Transcription of Ribosomal and Messenger RNAs in Early Wheat Embryo Germination

Germinating wheat embryos (Triticum aestivum L). synthesize both ribosomal and messenger RNA at the earliest times after the onset of germination. The rates of synthesis of these two RNAs are determined at various stages in germination by an analysis of newly synthesized radioactive RNA on oligo(dT)-cellulose. The rate of messenger RNA synthesis is essentially constant throughout 18 hours of germination, while that of ribosomal RNA synthesis increases steadily, particularly after the onset of cell expansion (6 hours), reaching at 16 to 18 hours, a rate of synthesis between 5- and 20-fold greater than that observed at the earliest stages. The net effect is a relative decrease in the fraction of transcribed high molecular weight RNA that is mRNA. Throughout the first 7 hours of germination, mRNA is 25 to 30% of the transcribed fraction, whereas by 16 to 18 hours it has declined to a level of 4 to 8%.     

Biochemical and Cytological Analyses of RNA Synthesis in Kinetin-treated Pea Root Parenchyma

Excised cortical parenchyma from the pea root (cv. Little Marvel) responds to kinetin/auxin treatment with an increased rate of RNA synthesis well before reinitiating DNA synthesis. Few cells synthesize RNA in the 1st hour of culture. In the presence of kinetin/auxin, the nuclear labeling index increases 2.5-fold as compared to control cultures. The RNA synthesis response has an apparent lag period of 2-4 hours as shown by double label ([³H]adenosine/[¹⁴C]adenosine) experiments. Qualitatively, the RNA synthesized at 4-6 hours sediments between 18S and 5S. The RNA synthesized at 14-16 hours and 24-26 hours is primarily ribosomal RNA when kinetin is present. In the absence of kinetin, no clear pattern of RNA synthesis emerges.     

Nucleic acid and protein synthesis and loss of vigour in germinating wheat embryos

A study has been made of the RNA and protein synthesising systems of wheat embryos isolated from seed lots having high viability but differing in vigour. The rate of RNA and protein synthesis in wheat embryos during the early hours of germination is related to the vigour of the seed lot. The imposition of a stress factor, in the nature of a sub-optimal germination temperature, during germination of isolated wheat embryos magnifies the differences in rates of protein and RNA synthesis between high and low vigour seed. Using cell-free protein synthesising systems it has been demonstrated that an important difference between high and low vigour embryos lies in the relative levels of messenger RNA in the embryo. High vigour embryos contain relatively higher levels of poly A⁺-RNA (i.e. potential mRNA species) than lower vigour embryos and furthermore the level of poly A⁺-RNA in high vigour embryos increases during early germination whilst in lower vigour embryos the level decreases. The difference in poly A⁺-RNA levels accounts, at least partially, for the differences in rates of protein synthesis observed between embryos from high and low vigour wheat seed during early germination at both optimal and sub-optimal germination temperatures.Abbreviations HEPES N-2-hydroxyethylpiperazine-N-2-ethane sulfonic acid - poly A⁺-RNA polyadenylated RNA - GM germination medium - PMS post-mitochondrial supernatant fraction     

Modulation of protein synthesis during the growth cycle of a culture of scarlet rose.

Dilution of a stationary phase culture of Scarlet Rose results in an increased rate of protein synthesis. This study compares the time course of this increase with the changes in polyribosome content and the levels of adenine and guanine nucleotides. During the first two hours after dilution, protein synthesis increases 2- to 3-fold; much of the large monoribosome pool that characterizes the stationary state disappears and a steady state situation is reached in which 70% of the ribosomes are in polyribosomes. Between two and eight hours, there is no further change in polyribosome content although the rate of protein synthesis increases an additional 2- to 3-fold. During this initial 8-hour period there is little change in the levels of ATP and GTP. An explanation consistent with these observations is that the initial activation (within the first 2 hours), characterized by the monoribosome to polysome transition, is at the level of a component(s) of the initiation system, and that between two and eight hours, since neither mRNA availability nor energy level are primary determinants, protein synthesis is augmented by the activation of a translational component, perhaps an elongation factor. After 24 hours, there is a proliferative phase characterized by the onset of ribosome accumulation. By day 5, maximum ribosome levels, 5-fold that of 24-hour cells, are reached, but the rate of protein synthesis increases only 2.5-fold during this period. The lack of quantitative coincidence between the changes in polyribosome content and the rates of protein synthesis again suggests that factors other than mRNA availability are involved in determining the overall rate of protein synthesis. Finally at days 6–8, while the growth of the culture is still in the exponential phase, the rate of protein synthesis per unit fresh weight drops markedly concomitant with a decline in ribosome content. At days 11–12, the monoribosome to polysome ratio begins to change with the monoribosome pool increasing. Presence of either actinomycin D or cordycepin inhibits increased protein synthesis in direct relation to the ability of these compounds to inhibit RNA synthesis. This suggests that the protein synthetic processes occurring after dilution require either the synthesis of the mRNA that is being translated or of an RNA functioning in a closely linked reaction.     

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.     

De Novo Biosynthesis of Deoxyribonucleic Acid Polymerase during Wheat Embryo Germination

An 8-fold enhancement in the activity of a DNA-dependent DNA polymerase was found in extracts from germinating wheat (Triticum vulgare var. Florence) embryos, as compared to the activity found in extracts from ungerminated embryos. The enhancement of this activity during the first hours of germination is concomitant to the increase of a Dnase activity. The two activities could be separated and the increased level of the DNA polymerase upon germination was observed in an enzymatic fraction which contains very low DNase activity. Addition of the protein synthesis inhibitor, blasticidin S, to germinating wheat embryos, reduced the increase in DNA polymerase. Incorporation of radioactive amino acids into a phosphocellulose preparation, which contains the DNA polymerase starts during the first 6 hours of germination. The amount of radioactivity incorporated is doubled in the next 6 hours, and the incorporation is continued between 12 and 18 hours of germination.     

Germination of wheat embryos and the transport of amino acids into a protein synthesis precursor pool

Wheat (Triticum aestivum L. var. Lew) embryonic axes take up externally supplied radioactive amino acid (from a solution greater than 2 millimolar) such that the specific radioactivity of the total internal amino acid rapidly reaches that of the external solution. Nevertheless, incorporation of radioactive amino acid into protein increases steadily as the concentration of external amino acid is increased, indicating that the amino acid that is precursor to protein synthesis is not in equilibrium with the total internal amino acid pool. When the external source of amino acid is removed, incorporation of radiolabeled amino acid into protein continues at a rate comparable to that of embryos maintained in the radioactive solution. In explanation of these data, it is suggested that there are two separate cytoplasmic pools of amino acids, one a protein synthesis precursor pool, and the second, an expandable pool into which exogenous radioactive amino acids are taken up. The protein synthesis pool is fed at a limited rate from the expandable pool and at a far greater rate from an endogenous source. As a consequence, the specific activity of the amino acid that is the precursor for protein synthesis is considerably below that of the total internal pool and is determined by the rate of movement into the protein synthesis pool from the expanded radioactive cytoplasmic pool.

The rate of movement of amino acids from the expandable pool into the protein synthesis pool increases approximately 5-fold during the initial 4.5 hours of embryo germination. When this change is considered in analyzing the relative rates of protein synthesis, there is probably no more than a 2-fold increase in protein synthetic capacity between embryos germinated for 1.5 and 4.5 hours. The leveling off of the change in transport capacity after 4.5 hours suggests that the earlier increase in the rate of this process may be a necessary step before the embryos can begin to accelerate their growth rate.

     

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.     

Fluctuations of DNA-dependent RNA polymerase and synthesis of macromolecules during the growth cycle of Novikoff rat hepatoma cells in suspension culture

The transition of suspension cultures of Novikoff rat hepatoma cells from the exponential to the stationary phase is accompanied by decreases of over 90% in the rates of synthesis of RNA, DNA and protein, a 90% loss of the apparent DNA-dependent RNA polymerase activity of the cells, and a disaggregation of the polyribosomes with a concomitant accumulation of 80 S and 110 S ribosomal structures. The cells also attain a minimum content of DNA, RNA and protein and a minimum size. Upon dilution of stationary phase cultures with fresh medium, the rate of protein synthesis begins to increase immediately and this correlates with a rapid reformation of the polyribosomes. The initial re-formation of polyribosomes is little affected by the presence of actinomycin D. RNA polymerase activity also begins to increase immediately after dilution and an increase in rate of RNA synthesis becomes apparent shortly thereafter. The increase in polymerase activity is inhibited by treating the cells with puromycin or actidione. Cell division commences only 9–13 hours after dilution and the rate of DNA synthesis begins to increase about midway through the lag period. During the lag period the average cellular content of protein increases about 80% and that of RNA and DNA about 30%. These increases are accompanied by a marked increase in the average size of the cells. Upon continued incubation of stationary phase cultures, the cells become irreversibly damaged physiologically before gross morphological damage becomes apparent. The irreversible physiological damage is recognized by the fact that the cells fail to recover when suspended in fresh medium.     

Changes of Template Activity and Proteins of Chromatin during Wheat Germination

Relationships between changes in template activity and composition of chromatin during germination of wheat embyros (Triticum aestivum L.) were investigated. The template activity of chromatin was determined with exogenous DNA-dependent RNA polymerase II (EC 2.7.7.6) prepared from wheat embryos. It was essentially constant for 18 hours of germination, corresponding to 2.5% of that of a native calf thymus DNA. Thereafter, the activity increased 2-fold and 5-fold at 24 and 60 hours of germination, respectively.     

The amounts,subunit structures,and template-engaged activities of RNA polymerases in germinating soybean axes

During the first 24 hr of soybean axis imbibition and growth, there is about a 25-fold increase in RNA polymerase activity associated with isolated nuclei. Within this same period, there is no increase in the amount of RNA polymerase I or II protein in soybean axes. There is no alteration in subunit structure of RNA polymerase II during germination and growth, with the possible exception of conversion of the 215,000 subunit to a 180,000 polypeptide, and no alteration in phosphorylation pattern of RNA polymerase II subunits. These results suggest that the rates of RNA synthesis during imbibition, germination, and growth of soybean axes are not regulated by altering the amount or subunit structure or by posttranslational modification of RNA polymerase II subunits.     

Synthesis of secretory proteins in developing mouse yolk sac

Synthesis of secretory proteins in the developing mouse visceral yolk sac was studied. Newly synthesized proteins were labeled with [³⁵S]methionine and characterized by two-dimensional gel electrophoresis. A large increase in the relative rate of synthesis of a small number of proteins occurred between Days 9.5 and 15.5 of development. These proteins were the predominant proteins synthesized and secreted by the yolk sac throughout this period of gestation. Two of these proteins were identified as α-fetoprotein and transferrin by specific immunoprecipitation. α-Fetoprotein synthesis increased from about 3% of the total protein synthesis at Day 9.5 to about 26% at Day 15.5 after which it declined slightly. The relative rate of transferrin synthesis had a similar developmental pattern, reaching the highest level (5%) at Day 15.5, but declined more rapidly than α-fetoprotein synthesis. Quantitatively, these two proteins represented about 60% of the total secreted protein. Gestational changes in the content of α-fetoprotein messenger RNA were determined by hybridization analysis using α-fetoprotein complementary DNA probe. The percentage of α-fetoprotein messenger RNA in total yolk sac RNA increased about ninefold from Day 9.5 to Day 14.5. This increase correlated well with the increase in the relative rate of α-fetoprotein synthesis during the identical period. This study suggests that after Day 9.5 the yolk sac is completing a differentiation process which is characterized by the preferential expression of a small group of secretory protein genes.     

Conserved pattern of embryonic actin gene expression in several sea urchins and a sand dollar

An examination of the size and relative abundance of actin-coding RNA in embryos of four sea urchins (Strongylocentrotus purpuratus, Strongylocentrotus droebachiensis, Arbacia punctulata, Lytechinus variegatus) and one sand dollar (Echinarachnius parma) reveals a generally conserved program of expression. In each species the relative abundance of these sequences is low in early embryos and begins to rise during late cleavage or blastula stages. In the four sea urchins, actin-coding RNAs increase between approximately 9- and 35-fold by pluteus or an earlier stage, and in the sand dollar about 5.5-fold by blastula. A major actin-coding RNA class of 2.0-2.2 kilobases (kb) is found in each species. A smaller actin-coding RNA class, which accumulates during embryogenesis, is also present in S. purpuratus (1.8 kb), S. droebachiensis (1.9 kb), and A. punctulata (1.6 kb), but apparently absent in L. variegatus and E. parma. In S. droebachiensis, actin-coding RNA is relatively abundant in unfertilized eggs and drops sharply by the 16-cell stage. This is in contrast to the other sea urchins where the actin message content is relatively low in eggs and does not change substantially in the embryos throughout early cleavage. The observations in this study suggest that the pattern of embryonic expression of at least some members of this gene family is ancient and conserved.     

Wheat embryo ribonucleates. XIV. Mass isolation of mRNA from wheat germ and comparison of its translational capacity with that of mRNA from imbibing wheat embryos

Commercially milled wheat germ is shown to be a convenient source material for facile recovery of mass (milligram) quantities of highly purified poly(A)-rich RNA. This poly(A)-rich RNA is efficiently translated in a nuclease-treated extract of rabbit reticulocytes. By sucrose density gradient fractionation of bulk poly(A)-rich RNA from wheat germ, it has been possible to show that there is a direct relationship between the molecular weights of the polypeptide products of cell-free synthesis and the molecular weights of the wheat mRNA molecules which program their synthesis. As assessed by SDS -- polyacrylamide gel electrophoresis, the same array of polypeptides is synthesized when nuclease-treated reticulocyte extract is programmed by poly(A)-rich RNA from either commercially supplied or laboratory-prepared wheat embryos. Significantly, there are gross quantitative if not qualitative differences between the translational capacities of poly(A)-rich RNA from dry and imbibing wheat embryos, and the possible importance of these differences for interpreting a changing pattern of polypeptide synthesis in imbibing wheat embryos is the subject of a brief discussion.     

Gibberellic Acid-enhanced synthesis and release of alpha-amylase and ribonuclease by isolated barley and aleurone layers

Gibberellic acid enhances the synthesis of α-amylase in isolated aleurone layers of barley-seeds (Hordeum vulgare var. Himalaya). In the presence of 20 mm calcium chloride the amount of enzyme obtained from isolated aleurone layers is quantitatively comparable to that of the half-seeds used in earlier studies. After a lag period of 6 to 8 hours enzyme is produced at a linear rate. Gibberellic acid does not merely trigger α-amylase synthesis, but it is continuously required during the period of enzyme formation. Enzyme synthesis is inhibited by inhibitors of protein and RNA synthesis. Small amounts of actinomycin D differentially inhibit enzyme release and enzyme synthesis suggesting 2 distinct processes. Gibberellic acid similarly enhances the formation of ribonuclease which increases linearly over a 48 hour period. During the first 24 hours the enzyme is retained by the aleurone cells and this is followed by a rapid release of ribonuclease during the next 24 hour period. The capacity to release the enzyme is generated between 20 and 28 hours after the addition of the hormone. Ribonuclease formation is inhibited by inhibitors of protein and RNA synthesis. These inhibitors also prevent the formation of the release mechanism if added at the appropriate moment.     

Amino acid uptake and protein synthesis in preimplanatation mouse embryos

Amino acid uptake and cycloheximide inhibitable incorporation into protein are demonstrable in follicular ova, unfertilized eggs, and in mouse embryos ranging from the 1-cell to the late blastocyst stages. The rates of uptake and incorporation are low and relatively constant until the early blastocyst (day 3) stage of development when they increase 3- to 9-fold. The rate of uptake continues to increase during the fourth day (late blastocyst stage) of development, but, despite embryonic growth, incorporation into protein remains constant. By exposing embryos to leucine and lysine at different concentrations, it is possible to dissociate the processes of uptake and incorporation into protein from one another and to use the latter as a measure of protein synthesis. Taking the number of embryonic cells into account, it is postulated that the period between 8- to 16-cell stage (day 2) and the early blastocyst stage is the only one in which the synthesis of major amounts of protein based on new messenger RNA synthesis is occurring.Leucine and lysine uptake take place by a facilitated process, although lysine transport is not readily saturated. Inhibitors of energy metabolism do not significantly affect amino acid uptake, but they do inhibit protein synthesis. However, since the rate of transport is highly temperature sensitive (Q₁₀ ? 3) and leucine is accumulated against a concentration gradient, active amino acid transport appears to be present.     

Rapid Increase in Adenosine 5'-Triphosphate during Early Wheat Embryo Germination

The ATP content of isolated wheat (Triticum aestivum L. var. Polk) embryos increases 5-fold during the first 30 minutes and 10-fold during the first hour of germination to 80% of maximum. The ATP level remains at approximately 800 nanomoles per gram of tissue during the next 15 hours. ADP, AMP, and total adenosine phosphates decrease between 1 and 6.5 hours, while adenylate energy charge increases from 0.6 to 0.8 and remains constant. The rapid increase in ATP during imbibition is consistent with the energy requirement for polyribosome formation and protein synthesis during the first hours of germination. A method for determining nanomole quantities of ATP in tissue extracts by isotopic dilution of γ-³²P-ATP in the hexokinase reaction is outlined.