Transport of Materials from the Cotyledons during Germination of Seeds of the Garden Pea (Pisum sativum L.)

After the first week of germination the relationship betweenthe amounts of total dry matter, nitrogen, phosphorus, sulphur,and potassium transferred to the axis from the cotyledons inthe intact plant remained approximately constant irrespectiveof the conditions of growth. It is proposed that the ratio inwhich the individual elements are transported is determinedby the proportions in which they are released by the storagecells. Deviation from this ratio during the first week of germination,and over a longer period in deshooted plants is attributed tocompetition for the available nutrients between actively metabolizingcells in the cotyledons and axis. It is demonstrated by steam-girdling that movement of materialsfrom the cotyledons into the shoot probably occurs via the phloem.Calcium is mobile in the phloem during the early stages of germination,possibly because the amount of free calcium in the cotyledonsis high.     

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.     

Amino Acids Content in Germinating Seeds and Seedlings from Castanea sativa L

During germination the chestnut (Castanea sativa L.) var ecotype 33 accumulates a large amount of asparagine in the cotyledons. This compound also accumulates in the growing axis:shoots and roots. In the cotyledons, γ-aminobutyrate (GABA) represents a major amino compound during germination and early seedling growth. In young seedlings, 35 days old, arginine predominates over the other soluble amino acids, particularly in roots. Five enzymic activities involved in arginine and GABA have been measured in the storage organ of the seed: arginase and ornithine carbamyltransferase decrease during germination indicating the slowing down of the urea cycle. In contrast, ornithine aminotransferase increases. Glutamate decarboxylase is particularly active about 21 days after imbibition and GABA aminotransferase activity decreases during germination. These two activities are in good agreement with the likely transport of GABA from cotyledons to growing axis. Asparagine, arginine, and GABA are the three amino compounds obviously involved in the mobilization of nitrogen reserves in the germinating chestnut seeds Castanea sativa.     

Control of Protein Hydrolysis in the Cotyledons of Germinating Pea (Pisum sativum L.) Seeds

The effects of removal of the shoot or whole axis on the levelsof total, protein, and TCA-soluble nitrogen and on proteaseactivity in cotyledons during germination of garden pea (Pisumsativum L ) seedlings grown in the light have been examined. Removal of the shoot 1 week after soaking the seed caused areduction in the rates of protein hydrolysis and of nitrogentransport from the cotyledons and an increase in the level ofsoluble nitrogen When the entire axis was excised after 4 or9 days there was a great reduction in protein hydrolysis whilethe level of soluble nitrogen remained the same as in de-shootedplants. In the intact plant, proteolytic activity of cotyledon extractsrose to a peak about 15 days after soaking of the seed and thenfell rapidly This fall coincided with a decrease in water contentand in oxygen consumption by the cotyledons. Removal of theshoot or entire axis led to a much smaller and more gradualincrease in protease activity and the subsequent decline inactivity of the enzyme and senescence of the cotyledons werealso delayed. It is concluded that control of protein hydrolysis in pea cotyledonsis not mediated through the level of protease enzymes, as indicatedby the proteolytic activity of tissue extracts, or by the amountof soluble nitrogen compounds accumulated. Protease activityseems to be controlled by the shoot and to be closely linkedto senescence of the cotyledons Protein hydrolysis and transportof nitrogen to the axis, on the other hand, are affected bythe presence of both shoot and root and the axis appears toexert independent control on each of these processes.     

STUDIES ON THE SOLUBLE CARBOHYDRATES AND CARBOHYDRATE PRECURSORS IN GERMINATING SOYBEAN SEED

The total soluble carbohydrate fraction of the cotyledons and embryo axis of germinating soybean seedlings declined rapidly during the first 3 days of germination. This depletion began earlier in the embryo axis than in the cotyledon. The total carbohydrate content of the cotyledons of plants grown in light and plants grown in dark was approximately the same for the first 7 days of germination. Between day 9 and 13 the total carbohydrate content of the cotyledons of soybean seedlings grown in dark was higher than that of plants grown in light. The reducing sugar content of light-grown soybean cotyledons increased approximately 5-fold during the first 9 days of germination, whereas that of dark-grown soybean cotyledons increased more slowly during this interval. Reducing sugars in the embryo increased during the early stages of germination until they approximately equalled the total carbohydrate. Between day 4 and 13, oil was depleted more rapidly in the cotyledons of seedlings grown in light than those grown in the dark. The reserve carbohydrates of soybean embryos and cotyledons consisted primarily of low molecular weight oligosaccharides, particularly sucrose, stachyose, and raffinose. These compounds decreased rapidly during germination. The isocitritase activity in the cotyledons of germinating soybean seeds increased rapidly for the first 6 days of germination and then decreased for the next 7 days. The isocitritase activity of plants grown in the dark was higher than that of the plants grown in light at all stages of development, particularly between day 7 and 11.     

Distribution and Isoenzymes of Aspartate Aminotrans-f erase in Cotyledons of Germinating Pumpkins

During germination a steady decline in the reserve protein occurred in dark grown pumpkin cotyledons. By 9 days, 80% of this nitrogen reserve was hydrolyzed but only 50 % was removed from the cotyledons. The remaining nitrogen (30 %) was incorporated into water soluble protein which reached a maximum 9 days after germination. The increase in water soluble protein in pumpkin cotyledons parallel the increase in soluble and particulate aspartate aminotransferase (E.C.2.6.1.1.), suggesting that this enzyme is involved in nitrogen metabolism during germination. Little enzyme activity was found in pumpkin tissues other than the cotyledons. Four anodally moving isoenzymes were found in the soluble aspartate aminotrans-ferase fraction and 3 anodally moving isoenzymes were found in the particulate fraction. The slowest moving isoenzymes disappeared first during germination.     

Developmental biochemistry of cotton seed embryogenesis and germination: x. Nitrogen flow from arginine to asparagine in germination

The enzymic basis for the flow of nitrogen from arginine to asparagine during the first 3 days of germination has been measured in extracts from cotton (Gossypium hirsutum) cotyledons. Evidence that asparagine synthetase regulates asparagine accumulation in germination (for transport to the axis) is presented. Further, evidence that the bulk of the nitrogen passed from one generation to the next in dicots is through an asparagine cycle involving the following sequence asparagine → arginine → storage protein → arginine → asparagine is discussed.     

The Influence of Axis Removal on Protein Metabolism in Cotyledons of Pisum sativum L

The protein metabolism of cotyledons attached to the embryonic axis has been compared with that in cotyledons removed from the axis at the initiation of a 6-day imbibition. Total protein declined in the attached but not in the detached cotyledons. Concurrent with the decline in protein level in the intact cotyledons there was an increased capacity to incorporate exogenously supplied leucine into protein. In contrast, detached cotyledons showed a restricted capacity for protein synthesis. It was demonstrated that ribosomal preparations from cotyledons of intact seedlings contained an increasing proportion of polyribosomes as germination progressed and such ribosomes were active in in vitro amino acid incorporation. Ribosomal preparations from detached cotyledons contained few polyribosomes and had a restricted capacity to incorporate amino acids in vitro. The in vitro incorporation of phenylalanine was stimulated by polyuridylic acid with the stimulation being greatest in ribosomal preparations from detached cotyledons. The results suggest that an axis component may regulate the availability of messenger RNA in the cotyledons during germination.     

THE EFFECT OF LIGHT ON THE USE OF THE NITROGEN RESERVES OF GERMINATING SOYBEAN SEEDS

Light affects the mobilization and distribution of several of the storage components of the cotyledons of germinating soybean seeds. The nitrogen content of the cotyledons began to decrease during the first day of germination, continued through day 12 for plants in the light, and day 14 for those in the dark. Cotyledons from both treatments had lost about the same amount of nitrogen by day 14. Plants from both treatments lost about the same amount of dry weight by day 8, but those in the light had taken up nitrogen from the nutrient solution; while those in the dark showed no increase. The plants in the light had higher concentrations of soluble amino nitrogen in the cotyledons than did those in the dark, but the opposite was true for the seedling axis. Aspartate and its amide accounted for half or more of the total free amino acids in all parts of dark-grown plants at 6 and 14 days. In the light-grown plants aspartate and asparagine usually accounted for less than half of the total free amino acids in all plant parts except the cotyledons at 6 and 14 days. Total soluble amino acids were much lower in these plants than those in the dark, excepting the cotyledons.     

胚轴对萌发豌豆子叶中淀粉酶活性表达的影响

萌发豌豆的上、下肢轴均能诱导子叶中淀粉酶活性,外源GA和6—BA具有类似胚轴的作用。离体子叶的淀粉酶凝胶电泳只有一条活性极低的酶带,连生子叶中有两条酶带,其中由胚轴诱导新出现了一条活性很高的同工酶带,它的活性受亚胺环己酮的强烈抑制,而受放线菌素D影响不大。推测豌豆子叶中存在淀粉酶的长寿命mRN—A,胚轴和外源激素的作用在于促进mRNA的翻译。     

Contribution of the Pentose Phosphate Pathway and Glycolytic Pathway to Dormancy Breakage and Germination of Peanut (Arachis hypogaea L.) Seeds

Levels of glucose-6-phosphate dehydrogenase (D-glucose-6-phosphate: NADPH oxidoreductase, E.C. 1.1.1.49 [EC] ) 6-phosphogluconate dehydrogenase(6-phospho-D-gluconate : NADP⁺ oxidoreduc tase, E.C. 1.1.1.44 [EC] )and aldolase (fructose 1, 6-diphosphate, D-glyceraldehyde, 3-phosphatelyase, E.C. 4.1.2.13 [EC] ) were assayed in the seeds of geneticallydormant and non-dormant pure lines of groundnut. In dormantlines cotyledons showed increased levels of activity of G-6-PDHand 6-PGDH during dry storage after-ripening. While the embryonicaxis did not exhibit detectable levels of enzyme activitiesimmediately after harvest, the activity started after a lapseof time during dry storage. When seeds of dormant lines wereincubated with kinetin (6-furfurylaminopurine) a distinct increasein the levels of both the enzymes was observed. The levels ofaldolase activity gradually decreased in the cotyledons andincreased in the embryonic axis of both control and kinetintreated seeds during the period of after-ripening. Comparedto control, kinetin treatment increased the aldolase activityin the embryonic axis and decreased it in the cotyledons. In non-dormant lines the activity of both the enzymes of PPpathway increased sharply both in the cotyledons and embryonicaxis while aldolase activity decreased in the cotyledons andincreased in the embryonic axis during germination i.e., from24 h to 96 h of germination. Abscisic acid caused inhibitionof enzyme activities to a large extent. Key words: PP pathway, dormancy breakage, germination, peanut     

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; )     

Hormonal control of proteinase activity in squash cotyledons

A crude proteolytic enzyme preparation which hydrolyzes casein was isolated from the cotyledons of squash seedlings. The presence of ethylene diamine tetraacetate or cysteine did not appreciably affect the activity of the preparation. During the course of germination, the level of proteolytic activity increased in the cotyledons of intact embryos through the third day and then decreased. The presence of the embryonic axis during the first 32 hours of germination was a prerequisite for the development of maximum proteolytic activity.     

Differential effects of the embryonic axis on chlorophyll production and photosynthesis of mustard cotyledons

Summary Mustard cotyledons detached from the dry seed or at intervals during five days dark germination produced consistently more chlorophyll but a lower photosynthetic rate when maintained in the dark on moist filter paper for 24 hr before exposure to light than cotyledons which were attached to the seedling axis during this time.The results suggest that the embryonic axis exerts a differential effect on the developing photosynthetic system, competing for material involved in chlorophyll formation and at the same time stimulating the development of other photosynthetic components.     

Embryonic control of isocitrate lyase activity in cotyledons of germinating soybean

The activity of isocitrate lyase (EC 4.1.3.1) in the cotyledons of germinating soybean is controlled by the embryonic axis. Plant growth regulators like gibberellic acid, indole acetic acid and 2,4-dichlorophenoxy acetic acid are able to increase the enzyme activity in cotyledons of whole seedlings but not in dissected cotyledons. The control of induction of the enzyme activity during germination by the embryo could be mediated by the elaboration of kinetin.     

Physiological significance of indoleacetic acid and factors determining its level in cotyledons of Lupinus albus during germination and growth

The results demonstrate the profile of the endogenous indole-3-acetic acid (IAA) in the cotyledons of Lupinus albus L. ( L. termis Forssk.) during germination and seedling growth. The auxin level increases markedly after seed hydration, especially during the time of radicle emergence 24 h after the onset of imbibition. This rise is accompanied by a minimal IAA-oxidase activity, formation of indoleacetylaspartic acid (IAAsp) and an increase in the endogenous tryptophan and tryptophan-carboxyl-¹⁴C degradation, though the latter cannot account for the high IAA level detected during early stages of germination. It is believed that cotyledons are a source of IAA to the developing embryonic axis. – The auxin level drops in the cotyledons during seedling growth, 2–18 days after sowing. This is true also for IAAsp and tryptophan-degrading activity of enzyme extracts. Conversely, endogenous tryptophan is increasingly liberated up to day 14, and IAA-oxidase activity climbs to a peak detected on day 12, prior to the appearance of senescence in the cotyledons. – The physiological significance of IAA and the factors regulating its level in the cotyledons during germination and growth are discussed.     

Amylase Activities in Attached and Excised Cotyledons and in Embryonic Axes of Pisum sativum L.

Amylase activity increased in attached cotyledons of peas, Pisumsativum L. var. Bördi, only during imbibition and remainedalmost constant up to 96 h after germination, but in excisedcotyledons the activity increased slightly at first then markedly.In contrast, the content of the reducing sugars was higher inattached cotyledons than in excised ones. A similar inverserelationship has been found between the concentration of reducingsugars in axes (both attached and excised) and amylase activity. The leakage from intact seeds contained more reducing sugarsthan the leakage from excised cotyledons, whereas the amountof proteins released from the cotyledons was four times greaterduring imbibition. This increase in amylase activity in excisedcotyledons is not thought to be the result of axis excision,but to be the result of the leakage of sugars from the cotyledonsduring incubation. These results suggest that the concentration of reducing sugarsmay be a factor that regulates amylase activity in vivo in boththe cotyledons and axis during the germination of pea seeds. (Received August 4, 1982; Accepted December 14, 1982)     

Dipeptidase development in cotyledons of Cucurbita maxima during germination

The dipeptidase activity of an unpurified soluble extract of the cotyledons of Cucurbita maxima Duch. var. Hubbard remained unchanged during the first 2 days of germination and then increased at a rapid rate during the next 3 days. The dipeptidase activity of two of three lots of seeds required the presence of the embryo axis for maximal dipeptidase activity, whereas the third lot was uninfluenced by the embryo axis. This discrepancy was possibly due to genetic differences. In those seeds which required the presence of the embryo axis for maximal dipeptidase activity, the cytokinin benzyladenine could replace the embryonic axis. When the protein synthesis inhibitor cycloheximide was added to the seeds at the beginning of germination, it inhibited dipeptidase activity of the cotyledons from 26 to 55 per cent, depending of the basis of calculation, at 5 days. When the cycloheximide was added to 3-day-old seedling the inhibition of dipeptidase activity in the cotyledons was almost immediate. The relative hydrolysis of -leucylglycine and glycylglycine were compared after temperature inactivation and purification; the results showed that more than one enzyme was responsible for the dipeptidase activity. The presence of a dialysable dipeptidase inhibitor(s) was demonstrated. Relatively high dipeptidase activity was also found in the roots and shoots.     

Interconversion and translocation of free sugars during galactomannan utilization in germinating guar (Cyamopsis tetragonoloba) seed

With the onset of the degradation of galactomannan, the galactose and mannose levels increased in the endosperm. The hydrolysis of galactomannan was more or less complete within the first 3 days of germination. In the cotyledons, sucrose was the predominant free sugar during the period of rapid galactomannan hydrolysis and reducing sugars (glucose + fructose) were present in only 10–20% proportion. The level of soluble acid invertase activity was in the order of embryonic axis > endosperm > cotyledons. On the basis of (a) absence of galactose and mannose, (b) high proportion of sucrose, (c) very fast conversion of [¹⁴C]glucose and [¹⁴C]mannose to [¹⁴C]sucrose and (d) very low levels of both soluble and bound invertases in cotyledons, we conclude that there is an active synthesis of sucrose in this tissue where disaccharide seems to be least hydrolysed during the period of galactomannan mobilization. A rapid hydrolysis of galactomannan in endosperm during early germination resulted in the synthesis of some starch, as a temporary reserve, in cotyledons. When the cotyledons entered the phase of first leaf formation, cotyledonary sucrose was hydrolysed giving rise to invert sugars. In the embryonic axis, the increase in the ratio of reducing sugars to sucrose coupled with a higher level of invertase, compared with sucrose-UDP glucosyl transferase, indicated that free sugars from the cotyledons are translocated to the embryonic axis as sucrose.     

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.