Acclimation and endogenous abscisic acid in the moss Physcomitrella patens during acquisition of desiccation tolerance

The moss Physcomitrella patens has been used as a model organism to study the induction of desiccation tolerance (DT), but links between dehydration rate, the accumulation of endogenous abscisic acid (ABA) and DT remain unclear. In this study, we show that prolonged acclimation of P. patens at 89% relative humidity (RH) [?16 MPa] can induce tolerance of desiccation at 33% RH (?153 MPa) in both protonema and gametophore stages. During acclimation, significant endogenous ABA accumulation occurred after 1 day in gametophores and after 2 days in protonemata. Physcomitrella patens expressing the ABA‐inducible EARLY METHIONINE promoter fused to a cyan fluorescent protein (CFP) reporter gene revealed a mostly uniform distribution of the CFP increasing throughout the tissues during acclimation. DT was measured by day 6 of acclimation in gametophores, but not until 9 days of acclimation for protonemata. These results suggest that endogenous ABA accumulating when moss cells experience moderate water loss requires sufficient time to induce the changes that permit cells to survive more severe desiccation. These results provide insight for ongoing studies of how acclimation induces metabolic changes to enable DT in P. patens.     

Physiological changes in gentian axillary buds during two-step preculturing with sucrose that conferred high levels of tolerance to desiccation and cryopreservation

BACKGROUND AND AIMS: Induction of dehydration tolerance is a key to achieving high survival rates in cryopreservation of plant specimens. It has been reported previously that two-step preculturing with sucrose effectively increased desiccation tolerance in axillary buds of gentian (Gentiana scabra), which allow the buds to survive cryopreservation. This study is aimed at characterizing each step of this preculturing and to elucidate physiological changes induced during this preculturing. METHODS: In standard two-step preculture, excised gentian axillary buds were incubated for 11 d on MS medium with 0.1 m sucrose at 25 degrees C (first step: mild osmotic stress was given) and the subsequent incubation on MS medium with 0.4 m and 0.7 m sucrose for 1 d each (second step). The levels of abscisic acid (ABA), proline and soluble sugars in gentian buds during the preculture were determined. Effects of various combinations of two-step preculturing and of exogenous ABA and proline were studied. KEY RESULTS: During the first preculture step, there was a transient increase in ABA content peaking on day 4, which declined to a background level at the end of the first and second step preculturing. Proline level increased steadily during the first preculture step and increased further in the second preculture step. Incubating buds with medium containing proline, instead of the two-step preculturing, did not allow them to survive desiccation. Incubating buds with ABA instead of 0.1 m sucrose-preculturing effectively increased desiccation tolerance only when it was followed by the second preculture step. Fluridone, an ABA synthesis inhibitor included in the two-step preculture medium, reduced desiccation tolerance of the buds. The normal first-step preculture increased the levels of soluble sugars 2.4-fold, especially sucrose and raffinose. Buds treated with the second preculture step had greatly increased sucrose levels. CONCLUSIONS: These observations lead to the hypothesis that the first preculture step involves ABA-mediated cellular changes and the second step induces loading of sucrose in the gentian buds.     

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.     

Rapid degradation of starch in chloroplasts and concomitant accumulation of soluble sugars associated with ABA-induced freezing tolerance in the moss Physcomitrella patens

Abscisic acid (ABA) has been postulated to play a role in the development of freezing tolerance during the cold acclimation process in higher plants, but its role in cold tolerance in tower land plants has not been elucidated. The moss Physcomitrella patens rapidly developed freezing tolerance when its protonemata were grown in a medium containing ABA, with dramatic changes in the LT50 value from -2 degrees C to over -10 degrees C. We examined physiological and morphological alterations in protonema cells caused by ABA treatment to elucidate early cellular events responsible for rapid enhancement of freezing tolerance. Microscopic observations revealed that ABA treatment for 1 day resulted in a dramatic alteration in the appearance of intracellular organelles. ABA-treated cells had slender chloroplasts, with a reduced amount of starch grains, in comparison with those of non-treated cells. The ABA-treated cells also had several segmented vacuoles while many of non-treated cells had one central vacuole. When frozen to -4 degrees C, freezing injury-associated ultrastructural changes such as formation of aparticulate domains and fracture-jump lesions were frequently observed in the plasma membrane of non-treated protonema cells but not in that of ABA-treated cells. The ABA treatment increased the osmotic concentration of the protonema cells, in correlation with accumulation of free soluble sugars. These results suggest that ABA-induced accumulation of soluble sugars, associated with morphological changes in organelles, mitigated freezing-induced structural damage in the plasma membrane, eventually leading to enhancement of freezing tolerance in the protonema cells.     

Cryopreservation of in vitro-grown shoot-tips of hop (Humulus lupulus L.) using encapsulation/dehydration

 A cryopreservation procedure using encapsulation/dehydration was established for shoot-tips obtained from in vitro-grown shoots of hop. After dissection, shoot-tips were encapsulated in medium with alginate and 0.5 M sucrose. Optimal conditions consisted of preculture for 2 days in solid medium with 0.75 M sucrose, or in increasing sucrose concentrations, desiccation for 4 h with silicagel in a flow cabinet (16% water content) followed by rapid freezing and slow thawing. Shoot recovery after freezing 60 min in liquid nitrogen was around 80%. No phenotypical changes were observed in the recovered plants from cryopreserved shoot-tips growing in the field. Received: 20 April 1997 / Revised: 20 February 1998 / Accepted: 1 Dezember 1998     

Abscisic acid-induced freezing tolerance in the moss Physcomitrella patens is accompanied by increased expression of stress-related genes

Abscisic acid (ABA)-induced genes are implicated in the development of freezing tolerance during cold acclimation in higher plants, but their roles in lower land plants have not been determined. We examined ABA- and cold-induced changes in freezing tolerance and gene expression in the moss Physcomitrella patens. Slow equilibrium freezing to -4 degrees C of P. patens protonemata grown under normal growth conditions killed more than 90% of the cells, indicating that the protonema cells are freezing-sensitive. ABA treatment for 24 h dramatically increased the freezing tolerance of the protonemata, while cold treatment only slightly increased the freezing tolerance within the same period. We examined the expressions of fourteen Physcomitrella patens ABA-responsive genes (PPARs), isolated from ABA-treated protonemata. ABA treatment resulted in a remarkable increase in the expression of all the PPAR genes within 24 h. Several of the PPAR genes (PPAR 1 to 8, and 14) were also responsive to cold, but the response was much slower than that to ABA. Treatment with hyperosmotic concentrations of NaCl and mannitol increased freezing tolerance of protonemata and also increased the expression levels of eleven PPAR genes (PPAR2, 3, 5 to 8, and 10 to 14). These results suggest that ABA and environmental stresses positively affect the expression of common genes that participate in protection of protonema cells leading to the development of freezing tolerance.     

Cryopreservation of wheat suspension culture and regenerable callus

Wheat (Triticum aestivum L. cv. Norstar) suspension cultures and regenerable calli initiated from immature embryos can be cryopreserved in liquid nitrogen temperature (–196°C) by slow freezing (0.5°C/min) in the presence of a mixture of DMSO and sucrose or sorbitol. Cold hardening or ABA treatment before cryopreservation increased the freezing resistance and improved the survival of wheat suspension culture in liquid nitrogen. Callus culture, established from immature embryos, prefrozen in 5% DMSO and 0.5M sorbitol survived liquid nitrogen storage and resumed plant regeneration after thawing. The results confirm the feasibility of long term preservation of wheat embryo callus by cryopreservation and retention of plant regeneration ability.Abbreviations ABA Abscisic acid - 2,4-D 2,4-Dichlorophenoxyacetic acid - DMSO Dimethylsulfoxide - LN Liquid nitrogen - TTC 2,3,5-triphenyltetrazolium chloride NRCC No. 23850.     

Survival and genetic stability of Picea abies embryogenic cultures after cryopreservation using a pregrowth-dehydration method

A vitrification method enabled efficient cryopreservation of embryogenic tissue (ETs) of Norway spruce (Picea abies L.) at ?196 °C in liquid nitrogen (LN). Correctly formed, normal somatic embryos were generated from ETs that had been thawed after removal from LN. The pregrowth-dehydration method involved preculture of ETs with sucrose (0.25–1.00 M) in the presence or absence of 10 μM abscisic acid (ABA), followed by air-drying for 2 h and rapid freezing in LN. Pretreatment of ETs with both sucrose and ABA promoted ET growth after preculture and thawing more effectively than treatment with sucrose alone. Survival of ETs after thawing from LN using both sucrose and ABA was 54.4 % compared to pretreatment with sucrose alone which was 20 %. Addition of ABA in the preculture medium also improved the ability of ETs to form cotyledonary stage somatic embryos. The somatic embryos, which had normal shoot and root apices and the correct number of cotyledons, were indistinguishable from regenerants obtained from control cultures. Genetic analysis of control and cryopreserved ETs, as well as somatic embryos derived from cryopreserved ETs, indicated that the cryopreservation method had no effect on any of the five microsatellite loci (SpAGC1, SpAGC2, SpAGG3, SpAC1H8, and SpAC1F7) tested. The cryopreservation protocol outlined should enable the long-term storage of valuable clones of Norway spruce in LN, potentially for hundreds of years.     

Cryopreservation of encapsulated gentian axillary buds following 2 step-preculture with sucrose and desiccation

Alginate beads containing axillary buds of in vitro-grown gentian (Gentiana scabra Bunge var. buergeri Maxim.), were successfully cryopreserved following 2 step-preculture with sucrose and desiccation. The optimal preculture conditions were as follows: axillary buds were excised from in vitro-grown gentian plants and precultured on semi-solid Murashige and Skoog (MS) medium containing 0.1 M sucrose for 10 days (25 °C, 16-h photoperiod) (first step). This was followed by incubation on semi-solid MS media containing 0.4 M (1 day) and then 0.7 M sucrose (1 day) (second step). After preculture, the buds were encapsulated in alginate beads and desiccated aseptically on silica gel for 9 h to a water content of 10% (fresh weight basis), followed by immersion in liquid nitrogen (LN). With this protocol, 87% of the gentian buds survived exposure to LN and showed normal development of shoots and roots in vitro and in vivo. Depletion of NH₄NO₃ in the regeneration medium did not improve survival following desiccation and exposure to LN. The results show that 2 step-preculture with sucrose is effectively applicable in encapsulation–desiccation based cryopreservation of gentian axillary buds. This preculture can replace the conventionally used lengthy cold-hardening treatment and is useful for routine cryopreservation of gentian germplasm.     

Accumulation of theanderose in association with development of freezing tolerance in the moss Physcomitrella patens

Mosses are known to have the ability to develop high degrees of resistance to desiccation and freezing stress at cellular levels. However, underlying cellular mechanisms leading to the development of stress resistance in mosses are not understood. We previously showed that freezing tolerance in protonema cells of the moss Physcomitrella patens was rapidly increased by exogenous application of the stress hormone abscisic acid (ABA) [Minami, A., Nagao, M., Arakawa, K., Fujikawa, S., Takezawa, D., 2003a. Abscisic acid-induced freezing tolerance in the moss Physcomitrella patens is accompanied by increased expression of stress-related genes. J. Plant Physiol. 160, 475-483]. Herein it is shown that protonema cells with acquired freezing tolerance specifically accumulate low-molecular-weight soluble sugars. Analysis of the most abundant trisaccharide revealed that the cells accumulated theanderose (G6-alpha-glucosyl sucrose) in close association with enhancement of freezing tolerance by ABA treatment. The accumulation of theanderose was inhibited by cycloheximide, an inhibitor of nuclear-encoded protein synthesis, coinciding with a remarkable decrease in freezing tolerance. Furthermore, theanderose accumulation was promoted by cold acclimation and treatment with hyperosmotic solutes, both of which had been shown to enhance cellular freezing tolerance. These results reveal a novel role for theanderose, whose biological function has been obscure, in high freezing tolerance in moss cells.     

Cryopreservation of embryogenic cultures of Quercus robur using desiccation and vitrification procedures

Oak embryogenic cultures are generally maintained by repetitive embryogenesis. To facilitate management of embryogenic lines and limit the risks of somaclonal variation and contamination a cryopreservation protocol should be developed. In this work we investigated the ability of several pre-treatments to enable 4-6mg clumps (1.0-1.5mm) of globular-heart stage somatic embryos of Quercus robur to withstand freezing in liquid nitrogen. In the best of the two embryogenic culture lines used, 56% of clumps resumed embryogenesis after cooling when they had been pre-treated by successive pre-culture on 0.3 and 0.7M sucrose supplemented media followed by desiccation in the air flow of a laminar flow cabinet to water contents of 24-34%. In both lines, embryogenesis resumption rates of about 70% were achieved by pre-culture on 0.3M sucrose medium followed by application of a vitrification solution (PVS2) for 60-90min prior to rapid plunging in liquid nitrogen.     

ABA Increases the Desiccation Tolerance of Photosynthesis in the Afromontane Understorey Moss Atrichum androgynum

The effect of pretreatment with abscisic acid (ABA) on the physiologyof the moss Atrichum androgynum during a desiccation–rehydrationcycle was examined. During rehydration following desiccationfor 16 h, net CO₂fixation recovered much more slowly than photosystemII (PSII) activity, conditions conducive to the formation ofreactive oxygen species (ROS) in the photosynthetic apparatus.Pretreatment with ABA increased the rate of recovery of photosynthesisand PSII activity, and also doubled non-photochemical quenching(NPQ). Increased NPQ activity will reduce ROS formation, andmay explain in part how ABA hardens the moss to desiccation.In ABA-pretreated, but not untreated mosses, desiccation significantlyincreased the concentration of soluble sugars. Sugar accumulationmay promote vitrification of the cytoplasm and protect membranesduring desiccation. Starch concentrations in freshly collectedA. androgynum were only approx. 40 mg g^-1dry mass; they roseslightly during desiccation but were only slightly affectedby ABA pretreatment. ABA did not reduce chlorophyll breakdownduring desiccation. Copyright 2001 Annals of Botany Company Moss, desiccation, abscisic acid, photosynthesis, chlorophyll fluorescence     

Sequence analysis of expressed sequence tags from an ABA-treated cDNA library identifies stress response genes in the moss Physcomitrella patens.

Partial cDNA sequencing was used to obtain 169 expressed sequence tags (ESTs) in the moss, Physcomitrella patens. The source of ESTs was a random cDNA library constructed from 7 day-old protonemata following treatment with 10(-4) M abscisic acid (ABA). Analysis of the ESTs identified 69% with homology to known sequences, 61% of which had significant homology to sequences of plant origin. More importantly, at least 11 ESTs had significant similarities to genes which are implicated in plant stress-responses, including responses which may involve ABA. These included a cDNA associated with desiccation tolerance, two heat shock protein genes, one cold acclimation protein cDNA and five others that may be involved in either oxidative or chemical stress or both, i.e., Zn/Cu-superoxide dismutase, NADPH protochlorophyllide oxidoreductase (PorB), selenium binding protein, glutathione peroxidase and glutathione S transferase. Analysis of codon usage between P. patens and seed plants indicated that although mosses and higher plants are to a large extent similar, minor variations also exists that may represent the distinctiveness of each group.     

Cryopreservation of somatic embryos of the herbaceous peony (Paeonia lactiflora Pall.) by air drying

This study was carried out to establish a suitable method for the cryopreservation of somatic embryos of the herbaceous peony. The somatic embryos were obtained from cotyledon and anther cultures on a MS medium supplemented with abscisic acid (ABA) and phenylacetic acid (PAA), respectively. The frequency of somatic embryo formation was the greatest (61%) from the cotyledons cultured on a MS medium supplemented with 1.0 mg l(-1) of ABA. Embryos were also obtained directly from anthers cultured on a MS medium with or without 2.0 mg l(-1) of PAA. For the cryopreservation of peony somatic embryos, the embryos were dried under a stream of sterile air and frozen by immersion in liquid nitrogen. Thawed embryos were germinated into plantlets after placing on a medium containing 0.3 mg l(-1) of gibberellic acid (GA(3)). The frequency of the post-thaw regrowth of cryopreserved somatic embryos was related to their size and desiccation time, the latter ranging from 0 to 2 h. When the somatic embryos were desiccated for 1 h, the frequency of post-thaw regrowth was greater than 66%. The frequency of post-thaw regrowth of the cryopreserved somatic embryos from anthers and cotyledon tissues was generally high when they were 2-3 mm in size. Desiccation may be a suitable method for the cryopreservation of somatic embryos of the herbaceous peony.     

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.     

Changes in protein metabolism during the acquisition of tolerance to cryopreservation of carrot somatic embryos

High concentrations of sucrose are often used to cryopreserve regenerable plant cell cultures in liquid nitrogen. A 21-h pretreatment of carrot somatic embryos in medium containing 0.4 M sucrose allows 80 % of them to germinate after freezing. Substitution of sucrose by polyethylene glycol 6000 led to lower germination rates. However, a high level of freezing tolerance was restored by addition of 1 μM abscisic acid in the pretreatment medium. Using these different media, both total water soluble protein, using SDS-PAGE, and boiling-stable protein, using 2-D electrophoresis, were studied in relation to acquisition of cryopreservation tolerance. Only boiling-stable protein patterns showed some changes: five polypeptides accumulated in 0.4 M sucrose-pretreated embryos or in embryos pretreated by media containing abscisic acid. This accumulation was not detected with polyethylene glycol 6000 used as sole cryoprotectant. Although over-accumulation of polypeptides was highest with media containing ABA, the best germination rates were linked to pretreatment with 0.4 M sucrose. The addition of okadaic acid in 0.4 M sucrose medium led to embryo death after freezing, confirming the existence of a message leading to metabolic changes and acquisition of cryotolerance. Water-soluble proteins obtained from 0.4 M sucrose-pretreated embryos appeared more active than those extracted from control embryos in protecting in vitro a freeze-labile enzyme. Boiling-stable proteins, corresponding to a part of total proteins, were more active than total proteins. These results suggest that these polypeptides may be involved in a mechanism of protection needed for cell survival during freezing stress.     

On the Metabolism of Tortula ruralis Following Desiccation and Freezing: Respiration and Carbohydrate Oxidation

Recovery from desiccation by Tortula ruralis (Hedw.) Gaertn., Meyer and Scherb was accompanied by an immediate, rapid increase in respiration (measured as oxygen uptake) at 25.5°C or 3.5°C. The respiratory burst was greater on rehydration of moss which had been rapidly desiccated over silica gel than that which had been more slowly desiccated in atmospheres of high relative humidity. No respiration was observed in dry moss. Dried moss which had been placed in liquid nitrogen resumed respiration on rewarming and rehydration but moss which had been frozen in the hydrated state respired to a lesser extent and showed signs of freeze damage. In the initial stages of slow drying a slight increase in respiration was noted, followed by a gradual decrease as drought became more severe. In contrast to observations made on many higher plants under drought stress, this moss did not exhibit any changes in its starch and sugar content during or following desiccation, nor were there any changes in free proline levels. Using (1-¹⁴C)-glucose and (6-¹⁴C)-glucose, the relative activities of the Embden–Meyerhof–Parnas and pentose phosphate pathways in hydrated and rehydrated moss were determined, as were the activities of specific enzymes involved in these pathways. An increased activity of the Embden–Meyerhof–Parnas pathway of glucose oxidation on rehydration of Tortula was observed. The possible significance of this latter observation is outlined.     

Effect of sole and combined pre-treatments on reserve accumulation, survival and germination of encapsulated and dehydrated carrot somatic embryos

In order to obtain dry artificial seeds, carrot somatic embryos were pre-treated before being encapsulated into calcium-alginate-gellan gum, and slowly dehydrated unitil 15% RH (relative humidity of the chamber). ABA (1 to 10 μM), 1 to 5 mM proline, an osmotic pressure of ±520 mOsm, or heat (35°C) enhanced the desiccation tolerance of encapsulated somatic embryos. Some treatments were complementary, like 10 μM ABA and 10% sucrose, 10 μM ABA and heat (35°C), or 10% sucrose and cold (4°C). In such conditions, complete or almost total (95.6–100% germination) desiccation tolerance was then obtained. These treatments may act by the acquisition of sufficient-and well-balanced-protein and starch reserves. osmotic treatments, ABA, and above all proline, promoted protein accumulation, meanwhile starch reserves were slightly depleted by 10–20 μM ABA, proline, and poor sucrose-osmotic treatments (8% trehalose). All the treatments were found to enhance viability during dehydration, as observed by fluorescence. Sucrose may be partly replaced by other osmotica. Alone, it has a negative effect on the depletion of starch reserves. Cold (4°C) with 10% sucrose may favor the glassy state transition. ABA and proline appear to be involved in the same process leading to the acquisition of partial desiccation tolerance. Heat (35°C), or 10% sucrose, have been found to complement ABA action in the acquisition of full desiccation tolerance.     

Disappearance of desiccation tolerance of imbibed crop seeds is not associated with the decline of oligosaccharides

The relationship between sugar content and loss of desiccation tolerance of hydrated crop seeds (tomato, okra, snow pea, mung bean, and cucumber) was evaluated by imbibing seeds with or without ABA, followed by dehydration and germination. During the process of hydration, but before the seeds lost desiccation tolerance, monosaccharide content increased only slightly, sucrose increased in snow peas, mung bean and cucumber, but maintained its original level in other species and the oligosaccharides declined dramatically. At the time of losing desiccation tolerance, the sucrose content of imbibed seeds was 2-3 times higher than the original level in most species. Positive significant correlation coefficients (r) were found in many, but not all crop seeds between desiccation tolerance and the oligosaccharide mass, or oligo/sucrose ratio. The ratio of oligo/sucrose in intact seeds at the time of losing desiccation tolerance, however, was not a fixed value and varied among species. Oligosaccharides declined significantly in different seed parts of imbibed cucumber seeds while sucrose increased to a higher level in the radicle than in the hypocotyl. Radicles were far more sensitive to desiccation than hypocotyls. The same observation was found for cucumber seeds imbibed in 100 M ABA, yet desiccation tolerance was largely maintained in hypocotyls and cotyledons. It is concluded that sucrose and oligosaccharides are not the determinants of the loss of desiccation tolerance in hydrated seeds.Imbibed seeds did not show any differences between seed parts in their ability to resynthesize sugars during the process of slow dehydration. Differences in sensitivity to desiccation among seed parts were not due to differences in the initial water content or to the rate of water content increase among seed parts. Physiological regulation of the loss of desiccation tolerance in crop seeds during hydration is discussed.