Desiccation sensitivity and tolerance in the moss <Emphasis Type="Italic">Physcomitrella patens</Emphasis>: assessing limits and damage

The moss Physcomitrella patens is becoming the model of choice for functional genomic studies at the cellular level. Studies report that Physcomitrella survives moderate osmotic and salt stress, and that desiccation tolerance can be induced by exogenous ABA. Our goal was to quantify the extent of dehydration tolerance in wild type moss and to examine the nature of cellular damage caused by desiccation. We exposed Physcomitrella to humidities that generate water potentials from −4 (97% RH) to −273 MPa (13% RH) and monitored water loss until equilibrium. Water contents were measured on a dry matter basis to determine the extent of dehydration because fresh weights (FW) were found to be variable and, therefore, unreliable. We measured electrolyte leakage from rehydrating moss, assessed overall regrowth, and imaged cells to evaluate their response to drying and rehydration. Physcomitrella did not routinely survive water potentials <−13 MPa. Upon rehydration, moss dried to water contents >0.4 g g dm⁻¹ maintained levels of leakage similar to those of hydrated controls. Moss dried to lower water contents leaked extensively, suggesting that plasma membranes were damaged. Moss protonemal cells were shrunken and their walls twisted, even at −13 MPa. Moss cells rehydrated after drying to −273 MPa failed to re-expand completely, again indicating membrane damage. ABA treatment elicited tolerance of desiccation to at least −273 MPa and limited membrane damage. Results of this work will form the basis for ongoing studies on the functional genomics of desiccation tolerance at the cellular level.     

NMR metabolite profiling analysis reveals changes in phospholipid metabolism associated with the re-establishment of desiccation tolerance upon osmotic stress in germinated radicles of cucumber

The adaptation of metabolism is thought to play a role in the acquisition of desiccation tolerance (DT). However, the importance of such a role and whether specific regulatory pathways exist remain to be assessed. Using in vitro 31P and 13C nuclear magnetic resonance (NMR) spectroscopy and biochemical assays, we analysed metabolite profiles of perchloric extracts from germinating radicles of cucumber to identify changes in carbon and phosphate metabolism associated with DT. Emerged radicles measuring 2 mm long can be rendered tolerant to desiccation by incubation in a polyethylene glycol (PEG) solution with a water potential of 1.5 MPa. However, in 4-mm-long emerged radicles, this treatment was ineffective. This manipulable system enabled the discrimination of changes in metabolites associated with DT from those associated with the response to osmotic stress. Independent of radicle length, the PEG treatment resulted in an increase in sucrose (Suc) content, whereas glucose (Glc), fructose (Fru) and the hexose phosphate pool, as well as phosphoenolpyruvate decreased three- to fourfold. In addition, three derivatives arising early during phospholipid catabolism (glycerylphosphorylcholine, glycerylphosphorylethanolamine and glycerylphosphorylinositol) appeared in the PEG-treated radicles. Interestingly, phospholipid degradation was much more pronounced in osmotically challenged radicles that remain sensitive to drying. This was proved by the appearance of catabolites, such as phosphocholine and phosphoethanolamine, solely in 4 mm PEG-treated radicles. Furthermore, glycerol-3-phosphate and its derivative 3-phosphoglycerate increased significantly. Our data suggest that the metabolic response leading to the re-establishment of DT is not entirely identical to that of an osmotic response. It is inferred that membrane remodelling and/or increased phospholipid catabolism is an adaptive response common to osmotic adjustment and DT but is controlled differently in tolerant and sensitive radicles.     

The role of sugars and hexose phosphorylation in regulating the re-establishment of desiccation tolerance in germinated radicles of Cucumis sativa and Medicago truncatula

This study examined whether sugars and hexose phosphorylation participate in the regulatory mechanisms that induce desiccation tolerance (DT) in seeds. In germinated desiccation-sensitive radicles of Cucumis sativa and Medicago truncatula , DT was re-established by an osmotic treatment using polyethylene glycol (PEG) for several days. In cucumber, Glc kinase activity (EC 2.7.1.1) transiently peaked early during PEG incubation before the induction of DT in protruded radicles, whereas Fru kinase activity (EC 2.7.1.4) increased progressively during the re-establishment of DT. Glucosamine (GAM, a competitive inhibitor of HXK) was able to repress the PEG-induced DT in both species, whereas hexose and poorly metabolizable hexose analogues had no effect. GAM was effective in repressing DT only early during PEG incubation, indicating that this effect is transient. Both Glc and Man fully rescued GAM-inhibited DT. PEG-induced accumulation of Suc was not affected by GAM. Isocitrate lyase (ICL) gene expression, which is known to be regulated by hexoses, responded to the re-establishment of DT and GAM feeding. In cucumber, expression of ICL was repressed after 6 h of PEG incubation whereas GAM feeding led to ICL de-repression. When GAM could no longer inhibit the re-establishment of DT, neither were steady-state levels of ICL influenced. The implication of HXK as a catalytic regulator and sugar-sensor in DT is discussed.     

Dehydration-induced redistribution of amphiphilic molecules between cytoplasm and lipids is associated with desiccation tolerance in seeds

This study establishes a relationship between desiccation tolerance and the transfer of amphiphilic molecules from the cytoplasm into lipids during drying, using electron paramagnetic resonance spectroscopy of amphiphilic spin probes introduced into imbibed radicles of pea (Pisum sativum) and cucumber (Cucumis sativa) seeds. Survival following drying and a membrane integrity assay indicated that desiccation tolerance was present during early imbibition and lost in germinated radicles. In germinated cucumber radicles, desiccation tolerance could be re-induced by an incubation in polyethylene glycol (PEG) before drying. In desiccation-intolerant radicles, partitioning of spin probes into lipids during dehydration occurred at higher water contents compared with tolerant and PEG-induced tolerant radicles. The difference in partitioning behavior between desiccation-tolerant and -intolerant tissues could not be explained by the loss of water. Consequently, using a two-phase model system composed of sunflower or cucumber oil and water, physical properties of the aqueous solvent that may affect the partitioning of amphiphilic spin probes were investigated. A significant relationship was found between the partitioning of spin probes and the viscosity of the aqueous solvent. Moreover, in desiccation-sensitive radicles, the rise in cellular microviscosity during drying commenced at higher water contents compared with tolerant or PEG-induced tolerant radicles, suggesting that the microviscosity of the cytoplasm may control the partitioning behavior in dehydrating seeds.     

Metabolic dysfunction and unabated respiration precede the loss of membrane integrity during dehydration of germinating radicles

This study shows that dehydration induces imbalanced metabolism before loss of membrane integrity in desiccation-sensitive germinated radicles. Using a photoacoustic detection system, responses of CO(2) emission and fermentation to drying were analyzed non-invasively in desiccation-tolerant and -intolerant radicles of cucumber (Cucumis sativa) and pea (Pisum sativum). Survival after drying and a membrane integrity assay showed that desiccation tolerance was present during early imbibition and lost in germinated radicles. However, tolerance could be re-induced in germinated cucumber radicles by incubation in polyethylene glycol before drying. Tolerant and polyethylene glycol (PEG)-induced tolerant radicles exhibited a much-reduced CO(2) production before dehydration compared with desiccation-sensitive radicles. This difference was maintained during dehydration. In desiccation-sensitive tissues, dehydration induced an increase in the emission of acetaldehyde and ethanol that peaked well before the loss of membrane integrity. Acetaldehyde emission from sensitive radicles was significantly reduced when dehydration occurred in 50% O(2) instead of air. Acetaldehyde/ethanol were not detected in dehydrating tolerant radicles of either species or in polyethylene glycol-induced tolerant cucumber radicles. Thus, a balance between down-regulation of metabolism during drying and O(2) availability appears to be associated with desiccation tolerance. Using Fourier transform infrared spectroscopy, acetaldehyde was found to disturb the phase behavior of phospholipid vesicles, suggesting that the products resulting from imbalanced metabolism in seeds may aggravate membrane damage induced by dehydration.     

Drought-induced oxidative damage and antioxidant responses in peanut (<Emphasis Type="Italic">Arachis</Emphasis><Emphasis Type="Italic">hypogaea</Emphasis> L.) seedlings

Two cultivars of peanut (Arachis hypogaea L.) which were designated as resistant (Florispan) and sensitive (Gazipasa) according to their growth retardation under drought stress conditions were compared for their oxidative damage and antioxidant responses. Sixteen days-old peanut seedlings were subjected to PEG-6000 solutions of two different osmotic potentials; −0.4 and −0.8 MPa, and various growth parameters, photosystem II activity, changes in malondialdehyde (MDA), hydrogen peroxide (H₂O₂) and proline levels, activities of ascorbate peroxidase (APX), catalase (CAT), peroxidase (POX) and gluthatione reductase (GR) enzymes were determined. Both cultivars exhibited water deficit at −0.8 MPa osmotic potential of PEG-6000 and H₂O₂ levels significantly increased during exposure to −0.4 MPa osmotic potential. However, H₂O₂ levels were under control in both cultivars at exposure to −0.8 MPa osmotic potential. Significant proline accumulation was observed in the tissues of cv. Florispan at −0.8 MPa osmotic potential, whereas proline accumulation did not appear to be an essential part of the protection mechanism against drought in cv. Gazipasa. No significant variation in chlorophyll fluorescence values were detected in neither of the cultivars. Enzyme activity measurements revealed that Gazipasa copes well with lesser magnitudes of drought stress by increasing the activity of mainly APX, and during harsh stress conditions, only APX maintains its activity in the tissues. In cultivar Florispan, GR activity appears to take role in lesser magnitudes of drought stress, whereas CAT and APX activities appear to be very crucial antioxidative defenses during intense stress conditions. The results indicate that, the level of proline and activities of the enzymes CAT and APX are important mechanisms for the maintenance of drought tolerance in peanut plants.     

Development of desiccation tolerance and vitrification by preculture treatment in suspension-cultured cells of the liverwort Marchantia polymorpha

Some cultured plant cells are able to acquire tolerance to various stresses when they are cultured under suitably controlled conditions. Induction of a high level of desiccation tolerance in suspension-cultured cells of the liverwort Marchantia polymorpha was examined for studying the mechanisms of desiccation tolerance and vitrification at the cellular level. Desiccation tolerance level of cells was very low and the survival rate was less than 10% after exposure to drying below 0.1 g H₂O g⁻¹ dry weight (DW). Preculture treatment in 0.5 M sucrose medium was the most effective method for inducing a high level of desiccation tolerance in cells and the survival rate was 87% even after being desiccated to below 0.1 g H₂O g⁻¹ DW. Preculture treatment caused alteration of cell structures and accumulation of a large amount of sucrose and newly synthesized proteins in cells. Abundant sucrose and preculture-induced proteins were necessary for full development of desiccation tolerance in the cells. When water content decreased to below 0.1 g H₂O g⁻¹ DW, desiccation-tolerant cells that had been precultured were vitrified above 0°C and maintained stable viability. We have succeeded in the induction of desiccation tolerance that allows formation of intracellular glass with cell viability at ambient temperatures by controlling culture conditions, and our results suggest that suspension-cultured cells of M. polymorpha are useful for studying cellular mechanisms for the development of desiccation tolerance and the stabilization of vitrified cells.     

In vitro germination and development of western hemlock dwarf mistletoe

A procedure for in vitro culture of the parasitic flowering plant western hemlock dwarf mistletoe, Arceuthobium tsugense (Rosend.) G.N. Jones subsp. tsugense, is described. A factorial experiment evaluated the effects of media (Harvey's medium (HM) and modified White's medium (WM)), temperatures (15 °C and 20 °C), presence or absence of light, and plant growth regulators (the auxin 2,4-dichlorophenoxyacetic acid (2,4-D) and the cytokinin 6-benzylaminopurine (BAP) at varying concentrations (0.001 mg l⁻¹ to 1 mg l⁻¹)). Seed explants germinated in less than one week in culture and produced radicles. Optimal conditions for radicle elongation were WM at 20 °C in the presence of light and without plant growth regulators. Some of the radicles split at the tip to yield callus while others swelled to become spherical holdfasts. Holdfasts were also produced at the tips of radicles, and callus arose from split holdfasts. Factors that promoted holdfast production were Harvey's medium, light, and 2,4-D at 1 mg l⁻¹. Callus development from split radicles and split holdfasts was optimal on WM with 0.5 mg l⁻¹ 2,4-D and 1 mg l⁻¹ BAP at 20 °C in the dark. This revised version was published online in June 2006 with corrections to the Cover Date.     

Desiccation tolerance in Physcomitrella patens: Rate of dehydration and the involvement of endogenous abscisic acid (ABA)

The moss Physcomitrella patens , a model system for basal land plants, tolerates several abiotic stresses, including dehydration. We previously reported that Physcomitrella patens survives equilibrium dehydration to ?13 MPa in a closed system at 91% RH. Tolerance of desiccation to water potentials below ?100 MPa was only achieved by pretreatment with exogenous abscisic acid (ABA). We report here that gametophores, but not protonemata, can survive desiccation below ?100 MPa after a gradual drying regime in an open system, without exogenous ABA. In contrast, faster equilibrium drying at 90% RH for 3–5 days did not induce desiccation tolerance in either tissue. Endogenous ABA accumulated in protonemata and gametophores under both drying regimes, so did not correlate directly with desiccation tolerance. Gametophores of a Ppabi3a/b/c triple knock out transgenic line also survived the gradual dehydration regime, despite impaired ABA signaling. Our results suggest that the initial drying rate, and not the amount of endogenous ABA, may be critical in the acquisition of desiccation tolerance. Results from this work will provide insight into ongoing studies to uncover the role of ABA in the dehydration response and the underlying mechanisms of desiccation tolerance in this bryophyte.     

Effect of exogenous ABA on somatic embryo maturation and germination in Persian walnut (<Emphasis Type="Italic">Juglans regia</Emphasis> L.)

Low efficiency of embryo maturation, germination and conversion to plantlets is a major problem in many species including Persian walnut. We studied the effects of abscisic acid (ABA) and sucrose, on the maturation and germination of Persian walnut (Juglans regia) somatic embryos. Individual globular somatic embryos were grown on a maturation medium supplemented with different combinations of ABA and sucrose for ca. 1 month, until shoot meristems and radicles had developed. White and opaque embryos in late cotyledonary stage were subjected to desiccation after the culture period on maturation media. The number of germinated somatic embryos was influenced by the concentrations of ABA in the maturation medium. The best treatment for germination, in which both shoot and root were developed contained 2 mg l⁻¹ ABA and resulted in 41% conversion of embryos into plantlets. Regeneration was reduced at higher levels of ABA. While ABA always reduced the rate of secondary embryogenesis, treatments containing 4.0% sucrose significantly increased the number of secondary embryos. On the other hand, sucrose had little influence on maturation. Normal and abnormal embryos were verified anatomically.     

Seed Germination and Radicle Growth of a Halophyte, Kalidium caspicum(Chenopodiaceae)

Effects of temperature, light, NaCl and polyethylene glycol(PEG)-6000 on seed germination and radicle growth in a halophyticshrub, Kalidium caspicum(L.) Ung.-Sternb. were investigated.When seeds were incubated in deionized water at constant temperaturesbetween 10 and 30°C, the percentage germination in the darkexceeded 75%; light suppressed seed germination at alternatingtemperatures. Incubating seeds with a hypersaline solution ofNaCl for 30 d had no adverse effect on their germinability.The percentage germination of seeds incubated with a –0.8MPa NaCl solution was 73, 80 and 54% at 10, 20 and 30°C,respectively, but all radicles died before their length exceeded5 mm. In contrast, when seeds were incubated with a –0.8MPa PEG solution at 20°C, 68% of seeds germinated, and 95%of the emerging radicles survived beyond 5 mm. The high sensitivityof small radicles of this species to salinity indicated thatsalt must be removed from the soil surface for seedling establishment.Copyright2000 Annals of Botany Company Chinese desert, radicle growth, germination, halophyte, Kalidium caspicum, salinity     

Development of white spruce (Picea glauca (Moench.) Voss) somatic embryos during culture with abscisic acid and osmoticum, and their tolerance to drying and frozen storage

The limit of permeability of white spruce (Picea glauca [Moench.]Voss) somatic embryo cell walls to molecules was in the orderof 30 . Polyethylene glycols (PEGs) and dextrans of molecularweights greater than 1000 and 6000, respectively, produced anonpermeating (non-plasmolysing) water stress which improvedembryo development. Somatic embryos converted to plantlets atfrequencies of 76–84% following slow drying and storageat –20 C for 1 year, which was similar to the 77% recordedfor control somatic embryos slowly dried then germinated withoutfreezing or storage. Culture for 7–8 weeks with mediumcontaining abscisic acid, 3% sucrose, and 7.5% PEG 4000 yieldedsomatic embryos with five times the embryo storage lipid contentrecorded for zygotic embryos. During culture with PEG the moisturecontent of the somatic embryos decreased from 96% for immaturesuspension-cultured somatic embryos, to 47% for mature embryos.Somatic embryos cultured for 7–8 weeks survived rapiddrying to 5% moisture content, and converted to plantlets atfrequencies of 60–70%, but no somatic embryos survivedrapid drying when cultured for only 4 weeks; however, slow dryingdid induce desiccation tolerance in 3-week cultured somaticembryos. Abscisic acid was important to maintain embryos ina developmental state, but ABA alone did not induce desiccationtolerance. In order to induce desiccation tolerance a waterstress treatment was required. Tolerance of rapid drying coincidedwith moisture contents below 55%, which occurred after 5 weeksof culture in the presence of PEG 4000 and abscisic acid. Key words: Dextran, molecular weight, polyethylene glycol, triacylglycerol, water stress     

Water status,drought responses,and growth of <Emphasis Type="Italic">Prosopis flexuosa</Emphasis> trees with different access to the water table in a warm South American desert

Prosopis flexuosa trees dominate woodlands in the Central Monte Desert (Mendoza, Argentina), with <200 mm rainfall, exploiting the water table recharged by Andean rivers, and also growing in dunes with no access to the water table. Prosopis woodlands were extensively logged during development of the agricultural oasis, and surface and groundwater irrigation could lower the depth of the water table in the future. We evaluated tree populations with decreasing access to the water table: valley adult trees, valley saplings, and dune adult trees, in order to assess their ecophysiological response to water table accessibility. High and seasonally stable pre-dawn leaf water potentials (−2.2 ± 0.2 to −1.2 ± 0.07 MPa) indicated that valley adults utilize larger and more stable water reservoirs than valley saplings and dune adults (−3.8 ± 0.3 to −1.3 ± 0.07 MPa), with higher midday leaf conductance to water vapor (valley adults ~250; dune adults <60 mmol m⁻² s⁻¹), potentially higher CO₂ uptake, and increased radial growth rate (valley adults 4.1 ± 0.07; dune adults 2.9 ± 0.02 mm year⁻¹). Trees with poor access to the water table exhibited drought tolerance responses such as midday stomata closure, leaflet closure, and osmotic adjustment. Stomata density decreased in response to drought when leaf expansion was restricted. The combination of phreatophytism and drought tolerance would enlarge P. flexuosa habitats and buffer populations against changes in rainfall dynamics and water table depth.     

Leaf osmotic potential decrease: a possible cause of mortality of greenhouse whitefly eggs

Trialeurodes vaporariorum (Westwood) (Homoptera: Aleyrodidae) white eggs were detached from the leaf and exposed to a range of osmotic concentrations (between −0.4 and −2.2 MPa) in controlled conditions. Eggs were able to hatch in the low and medium solute concentrations. In the higher concentrations, eclosion was delayed and significant mortality due to egg desiccation was observed. These results indicate leaf osmotic potential is a plant characteristic that affects greenhouse whitefly survivorship. Therefore leaf osmotic potential should be considered when evaluating greenhouse whitefly resistance.     

Secondary Somatic Embryogenesis in Abies numidica

The induction of secondary somatic embryogenesis in Abies numidica De Lann. was achieved. Precotyledonary, cotyledonary, and desiccated cotyledonary embryos were used as explants. Cotyledonary embryos before desiccation were the most suitable. The most beneficial was induction medium Schenk and Hildebrandt (SH) with 1 mg dm⁻³ thidiazuron and 1000 mg dm⁻³ myo-inositol. Initiation frequency was from 1 to 34 %. Maturation of somatic embryos was achieved on modified Murashige and Skoog medium supplemented with 40 g dm⁻³ maltose, 100 g dm⁻³ polyethylene glycol-4000 and 10 mg dm⁻³ abscisic acid. Mature somatic embryos after three weeks of desiccation germinated on SH medium with 10 g dm⁻³ charcoal and 10 g dm⁻³ sucrose. This revised version was published online in July 2006 with corrections to the Cover Date.     

Simulating in ovulo osmotic potentials and O<Subscript>2</Subscript> tensions normalize growth and pigmentation of immature cotton embryos

Oxygen tensions and osmotic potentials are important physiological factors of plant growth and development. To optimize these variables for cotton (Gossypium hirsutum L.) embryo culture, we quantified dissolved O₂ (dO₂) tensions, osmotic potentials, and pH at several locations in cotton ovules during embryony. Clark O₂ microelectrodes were micromanipulated into intact ovules at an angle lateral to the developing embryo, and dO₂ tensions were determined in integuments, nucelli and embryos. Ovular osmotic potentials and pH were determined from extracted ovule sap using vapor pressure osmometers and pH microelectrodes. Dissolved O₂ tensions near or in embryos decreased from 104 mmol m⁻³ at 5 days post-anthesis (DPA) to 83 mmol m⁻³ at 18 DPA. Osmotic potentials of ovule sap decreased from −0.70 megapascals (MPa) at 2 DPA to −1.12 MPa at 8 DPA but then increased to −0.84 MPa by 17 DPA. Ovule sap pH at 5–17 DPA varied inconsistently and ranged from 5.4 to 6.5. Based on these results, a factorial experiment with two osmotic and three O₂ treatments was designed. Immature embryos of cotton cultivar HS-26 were randomly assigned to the treatment combinations and cultured for 33 days. Oxygen treatments did not affect embryo growth, and there were no differences among treatments with regard to percentage of embryos that progressed to a more advanced stage of embryo development. However, cotyledons of embryos grown without osmotic adjustment were abnormally large, and embryos exposed to these treatments were abnormally brown. Browning was less severe for embryos exposed to low O₂ tensions. Growth and pigmentation were most normal for embryos simultaneously exposed to O₂ tensions and osmotic potentials that best simulated the observed in ovulo conditions.     

Changes in composition of phenolic compounds and antioxidant properties of <Emphasis Type="Italic">Vitis amurensis</Emphasis> seeds germinated under osmotic stress

The research focused on the changes of phenolic compounds as well as their antiradical activity and reducing power isolated from Amur grape (Vitis amurensis) seeds during germination under optimal conditions and under osmotic stress. The seeds were found to contain tannins, (+) catechin, (−) epicatechin, and gallic acid (in free, ester- and glycoside-bound forms). Extracts from the seeds were also shown to contain two other phenolic acids: caffeic and p-coumaric acids, in very low levels. During a 3-day seed germination test under osmotic stress (−0.5 MPa), the content of total phenolics, tannins and phenolic acids declined as compared to the control. However, seed germination under stress conditions led to a significant increase in the amount of catechins. Because catechin is the one of the units in condensed tannins, its dynamic increase during seed germination may be involved in metabolism of tannins under osmotic stress. It is also likely that the synthesis of catechins is greater under stress conditions and these compounds may be engaged in the process of acclimatization of grapevines to stress conditions. The content of total phenolic compounds in seed extracts is positively correlated with their antioxidant properties. The extracts from seeds germinated under optimal conditions exhibited strong antiradical properties against the DPPH (2,2-diphenyl-1-picrylhydrazyl) radical as well as reducing power. As regards the extracts from grape seeds germinated under osmotic stress, this capability was much weaker. The research demonstrated that antioxidants could interfere with the oxidation process induced by various stresses by acting as oxygen scavengers, therefore the tolerance to drought stress might be correlated with an increase in the antioxidant potential.     

Changing desiccation tolerance of pea embryo protoplasts during germination

Protoplasts were isolated from pea (Pisum sativum L. cv. Alaska) embryonic axes during and after germination to determine whether the loss of desiccation tolerance in the embryos also occurs in the protoplasts. At all times studied, protoplast survival decreased as water content decreased; however, the sensitivity to dehydration was less when the protoplasts were isolated from embryos that were still desiccation-tolerant (12 h and 18 h of imbibition) than when protoplasts were derived from axes that were sensitive (24 h and 36 h of imbibition). The water content at which 50% of the population was killed (WC50) increased throughout germination and early seedling growth for both the intact tissue and the protoplasts derived from them. Prior to radicle emergence, protoplasts were less desiccation-tolerant than the intact axes; however, protoplasts isolated from radicles shortly after emergence had lower WC50s than the intact radicles. A comparison of protoplast survival after isolation and dehydration in either 500 mM sucrose/raffinose or 700 mM sucrose revealed no difference in tolerance except at 24 h of imbibition, when protoplasts treated in the more concentrated solution had improved tolerance of dehydration. Although intact epicotyls are generally more desiccation-tolerant than radicles, protoplasts isolated separately from epicotyls and radicles did not differ in tolerance. Collectively, these data suggest that protoplasts gradually lose desiccation tolerance during germination, as do the orthodox embryos from which they were derived. However, even prior to radicle emergence, protoplasts display a sensitivity to progressive dehydration that is similar to that shown by recalcitrant and ageing embryos.