Changes in Cell Fine Structure in the Cotyledons of Phaseolus vulgaris L. during Germination

When germination begins, the storage cells of Phaseolus vulgariscotyledons are packed with starch grains and protein bodies.Digestion of these reserves starts in cells furthest away fromthe vascular bundles and is practically completed in eight daysat 25° C. After the reserves are hydrolysed, the storagecells die. The changes in fine structure during the processof digestion and protoplasmic breakdown are described. Vascularbundle and epidermal cells survive till the cotyledons absciss,but in these tissues also profound changes occur in cellularorganization. The observations on fine structure are discussedwith reference to the metabolic activities of the cotyledons.     

Ultrastructural Observations on Proliferating Storage Cells of Mature Cotyledons of Phaseolus vulgaris L. Cultured in vitro

Explants of mature cotyledons of Phaseolus vulgaris form callusrapidly when cultured in vitro with their adaxial surfaces embeddedin a solidified nutrient medium containing coconut milk, kinetinand 2,4-D. Proliferation is confined to the highly polyploidstorage cells and commences near the adaxial epidermis, whichis soon ruptured by the callus developing internally. Callusformation progresses to the abaxial tissue and within 3–4weeks sub-culturing is possible. The in vitro grown storage cells undergo thinning of their walls,loss of food reserves, hypertrophy, development of various new-wallsand nuclear activation leading to division. The induction ofnuclear and cell divisions within this mature storage tissuecontrasts with normal germination in which these cells undergorapid senescence after depletion of their food reserves. Nuclear division in early callus growth is apparently mainlyamitotic. It is preceded by the development of multiple nucleoli.The nuclear envelope also becomes more complex and deeply lobed;leading to formation of a nuclear isthmus and final separationinto two nuclei. No chromosomes are visible during nuclear fragmentation.Amitosis is accompanied by freely-forming walls, which may developadjacent to a nuclear isthmus and perhaps participate in nuclearfragmentation. Large labyrinthine wall bodies frequently occuron these walls. Mitoses are only observed in already dividedstorage cells. A cell plate forms between the two daughter nuclei,and microtubules are present at its margins in contrast to freely-formingwalls where none are evident. Phaseolus vulgaris L., bean, in-vitro culture, cotyledon, ultrastructure     

Utilization of Seed Reserves and Currently Produced Photosynthates by Embryonic Tissues of Pine Seedlings

The importance of seed reserves for growth of Pinus resinosaAit. during and shortly after seed germination was studied undercontrolled conditions. Tissues in the resting embryo were notcompletely differentiated. Many small, presumably reserve particleswere present in the embryo in addition to reserves in the megagametophyte.During seed germination, procambia in the embryo first differentiatedprotophloem 2 days after seeds were sown. The radicle beganto emerge from the seed coat at 5 days, at which time initialxylem formation was observed. Also, at approximately the sametime, primordia of primary needles were forming in the peripheralzone of the apex. Elements of the photosynthetic apparatus,including stomata and mesophyll with chloroplasts, were differentiatedfirst in the hypocotyl and then in cotyledons between 5 and8 days after seeds were sown. Photosynthetic rates of youngseedlings were correlated with rates of cotyledon expansion.During early developmental stages, reserve particles in megagametophytecells and embryo cells gradually disappeared. Surgical removalof megagametophytes at various stages of seed germination resultedin subsequent growth inhibition of the hypocotyl-radicle axis,with early removal of cotyledons suppressing most growth. Growthof primary needles appeared to be influenced indirectly by megagametophytereserves, probably by changes in amount of photosynthetic tissue.The embryo alone possessed capacity to differentiate such tissuesas primary needle primordia, stomata, and primary and secondaryvascular systems. Megagametophyte reserves appeared to contributeto growth of embryonic tissues only after the embryo itselfinitiated growth. Both current photosynthesis of seedlings andseed reserves contributed importantly to seedling development.     

Ultrastructural and Biochemical Changes in Cotyledon Reserve Tissues3

Changes in major protein, lipid and carbohydrate reserves duringthe germination of Citrus limon (L.) Burm. f. seeds have beenstudied. The rate of release of amino acids and soluble sugarshas been evaluated. Mobilization of protein reserves began 4 d after the onset ofimbibition. The main period of hydrolysis occurred between 8d and 24 d after the start of germination. Ultrastructural studies showed the presence of protein bodiesin quiescent cotyledon cells. These bodies virtually disappeared14 d after the start of germination. The nitrogenous compoundsthat were liberated and subsequently translocated were predominantlyin the form of asparagine, arginine, and proline. The cotyledonshad a lipid content representing 51.7% of their dry weight.Lipid reserves in quiescent cotyledons were laid down in theform of oil-bodies. These organelles rapidly disappeared asgermination progressed, and were replaced by vacuoles. The starch content of quiescent cotyledons is very low, butit increased considerably up to 20 d after germination started. Key words: Proteins, lipids, carbohydrates     

Protein Synthesis During Rehydration, Germination and Seedling Growth of Naturally and Precociously Matured Soybean Seeds (Glycine max)

Soybean seeds [Glycine max (L.) Merr.] synthesize de novo andaccumulate several non-storage, soluble polypeptides duringnatural and precocious seed maturation. These polypeptides havepreviously been coined ‘maturation polypeptides’.The objective of this study was to determine the fate of maturationpolypeptides in naturally and precociously matured soybean seedsduring rehydration, germination, and seedling growth. Developingsoybean seeds harvested 35 d after flowering (mid-development)were precociously matured through controlled dehydration, whereasnaturally matured soybean seeds were harvested directly fromthe plant. Seeds were rehydrated with water for various timesbetween 5 and 120 h. Total soluble proteins and proteins radio-labelledin vivo were extracted from the cotyledons and embryonic axesof precociously and naturally matured and rehydrated seed tissuesand analyzed by one-dimensional PAGE and fluorography. The resultsindicated that three of the maturation polypeptides (21, 31and 128 kDa) that had accumulated in the maturing seeds (maturationpolypeptides) continued to be synthesized during early stagesof seed rehydration and germination (5–30 h after imbibition).However, the progression from seed germination into seedlinggrowth (between 30 and 72 h after imbibition) was marked bythe cessation of synthesis of the maturation polypeptides followedby the hydrolysis of storage polypeptides that had been synthesizedand accumulated during seed development. This implied a drasticredirection in seed metabolism for the precociously maturedseeds as these seeds, if not matured early, would have continuedto synthesize storage protein reserves. Glycine max (L.) Merr, soybean, cotyledons, maturation, germination/seedling growth     

Growth Analysis of Soybean Seedlings During the Lifespan of the Cotyledons

Patterns of seedling growth of Glycine max in light and darknesswere compared during the period from germination to cotyledonabscission. Fitted growth curves and the derived functions,relative growth rate, unit leaf rate, leaf area ratio and specificleaf area, were used to assess the relative importance in seedlinggrowth of cotyledon storage reserves, cotyledon photosynthesisand leaf photosynthesis. The cotyledons are of an intermediatetype with a predominant storage and a minimal photosyntheticfunction. Cotyledon reserves support seedling growth until theprimary leaves expand, after which growth depends on leaf photosynthesis. Glycine max (L.) Merr., soybean, cotyledons, growth analysis, seedling development     

Analysis of Lipids of Citrullus lanatus (cv. Sugar baby) During Seed Germination and Seedling Growth

Changes in the dry weight (dry wt.), total and neutral lipids,and fatty acid composition were determined in the cotyledonsand axis of Citrullus lanatus cv. Sugar baby seedlings duringtheir first 12 d growth in the dark, at 25 ? 1 ?C. The major stored reserves were mobilized between days 3 and8. The lipid concentration after day 4 decreased rapidly inthe cotyledons. On the first day the lipid concentration inthe axis was higher than in the cotyledons but decreased rapidlyand from day 5 up to the end of the experiments it remainedat very low values. In the cotyledons, the change in the fattyacid composition was relatively small compared to the significantchange observed in the axis. The neutral lipids of the cotyledonsdecreased sharply between days 2 and 6 while their fatty acidcomposition suffered no significant change. The axis, comparedto the cotyledons, contained a small but concentrated amountof neutral lipids, which decreased up to day 6. Thereafter,an increase was observed. The fatty acid composition of theaxis neutral lipids changed significantly, linoleic and oleicacid decreased while palmitic and linolenic acid increased. Key words: Citrullus lanatus, seed germination, seedling growth, lipids, fatty acids     

Histochemical studies on mobilization of storage components in cotyledons of germinatingPhaseolus mungo seeds

Phaseolus mungo seeds were allowed to germinate in the dark at 27 C, and time-sequence changes of mobilization of protein and starch reserves in cotyledons were observed by histochemical techniques. The distributions of amylase and protease activities in cotyledon sections were also examined during germination by use of the starch-polyacrylamide gel film and India ink-gelatin film methods, respectively. Amylolytic and proteolytic processes occurred more or less simultaneously during the germination. At the day 2 stage, low levels of hydrolytic enzyme activities were observed throughout cotyledon sections. At day 4, both amylase and protease activities appeared to increase in tissue areas farthest from vascular bundles, and the mobilization of starch and protein reserves also proceeded in these areas. At day 6, the reserves were found to remain only in the cells around vascular bundles. When cotyledons were detached from axis organs, allowed to imbibe water and incubated for 4 days at 27 C, the breakdown of reserves was markedly retarded and the patterns of enzyme localization in cotyledon sections appeared not as conspicuous as those in the sections from intact cotyledons. These histochemical results are discussed with reference to the previous results ofin vitro experiments.     

Influence of Axis Removal on Amino-, Carboxy- and Endopeptidase Activities in Cotyledons of Germinating Vigna mungo Seeds

Endopeptidase (azocaseolytic enzyme) and carboxypeptidase activitiesin cotyledons of germinating Vigna mungo seeds increased until3 days after the onset of imbibition and decreased thereafter.In detached and incubated cotyledons, the endopeptidase activityincreased only a little while the carboxypeptidase activitycontinued increasing even after 3 days of incubation. The activitiesof leucine-aminopeptidase and alanine-aminopeptidase, exceptfor that of one leucine-aminopeptidase isoenzyme relativelyabundantly present in unimbibed dry cotyledons, increased slightlyon the first day and declined during germination. In detachedcotyledons, the activities maintained their initial levels throughoutthe incubation period. When cotyledons were detached from germinatingseedlings on days 2 and 4 then incubated, the endopeptidaseactivity started to decrease just after removal of the axisbut the carboxypeptidase activity increased more markedly thanwhen the axis remained attached. Exogenously supplied GA₃, kinetin,IAA, or their combinations, showed no significant effect onthe developmental patterns of the endopeptidase and carboxypeptidaseactivities in cotyledons. These results are discussed in relationto the role of the axis in controlling peptidase formation incotyledons of germinating V. mungo seeds. (Received November 18, 1983; Accepted February 28, 1984)     

Evidence for the involvement of cytokinins in the regulation of proteolytic activity in cotyledons of germinating beans

The proteolytic activity of an extract of cotyledons of Phaseolusvulgaris increased during the first 7 days of germination, bothwhen casein was the substrate and when the endogenous proteinserved as such. The increase was partially dependent on thepresence of the embryo axis. The effect of the axis was replaceableby kinetin or zeatin, but not by gibberellic acid or IAA. During the period of 3–6 days after the beginning of incubation,the level of amino acids in cotyledons attached to the embryoaxis was lower than in detached ones. No such difference couldbe detected in the first 2 days of incubation. On the otherhand, the influence of the axis on protease activity alreadywas clearly detectable on the second day of germination. Applicationof casein hydrolysate to the seeds brought about an increasein the concentration of amino acids in the cotyledons, but nosimultaneous decrease in the protease level could be detected.We concluded that these results do not confirm the hypothesisthat the influence of the axis on proteolytic activity is dueto its function as a sink for amino acids produced in the cotyledons. (Received August 9, 1979; )     

Effect of growth temperature on reserve mobilization and hydrolytic enzyme activities in Vigna mungo cotyledons

Seeds of Vigna mungo were allowed to germinate at 27, 18 and15°C, and time-course changes of hydrolytic enzyme activitiesand the mobilization rate of reserve components in cotyledonswere studied. The seeds germinated at 27 and 18°C grew normally,whereas the growth at 15°C was markedly retarded. In cotyledonsof seedlings grown at 27 and 18°C, amylolytic and proteolyticenzyme activities increased at early stages of growth and therates of starch and protein mobilization changed correspondingto the hydrolytic enzyme activities. At 15°C the enzymeactivities increased gradually during the experimental periodof 16 days, but the reserves in cotyledons remained almost unchangeduntil the end of the experimental period. Changes of zymogram patterns of amylolytic and proteolytic activitiesin cotyledons of seedlings grownat 27, 18 and 15°C wereexamined using polyacrylamide gel electrophoresis. The intensitiesof a main band of a-amylase and at least two bands of protease(gelatin-hydrolyzing activity) increased concurrently with invitro activities of amylolytic and proteolytic enzymes. At leastthree bands of starch phosphorylase were present in cotyledonsat early stages of germination and their intensities decreasedduring the growth of seedlings at 27, 18 and 15°C. (Received June 4, 1980; )     

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     

Some Effects of Potassium Deficiency on Seedling Development

Seedlings with leaf-like photosynthetic cotyledons such as Cucumissativus, Sinapis alba and Trifolium pratense have higher growthrates and a greater requirement for an external supply of potassiumthan hypogeal species (Pisum sativum, Vicia faba) or epigealspecies with very fleshy cotyledons (Phaseolus vulgaris, Lupinusalbus, Lupinus angustifolius). The initial stages of seedlingdevelopment in the latter two groups involve mainly transferof reserves from cotyledons to axis and a relatively small increasein total seedling dry weight takes place during the first 2to 3 weeks. Potassium may be drawn either from the supply already presentin the cotyledons or from an external source. Species with expandingphotosynthetic cotyledons utilize the reserve potassium duringcotyledon development and it is not transported to the epicotyl.Thus, in these species an external supply of potassium is essentialfor full development of the photosynthetic system and the roots.In species whose cotyledons are not major photosynthetic organsthe reserve potassium is transported from the cotyledons tothe developing axis. In these species culture in a nutrientsolution deficient in potassium or in distilled water increasesroot dry weight but reduces plumule weight (although to a lesserextent than in species with leaf-like cotyledons). In general,the response of seedlings to culture in a nutrient solutiondeficient in potassium was very similar to culture in distilledwater only. Thus, although all the species studied had similar levels ofpotassium in the seed (µg potassium/mg dry weight) itssite of utilization differs. It appears that seedlings withleaf-like cotyledons are more susceptible during early seedlinggrowth to deficiencies in external factors, such as potassium,than are species with fleshy cotyledons.     

Mobilisation of the major stored reserves in the embryo of fenugreek (Trigonella foenum-graecum L., Leguminosae), and correlated enzyme activities

Changes in total nitrogen, soluble amino nitrogen, lipid and phytate contents, and in the activities of proteinase (pH 7.0), isocitrate lyase and phytase were followed in the endosperm, cotyledons, and axis during germination of fenugreek seeds and subsequent growth of the seedlings. The endosperm is comprised largely of cell-wall galactomannans: the majority of the seed total nitrogen, lipid and phytate (5%, 8%, 0.44% of seed dry weight respectively) is localised within the cotyledons as stored reserves. Germination is completed after 10–14 h from the start of imbibition, but the major reserves are not mobilised during the first 24 h. Then the total nitrogen content of the cotyledons starts to decrease and that of the axis increases; there is a concomitant accumulation of soluble amino nitrogen in both cotyledons and axis. An increase in proteinase activity in the cotyledons correlates well with the depletion of total nitrogen therein. Depletion of lipid and phytate reserves in the different seed tissues constitutes a late event, occurring after 50 h from the start of imbibition, and is coincident with the final disintegration of the endosperm tissue. The depletion of phytate and stored lipids is accompanied by an increase in phytase and isocitrate lyase activity. It appears that the products of lipid hydrolysis are converted by gluconeogenesis to serve as the major source of sugars for the growing axis after the endosperm galactomannan has been completely mobilised.     

Cell Cycle Activation During Imbibition and Visible Germination in Embryos and Megagametophytes of Jack Pine (Pinus banksiana Lamb.)

Flow cytometric determination of cell cycle activation duringimbibition and visible germination in five families of jackpine (Pinus banksiana Lamb.) embryos and megagametophytes revealedthat in seeds that had undergone no imbibition the majorityof cells were in the 2C state. As the imbibition period increased,less of the nuclei were blocked in the G0/G1 state and morebecome active in the cell cycle. The augmentation in the nucleiactive in the 2C–4C cycle as well as those with DNA levelshigher than the 4C state occured gradually and preceeded radicleemergence. In megagametophyte tissue examined at various stagesof imbibition, cell cycle activity became apparent rapidly followingimbibition. In nuclei of green and white embryos examined separatelythe ²frequency distributions were significantly different forall three families after 144h. As imbibition period increased,fewer nuclei from the green embryos were blocked in the 2C state,and more became active in the 2C–4C cell cycle. This wasnot the case for white embryos where no significant linear relationwas noted. Cell cycle activity in the hypocotyl+cotyledons regionand the emerging radicle were examined separately. Functionalrelations found in the hypocotyl+cotyledons region were notevident in the radicle. As visible germination proceeded, cellcycle activity in the hypocotyl + cotyledons region for thisperiod of germination showed a reversal of the activity notedduring imbibition: fewer nuclei were active and once again ahigher proportion were found in the 2C state. cell cycle; C levels; DNA content; flow cytometry; germination; imbibition; jack pine; megagametophyte; Pinus banksiana Lamb     

Changes in Nuclear DNA Content, Cell and Nuclear Size, and Frequency of Cell Division in the Cotyledons of Brassica napus L. during Embryogenesis

Cellular behaviour was examined during embryogenesis in Brassicanapus to test whether or not polyploidy occurs in the cotyledonsduring the phase of oil deposition. Nuclear DNA content, nuclearand cell size, and the mitotic index were measured in the cotyledonson various days post anthesis (dpa). In squashed monolayersfrom 15 dpa cotyledons, a polyploid (>5C) population wasdetected together with a substantial number of cells in G2 (4C).Nuclear volume was measured on sectioned tissues and, at 15dpa, the range of values from the cotyledons (40–500 *m³)contrasted with that in the vestigial suspensor and endosperm(50–> 600 µm³). At 15 dpa the nuclear volumedata suggest that whilst cells in the cotyledons were in Gland G2 many endosperm and suspensor cells were polyploid. Thus,polyploidy observed in the squashed monolayers was probablydue to contaminating endosperm/suspensor cells. At 25 and 35dpa, polyploidy was not detected; all cells were in Gl (2C)and cell area increased. The mitotic index peaked at 20 dpabefore declining and given the narrower distribution of nuclearvolumes at 25 and 35 dpa (50–300 µm³), these dataare consistent with cell arrest in Gl. Thus, polyploidy wasnot detected in the cotyledons of B. napus which differs fromwhat is known about cellular development in legume cotyledons. Key words: Brassica napus L., DNA, nuclear volume     

Importance of Endosperm for Nutrition of Fraxinus pennsylvanica Seedlings

Contact between endosperm and cotyledons of germinating Fraxinuspennsylvanica Marsh. seedlings was not essential for continuationof seedling growth or adaptation of cotyledons for photosynthesis.However, when cotyledons were in contact with endosperm, thecotyledons had faster rates of elongation and dry weight increase,slower depletion of reserves, and higher chlorophyll contents.Photosynthetic contributions by cotyledons may be enhanced ifenviron mental conditions support rapid emergence of cotyledonsfrom surrounding seed structures.     

Seed Dormancy in Acer: The Role of Testa-imposed and Embryo Dormancy in Acer velutinum

The embryo dormancy shown in freshly harvested samples of Acervelutinum seeds is weakly established and very short-lived.Loss of this embryo dormancy occurred during post-harvest fruitstorage at either 5 or 17 C. In contrast, the dormancy of intactfruits and seeds was overcome only during storage at the lowertemperature. Removal of the cotyledons from embryos of freshlyharvested fruits allowed more rapid germination of the embryonicaxes, indicating that the cotyledons exert an inhibitory effect,although the axes still retained a measure of innate dormancy.The inhibitory effect of the cotyledons became less marked withincreasing duration of fruit storage, this loss of inhibitoryeffect occurring at both storage temperatures. Applied ABA stronglysuppressed germinative capacity in intact embryos and isolatedembryonic axes from freshly harvested fruits, but when ABA wasapplied to embryos of fruits that had been stored for variousperiods at 5 or 17 C, the inhibitory effect was first weakenedand then lost with increased storage. Although dormancy in the seeds of A. velutinum may be describedas intermediate between testa-imposed dormancy and true dormancy,it is perhaps more properly included in the former category. Acer velutinum Boiss. var. vanvolxemii, abscisic acid, embryo dormancy, germination, seed storage, testa-imposed dormancy, tissue sensitivity     

The recalcitrant plant species, Castanospermum australe and Trichilia dregeana, differ in their ability to produce dehydrin-related polypeptides during seed maturation and in response to ABA or water-deficit-related stresses

In constrast to seeds of orthodox species, those of recalcitrantspecies do not acquire desiccation tolerance during their developmentand are shed from the parent plant at high water contents. Dehydrinproduction in seeds of recalcitrant species was examined duringdevelopment and germination, in response to abscisic acid (ABA),and following the imposition of various water-deficit-relatedstresses, including desiccation, water stress, high salt, highosmolarity, and low temperature. Two tropical species exhibiteda differential capacity to produce dehydrin-related proteinsduring seed maturation. Dehydrins were present in axes and cotyledonsof Castanospermum australe seeds during mid-maturation and atmaturity. In Trichilia dregeana, no dehydrin-related polypeptideswere detected in the mature seed. During the development ofC. australe seeds, the nature of the dehydrin related polypeptidesaccumulated in the cotyledons and axis changed and new polypeptideswere detected in the mature seeds that were not present duringmid-maturation. The dehydrins present in cotyledons of matureseeds (31, 37 and 40 kDa) were still detectable after germination(i.e. in untreated seedlings). These dehydrins became less abundantin the cotyledons of C. australe seedlings following ABA andall stress treatments except cold, although most of the dehydrinswere still detectable. An exception was the desiccation-treatedseedlings, in which no dehydrins were detected. In the rootsof C. australe seedlings, no dehydrins were found after germinationnor were they induced in the root by ABA or any of the stresstreatments imposed on seedlings. Seedlings of Trichilia dregeanadid not produce dehydrins in the roots or cotyledons when exposedto ABA or water-deficit-related stresses. Key words: Dehydrin, ABA, desiccation, recalcitrant, seed