The Changes of Protein Content and Synthetic Activity in Squash Pollen During Germination

The total protein content of squash (Cucurbita moschata Duch.) pollen decreased gradually during in vitro germination. It was caused by the release of wall proteins and part of the cytoplasmic proteins. The release of the pollen wall proteins was not dependent on germination, it was a passive diffusion process. However, the cytoplasmic proteins did not release until the pollen germinated, a fraction of them was synthesized de novo during germination. The RNA and protein synthetic activities initiated soon after in vitro pollen germination. The RNA synthesis decreased during germination. As about half the activity was inhibited by α-amanitin, mRNA might be the major RNA synthesized de novo. The total protein synthesis increased during germination, almost all of this synthesis was inhibited by cycloheximide, and partially by α-amanitin, but it was not affected significantly by actinomycin D. These results indicated that both stored and de novo synthesized mRNA might play a role in the protein synthesis. The content of stored mRNA of squash pollen was about 11-3 pg/grain as measured by UV absorption after its purification from total RNA (2440 pg/grain) by oligo (dT)-cellulose affinity chromatagraphy. Both cycloheximide and α-amanitin inhibited pollen tube growth in vitro. Actinomycin D and tunicamycin inhibited pollen germination in the first hour, however, no reduction ,of the tube length was observed later. Cyclohex,nide inhibited the pollen germination and tube elongation in vivo, that fitted well with the in vitro results. According to these results, it was suggested that the de novo syntheses of mRNA and protein were neccessary for the maintenance of pollen tube growth.     

Polyadenylic acid-containing of rna in unfertilized and fertilized eggs of the rabbit.

Molecular hybridization between ³H-polyuridylic acid and unlabeled RNA prepared from unfertilized rabbit eggs and 10-h postfertilization stage rabbit embryos has been used to measure the amount and subcellular localization of adenylated maternal RNA. The results reported indicate that there is poly (A)-containing RNA (putative messenger RNA) in unfertilized rabbit eggs. The amount of poly (A) in the RNA in rabbit eggs does not increase immediately after fertilization and is located primarily in the ribosomal fraction of the cell. The rate of protein synthesis in fertilized eggs is insensitive to α-amanitin at concentrations which inhibit RNA synthesis. These results suggest that maternal mRNA makes an important contribution to protein synthesis in early stages of cleavage in the rabbit embryo.     

Control of protein synthesis during blastocyst formation in the mouse.

In order to evaluate the dependence of the embryo on new mRNA synthesis during the period leading to blastulation, quantitative and qualitative aspects of protein synthesis in developing mouse morulae were investigated using α-amanitin, an inhibitor of RNA polymerase II. Only 1 of 423 early morulae cultured for 27 hr in the presence of 11 μg/ml α-amanitin cavitated, although most progressed as far as fully compacted morulae. About two-thirds of the untreated embryos cavitated during the same period. Incorporation of [³⁵S]methionine into protein was measured at 3- or 4-hr intervals over a 24-hr period and showed a two- to fivefold increase in control embryos. This increase was blocked in the α-amanitin-treated group although initial levels of incorporation were maintained. Total uptake of the amino acid appeared to be unaffected by the inhibitor. RNA synthesis, as measured by [³H]uridine incorporation over the same period, was reduced by between 5 and 52%, and the preblastulation surge in RNA synthesis was also blocked by α-amanitin. Two-dimensional polyacrylamide gel electrophoresis of labeled polypeptides synthesized by the embryos after 24-hr incubation in the presence or absence of the inhibitor revealed three distinct classes of polypeptide. The majority of polypeptides continued to be synthesized in the presence of α-amanitin whereas a small number of polypeptides, the synthesis of which would normally have increased during the development of the morula to the blastocyst, were prevented from doing so. A few polypeptides which normally cease to be synthesized over this period continued to be synthesized in the presence of α-amanitin. It is concluded that, while most of the proteins detectable at the morula stage are synthesized on mRNA templates of relatively long translational life, the general surge in protein synthesis, including the increased synthesis of a few species of polypeptide, are dependent on continuous translational activity.     

Synthesis of messenger and ribosomal RNA precursors in isolated nuclei of the cellular slime mold Dictyostelium discoideum

When incubated with all four ribonucleoside triphosphates, isolated nuclei of the cellular slime mold, Dictyostelium discoideum, will synthesize RNA linearly for 10 to 50 minutes, depending on the salt concentration of the reaction. A fraction (10 to 30%) of the RNA labeled in isolated nuclei binds to immobilized polyuridylic acid. By the following criteria this RNA species is identical to the messenger RNA precursor characterized in whole cells: (a) both contain polyadenylic acid sequences of identical size; (b) they have the same base composition; (c) they have the same mean size as determined by dimethylsulfoxide—sucrose centrifugation; (d) they renature to excess nuclear DNA with similar kinetics; and (e) synthesis of both RNAs is resistant to 2 to 3 μg of actinomycin D/ml. Two independent RNA polymerase activities appear to synthesize poly(A)-containing RNA in isolated nuclei. One is equally active at 0.01 m-KCl and 0.25 m-KCl and is resistant to α-amanitin; the other is considerably more active at the higher salt concentration and is sensitive to α-amanitin. By the criteria of sedimentation coefficients, base composition and sensitivity of synthesis to actinomycin D, the remainder (70 to 90%) of the RNA synthesized by isolated nuclei was identical to cellular ribosomal RNA or its precursors.     

STUDIES ON RNA SYNTHESIS IN TWO POPULATIONS OF NUCLEI FROM THE MAMMALIAN CEREBRAL CORTEX

A method is presented for the rapid separation of cell nuclei from the rabbit cerebral cortex into two populations. The first of these consists largely of nuclei with the morphological characteristics of neuronal nuclei, the second almost entirely of nuclei with the morphological characteristics of glial cell nuclei. From studies based upon sensitivity to the toxin α-amanitin, the ratio of incorporation of different bases, ionic requirements and differential sensitivity to actinomycin D, it is concluded that under both the classical low and high salt conditions described by other workers, two enzymes are active in RNA synthesis. The presence of a third enzyme of low activity cannot be excluded. No qualitative difference in the number of enzymes involved in RNA synthesis in neuronal and glial cell nuclei has been found, but there are quantitative differences in activity between the two nuclear populations.     

Specific interference of metalaxyl with endogenous RNA polymerase activity in isolated nuclei fromPhytophthora megasperma f. sp.medicaginis

The systemic fungicide metalaxyl preferentially inhibits [³H]uridine incorporation into RNA by mycelium ofPhytophthora megasperma f. sp.medicaginis. Even at high concentrations of metalaxyl inhibition is not complete but circa 80%. Neither uptake of [³H]uridine nor its conversion into UTP is inhibited, indicating that interference with RNA synthesis takes place. Synthesis of RNA that lacks poly(A) sequences is more affected than that of poly(A)⁺ RNA. Metalaxyl has no effect on the activity of RNA polymerases present in mycelial extracts fromPhytophthora nor on that of polymerases I and II that have been partially purified with a procedure involving precipitation with polyethyleneimine, selective elution of RNA polymerases from the polyethyleneimine precipitate, ammonium sulfate fractionation, and DEAE-Sephadex chromatography. RNA polymerase II in mycelial extracts is half-maximally inhibited by α-amanitin at concentrations below 0.01 ¼g/ml. Both metalaxyl and α-amanitin inhibit endogenous RNA polymerase activity of isolated nuclei ofPhytophthora. According to their sensitivity to metalaxyl and α-amanitin, three types of endogenous activity can be distinguished: (a) an α-amanitin-sensitive type, the activity of which is stimulated by ammonium sulfate; (b) an α-amanitin-insensitive but metalaxyl-sensitive type; and (c) a type insensitive to both metalaxyl andα-amanitin. The first type of activity is characteristic of RNA polymerase II; the identity of the latter two remains to be elucidated. Metalaxyl andα-amanitin do not have any effect on free nuclear polymerases when assayed at a concentration of 50 mM ammonium sulfate with poly[d(A-T)] as exogeneously added template in the presence of actinomycin D to inhibit endogenous RNA polymerase activity. At 250 mM ammonium sulfate the free polymerase activity becomes α-amanitin sensitive but remains metalaxyl insensitive. Metalaxyl apparently inhibits RNA synthesis by specific interference with template-bound andα-amanitin-insensitive RNA polymerase activity. Endogenous polymerase activity of nuclei isolated from a metalaxyl-resistant mutant ofP. megasperma f. sp.medicaginis is not inhibited by metalaxyl, indicating that interference with RNA synthesis is the primary action of metalaxyl and that modification of the target site may lead to resistance.     

Nucleo-cytoplasmic protein migration during the activation of chick erythrocyte nuclei in heterokaryons

The reactivation of the chick erythrocyte nucleus was studied after erythrocytes were induced to fuse with rat epithelial cells in the presence of Sendai virus. The chick nucleus swells, shows an increase in dry mass and protein content and resumes RNA synthesis. Nucleoplasmic antigens characteristic of the rat cell are found to migrate into the erythrocyte nucleus. The rate of uptake of these molecules, which are believed to be proteins, appears to be directly related to increases in nuclear size, ³H-uridine incorporation and RNA polymerase activity. The polymerase activity which increases during the first days after cell fusion is sensitive to α-amanitin but relatively resistant to actinomycin D. At later time points there is an increase in α-amanitin resistant polymerase activity which probably reflects the appearance of ribosomal RNA synthesis.When heterokaryons containing different proportions of rat: chick nuclei are compared, reactivation is found to proceed most rapidly in those containing a high rat: chick nuclear ratio. As the number of erythrocyte nuclei in heterokaryons increases, the rate of reactivation in the individual nuclei is progressively reduced suggesting that the erythrocyte nuclei compete with each other for macromolecules of specific importance for the activation process.     

RNA biosynthesis in adipose tissue: effect of fasting

RNA metabolism has been examined in intact adipose tissue and isolated fat cells from rats. The lipocyte contains three species of RNA with sedimentation rates corresponding to those of ribosomal and transfer RNA. The de novo biosynthesis of RNA by adipose tissue cells in vitro was demonstrated. The base ratios of the RNA formed indicate that it was synthesized from a DNA template. Actinomycin D administered in vivo and in vitro decreased total RNA synthesis with the most marked effect on the synthesis of the heavy RNA components. Actinomycin D or puromycin added in vitro was not toxic: they did not inhibit total fatty acid biosynthesis or glucose utilization by the fat pad nor did they inhibit the immediate stimulation of fatty acid biosynthesis and glucose uptake by the addition of insulin in vitro. Starvation for 48-72 hr significantly depressed the synthesis of the heavy RNA components as measured by in vitro uridine incorporation into the individual RNA classes. Refeeding the fasted rat with glucose repaired the defect in RNA biosynthesis before the biosynthesis of monoenoic fatty acid was completely restored. Actinomycin D administered at the time of refeeding prevented the repair of monoenoic fatty acid synthesis. It is concluded that RNA metabolism is intimately involved in the control of biosynthetic reactions in adipose tissue.     

PHYLOGENETIC ANALYSIS OF BREEDING SITE USE AND α-AMANITIN TOLERANCE WITHIN THE DROSOPHILA QUINARIA SPECIES GROUP

The Drosophila quinaria group is unusual within the genus in that it comprises both mycophagous and nonmycophagous species. DNA sequence data from three regions of the mitochondrial genome were used to infer relationships among four mycophagous species and three that breed on decaying water plants. Phylogenetic analysis of these species show that breeding in mushrooms and tolerance of high levels of α-amanitin were the ancestral states within the group. Thus, breeding in decaying water plants and intolerance of α-amanitin are derived conditions. We also found that the D. quinaria species group does not comprise separate mycophagous and nonmycophagous clades, but rather that (1) the shift from mushrooms to decaying plants occurred on at least two occasions; or (2) mycophagy reevolved within a lineage that had previously shifted to breeding on plants. The correlation between mycophagy and α-amanitin tolerance is perfect across the species we have examined, indicating that there is no detectable time lag between an ecological shift to a new breeding site and correlated changes in biochemical adaptation. The genetic distance between the mycophagous D. recens and the nonmycophagous D. quinaria indicates that these species split only about 1 M.Y.B.P. In terms of α-amanitin tolerance, D. recens and D. quinaria are typical of other ecologically similar species within the group. Thus, evolutionary changes in α-amanitin tolerance can evidently occur on the order of about 1 million yr. Our data also indicate that, in comparison to other groups of Drosophila, the quinaria species group may be undergoing an adaptive radiation.     

Studies on Phytoalexins: The Relationship between Actinomycin D and Ribonucleic Acid Synthesis during the Induction of Phaseollin in the French Bean (Phaseolus vulgaris L.)

Actinomycin D stimulated phaseollin production in endocarp tissues of the French bean (Phaseolus vulgaris L.), maximum production being obtained with 25 to 30 micrograms per milliliter of antibiotic. Under these conditions, net incorporation of ³H-uridine into total cell ribonucleic acid was inhibited by more than 80% over a 6-hour induction period. If allowance was made for a 2-hour lag in the action of actinomycin D, inhibition of incorporation was greater than 95%. Contrary to other reports, no evidence was obtained of an increased formation of any specific ribonucleic acid fraction. Actinomycin D applied in the cold (4 C) was not found to be effective in stimulating phaseollin production. When applied in this way, actinomycin D did not affect induction of phaseollin by a fungal peptide, Monilicolin A, although ribonucleic acid synthesis was inhibited by more than 95%. It is suggested that the induced formation of phytoalexins may not be dependent on increased ribonucleic acid synthesis as has previously been claimed.     

RNA synthesis in the presence of transfer RNa by DNA-dependent RNA polymerase II from mouse ascites sarcoma cells

RNA polymerase II from mouse sarcoma cells catalyzed the incorporation of UMP into an acid-insoluble fraction in the presence of tRNA. This reaction was not affected by DNase or actinomycin D but was inhibited by α-amanitin. This reaction was dependent on nucleoside triphosphate and manganese ions. RNA synthesized in the presence of tRNA could be digested with RNase A. These results suggest that the RNA synthesis by RNA polymerase II from mouse sarcoma is dependent on the presence of tRNA.     

Variations in the amounts of RNA polymerase forms I, II and III during preimplantation development in the mouse.

DNA-dependent RNA polymerase has been measured at various stages of preimplantation development in mouse embryos. The total RNA polymerase activity per embryo increases rapidly from the 8-cell stage to the blastocyst stage. Studies with low α-amanitin concentrations, which inhibit form II RNA polymerase, and high α-amanitin concentrations, which inhibit both form II and III RNA polymerases indicate that the relative proportions of the three forms change significantly during preimplantation development. The changes which occur in the types and levels of RNA polymerase appear to parallel corresponding changes in the synthesis of the major classes of RNA.     

The effects of aphidicolin and α-amanitin on DNA synthesis in preimplantation mouse embryos

The effects of aphidicolin and α-amanitin on DNA synthesis by preimplantation mouse embryos were studied. It was found that both blastocyst and 8-cell embryos showed marked inhibition of ³H-thymidine incorporation into DNA by aphidicolin at concentrations of 20–50 μg/ml. However, aphidicolin did not inhibit the conversion of morula embryos to blastocyst embryos, although aphidicolin-treated blastocysts lost their blastocoel and collapsed into a compact form after prolonged exposure to the drug. Both 8-cell and blastocyst embryos were found to be susceptible to inhibition of DNA synthesis by α-amanitin.