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.     

Reduction of endogenous nucleic acid in a single-cell protein.

Two compounds showing self-inhibitory action during germination of aeciospores of the comandra blister rust fungus (Cronartium comandrae Pk.) were extracted from these aeciospores by shaking with 0.2 M NH₄HCO₃ (pH 7.8) for 4 h. One of these, the germination self inhibitor (D. A. Eppstein and F. H. Tainter, Phytopathology 66:1395-1397, 1976), was removed from the ammonium bicarbonate buffer by using chloroform. The water layer which remained contained a substance which, at ca. 10⁻⁴ M concentration, had no apparent effect on germ tube emergence but which inhibited normal germ tube growth. Linear germ tube growth ceased or a dendritic or vesicular pattern of growth resulted, depending on the concentration of inhibitor added to extracted germinating spores. The germ tube growth inhibitor appears to be a peptide with a molecular weight of ca. 2,000.     

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.     

Factors involved in the expression of gene activity in polytene chromosomes

In order to separate some of the factors involved in the formation of puffs the antibiotic actinomycin D was applied at different stages of puff activity. Puffs were induced by temperature shocks or eodysone.Inhibition of RNA synthesis with actinomycin D before application of a puff inducing stimulus prevents neither the appearance of the stimulus specific puffs nor the accumulation of acidic proteins in the puff regions. The puffs attained under these conditions approximately 1/3 of the size normally produced by the stimulus.Indications were obtained that during puff formation acidic protein accumulation precedes the onset of RNA synthesis.Synthesis and storage of newly synthesized RNA within the puff region was studied on the basis of grain distribution in uridine-H³ autoradiographs after various incubation periods. RNA synthesis appears to be restricted to a particular area of the puff region. After a 3 min temperature shock following injection of uridine-H³ silver grains are located only over a particular area of the newly formed puff. The same area becomes labeled during a 1 min pulse of uridine-H³ applied at a stage of maximum puff development. Longer periods of incubation result in a random distribution of the grains over the whole puff region. Grain counts on different areas of experimentally induced puffs and on the same areas at a stage of puff regression indicate that the newly synthesized RNA becomes transferred from the area where it was synthesized and is stored for a certain period within the puff region. Complete release of newly synthesized RNA from puffs in which RNA synthesis was inhibited by actinomycin D at a stage of maximal activity is accomplished within 30 to 35 min.     

A temporal analysis of the synthesis of the mRNA sequestered in zoospores of Blastocladiella emersonii

To determine when the dormant mRNA of Blastocladiella emersonii zoospores is synthesized, the metabolism of poly(A) RNA and rRNA was studied during growth and sporulation using pulse-chase techniques. Zoospore poly(A) RNA is synthesized at all stages of the growth cycle investigated in cultures grown either on a normal 15-hr growth cycle or in minicyclic cultures induced to sporulate after only 6.5 hr growth. For cells labeled during the growth phase the specific activity of the pulse-labeled poly(A) RNA and rRNA was identical at the beginning and end of sporulation for any of the 2-hr labeling times investigated. From this it was concluded there is neither a preferential conservation nor degradation during sporulation of the poly(A) RNA and rRNA synthesized at various times during growth. Poly(A) RNA synthesized during early sporulation is preferentially degraded; in contrast, poly(A) RNA synthesized during late sporulation is conserved in the zoospore. Approximately one-third of the total zoospore poly(A) RNA accumulates during the final 15–20 min of sporulation. The accumulation rate for both poly(A) RNA and rRNA decreases as sporulation proceeds. In addition, the rate of degradation for both types of RNA decreases at later stages of sporulation.     

Stable Messenger Ribonucleic Acid and Germination of Myxococcus xanthus Microcysts

We have examined germination, protein synthesis and ribonucleic acid (RNA) synthesis by microcysts of the fruiting myxobacterium Myxococcus xanthus. The morphological aspects of microcyst formation were completed at about 2 hr after induction had begun. In such microcysts, germination, RNA synthesis, and protein synthesis were inhibited by actinomycin D (Act D). At 6 hr after induction, germination and protein synthesis had become relatively resistant to Act D, whereas RNA synthesis was inhibited by about 95%. Experiments with (3)H-Act D indicated that the deoxyribonucleic acids of both young and old microcysts bind Act D equally. Resistance of germination to Act D was acquired 4 to 5 hr after induction of microcyst formation, and was due to an Act D-sensitive synthesis at that time. Vegetative cells and microcysts were pulsed with uridine-5-(3)H and chased for 60 min; the RNA was extracted and analyzed by means of sucrose density gradient centrifugation and gel electrophoresis. Both microcysts and vegetative cells were found to contain grossly the same types of RNA in the same proportions. RNA pulse-labeled in microcysts was more stable than that in vegetative cells. No particular portions of the microcyst pulse-labeled RNA were selectively stabilized. These data indicate that a stable messenger RNA required for synthesis of germination proteins was synthesized during microcyst formation. This may be the same as the RNA synthesized 4 to 5 hr after initiation of microcyst formation. We suggest that the existence of such stable messenger RNA in microcysts is consistent with the limited biosynthetic activities of such cells.     

Metabolism of polyadenylic acid sequences during germination of blastocladiella emersoni: Zoospores.

The metabolism of the poly(A) sequences isolated from Blastocladiella emersonii was followed during the first hour of germination. Poly (A) sequences synthesized during the first 30 min of germination do not undergo detectable changes in size. During the first 45 min of germination, poly(A) sequences synthesized during zoosporogenesis decrease in size to the extent that there is essentially no size overlap between poly(A) fragments which were present in the zoospore and newly synthesized poly(A) sequences. The results presented indicate that during germination, polyadenylation occurs in RNA molecules which were present in the zoospore but lacked poly(A) sequences. No detectable size differences were observed between poly(A) sequences added to newly synthesized RNA compared to those added to the nonpolyadenylated RNA present in the zoospore during germination. Cycloheximide did not prevent the observed decrease in size of the poly(A) sequences during germination.     

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.     

Macromolecular synthesis accompanying the transition from spores to vegetative forms ofStreptomyces granaticolor

The rates of RNA, protein and DNA synthesis were estimated in synchronously germinating spores ofStreptomyces granaticolor. Rapid uptake of labelled precursors of RNA and proteins was observed after 20 s. The germination process took place through a sequence of time + ordered events. RNA synthesis started after 3 min of germination, protein synthesis began at 4 min and net DNA synthesis at 60–70 min of germination. A characteristic feature of germination was the biphasic pattern in the rate of RNA and protein synthesis. Spores ofStreptomyces granaticolor were sensitive to actinomycin D, rifampicin and chloramphenicol even at the start of germination. Protein synthesis during germination was dependent on new mRNA synthesis and was independent during the first 60–70 min on replication of the spore genome.     

Inhibition of RNA and protein synthesis in pollen tube development of Pinus bungeana by actinomycin D and cycloheximide

* The effects of actinomycin D and cycloheximide on RNA and protein synthesis were investigated during pollen tube development of Pinus bungeana. * RNA and protein contents, protein expression patterns, cell wall components and ultrastructural changes of pollen tubes were studied using spectrophotometry, SDS-PAGE electrophoresis, Fourier transformed infrared (FTIR) microspectroscopy and transmission electron microscopy (TEM). * Pollen grains germinated in the presence of actinomycin D, but tube elongation and RNA synthesis were inhibited. By contrast, cycloheximide inhibited pollen germination and protein synthesis, induced abnormal tube morphology, and retarded the tube growth rate. SDS-PAGE analysis showed that protein expression patterns changed distinctly, with some proteins being specific for each phase. FTIR microspectroscopy established significant changes in the chemical composition of pollen tube walls. TEM analysis revealed the inhibitors caused disintegration of organelles involved in the secretory system. * These results suggested RNA necessary for pollen germination and early tube growth were present already in the pollen grains before germination, while the initiation of germination and the maintenance of pollen tube elongation depended on continuous protein synthesis.     

Identification and cytogenetic localization of vitelline membrane messenger RNAs in Drosophila

During stages 9 and 10 of oogenesis in Drosophila the major proteins involved in vitelline membrane (VM) formation are synthesized and secreted by the somatic follicle cells surrounding the oocyte. To identify potential mRNAs involved in VM protein synthesis, newly synthesized poly(A)-containing RNA from egg chambers of different developmental stages was studied. Urea-agarose gel electrophoresis revealed two RNA bands in stage 10 egg chambers in the size range expected for those which encode the smaller VM proteins. These RNA bands, T₁ and T₂, are specifically enriched in stage 10 follicle cell preparations. In vitro translations in reticulocyte lysates in the absence and presence of microsomal membranes showed both RNA bands code for products that are synthesized in precursor forms which are processed to species that comigrate with VM proteins. T₂ directed the synthesis of processed species that comigrated with the 23- to 24-kDa and 17.5-kDa VM proteins (J. Fargnoli and G. L. Waring, 1982, Dev. Biol. 92, 306–314) while the T₁ translation product comigrated with the 14-kDa protein. To determine the cytogenetic location of the genes encoding T₁ and T₂ RNAs, radiolabeled T₁ and T₂ RNAs were hybridized in situ to salivary gland chromosomes. The results suggest that the structural genes coding for the small vitelline membrane proteins are localized at two sites on the second chromosome: 39DE and 42A.     

Effect of RNA synthesis inhibitors on stimulation of sulfation by L-3,5,3'-triiodothyronine

Stimulation of sulfation by T₃¹ in chick embryo cartilage was blocked when actinomycin D or camptothecin was added to the incubation medium together with the T₃. When either inhibitor was added 2 hr after the T₃, the stimulation was not affected. The results suggest that there is an early step in the action of T₃ that involves synthesis of a stable species of RNA that is larger than 5S. α-Amanitin had no effect on the stimulation of sulfation by T₃, although it inhibited synthesis of poly(A)-rich RNA almost completely. This suggests that the action of T₃ is not associated with increased synthesis of RNA by RNA polymerase II. We conclude that the stimulation of sulfation by T₃ involves synthesis of a species of RNA that is larger than 5S but is not a messenger.