Regulation of Gene Expression in Developing Zea mays Embryos: Protein Synthesis during Embryogenesis and Early Germination of Maize

Polypeptides synthesized in dissected embryos of Zea mays at different stages of embryogenesis and early germination have been characterized by their migration in two-dimensional gel electrophoresis. This analysis has been carried out with in vivo labeled polypeptides from excised embryos and with proteins synthesized in vitro in the rabbit reticulocyte system directed by poly(A⁺) RNA isolated from the different developmental stages. We have identified three main sets of expressed polypeptides: (a) embryonic set: this group of polypeptides is synthesized in young and mature embryos but not in early germination; (b) maturation set: this group of polypeptides is not present in young embryos and appears during the maturation period. Some of these polypeptides are still present in early germination while others disappear from stored mRNAs in dry embryos. One particular group from this set can be induced prematurely in young embryos by incubation with abscisic acid; and (c) germination set: this group of polypeptides is not expressed in the maturation period and appears after brief imbibition of the dry embryos.     

De novo synthesis of 3'-nucleotidase in germinating wheat embryo

The enzyme 3′-AMP nucleotidase was purified 2,500- to 5,000-fold from extracts of an acetone powder of wheat (Triticum aestivum) embryonic axes germinated for 40 hours. Sodium dodecyl sulfate acrylamide gel electrophoresis and chromatography on Biogel-P100 indicate that the enzyme is monomeric with a molecular weight of 39,000. Extracts of embryos germinated up to 6 hours have only 1% of the 40-hour level of enzyme activity. To see if the increase to 40 hours represents de novo synthesis, extracts were compared for their ability to react with a rabbit antibody prepared against the enzyme. In immunodiffusion tests, 40-hour extracts showed a strong precipitin line coincident with that of the purified enzyme, whereas no precipitation was observed with 1-hour extracts. When the enzyme present in 40-hour extracts was partially inactivated by EDTA, it still blocked the ability of the antibody to inhibit enzyme activity. Extracts of 1-hour embryos, in contrast, were not able to block the inhibitory activity of the antibody. Embryos allowed to take up ³⁵SO₄ between 40 and 46 hours of germination synthesized ³⁵S-labeled 3′-nucleotidase. In contrast, no radioactive protein synthesized by embryos during the first 6 hours of germination coincided on gel electrophoresis with the enzyme. These results indicate that the increase in 3′-nucleotidase activity is a consequence of de novo synthesis of the enzyme.     

Lipid synthesis in germinating Tradescantia pollen

Synthesis of neutral and polar lipids in pollen of Tradescantia paludosa during germination and tube growth was studied by the incorporation of acetate-[1-¹⁴C] into lipids in the presence and absence of inhibitors of RNA and protein synthesis. The proteins required for the synthesis of both neutral lipids and phospholipids are not made de novo during germination but are already present in the mature ungerminated pollen grain and they are functionally stable during the first 2 hr of pollen growth.     

Timing, localization, and control of wheat germ agglutinin synthesis in developing wheat embryos

The lectin, wheat germ agglutinin (WGA), is synthesized de novo by developing wheat (Triticum aestivum, L.) embryos but is not synthesized or localized in developing endosperm as shown by radioimmunoassay. Young embryos removed from the grain and cultured on a defined medium germinate precociously and concomitantly cease WGA synthesis. In vitro precocious germination of young embryos is reversibly inhibited by low levels (1–100 μM) of the plant growth substance abscisic acid (ABA). Embryos inhibited from germinating by this growth regulator not only continue synthesizing WGA, but do so at an accelerated rate when compared with embryos left associated with the grain.     

Proteins in development and germination of a desiccation sensitive (recalcitrant) seed species

In the recalcitrant seeds of Avicennia marina, protein content and the rates of protein synthesis increase during histodifferentiation. This is similar to the situation in desiccation tolerant seeds. During the stage of reserve accumulation the protein content and rates of synthesis remain constant and there is no de novo synthesis of proteins which might qualify as storage proteins. There is also no change in the nature of proteins present in either axis or cotyledonary tissues during development or germination. Similarly, fluorographs of axis proteins show only very limited changes in the patterns of protein synthesis during development and germination, at least until the onset of root growth. Heat-stable proteins are present from an early developmental stage. However, no late embryogenic abundant (LEA) proteins are synthesised during the late stages of development, indicating that seedling establishment is independent of such maturation proteins. It is suggested that the lack of desiccation tolerance of A. marina seeds might be related to the absence of desiccation-related LEAs. Although the rate of protein synthesis increases during germination, protein metabolism appears to remain qualitatively the same as that occurring during development. The present results suggest that in these desiccation sensitive seeds, protein metabolism characterising development changes imperceptibly into that of germination.     

The Hydrolysis of Endosperm Protein in Zea mays

Degradation of the major storage proteins in maize endosperm, zein and glutelin, begins during the 2nd day of germination. The protein most abundant in the mature endosperm is degraded most rapidly. The patterns of protein loss are essentially similar in germinating seeds and excised endosperms. Cycloheximide, added at the beginning of the incubation period, prevents the development of α-amylase and protease activities and the disappearance of starch and protein reserves. Late additions (70 hours) of cycloheximide still inhibit the increase in hydrolase activity but have no effect on the hydrolysis of storage reserves. The results indicate that the hydrolytic enzymes are synthesized de novo in the maize endosperm.     

Monitoring Astrocytic Proteome Dynamics by Cell Type-Specific Protein Labeling

The ability of the nervous system to undergo long-term plasticity is based on changes in cellular and synaptic proteomes. While many studies have explored dynamic alterations in neuronal proteomes during plasticity, there has been less attention paid to the astrocytic counterpart. Indeed, progress in identifying cell type-specific proteomes is limited owing to technical difficulties. Here, we present a cell type-specific metabolic tagging technique for a mammalian coculture model based on the bioorthogonal amino acid azidonorleucine and the mutated Mus musculus methionyl-tRNA synthetase^L274G enabling azidonorleucine introduction into de novo synthesized proteins. Azidonorleucine incorporation resulted in cell type-specific protein labeling and retained neuronal or astrocytic cell viability. Furthermore, we were able to label astrocytic de novo synthesized proteins and identified both Connexin-43 and 60S ribosomal protein L10a upregulated upon treatment with Brain-derived neurotrophic factor in astrocytes of a neuron-glia coculture. Taken together, we demonstrate the successful dissociation of astrocytic from neuronal proteomes by cell type-specific metabolic labeling offering new possibilities for the analyses of cell type-specific proteome dynamics.     

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     

Regulation of loblolly pine (Pinus taeda L.) arginase in developing seedling tissue during germination and post-germinative growth

After seed germination, hydrolysis of storage proteins provides a nitrogen source for the developing seedling. In conifers the majority of these reserves are located in the living haploid megagametophyte tissue. In the developing loblolly pine (Pinus taeda L.) seedling an influx of free amino acids from the megagametophyte accompanies germination and early seedling growth. The major component of this amino acid pool is arginine, which is transported rapidly and efficiently to the seedling without prior conversion. This arginine accounts for nearly half of the total nitrogen entering the cotyledons and is likely a defining factor in early seedling nitrogen metabolism. In the seedling, the enzyme arginase is responsible for liberating nitrogen, in the form of ornithine and urea, from free arginine supplied by the megagametophyte. In this report we investigate how the seedling uses arginase to cope with the large arginine influx. As part of this work we have cloned an arginase cDNA from a loblolly pine expression library. Analysis of enzyme activity data, accumulation of arginase protein and mRNA abundance indicates that increased arginase activity after seed germination is due to de novo synthesis of the enzyme. Our results suggest that arginase is primarily regulated at the RNA level during loblolly pine seed germination and post-germinative growth.     

Changs in pyrimidine nucleotide biosynthesis during germination of white spruce (picea glauca) somatic embryos

Summary Changes in pyrimidine metabolism were investigated in germinating white spruce somatic embryos by following the metabolic fate of [2-¹⁴C]uracil and [2-¹⁴C]uridine, intermediate metabolites of the salvage pathway and [6-¹⁴C]orotic acid, a central metabolite of the de novo. nucleotide biosynthesis. An active uridine salvage was found to be responsible for the enlargement of the nucleotide pool at the inception of germination. Uridine kinase, which catalyzes the conversion of uridine to uridine monophosphate (UMP), was found to be very active in partially dried embryos and during the early phases of imbibition. The contribution of uracil to the nucleotide pool was negligible since a large amount of radioactivity from [2-¹⁴C]uracil was recovered in degradation products. As germination progressed, the decline of the uridine salvage pathway was concomitant with an increase of the de novo biosynthetic pathway. The central enzyme of the de novo pathway, orotate phosphoribosyltransferase, showed increased activity and contributed to the larger amount of orotate being anabolized. These results suggest that although both the salvage and de novo pathways operate in germinating white spruce somatic embryos, their contribution to the enlargement of the nucleotide pool appears tightly regulated as germination progresses.     

Differential Protein Pattern of Two Cotyledon Explants of Vigna radiata During Induced In Vitro Differentiation: Probable Implication in the Conundrum of Differential Regeneration Response

Differential regeneration response in two cotyledon types (Cot and Cot E) of Vigna radiata was reported earlier. The Cot (one cotyledon) is easily detachable from the germinating embryonal axis, whereas, Cot E (the other cotyledon) remains firmly attached during seed germination or after imbibition. Shoots differentiated directly from the Cot E under the induction of in vitro differentiation, while, under the same milieu, shoot differentiation was preceded by callus differentiation from Cot. In this study, we present comparative analyses of protein profiles from these two explant types recorded at different point of time during induction of differentiation. Cot E always contained higher amounts of soluble protein than the Cot. Likewise, higher de novo protein synthesis was noted in Cot E than in Cot as revealed by ³⁵S methionine labeled study. Two polypeptides of ～37 and 84 kD disappeared earlier from Cot E than Cot and is presumed to be linked with shoot induction. Two marker proteins of ～88 and 158 kD synthesized during shoot differentiation were apparent. It was observed that the labeled protein synthesis initiated within 3h in Cot E under in vitro condition, while, no labeled protein was detected from Cot even at 12h. Irrespective of the mode of differentiation, a large amount of protein was hydrolyzed during the process of differentiation. However, in case of Cot, the process was delayed by a day than Cot E. In all probability, this is an indication of delayed cytokinin induced rejuvenation of Cot. Temporal difference in protein profile was also evident in these two explant types during in vitro differentiation. Yet, three major groups of proteins were consistently present in both the explants. The biochemical differences recorded between these two explants during induction of in vitro differentiation reflects the temporal difference in gene expression. Perhaps Cot E has the distinctiveness due to the temporal differences in certain key gene expression and proved its greater suitability over Cot for shoot regeneration purposes.     

Acid invertase in germinating Lactuca sativa seeds: Evidence for de novo synthesis

Acid invertase activity in germinating lettuce seeds is first observed after 15 hr germination, from when it rises steadily at least till 30 hr of germination. The enzyme was purified about 500-fold using ammonium sulphate fractionation followed by isoelectric focussing. Labelling the enzyme with ³⁵SO₄ or leucine-¹⁴C during development of its activity, followed by purification suggests that acid invertase is synthesized de novo during germination. The possible significance of acid invertase in the metabolism of the seed is discussed.     

SOURCES OF LARVAL SALIVARY GLAND SECRETION IN THE DIPTERAN CHIRONOMUS TENTANS

The soluble proteins in the hemolymph, the salivary gland, and the salivary secretion of fourth instar Chironomus tentans were examined by disc electrophoresis in acrylamide gels. Of the 11 protein fractions detected in buffered saline extracts of the gland, 10 are present also in the hemolymph. Amino acid isotope incorporation experiments indicate that the protein fractions shared by the salivary gland and the hemolymph are not synthesized in the gland but are synthesized in other larval tissues. Immunochemical studies show that most of these proteins eventually are secreted from the gland. The salivary gland in vivo and in vitro is active in de novo protein synthesis. The protein synthesized tends to form large molecular weight aggregates. As demonstrated by radioautography, at least 80% of this protein is secreted from the 30 large cells forming most of the gland. The proteins synthesized in the salivary gland cannot be detected in the hemolymph. The results of this investigation are consistent with a mechanism of secretion formation involving both de novo synthesis of some secretion proteins and the selective uptake, transport, and secretion of hemal proteins by the salivary gland.     

Microscopic observations of germination and septum formation in pycnidiospores of Botryodiplodia theobromae

A population of aseptate pycnidiospores of the fungus Botryodiplodia theobromae can be induced to germinate or to form septa delimiting two cells; this developmental process is dependent upon nutritional and environmental factors. Transmission electron microscope investigations indicate that during germination of the aseptate spore, a new inner wall layer is synthesized de novo at the site of germ tube emergence. Formation of the septum also involves the de novo synthesis of an inner wall layer which comprises the majority of the septum and completely surrounds the spore. The wall of the germ tube emerging from the septate spore is a direct extension of this inner layer deposited during the formation of the septum. Although the early stages of spore germination may involve localized enzymatic degradation of the internal layers of the spore wall, transmission and scanning electron micrographs of germinating spores show that the outer wall layers are physically fractured by the emerging germ tube. It is suggested that spore germination and septum formation are initially similar processes regarding cell wall genesis but that some mechanism responsive to environmental and nutritional conditions determines the course of development.     

Onset of deoxyribonucleic Acid synthesis in germinating wheat embryos

Germinating wheat embryos (Triticum vulgare var. Florence) synthesize proteins before the onset of DNA synthesis. The onset of DNA replication occurs at about 15 hours of germination and was shown to depend on proteins synthesized before 9 hours of germination with the use of blasticidin S, a specific inhibitor of protein synthesis. A 10-fold increase in the activity of DNA-dependent DNA polymerase was found in extracts derived from germinated embryos, as compared to the activity found in extracts from ungerminated embryos.     

Regulation of the maize (Zea mays L.) embryo proteome by RTCS which controls seminal root initiation

Seminal roots are initiated at the scutellar node during maize (Zea mays L.) embryo development. The maize mutant rtcs (rootless concerning crown and seminal roots) does not initiate seminal roots while its wild-type siblings form on average 2.9 seminal roots per seedling. In this study, proteome profiles of 25-day-old immature maize embryos were compared between wild-type and rtcs plants via two-dimensional electrophoresis (2-DE). Electrospray ionization tandem mass spectrometry (ESI-MS/MS) identified 23 proteins encoded by 21 different genes that were differentially accumulated between wild-type and rtcs embryos (Fc≥2; FDR<10%). Among the differentially accumulated proteins, two isoforms of a phosphoglycerate kinase and a malate dehydrogenase were preferentially accumulated in wild-type embryos. Both enzymes are related to the generation of energy-rich ATP or NADPH molecules and are crucial checkpoints of cellular energetics in plants. Comparison of embryonic proteins differentially accumulated between wild-type and rtcs embryos revealed little overlap with proteins differentially accumulated between wild-type and rum1 embryos which also do not initiate seminal roots. This might be due to distinct influences of RTCS and RUM1 on the composition of the embryo proteome, but could also be explained by different stages of embryo development that were analyzed in these studies.