Glutamine synthetase isozymes in germinating barley seeds

Glutamine synthetase (GS; EC 6.3.1.2) is a key enzyme of ammonia assimilation in higher plants. In the present study the subunit composition and localization of GS in germinating barley ( Hordeum vulgare ) seed have been clarified. Analysis of the GS polypeptide composition by immunoblotting revealed two different polypeptides. A and B, with a molecular mass of 42 and 40 kDa, respectively. In the scutellum subunit A was already present in the ungerminated seed and remained unchanged, whereas subunit B appeared on day 2 and increased about 5-fold during germination. Polypeptide B also appeared later during germination in the aleurone layer, roots and weakly in the etiolated shoots. By immunogold microscopy, GS was detected in the scutellum and the aleurone layer of barley seeds during germination. Subcellular localization of GS on ultrathin cryosections showed that a cytosolic isozyme was present in the scutellum. Our study confirms that only a cytosolic GS is expressed in barley seed, and its subunit composition changes during germination.     

Possible effect of gibberellin on phytate degradation in germinating barley seeds

Changes in the contents of phytate (IP₆) and other phosphorus(P)-compoundsin germinating seeds of a huskless barley were investigatedin the embryo with scutellum (EM), the starchy endosperm (EN),and the aleurone layer with pericarp-testa (AL). More than 80%of the total P in the AL of 1-day germinated seeds was foundin acid-soluble organic P, most of which was IP₆. During germination,the IP₆ in AL decreased markedly with no accumulation of lessphosphorylated myo-inositols and Pi and acid-insoluble organicP increased in the EM. The total P in the EN of 1-day germinatedseeds was about one-third that in the AL, the greater part ofwhich was found in the acid-insoluble fraction and decreasedgradually during germination. Only a small amount of IP₆ couldbe detected in the EM and EN during the early stage of germination. IP₆ in AL of embryoless half-seeds incubated without gibberellicacid (GA₃) decreased slightly even after 6 days. Incubationwith 10 ppm GA₃ remarkably stimulated the IP₆ degradation. Thisstimulation was reduced, with no change in the Pi content, byabout 80–90% with 1 mM 6-methylpurine or 10 ppm cycloheximide.The addition of 0.1 M KH₂PO₄ caused a 4-fold increase in thePi content of AL in the presence of GA₃. In addition, it suppressedthe GA₃-dependent -amylase synthesis by about 20% and the GA₃effect on IP₆ degradation by about 50%. In light of these results, IP₆ seems to be hydrolyzed completelyinto Pi and myo-inositol within the aleurone tissue, and gibberellinseems to control this process. (Received August 24, 1979; )     

trxS基因对大麦发芽籽粒中蛋白质降解的影响

对转trxS基因大麦籽粒发芽过程中蛋白酶活性、不同蛋白组分含量和贮藏蛋白SDS-PAGE图谱的变化进行了研究。结果表明：与对照相比,转基因籽粒中的蛋白酶活性提高;清蛋白、球蛋白、醇溶蛋白和谷蛋白含量低于对照。SDS-PAGE图谱也表明,转基因籽粒中贮藏蛋白降解快于对照。     

Osmotic sensitivity in relation to salt sensitivity in germinating barley seeds

Abstract Cultivars of barley (Hordeum vulgare L.) were tested for germination sensitivity to progressively higher concentrations of salt, mannitol, and betaine. The three solutes were equally inhibitory at equal osmotic potential, but there was a consistent difference in osmotic sensitivity between two cultivars, CM-67 and Briggs (Briggs was the most sensitive). There was no difference between the two cultivars in salt or water uptake from salt solutions during imbibition. Brief presoaking in water did not improve salt resistance, indicating that a hydration-dependent decrease in membrane permeability is not involved in salt tolerance. The calcium content of Briggs was higher than CM-67. These results suggest that salt inhibits barley germination primarily by osmotic effects, and that salt influx during imbibition does not play a role in this inhibition. A hypothesis regarding salt effects on germination is discussed.     

A major cysteine proteinase, EPB, in germinating barley seeds: structure of two intronless genes and regulation of expression

The barley cysteine proteinase B (EPB) is the main protease responsible for the degradation of endosperm storage proteins providing nitrogenous nutrients to support the growth of young seedlings. The expression of this enzyme is induced in the germinating seeds by the phytohormone, gibberellin, and suppressed by another phytohormone, abscisic acid. In situ hybridization experiments indicate that EPB is expressed in the scutellar epithelium within 24 h of seed germination, but the aleurone tissue surrounding the starchy endosperm eventually becomes the main tissue expressing this enzyme. The EPB gene family of barley consists of two very similar genes, EPB1 and EPB2, both of which have been mapped to chromosome 3. The sequences of EPB1 and EPB2 match with the two previously published cDNA clones indicating that both genes are expressed. Interestingly, neither of these genes contain any introns, a rare phenomenon in which all members of a small gene family are active intronless genes. Sequence comparison indicates that the barley EPB family can be classified as cathepsin L-like endopeptidases and is most closely related to two legume cysteine proteinases (Phaseolus vulgaris EP-C1 and Vigna mungo SHEP) which are also involved in seed storage protein degradation. The promoters of EPB1 and EPB2 have been linked to the coding sequence of a reporter gene, GUS, encoding -glucuronidase, and introduced into barley aleurone cells using the particle bombardment method. Transient expression studies indicate that EPB promoters are sufficient to confer the hormonal regulation of these genes.     

Evidence for osmotic regulation of hydrolytic enzyme production in germinating barley seeds

α-Amylase levels in intact seeds of barley (Hordeum vulgare L. cv. Himalaya) reach a maximum at 3 to 4 days of germination while gibberellin levels continue to increase beyond 6 days of germination. In contrast to its effect on half seeds, gibberellic acid does not increase the total amount of α-amylase produced in germinating seeds. The inability of gibberellic acid to stimulate α-amylase production is not related to its availability; rather, evidence suggests that a factor(s) in whole seeds prevents further enhancement of α-amylase formation and accumulation. Hydrolysis products accumulate in the subaleurone space of the endosperm of germinating seeds up to concentrations of 570 milliosmolar. Chromatography of these hydrolysis products indicate the presence of maltose and glucose. Calculations based on reducing sugar determinations show that glucose accounts for as much as 57% of the solutes present in the endosperm fluid. Both maltose and glucose in the range of 0.2 to 0.4 M effectively inhibit the production of α-amylase by isolated barley aleurone layers. This inhibition is quantitatively similar to that brought about by solutions of polyethylene glycol and mannitol. On the basis of these data we propose that hydrolysis products which accumulate in the starchy endosperm of germinating seeds function to regulate the production of hydrolytic enzymes by the aleurone layer.     

Expression and inhibition of aquaporins in germinating Arabidopsis seeds

Extensive and kinetically well-defined water exchanges occur during germination of seeds. A putative role for aquaporins in this process was investigated in Arabidopsis. Macro-arrays carrying aquaporin gene-specific tags and antibodies raised against aquaporin subclasses revealed two distinct aquaporin expression programs between dry seeds and young seedlings. High expression levels of a restricted number of tonoplast intrinsic protein (TIP) isoforms (TIP3;1 and/or TIP3;2, and TIP5;1) together with a low expression of all 13 plasma membrane aquaporin (PIP) isoforms was observed in dry and germinating materials. In contrast, prevalent expression of aquaporins of the TIP1, TIP2 and PIP subgroups was induced during seedling establishment. Mercury (5 microM HgCl(2)), a general blocker of aquaporins in various organisms, reduced the speed of seed germination and induced a true delay in maternal seed coat (testa) rupture and radicle emergence, by 8-9 and 25-30 h, respectively. Most importantly, mercury did not alter seed lot homogeneity nor the seed germination developmental sequence, and its effects were largely reversed by addition of 2 mM dithiothreitol, suggesting that these effects were primarily due to oxidation of cell components, possibly aquaporins, without irreversible alteration of cell integrity. Measurements of water uptake in control and mercury-treated seeds suggested that aquaporin functions are not involved in early seed imbibition (phase I) but would rather be associated with a delayed initiation of phase III, i.e. water uptake accompanying expansion and growth of the embryo. A possible role for aquaporins in germinating seeds and more generally in plant tissue growth is discussed.     

Purification and partial characteristic of a major gliadin-degrading cysteine endopeptidase from germinating triticale seeds

The endopeptidase of the highest electrophoretic mobility was the main endopeptidase hydrolyzing gliadin in the endosperm of germinated triticale (X Triticosecale Wittm.) grains after three days of imbibition. Activity of this endopeptidase, named EP8 starts to be detectable after two days of imbibition. The appearance of its activity in the endosperm on a second day of imbibition may suggest that EP8 is synthesized in aleurone during germination and/or secreted into the starchy endosperm as an inactive polypeptide during grains development and then activated. EP8 was isolated from the endosperm of germinating triticale seeds and purified 257-fold using ammonium sulphate, ion exchange chromatography on DEAE Sepharose CL-6B and gel filtration on Sephadex G-100. The enzyme was totally inhibited by E-64—class-specific cysteine proteinases inhibitor and activated by thiol compounds. Molecular weight estimated by SDS-PAGE was 39.5 kDa. The optimum pH for the hydrolysis of gliadin was 4.2 and for hemoglobin 5.2. High activity of EP8 against wheat gliadin in vitro suggests that this cysteine endopeptidase plays a major role in the mobilization of storage proteins in the endosperm of germinating triticale grains.     

Water relations in germinating seeds

Life strategy of plants depends on successful seed germination in the available environment, and sufficient soil water is the most important external factor. Taking into account a broad spectrum of roles played by water in seed viability and its maintenance during germination, the review embraces early germination events in seeds different in their water status. Two seed types are compared, namely orthodox and recalcitrant seeds, in terms of water content in the embryonic axes, vacuole biogenesis, and participation of water channels in membrane water transport. Mature orthodox seeds desiccate to low water content and remain viable during storage, whereas mature recalcitrant seeds are shed while well hydrated but die during desiccation and cannot be stored. In orthodox Vicia faba minor air-dry seeds remaining viable at 8–10% water content in embryonic axes, the vacuoles in hypocotyl are preserved as protein storage vacuoles, then restored to vacuoles in imbibing seeds in the course of protein mobilization. However, in newly produced meristematic root cells, the vacuoles are formed de novo from provacuoles. In recalcitrant Aesculus hippocastanum seeds, embryonic axes have a water content of 63–64% at shedding and they lack protein storage vacuoles but preserve vacuoles preformed in maturing seeds. Independent of the vacuolar biogenetic patterns, their further trend is similar; they expand and fuse, thus producing an osmotic compartment, which precedes and becomes an obligatory step for the initiation of cell elongation. Prior to this, water moves in imbibing seeds through the membranes by diffusion, although the aquaporins forming water channels are present. In both seed types, water channels are opened and actively participate in water transport only after growth initiation. Aquaporin gene expression and their composition change in broad bean embryonic axes after growth initiation. This is the way how a mass water flow into growing seedling cells is achieved, independent of differences in seed water content and vacuole biogenesis patterns.     

Transaminase studies in germinating seeds

The changes in glutamic-alanine and glutamic-aspartic transaminase during the germinating period of the seedling have been studied with plants from three plant families. It was found that in the germinating seed embryo the glutamic-aspartic transaminase activity was in general higher than the glutamic-alanine transaminase activity. At the beginning of germination all plants studied contained approximately the same amount of transaminase: i.e., about 5–10 units/embryo. However after 120 hr. of germination there were wide variations in the amount of transaminase found in the different species. In most of the plants studied the transaminase activity/mg. protein nitrogen revealed a proportionally greater increase in the enzymatic activity than that of the protein nitrogen.Stimulation of growth and metabolism of the embryo by the use of a mineral supplement for germination of the seeds produced an increase in the rate of formation of both transaminase and protein nitrogen. However, the production of the enzyme was relatively greater than the formation of protein nitrogen.The results indicated that no definite relationships existed between the changes in glutamic-alanine or glutamic-aspartic transaminase activity and the formation of protein. This would suggest that in plants, protein synthesis is not a direct function of transaminase activity; it may play an indirect role in protein synthesis by its action on the interconversion of amino and keto acids.     

Beta-amylase in germinating millet seeds

Beta-amylase (EC 3.2.1.2) was isolated from germinating millet (Panicum miliaceum L.) seeds by a procedure that included ammonium sulfate fractionation, chromatography on DEAE-cellulofine and CM-cellulofine, and preparative isoelectric focusing. The enzyme was homogeneous by SDS-PAGE. The M(r) of the enzyme was estimated to be 58,000 based on its mobility on SDS-PAGE and gel filtration with TSKgel G4000SW(XL), which showed that it is composed of a single unit. The isoelectric point of the enzyme was 4.62. The enzyme hydrolyzed malto-oligosaccharides more readily as their degree of polymerization increased, this being strongest for malto-oligosaccharides larger than 13 glucose residues and very weakly for maltotriose. Amylose, amylopectin and soluble starch were the most suitable substrates for the enzyme. While the enzyme showed some activity against native starch by itself, starch digestion was accelerated 2.5-fold using alpha-amylase, pullulanase and alpha-glucosidase. This enzyme appears to be very important for the germination of millet seeds.     

Selenium-containing peroxidases of germinating barley

Germinating barley grown on an artificial medium was exposed to⁷⁵Se-selenite for 8 d. Then the leaves were homogenized and proteins were separated by means of Sephadex G-150 filtration, followed by DEAE-Sepharose chromatography. Each fraction collected was assayed for total protein, radioactivity, and peroxidase activity. In barley leaves, three protein peaks (peaks no. I, II, and III) with peroxidase activity could be separated by Sephadex G 150 filtration. Each fraction was then further separated on DEAE-Sepharose chromatography. Thus, peaks I and II were resolved by DEAE-Sepharose into one major and two minor peaks of radioactivity. However, only the major peak showed peroxidase activity. Peak III was resolved from the gel filtration on the DEAE-sepharose into one major and four minor peaks of radioactivity. The major and three of the minor radioactivity peaks contained peroxidase activity. The protein fractions were separated by polyacrylamide gel electrophoresis. The molecular weights of separated proteins were estimated by means of molecular markers, and⁷⁵Se radioactivity was evaluated by autoradiography. Thus, gel filtration peak I contained four bands with mol wts of 128, 116, 100, and 89 kDa. Of these, the 89 kDa protein contained selenium. Peak II contained three protein bands, with mol wts 79.4, 59.6, and 59.9. The 59.6 band was a selenoprotein. Peak III contained four protein bands (and some very weak bands). The four major bands had mol wts of 38.6, 31.6, 30.2, and 29.2 kDa. The last mentioned band was a selenoprotein.