Isolation of ribosomal RNA precursors from Physarum polycephalum

Ribosomal RNA synthesis in Physarum polycephalum was studied by labeling intact microplasmodia with [³H]uridine. Labeled, high-molecular-weight RNA species were found in a 30,000 S structure released by phenol extraction at room temperature. RNA was released from the structure by further phenol extraction at 65–70 °C. If the labeling period was 15 min or longer, the labeled RNA was seen by polyacrylamide gel electrophoresis to be of two major types, a heterodisperse collection of 45-35 S molecules and a 26 S species. If the labeling was carried out for 30 min in the presence of cycloheximide, the major labeled species had an electrophoretic mobility corresponding to 40 S. Studies of the labeling kinetics, methylation, and base composition of these RNA molecules indicate that they are precursors to ribosomal RNA. The molecular weights of the homogeneous 40 and 26 S precursors are 3.0 × 10⁶ and 1.45 × 10⁶ daltons, respectively, in comparison with molecular weights of 1.29 × 10⁶ and 0.68 × 10⁶ daltons for the completed ribosomal RNA's.     

SELECTIVE RELEASE OF CONTENT FROM MICROSOMAL VESICLES WITHOUT MEMBRANE DISASSEMBLY : II. Electrophoretic and Immunological Characterization of Microsomal Subfractions

Rough and smooth microsomes were shown to have similar sets of polypeptide chains except for the proteins of ribosomes bound to the rough endoplasmic reticulum (ER). More than 50 species of polypeptides were detected by acrylamide gel electrophoresis, ranging in molecular weight from 10,000 to approximately 200,000 daltons. The content of rough and smooth microsomes was separated from the membrane vesicles using sublytic concentrations of detergents and differential centrifugation. A specific subset of proteins which consisted of approximately 25 polypeptides was characteristic of the microsomal content. Some of these proteins showed high rates of in vivo incorporation of radioactive leucine or glucosamine, but several others incorporated only low levels of radioactivity within short labeling intervals and appeared to be long-term residents of the lumen of the ER. Seven polypeptides in the content subfractions, including serum albumin, contained almost 50% of the leucine radioactivity incorporated during 5 min and cross-reacted with antiserum against rat serum. Almost all microsomal glycoproteins were at least partly released with the microsomal content. Smooth microsomes contained higher levels of albumin than rough microsomes, but after short times of labeling with [³H]leucine the specific activity of albumin in the latter was higher, supporting the notion that newly synthesized serum proteins are transferred from rough to smooth portions of the ER. On the other hand, after labeling for 30 min with [³H]glucosamine, smooth microsomes contained higher levels of radioactivity than rough microsomes. This would be expected if glycosidation of newly synthesized polypeptides proceeds during their transit through ER cisternae. The labeling pattern of membrane proteins in microsomes obtained from animals which received three daily injections of [³H]leucine, the last administered 1 day before sacrifice, followed the intensity of bands stained with Coomassie blue, with a main radioactive peak corresponding to cytochrome P 450. After the long-term labeling procedure most content proteins had low levels of radioactivity; this was especially true of serum proteins which were highly labeled after 30 min.     

Post-replication DNA repair in barley embryos treated with N-methyl-N-nitrosourea

In sterile cultures of free barley embryos, N-methyl-N-nitrosourea (MNU) caused a decrease in the size of both template [¹⁴C]-labeled DNA and of daughter [³H]DNA strands as determined in alkaline sucrose gradients, and inhibited the rate of [³H]thymidine incorporation. In addition, duplexes containing [³H]-daughter DNA analyzed in BND cellulose contained more single-stranded regions in MNU-treated embryos than in the corresponding control. Incubation of MNU-treated embryos in nutrient medium for up to 18 h after the [³H]-labeling permitted the recovery of small-sized daughter DNA to full-sized strands and led to the enhancement of double-strandedness of DNA duplexes containing [³H]-labeled strands. If [³H]-labeling had been carried out 8–10 h after the MNU treatment, the size of daughter DNA, the proportion of double-strandedness and the rate of thymidine uptake into DNA partially increased in comparison with rates observed when labeling had been done just after or 3 h after the MNU treatment, but these variables did not reach the values of the corresponding controls.     

Extremely rapid degradation of [3H] methionine-enkephalin by various rat tissues in vivo and in vitro

Thirty sec after the intrajugular injection of [³H] methionine-enkephalin (met-enkephalin) in the rat, the radioactivity was already distributed in an apparent volume of 53 ml and the metabolic clearance rate calculated from the characteristics of the plasma disappearance curve was 10 ml/min. As shown by partition chromatography plasma extracts obtained 15 sec after injection of [³H] met-enkephalin, only 5% of the total radioactivity migrated as the intact pentapeptide, while no detectable intact pentapeptide remained 2 min after injection, thus indicating a half-life of [³H] met-enkephalin of the order of 2 to 4 sec. Incubation of rat cerebral tissue with [³H] met-enkephalin indicates that the first step in the breakdown of met-enkephalin in both plasma and brain tissue is cleavage of the Tyr-Gly amide bond. These data offer an explanation for the low activity of met-enkephalin after intraventricular or intravenous administration.     

Early DNA synthesis during the germination of wheat embryos

Both [³H]thymidine and [³H]deoxyadenosine were found to be incorporated into the nuclear DNA of wheat embryos immediately after dry embryos were allowed to imbibe aqueous solutions of the radioactive precursors. The early labelled DNA sedimented in a manner suggesting that replicative intermediates were already formed within the first 90 min of germination. However, aphidicolin remained without any effect on this early DNA synthesis. Likewise, a cell-free system derived from early embryos incorporated [³H]dCTP into DNA independently of the presence of aphidicolin. On the contrary, dideoxyTTP inhibited the DNA synthesis considerably. It is concluded that a proportion of the resting wheat embryo cells is able to initiate a replicative DNA synthesis immediately upon imbibition. The synthesis seems, however, to proceed with the participation of a γ-like, rather than an α-like, DNA polymerase.     

DETERMINATION OF RATES OF DNA SYNTHESIS IN CULTURED MAMMALIAN CELL POPULATIONS

In cultures of a murine mastocytoma, endogenous synthesis of thymidine phosphates, as determined by the incorporation of [³H]deoxyuridine into DNA, was reduced within 15 min to less than 3% of control values by the addition of amethopterin (10 µM) in combination with hypoxanthine and glycine. If [³H]thymidine and unlabeled thymidine were added simultaneously with amethopterin, the increase with time of radioactivity in cellular DNA was linear at least between 30 and 90 min, while radioactivity in the acid-soluble nucleotide fraction remained constant during this time interval, indicating that intracellular thymidine nucleotides had the same specific activity as exogenously supplied [³H]thymidine. This permitted calculation of the amount of thymidine incorporated per hour into DNA of 10⁶ cells. In conjunction with the base composition of mouse DNA, these results were used to calculate rates of DNA synthesis. Cell proliferation rate, cell cycle time, and the duration of the S period were not affected to any appreciable extent by the addition of amethopterin and thymidine. Rates of DNA synthesis, as derived from thymidine incorporation rates, were in good agreement with those derived from the measured mean DNA content of exponentially multiplying cells and rates of cell proliferation.     

DNA REPLICATION: DIRECTION AND RATE OF CHAIN GROWTH IN MAMMALIAN CELLS

Using pulse labeling techniques with [³H]thymidine or [³H]cytidine, combined with DNA fiber autoradiography, we have investigated the direction and rate of DNA chain growth in mammalian cells. In general, chain elongation proceeds bidirectionally from the common origin of pairs of adjacent replication sections. This type of replication is noted whether the DNA is labeled first with [³H]thymidine of high specific activity, followed by [³H]thymidine of low specific activity or the sequence is reversed. Approximately one-fifth of the growing points have unique origins and in these replication units, chain growth proceeds in one direction only. Fluorodeoxyuridine and hydroxyurea both inhibit DNA chain propagation. Fluorodeoxyuridine exerts its effect on chain growth within 15–23 min, while the effect of hydroxyurea is evident within 15 min under conditions where the endogenous thymidine pool has been depleted by prior treatment with fluorodeoxyuridine. Puromycin has no effect on chain growth until 60 min after addition of the compound, even though thymidine incorporation is more than 50% reduced within 15 min. After 2 h of treatment with puromycin, the rate of chain growth is reduced by 50%, whereas thymidine incorporation is reduced by 75%. Cycloheximide reduces the rates of DNA chain growth and thymidine incorporation 50% within 15 min, and, on prolonged treatment, the decrease in rate of chain growth generally parallels the reduction in thymidine incorporation.     

Calculation of Cell Production from [3H]Thymidine Incorporation with Freshwater Bacteria

The conversion factor for the calculation of bacterial production from rates of [³H]thymidine incorporation was examined with diluted batch cultures of freshwater bacteria. Natural bacterial assemblages were grown in aged, normal, and enriched media at 10 to 20°C. The generation time during 101 growth cycles covered a range from 4 to >200 h. The average conversion factor was 2.15 × 10¹⁸ cells mol^-1 of thymidine incorporated into the trichloroacetic acid (TCA) precipitate (standard error = 0.29 × 10¹⁸; n = 54), when the generation time exceeded 20 h. At generation times of <20 h, the average conversion factor was 11.8 × 10¹⁸ cells mol^-1 of thymidine incorporated into TCA precipitate (standard error = 1.72 × 10¹⁸; n = 47). The amount of radioactivity in purified DNA increased with decreasing generation time and increasing conversion factor (calculated from the TCA precipitate), corresponding to a decrease in the percentage in protein. The conversion factors calculated from purified DNA or from the TCA precipitate gave the same variability. Conversion factors did not change significantly with the medium, but were significantly higher at 20°C than at 15 and 10°C. A detailed examination of the [³H]thymidine concentrations that were needed to achieve maximum labeling in DNA was carried out 6 times during a complete growth cycle. During periods with low generation times and high conversion factors, 15 nM [³H]thymidine was enough for the maximum labeling of the TCA precipitate. This suggests that incorporation of [³H]thymidine into DNA is probably limited by uptake during periods with generation times of <20 h and that freshwater bacterioplankton cell production sometimes is underestimated when a conversion factor of 2.15 × 10¹⁸ cells mol^-1 of thymidine incorporated is used.     

Differential permeability of murine visceral yolk sac to thymidine and to hydroxyurea.

Mouse embryos at the 10–12-somite stage of development were excised from the uterus either with or without the encapsulating visceral yolk sac and were incubated in vitro in 3 × 10^?7M thymidine (methyl-T, 5 μCi/ml) for 30 min or in 4 × 10^?3M hydroxyurea for 45 min with [³H]thymidine present for the last 30 min. Radioautograms of nuclei of neural epithelium enabled an estimate of the effectiveness of the barrier imposed by the visceral yolk sac membrane to the passage of thymidine and hydroxyurea.Labeling of nuclei in the neural epithelium showed that the visceral yolk sac caused a 44% decrease in frequency and a 51% decrease in intensity of label. Hydroxyurea inhibited labeling by 15% in frequency and 37% in intensity irrespective of the presence or absence of visceral yolk sac. These results show that hydroxyurea and the presence of visceral yolk sac independently interfered with labeling of the neural epithelium by thymidine and that visceral yolk sac caused a proportionally greater retardation of label than did hydroxyurea.Nuclei of the endodermal epithelium of the intervening yolk sac, following exposure to hydroxyurea, showed a labeling decrease of 44% in frequency and 77% in intensity. The inhibitory effect of hydroxyurea on yolk sac labeling, however, did not alter yolk sac permeability to hydroxyurea. The results indicate that the visceral yolk sac, by offering no detectable barrier to hydroxyurea, permits prompt teratogenic action of hydroxyurea directly upon the embryo and suggest that the visceral yolk sac is a likely candidate to account for reports that the 8.5-day mouse embryo in situ fails to label with radioisotopic thymidine.     

DNA synthesis in developing two-cell mouse embryos

Mated CF1 (Carworth) female mice were sacrificed at 2 hr intervals between 29 and 43 hr after human chorionic gonadotrophin (HCG) administration. One- and two-cell eggs were incubated in [³H]thymidine for 1 hr. Labeled two-cell embryos were first observed at 31 hr and reached a maximum number at 35 hr. The S period is approximately 6 hr in duration. Although both blastomeres were labeled in most cases, embryos with only one labeled blastomere were more numerous at later times. In vitro labeling was corroborated by injecting [³H]thymidine directly into the isthmic portion of the oviduct. Embryos usually complete the second cleavage division 18–20 hr after onset of DNA synthesis. The cell cycle at the two-cell stage is thus characterized by a G₁ of close to 1 hr, a 6 hr S, and a G₂ of about 12 hr.Embryos developing in vitro frequently fail to progress beyond the two-cell stage. The block is not due to absence of DNA synthesis since these embryos were found to incorporate [³H]thymidine.     

Exogenous sphingosine enters Xenopus laevis embryos grown in petri dishes and it is metabolized

Xenopus embryos of different developmental stages were exposed to 0.1 M [1-³H]sphingosine. Labeled sphingosine was quickly absorbed by Xenopus embryos. The amount of radioactivity absorbed increased with embryo age and appeared to be linearly correlated (R=0.97) to the embryo surface area. About 45% of the total radioactivity associated to the embryos was found in the skin, 22% in the intestine, 15% in the heart, 12% in the liver and 6% in the brain.A portion of [1-³H]sphingosine entered very rapidly the biosynthetic pathway of sphingolipids; after 30 min of incubation, in fact, only a small amount of free radioactive sphingosine could be detected. Sphingomyelin was the main radioactive sphingolipid synthesized; radioactive ceramide, galactosylceramide and lactosylceramide could also be recognized and quantified. On the contrary, the amount of radioactive gangliosides was hardly detectable.A portion of [1-³H]sphinogosine absorbed by Xenopus embryos (30 to 60% depending on the developmental stage) entered the catabolic pathway producing radioactive phosphoethanolamine that was recycled for the biosynthesis of radioactive phosphatidylethanolamine. This phospholipid was produced mainly in the intestine and in the skin, while sphingomyelin was the main radioactive lipid in the heart, liver and brain.     

Correlation of nonspecific macromolecular labeling with environmental parameters during [3H]Thymidine incorporation in the waters of southwest florida

During routine [³H]thymidine incorporation measurements of environmental samples, significant amounts of radioactivity are often incorporated into macromolecules other than DNA. Although the percentage of nonspecific labeling varies both temporally and spatially, the cause(s) of these variations remain unknown. Correlations between the percent incorporated radioactivity in DNA and a variety of experimental and environmental parameters measured in the Alfia River, Crystal River, Medard Reservoir, and Bayboro Harbor were examined. The amount of radioactivity incorporated into DNA ranged from 6 to 95% ( ; n=121). Nonspecific labeling began immediately upon the addition of [³H]thymidine and was linear over time. Labeling patterns were independent of both the amount of thymidine added and cell-size fraction. A two year study of Bayboro Harbor indicated no conclusive relationship between nonspecific labeling and seasonality. The amount of radioactivity incorporated into DNA was inversely correlated with total rates of thymidine incorporation and a strong diurnal pattern was observed in the Crystal River. No consistent relationship was observed between labeling patterns and primary productivity, chlorophylla, particulate DNA, dissolved DNA, bacterial cell numbers, temperature, salinity, and dissolved organic carbon. The only relationship with dissolved inorganic nutrients (N and P) occurred in the Crystal River. In this phosphate limited river, the percent of radioactivity incorporated into DNA was positively correlated with phosphate concentrations. These results indicate that nonspecific labeling is not dependent on any one parameter but may be a function of many interacting environmental factors or a function of the specific ambient bacterial population.     

Localization of nucleic acids in the nucleoli of oocytes and early embryos of mouse and hamster: An autoradiographic study

Mouse preovulatory oocytes, zygotes, parthenogenetically activated pronuclear oocytes, and early embryos, as well as hamster zygotes, were analyzed, by autoradiography, for the distribution of either “maternal” or newly synthesized RNAs. Early mouse embryos were also examined for the distribution of newly replicated DNA. Special attention was attributed to NLBs in oocytes or to NPBs in early embryos. In mouse oocytes, [5-³H]uridine radioactivity accumulated (after a 2-hr pulse) in vitro, in addition to other nuclear compartments, in the central compact material of the NLBs. There was no cytoplasmic labeling. In all parthenogenetic pronuclear embryos developed from similarly labeled oocytes, this label was distinctly detectable in the central compact material of the NPBs; less intensive labeling was seen in the nucleoplasm and cytoplasm. On the contrary, the central compact part of the mouse NPB did not show labeling in DNA after a continuous culture with [6-³H]thymidine. In mouse and hamster pronuclear zygotes, convincing evidence was obtained for a lack of any newly synthesized nucleic acids in the compact material of NPBs using 4- to 10-hr culture with [8-³H]adenosine. Based on these data, it was shown that the NLBs of oocytes or NPBs of early embryos probably contain RNAs synthesized during the last stages of antral follicle oocyte differentiation. This unique pathway of RNAs in the oocyte—embryo system may explain the specific morphology of both oocyte and early embryo “nucleoli.” © 1995 Wiley-Liss, Inc.     

Effect of 5-Fluoro-2′-Deoxyuridine on [3H]Thymidine Incorporation by Bacterioplankton in the Waters of Southwest Florida

The effect of 5-fluoro-2′-deoxyuridine (FdUrd) on [methyl-³H] thymidine incorporation by bacterioplankton populations in subtropical freshwater, estuarine, and oceanic environments was examined. In estuarine waters, intracellular isotope dilution was inhibited by FdUrd, which enabled us to estimate both intracellular and extracellular isotope dilution. In 2 of 10 cases, extracellular isotope dilution was significant. At low concentrations of [methyl-³H]thymidine or [6-³H]thymidine, FdUrd completely inhibited incorporation of radioactivity into protein and RNA. At high concentrations of [³H]thymidine, however, FdUrd had little effect on labeling patterns. The dihydrofolate reductase inhibitors amethopterin and trimethoprim had no effect on macromolecular labeling patterns. These results suggest that thymidylate synthase is not involved in nonspecific labeling and that FdUrd inhibits nonspecific labeling by blocking some other enzyme involved in thymidine catabolism. In oligotrophic oceanic and freshwater samples, FdUrd did not inhibit intracellular isotope dilution or [³H]thymidine labeling of protein and RNA, but caused some inhibition of [³H]thymidine incorporation into DNA. The ability of FdUrd to inhibit nonspecific macromolecular labeling during [³H]thymidine incorporation was significantly correlated (r = 0.84) with total thymidine incorporation (in picomoles per liter per hour). The results are discussed in terms of applications of FdUrd to routine bacterial production measurements and the general assumptions of [³H]thymidine incorporation.     

Interferon inhibition of thymidine incorporation into DNA through effects on thymidine transport and uptake

Replenishment of medium after 72 hr of growth of HeLa-S3 cells in dense suspension cultures increased [³H]-thymidine uptake into cells and incorporation into DNA, with the levels reaching a peak ～ 12 hr following medium change; β interferon inhibits the enhanced uptake of [³H]-thymidine and labeling of DNA in a dose-dependent manner. Some reduction in these processes is observed at a concentration as low as 1 u/ml, and ～ 75% inhibition at 640 u/ml. Kinetic analysis has revealed that the rate of labeling of the acid-soluble pool with [³H]-thymidine, measured either at 22°C, or 37°C, is reduced in interferon-treated (640 u/ml, 24 hr) HeLa-S3 cells. At 22°C, the initial rate of thymidine transport at a high (500 μM) thymidine concentration, determined within the first 30 sec of [³H]-thymidine addition was depressed by 44% in interferon-treated HeLa cells. At 37°C, labeled precursors accumulate in acid-soluble material for ～ 8 min after the addition of [³H]-thymidine, after which an apparent equilibrium level is attained. At this temperature, the rate of thymidine uptake and the apparent equilibrium level attained were depressed by 70% in interferon-treated HeLa cells. The reduced incorporation of [³H]-thymidine into DNA in interferon-treated HeLa-S3 cells can be largely explained by interferon inhibition of thymidine transport and phosphorylation.     

Calculation of cell production from [h]thymidine incorporation with freshwater bacteria

The conversion factor for the calculation of bacterial production from rates of [H]thymidine incorporation was examined with diluted batch cultures of freshwater bacteria. Natural bacterial assemblages were grown in aged, normal, and enriched media at 10 to 20 degrees C. The generation time during 101 growth cycles covered a range from 4 to >200 h. The average conversion factor was 2.15 x 10 cells mol of thymidine incorporated into the trichloroacetic acid (TCA) precipitate (standard error = 0.29 x 10; n = 54), when the generation time exceeded 20 h. At generation times of <20 h, the average conversion factor was 11.8 x 10 cells mol of thymidine incorporated into TCA precipitate (standard error = 1.72 x 10; n = 47). The amount of radioactivity in purified DNA increased with decreasing generation time and increasing conversion factor (calculated from the TCA precipitate), corresponding to a decrease in the percentage in protein. The conversion factors calculated from purified DNA or from the TCA precipitate gave the same variability. Conversion factors did not change significantly with the medium, but were significantly higher at 20 degrees C than at 15 and 10 degrees C. A detailed examination of the [H]thymidine concentrations that were needed to achieve maximum labeling in DNA was carried out 6 times during a complete growth cycle. During periods with low generation times and high conversion factors, 15 nM [H]thymidine was enough for the maximum labeling of the TCA precipitate. This suggests that incorporation of [H]thymidine into DNA is probably limited by uptake during periods with generation times of <20 h and that freshwater bacterioplankton cell production sometimes is underestimated when a conversion factor of 2.15 x 10 cells mol of thymidine incorporated is used.     

Ribosomal RNA synthesis in mitochondria of Neurospora crassa

Ribosomal RNA synthesis in Neurospora crassa mitochondria has been investigated by continuous labeling with [5-³H]uracil and pulse-chase experiments. A short-lived 32 S mitochondrial RNA was detected, along with two other short-lived components; one slightly larger than large subunit ribosomal RNA, and the other slightly larger than small subunit ribosomal RNA. The experiments give support to the possibility that 32 S RNA is the precursor of large and small subunit ribosomal RNA's. Both mature ribosomal RNA's compete with 32 S RNA in hybridization to mitochondrial DNA. Quantitative results from such hybridization-competition experiments along with measurements of electrophoretic mobility have been used to construct a molecular size model for synthesis of mitochondrial ribosomal RNA's. The large molecular weight precursor (32 S) of both ribosomal RNA's appears to be 2.4 × 10⁶ daltons in size. Maturation to large subunit RNA (1.28 × 10⁶ daltons) is assumed to involve an intermediate ~1.6 × 10⁶ daltons in size, while cleavage to form small subunit RNA (0.72 × 10⁶ daltons) presumably involves a 0.9 × 10⁶ dalton intermediate. In the maturation process ~22% of the precursor molecule is lost. As is the case for ribosomal RNA's, the mitochondrial precursor RNA has a strikingly low G + C content.     

In vivo chain elongation of hepatic DNA: 1-beta-D-arabinofuranosyl cytosine sensitive steps.

The $\text{in vivo}$ chain elongation of rat liver DNA following partial hepatectomy was studied using alkaline sucrose gradients. DNA made in 5 min was less than 4 × 10⁷ daltons and that made in 30 min was heterodisperse and by 4 hr 75% of the DNA became larger than 1 × 10⁹ daltons. Administration of 1-β-D-arabinofuranosyl cytosine (ara-C) 5 min after thymidine-³H injection inhibited the chain elongation, whereas if given 30 minutes after thymidine-³H pulse did not inhibit the chain elongation. Thus the $\text{in vivo}$ chain elongation of rat liver DNA consists of at least two steps 1) a step sensitive to ara-C involving nucleotides addition and 2) the other insensitive to ara-C and probably involving ligation of polynucleotide chains.     

Size distribution and maturation of newly replicated DNA through the S and G2 phases of physarum polycephalum

The size distribution of newly made DNA and the dynamics of size maturation of progeny DNA molecules were studied in the synchronous S and G2 phases of Physarum polycephalum. Pulse labeling of DNA and analysis of the products on alkaline sucrose gradients showed that synthesis of primary replication units (which will also be referred to as “Okazaki” fragments) occurred throughout the S period. Pulse and pulse-chase experiments revealed a distinct pattern of size maturation. An apparently linear increase in molecular weight of progeny DNA molecules during the first hour of the S phase occurred at a rate of approximately 4–5 × 10⁵ daltons per min at 26°C, corresponding to the joining of 6–8 Okazaki fragments. The resulting 35–45S (1.1–2.2 × 10⁷ daltons) DNA molecules may correspond to the Physarum “replicon.” The further size increases of the newly made DNA appear to occur in steps, possibly reflecting a clustering of isochronous replicons along the chromatide. These observations are discussed with regard to mechanisms of DNA replication and size maturation.     

Rates of RNA chain growth in developing sea urchin embryos

The average time necessary to add a nucleotide onto growing RNA chains (step time) has been determined for several developmental stages of Strongylocentrotus purpuratus embryos. One procedure involved quantitation of isolated nucleosides derived from the 3′ end of newly synthesized chains plus total rates of nucleotide incorporation. The former values provide the number of growing chains so that rates of incorproation per RNA chain may be calculated. A second procedure involves determinations of the times required for RNA molecules of given size classes to become fully labeled. These times may be equated to the synthetic times for the particular size class [Bremer, H., and Yuan, D. (1968). RNA chain growth-rate in Escherichia coli. J. Mol. Biol.38, 163–180]. The step times for blastula and pluteus embryos is 6–9 nucleotides/sec at 15°C, which would result in an average synthetic time for heterogeneous nuclear RNA (HnRNA) molecules of about 2 × 10⁶ daltons of 12–18 min. The half-life of HnRNA in this species of sea urchins is 15–20 min, implying a transient existence for large HnRNA molecules.