Transport of different RNA species from the nucleus to the cytoplasm in Xenopus laevis neurula cells

Isolated cells from Xenopus laevis neurulae were labeled, and the RNAs extracted from their nuclear and soluble cytoplasmic fractions were analyzed on polyacrylamide gels. In the soluble cytoplasm, 4S RNA emerged very rapidly, and this was immediately followed by the emergence of poly(A)-containing RNA and 18S ribosomal RNA. In contrast, the emergence of 28S ribosomal RNA was delayed by about 2 hr. The size distribution of cytoplasmic poly(A)-containing RNA was much smaller as compared to that of nuclear poly(A)-containing RNA. These results indicate that the newly synthesized RNAs in Xenopus neurula cells are transported from the nucleus to the cytoplasm in a characteristic sequence.     

A transient accumulation of poly(A)-containing RNA in the tapetum of Hyoscyamus niger during microsporogenesis

The distribution of poly(A)-containing RNA in the tapetal cells of Hyoscyamus niger during microsporogenesis was followed by in situ hybridization with [³H]poly(U) as a probe. Although no poly(A)-containing RNA accumulated in the premeiotic tapetum, [³H]poly(U) binding sites were detected in the tapetum as meiosis was completed in the microsporocytes. Accumulation of poly(A)-containing RNA in the tapetal cells reached a peak before the first haploid mitosis in the pollen grains. With the onset of tapetal senescence at the late uninucleate stage of the pollen grain, [³H]poly(U) binding sites gradually decreased and they completely disappeared in the tapetum at the binucleate pollen stage. The significance of the results is discussed, particularly with regard to the possible role of tapetum in the synthesis of informational macromolecules during microsporogenesis.     

Degradation of maternal poly(A)-containing RNA during early embryogenesis of an insect (Smittia spec., chironomidae,diptera)

Summary Eggs of the chironomid midgeSmittia spec. were shown to contain maternal rRNA, tRNA and poly(A)-containing RNA. The ribonucleoprotein spectrum consisted of monosomes, ribosomal subunits, and subribosomal particles, whereas polysomes could be detected only in small amounts. Poly(A)-containing RNA was found in different regions of the RNP spectrum, mainly between 15 S and 60 S. After labelling maternal RNA by feeding tritiated uridine to the larvae, the radioactivity associated with poly(A)-containing RNA accounted for about 4% of the label in the total RNA extracted from newly deposited eggs. About half of the radioactivity in the poly(A)-containing RNA was lost between egg deposition and an advanced blastoderm stage. The loss was accompanied by both a decrease in the size of the poly(A)-containing RNA molecules and a shift of poly(A)-containing RNP particles to less dense regions in sucrose gradients. Comparison with poly(A)-containing RNA synthesized by the embryo indicates that the reduction in size of maternal poly(A)-containing RNA is not artifactual but reflects its degradation after the formation of blastoderm.     

Polyribosome formation and poly(A)-containing RNA in embryos of the sand dollar,Dendraster excentricus

Summary The pattern of appearance of ribosomes, newly synthesized mRNA, and poly(A)-containing mRNA in polyribosomes has been examined in sand dollar embryos. From early blastula until shortly before hatching small polyribosomes engaged in histone synthesis predominate. At the time of hatching, when the rate of cell increase is maximal, the proportion of poly(A)-containing RNA in polyribosomes is low. After hatching a new class of large polyribosomes appears and the amount of poly(A)-containing polyribosomal RNA increases. Cordycepin, an inhibitor of RNA adenylylation, prevents the appearance of the large polyribosomes after hatching as well as the increase in poly(A)-containing polyribosomal RNA.     

Culture of intact Sertoli/germ cell units and isolated Sertoli cells from Squalus testis: I. Evidence of stage-related functions in vitro

As part of an ongoing program of research using the testis of the dogfish shark (Squalus acanthias) to characterize morphologic and functional changes during spermatogenesis, we have developed procedures for culturing intact spermatocysts (germ cell/Sertoli cell clones) and isolated Sertoli cells from premeiotic, meiotic, and postmeiotic stages of development. Phase contrast and light microscopy confirmed the stage and cellular composition of spermatocysts and showed that they retained their closed, spherical configuration for at least 15 d in culture. Stage-related variations in [3H]thymidine incorporation (premeiotic much greater than meiotic = postmeiotic) were observed, a pattern that was the same quantitatively and qualitatively after one or seven days of culture. [3H]Leucine-labeled protein synthesis was twofold greater in cultures with premeiotic spermatocysts than in cultures with more mature stages, whether medium or cysts were analyzed. Sertoli cells isolated from spermatocysts of different stages differed in size, shape, cytological appearance, ability to form flattened monolayers, and rate of DNA synthesis. One day after seeding, [3H]thymidine labeling of Sertoli cells corresponded to the pattern obtained with intact spermatocysts (premeiotic much greater than meiotic = postmeiotic); however, 7 days in culture effected a 40- to 200-fold increase in this parameter and altered the stage-dependent pattern (premeiotic = meiotic greater than postmeiotic). Also, when [3H]leucine-labeled macromolecules secreted by Sertoli cells from premeiotic versus meiotic stages were analyzed by polyacrylamide gel electrophoresis (PAGE), banding patterns differed. Initial results demonstrate the feasibility and potential of this in vitro system for studying qualitative and quantitative changes during spermatogenesis.     

Isolation and Characterization of Adenovirus Messenger Ribonucleic Acid in Productive Infection

Messenger ribonucleic acid (mRNA) from cells productively infected with adenovirus type 2 was isolated by affinity chromatography on polyuridylic acid [poly (U)] bound to Sepharose. At least 90% of the polyadenylic acid [poly (A)]-containing polysomal mRNA was retained by the poly (U) Sepharose and thus separated from more than 95% of the ribosomal RNA and transfer RNA. In these experiments, 65% of the early (3 to 5 hr postinfection) and 85% of the late (14 to 16 hr postinfection) virus-specific RNA was retained by the poly (U) Sepharose. Early in the infection 18%, and late in the infection more than 95%, of the poly (A)-containing fraction, eluted from the poly (U) Sepharose with 90% formamide, was adenovirus-specific, as shown by exhaustive hybridization. Different patterns, containing several distinct species of viral mRNA, were detected early and late in the infectious cycle. No distinct viral mRNA lacking poly (A) was discovered.     

Mobilization of newly synthesized RNAs into polysomes inXenopus laevis embryos

Summary The mobilization of newly synthesized 18S and 28S rRNAs, 4S RNA and poly(A)⁺ RNA into polysomes was studied in isolated cells ofXenopus laevis embryos between cleavage and neurula stages. Throughout these stages, 4S RNA and poly(A)⁺ RNA were mobilized immediately following their appearance in the cytoplasm. 18S rRNA however, stayed in the ribosomal subunit fraction for about 30 min until the 28S rRNA appeared, when the two rRNAs were mobilized together at an equimolar ratio. This mobilization, at a 1:1 molar ratio, appeared to be realized at initiation monome formation. Thus, the efficiency of the mobilization of two newly synthesized rRNAs, shortly after their arrival at the cytoplasm, differed considerably but difference disappeared once steady state was reached.The contribution of newly synthesized 18S and 28S rRNAs to polysomes remains small throughout early development. around 3% of newly synthesized 4S RNA is polysomal which is the same distribution observed for unlabeled 4S RNA. Less than 10% of the newly synthesized cytoplasmic poly(A)⁺ RNA was mobilized into polysomes during cleavage, but in later stages the proportion increased to around 20%–25%. These results show that newly synthesized RNAs are utilized for protein synthesis at characteristic rates soon after they are synthesized during early embryonic development. On the basis of the data presented here and elsewhere we discuss quantitative aspects of the utilization of newly synthesized and maternal RNAs during early embryogenesis.     

Mitochondrial poly(A) RNA synthesis during early sea urchin development

The synthesis of mitochondrial messenger RNA during early sea urchin development was examined. Oligo(dT) chromatography and electrophoresis on aqueous or formamide gels of mitochondrial RNA from pulse-labeled embryos showed the presence of eight distinct poly(A)-containing RNA species, ranging in size from 9 to 22 S. Nuclease digestion of these RNAs revealed poly(A) sequences of 4 S size. Using sea urchin anucleate fragments, we were able to demonstrate that all eight messenger RNAs are transcribed from mitochondrial DNA, rather than being transcribed from nuclear DNA and imported into the mitochondria.There was no change in the electrophoretic profile of the eight poly(A) RNAs when embryos were pulsed with [³H]uridine at various times after fertilization. Neither was there any change in the incorporation of [³H]uridine into these species or in the percentage of total newly synthesized mitochondrial RNA that contains poly(A) sequences as development progresses. Even though these RNAs appear to be transcribed at a constant rate throughout early development, they were not detected in mitochondrial polysomes until 18 hr after fertilization.     

RNA metabolism and membrane-bound polysomes in relation to globulin biosynthesis in cotyledons of developing field beans (Vicia faba L.).

In cotyledon cells of developing field beans the RNA content per cell does not change in the second half of developmental period 2, whereas globulin biosynthesis continues. The constant RNA content per cell results from an equilibrium between RNA synthesis and degradation. All types of RNA are synthesized until the end of globulin biosynthesis, but poly(A)-containing RNA was preferentially labelled during maximum globulin formation. During stage 2 of seed development of poly(A)-containing RNA fraction represents a discrete peak in the 12--18-S region on agarose gels and corresponds to the peak of poly(A)-containing RNA isolated from polysomes. alpha-Amanitin inhibits selectively the labelling of poly(A)-containing RNA and concomitantly globulin formation. Translation of total poly(A)-containing RNA, free and membrane-bound polysomes in a cell-free wheat germs demonstrates that the globulins are preferentially produced on membrane-bound polysomes and that poly(A)-containing RNA includes the mRNA for both vicilin and legumin.     

RNA synthesised during oogenesis and early embryogenesis in an insect egg (Euscelis plebejus)

Summary RNA labelled during oogenesis or early embryogenesis was isolated from eggs of the leaf hopperEuscelis plebejus. The polyadenylated RNA fraction deposited during early oogenesis accounted for approximately 2.7% of the total RNA content of the newly laid egg. This fraction differed significantly in molecular weight (15–32 S) from poly(A)-containing RNA synthesised between early cleavage and early germ anlage stages (4–20S). Locally injected³H-uridine spread through the egg within approximately 3 h. A considerable fraction (25–35%) of label injected as³H-uridine during early cleavage was recovered in DNA at subsequent stages (10–20 h later); labelled RNA was not found prior to the cellular blastoderm stage. When the yolk-endoplasm was separated from the blastoderm cells, only the latter contained demonstrable amounts of RNA synthesised by the embryo. Of the precursor incorporated into embryonic RNA, approximately 10% was found in the polyadenylated fraction at the early blastoderm stage, but only 3% at the early germ anlage stage. No differences in size distribution of polyadenylated RNA were evident between anterior and posterior halves of the early germ anlage stage.Supported by the Deutsche Forschungsgemeinschaft, SFB 46     

RNA synthesis in embryo axes of germinating pea seeds

RNA synthesis during germination was investigated by labelingpea embryo axes or seedling roots with radioactive uridine oradenosine. The results indicated that all RNA species of pre-rRNAs(ribosomal precursor RNAs), rRNAs, heterodisperse-type RNA and4–5S low molecular weight RNA were synthesized from the6th to 64th hour of the period examined. At the very early stageof germination, some conspicuous labeling of the heterodisperse-typeRNA was observed after pulse-labeling. There was no great differencein the labeling patterns of various RNA species with regardto other later stages. When embryo axes were labeled for 1 hrwith ³H-adenosine from the 16th hour, about 25% of the labeledwhole cell RNA was retained on the membrane filter. The ratioof labeled poly(A)-containing RNA, however, decreased as germinationproceeded. The poly (A)-containing RNA sedimented heterodisperselywith a mean value of about 20S in a sucrose density gradient;this size-distribution did not vary throughout germination. (Received January 16, 1979; )     

Electrophoretic analysis of newly synthesized and stored maternal RNA during oogenesis ofCalliphora erythrocephala (Dipt.)

Summary Ovaries ofC. erythrocephala synthesize large amounts of poly(A)⁺ and poly(A)^– RNA during early and middle stages of oogenesis as shown by labelling with³H-uridine in vivo. After incubation for 1 h, a striking difference in the electrophoretic pattern of newly synthesized labelled poly(A)⁺ RNA and the poly(A)⁺ RNA present in sufficient amounts for optical density measurements (steady state poly(A)⁺ RNA) was observed. During early and mid-oogenesis, in the poly(A)^– RNA fraction, 4S predominantly mature rRNA, 5S RNA and tRNA were labelled. These fractions were no longer synthesized during late oogenesis, whereas poly(A)⁺ RNA was labelled continously During oogenesis stage specific differences in the size distribution of newly synthesized and steady state poly(A)⁺ RNA were not obvious. However, different sizes of labelled poly(A)⁺ RNA species were detected in 0–2h old preblastoderm embryos, after injection of³H-uridine into females either 3–4 days (stage 3–4 of oogenesis) or 24 h before oviposition (stage 5–6 of oogenesis). This difference in RNA synthesis was related to the presence of active nurse cell nuclei. The poly(A)⁺ RNA fraction represents about 2–3% of the total RNA in both ovaries and freshly laid eggs as judged by measurements of optical density and radioactivity bound to oligo(dT). The length of poly(A)-segments in ovarian poly(A)⁺ RNA varied from about 30 to 200 nucleotides.     

Kinetic estimation of the base sequence complexity of poly(A)-containing mRNA in Ehrlich-ascites-tumor cells and its abundance in nuclear RNA.

Poly(A)-containing messenger RNA was isolated from polysomes of Ehrlich ascites tumor cells, and analyzed for sequence complexity by hybridization to its complementary DNA. The results indicate the presence of about 27,000 diverse mRNA species in mouse Ehrlich ascites tumor cells. Total nuclear RNA was also hybridized to cDNA transcribed from polysomal poly(A)-containing mRNA up to an rot of 3,000 M . s. It was found that all classes of the polysomal poly(A)-containing mRNA sequences were also present in the nucleus, although the distribution varied. About 2% of the total nuclear RNA sequences were expressed as total polysomal poly(A)-containing mRNA. We also report that the total percentage of the haploid mouse genome transcribed in Ehrlich cells is significantly higher than that found in other mouse cells previously examined for poly(A)-containing mRNA sequence complexity.     

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.     

The synthesis of polyadenylic acid-containing ribonucleic acid by isolated mitochondria from Ehrlich ascites cells.

The synthesis of poly(A)-containing RNA by isolated mitochondria from Ehrlich ascites cells was studied. Isolated mitochondria incorporate [3H]AMP or [3H]UTP into an RNA species that adsorbs on oligo (dT)-cellulose columns or Millipore filters. Hydrolysis of the poly(A)-containing RNA with pancreatic and T1 ribonucleases released a poly(A) sequence that had an electrophoretic mobility slightly faster than 4SE. In comparison, ascites-cell cytosolic poly(A)-containing RNA had a poly(A) tail that had an electrophoretic mobility of about 7SE. Sensitivity of the incorporation of [3H]AMP into poly(A)-containing RNA to ethidium bromide and to atractyloside and lack of sensitivity to immobilized ribonuclease added to the mitochondria after incubation indicated that the site of incorporation was mitochondrial. The poly(A)-containing RNA sedimented with a peak of about 18S, with much material of higher s value. After denaturation at 70 degrees C for 5 min the poly(A)-containing RNA separated into two components of 12S and 16S on a 5-20% (w/v) sucrose density gradient at 4 degrees C, or at 4 degrees and 25 degrees C in the presence of formaldehyde. Poly(A)-containing RNA synthesized in the presence of ethidium bromide sedimented at 5-10S in a 15-33% (w/v) sucrose density gradient at 24 degrees C. The poly(A) tail of this RNA was smaller than that synthesized in the absence of ethidium bromide. The size of the poly(A)-containing RNA (approx. 1300 nucleotides) is about the length necessary for that of mRNA species for the products of mitochondrial protein synthesis observed by ourselves and others.