Long-lived Messenger RNA and its Relationship to Protein Synthesis During Germination of Pea (Pisum sativum L.) Seeds

Synthesis of both protein and RNA is initiated very early ingermination in the embryo axes of pea seeds. The early RNA synthesisinvolves all three types, although there is some evidence forpreferential synthesis of mRNA in the first few hours afterthe onset of imbibition. In addition to newly synthesized mRNA,the embryo axis also contains long-lived mRNA. The amount ofthis long-lived mRNA declines markedly during the first 20 hof germination. Synthesis of both protein and RNA is initiated very early ingermination in the embryo axes of pea seeds. The early RNA synthesisinvolves all three types, although there is some evidence forpreferential synthesis of mRNA in the first few hours afterthe onset of imbibition. In addition to newly synthesized mRNA,the embryo axis also contains long-lived mRNA. The amount ofthis long-lived mRNA declines markedly during the first 20 hof germination. Results from in vitro and in vivo protein synthesis experimentsand from studies of polysome formation suggest that much ofthe long-lived mRNA present in the embryo axis does not directprotein synthesis. The increase in the rate of protein synthesisduring germination is thus dependent on recruitment of newlysynthesized mRNA molecules. Pea, Pisum sativum L., germination, mRNA, protein synthesis     

Changing rates of DNA and RNA synthesis in Drosophila embryos

Rates of DNA and RNA synthesis during Drosophila embryogenesis were measured by labeling octane-treated embryos with [¹⁴C]thymidine and [³H]uridine. Radioactivity incorporated per hour was converted to rates of synthesis using measurements of the pool-specific activity during the labeling periods. The rate of DNA synthesis during early embryogenesis increases to a maximum at 6 hr after oviposition and then decreases sharply. Measured rates of DNA synthesis were used to calculate that the total amount of DNA per embryo doubles every 18 min at blastoderm, every 70–80 min during gastrulation, and less than once every 7 hr at later stages. The rate of RNA accumulation per embryo increases continuously during the first 14 hr of embryogenesis. The rate of nuclear RNA synthesis per diploid amount of DNA, however, decreases fivefold between blastoderm and primary organogenesis. The cytoplasmic poly(A)⁺ RNA synthesized by blastoderm embryos associates rapidly with polysomes. The relatively high rate of synthesis of polysomal poly(A)⁺ RNA per nucleus at blastoderm allows the small number of nuclei present at blastoderm to make a significant quantitative contribution to the informational RNA active in the early embryo. At the end of blastoderm, approximately 14% of the mRNA being translated in the embryo has been synthesized after fertilization.     

Cell cycle analysis in asynchronous cultures using the BUdR-Hoechst technique.

During synchronized germination of spores of Dictyostelium discoideum, protein synthesis begins almost concomitantly with syntheses of messenger-like RNA (mlRNA) and 4–5S RNA (presumably tRNA) in the swollen spore stage and the initiation of ribosomal RNA (rRNA) synthesis is somewhat delayed. DNA synthesis occurs in the early stages of the amoeba emergence phase. Cycloheximide (200 μg/ml) blocked spore germination as well as total protein synthesis, whereas actinomycin D (60 μg/ml) did not affect either. This concentration of actinomycin D selectively inhibited formation of rRNA but did not influence the synthesis of mlRNA. Examinations of RNA labeled with [¹⁴C]uracil during germination indicated that polysomes initially detectable in the course of the germination process contain ¹⁴C-labeled mlRNA. It was concluded that at least some of mRNA synthesized during germination of D. discoideum spores is involved in protein synthesis required for the germination.     

Early Actions of Gibberellic Acid on the Embryo and on the Endosperm of Avena fatua Seeds

Gibberellic acid at 0.1 μm stimulates amylase synthesis in dormant Avena fatua seeds without inducing germination; at 0.5 mm it enhances biosynthesis of proteins and RNA in both the embryo and the endosperm and utilization of the endosperm sugars by the embryo. These events occur in early hours (0-14th hour) and prior to germination, which begins 24 hours after gibberellic acid application. These observations are in agreemeent with the concept that in cereal grains gibberellic acid has two morphological sites of actions: the embryo and the endosperm, and that germination (radicle protrusion) is not caused by gibberellic acid-induced amylase synthesis in the endosperm.     

Deoxyribonucleic acid synthesis and deoxyribonucleic acid-polymerase activity during early germination of wheat embryos at high and low viability

³H-thymidine incorporation and DNA-polymerase activity during early hours of wheat embryo germination at two viability levels have been studied. The patterns of two biosynthetic activities, as well as the dependence of DNA synthesis on protein synthesis, indicated the presence of a delay in the early phase of imbibition of the aged embryos with respect to viable germs.     

Lack of correlation between overall protein synthesis and the onset of cell elongation in germinating embryos of Haplopappus gracilis

10⁻⁵M abscisic acid (ABA) completely inhibits germination or (if seeds deprived of integuments are used) embryo elongation in Haplopappus gracilis (Nutt.) Gray. Nevertheless, considerable rates of protein and RNA synthesis were found in embryos grown in abscisic acid, at least during the early hours after sowing. On the contrary, seeds grown in cycloheximide + fusicoccin (a powerful promoter of cell expansion), where protein synthesis is almost completely inhibited, show full protrusion of radicle, thus simulating a "germination" process. These results suggest that some of the most important events involved in seed germination, i.e. protein and RNA synthesis, and cell elongation which leads to radicle protrusion, may not necessarily be linked together and are possibly regulated by different control mechanisms. Moreover, when seeds or embryos are grown in abscisic acid + fusicoccin, protein synthesis is considerable, cell elongation is greater than in water controls at least for 12 h, and germination in its early stages appears to be normal; but DNA synthesis and cell division are not resumed, possibly since some other factor is required. All these findings propose a reevaluation of criteria for defining successful germination.     

Germination of Rye Embryos Following Hydration-Dehydration Treatments: Enhancement of Protein and RNA Synthesis and Earlier Induction of DNA Replication

On germination of low viability embryos of rye, var. LovaszPatonai, the rate of protein synthesis increases during theearly hours of imbibition and high rates of DNA replicationcommence around the 9th hour. If embryos are imbibed for 3 or6 h then dehydrated back to their original weight, their rateof protein synthesis when next imbibed closely corresponds tothat of embryos germinated for a period equal to that of thehydration pre-treatment plus the duration of the second imbibition.Pre-treatment also enhances subsequent RNA synthesis and embryoshydrated for 9 h then dehydrated start major DNA synthesis atonce as water is again supplied. Many changes occurring duringthese periods of hydration pre-treatment must therefore be stableto subsequent dehydration. Damage occurs to areas that are firstactive in protein and RNA synthesis if pre-treatments extendbeyond 9 h and subsequent germination of the embryo is thenimpaired. The implications of these results are discussed inrelation to the effects of hydration pre-treatments upon enhancedgermination and the stability to dehydration of the productsof early RNA and protein synthesis.     

Characterization of the early synthesized DNA in germinating Triticum aestivum embryos

A radioactive DNA preparation was isolated from the post-mitochondrial supernatant fraction of thymidine-[¹⁴C] fed wheat embryos. The isolated sDNA preparation was similar to cytoplasmic non-mitochondrial DNA of other eukaryotic cells. The buoyant density and frequency of pyrimidine nucleotide clusters found for the sDNA were, essentially, the same as those found for the nuclear DNA. In contrast to DNA that can be leaked from nuclei or other DNA-containing organelles, the sDNA is firmly bound to a protein component. At an early germination stage (6–12 hr), the sDNA is the only newly-synthesized DNA fraction that can be isolated from the embryo homogenate. Considerable synthesis of nuclear and organellar DNA starts 18 hr after the beginning of germination, just prior to the first maximum of the cell divisions. It is concluded that wheat embryo cells contain cytoplasmic non-mitochondrial DNA and are able to resume its synthesis at an early germination stage, prior to the first post-dormant round of nuclear DNA replication.     

DNA and histone synthesis are uncoupled during germination of maize embryos

The rate of synthesis of DNA and histones was studied in germinating maize embryos as a function of the length of the germination period. To that end excised embryos from seeds germinated for different periods of time were pulse labelled either with [¹⁴C]protein hydrolysate or with [³H]TdR. Specific activities were determined for the total cellular proteins and the total histone fraction obtained by acid-extraction of the cellular homogenate and BioRex70 ion exchange chromatography. The results show that the early germination period is characterized by a lack of coupling between the histone synthesis and that of the nuclear DNA. The early histone synthesis peak might be necessitated by the reprogramming of the embryo genome that takes place during germination.     

Ribosomal protein mRNAs increase dramatically during Xenopus development

The amount of messenger RNA per microgram of rRNA increases three- to fourfold during Xenopus early development. This increase is the same when measured by stimulation of in vitro protein synthesis or by poly(U) hybridization. The increase in mRNA per embryo therefore is approximately six- to eightfold since the ribosome content doubles between fertilization and the stage 41 tadpole. The amount of ribosomal protein mRNA, as assayed by in vitro protein synthesis, also increases dramatically during early development. This increase is much more pronounced than the general increase in mRNA content, i.e., there is a dramatic increase in the abundance as well as the amount of the ribosomal protein mRNA. Since ribosomal protein mRNAs are predominantly small mRNAs, the increase in ribosomal protein mRNA abundance contributes to the general decrease in the average size of pA⁺ RNA that occurs during early development in Xenopus.     

Control of Seed Germination by Abscisic Acid: I. Time Course of Action in Sinapis alba L

The germination process of mustard seeds (Sinapis alba L.) has been characterized by the time courses of water uptake, rupturing of the seed coat (12 hours after sowing), onset of axis growth (18 hours after sowing), and the point of no return, where the seeds lose the ability to survive redesiccation (12 to 24 hours after sowing, depending on embryo part). Abscisic acid (ABA) reversibly arrests embryo development at the brink of radicle growth initiation, inhibiting the water uptake which accompanies embryo growth. Seeds which have been kept dormant by ABA for several days will, after removal of the hormone, rapidly take up water and continue the germination process. Seeds which have been preincubated in water lose the sensitivity to be arrested by ABA after about 12 hours after sowing. This escape from ABA-mediated dormancy is not due to an inactivation of the hormone but to a loss of competence to respond to ABA during the course of germination. The sensitivity to ABA can be restored in these seeds by redrying. It is concluded that a primary action of ABA in inhibiting seed germination is the control of water uptake of the embryo tissues rather than the control of DNA, RNA, or protein syntheses.     

Stored polyadenylated RNA and loss of vigour in germinating wheat embryos

Loss of vigour in wheat seed is associated with lesions affecting the rate of disappearance of stored poly A⁺ RNA (presumptive mRNA) in the germinating embryo when germination takes place at a sub-optimal temperature. During germination in the presence of α-amanitin and consequent of de novo polyA⁺ RNA biosynthesis, the wheat embryo can degrade up to 70% of the stored poly A⁺ RNA of the quiescent embryo before any significant reduction in the rate of protein biosynthesis in the embryo becomes apparent. It is possible that two subpopulations of poly A⁺ RNA species exist in wheat embryos during early germination, one population being degraded rapidly upon rehydration of the embryo whilst the other population supports protein biosynthesis in the initial germination stages prior to degradation.     

Seed Dormancy in Red Rice : VIII. Embryo Acidification during Dormancy-Breaking and Subsequent Germination

Exposure of dehulled, dormant red rice (Oryza sativa) seeds to dormancy-breaking treatments (10 mm sodium nitrite, 20 mm propionic acid, 30 mm methyl propionate, 40 mm propionaldehyde, or 70 mmn-propanol) induced tissue pH acidification during chemical contact at least 12 h before visible germination. During chemical contact, the onset of embryo acidification occurred before or coincident with the chemical contact interval necessary for subsequent germination. Upon seed transfer to H₂O following chemical contact, embryo pH also decreased coincident with visible germination. During this period, the percentage of germination and embryo pH were closely linked irrespective of the dormancy-breaking compound used. Therefore, tissue acidification during the breaking of seed dormancy and the germination process may be analogous to similar tissue pH changes associated with the termination of developmental arrest in other multicellular systems, such as brine shrimp cysts and nematode larvae.     

Metabolism of Inositol Phosphates: I. Phytase Synthesis during Germination in Cotyledons of Mung Beans, Phaseolus aureus

The degradation of phytin in germinating mung bean seeds has been found to be associated with the increased activity of phytase in the cotyledon. In the differentiated embryo the increase of this activity is very low all throughout the growth periods studied. Phytase appears in the cotyledon during germination. No activity has been detected in the cotyledons of unsoaked seeds. Cycloheximide (10⁻⁶ M) inhibits the appearance of phytase by 61% during 24 and 48 hours after the start of germination. This phytase increase is dependent on the synthesis of new RNA in the cotyledon. Synthesis of DNA is not detected in the cotyledon during germination.     

Nucleic Acid Metabolism in Germinating Onion: I. Changes in Root Tip Nucleic Acid during Germination

Nucleic acid synthesis in the G₁ cell population of the 1-millimeter apex of the Allium cepa embryo was studied during the initial 73 hours of germination. Quantitative data indicate that the total amount of RNA per cell began to increase after 18 hours of germination while the initial DNA per cell increase did not occur until some 20 hours later. Polyacrylamide gel electrophoresis patterns of ³H-uridine-labeled total nucleic acid samples indicated that synthesis of all detectable RNA fractions present in the pre-emergent 1-millimeter apex (i.e., cytoplasmic and “chloroplast-like” RNA) began at approximately the same time (18 hours). Synthesis of the various cytoplasmic RNA fractions continued throughout the germination period. Data indicating synthesis of the “chloroplast-like” RNA were obtained only for the initial 36 hours of germination. Specific radioactivity of ³H-uridine-labeled total nucleic acid increased during the first 41.5 hours of germination but then decreased while the accumulation of RNA per cell continued to increase throughout the 73-hour period. In addition, a method is described which reduced the bacterial contamination of Allium seed to a level not detectable by incorporation of radioactive precursors into bacterial ribosomal RNA.