Cryopreservation of Indigenous Plums and Monitoring of Multiplication and Rooting Capacity of Shoots Obtained from Cryopreserved Specimens.

The objective of this study is to assess the suitability of vitrification cryo-plate (V cryo-plate) and dehydration cryo-plate (D cryo-plate) methods for the long-term conservation of eight autochthonous Prunus domestica L. genotypes originating from the Balkan Peninsula region. In vitro shoot tips were briefly pre-cultured for 1 day at 23 °C in the dark on a medium containing 0.3 M sucrose and then embedded in calcium alginate gel within the wells of the aluminum cryo-plates. In the V cryo-plate protocol, dehydration was carried out at room temperature using the following vitrification solutions: original plant vitrification solution 2 (PVS2) and 90% PVS2 solution (for 20 and 40 min) and plant vitrification solution 3 (PVS3) (for 60 and 80 min). In the D cryo-plate protocol, desiccation was performed for 2, 2.5, or 3 h over silica gel at 23 °C. The effect of different treatments was evaluated by monitoring the regrowth of both non-frozen and cryo-preserved explants. After cryo-preservation, five genotypes achieved regrowth rates over 40% in at least one of the applied protocols, while two genotypes showed regrowth rates of around 10%. A significant improvement in regrowth success for all genotypes using both cryo-plate methods was achieved by pre-culturing shoot tips for 7 days on a medium containing 0.5 M sucrose in complete darkness at 4 °C. Shoots regenerated from cryo-preserved explants were further monitored in vitro. By the third subculture, they had not only regained but had even exceeded the multiplication capacity (index of multiplication, length of axial, and lateral shoots) of shoots regenerated from dissection controls. Following multiplication, the cryo-preserved shoots were successfully rooted and rooting ability was assessed by monitoring the percentage of rooting, number and length of roots, and height of rooted plantlets.

Cryopreservation of carnation (Dianthus caryophyllus L.) and other Dianthus species.

MAIN CONCLUSION: This paper reviews the cryopreservation of the ornamental, carnation (Dianthus caryophyllus L.), as an important method for the long-term preservation of this plant's germplasm. Carnation (Dianthus caryophyllus L.) is an important ornamental plant that is used as a potted plant as well as a cut flower. Important Dianthus germplasm would benefit from long-term strategies such as cryopreservation. Unlike the in vitro tissue culture literature of this ornamental, which has been studied in considerable detail, and with several genetic transformation protocols, surprisingly, the literature on its cryopreservation is still fairly scant, with barely two dozen or so studies, mostly having employed shoot tips. Early (< 2007) and more recent (2007-2020) cryopreservation techniques for carnation, including ultra-rapid cooling, encapsulation-vitrification, and encapsulation-dehydration, efficiently replaced programmed slow cooling processes used in early studies in the 1980s. Two large gaps (1997-2006, and 2016-2020) in which no carnation cryopreservation studies were published, requires future studies to cover new knowledge to fill gaps in information. Carnation cryopreservation research would benefit from testing a wide range of in vitro explants, new techniques such as the cryo-mesh, improved regeneration protocols for post-cryopreserved material, and the use of low-temperature storage as a mid- to long-term complementary germplasm storage strategy. This mini-review provides details of what has been achieved thus far and future objectives that could fortify cryopreservation research of this ornamental, as well as provide a robust long-term germplasm repository.

Long-term conservation of Tarenaya rosea (Cleomaceae) root cultures: histological and histochemical analyses during cryopreservation using the encapsulation-vitrification technique.

Adventitious root cultures of Tarenaya rosea were successfully cryopreserved using the encapsulation-vitrification technique. Histological analysis revealed useful information on the successive steps of cryopreservation. Coupled with complementary histochemical approaches, these studies provided cellular and tissue descriptions of T. rosea root cultures during cryopreservation and contributed to an understanding of cellular stress responses, as well as characterization of the anatomical pattern of root regeneration. The effects of exposure duration to PVS3 solution (0-120 min), unloading treatment (direct and gradual), and recovery medium (liquid and solid) on recovery of cryopreserved roots were investigated. The highest recovery (91%) after cooling in liquid nitrogen (LN) was reached with PVS3 treatment for 90 min, gradual rehydration in unloading solution, and recovery on solid MS medium. The cryopreserved roots showed high multiplication capacity, which was maintained for up to four subcultures. The effect of cryopreservation on root structure was investigated by histological and histochemical studies. Plasmolysis intensified during exposure to loading and PVS3 solutions, but decreased after unloading treatment. The proportion of intercellular spaces increased progressively throughout the cryopreservation protocol, culminating in root cortex disruption. Histochemical analyses revealed polysaccharides, proteins, and both lipidic and pectic substances in intercellular spaces. The vascular cylinder remained intact, ensuring the formation of new roots from the pericycle, showing that proliferative capacity of cryopreserved roots had not diminished.

Histological characterization of Passiflora pohlii Mast. root tips cryopreserved using the V-Cryo-plate technique.

Cryopreservation stands out as the main strategy to ensure safe and cost efficient long-term conservation of plant germplasm, especially for biotechnological materials. However, the injuries associated with the procedure may result in structural damage and low recovery rates after cooling. Histological analysis provides useful information on the effects of osmotic dehydration, LN exposure, and recovery conditions on cellular integrity and tissue organization, allowing the determination of the critical steps of the cryopreservation protocol and, thus, the use of optimized treatments. Passiflora pohlii Mast. (Passifloraceae) is a native species from Brazil with potential agronomic interest. Recent studies showed the presence of saponins in its roots, which presented antioxidant activity. The goal of this work was to develop a cryopreservation technique for root tips of in vitro-derived plants of P. pohlii using the V-Cryo-plate technique and to characterize the anatomical alterations that occurred during the successive steps of the protocol. Root tips were excised from in vitro plants and precultured before adhesion to cryo-plates and then treated for different periods with the plant vitrification solutions PVS2 or PVS3. Treatment with PVS2 for 45 min resulted in higher recovery (79%) when compared with PVS3 (43%). The greatest number of adventitious roots per cryopreserved explant was also observed after a 45-min exposure to PVS2. Plasmolysis levels were higher in cortical cells of cryopreserved explants treated with PVS2, while pericycle and central cylinder cells were not damaged after this treatment. Thirty days after rewarming, no plasmolysis could be detected, regardless of the experimental conditions.

Cryopreservation of Date Palm Pro-Embryonic Masses Using the D Cryo-plate Technique.

In this chapter, we describe a cryopreservation (liquid nitrogen, -196 °C) protocol developed for long-term storage of date palm pro-embryonic masses (PEMs), which uses the recently established D cryo-plate technique. Clumps of PEMs (3-5 mm in size) were dissected from PEM cultures and placed on pretreatment medium containing 171 g/L sucrose for 3 days. Clumps were placed in the wells of aluminum cryo-plates in which they were made to adhere using droplets of 3% calcium alginate. PEMs were treated for 20 min with a loading solution containing 184 g/L glycerol and 136.8 g/L sucrose. They were then dehydrated for 90-120 min in the air current of a laminar airflow cabinet and immersed directly in liquid nitrogen. For rewarming, the cryo-plates holding the PEMs were immersed for 15 min in an unloading solution containing 410.4 g/L sucrose. The PEMs were then detached from the cryo-plates, placed for 3 days in the dark on posttreatment medium containing 102.6 g/L sucrose, and transferred on recovery medium under light conditions. Using this protocol, 74.6 and 95.8% recovery were achieved with the PEMs of the two cultivars tested, Sukkari and Sultany.

Cryopreservation of oil palm (Elaeis guineensis Jacq.).

Oil palm (Elaeis guineensis Jacq.), a tropical plant, is the leading source of edible oil. This review deals with the cryopreservation of oil palm as a way to preserve this important tropical germplasm. Somatic embryos have been the most popular source of material for cryopreservation as they are propagules that are effectively produced during micropropagation. In contrast, fewer studies exist on the cryopreservation of pollen, zygotic embryos, seeds, kernels and embryogenic cell suspensions. This review highlights the ideal protocols, in detail, in a bid to offer guidance for further advances in oil palm cryopreservation.

Frozen beauty: The cryobiotechnology of orchid diversity.

Orchids (Orchidaceae) are one of the most diverse plant groups on the planet with over 25,000 species. For over a century, scientists and horticulturalists have been fascinated by their complex floral morphology, pollinator specificity and multiple ethnobotanical uses, including as food, flavourings, medicines, ornaments, and perfumes. These important traits have stimulated world-wide collection of orchid species, often for the commercial production of hybrids and leading to frequent overexploitation. Increasing human activities and global environmental changes are also accelerating the threat of orchid extinction in their natural habitats. In order to improve gene conservation strategies for these unique species, innovative developments of cryopreservation methodologies are urgently needed based on an appreciation of low temperature (cryo) stress tolerance, the stimulation of recovery growth of plant tissues in vitro and on the 'omics' characterization of the targeted cell system (biotechnology). The successful development and application of such cryobiotechnology now extends to nearly 100 species and commercial hybrids of orchids, underpinning future breeding and species conservation programmes. In this contribution, we provide an overview of the progress in cryobanking of a range of orchid tissues, including seeds, pollen, protocorms, protocorm-like bodies, apices excised from in vitro plants, cell suspensions, rhizomes and orchid fungal symbionts. We also highlight future research needs.

IMPACT OF LIQUID NITROGEN EXPOSURE ON SELECTED BIOCHEMICAL AND STRUCTURAL PARAMETERS OF HYDRATED Phaseolus vulgaris L. SEEDS.

BACKGROUND: It is well known that cryopreserving seeds with high water content is detrimental to survival, but biochemical and structural parameters of cryostored hydrated common bean seeds have not been published. OBJECTIVE: The objective of this work was to study the effect of liquid nitrogen exposure on selected biochemical and structural parameters of hydrated Phaseolus vulgaris seeds. MATERIALS AND METHODS: We cryopreserved seeds at various moisture contents and evaluated: germination; electrolyte leakage; fresh seed weight; levels of chlorophyll pigments, malondialdehyde, other aldehydes, phenolics and proteins; thickness of cotyledon epidermis, parenchyma, and starch storage parenchyma; and radicle and plumule lengths. RESULTS: Germination was totally inhibited when seeds were immersed in water for 50 min (moisture content of 38%, FW basis) before cryopreservation. The combined effects of seed water imbibition and cryostorage decreased phenolics (free, cell wall-linked, total), chlorophyll a and protein content. By contrast, electrolyte leakage and levels of chlorophyll b and other aldehydes increased as a result of the combination of these two experimental factors. These were the most significant effects observed during exposure of humid seed to liquid nitrogen. CONCLUSION: Further studies are still required to clarify the molecular events taking place in plant cells during cryostorage.

Towards a vitrification-based cryopreservation protocol for the coral Pocillopora damicornis L.: Tolerance of tissue balls to 4.5 M cryoprotectant solutions.

In this study, we tested the tolerance of tissue balls (TBs, 100-400 µm in diameter) from the coral Pocillopora damicornis produced using mechanical excision to exposure to cryoprotectant (CPA) solutions. TBs were treated for 20 min at room temperature with individual, binary, ternary or quaternary CPA solutions with a total molarity from 2.0 to 5.0M. Four CPAs were used: ethylene glycol (EG), dimethylsulfoxide (Me2SO), methanol (Met) and glycerol (Gly). In some experiments, the molarity of the CPA solutions was increased and decreased in a stepwise manner. The tolerance of TBs following CPA treatment was evaluated using two parameters. The Tissue Ball Regression (expressed in µm/h) measured the diameter regression of TBs over time. The % Undamaged TBs quantified the proportion of TBs, which remained intact over time after the CPA treatment. TBs tolerated exposure to binary solutions with a total molarity of 4.0 M containing 2.0 M EG+2.0 M Met and 2.0 MEG+2.0 M Gly. TBs displayed tolerance to ternary solutions with a total molarity up to 3.0 M, containing each CPA at 1.0 M. Quaternary solutions with a total molarity of 4.0M containing each CPA at 1.0 M were not tolerated by TBs. When the molarity of the CPA solutions was increased and decreased in a stepwise manner, TBs withstood exposure to a CPA solution with a total molarity of 4.5 M, containing 1.5 M EG+1.5 M Gly+1.5 M Me(2)SO. This study confirmed the interest of using TBs to test CPA solutions, with the objective of developing a vitrification-based cryopreservation protocol.

Survival of tissue balls from the coral Pocillopora damicornis L. exposed to cryoprotectant solutions.

In this study, the tolerance of tissue balls (TBs, 100-300 µm in diameter) from the coral Pocillopora damicornis produced using mechanical excision to exposure to cryoprotectant (CPA) solutions was tested. TBs were treated for 20 min at room temperature with solutions of ethylene glycol (EG), methanol (Met), glycerol (Gly) or dimethyl sulfoxide (Me2SO) at concentrations between 1.0 and 4.5M. Two parameters were used to evaluate the survival of TBs following CPA treatment. The Undamaged Duration of Tissue Balls (expressed in h) corresponded to the time period during which the membrane surface of TBs remained smooth and their motility was preserved. Tissue Ball Regression (expressed in µm/h) corresponded to the size reduction of TBs over time. TBs tolerated exposure to all CPAs tested at the three lower concentrations employed (1.0 M, 1.5 M and 2.0 M). No survival was achieved following exposure to a 4.5 M CPA solution. At concentrations of 3.0 and 4.0 M, higher Undamaged Duration of Tissue Balls and lower Tissue Ball Regression were obtained following treatment with EG compared to the other three CPAs. Our experiments show that TBs constitute a good experimental material to evaluate CPA toxicity on corals using large numbers of samples. Performing preliminary experiments with TBs may allow reducing the number of tests carried out with less easily available coral forms such as planulae, thereby preserving larval stocks.

Effect of shooting medium and source of material on grapevine (Vitis vinifera L.) shoot tip recovery after cryopreservation.

BACKGROUND: Selecting experimental material at the optimal physiological stage is of paramount importance for successful cryopreservation. OBJECTIVE: The study was to investigate the effect of the physiological state of grapevine buds on their regrowth after liquid nitrogen exposure. METHODS: In a first set of experiments, we tested the regrowth of cryopreserved buds sampled from microcuttings cultured on shooting medium containing benzylaminopurine or zeatin riboside for various durations. In a second set of experiments, we studied the regrowth after liquid nitrogen exposure of buds sampled from different positions on the stem of in vitro plantlets. RESULTS: Regrowth of cryopreserved buds sampled from microcuttings was higher (30%), compared to buds sampled directly from in vitro plantlets (23%), for all culture durations of microcuttings on shooting medium tested (2-6 weeks). Addition of cytokinin in the shooting medium improved regrowth of cryopreserved buds compared to buds sampled from microcuttings cultured on medium devoid of growth regulators; however similar results were obtained with the two cytokinins tested. Buds sampled on nodes 3-4 and 6-7 (from the top of the stem) displayed higher regrowth compared to shoot tips. No significant differences were noted in regrowth after cryopreservation between buds sampled from microcuttings produced from the terminal node, or nodes 3-4 and 6-7. CONCLUSION: The physiological state of the plant material is important for cryopreservation success. Actively growing buds sampled from microcuttings displayed higher regrowth compared to buds sampled directly on in vitro plantlets.

Tolerance of apexes of coral Pocillopora damicornis L. to cryoprotectant solutions.

In this study, we investigated the tolerance of Pocillopora damicornis apexes to treatments with solutions containing penetrating and non-penetrating cryoprotective agents (CPAs). CPAs were employed individually or in binary, tertiary or quaternary solutions. In some experiments apexes were treated successively with two CPA solutions with increasing total concentration. P. damicornis apexes withstood exposure for up to 30 min to solutions containing 0.6-0.8 M sucrose (Suc) or trehalose (Tre). When apexes were treated with binary cryoprotectant solutions containing Suc and ethylene glycol (EG), methanol (Meth), dimethyl sulfoxide (Me(2)SO) or glycerol (Gly), the CPAs employed in combination with Suc could be ranked in the following order of decreasing tolerance: EG>Meth>Me(2)SO>Gly. P. damicornis apexes tolerated exposure to complex CPA solutions containing Suc, Me(2)SO, EG and/or Meth with a total molarity of 2.45 M. In experiments where two successive CPA solutions were employed, apexes withstood treatment with the second, more concentrated solution at 0°C for up to 10 min. These preliminary results pave the way to the development of a cryopreservation protocol for P. damicornis apexes.

Effect of the successive steps of a cryopreservation protocol on the structural integrity of Rubia akane Nakai hairy roots.

In this work, we studied the impact of the successive steps of the droplet-vitrification protocol technique employed for cryopreservation of Rubia akane hairy roots on the features of cortical, pericycle and endoderm cells of apical and central root segments, using histology techniques and combining qualitative and quantitative observations. In apical segments, plasmolysis (22-71 %, depending on cell type) was observed only after the loading treatment and did not increase after the following steps of the protocol. By contrast, in central segments, plasmolysis (39-45 %) was already observed after the sucrose pretreatment; it increased to 54-68 %, depending on cell type, after the loading treatment, but no further changes were noted after treatment with the vitrification solution. After liquid nitrogen exposure and unloading treatment, deplasmolysis was more rapid in apical segments, with cortical and pericycle cells having retrieved their original features. In central segments, only cortical cells had retrieved their original features and endoderm and pericycle cells were still highly plasmolysed. Nuclei were more strongly impacted by the cryopreservation protocol in central segments, where they displayed a highly condensed nucleoplasm from the loading treatment onwards and had not retrieved their original aspect after the unloading treatment. By contrast, nuclei had a much less condensed nucleoplasm in cells of apical segments, and they had retrieved their original aspect after the unloading treatment.

Histocytological analysis of yam (Dioscorea alata) shoot tips cryopreserved by encapsulation-dehydration.

In this work, we performed qualitative and quantitative observations of the cytological changes occurring in cells of yam (Dioscorea alata) in vitro shoot tips cryopreserved using the encapsulation-dehydration (E-D) technique. Shoot tip osmoprotection for 24 h in 1.25 M sucrose medium induced drastic changes in cellular cytological features, including high plasmolysis in all three cellular areas studied, the external cell layer (L1), one to three (L1-3) and seven to nine (L7-9) cell layers from the surface of the meristematic dome, pyknotic nuclei in meristematic area cells and disappearance of nucleoli. Nucleus size decreased significantly in all cellular areas studied. Nucleocytoplasmic ratio decreased significantly in L1-3 and L7-9 cells. Nuclear protein content increased, particularly in L1 and L1-3 cells. After physical dehydration, plasma membrane of numerous basal part cells was broken and intracellular soluble protein leakage was observed. Nucleus area and nucleocytoplasmic ratio decreased significantly in L7-9 cells. One week after cryopreservation, shoot tips showed regrowth and living cells had recovered their original morphology. In all cellular areas studied, nuclei had retrieved their original staining and nucleoli were visible. Original nucleus area values were recovered in L1-3 and L1 cells. The nucleocytoplasmic ratio retrieved its initial value in L1 cells but remained at levels observed after osmoprotection for L1-3 and L7-9 cells. The nuclear protein content had retrieved its original level. This investigation provided new insights in changes occurring in D. alata apices throughout an E-D protocol.

Recent advances in the cryopreservation of shoot-derived germplasm of economically important fruit trees of Actinidia, Diospyros, Malus, Olea, Prunus, Pyrus and Vitis.

This paper presents the advances made over the last decade in cryopreservation of economically important vegetatively propagated fruit trees. Cryopreservation protocols have been established using both dormant buds sampled on field-grown plants and shoot tips sampled on in vitro plantlets. In the case of dormant buds, scions are partially dehydrated by storage at -5 °C, and then cooled slowly to -30 °C using low cooling rates (c.a. 1 °C/h) before immersion in liquid nitrogen. After slow rewarming and rehydration of samples, regrowth takes place either through grafting of buds on rootstocks or excision of apices and inoculation in vitro. In the case of shoot tips of in vitro plantlets, the cryopreservation techniques employed are the following: controlled rate cooling procedures involving slow prefreezing followed by immersion in liquid nitrogen or vitrification-based procedures including encapsulation-dehydration, vitrification, encapsulation-vitrification and droplet-vitrification. The current status of cryopreservation for a series of fruit tree species including Actinidia, Diospyros, Malus, Olea, Prunus, Pyrus and Vitis is presented. Routine application of cryopreservation for long-term germplasm storage in genebanks is currently limited to apple and pear, for which large cryopreserved collections have been established at NCGRP, Fort Collins (USA), using dormant buds and in vitro shoot tips, respectively. However, there are a growing number of examples of pilot scale testing experiments under way for different species in various countries. Progress in the further development and application of cryopreservation techniques will be made through a better understanding of the mechanisms involved in the induction of tolerance to dehydration and cryopreservation in frozen explants.

Effects of cryopreservation of Phaseolus vulgaris L. seeds on early stages of germination.

In this work, we studied the effects of cryopreservation on various parameters of early stages of germination of Phaseolus vulgaris seeds (0, 7 and 14 days). Percentages of germination, fresh mass of different plant parts, levels of chlorophyll pigments (a, b, total), malondialdehyde, other aldehydes, phenolics (cell wall-linked, free, and total) and protein were determined. No phenotypic changes were observed visually in seedlings recovered from cryopreserved seeds. However, several significant effects of seed liquid nitrogen exposure were recorded at the biochemical level. There was a significant negative effect of cryopreservation on shoot protein content, which decreased from 3.11 mg g(-1) fresh weight for non-cryopreserved controls to 0.44 mg g(-1) fresh shoot weight for cryopreserved seeds. On the other hand, cryopreservation significantly increased levels of other aldehydes than malondialdehyde in shoots at day 7, from 56.47 µmol g(-1) for non-cryopreserved controls to 253.19 µmol g(-1) fresh shoot weight for cryopreserved samples. Liquid nitrogen exposure significantly reduced phenolics contents (free, cell-wall linked, total) in roots at day 7 after onset of germination. In general, roots were more affected by cryostorage compared with other plant parts, while leaves were the least affected. The effects of seed cryopreservation seem to decline progressively along with seedling growth.

In vitro culture of coconut (Cocos nucifera L.) zygotic embryos.

Coconut is a very important crop for millions of people in tropical countries. With coconut, in vitro culture protocols have been developed with two main objectives, viz. the large scale production of particular types of coconuts and the international exchange and conservation of coconut germplasm. The methods described in this chapter have been developed in the framework of collaborative activities between research institutes in Côte d'Ivoire and France. Two coconut embryo in vitro collecting protocols have been established, one consisting of storing the disinfected embryos in a KCl solution until they are brought back to the laboratory, where they are re-disinfected and inoculated in vitro under sterile conditions, and the other including in vitro inoculation of the embryos in the field. For international germplasm exchange, zygotic embryos inoculated in vitro in plastic test tubes or endosperm cylinders containing embryos in plastic bags are used. For in vitro culture, embryos are inoculated on semi-solid medium supplemented with sucrose and activated charcoal and placed in the dark, and then transferred to light conditions with the same (solid or liquid) medium once the first true leaf is visible and the root system has started developing.

Cryopreservation of embryos: an overview.

Cryopreservation (liquid nitrogen, -196°C) is the only safe and cost-effective option for long-term -conservation of genetic resources of non-orthodox seed species. Cryopreservation protocols have been developed for various materials including seeds, dormant buds, cell suspensions, calli, apices, zygotic, and somatic embryos of numerous plant species. Zygotic embryos or embryonic axes of almost 100 different species and somatic embryos of almost 40 different species from both temperate and tropical climates, comprising crops, fruit, and forest trees as well as wild species, whose seeds displayed orthodox, intermediate, and recalcitrant storage characteristics, have been successfully cryopreserved. With zygotic embryos and embryonic axes, the desiccation technique has been used with the majority of the species tested, leading to highly variable survival and recovery after freezing, especially during earlier experiments. More recently, new cryopreservation techniques viz. encapsulation-dehydration and vitrification have been employed, leading to generally improved results. With somatic embryos, different cryopreservation methods have been used viz. desiccation, pre-growth-desiccation, encapsulation-dehydration, vitrification, encapsulation-vitrification, and droplet-vitrification. There are also a few examples of the utilisation of slow controlled freezing, which correspond to the earlier experiments performed with somatic embryos. The development and application of cryopreservation is significantly more advanced for somatic embryos, in comparison with zygotic embryos, mainly because of the different origin and characteristics of the species treated. In most cases, zygotic embryos originate from tropical, wild species, for which knowledge and techniques relevant to the development of cryopreservation protocols are limited, or even non-existent. By contrast, somatic embryos are generally produced from cultivated species, which have already been studied extensively and for which propagation techniques are already operational. A number of technical possibilities to explore exist in order to improve the development of cryopreservation protocols for zygotic embryos and embryonic axes. For both categories of materials, the utilisation of analytical techniques has proved to be extremely useful to assist in the development of cryopreservation protocols.

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.

Improved cryopreservation of chrysanthemum (Chrysanthemum morifolium) using droplet-vitrification.

A droplet-vitrification protocol has been established for cryopreserving Chrysanthemum morifolium cv. Peak using axillary shoot tips and apical shoots of in vitro plants. In the optimized procedure, explants were submitted to a step-wise preculture in liquid sucrose-enriched medium (0.3, 0.5 and 0.7 M for 31,17 and 7 h, respectively). Precultured explants were treated for 40 min with C4 loading solution comprising (w/v) 17.5 percent glycerol + 17.5 percent sucrose, then dehydrated with PVS3 vitrification solution (w/v, 50 percent glycerol + 50 percent sucrose) for 60 min (axillary shoot tips) or 90 min (apical shoots). Explants were cryopreserved by direct immersion in liquid nitrogen in minute drops of PVS3 attached to aluminum foil strips. The optimal age of donor plants was 4-5.5 weeks for apical shoots and 7 weeks for axillary shoot tips, producing post-cryopreservation regeneration percentages of 81.9 percent and 84.9 percernt, respectively. Plants regenerated from cryopreserved samples showed no phenotypical abnormalities and similar profiles of relative DNA content were recorded for control and cryopreserved plants. Our results suggest that the modified droplet-vitrification protocol described in this paper is highly effective and may prove user-friendlier than the cryopreservation protocols already published for chrysanthemum.