The Damaging Effect of Water on Dry Pea Embryos During Imbibition

When pea seeds were imbibed in water without their seed coats,vital staining revealed that cells on the abaxial surface ofthe cotyledons were dead. No damage occurred on the surfaceof cotyledons when the seeds were imbibed intact, or beneaththe testa when only half of the testa was removed. Cell deathoccurred as a result of rapid water uptake within the first2 min of imbibition, since reducing the rate of imbibition insolutions of Carbowax 4000 lessened the damage. Cell death wasrestricted to the outer layers of the cotyledons; inner tissuesremained alive. These observations supported the hypothesisthat rapid early leakage during imbibition of dry embryos resultedfrom the death of cells caused by the physical disruption ofmembranes. Imbibition damage resulted in reduced respirationand germination, a decline in the rate of food reserve transferfrom the cotyledons to the growing axis, and a lower growthrate in the seedlings produced. Greater sensitivity of embryosto imbibition damage at low temperature, and similarities betweenfeatures of imbibition damage and chilling injury led to thesuggestion that so-called chilling injury is the result of imbibitiondamage rather than the effects of low temperature.     

The Role of Imbibition Damage in Determining the Vigour of White and Coloured Seed Lots of Dwarf French Beans (Phaseolus vulgaris)

Seeds of dwarf French beans showed evidence of damage alterimbibition in water in the form of dead tissue and high soluteleakage. Damage was more extensive in seeds of a cultivar withwhite testae (Tenderette) both at 20?C and with the initial6 h imbibition at 4?C where damage was more severe, whereasa cultivar with brown testae (Provider) was damaged only alterthe 4?C treatment. Tenderette imbibed more rapidly than Providerin both imbibition treatments. The significant correlationswithin each cultivar of both solute leakage (positive) and theextent of living tissue (negative) with the rate of water uptake,and the reduced damage when seeds imbibed slowly in PEG indicatedthat this was imbibition damage due to rapid water uptake. Differencesin the rates of water uptake were also observed in sand at 15%and 20% mc where rapid imbibition was associated with reducedgermination and the production of more abnormal seedlings. Atemperature of 4?C during the first 6 h germination in sandat 15% mc also reduced germination, particularly in Tcnderette.It is suggested that the more rapid water uptake by white seededcultivars of dwarf French beans and their greater susceptibilityto imbibition damage are responsible for their low vigour. Key words: Imbibition damage, vigour, dwarf French beans     

Temperature effects on soybean imbibition and leakage

As a part of an analysis of the nature of chilling injury to seeds, measurements were made of the initial linear rates of water entry into and solute leakage out of cotyledons of soybean at various temperatures. Arrhenius plots were approximately linear for water entry into both living and dead cotyledons, with the slope (and activation energy) for entry into living cells being insignificantly higher than for dead cells, suggesting little effect of membrane barriers on water entry. The plots for solute leakage showed 10-fold lower leakage rates from living than from dead tissues; a reversal of slope in the Arrhenius plot at temperatures below 15 C reflected increasing leakage rates, interpreted as a quantitative disruption of membrane reorganization at the temperatures associated with chilling injury.     

聚乙烯醇预处理提高大豆种子活力和抗冷能力的作用

聚乙烯醇预处理大豆种子和聚乙二醇一样,能明显地提高种子的活力、萌发率和抗冷能力。其主要作用可能是:在整个吸胀过程中减少了吸水速度,使膜的修复作用有足够的时间;启动和改善种子内部的生理代谢过程.保证了生长胚根有更多的物质供应。     

Soaking injury and its reversal with polyethylene glycol in relation to respiratory metabolism in high and low vigor soybean seeds

Germination and growth of unaged (high vigor) and accelerated aged (41°C and 100% RH for 4 days; low vigor) soybean [ Glycine max (L.) Merr. cv. Essex] seeds were severely reduced by soaking the seeds under water at 25°C during the first 1 to 8 h of imbibition. Soaking in 30% polyethylene glycol (PEG) did not injure high vigor seeds and improved the performance of low vigor seeds. Soaking in water increased subsequent RQ values and acetaldehyde and ethanol levels. In high vigor seeds, the increase in RQ lasted only 1 h after transfer to aerobic conditions, whereas in low vigor seeds the increase persisted into the second h. Increases in ethanol and acetaldehyde after soaking were more pronounced in low than in high vigor seeds. The data indicate that relatively short periods under water can cause water uptake injury to imbibing soybean seeds and that this injury can be avoided by osmotically reducing the initial rate of water uptake. Seeds whose vigor has declined during accelerated aging show an additional injury which increases with soaking duration and involves alterations in respiratory metabolism including accumulation of acetaldehyde and ethanol to high, and possibly toxic, levels during imbibition.     

The Importance of Genetically Determined Seed Coat Characteristics to Seed Quality in Grain Legumes

Comparisons of five pairs of isogenk lines of peas, differingonly in the A gene for seed coat colour showed that white seeds(genotype aa) imbibed more rapidly than coloured seeds (AA),suffered greater imbibition damage revealed by dead tissue onthe cotyledons, and higher solute leakage. Seed-coat pigmentationwas closely associated with slow water uptake, since when expressionof the A gene was suppressed by the recessive pollens gene,the resulting white seeds {palpal AA) imbibed rapidly. The slowwater uptake by coloured seeds was not due to the restrictionof water entry by the seed coat since the differences in imbibitionrate were maintained when a portion of the seed coat was removedand seeds were imbibed with the exposed cotyledon in contactwith moist filter paper. Imbibition of similarly treated seedsby immersion in polyethylene glycol solutions (1–4%) whichincreased the seed/solution wettability, had little effect onthe water uptake of coloured seeds compared to imbibition inwater whereas that of white seeds increased in the first 10mins imbibition. Poor wettability of the inner surface of colouredseed coats did not therefore explain the slow imbibition ofthese seeds. The white seed coats loosened rapidly during imbibitionwhilst the coloured seed coats remained closely associated withthe cotyledons suggesting that the adherence of the seed coatto the cotyledons and therefore the ease of access of waterbetween the testa and cotyledons determines the rate of imbibition.The rapid water uptake by white-coated seeds and the subsequentimbibition damage may explain the high incidence of infectionof these seeds by the soil-bome fungus Pythhan after 2 d insoil. Improved seed quality and emergence may therefore be achievedby breeding for seed coat characteristics leading to reducedrates of imbibition Pisum sativum, isogenic lines, A gene, seed coat colour, imbibition, imbibition damage, wettability, pollens gene, seed quality, grain legumes     

ULTRASTRUCTURAL ASPECTS OF CHILLING INJURY IN THE SOYBEAN SEED RADICLE

Imbibitional chilling injury of soybean seeds was studied using light and electron microscopy. Intact seeds were allowed to take up water at 4 C or room temperatures and the ultrastructure of the radicle was examined after hydration. In chilled seeds, mitochondria showed weakly defined envelopes and cristae, in contrast to the well-formed internal structure in the controls. Nuclei of chilled seeds were irregular in shape. Tannic acid was used as a probe of plasmalemma integrity. Most cells in both chilled and control treatments were able to exclude tannin, indicating that chilling injury effects did not damage the plasma membrane enough to allow passage of molecules of that size.     

Relationship between Thermal Transitions and Freezing Injury in Pea and Soybean Seeds

In an attempt to correlate freezable water with freezing injury, the thermal behavior of pea (Pisum sativum L.) and soybean (Glycine max L. Merr) seed parts at different moisture contents were compared with survival of the seeds when exposed to low temperatures. Thermal transitions between −150 and 10°C were studied using differential scanning calorimetry. In pea, reduction of germinability, after exposure of seeds to temperatures between − 18 and − 180°C, occurred at a constant moisture content (about 0.33 gram H₂O/gram dry weight) regardless of the temperature; this moisture level was above that at which freezable water was first detectable by differential scanning calorimetry (0.26 gram H₂O/gram dry weight). In contrast, damage to soybean seeds was observed at progressively lower moisture contents (from 0.33 to 0.20 gram H₂O/gram dry weight) when the temperature was decreased from −18°C to −50°C. At −18 and −30°C, moisture contents at which damage to soybean seeds was evident were above that at which freezable water was first detectable (0.23 gram H₂O/gram dry weight). However, at −50, −80, and −180°C, damage was evident even when freezable water was not detectable. The data suggest that, while the quantity of water is important in the expression of freezing injury, the presence of freezable water does not account for the damage.     

Effects of temperature and drying rate during dehydration of celery seeds on germination, leakage and response to gibberellin and cytokinin

A high temperature treatment of 32°C which prevents dehydration injury in celery seeds imbibed for 3 days at 17°C and then dried at 20°C, reduced leakage during rehydration, compared with seeds not given the high temperature treatment. Treatments which would normally release celery seeds from dormancy, such as low temperature imbibition or gibberellin (GA_4/7) and benzyladenine (BA) applications had little effect on the germination of seeds exhibiting desiccation injury. However, GA_4/7 did induce splitting of the seed coat and swelling of the endosperm, and this effect was enhanced by BA. It is suggested that in celery seeds high temperature prevents irreversible embryo damage, including membrane damage, caused by drying.     

Partial Sequence Analysis of the 5S to 18S rRNA Gene Region of the Maize Mitochondrial Genome

Measurements of the rate of imbibition by isolated cotyledons of soybean (Glycine max (L.) Merr cv Wayne) indicated that water uptake rates were slowed by low temperatures and by low initial moisture contents of the tissue. The role of water viscosity in the temperature effects on imbibition was examined, and a linear relation between imbibition rate and the reciprocal of viscosity was found only for seeds of very high initial moisture content. Adding solutes which lowered the surface tension, or increased the wetting ability of the water, yielded markedly increased rates of imbibition, especially for tissue of low initial moisture content. The data are interpreted as indicating a first component of water entry which is a wetting reaction influenced by the surface tension of the water, and a second component which resembles water flow through a porous matrix and is influenced by the water viscosity. We speculate that damage to soybeans during imbibition, such as in the case of chilling injury, may be particularly related to the initial wetting reaction rather than to the longer-term imbibitional rate.     

Imbibition temperature sensitivity of lima bean seeds controlled by initial seed moisture

Excised embryonic axes and whole seeds of Phaseolus lunatus L. were previously shown to be injured if exposed to low (5°-15°) temperature during the initial stages of imbibition. Present data show that this chilling injury during imbibition of liquid water can be prevented if axes are first allowed to absorb water vapor. The increase of initial water content to 20% increases growth even of unchilled axes, and reduces leaching of 264 mμ absorbing compounds. Protection resulting from increased water content is at first independent of the temperature at which water vapor was absorbed. However, longer exposure of high moisture axes to low temperature results in typical chilling injury. The response to initial seed moisture is repeatedly reversible with changes in water content. Because the same response occurs in intact seeds, it may be possible both to protect them against low temperature injury and to increase vigor by increasing seed water-content prior to planting.     

Prevention of imbibitional injury in low vigor soybean embryonic axes by osmotic control of water uptake

Deterioration of soybean [ Glycine max (L.) Merr. cv. Essex] seeds during accelerated aging at 41°C and 100% relative humidity predisposes the embryonic axis to injury during the initial period of imbibition. This injury was prevented or greatly reduced in severity when excised axes were imbibed on blotters containing 30% polyethylene glycol which slowed the rate of water uptake and when axes were pre-equilibrated to a high moisture level. Rates of water uptake by "high"(no treatment) and "low vigor"(accelerated aged) excised axes were identical. However, high vigor axes tolerated rapid water uptake during early imbition, whereas low vigor axes did not. Leakage of electrolytes during early imbibition was nearly six times greater in low than in high vigor axes. Polyethylene glycol significantly reduced the leakage of electrolytes from both low and high vigor axes. The data are in agreement with the hypothesis that seed deterioration in soybeans involves membrane changes which may predispose embryonic tissues to injury during imbibition. Reduction of the rate of water uptake during the initial period of imbibition would allow extra time for membrane repair or rearrangement, thus permitting the tissues to develop in a more orderly manner. The data indicate that deterioration in soybean seeds involves, at least in part, a decrease in ability of seed axes to tolerate rapid water uptake at the start of imbibition and that this weakness may be compensated by osmotic control of water uptake.     

Hypoxia and Imbibition Injuries to Aging Seeds

The development of hypoxia and primary injuries were examined during the imbibition of aging pea seeds (Pisum sativum L., cv. Nemchinovskii). The distribution of air-dry pea seeds by their room-temperature phosphorescence revealed the presence of two fractions (I and II) in a seed lot with 72% germinability and three fractions (I, II, and III) in a seed lot with 50% germinability. The water uptake during imbibition was slower in the fraction I seeds than in the fraction-II seeds. The fraction-I seeds produced normal seedlings, whereas the fraction-II seeds either produced seedlings with morphological defects (abnormal) or did not germinate at all. The fraction-III seeds were all dead. The phosphorescence of endogenous porphyrins, emitted only at low O₂ content, was measured after 20-h seed imbibition. The fraction-I seeds emitted no discernible phosphorescence. The fraction-II comprised highly phosphorescent seeds incapable of radicle protrusion and moderately phosphorescent seeds producing abnormal seedlings. The fraction-II seeds experienced hypoxia during the imbibition because of rapid oxygen consumption by the embryo and restrictions to O₂ diffusion imposed by the seed coat. In the fraction-I seeds, the rate of oxygen consumption by the embryo was slower and the seed coat resistance to oxygen diffusion was lower than in the fraction-II seeds. Therefore, hypoxia did not arise in the fraction-I seeds. The submergence of seeds in water caused lethal injuries. The imbibition of seeds without any contact with water caused no lethal damages but did not reduce the percentage of seeds dying of hypoxia. A slow imbibition of seeds in the media containing either an osmoticum (PEG) or an inhibitor of aquaporin channels (p-chloromercuribenzoate) prevented the lethal injuries at early stages of seed hydration and retarded the appearance of oxygen deficiency in fraction-II seeds. Different rates of water uptake by fraction-I and fraction-II seeds were controlled by permeability of cell membranes rather than by permeability of seed coat. It is proposed that low permeability of plasma membranes to water in fraction-I seeds results from the predominantly closed aquaporin channels, whereas a higher permeability of weak seeds (fraction II) is due to open channels.     

Response of “storage” effects in barley seeds to the dose of ethyl methanesulphonate and X-ray treatment

1. Ethyl methanesulphonate (BMS)-treated barley seeds stored at 30 % water content for 1 – 4 weeks are capable of recovering from the mutagen induced injury. The level and speed of the recovery depends on the EMS dose and storage period. Seeds treated with extremely severe EMS doses reducing the% of germination to 5 – 10 % cannot recover from the induced injury. 2. Due to a 1 to 6 weeks storage of EMS-treated seeds with 20 % water content the amount of induced injury increases in dependence on the applied EMS dose and storage period. Doses of EMS, reducing the seedling height in the M₁ generation to 90 – 95 % of the control reveal no storage after-effects. 3. Storage of X-ray exposed seeds at 20 % or 30 % water content did not result in any significant changes in the yield of induced genetic damage.     

Function of the ascorbate-glutathione cycle in aged sunflower seeds

The function of the ascorbate-glutathione (AsA/GSH) cycle was analyzed in seeds of sunflower ( Helianthus annuus L. cv. Peredovik) subjected to accelerated ageing at 43°C and 75% relative humidity for 1 to 11 days. The study was performed using dry seeds and seeds hydrated by imbibition in distilled water for 4 h at 25 °C. Lipid peroxidation was also determined by measuring the malondialdehyde (MDA) level. As the ageing period increased, a progressive loss of seed viability became increasingly evident. Even though high levels of MDA were delected, the MDA level did not change during accelerated ageing, suggesting that lipid peroxidation might occur to some extent. The study of the ascorbate/glutathione (AsA/GSH) cycle revealed that the GSH system is the major detoxifying mechanism in both dry and imbibed sunflower seeds. The GSH system is mainly located in the embryo, and its protective role is mediated by reactions that consume the GSH pool and, thereby, minimize the increase of the oxidized form (GSSG). Seed imbibition activates cellular metabolism and allows some antioxidant enzymes like glutathione reductase (EC 1,6,4,2) to act upon toxic agents. These reactions provide a reducing status, so that repair of damage becomes possible. However, prolonged ageing conditions (11 days) result in an irreversible damage, as evidenced by the appearance of dead seeds when the germination period ended. Multiple regression analysis revealed the effectiveness of the GSH system in aged seeds, especially upon imbibition and until the AsA/GSH cycle became completely functional.     

Increased drying rate lowers the critical water content for survival in embryonic axes of English oak (Quercus robur L.) seeds

The potential to cryopreserve embryonic axes of desiccation-sensitive (recalcitrant) seeds is limited by damage during the desiccation necessary for low temperature survival, but the basis of this injury and how to reduce it is not well understood. The effects of drying rate on the viability, respiratory metabolism and free radical-mediated processes were therefore investigated during dehydration of Quercus robur L. embryonic axes. Viability, assessed by evidence of germination and tetrazolium staining, showed a sharp decline at 0.27 and 0.8 g/g during rapid (<12 h) or slow (3 d) dehydration, respectively. Rapid dehydration therefore lowered the critical water content for survival. At any given water content rapid dehydration was associated with higher activities of the free radical processing enzymes, superoxide dismutase, catalase and glutathione reductase and lower levels of hydroperoxide and membrane damage. Rapid dehydration was also associated with lower malate dehydrogenase activity, and a reduced decline in phosphofructokinase activity and in levels of the oxidized form of nicotinamide dinucleotide. Ageing may have contributed to increased damage during slow dehydration, since viability declined even in hydrated storage after 3 d. The results presented are consistent with rapid dehydration reducing the accumulation of damage resulting from desiccation induced aqueous-based deleterious reactions.     

Alcohol Stress on Soya Bean Seeds

When soya bean seeds were exposed to pure aliphatic alcohols,the shorter alcohols were the most damaging (methanol > ethanol> n-propanol > n-butanol); when the alcohols were appliedin equal volumes of water, the opposite was found (n-propanol> ethanol > methanol), leakage of solutes from the pre-treatedtissue during subsequent imbibition in water was associatedin each case with the loss of germination and a decline in axisgrowth. Damage by the pure alcohols was related to the extentof their penetration and the amount of phospholipid eluted,injury caused by alcohols in the presence of water did not exhibitthese functions. It is proposed that damage to seeds by alcoholsis due to the elution or displacement of cellular phospholipidsand possibly the partial denaturation of membrane proteins Membranedamage is considered to be a prime cause of injury to the seed. Glycine max (L.) Merr., soya bean, seed, denaturation of membranes, alcohols, phospholipids     

Lipid peroxidation, carbohydrate hydrolysis, and Amadori-Maillard reaction at early stages of dry seed aging

Processes underlying aging of air-dry seeds were investigated. Naturally aged seeds of pea (Pisum sativum L.), cucumber (Cucumis sativus L.), and buckwheat (Fagopyrum esculentum Moench.) were separated into three fractions of different quality according to their room temperature phosphorescence (RTP): fraction I contained strong seeds; fraction II comprised weak seeds; and fraction III was composed of dead seeds. These seed fractions were used to identify the processes in air-dry seeds that account for the initial deterioration in seed quality at early stages of aging and for the possible transient improvement of seed quality at further aging. Experiments with seed powders showed that the increase in thermochemiluminescence (TCL) in the temperature range of 50?C110°C was determined by the presence of lipid peroxidation products. No difference was observed between TCL levels in fraction I and fraction II seeds; hence, lipid peroxidation is not responsible for the transition of strong seeds to the fraction of weak seeds. The TCL intensity monitored upon heating in the range of 50?C110°C increased only in the fraction of dead seeds. In fraction II seeds, a twofold increase in TCL upon heating at 150°C was observed in aged seeds; this indicates that the products of oligosaccharide hydrolysis (glucose) were more abundant in fraction II seeds than in fraction I seeds under similar conditions. This assumption was confirmed by direct determination of glucose content with a glucometer. Hence, the transition of air-dry seeds from fraction I (strong seeds) to fraction II (weak seeds) occurred due to the activation of carbohydrate hydrolysis in aging seeds. Since air-dry seeds contain no free water during aging, the seed moisture content decreases during hydrolysis, presumably, because the bound water participates in the hydrolysis reaction. The decrease in ??improved?? seeds of glucose content and the increase in moisture content suggest the activation of amino-carbonyl reaction. It is proposed that the amino-carbonyl (Amadori-Maillard) reaction is responsible for closing water channels in improved seeds, as well as for the decreased water permeability of cell membranes during seed imbibition.     

Influence of insulating dead leaves and low temperatures on water balance in an Andean giant rosette plant

Abstract. The influence of insulating dead leaves on water balance in Espeletia timotensis Cuatr., an Andean caulescent giant rosette plant, was studied under field and laboratory conditions. Removal of the dead leaf layer surrounding the stem changed the pattern of diurnal stem temperature variation and produced transient and permanent effects on water balance. The pattern of liquid water flow resistance increase at low stem temperatures suggested that much of the water flow in the stem was through living membranes, probably those of the pith cells. The pith was determined to be an important source of stored water for daily transpirational needs. The lethal effects of dead leaf removal were attributed to one or more of the following causes: (1) inhibition of pith recharge by subfreezing stem temperatures; (2) embolisms in stem xylem; (3) freezing injury to pith tissue. The results suggested that an insulating layer of marcescent leaves and the presence of an internal water reservoir closer to the rosette than the soil water are important adaptations for maintenance of a favourable water balance in tropical alpine habitats where freezing temperatures occur regularly but last only a few hours.     

Possible involvement of aquaporins in water uptake by pea seeds differing in quality

Using the method of room temperature phosphorescence (RTP), we divided air-dry pea (Pisum sativum L.) seeds subjected to accelerated ageing (40°C, 85% relative humidity) into three fractions: (I) high-quality seeds, (II) weakened seeds, and (III) dead seeds. In the process of ageing, seed germinability firstly decreased and then increased due to so-called “improved” seeds of fraction II, which returned to fraction I as judged from the RTP level; the germinability of these seeds became equal to that of fraction I seeds. Seeds capable of germination (fractions I and II) differed in the rates of imbibition, which depended on plasma membrane permeability (opened or closed water channels) but not on the presence of the seed coat. A low activation energy of seed imbibition in fraction II (less than 5 kcal/mol) indicates that water channels are open. A mercury-containing compound (5 μM p-chloromercuribenzoate (PCMB) reduced the rate of water uptake by these seeds, and dithiothreitol restored it. A high activation energy of fraction I seed imbibition (more than 12 kcal/mol) corresponded to the water uptake mainly across the lipid bilayer when water channels are closed. PCMB did not affect the rate of fraction I seed imbibition. We supposed that mature air-dry pea seeds had open water channels. During the first stages of fraction I seed imbibition, these channels were closed, limiting water uptake. NaF (100 μM), an inhibitor of phosphatase, prevented channel closing and accelerated the imbibition of fraction I seeds. It did not affect the imbibition rate of fraction II seeds, indicating their water channels to be opened. However, NaF did not affect the water uptake of “improved” fraction II seeds as well. It seems likely that their channels were closed during accelerated ageing but otherwise than via dephosphorylation. The results obtained indicate the possibility of water inflow regulation in the weakened seeds via the state of aquaporins, which form water channels in the membranes.