Changes in soluble sugars in relation to desiccation tolerance and effects of dehydration on freezing characteristics of Acer platanoides and Acer pseudoplatanus seeds

The role of soluble sugars in desiccation tolerance was investigated in seeds of two species from the genus Acer: Norway maple (Acer platanoides L.) — tolerant and sycamore (Acer pseudoplatanus L.) — intolerant to dehydration. During two years of observations it was found that seeds of Norway maple acquire desiccation tolerance at the end of August i.e. about 125 days after flowering (DAF). During seed development, the transition from intolerant to tolerant state in Norway maple seeds was accompanied by the accumulation in seed tissues of raffinose, stachyose and sucrose. The sucrose/raffinose ratio in Norway maple seeds was lower than in sycamore. In mature Norway maple seeds sucrose and raffinose contents were higher than in sycamore. It was concluded, that soluble sugars such as sucrose, raffinose and stachyose may play an important role in desiccation tolerance and/or intolerance of Norway maple and sycamore seeds. Differential thermal analysis (DTA) was used to study the relationship between desiccation sensitivity and the state of water in seed tissues. The level of non-freezable water was the same in both analysed seed species, but the temperature of water crystallization during desiccation was lower in sycamore seeds.     

The role of sugar, vitrification and membrane phase transition in seed desiccation tolerance

In a search for the mechanism of desiccation tolerance, a comparison was made between orthodox (desiccation-tolerant) soybean ( Glycine max [L.] Merrill) and recalcitrant (desiccation-intolerant) red oak ( Quercus rubra L.) seeds. During the maturation of soybean seeds, desiccation tolerance of seed axes is correlated with increases in sucrose, raffinose and stachyose. In cotyledons of mature oak seeds, sucrose levels are equal to those in mature soybeans, but oligosaccharides are absent. By using the thermally stimulated current method, we observed the glassy state in dry soybean seeds during maturation. Oak cotyledons showed the same phase diagram for the glass transition as did mature soybeans. By using X-ray diffraction, we found the maturation of soybeans to be associated with an increased ability of membranes to retain the liquid crystalline phase upon drying, whereas the mature oak cotyledonary tissue existed in the gel phase under similar dry conditions. These findings lead to the conclusion that the glassy state is not sufficient for desiccation tolerance, whereas the ability of membranes to retain the liquid crystalline phase does correlate with desiccation tolerance. An important role for soluble sugars in desiccation tolerance is confirmed, as well as their relevance to membrane phase changes. However, the presence of soluble sugars does not adequately explain the nature of desiccation tolerance in these seeds.     

Degradation of the endosperm cell walls of Lactuca sativa L., cv. Grand Rapids

The timing of mobilisation of lipid, sucrose, raffinose and phytate in lettuce seeds (achenes) (cv. Grand Rapids) has been examined. These reserves (33%, 1.5%, 0.7%, 1.4% of achene dry weight, respectively) are stored mostly in the cotyledons. Except for a slight degradation of raffinose and increase in sucrose, there is no detectable reserve mobilisation during germination. The endosperm (8% of seed dry weight), which has thick, mannan-containing cell walls (carbohydrate, 3,4% of seed dry weight), is completely degraded within about 15h following germination. Mannanase activity increases about 100-fold during the same period and arises in all regions of the endosperm. Also during this period sucrose and raffinose are degraded and fructose and glucose accumulate in the embryo. The endosperm hydrolysis products are taken up by the embryo, and are probably used as an additional reserve to support early seedling growth. However, endosperm cell-wall carbohydrates, such as mannose, are not found as free sugars. Lipid and phytate are degraded in a later, second phase of mobilisation. Low levels of sucrose are present in the embryo, mostly in the cotyledons, and large amounts of fractose and glucose (14% of seedling dry weight at 3 days after sowing) accumulate in the hypocotyl and radicle. It is suggested that sucrose, produced in the cotyledons by gluco-neogenesis, is translocated to the axis and converted there to fructose and glucose.     

Changes in Soluble Carbohydrates during Seed Storage

The soluble sugars present in the maize (Zea mays L.) embryo may serve as important components of protection or may contribute to the deteriorative changes occurring during seed storage. Examination of the changes in sugars during accelerated aging of maize seeds indicates that the decline in vigor is associated with a marked decline in monosaccharides and in raffinose. Sucrose content remains relatively stable. The depletion of raffinose may have special relevance to the decline in seed vigor.     

α-Galactosidase from sweet chestnut seeds

The major sugars of fresh seeds of Castanea sativa were shown to be raffinose, stachyose and sucrose. Drying seeds at 25° for 14 weeks increased the ratio raffinose: stachyose from 1.1 to 3.5, reduced sucrose content by ca 50 % and decreased total extractable α-galactosidase. The enzyme activity was resolved into two peaks, a high MW form I (apparent MW215 000) and a low MW form II (apparent MW 53 000). The latter form was predominant in the extract of fresh seeds whereas the former was the main form in the 14-week dried seeds. An increase in the amount of enzyme I was also observed when a buffered extract (pH 5.5) of fresh seeds was stored at 4°. Enzymes I and II had pH optima of 4.5 and 6, respectively. Both enzymes hydrolysed p-nitrophenyl α-d-galactoside at a much greater rate than the natural substrates raffinose, stachyose, locust bean gum and carob gum. However, enzyme I showed preference for stachyose as compared to raffinose; the opposite order was observed for enzyme II.     

Changes in the pool of soluble sugars induced by dehydration at the heterotrophic phase of growth of wheat seedlings

Loss of dehydration tolerance coincides with a shift from heterotrophy to autotrophy during post-germination growth of spring wheat seedlings. This critical stage falls on the fifth day following imbibition. Till the sixth day of experiment light had no effect on dry weight of the seedlings but the survival of six day old seedlings was reduced by half upon dehydration. Germinating seeds in the presence of 5 mM glucose, fructose, mannose or sucrose did not promote seedling growth but either increase (glucose, fructose) or decreased (mannose, sucrose) the survival of dehydrated seedlings. Protection against dehydration by the former sugars was correlated, irrespective of the seedling age, with the decrease of sugar pool in seeds and increase in shoots (coleoptile and first leaf) and roots. The opposite changes were provoked by the sugars hampering seedling survival. Generally, survival of wheat seedlings was not correlated with the size of soluble sugar pool but its distribution and composition. Lower mobilisation of soluble sugars in seed, lower proportion of reduced sugars to sucrose and higher share of raffinose is characteristic for the tolerant four day old seedlings and those grown in the media containing glucose or fructose. The results presented indicate that higher proportion of reduced sugars to sucrose and lower share of raffinose in six day old seedlings seems to be associated with the loss of dehydration tolerance of these seedlings, despite heterotrophic character of growth.     

Interactions of sugars with membranes

Water profoundly affects the stability of biological membranes, and its removal leads to destructive events including fusion and liquid crystalline to gel phase transitions. In heterogeneous mixtures such as those found in biological membranes the phase transitions can lead to increases in permeability and lateral phase separations that often are irreparable. Certain sugars are capable of preventing these deleterious events by inhibiting fusion during drying and by maintaining the lipid in a fluid state in the absence of water. As a result, the increased permeability and lateral phase separations that accompany dehydration are absent. The weight of the evidence suggests strongly that there is a direct interaction between the sugars and lipids in the dry state. Although the evidence is less clear about whether these sugars can interact directly with hydrated bilayers, there are strong suggestions in the literature that sugars free in solution or covalently linked to membrane constituents can also affect the physical properties and presumably the stability of bilayers. Finally, we have far less evidence concerning the mechanism by which they do so, but the same sugars are also capable of preserving the structure and function of both membrane-bound and soluble proteins in the absence of water. We believe these effects may be important in the survival of intact cells and organisms such as seeds in the absence of water. Furthermore, in view of the practical importance of preserving biological structures we suspect that the results described here will ultimately have important applications in biology and medicine.     

Interaction of carbohydrates with dry dipalmitoylphosphatidylcholine

Interactions of six carbohydrates (trehalose, sucrose, glucose, raffinose, inositol, and glycerol) with dry dipalmitoylphosphatidylcholine (DPPC) were studied using differential scanning calorimetry (DSC) and infrared spectroscopy (ir) in order to elucidate the mechanism by which some of these carbohydrates preserve structural and functional integrity of dry membranes. Results with DSC showed that trehalose depressed the main transition temperature (Tmid) of dry DPPC below that of fully hydrated DPPC, and raised the enthalpy of that transition more than did addition of water. Results obtained with ir spectroscopy suggested a potential mechanism for this interaction. In the presence of most of the carbohydrates the ir spectrum for DPPC showed changes similar to those seen when water was added to dry DPPC, and the asymmetric P = O stretching band was diminished in intensity. The degree to which the carbohydrates tested affected the integrated intensity of this band and the Tmid was correlated with the ability of those carbohydrates to preserve dry membranes. Also, bands assigned to -OH deformations in the trehalose and other carbohydrates were depressed in the presence of DPPC. Based on these observations, it is suggested that the mechanism of interaction between the carbohydrate and lipid involves hydrogen bonding between -OH groups on the carbohydrate and the phosphate head group of the phospholipid. The only exceptions to this pattern are glycerol, which depresses Tmid of dry DPPC, and myo-inositol, which has no effect on Tmid or the ir spectrum of DPPC; neither carbohydrate can preserve dry membranes. It is suggested, based on ir spectroscopy and previous results with monolayer preparations, that glycerol interacts with phospholipids by a mechanism different from that shown by the other carbohydrates.     

Galactinol synthase activity and soluble sugars in developing seeds of four soybean genotypes

Galactinol synthase (UDP-galactose:inositol galactosyltransferase) is the first unique enzyme in the biosynthetic pathway of raffinose saccharides. Its role as a regulator of carbon partitioning between sucrose and raffinose saccharides in developing soybean (Glycine max L. Merrill) seeds was examined. Galactinol synthase activity and concentrations of sucrose, stachyose, and raffinose were compared during seed development between two genotypes that were high and two genotypes that were low in mature seed raffinose saccharide concentration. In all genotypes, sucrose concentration increased as seed development progressed, but in both low raffinose saccharide genotypes, greater increases in sucrose concentration were observed late in seed development. Sucrose to stachyose ratios in mature seeds were 2.3-fold greater in low raffinose saccharide genotypes than in the high raffinose saccharide genotypes. During seed development, higher levels of galactinol synthase activity were observed in the high raffinose saccharide genotypes than in the low raffinose saccharide genotypes. A common linear relationship for all four soybean genotypes was shown to exist between galactinol formed estimated from galactinol synthase activity data and the concentration of galactose present in raffinose saccharides. Results of this study implied that galactinol synthase is an important regulator of carbon partitioning between sucrose and raffinose saccharides in developing soybean seeds.     

Protection by sugars against phase transition-induced leak in hydrated dimyristoylphosphatidylcholine liposomes

The disaccharides trehalose and sucrose have small effects on temperature and enthalpy of the pre- and main phase transition in hydrated DMPC bilayers. In contrast, these sugars cause a considerable retention of carboxyfluorescein when large unilamellar vesicles of DMPC are heated through the main transition. This effect is sugar specific, as the monosaccharides glucose and fructose are less effective and ethyleneglycol has no effect at all.     

An integrated overview of seed development in Arabidopsis thaliana ecotype WS

This work is part of a research program aiming at identifying and studying genes involved in Arabidopsis thaliana seed maturation. We focused here on the Wassilewskija ecotype seed development and linked physiological and biochemical data, including protein, oil, soluble sugars, starch and free amino acid measurements, to embryo development, to obtain a complete and thorough reference data set. A. thaliana seed development can be divided into three stages. During early embryogenesis (i.e. morphogenesis), seed weight and lipid content were low whereas important amounts of starch were transiently accumulated. In the second stage, or maturation phase, a rapid increase in seed dry weight was observed and storage oils and proteins were accumulated in large quantities, accounting for approximately 40% of dry matter each at the end of this stage. During the third and last stage (late maturation including acquisition of desiccation tolerance), seed dry weight remained constant while an acute loss of water took place in the seed. Storage compound synthesis ended concomitantly with sucrose, stachyose and raffinose accumulation. This study revealed the occurrence of metabolic activities such as protein synthesis, in the final phase of embryo desiccation. A striking correlation between peaks in hexose to sucrose ratio and transition phases during embryogenesis was observed.     

Carbohydrate Changes during Maturation of Cucumber Fruit : Implications for Sugar Metabolism and Transport

Changes in the carbohydrate profiles in the mesocarp, endocarp, and seeds of maturing cucumber (Cucumis sativus, L.) fruit were analyzed. Fruit maturity was measured by a decrease in endocarp pH, which was found to correlate with a loss in peel chlorophyll and an increase in citric acid content. Concentrations of glucose and fructose (8.6-10.3 milligrams per gram fresh weight, respectively) were found to be higher than the concentration of sucrose (0.3 milligrams per gram fresh weight) in both mesocarp and endocarp tissue. Neither raffinose nor stachyose were found in these tissues. The levels of glucose and fructose in seeds decreased during development, but sucrose, raffinose, and stachyose accumulated during the late stages of maturation. Both raffinose and stachyose were found in the seeds of six lines of Cucumis sativus L. This accumulation of raffinose saccharides coincided with an increase in galactinol synthase activity in the seeds. Funiculi from maturing fruit were found to be high in sucrose concentration (4.8 milligrams per gram fresh weight) but devoid of both raffinose and stachyose. The results indicated that sucrose is the transport sugar from the peduncle to seed, and that raffinose saccharide accumulation in the seed is the result of in situ biosynthesis and not from direct vascular transport of these oligosaccharides into the seeds.     

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.     

The preservation of liposomes by raffinose family oligosaccharides during drying is mediated by effects on fusion and lipid phase transitions

Raffinose family oligosaccharides (RFO) have been implicated as protective agents in the cellular dehydration tolerance, especially of many plant seeds. However, their efficacy in stabilizing membranes during dehydration has never been systematically investigated. We have analyzed the effects of sucrose, raffinose, stachyose, and verbascose on liposome stability during air-drying. With increasing degree of polymerization (DP), the RFO were progressively better able to stabilize liposomes against leakage of aqueous content and against membrane fusion after rehydration. Indeed, there was a very tight linear correlation between fusion and leakage for all RFO. These data indicate that increased protection of liposomes against leakage with increasing DP is due to better protection against fusion. This is in accord with the higher glass transition temperature of the longer chain oligosaccharides. Further evidence for the influence of glass transitions on membrane stability in the dry state was provided by experiments testing the temperature dependence of membrane fusion. During incubation at temperatures up to 95 °C for 2 h, fusion increased less with temperature in the presence of higher DP sugars. This indicates that RFO with a higher glass transition temperature are better able to protect dry membranes at elevated temperatures. In addition, Fourier-transform infrared (FTIR) spectroscopy showed a reduction of the gel to liquid-crystalline phase transition temperature of dry liposomes in the presence of all investigated sugars. However, the RFO became slightly less effective with increasing chain length, again pointing to a decisive role for preventing fusion. A direct interaction of the RFO with the lipids was indicated by a strong effect of the sugars on the phosphate asymmetric stretch region of the infrared spectrum.     

Effects of exogenous abscisic acid on leaf carbohydrate metabolism during cucumber seedling dehydration

Cucumber (Cucumis sativus L.) seeds were pretreated with exogenous abscisic acid (ABA) prior to germination. After germination, seedlings with three leaves were exposed to gradual dehydration. The effects of ABA on photosynthetic rate (Pn), daily water loss (WL) and water utilization efficiency (WUE) during dehydration were investigated, in addition to the variation of carbohydrates in leaves. ABA improved the Pn, WL and WUE of cucumber seedlings during dehydration. After rehydration, the seedlings pretreated with ABA showed a higher recovery in Pn, WL and WUE, as compared to those without an ABA pretreatment. Subsequent to dehydration, concentration of stachyose, raffinose, sucrose, glucose, and fructose increased in seedlings pretreated with ABA. Dehydration altered the proportions of the sugars in the total carbohydrates, and accelerated the accumulation of stachyose, raffinose and sucrose. After rehydration, carbohydrate concentrations of seedlings pretreated with ABA recovered to levels observed prior to dehydration. These results demonstrated that pretreatment of seeds with exogenous ABA enhanced carbohydrate tolerance to dehydration of cucumber seedlings.     

Sugar compartmentation in frost-hardy and partially dehardened cabbage leaf cells

In frost-hardy and partially dehardened leaves of Brassica oleracea L. var. sabellica L. the distribution of cryoprotective sugars and of chloride between chloroplasts and the nonchloroplast part of leaf cells was investigated using the nonaqueous isolation technique as a means of cell fractionation. In chloroplasts of frost-hardy leaves high concentrations of sucrose and raffinose and comparatively low concentrations of chloride have been found. The ratios between sugars and chloride were so as to ascertain complete protection of the frost-sensitive thylakoid membranes during freezing. During dehardening, sugars decreased especially in the chloroplasts. There was a conversion of sucrose and raffinose into monosaccharides. This led to a large increase in the concentration of glucose and fructose in the nonchloroplast parts of the cells. There is evidence that the sugar concentration in the vacuole increased at the expense of sugars located in chloroplasts and cytoplasm. The quantity of sugars that remained in the chloroplasts did not appear to be sufficient for complete membrane protection at very low freezing temperatures.     

The preservation of liposomes by raffinose family oligosaccharides during drying is mediated by effects on fusion and lipid phase transitions

Raffinose family oligosaccharides (RFO) have been implicated as protective agents in the cellular dehydration tolerance, especially of many plant seeds. However, their efficacy in stabilizing membranes during dehydration has never been systematically investigated. We have analyzed the effects of sucrose, raffinose, stachyose, and verbascose on liposome stability during air-drying. With increasing degree of polymerization (DP), the RFO were progressively better able to stabilize liposomes against leakage of aqueous content and against membrane fusion after rehydration. Indeed, there was a very tight linear correlation between fusion and leakage for all RFO. These data indicate that increased protection of liposomes against leakage with increasing DP is due to better protection against fusion. This is in accord with the higher glass transition temperature of the longer chain oligosaccharides. Further evidence for the influence of glass transitions on membrane stability in the dry state was provided by experiments testing the temperature dependence of membrane fusion. During incubation at temperatures up to 95 degrees C for 2 h, fusion increased less with temperature in the presence of higher DP sugars. This indicates that RFO with a higher glass transition temperature are better able to protect dry membranes at elevated temperatures. In addition, Fourier-transform infrared (FTIR) spectroscopy showed a reduction of the gel to liquid-crystalline phase transition temperature of dry liposomes in the presence of all investigated sugars. However, the RFO became slightly less effective with increasing chain length, again pointing to a decisive role for preventing fusion. A direct interaction of the RFO with the lipids was indicated by a strong effect of the sugars on the phosphate asymmetric stretch region of the infrared spectrum.     

Low amounts of sucrose are sufficient to depress the phase transition temperature of dry phosphatidylcholine, but not for lyoprotection of liposomes

Disaccharides such as sucrose and trehalose play an important role in stabilizing cellular structures during dehydration. In fact, most organisms that are able to survive desiccation accumulate high concentrations of sugars in their cells. The mechanisms involved in the stabilization of cellular membranes in the dry state have been investigated using model membranes, such as phosphatidylcholine liposomes. It has been proposed that the lyoprotection of liposomes depends on the depression of the gel to liquid-crystalline phase transition temperature (T(m)) of the dry membranes below ambient and on the prevention of membrane fusion by sugar glass formation, because both lead to leakage of soluble content from the liposomes. Since fusion is prevented at lower sugar/lipid mass ratios than leakage, it has been assumed that more sugar is needed to depress T(m) than to prevent fusion. Here, we show that this is not the case. In air-dried egg phosphatidylcholine liposomes, T(m) is depressed by >60 degrees C at sucrose/lipid mass ratios 10-fold lower than those needed to depress fusion to below 20%. In fact, T(m) is significantly reduced at mass ratios where no bulk sugar glass phase is detectable by Fourier transform infrared spectroscopy or differential scanning calorimetry. A detailed analysis of the interactions of sucrose with the P=O, C=O, and choline groups of the lipid and a comparison to published data on water binding to phospholipids suggests that T(m) is reduced by sucrose through a "water replacement" mechanism. However, the sucrose/lipid mass ratios necessary to prevent leakage exceed those necessary to prevent both phase transitions and membrane fusion. We hypothesize that kinetic phenomena during dehydration and rehydration may be responsible for this discrepancy.     

Phase transitions as a function of osmotic pressure in Saccharomyces cerevisiae whole cells, membrane extracts and phospholipid mixtures

Fourier Transform Infrared spectroscopy (FTIR) was used to determine the phase transition temperature of whole Saccharomyces cerevisiae W303-1 A cells as a function of Aw in binary water-glycerol media. A phase transition occurred at 12 °C in water, at 16.5 °C at Aw=0.75, and at 19.5 °C at Aw=0.65. The temperature ranges over which transition occurred increased with decreasing Aw. A total lipid extract of the plasma membranes isolated from S. cerevisiae cells was also studied, with a phase transition temperature determined at 20 °C in pure water and at 27 °C in binary water-glycerol solutions for both Aw levels tested. The pure phospholipids dimyristoylphosphatidylcholine (DMPC) and dimyristoylphosphatidylethanolamine (DMPE) and three binary mixtures of these phospholipids (percentage molar mixtures of DMPC/DMPE of 90.5/9.5, 74.8/25.2, and 39.7/60.3) were studied. For DMPC, there was no influence of Aw on the phase transition temperature (always 23 °C). On the other hand, the phase transition temperature of DMPE increased with decreasing Aw for the three aqueous solutions tested (glycerol, sorbitol and sucrose), from 48 °C in water, to 64 °C for a solution at Aw=0.67. For the DMPC/DMPE mixtures, transitions were found intermediate between those of the two phospholipids, and a cooperative state was observed between species at the gel and at the fluid phases.     

The effect of soil drought on the composition of carbohydrates in yellow lupin seeds and triticale kernels

Carbohydrate analysis was made of yellow lupin seeds (cv. Juno) and triticale kernels (cv. Dagro), produced by plants exposed to drought stress for 21 days after the initial flowering of the first node of lupin and initial earing of triticale. The seeds of all experimental variants were harvest at full maturity, dried and stored in linen bags at 18–20 °C. Soluble carbohydrates were extracted and analysed as described by Horbowicz and Obendorf (1994). Gas chromatographic separation of carbohydrates showed that raffinose family oligosaccharides (RFO) were dominant in lupin seeds. The other carbohydrates present were sucrose (10 %), cyclitols and galactosyl cyclitols (12–13 %). Soil drought resulted in higher levels of verbascose, but decreased the quantities of the other carbohydrates in lupine seeds. In triticale kernels, over 50 % of soluble sugars were composed of sucrose and maltose, while 17.7 % were raffinose and stachyose. In response to drought the content of mono- and oligosaccharides declined. The decrease of soluble carbohydrates content in seeds of lupin and triticale kernels has no effect on the seed germination and vigour. It is assumed that the changes in the concentration of soluble sugars observed under drought may impair the storability of triticale kernels, but improve it for lupine seeds.