Ageing-induced changes in glutathione system of sunflower seeds

The glutathione system is thought to be involved in defence mechanisms present in plant tissues. The efficacy of this system was evaluated in large seeds of sunflower ( Helianthus annuus L. cv. Peredovik) in response to accelerated ageing (43°C/75% relative humidity from 1 to 11 days). Differences between the embryo axis and cotyledons in relation to the glutathione system were also investigated. Additionally, lipid peroxidation was determined by measuring the malondialdehyde (MDA) content. All assays were performed using dry seeds and seeds subsequently hydrated by imbibition in distilled water for 12 h at 25°C. Accelerated ageing caused a marked decrease in seed viability, accompanied by an increase in mean germination time. There were no changes in total glutathione in dry seeds. However, the distribution in its reduced (GSH) and oxidized (GSSG) forms revealed that ageing produced a slow conversion from GSH to GSSG. As the ageing period increased, this effect was accompanied by a decrease in glutathione reductase (GR, EC 1.6.4.2) activity. The results also indicated that the GSH system exerts a different response in the embryo axis as compared with the cotyledon: (1) the GSH levels decreased less in the cotyledons than in axes of aged seeds, and (2) the GSSG level in cotyledons was independent of ageing, while its amount increased in aged embryo axes. These different responses, in conjunction with the lower MDA levels in large as compared with small seeds, indicate a possible protective role of the reserve lipids. The efficacy of the GSH system in aged seeds was associated with seed viability, as revealed by multiple regression analysis. Upon imbibition, aged seeds were able to restore their GSH levels, reaching values approximating those of unaged seeds.     

Transport and Metabolism of Dihydrozeatin Riboside in Germinating Lupin Seeds

[³H]-dihydrozeatin riboside was applied selectively to the embryonicaxes or to the cotyledons of germinating lupin (Lupinus luteusL. cv. Weiko III) seeds 6 h following the start of imbibition.There was little transport of dihydrozeatin riboside from embryoto cotyledons up to 6 h after the application, but a substantialamount of radioactivity had moved into the cotyledons at theend of the 10 h incubation period. However, there was no detectablemovement of [³H]-dihydrozeatin riboside from the cotyledonsto the embryonic axis. This indicated a highly polarized movementof cytokinins during the early stages of seed germination. Exogenouslyapplied [³H]-dihydrozeatin riboside was found to be very stable,both when applied to the embryonic axes and cotyledons of intactseed, or following excision, and there was little metabolismwith only small amounts of radioactivity found associated withdegradative metabolites. The embryonic axis of this specieshas recently been found to synthesize cytokinins within 12 hfrom the start of imbibition, and the results of this studyindicate that the embryo-derived cytokinin is probably transportedto the cotyledons where it accumulates and subsequently participatesin the control of cotyledon function. Key words: Lupinus luteus, cytokinin transport and metabolism, dihydrozeatin riboside, seed germination     

Amide-Linked Indoleacetic Acid Conjugates May Control Levels of Indoleacetic Acid in Germinating Seedlings of Phaseolus vulgaris

We have shown that amide-linked IAA (indole-3-acetic acid) conjugates accumulated to high levels during maturation of bean seeds (K. Bialek and J.D. Cohen [1989] Plant Physiol 91: 775-779). In the present study, we were interested in the fate of these and other IAA conjugates during seed germination. The content of amide-linked conjugates of IAA in cotyledons declined dramatically during the first hours of imbibition. The rate of decline slowed markedly during the period of the resumption of axis growth. The level of amide-linked IAA conjugates in cotyledons remained relatively high after almost 1 week of germination. The decline of IAA conjugates in cotyledons was followed by a steady increase in the content of both free and amide-linked IAA in the embryonic axes. Amide-linked IAA conjugates were also present in the axes cultured on agar after the cotyledons were removed, which suggests that de novo production of these IAA conjugates occurs in the axis of germinating bean seedlings. A comparison of relative amounts of free and conjugated IAA in the axes of intact seedlings and axes cultured on agar showed lower levels of free IAA and higher levels of conjugated IAA in much slower growing isolated axes. These results suggest a more general role for IAA conjugates in the control of seedling growth than simply to serve as a seed storage form of auxin.     

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.     

Endogenous abscisic acid during the germination of chick-pea seeds

Over the past twenty years many studies have been undertaken to elucidate the regulation of seed germination. Abscisic acid (ABA) and the gibberellins (GAs) are the hormones proposed to control this process, the first by inhibiting and the second by inducing germination. It has been proposed that a high water potential increases the growth potential of the embryo, presumably permitting the production or activation by GA of the cell wall hydrolases and thus decreasing the yield threshold of the endosperm close to the radicle tip. A low water potential, e.g., imbibition in an osmoticum. imposes a stress on cell metabolism, by reducing the turgor of the radicle cells, and there is a decrease in growth potential. Exogenous ABA also causes a decline in growth potential of the radicle: however, the actions of low water potential in preventing germination are not mediated through an increase in ABA in the seeds. In the present paper an attempt is made to asses the role of ABA and polyethylene glycol (PEG) in the germination of chick-pea (Cicer arietinum L.) seeds. The endogenous ABA of chick-pea seeds was purified by reversed-phase HPLC and quantified by GC-ECD. The variations in the ABA levels in the embryonic axes and the cotyledons were studied during 120 h. of imbibition. The highest ABA level in the embryome axes was found at 18 h. coinciding with an increase in fresh weight and a high germination percentage. ABA was not detected in the cotyledons during incubation which probably indicates that the hormone is more involved in the active growth of the embryonic axes itself than in the mobilization process of the reserves. When seeds were treated with different PEG-cycles. PEG delayed germination, reduced the fresh weight of embryonic axes, and retarded the onset of ABA synthesis. It is concluded that endogenous ABA is related to the onset of germination and the growth of the embryonic axis. In addition, there is no correlation among the different PEG-cycles and the level of ABA and germination. Germination was related more to the water conditions inside the embryo's cells than to ABA levels.     

Differential response of antioxidative enzymes in embryonic axes and cotyledons of germinating lupine seeds

Germination of lupine (Lupinus luteus L.) seeds was accompanied by an increase in concentration of free radicals with g ₁ and g ₂ values of 2.0056 ± 0.0003 and 2.0033 ± 0.0005, respectively. The highest intensity of free radical signal was observed in embryo axes immediately after radicle protruded through the seed coat. Hydrogen peroxide accumulated in embryonic axes and cotyledons during imbibition before the onset of germination in the seed population. The activities of superoxide dismutase (SOD, EC 1.15.1.1) and catalase (CAT, EC 1.11.1.6) rose progressively in embryo axes. In cotyledons SOD activity did not change significantly, while that of CAT increased during germination. The enhancement of Cu, Zn-SODs and Mn-SOD isoforms in embryonic axes was observed. A new isoform of catalase was synthesized, suggesting that it plays a relevant role during germination. SOD and CAT activities were detected in dry seeds. Free radical generation and response of antioxidative enzymes differed between embryo axes and cotyledons during the germination timecourse.     

Role of Endogenous Growth Regulators in Seed Dormancy of Avena fatua: I. Short Chain Fatty Acids

The hypothesis that endogenous short chain fatty acids (C 6-C 10) are important in maintaining seeds of wild oat (Avena fatua L.) in the dormant state by acting as natural germination inhibitors (Berrie, Buller, Don, Parker, 1979 Plant Physiol 63: 758-764) was investigated. When germination of nondormant seeds was inhibited by treatment with short chain fatty acids, the seeds did not revert to a similar biochemical and physiological state as exhibited by dormant seeds. First, nonanoic acid-induced inhibition of seed germination was not reversed by hormone treatments which normally break dormancy in wild oat seeds. Second, nondormant seeds treated with short chain fatty acids maintained similar relative proportions of the pentose phosphate pathway and the Embden-Meyerhoff-Parnas pathway for respiratory glucose metabolism as that found in the nondormant controls. Seeds imbibed in the presence of nonanoic acid lost more amino acids and proteins into the imbibition solution than did the untreated controls, suggesting membrane damage had occurred. Inasmuch as increasing concentrations of nonanoic acid also progressively reduced the growth of the coleoptile and roots of intact seedlings until all growth ceased and no germination occurred, the inhibition of seed germination could be due to a nonspecific inhibition of growth of the embryo, perhaps because of disruption of membrane structure and function. Finally, no correlation between endogenous levels of short chain fatty acids in seeds or isolated embryonic axes and seed dormancy could be demonstrated.     

Changes in trigonelline (N-methylnicotinic acid) content and nicotinic acid metabolism during germination of mungbean (Phaseolus aureus) seeds

Changes in trigonelline content and in biosynthetic activity were determined in the cotyledons and embryonic axes of etiolated mungbean (Phaseolus aureus) seedlings during germination. Accumulation of trigonelline (c. 240 nmol per pair of cotyledons) was observed in the cotyledons of dry seeds; trigonelline content decreased 2 d after imbibition. Trigonelline content in the embryonic axes increased with seedling growth and reached a peak (c. 380 nmol per embryonic axis) at day 5. Trigonelline content did not change significantly during the differentiation of hypocotyls, and the concentration was greatest in the apical 5 mm. Nicotinic acid and nicotinamide were better precursors for pyridine nucleotide synthesis than quinolinic acid, but no great differences were found in the synthesis of trigonelline from these three precursors. Trigonelline synthesis was always higher in embryonic axes than in cotyledons. Activity of quinolinate phosphoribosyltransferase (EC 2.4.2.19), nicotinate phosphoribosyltransferase (EC 2.4.2.11), and nicotinamidase (EC 3.5.1.19) was found in cotyledons and embryonic axes, but no nicotinamide phosphoribosyltransferase (EC 2.4.2.12) activity was detected. It follows that quinolinic acid and nicotinic acid were directly converted to nicotinic acid mononucleotide by the respective phosphoribosyltransferases, but nicotinamide appeared to be converted to nicotinic acid mononucleotide after conversion to nicotinic acid. Trigonelline synthase (nicotinate N-methyltransferase, EC 2.1.1.7) activity increased in the embryonic axes, but decreased in cotyledons during germination. [14C]Nicotinic acid and trigonelline absorbed by the cotyledons were transported to the embryonic axes during germination. Trigonelline had no effect on the growth of seedlings, but nicotinic acid and nicotinamide significantly inhibited the growth of roots. Based on these findings, the role of trigonelline synthesis in mungbean seedlings is discussed.     

Phospholipids and the Phospholipid Fatty Acids of Germinating Hazel Seeds (Corylus avellana L.)

An analysis of the phospholipids and phospholipid fatty acidsof germinating hazel seeds has been carried out. The phospholipidcontent of the cotyledons and embryonic axes increased duringgermination. Early increases in the relative amounts of phosphatidylglycerol and decreases in the relative amounts of phosphatidylethanolamine occurred in both cotyledons and axes. The laterstages of germination were accompanied by further changes inthe phospholipid composition of the axes. Increases in the degreeof unsaturation of the C₁₈ fatty acids occurred in both tissues.     

Gibberellin-like activity in cotyledons and embryonic axes during pea seed germination

Endogenous gibberellin-like activity was determined in dry pea seeds (Pisum sativum cv. Bördi), in cotyledons and axes of germinating pea seeds and also in excised cotyledons and axes. During the first two days of pea seed germination, neither the embryonic axes nor the cotyledons show a mutual influence on gibberellin activity, but this appears after 72–96 h of germination. The gibberellin-like activity m cotyledons and axes of germinating seeds increased during the same period, but it decreased in isolated axes and excised cotyledons.     

Ureide metabolism during seedling development in French bean (Phaseolus vulgaris)

French bean ( Phaseolus vulgaris ) is a legume that transports most of the atmospheric nitrogen fixed in its nodules to the aerial parts of the plant as ureides. Changes in ureide content and in enzymatic activities involved in their metabolism were identified in the cotyledons and embryonic axes during germination and early seedling development. Accumulation of ureides (ca. 1300 nmol per pair of cotyledons) was observed in the cotyledons of dry seeds. Throughout germination, the total amount of ureides slightly decreased to about 1200 nmol, but increased both in cotyledons and in embryonic axes after radicle emergence. In the axes, the ureides were almost equally distributed in roots, hypocotyls and epicotyls. The pattern of ureide distribution was not affected by the presence of nitrate or sucrose in the media up to 6 days after imbibition. Ureides are synthesized from purines because allopurinol (a xanthine dehydrogenase inhibitor) blocks the increase of ureides. Allantoin and allantoate-degrading activities were detected in French bean dried seeds, whereas no ureidoglycolate-degrading activity was detected. During germination, the levels of the three activities remain unchanged in cotyledons. After radicle emergence, the levels of activities in cotyledons changed. Allantoin-degrading activity increased, allantoate-degrading activity decreased and ureidoglycolate-degrading activity remained undetectable in cotyledons. In developing embryonic axes, the three activities were detected throughout germination and early seedling development. The embryonic axes are able to synthesize ureides, because those compounds accumulated in axes without cotyledons.     

Allelopathy due to purine alkaloids in tea seeds during germination

Summary During imbibition of whole tea seeds (6 days) two purine alkaloids, caffeine and theobromine, did not decrease in the seed coats and there was no increase in the seeds. In parallel with and after the breaking of seed coats there was a gradual release of caffeine from coats of germinating seeds. By contrast, when the seed was freed from the outer seed coat and soaked, imbibition of the seed required only 2 days and simultaneously caffeine was released from the inner seed coat. In such seeds, but not in whole seeds, growth of embryonic tissues (roots and shoots) was inhibited after the breaking of the inner seed coats. Nevertheless, caffeine increased more in such roots of the seedlings of decoated seeds than in roots of normal seedlings.     

Allene Oxide Synthase and Allene Oxide Cyclase,Enzymes of the Jasmonic Acid Pathway,Localized in Glycine max Tissues

Because jasmonic acid regulates a number of processes, including the expression of vegetative storage proteins in soybean (Glycine max L.) leaves, the relative activity of a specific portion of the jasmonic acid biosynthetic pathway in soybean tissues was examined. Allene oxide synthase and allene oxide cyclase were examined because they constitute a branch point leading specifically from 13(S)-hydroperoxy-9(Z), 11(E), 15(Z)-octadecatrienoic acid to 12-oxo-phytodienoic acid, the precursor of jasmonic acid. From growing plants, seed coats (hila plus testae) of green fruits (38 d post-anthesis) were most active, eliciting about 1.5 times greater activity on a per milligram of protein basis than the next most active tissue, which was the pericarp. Leaves from fruiting plants were only one-seventh as active as seed coats, and activities in both immature cotyledons and embryonic axes were very low. No activity was detected in any part of stored, mature seeds. After 72 h of germination of stored seeds, a small amount of activity, about 4% of that in immature seed coats, was found in the plumule-hypocotyl-root, and no activity was detected in the cotyledons. The high levels of jasmonic acid biosynthetic enzymes in soybean pericarp and seed coat suggest a role for jasmonic acid in the transfer of assimilate to seeds.     

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     

Comparison of globulin mobilization and cysteine proteinases in embryonic axes and cotyledons during germination and seedling growth of vetch (Vicia sativa L.)

Vicilin and legumin, the storage globulins of mature dry vetch (Vicia sativa L.) seeds, are found in protein bodies which are present not only in the cotyledons, but also in the radicle, axis and shoot (together, for reasons of simplicity, here called axis). When at 24 h after the start of imbibition (hai) the radicle breaks through the seed coat a major part of the globulins in the axis has already been degraded, whereas in the cotyledons globulin breakdown cannot yet be detected. Globulin mobilization starts with the degradation of vicilin. At 48 hai when globulin mobilization in the cotyledons just begins, the axis is already nearly depleted of globulins. Mobilization of storage globulin is probably brought about by a complex of different cysteine proteinases (CPRs). The papain-like CPR2 and CPR4, and the legumain-like VsPB2, together with their mRNAs, are already present in axes and cotyledons of dry seeds. This means that they must have been formed during seed maturation. Additional papain-like CPRs are formed later during germination and seedling growth. CPR4 and VsPB2 together with their corresponding mRNAs become undetectable as germination and seedling growth proceed. VsPB2 and VsPB2-mRNA are substituted by the homologous legumain-like proteinase B and its mRNA. The composition of stored and newly formed CPRs undergoes developmental changes which differ between axes and cotyledons. It is concluded that storage globulin mobilization in germinating vetch seeds is started by stored CPRs, whereas the mobilization of the bulk of globulin is predominantly mediated by CPRs which are formed de novo.     

Different functions of vicilin and legumin are reflected in the histopattern of globulin mobilization during germination of vetch (Vicia sativa L.)

The temporal and spatial patterns of storage-globulin mobilization were immunohistochemically pursued in the embryonic axis and cotyledons of vetch seed (Vicia sativa L.) during germination and early seedling growth. Embryonic axes as well as cotyledons of mature seeds contain protein bodies with stored globulins. Prevascular strands of axes and cotyledons, the radicle and epidermal layers of axis organs were nearly exclusively stained by vicilin antibodies whereas the cotyledonous storage mesophyll gave similar staining for vicilin and legumin. Globulin breakdown started locally where growth and differentiation commenced in the axis. There, vicilin mobilization preceded legumin mobilization. Thus vicilin represents the initial source of amino acids for early growth and differentiation processes in vetch. Legumin presumably only serves as a bulk amino acid source for subsequent seedling growth during postgerminative globulin degradation. During the first 2–3 d after the start of imbibition the axis was depleted of globulins whereas no decrease in immunostainability was detected in the cotyledons except in their vascular strands where immunostainability was almost completely lost at this time. Continuous vascular strands were established at the third day when globulin breakdown was finished in the axis but had just started in the cotyledon mesophyll. Protein mobilization proceeded in a small zone from the epidermis towards the vascular strands in the center of the cotyledons. In this zone the storage cells, which initially appeared densely packed with starch grains and protein bodies, concomitantly transformed into cells with a large central vacuole and only a thin cytoplasmic layer attached to the cell wall. These results agree well with the hypothesis that during the first 2 d after imbibition the axis is autonomous in amino acid provision. After the endogenous reserves of the axis are depleted and the conductive tissue has differentiated, globulins are mobilized in the cotyledons, suggesting that then the amino acid supply is taken over by the cotyledons. For comparison with other degradation patterns we used garden bean (Phaseolus vulgaris L) and rape (Brassica napus L.) as reference plants. Received: 3 August 1999 / Accepted: 11 December 1999     

Effects of gibberellic Acid and gold light on germination, enzyme activities, and amino Acid pool size in a dwarf strain of watermelon

Gibberellic acid (GA₃) promotes and continuous gold light inhibits germination of seeds of a dwarf strain (WB-2) of watermelon [Citrullus lanatus (Thunb.) Matsu. and Nakai]. Osmotic inhibition of germination with mannitol in light-grown seeds of WB-2 was only slightly reversed by GA₃ at the concentrations used, whereas, GA₃ substantially relieved osmotic inhibition in dark-grown seeds.

The effects of GA₃ and gold light on development of catalase and invertase activities and on levels of free amino acids in germinating seeds of WB-2 were examined. Light depressed development of catalase and invertase activity. Levels of free amino acids increased more slowly in embryonic axes of light- than dark-incubated seeds, but in cotyledons higher levels of amino acids were maintained in light-grown seeds. GA₃ accelerated the development of catalase activity in whole embryos and invertase activity in embryonic axes, but did not significantly affect invertase activity in cotyledons during germination. GA₃ had little effect on amino acid pools in cotyledons and embryonic axes.

     

Inter-nucleosomal DNA fragmentation and loss of RNA integrity during seed ageing

The germination of viable seeds is the basis for new plant growth and development. Seeds lose viability during storage, but the biochemical mechanisms of seed death are not fully understood. This study aimed to investigate degradation patterns of nucleic acids during seed ageing and subsequent water uptake. Seeds of Pisum sativum L. were artificially aged at 50°C and 12% seed water content (WC). Nucleic acids degradation was studied during ageing and during imbibition of four seed lots with differential viability from highly viable to dead. As seeds lost viability during ageing, DNA was gradually degraded into internucleosomal fragments, resulting in ‘DNA laddering’, in conjunction with disintegration of 18S and 28S rRNA bands. During imbibition, non-aged controls had high levels of DNA and RNA integrity through to radicle protrusion. In an aged seed lot with 85% total germination (TG) DNA fragmentation decreased upon imbibition probably due to nucleosome degradation, while rRNA integrity did not improve. In an aged seed lot with 44% TG, neither DNA nor rRNA integrity improved upon imbibition. Dead seeds showed DNA degradation as laddering throughout imbibition along with extensive degradation of rRNA. We present a model in which interlinked programmed and non-programmed events contribute to seed ageing, and suggest that protection of nucleic acids during ageing is key to seed longevity.