was used as a loading solution followed by application of 100% plant vitrification solution (PVS2) for 20 min. Increased duration of exposure to the loading solution up to 60 min increased survival (83%) and regrowth (47%) of cryopreserved shoot tips. With encapsulation-vitrification, dehydration with 100% PVS2 for 2 or 3 h at 0°C resulted in 50 or 57% survival and 30 or 40% regrowth, respectively, of cryopreserved shoot tips.     

Cryopreservation of <Emphasis Type="Italic">Dendrobium candidum</Emphasis> Wall. ex Lindl. protocorm-like bodies by encapsulation-vitrification

Protocorm-like bodies (PLBs) of Dendrobium candidum Wall. ex Lindl., orchid, were successfully cryopreserved using an encapsulation vitrification method. PLBs were precultured in liquid Murashige and Skoog (MS) medium containing 0.2 mg l⁻¹ α-naphthalene acetic acid and 0.5 mg l⁻¹ 6-benzyladenine enriched with 0.75 M sucrose, and grown under continuous light (36 μmol m⁻² s⁻¹) at 25 ± 1°C for 5 days. PLBs were osmoprotected with a mixture of 2 M glycerol and 1 M sucrose for 80 min at 25°C and dripped in a 0.5 M CaCl₂ solution containing 0.5 M sucrose at 25 ± 1°C and left for 15 min to form Ca-alginate beads (about 4 mm in diameter). Then, these were dehydrated with a plant vitrification solution 2 (PVS₂) consisting of 30% (w/v) glycerol, 15% (w/v) ethylene glycol, and 15% (w/v) dimethyl sulfoxide in 0.5 M sucrose, pH 5.8, for 150 min at 0°C. Encapsulated and dehydrated PLBs were plunged directly into liquid nitrogen for 1 h. Cryopreserved PLBs were then rapidly re-warmed in a water bath at 40°C for 3 min and then washed with MS medium containing 1.2 M sucrose for three times at 10 min intervals. Within 60 days, plantlets with the cryopreserved PLBs developed normal shoots and roots, and without any observed morphological abnormalities, were obtained. The survival rate of encapsulated-vitrified PLBs was above 85%. Thus, this encapsulation-vitrification method was deemed promising for cryopreservation of PLBs of D. candidum.     

Effects of different sucrose concentrations on vitrified porcine preantral follicles: Qualitative and quantitative analysis

The aim of the present study was to perform a qualitative and quantitative analysis of the effect of different sucrose concentrations combined with ethylene glycol in the preservation of vitrified porcine preantral follicles. Fragments of ovarian cortex were vitrified in cryotubes containing 200 μl of the vitrification solution (30% Ethylene Glycol; 20% Fetal Bovine Serum; 0 M–0.25 M – 0.75 M or 1 M sucrose) and stored in liquid nitrogen for a week. Histological analysis showed that after vitrification the number of normal follicles decreased compared to the fresh tissue (control). The percentage of normal primordial follicles was sucrose dose dependent. The percentage of normal primary follicles was similar in 0 M or 0.25 M sucrose, while higher concentrations (0.75 M and 1 M) increased significantly the percentage of abnormal follicles (p < 0.05). Morphometric analysis showed a statistically significant reduction in the total area of primordial follicles with 0.75 M sucrose and a significant increase in the cytoplasmic area of primordial follicles with 0 M sucrose (p < 0.05). The qualitative and the quantitative analysis appear to be a complementary tool when choosing a vitrification protocol. For our cryopreservation system - vitrification of ovarian cortex slices in cryotubes-the best vitrification medium was TCM 199-Hepes with 30% de ethylene glycol, 20% of Fetal Bovine Serum and 0 or 0.25 M sucrose. The present study shows that the use of high sucrose concentrations in the vitrification solution has a deleterious effect on the preservation of porcine preantral follicles contained in ovarian tissue. Consequently, its use at 0.75 M or 1 M wouldn't be recommended.     

Effect of loading and vitrification solutions on survival of cryopreserved oil palm polyembryoids

The present study evaluates the effect of six loading solutions and five vitrification solutions (VS) and their time of exposure on the survival of oil palm (Elaeis guineensis) polyembryoids in liquid nitrogen (LN). In vitro grown polyembryoids of oil palm were successfully cryopreserved by vitrification with 45% survival. Individual polyembryoids, isolated from 2-month old culture, were precultured in liquid Murashige and Skoog medium supplemented with 0.5 M sucrose for 12 h and treated with a mixture of 10% (w/v) dimethyl sulphoxide (DMSO) plus 0.7 M sucrose for 30 min. Polyembryoids were then subjected to plant vitrification solution-2 (PVS2) (30% (w/v) glycerol plus 15% (w/v) EG plus 15% (w/v) DMSO plus 0.4 M sucrose) exposure for 5 min at 26 ± 2°C and subsequently plunged into LN. Thawed polyembryoids resumed growth within 8 days of culture and shoot development was recorded at 25 days of growth. Scanning electron micrograph revealed that successful regeneration of cryopreserved polyembryoids was due to stabilization of cellular integrity through optimum VS exposure.     

Encapsulation-Dehydration and Encapsulation-Vitrification Based Cryopreservation of in vitro-Grown Shoot-Tips of Medicinal Plant Astragalus membranaceus

Shoot tips of Amembranaceus excised from in vitro grown axillary bud were encapsulated in calcium alginate beads. Subsequently, shoot tips were precultured in liquid MS medium enriched with 075mol·L-1 sucrose for 5d at 25℃ and then desiccated aseptically on dried silica gel for 5h to a water content of 231% (fresh weight basis) prior to immersion in liquid nitrogen (LN) for 1d. After rewarming at a 40℃ water bath for 2-3min and transferred to solid culture medium for shoot tip recovery. About 50% of cryopreserved shoot tips grew into shoots within 2 weeks after plating. Cryopreservation of Astragalus membranaceus (Fisch.) Bge. shoot tips by encapsulation vitrification has also been developed. Excised shoot tips were firstly encapsulated into alginate gel beads and then precultured in liquid MS medium containing 1mg·L-1 6 BA, 005mg·L-1 NAA and 075mol·L-1 sucrose at 25℃ for 3d. After loading for 90min with a mixture of 2mol·L-1 glycerol and 04mol·L-1 sucrose at 25℃, shoot tips were dehydrated with PVS2 for 120min at 0℃ prior to direct immersion in liquid nitrogen for 1d. After rapidly thawing at a 37℃ water bath for 2-3min, shoot tips were washed for 10min with liquid MS medium supplemented with 1mg·L-1 6 BA, 005mg·L-1 NAA and 12mol·L-1 sucrose at 25℃ and then post cultured on solid MS medium supplemented with 2mg·L-1 6 BA, 005mg·L-1 NAA. The regeneration rate of shoot tips amounted to nearly 80%. Both of plantlets regenerated from cryopreserved shoot tips were morphologically uniform, which both showed as that of control plants. Thus, this encapsulation dehydration and encapsulation vitrification technique appears promising as a routine method for the cryopreservation of shoot tips of Amembranaceus.     

Cryopreservation of Shoot Tips of Tetraploid Potato (Solanum tuberosumL.) Clones by Vitrification

In vitro-grown shoot tips of five tetraploid potato (SolanumtuberosumL.) clones were cryopreserved by vitrification. Excisedshoot tips (0.5–0.7 mm) were pre-cultured on filter paperdiscs over half strength liquid Murashige and Skoog (MS) mediumsupplemented with 8.7 µMGA₃and different combinationsof sucrose (0.3, 0.5 and 0.7M) plus mannitol (0, 0.2 and 0.4M)for 2 d under a 16 h photoperiod at 24 °C. The pre-culturedshoot tips were either successively loaded with 20 and 60% PVS2 solutions or directly exposed to concentrated vitrificationsolution before physical vitrification during liquid nitrogentreatment. The vitrified shoot tips were warmed rapidly andtreated with dilution mixture (MS+1.2Msucrose) for 30 min beforeplating on regrowth medium. Addition of mannitol to the pre-culturemedium improved survival of vitrified shoot tips. Direct dehydrationof pre-cultured shoot tips with concentrated PVS 2 was detrimentalto survival of vitrified shoot tips. Shoot tips pre-culturedon medium containing 0.3Msucrose plus 0.2Mmannitol, and loadedwith 20% PVS 2 for 30 min followed by 15 min incubation in 60%PVS 2 and 5 min incubation in 100% PVS 2 at 0 °C resultedin up to 54% survival after vitrification. About 50% of vitrifiedand warmed shoot tips formed shoots directly. Post-thaw culturingof vitrified shoot tips on medium containing an elevated levelof sucrose (0.2M) under diffuse light for the first week enhancedthe survival rate. Continuous culturing of vitrified shoot tipson high-sucrose medium induced multiple shoot formation.Copyright1998 Annals of Botany Company Solanum tuberosumL., potato, cryopreservation, germplasm conservation,in vitroconservation, meristems, shoot tips, tissue culture, vitrification.     

High-efficiency vitrification protocols for cryopreservation of in vitro grown shoot tips of transgenic papaya lines

In vitro grown shoot tips of transgenic papaya lines (Carica papaya L.) were successfully cryopreserved by vitrification. Shoot tips were excised from stock shoots that were preconditioned in vitro for 45–50-day-old and placed on hormone-free MS medium with 0.09 M sucrose. After loading for 60 min with a mixture of 2 M glycerol and 0.4 M sucrose at 25°C, shoot tips were dehydrated with a highly concentrated vitrification solution (PVS2) for 80 min at 0°C and plunged directly into liquid nitrogen. The regeneration rate was approximately 90% after 2 months post-thawing. Successfully vitrified and warmed shoot tips of three non-transgenic varieties and 13 transgenic lines resumed growth within 2 months and developed shoots in the absence of intermediate callus formation. Dehydration with PVS2 was important for the cryopreservation of transgenic papaya lines. This vitrification procedure for cryopreservation appears to be promising as a routine method for cryopreserving shoot tips of transgenic papaya line germplasm.     

Cryopreservation of somatic embryos from <Emphasis Type="Italic">Petiveria alliacea</Emphasis> L. by different techniques based on vitrification

Petiveria alliacea L. is a medicinal plant originating from the Amazon region. This study describes an efficient cryopreservation protocol for somatic embryos (SEs) produced from roots of P. alliacea based on the comparison of vitrification, encapsulation-dehydration, and D cryo-plate techniques. With the vitrification technique, SEs treated with PVS2 solution (0.4 M sucrose, 3.3 M glycerol, 2.4 M ethylene glycol, and 1.9 M DMSO) for 30 min displayed high viability (85%) and intermediate proliferation recovery (about 12 adventitious SEs produced from original SEs [SEs/SE] after 90 d of culture). With the encapsulation-dehydration technique, lower viability (70%) and very low proliferation recovery (about two SEs/SE) were achieved with cryopreserved SEs dehydrated for 10 min in a laminar air flow cabinet. The D cryo-plate technique led to high viability (85%) and proliferation recovery (19 SEs/SE) of cryopreserved SEs after 90 min dehydration. In the experimental conditions tested, the D cryo-plate method was the most efficient technique for cryopreservation of P. alliacea SEs.     

Water status and thermal analysis of alginate beads used in cryopreservation of plant germplasm

Encapsulation and dehydration techniques using alginate beads are used increasingly for the pre-treatment of various plant materials for cryopreservation to improve survival post-cryogenic storage. This study reports the effects of the water content of beads (formed with 3% (w/v) alginic acid in liquid S-RIB), polymerisation time (in 100 mM calcium chloride solution), osmotic dehydration (in 0.75 M sucrose solution), and evaporative air desiccation on the thermal properties of alginate beads used in cryopreservation protocols. Experimental beads were assayed using a differential scanning calorimeter (DSC) with a cooling programme to -150 degrees C, followed by re-warming. Resultant thermograms were evaluated with particular reference to the onset temperature and enthalpy of the melt endotherm from which the quantities of frozen and unfrozen water were calculated. Treatments were applied sequentially to samples of beads and their thermal features evaluated at each stage of the protocol. Using 'standard' beads (40-55 mg fresh weight), formed using plastic disposable pipettes, the degree of polymerisation (>10 min) proportionally reduced their dry weight and increased their water content. Thermal characteristics of the beads were unaffected by polymerisation times >10 min, but the maximum level (23%) of unfrozen (osmotically inactive) water was achieved after 15 min polymerisation. Osmotic dehydration using 0.75 M sucrose significantly lowered bead water content and mean dry weight approximately doubled with 20-24 h immersion time. Bead desiccation in still air reduced their water content by 83% of fresh weight, whilst dry weight remained constant. After 8 h desiccation in air between 27 and 37% of the water in the bead was osmotically inactive (unfrozen) in DSC scans. Desiccation >18 h reduced this fraction to zero. The melt onset temperature and the enthalpy of melting were directly related to bead water content. The unfrozen water fraction increased substantially with reduced water content of the beads (from 23 to 37% of total water content), concomitant with a reduction in the ratio of unfrozen to frozen water from 1:3 to 1:2. For successful vitrification and the production of a glass that did not destabilise on rewarming, a bead water content of ca. 26% of fresh weight (0.4 g waterg(-1) dry weight) was required, much of which was osmotically inactive water. These data are discussed in relation to optimal pre-treatments for alginate bead encapsulation techniques used in the cryopreservation of a range of plant germplasm. It is proposed that increased standardisation of alginate beads, in terms of volume, fresh weight, and water content, is required to reduce the variability in physical and thermal features, which in turn will improve survival of plant samples post-cryopreservation.     

Advances in cryopreservation of vanilla (Vanilla planifolia Jacks.) shoot-tips: assessment of new biotechnological and cryogenic factors

The effect of dehydration, cryopreservation, and reculture conditions on growth recovery (%) of vanilla (Vanilla planifolia) shoot-tips was evaluated using a D-cryoplate procedure. Tissues were excised from in vitro grown plantlets, preconditioned on MS semisolid medium supplemented with 0.15 M trehalose for 1 d, loaded in a solution of 0.4 M sucrose or trehalose and 2 M glycerol for 30 min, and dehydrated within a laminar flow cabinet for various durations (30, 60, 90, 120, 150, and 180 min). The same preconditioning and loading treatments were compared using dehydration with vitrification solutions (PVS2 or PVS3) for 30 min at room temperature according to droplet-vitrification and V-cryoplate methods. The highest (33%) recovery of cryopreserved shoot-tips was achieved using the D-cryoplate method after 0.15 M trehalose preconditioning, loading with sucrose-glycerol solution and desiccation for 180 min. DSC analyses revealed that the osmotically active water (OAW) content of the shoot-tips was reduced from 77% (fresh weight basis) to 17% after the only effective drying duration (180 min). Melting endotherms indicated that crystallization events accompanied cryopreservation of the tissues. Proliferation of multiple shoots was obtained by indirect organogenesis. Histological analysis of the explants during post-cryopreservation recovery confirmed the organogenic nature of the callus formed after 3–4 mo of reculture in the dark on semisolid multiplication medium. This was followed by a secondary organogenesis on MS medium with kinetin (2 mg L⁻¹) and exposure to a photoperiod. At present, this is the most optimized cryopreservation protocol for shoot-tips of V. planifolia.