Ribonucleic acid synthesis in vitro in primary spermatocytes isolated from rat testis

The incorporation of [(3)H]uridine into RNA was studied quantitatively (by incorporation of [(3)H]uridine into acid-precipitable material) and qualitatively (by phenol extraction and electrophoretic separation of RNA in polyacrylamide gels) in preparations enriched in primary spermatocytes, obtained from testes of rats 26 or 32 days old. The rate of incorporation of [(3)H]uridine into RNA of isolated spermatocytes was constant during the first 8h of incubation, after which it decreased, but the decreased rate of incorporation was not reflected in a marked change in electrophoretic profiles of labelled RNA. In isolated spermatocytes, [(3)H]uridine was incorporated mainly into heterogeneous RNA with a low electrophoretic mobility. Most of this RNA was labile, as shown when further RNA synthesis was inhibited with actinomycin D. Spermatocytes in vivo also synthesized heterogeneous RNA with a low electrophoretic mobility. A low rate of incorporation of [(3)H]uridine into rRNA of isolated spermatocytes was observed. The cleavage of 32S precursor rRNA to 28S rRNA was probably retarded in spermatocytes in vitro as well as in vivo. RNA synthesis by preparations enriched in early spermatids or Sertoli cells was qualitatatively different from RNA synthesis by the spermatocyte preparations. It is concluded that isolated primary spermatocytes maintain a specific pattern of RNA synthesis, which resembles RNA synthesis in spermatocytes in vivo. Therefore isolated spermatocytes of the rat can be used for studying the possible regulation of RNA synthesis during the meiotic prophase.     

DNA and RNA Syntheses by Intraerythrocytic Stages of Plasmodium knowlesi*

Incorporation of the nucleic acid precursors, orotic acid, adenosine, thymidine, and uridine, was studied in various stages of intraerythrocytic Plasmodium knowlesi from infected rhesus monkeys. Incubation of the parasitized erythrocytes with the precursors was for 3 hr periods using a plasma-free culture medium. The samples containing primarily rings, early trophozoites, or late trophozoites incorporated orotic acid, adenosine, and uridine into RNA; however, these stages exhibited negligible or very low levels of incorporation of any of the precursors into DNA. The sample containing late trophozoite and schizont stages incorporated orotic acid, adenosine, and uridine into RNA, and orotic acid, adenosine, and very low levels of thymidine into DNA. These results indicate that DNA synthesis (the S phase of the cell cycle) occurs very close to the time of nuclear division, and that either the G1 or G2 phase is very short in P. knowlesi. It was also observed that adenosine and orotic acid, 2 precursors which are incorporated into both DNA and RNA, are utilized differently by the intraerythrocytic parasites. Incorporation of orotic acid into RNA and DNA and adenosine incorporation into DNA were continuous for the entire incubation period, whereas incorporation of adenosine into RNA was very low during the last 2 hr of each period. It was further demonstrated that the parasites utilized exogenous uridine for synthesis of RNA, and that the older parasite stages incorporated thymidine into DNA.     

Autoradiographic study of protein and RNA formation during early development of Drosophila eggs

Permeabilized eggs of Drosophila melanogaster were incubated in tritiated uridine, valine, and phenylalanine. The uptake and incorporation into TCA-insoluble material were measured by scintillation counting. There was very little incorporation of uridine before the blastoderm stage. At the blastoderm stage, the egg took up 2.4 pmoles/hr of uridine and incorporated 0.13 pmoles into RNA (assuming no dilution of specific activity of the precursor). The uptake of amino acids varied with the age of the embryo; virgin eggs synthesized about as much protein as fertilized eggs. Autoradiography of eggs incubated in uridine showed a lack of RNA synthesis in nuclei until the start of the blastoderm formation. The small amount of uridine incorporation before this stage was due to mitochondria. Incorporation of amino acids was uniform in the cytoplasm until the blastoderm; there was no incorporation by yolk granules. Regional difference in labeling appeared during gastrulation. The pole cells did not form RNA during the blastoderm stage, formation started during gastrulation. Protein labeling of the pole cells, on the contrary, was very strong in the blastoderm and early gastrula. These results indicate that the expression of zygotic genome before the blastoderm stage is unlikely.     

Synthesis of ribonucleic acid in normal bone in vitro

1. The incorporation of [2-(14)C]uridine into nucleic acids of bone cells was studied in rat and pig trabecular-bone fragments surviving in vitro. 2. The rapid uptake of uridine into trichloroacetic acid-soluble material, and its subsequent incorporation into a crude nucleic acid fraction of bone or purified RNA extracted from isolated bone cells, was proportional to uridine concentration in the incubation medium over a range 0.5-20.0mum. 3. During continued exposure to radioactive uridine, bulk RNA became labelled in a curvilinear fashion. Radioactivity rapidly entered nuclear RNA, which approached its maximum specific activity by 2hr. of incubation; cytoplasmic RNA, and particularly microsomal RNA, was more slowly labelled. The kinetics of labelling and rapid decline of the nuclear/microsomal specific activity ratio were consistent with a precursor-product relationship. 4. Bulk RNA preparations were resolved by zonal centrifugation in sucrose density gradients into components with approximate sedimentation coefficients 28s, 18s and 4s. 5. Rapidly labelled RNA, predominantly nuclear in location, demonstrated a polydisperse sedimentation pattern that did not conform to the major types of stable cellular RNA. Material of highest specific activity, sedimenting in the 4-18s region and insoluble in 10% (w/v) sodium chloride, rapidly achieved its maximum activity during continued exposure to radioactive precursor and decayed equally rapidly during ;chase' incubation, exhibiting an average half-life of 4.3hr. 6. Ribosomal 28s and 18s RNA were of lower specific activity, which increased linearly for at least 6hr. in the continued presence of radioactive uridine. There was persistent but variable incorporation into ribosomal RNA during ;chase' incubation despite rapid decline in total radioactivity of the acid-soluble pool containing RNA precursors.     

EFFECTS OF HYPOPHYSECTOMY ON RNA METABOLISM IN RAT BRAIN STEM

Abstract— Ribosomal aggregates were isolated from rat brain stem and characterized as polysomes by sedimentation analysis and by their sensitivity to RNase and EDTA treatment.
Three weeks following hypophysectomy there was a significant decrease in the content of large polysomes in the rat brain stem. The incorporation of radioactive uridine into RNA was studied using a double-labelling technique with [³H]- and [¹⁴C]uridine and labelling periods of 70 and 180 min. It was found that after hypophysectomy the incorporation of radioactive uridine into total, nuclear and cytoplasmic RNA and in polysomes was decreased after 70 and 180 min. Information on the nature of the rapidly-labelled RNA in the various subcellular fractions was obtained by sucrose gradient sedimentation analysis.
After 70 min of labelling the nucleus contained heterogeneous RNA with a considerable fraction of RNA sedimenting faster than 28 S. In the cytoplasmic fraction heterogeneous 4 to 30 S RNA was found, presumably associated with RNP particles, whereas after 180 min the polyribosomal aggregates were also labelled.
The present results indicate a profound effect of hypophysectomy on the metabolism of all species of brain RNA investigated.     

Incorporation of different labelled precursors into chloroplast RNA of Chlorella

Summary Radioactive uridine is incorporated by Chlorella strain 211-8b/p into ribosomal subunits and their rapidly labelled RNA comigrates with chloroplast RNA on polycrylamide gels.Ribosomal particles which can be labelled by short pulses of orotic acid cosediment with the particles labelled by uridine pulses and contain the same RNA species as these when separated either on sucrose gradients or on polycrylamide gels. This incorporation is, like that of uridine, sensitive to rifampin and chloramphenicol, but insensitive to cycloheximide.A comparative study of short-time incorporation of uridine, orotic acid and guanosine into the RNA of Chlorella showed that all three precursors were incorporated mainly into RNA of chloroplastic origin. However, guanosine was also partly incorporated into cytoplasmic rRNA. Nitrogen-deficient cells always incorporated part of all three precursors into cytoplasmic rRNA, but the proportions of these were different among the different precursors.These results are consistent with the hypothesis that the described differences in the incorporation of the above mentioned precursors into RNA of different cellular compartments are largely attributable to effects of pool sizes.     

Effect of hypoxia on nucleic acid and protein synthesis in different brain regions

The incorporation of [methyl-³H]thymidine into DNA, of [5-³H]uridine into RNA, and of [1-¹⁴C]leucine into proteins of cerebral hemispheres, cerebellum, and brainstem of guinea pigs after 80 hr of hypoxic treatment was measured. Both in vivo (intraventricular administration of labeled precursors) and in vitro (tissue slices incubation) experiments were performed. The labeling of macromolecules extracted from the various subcellular fractions of the above-mentioned brain regions was also determined. After hypoxic treatment the incorporation of the labeled precursors into DNA, RNA, and proteins was impaired to a different extent in the three brain regions and in the various subcellular fractions examined; DNA and RNA labeling in cerebellar mitochondria and protein labeling in microsomes of the three brain regions examined were particularly affected.     

Der Einfluß von Rifampicin,Chloramphenicol und Cycloheximid auf den Uridin-Einbau in chloroplastidäre Ribosomenvorstufen von Chlorella

Summary The unicellular green alga Chlorella incorporates labeled uridine mainly into the precursors of chloroplast ribosomes. After treatment with rifampicin for 60 min, the uridine incorporation into the particles is completely inhibited. Chloramphenicol treatment results in the same complete inhibition. In constrast, cycloheximide (actidione) slightly stimulates the incorporation of uridine into the chloroplast ribosome precursors.Short-time incorporation of inorganic phosphate into the ribosome fractions is nearly unaffected by rifampicin and chloramphenicol, but it is strongly inhibited by cycloheximide.Isolation and chromatographic separation of nucleic acids after treatment of cells with rifampicin shows that uridine incorporation into RNA is completely inhibited. Chloramphenicol causes only partial inhibition of uridine labeling in the high molecular weight RNA. Here again, cycloheximide stimulates the uridine incorporation.The results indicate that uridine is preferentially incorporated by Chlorella cells into the chloroplast ribosome precursors. Inorganic phosphate is introduced both into cytoplasmic and into chloroplasmic RNA, but because of the quantitative distribution, the cytoplasmic ribosomes are more extensively labeled. Since only inhibitors of bacterial and chloroplasmic RNA-and protein synthesis affect the formation of uridine-labeled ribosomes, this synthesis must take place in the chloroplast itself.

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Abkürzungen DNA Desoxyribonucleinsäure - RNA Ribonucleinsäure - MAK-Säule Säule aus methyliertem Albumin mit Kieselgur - Bis-MSB bis-(O-Methylstyryl)-Benzol - PPO 2,5 Diphenyloxazol - Tris Trimethylaminomethan     

Hormonal studies of uridine utilization in an insect cell line CP-1268 derived from the codling moth Laspeyresia pomonella.

Ecdysterone decreased cellular growth and the incorporation of uridine into RNA following 4 days of hormone exposure. This hormone did not affect uridine incorporation following short-term exposure up to 25 hours. Juvenile hormone and farnesol both significantly decreased uridine uptake and incorporation into RNA; however, uridine uptake was inhibited to a greater extent than uridine incorporation. Cyclic AMP increased the incorporation of uridine into RNA but had no demonstrable effect on the uptake process. This stimulation was not the result of cAMP degradation products. Cyclic AMP and ecdysterone together produced a significant increase in uridine incorporation into RNA. These studies demonstrate the potential utilization of insect cell lines for studying the mode of action of insect developmental hormones.     

ANALYSIS OF RNA SYNTHESIZED BY AN ISOLATED RAT BRAIN SYNAPTOSOMAL FRACTION

Abstract— A synaptosomal fraction derived from rat brain, when incubated in an appropriate medium. incorporates [5-³H]uridine into RNA. On the basis of sedimentation analysis, RNA-DNA hybridization and metabolic inhibitor studies, mitochondrial RNA species appear to be the major, if not sole, RNA products synthesized by the isolated synaptosomal fraction. Electronmicroscope autoradiographic analysis showed that about 50% of the incorporation of [5-³H]uridine into RNA by this fraction occurs in the presynaptic endings. The capacity of mitochondrial RNA synthesis in isolated nerve endings declines as the age of the animal increases from 10 to 30 days, and by 60 days of age discrete mitochondrial RNA species are barely detectable.     

Labeling of RNA in young and adult rat brain: Evidence for different RNA processing

The labeling of RNA in young and adult rat brain has been studied by measuring in vitro (tissue slices incubation) the incorporation of labeled uridine into RNA of total tissue and of the various subcellular fractions purified from cerebral hemispheres of 1- and 10-month-old rats. Gel electrophoretic analysis of the newly synthesized nuclear and microsomal RNA was also accomplished. An active metabolism of RNA in adult animals was found; moreover, distinct differences in ribosomal RNA processing in cerebral hemispheres of 1- and 10-month-old rats, with a more rapid processing in the brain of adult animals, were obtained.     

Age related changes in total DNA and RNA and incorporation of uridine and thymidine in rat brain

1. Total brain DNA and total brain RNA and the incorporation of thymidine[14C] and uridine[3H] were measured in young and aged rats. 2. From 20 days to the time of sexual maturation, both DNA and RNA levels increase. Total RNA exceeds total DNA at all ages. Comparatively, the ratio of total DNA/RNA is higher in young than in aged animals. 3. The incorporation of thymidine[14C]/g of DNA and of uridine[3H]/g of RNA decreases with age. This decrease is rapid in young animals. After 350 days of age, the incorporation becomes very low. The significance of data is discussed.     

Hormonal studies of uridine utilization in an insect cell line CP-1268 derived from the codling mothLaspeyresia pomonella

Summary Ecdysterone decreased cellular growth and the incorporation of uridine into RNA following 4 days of hormone exposure. This hormone did not affect uridine incorporation following short-term exposure up to 25 hours. Juvenile hormone and farnesol both significantly decreased uridine uptake and incorporation into RNA; however, uridine uptake was inhibited to a greater extent than uridine incorporation. Cyclic AMP increased the incorporation of uridine into RNA but had no demonstrable effect on the uptake process. This stimulation was not the result of cAMP degradation products. Cyclic AMP and ecdysterone together produced a significant increase in urdine incorporation into RNA. These studies demonstrate the potential utilization of insect cell lines for studying the mode of action of insect developmental hormones.     

Autoradiographic study of RNA synthesis in isolated cells in culture from chick embryo spinal ganglia

Summary Dissociated cells from 9, 12 and 15 day-old chick embryo spinal ganglia were cultivated in presence of total embryo-extract, brain embryo extract, or total embryo extract supplemented with purified nerve growth factor (NGF). The cells were maintained during 4 days in Maximow assembly and during 1 month in Rose chamber. Neurons showed growth of nerve fibres. The non-neural cells evolved to spindle cells, Schwann cells, or fibroblasts.Ribonucleic acid (RNA) synthesis was followed with tritiated uridine by autoradiography. Some nerve cells showed tritiated uridine incorporation. The highest incorporations for short-term cultures were at 15 hours in presence of NGF, at 48 hours in presence of total or brain extract, and for long-term cultures at 8 days. These periods corresponded to the highest growing activity of the nerve fibres. After 4 days all the non-neural cells incorporated tritiated uridine.The tritiated uridine was first incorporated into the RNA of the nucleus and, afterwards was found also in the cytoplasm. The presence of brain extract or of NGF stimulates the incorporation of labelled uridine into RNA. No labelling was found in the nerve fibres, even after 4 hours incubation.Chargée de Recherche au C.N.R.S.This communication is a part of the Doctorat és-Sciences thesis, presented by Mrs. J. Treska-Ciesielski.With the technical assistance of Mrs. M. F. Knoetgen and A. Bieth.     

The cyclo-oxygenase inhibitors indomethacin and ibuprofen inhibit the insulin-induced stimulation of ribosomal RNA synthesis in L6 myoblasts.

Insulin stimulated total RNA accretion and the incorporation of [3H]uridine into RNA in L6 skeletal-muscle myoblasts. Incorporation of uridine into the rRNA was measured after either separation of 18 S and 28 S rRNA species by agarose-gel electrophoresis or separation of dissociated 40 S and 60 S ribosomal subunits on sucrose density gradients. Both methods showed a stimulation by insulin of uridine incorporation into the RNA of the two subunits. Two non-steroidal anti-inflammatory drugs, indomethacin and ibuprofen, which inhibit the metabolism of arachidonic acid by the cyclo-oxygenase pathway, inhibited the insulin-induced accretion of total cellular RNA and the incorporation of uridine into the RNA of both ribosomal subunits. The effect of insulin was observed both by using a tracer dose of [3H]uridine (5 microM) and in the presence of a high concentration (1 mM) of uridine to minimize possible changes in intracellular precursor pools. Neither insulin nor indomethacin was found to affect the incorporation of uridine into the total intracellular nucleotide pool, or the conversion of uridine into UTP. The ability of inhibitors of arachidonic acid metabolism to prevent insulin-induced increases in RNA metabolism suggests that a prostaglandin or other eicosanoid is involved in the signal mechanism whereby insulin stimulates RNA synthesis.     

Uridine transport and RNA synthesis in growing and in density-inhibited animal cells

Both chick embryo fibroblasts and mouse 3T3 cells reduce the rate at which they incorporate H³ uridine into RNA as their growth becomes inhibited at high cell density. This reduction occurs as a function of the cell population density, and with chick embryo cells (in contrast to 3T3 cells) it is not accompanied by significant medium alterations. This indicates the importance of the cell population density in the control of cellular metabolism. The decline in H³ uridine incorporation is paralleled by a decline in the rate of uptake of the isotope into the acid-soluble pool, suggesting that decreased entry of H³ uridine into the cell, rather than a decreased rate of RNA synthesis, is responsible for the reduced rate of incorporation into RNA of density-inhibited cells. This suggestion was confirmed by finding that when the restriction on uridine uptake was overcome by increasing the concentration of uridine in the medium, the density-dependent inhibition of uridine incorporation was largely reversed. We conclude that, even though the rate of H³ uridine incorporation into RNA is reduced three- to five-fold in density-inhibited cells, the rate of synthesis of pulse-labeled RNA continues at 70 to 85% of the rapidly-growing rate.     

Differences in the synthesis of total and poly(A)+RNA in the Kennebec potato and its dihaploid

RNA synthesis as measured by the incorporation of tritiated uridine into trichloroacetic acid insoluble material was studied in the leaf protoplasts of cv. Kennebec and its parthenogenically derived dihaploid. Protoplasts of cv. Kennebec incorporated tritiated uridine at a greater rate and accumulated more than twice the amount of radioactive materials than did the dihaploid over a 6-h incubation period. Poly(A)⁺RNA, isolated from the total RNA of the tetraploid and of the dihaploid, by oligo(dT)-cellulose column chromatography, was present in amounts of 11.3 and 5.2 % respectively. The tetraploid synthesized 4.8 times the amount of poly(A)⁺RNA that was synthesized by the dihaploid.     

Exogenous nucleosides stimulate RNA synthesis in resting cells of a culture of scarlet rose

RNA synthesis in response to exogenous nucleoside precursors was studied in a suspension culture of rose cells. Exponentially growing and resting cells were prelabeled with [3H] uridine, an excess of unlabeled uridine added, and subsequent isotopic incorporation into nuclear and ribosomal fractions measured. The data were compared to control values in cells continuously labeled in the absence of unlabeled uridine. Addition of uridine to the growing culture reduced the further uptake, and incorporation of [3H] uridine into RNA. In contrast, in resting cells, the addition of uridine (or, purine nucleosides) enhanced the apparent utilization of [3H] uridine in RNA synthesis by 2- to 4-fold.     

Pyrimidine biosynthesis and its regulation in the developing rat brain.

—Measurements of the incorporation of [¹⁴C]NaHCO₃ into orotic acid, uridine nucleotides and RNA in tissue minces establish the occurrence of the complete orotate pathway for the de novo biosynthesis of pyrimidines in rat brain. Selective inhibition of the incorporation of various radiolabelled precursors into orotic acid by uridine demonstrates the operation of a feedback control mechanism in brain minces and indicates carbamoylphosphate synthetase to be the site of inhibition; purine nucleosides were similarly found to inhibit the de novo biosynthesis of pyrimidines. The activity of the orotate pathway, as assessed by the rate of incorporation of [¹⁴C]NaHCO₃ into orotic acid, was found to be very high in fetal brain and to decline rapidly with neurological development; the mature rat brain exhibits less than 1% of the activity of the fetal brain at 18 days of gestation. Comparative studies on the ability of minces of the brain and several extraneural tissues to utilize [¹⁴C]NaHCO₃ and [¹⁴C]aspartate as precursors of orotic acid lead us to speculate that variations in the ability of tissues to synthesize orotic acid de novo are determined by similar variations in their ability to synthesize carbamoylphosphate.     

Enhancement of RNA labeling in iris and lens by wounding cornea

Lentectomy of the newt eye leads to formation of the lens from the iris. The initial event which occurs in the iris after lentectomy is enhancement of uridine incorporation into RNA. The present data demonstrate that surgery on the cornea without lentectomy enhances uridine incorporation into iris RNA. However, the profile of incorporation after cornea surgery is different from that after lentectomy. Furthermore, cornea surgery fails to cause the high level of incorporation of thymidine into iris which occurs after lentectomy. Cornea surgery also causes enhancement of uridine incorporation into lens RNA with a profile different from that in iris RNA.