Control of alpha-Amylase Development in Cotyledons during and following Germination of Mung Bean Seeds

Developmental patterns of α-amylase in Vigna radiata cotyledons during and following germination were quite different depending on the differences in the treatments of cotyledons during the imbibitional stage. When axis-detached cotyledons were imbibed in water with seed-coats attached, α-amylase activity did not increase and remained low. On the other hand, when the cotyledons were imbibed in water after seed-coat removal, the enzyme activity increased markedly. If the axis was attached to the cotyledons, α-amylase showed a marked development even under the former imbibition conditions. These changes in the enzyme activity were in parallel with those in the enzyme content, and the content, in turn, was dependent upon the availability of mRNA for α-amylase. We propose that the regulation of the development of α-amylase in cotyledons may involve some factor(s) inhibitory to accumulation of α-amylase mRNA, which is present in dry cotyledons and can be removed from cotyledons by leakage or by the presence of the axis.     

Presence in Dry Pea Cotyledons of Soluble Succinate Dehydrogenase That Is Assembled into the Mitochondrial Inner Membrane during Seed Imbibition

SUCCINATE DEHYDROGENASE (SUCCINATE: phenazine methosulfate oxidoreductase, EC 1.3.99.1) activity in crude mitochondrial fraction from pea (var. Alaska) cotyledons increased during seed imbibition to reach a maximum after about 12 hours. The increase was not inhibited by either cycloheximide or d(-)threo-chloramphenicol. The postmicrosomal fraction from dry cotyledons, but not that from fully imbibed ones, contained a soluble form of succinate dehydrogenase. The soluble enzyme was partially purified by ammonium sulfate fractionation and diethylaminoethyl-cellulose and Sepharose 6B column chromatography. The enzyme showed no succinate-coenzyme Q oxidoreductase activity and had a molecular mass of about 100,000 daltons. The soluble enzyme seemed to differ only slightly from succinate dehydrogenase solubilized from the mitochondrial inner membrane from fully imbibed cotyledons by a detergent. It is proposed that the soluble succinate dehydrogenase is associated with an inert mitochondrial inner membrane in dry cotyledons to form an active one during seed imbibition.     

Influence of the axis on the enzymes of protein and amide metabolism in the cotyledons of mung bean seedlings

The growth of the mung bean (Vigna radiata) seedling is accompanied by the biosynthesis and accumulation of the endopeptidase vicilin peptidohydrolase and the catabolism of the reserve proteins in the cotyledons. If the axis is removed from the dry seeds and the cotyledons incubated on moist sand the accumulation of vicilin peptidohydrolase is reduced by 77% and the catabolism of reserve proteins slowed to 25% of the rate in intact seedlings. The cotyledons and the cotyledon exudate are rich in asparagine and this amino acid accounts for more than half of the reduced nitrogen exported from the cotyledons. Glutamine synthetase and asparagine synthetase, two key enzymes in the pathway of asparagine synthesis, are under temporal control in the cotyledons. Their activities increase 3.5- and 10-fold, respectively, then decline again. These increases in enzyme activity occur to the same extent in excised cotyledons and are prevented when the cotyledons are incubated in 5 micromolar cycloheximide. The results indicate that the axis may control certain key metabolic events in the cotyledons, such as the synthesis of vicilin peptidohydrolase, while many other anabolic activities may not depend on a growing axis.     

The biosynthesis of ribonuclease and its accumulation in protein bodies in the cotyledons of mung bean seedlings

Germination and seedling growth of mung bean are accompanied by a 7- to 10-fold increase in the ribonuclease content of the cotyledons. The increase occurs during the first 4 days of seedling growth and precedes the senescence of the cotyledons. Separation of the RNases in the cotyledons by polyacrylamide gel electrophoresis indicates the presence of several minor bands in seeds imbibed for 24 hr. On the second day of seedling growth a new major band with an R_f of 0.76 is present. In 4- to 5-day old seedlings this major band accounts for nearly all the RNase activity in the tissue. The characteristics of this RNase show that it is a plant ribonuclease I (pH optimum of 5.0; MW 16,000; activity preferentially inhibited by purine nucleotides; no activity toward DNA; no phosphodiesterase activity). When the seedlings are grown in 66% D₂O the RNase activity undergoes a density shift of 0.61% indicating that the increase in enzyme activity is due to the de novo synthesis of the enzyme molecules. A method is described for the isolation of protein bodies from protoplasts of storage parenchyma cells. Fractionation of protoplast lysates on Ficoll gradients results in the recovery of a high proportion (75%) of intact protein bodies. On these gradients RNase activity comigrates with α-mannosidase, a protein body marker enzyme indicating that the newly synthesized RNase accumulates in the protein bodies. We suggest that the synthesis of RNase in the cotyledons and its accumulation in the protein bodies indicates that protein bodies may function in the degradation of cellular macromolecules other than the reserves stored within them.     

Characterization of the activity of fatty-acid epoxide hydrolase in seeds of castor bean (Ricinus communis L.)

Epoxide hydrolase (EC 3.3.2.3) activity was measured with [1-¹⁴C]cis-9,10-epoxystearic acid as the substrate. Homogenates were prepared from the endosperm tissue of germinating seeds of castor bean (Ricinus communis L. zanzibariensis). The activity of fatty-acid epoxide hydrolase was characterized with respect to dependence on time, amount of protein, pH and temperature. Analyses of enzyme distribution in endosperm, cotyledons, root and hypocotyl showed the highest total activity in the endosperm, less in the cotyledons and low activity in the root and hypocotyl. The specific activity was similar for cotyledons and endosperm. Analysis of the temporal expression of the enzyme in the endosperm during germination revealed high activity already in the imbibed seed. Activity was maximal between days four to six and then decreased at the end of one week. Subcellular fractionation of endosperm revealed a dual distribution of activity between the glyoxysomal and the cytosolic fractions.     

Biogenesis of Mitochondria in Imbibed Peanut Cotyledons: Influence of the Axis

Development of mitochondrial activities (state 3 respiration,respiratory control ratio, ADP/O ratio) in peanut cotyledonsoccurs over the first 5 d from the start of imbibition. Mitochondriain cotyledons with the axis attached develop better than inthose from which the axis has been removed. Initially, mitochondriaare deficient in cytochrome c, but after 2 d from the startof imbibition this deficiency is overcome. Mitochondrial developmentin attached cotyledons, as measured by state 3 respiration,respiratory control ratio, ADP/O ratio, and succinate dehydrogenaseand cytochrome oxidase activities, is severely impaired by cycloheximide.This indicates that de novo synthesis of proteins is necessaryfor mitochondria and their enzymes to develop, a situation whichis in sharp contrast to the situation in pea cotyledons. Electronmicroscope studies also show that there is an increase in thenumbers of mitochondria in peanut cotyledons with time afterthe start of imbibition. Two patterns of mitochondrial developmentexist in legumes: in imbibed peanut cotyledons respiratory activitiesincrease due to biogenesis of mitochondria, whereas in pea cotyledonsthe increases are due to improvement of pre-existing organelles     

Increased activity of aminopeptidase in the cotyledons of red light-promoted lettuce seeds is controlled by the axis

The first major reserves to be mobilized following germination of light-promoted lettuce seeds ( Lactuca saliva L. cv. Grand Rapids) are the carbohydrates, largely mannans, located within the cell walls of the endosperm. When these have been depleted, the cotyledonary reserves are hydrolysed; the first of these to decline is protein. Water-, salt- and ethanol-soluble proteins are mobilized simultaneously, and coincident with their loss from the cotyledons there is an increase in aminopeptidase activity. The level of enzyme activity increases appreciably in irradiated seeds after about 30 h from the start of imbibition. Essential for this increase, at least initially, is the presence of the axis - first to perceive the light stimulus, and then to produce and/or release a chemical promoter which diffuses into the cotyledons and effects the rise in enzyme activity. Protein synthesis in the cotyledons is a prerequisite for both development and maintenance of the increased aminopeptidase activity.     

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.     

The influence of the embryonic axis and cytokinins on reserve mobilization in germinating lupin seeds

The influence of the embryonic axis and cytokinins (CKs) onreserve mobilization has been examined in yellow lupin (Lupinusluteus L. cv. JSG 6167) seed during germination and during earlygrowth for up to 9 d in the dark. The study included determinationof starch, soluble sugars, proteins, and amino acid content.Amylolytic and proteolytic enzyme activity was also measuredin untreated cotyledons with intact embryo (attached) or detachedcotyledons (embryo removed), and in detached cotyledons followingtreatment with CKs namely, dihydrozeatin, (diH)Z, and 6-benzylaminopurine,BAP. Generally, the detached cotyledons showed reduced mobilizationand decreased enzymatic activity in comparison to attached cotyledons,indicating the importance of the embryonic axis in this process.However, a rise in protease activity and free amino acid contentwas detected in 9-d-old detached cotyledons suggesting thatthe end products do not necessarily inhibit enzyme activity.While (diH)Z was partially effective in inducing reserve mobilizationand enzymatic activity in detached cotyledons, the effect ofBAP was more pronounced and appeared to replace the embryonicaxis. The embryonic axis of this species has recently been shownto synthesize CKs which are transported to the cotyledons, arehighly stabe and induce cotyledon expansion and chlorophyllsynthesis. The results of the present investigation and previousstudies from this laboratory collectively indicate that theregulation of reserve mobilization in yellow lupin seeds appearsto be mediated, at least in part, by a stimulus, probably aCK, emanating from the embryonic axis. Key words: Lupinus luteus, cytokinins, benzylaminopurine, dihydrozeatin, embryonic axis, lupin seeds, reserve mobilization     

Studies on the Development of Mitochondria of Mung Bean Cotyledons During Imbibition

The development of mitochondria in the course, of imbibition ofmung bean cotyledons was studied. Mitochondria were prepared by differential centrifugation, and purified by discontinuous sucrose, density gradient centrifugation. Theelectron micrographs revealed that the mitochondria isolated from dry seeds cotyledonslook like small vesicles, when cotyledons were imbibed for two hours, the mitochondrial cristae were not observed, but after four hours, a few cristae appeared on the innermembrane. Till 12 hours, the inner membrane systems wore well-developed. Al this time.all the space in mitochondria are filled with cristae. With the structural integrity of the mitochondria, the functions of oxidation and phosphorylation were graduallyshown, For instance, ADP/O ratio and RCR were not able to be measured in the imbibition of 2 and 4 hours, but at 6th hours, ADP/O Was increased by 0.6, RCR nearly 2.0, After 24 hours imbibition, ADP/O and RCR were increased to 1.5 and 3.5 respectively. The activity of cytochrome oxidase reached the highest after imbibition for 3 hours (2.54 OD/mg protein/min). If cotyledons were imbibed continuously, the activityof this enzyme in mitochondria remained constant. The activity of ATPase located onthe inside of the mitochondrial inner membrane was gradually enhanced from the beginnning of imbibition. These results suggest that the assembly of cytochrome oxidaseand ATPase on mitochondrial membrane may not be synchronous.     

Characteristics and subcellular localization of phospholipase d and phosphatidic Acid phosphatase in mung bean cotyledons

Mixed micelles of ³²P-labeled phosphatidylcholine or phosphatidic acid (PA) and the nonionic detergent octylphenol polyethylene oxide (NP-40 Nonidet) were used to assay the activities of phospholipase D and PA phosphatase in crude extracts of mung bean (Vigna radiata) cotyledons. Together these enzymes degrade phosphatidylcholine to free choline, inorganic phosphate, and sn-1,2-diacylglycerol. Both enzymes have pH optima around 5.0. The enzymes are present in fully imbibed cotyledons and increase in activity during seedling growth. Fractionation of cotyledon extracts on sucrose gradients showed that the cells contain two PA phosphatases. One enzyme with a pH optimum of 7.5 has the same distribution on sucrose gradient as the endoplasmic reticulum marker enzyme NADH-cytochrome c reductase. The other, PA phosphatase, with a pH optimum of 5.0, was present in a protein body-rich fraction and in the load portion of the gradient. Fractionation of broken protoplasts on Ficoll gradients (a method which allows for the isolation of a high proportion of intact protein bodies) indicates that most of the cellular phospholipase D and PA phosphatase (pH 5.0) are associated with the protein bodies. Using column chromatography (DEAE-cellulose and Sephadex G-200), PA phosphatase (pH 5.0) was found to be a different enzyme from the major acid phosphatase in the cotyledons. Apparent molecular weights of phospholipase D and PA phosphatase were 150,000 and 37,000, respectively. The activity of phospholipase D was not affected by free choline, but was markedly inhibited by the choline analog and plant growth retardant isopropyl 4′-(trimethylammonium chloride-5′-methylphenyl piperidine-1-carboxylate (AMO 1618). The finding that these acid hydrolases are located in the protein bodies supports the conclusion that protein bodies form the general lytic compartment in the storage parenchyma cells.     

Changes in the Ribonuclease Activity of Flax Cotyledons following Inoculation with Flax Rust

There was a significant increase in the ribonuclease activity of both resistant (Bombay) and susceptible (Bison) varieties of flax (Linum usitatissimum L.) 3 to 4 days after inoculation with flax rust (Melampsora lini [Pers.] Lev., race No. 3). A second and much greater increase in the activity of this enzyme occurred only in the susceptible host at later stages of disease development. While a similar increase in ribonuclease level was also caused by mechanical injury, evidence is presented showing qualitative differences between the enzyme from parasitized tissue and that from the mechanically injured cotyledons. Comparison of the enzyme from healthy and inoculated cotyledons and from flax rust revealed the presence of a relatively unstable component and some unique catalytic properties in the enzyme from inoculated cotyledons.     

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     

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.     

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.     

Red-light- and gibberellic-acid-enhanced α-galactosidase activity in germinating lettuce seeds,cv. Grand Rapids

Dry lettuce (Lactuca sativa L.) seeds (achenes) contain -galactosidase (EC 3.2.122) at a level which is maintained in the imbibed dormant state in darkness. Both red light (R) and gibberellic acid promote an increase in enzyme activity several hours prior to the completion of germination. Germination and enzyme activity are not essentially linked, however, for the latter can increase while the former is inhibited. -Galactosidase activity increases within the cotyledons and the endosperm following R stimulation, but the axis is essential to perceive the stimulus and to promote and maintain the increase in enzyme activity. A diffusible factor (or factors) is produced by and-or released from irradiated axes, and it migrates to the cotyledons (and possibly endosperm) to promote the increase in -galactosidase activity. Gibberellic acid, particularly in the presence of benzyladenine, can replace the requirement for irradiated axes.Abbreviations GA₃ gibberellic acid - R red light     

Long-term storage of dormant Grand Rapids lettuce seeds in the imbibed state: physiological and metabolic changes

Grand Rapids lettuce (Lactuca sativa L.) seeds retained their viability for up to ten months when maintained in the fully imbibed state on moist filter paper at 25°C in darkness. The ability of red light (R) to promote their germination was essentially lost within one week from the start of imbibition; sensitivity to gibberellic acid was retained for two weeks longer. Seeds which did not respond to either treatment had entered the state of secondary dormancy (skotodormancy). This could be relieved at all times by a combination of benzyladenine and R applied to the intact seed, or by isolation of the embryo and incubation on water. Protein synthesis increased initially following imbibition but declined after 72 h to a constant low level. Respiration declined over the first week of storage in the imbibed state to a much-reduced steady level. Cotyledonary lipid declined between four and ten months of storage but the axial lipid remained unchanged. Sucrose in the embryo increased after five months, but no changes in glucose, galactose, fructose or mannose were found. The total N content of the cotyledons declined over the first three months of storage in the imbibed state, with a concomitant rise in axial N; the latter declined slowly thereafter. Basal α-galactosidase (EC 3.2.1.22) activity decreased over seven months, but the phytochrome-induced component could not be raised by a 15-min R treatment even after one month. Germination induced by R and benzyladenine was achieved at later times without a rise in α-galactosidase levels.     

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.     

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.     

Changes of Adenine Nucleotide in the Course of Mitochondrial Development of Mung Bean Cotyledon and Their Effect on Cellular Energy Status

The changes of adenine nucleotide and adenylate energy charge (AEC) during the development of mitochondria in imbibed mung bean cotyledons and the relationship between these changes and cellular energy status are studied. After cotyledons were imbibed in water for two hours, mitochondrial cristae were not observed, but for 12 hours, they appeared obviously on the inner membrane. With the structural integrity of the mitochondria, the functional mitochondria were graduately shown. For instance, the activity of H+-ATPase of cotyledons imbibed for 24 hours was about twice higher than that of 2 hours. The ATP content and the AEC value in the cotyledons imbibed for 24 hours increased sharply and the AMP decreased, but these were not observed in the mitochondria of the cotyledons imbibed either for 24 hours or 2 hours. When the cotyledons were imbibed in 1 × 10-4 mol/l or 5 × 10-4 mol/l DNP solution for 24 hours, the ATP and the AEC in the Cells exhibited a rapid decrease, but in the mitochondria they remained canstant. In the same DNP solution with cotyledons for 24 hours, the activity of mitochondrial adenylate kinase (AK) not only was not decreased but also increased by about 50% over the control. This result shows that the energy equilibration in the mitochondria seems likely to be regulated by adenylate kinase locating between inner and out membranes of the mitochondria.