TRANSPORT OF VIRAL RNA IN KB CELLS INFECTED WITH ADENOVIRUS TYPE 2

Messenger RNA transport was studied in KB cells infected with the nuclear DNA virus adenovirus type 2. Addition of 0.04 µg/ml of actinomycin completes the inhibition of ribosome synthesis normally observed late after infection and apparently does not alter the pattern of viral RNA synthesis: Hybridization-inhibition experiments indicate that similar viral RNA sequences are transcribed in cells treated or untreated with actinomycin. The polysomal RNA synthesized during a 2 hr labeling period in the presence of actinomycin is at least 60% viral specific. Viral messenger RNA transport can occur in the absence of ribosome synthesis. When uridine-³H is added to a late-infected culture pretreated with actinomycin, viral RNA appears in the cytoplasm at 10 min, but the polysomes do not receive viral RNA-³H until 30 min have elapsed. Only 25% of the cytoplasmic viral RNA is in polyribosomes even when infected cells have been labeled for 150 min. The nonpolysomal viral RNA in cytoplasmic extracts sediments as a broad distribution from 10S to 80S and does not include a peak cosedimenting with 45S ribosome subunits. The newly formed messenger RNA that is ribosome associated is not equally distributed among the ribosomes; by comparison to polyribosomes, 74S ribosomes are deficient at least fivefold in receipt of new messenger RNA molecules.     

Polysome formation and incorporation of new ribosomes into polysomes during germination of the embryonic axis of maize

Isolated axes of Zea mays L. cvs CiV₂ and CUZCO were imbibed for different periods of time, and free polysomes were extracted and analysed by centrifugation in a sucrose gradient. The amount of rRNA per axis was determined at different moments of germination. Polysome reassembly was practically completed by 8 h and 54% of the preformed ribosomes were found in the polysome fraction. An increase in the proportion of large polysomes was also observed during this period of germination. During the following period, the polysome content and the distribution of the various classes of polysomes remained unchanged.
The time of appearance of newly synthesized ribosomes into the polysomes was investigated using axes germinated in the presence of [³H]-uridine. Centrifugal analysis of EDTA-dissociated polysomes and gel electrophoretic analysis of polysomal RNA showed that new ribosomes appeared into polysomes a few hours after completion of the initial polysome assembly. When released into the cytoplasm, the new ribosomes were preferentially incorporated into polysomes rather than stored as free ribosomes.     

Changes in the polyadenylated messenger RNA population during development of Dictyostelium discoideum

The program of gene expression during the life cycle of Dictyostelium discoideum has been assessed by molecular hybridization of cDNA probes with polysomal RNA extracted at the following different stages of development: vegetative growth, interphase (2.5 hr), aggregation (8 hr), postaggregation (12 hr), and preculmination (18 hr). Several different cDNA probes were used. Two probes were prepared from vegetative stage poly(A⁺) RNA, one representing all species present and the other enriched for abundant species. A third cDNA probe was prepared from preculmination stage polysomal RNA and a fourth probe consisted of the preculmination stage cDNA depleted in those species also present at the vegetative stage. Hybridization of the various probes with the different polysomal RNA preparations has revealed developmental changes in the mRNA populations. These changes were not detected in an aggregation less mutant under similar conditions of starvation. Abundant RNA species of vegetative cells were found to drop to low levels, especially during the aggregation period. Fifty percent by mass of the RNA present in polysomes at 18 hr is not present during vegetative growth. Some of the new RNA species appeared during interphase and the remaining during the postaggregation period. A gradual increase in the number of copies per cell of certain RNA species comprising both new species as well as some shared with vegetative cells was observed throughout development. Other results indicated that the composition of polysomal and cytoplasmic RNA is similar during vegetative growth but differs markedly at 18 hr of development. Also, cytoplasmic RNA at 18 hr contained, in addition to polysomal RNA, a large proportion by mass of nonpolysomal RNA similar to vegetative RNA. The number of polysomal RNA species detected by this analysis during vegetative growth and during the preculmination stage were estimated to be 3000 and 3700, respectively. The number of copies of these RNA species ranged between 30 and 2000 per cell during vegetative growth and 3 to 300 per cell in polysomes at 18 hr. Developmentally induced RNAs which were preferentially distributed among abundant and intermediate classes were estimated to number 700–900 species.     

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.     

Synthesis and turnover of polysomal mRNAs in sea urchin embryos

The synthesis and turnover kinetics of polysomal mRNA have been measured in sea urchin embryos. Polysomes were isolated from stages ranging between mesenchyme blastula and late gastrula Strongylocentrotus purpuratus embryos which had been exposed to exogenous ³H-guanosine. The amount of radioactivity incorporated into messenger and ribosomal RNAs was determined separately as a function of time, and the precursor pool specific activity was measured in the same embryos. Synthesis and decay rate constants were extracted from the data by a leastsquares procedure. Per embryo, the rate of mRNA synthesis was calculated to be about 0.13 pg min^?1, while the rate of rRNA synthesis is about 0.022 pg min^?1. The newly synthesized mRNA turns over with a half-time of 5.7 hr. The data support only a single decay rate for the mRNA, but small fractions of mRNA decaying at different rates cannot be excluded. Previous studies have shown that a minor fraction of the mRNA includes the least abundant, most highly diverse set of messages (“complex class” mRNAs). To determine whether mRNAs of the complex class are synthesized and degraded at similar rates, labeled mRNA was measured in hybrids formed in mRNA excess reactions with single copy DNA. These experiments showed that complex class mRNAs represent an approximately proportional amount of the new mRNA synthesis, and turn over at the same average rate as does the bulk of the mRNA. Most of the mRNAs in the embryo polysomes are newly synthesized, rather than maternal. This statement refers both to complex class mRNAs and to prevalent mRNAs. Considering the sequence homology between embryo and oocyte mRNAs shown earlier, these results indicate that many of the same structural genes active during oogenesis are being transcribed in embryos at these stages.     

Magnesium Starvation of Aerobacter aerogenes II. Rates of Nucleic Acid Synthesis and Methods for Their Measurement

The rates of synthesis of Aerobacter aerogenes nucleic acids were estimated during incubation of the bacteria in a Mg(++)-free medium. Deoxyribonucleic acid (DNA) synthesized during Mg(++) starvation, or in the preceding exponential growth, remained acid-precipitable for 2.5 hr before breaking down to acid-soluble products during a period of many hours. Rates of DNA synthesis were calculated by correcting the net amounts of DNA per milliliter to values that would have appeared had there been no decay. After the first few hours, this rate was constant, the amount of DNA present at the start of Mg(++) starvation being synthesized every 130 min. Rates of synthesis of total ribonucleic acid (RNA) were established in two ways: (i) by measurements of the incorporation of exogeneous uracil and glucose carbon into RNA, and (ii) by the accumulation of transfer RNA (tRNA), since this component is stable during Mg(++) starvation. After the first few hours, this rate was constant, the amount of RNA present at the start of Mg(++) starvation being synthesized about every 120 min. Fractionation by gradient centrifugation revealed that at all times of starvation the ratio of newly synthesized tRNA-rRNA was the same as it was during exponential growth. Furthermore, newly synthesized ribosomal RNA (rRNA) became a part of polysomal structures. Thus, in the absence of Mg(++), DNA, tRNA, and rRNA were synthesized in the same relative proportions as during exponential growth, at rates close to one-half the instantaneous rates of synthesis in the bacteria growing exponentially at the start of starvation.     

EFFECTS OF CHLORAMPHENICOL ON CHLOROPLAST AND MITOCHONDRIAL ULTRASTRUCTURE IN OCHROMONAS DANICA

The effect of chloramphenicol (CAP) on cell division and organelle ultrastructure was studied during light-induced chloroplast development in the Chrysophyte alga, Ochromonas danica. Since the growth rate of the CAP-treated cells is the same as that of the control cells for the first 12 hr in the light, CAP is presumed to be acting during that interval solely by inhibiting protein synthesis on chloroplast and mitochondrial ribosomes. CAP markedly inhibits chloroplast growth and differentiation. During the first 12 hr in the light, chlorophyll synthesis is inhibited by 93%, the formation of new thylakoid membranes is reduced by 91%, and the synthesis of chloroplast ribosomes is inhibited by 81%. Other chloroplast-associated abnormalities which occur during the first 12 hr and become more pronounced with extended CAP treatment are the presence of prolamellar bodies and of abnormal stacks of thylakoids, the proliferation of the perinuclear reticulum, and the accumulation of dense granular material between the chloroplast envelope and the chloroplast endoplasmic reticulum. CAP also causes a progressive loss of the mitochondrial cristae, which is paralleled by a decline in the growth rate of the cells, but it has no effect on the synthesis of mitochondrial ribosomes. We postulate that one or more chloroplast ribosomal proteins are synthesized on chloroplast ribosomes, whereas mitochondrial ribosomal proteins are synthesized on cytoplasmic ribosomes.     

AUTORADIOGRAPHIC EVIDENCE FOR MANY SEGREGATING DNA MOLECULES IN THE CHLOROPLAST OF OCHROMONAS DANICA

Light-grown cells of Ochromonas danica, which contain a single chloroplast per cell, were labeled with [methyl-³H]thymidine for 3 h (0.36 generations) and the distribution of labeled DNA among the progeny chloroplasts was followed during exponential growth in unlabeled medium for a further 3.3 generations using light microscope autoradiography of serial sections of entire chloroplasts. Thymidine was specifically incorporated into DNA in both nuclei and chloroplasts. Essentially all the chloroplasts incorporated label in the 3-h labeling period, indicating that chloroplast DNA is synthesized throughout the cell cycle. Nuclear DNA has a more limited S period. Both chloroplast DNA and nuclear DNA are conserved during 3.3 generations. After 3.3 generations in unlabeled medium, grains per chloroplast followed a Poisson distribution indicating essentially equal labeling of all progeny chloroplasts. It is concluded that the average chloroplast in cells of Ochromonas growing exponentially in the light contains at least 10 segregating DNA molecules.     

Ribosome metabolism in hormone-treated Jerusalem artichoke tuber slices in the absence and presence of 5-fluorouracil

In order to examine the relation of protein synthesis to the onset of growth, changes in ribosome content and activity were compared in aged, metabolically active Jerusalem artichoke (Helianthus tuberosus L.) slices incubated in water or 2,4-dichlorophenoxyacetic acid+kinetin. In water, cells do not grow or divide and rRNA and protein levels remain constant. The percentage membrane-bound (mb) ribosomes drops from 25% to 16% during 24h. At the same time the proportion of ribosomes active in protein synthesis in both free and mb populations declines from about 69% to 54%. In auxin+kinetin, cell expansion occurs and is accompanied by a 3-fold increase in rRNA and a 50% increase in total protein content. The percentage mb ribosomes remains at 25% throughout 48 h of growth. During the first 24h of growth 70% of ribosomes in both free and mb populations are active; this value declines to near water levels at 48 h. Considering the large increase in total ribosomes the number of synthetically active ribosomes is substantially increased during growth. 5-Fluorouracil (5-FU) does not inhibit hormone induced growth but does depress total rRNA content by about one-third. It also reduces [³H]uridine incorporation into ribosomes by 70% and the newly made ribosomes are mostly inactive in protein synthesis. On the other hand, the inhibitor does not significantly affect the proportion of total ribosomes active in protein synthesis and only partially reduces protein accumulation during the second 24 h of growth. It is suggested that while ribosome production is reduced in 5-FU, ribosome turnover is also retarded resulting in retention of near normal capacity for protein synthesis and growth.     

Effects of Benzylaminopurine and Abscisic Acid on Distribution of rRNA in the Palisade Cells of Excised Cucurbita Pepo Cotyledons

rRNA was labelled with RNase-gold complexes applied to ultrathin Lowicryl sections of excised Cucurbita pepo L. (zucchini) cotyledons grown in darkness. Benzylaminopurine-caused stimulation of cotyledon growth decreases the density of ribosomes in palisade cells despite stimulating rRNA synthesis. Abscisic acid inhibits RNA synthesis and transport, but does not visibly affect the number of pre-existing ribosomes in retarded growth cells. The amount of rRNA in the cells of 24 h treated cotyledons is rather consequence of the growth rate than its leading factor.     

Changing rates of DNA and RNA synthesis in Drosophila embryos

Rates of DNA and RNA synthesis during Drosophila embryogenesis were measured by labeling octane-treated embryos with [¹⁴C]thymidine and [³H]uridine. Radioactivity incorporated per hour was converted to rates of synthesis using measurements of the pool-specific activity during the labeling periods. The rate of DNA synthesis during early embryogenesis increases to a maximum at 6 hr after oviposition and then decreases sharply. Measured rates of DNA synthesis were used to calculate that the total amount of DNA per embryo doubles every 18 min at blastoderm, every 70–80 min during gastrulation, and less than once every 7 hr at later stages. The rate of RNA accumulation per embryo increases continuously during the first 14 hr of embryogenesis. The rate of nuclear RNA synthesis per diploid amount of DNA, however, decreases fivefold between blastoderm and primary organogenesis. The cytoplasmic poly(A)⁺ RNA synthesized by blastoderm embryos associates rapidly with polysomes. The relatively high rate of synthesis of polysomal poly(A)⁺ RNA per nucleus at blastoderm allows the small number of nuclei present at blastoderm to make a significant quantitative contribution to the informational RNA active in the early embryo. At the end of blastoderm, approximately 14% of the mRNA being translated in the embryo has been synthesized after fertilization.     

Translation of an mRNA in rat L6 muscle cells is regulated within the cell cycle

In muscle cells two populations of mRNA are present in the cytoplasm. The majority of mRNA is associated with ribosomes and active in protein synthesis. A small population of cytoplasmic mRNA occur as free mRNA-protein complex and is not associated with ribosomes. This apparently repressed population of mRNA from rat L6 myoblast cells was used to construct a cDNA library. Radioactively labeled cDNA preparations of polysomal and free (or repressed) mRNA populations showed that at least ten recombinant clones preferentially annealed to the cDNA from repressed mRNA. One of these clones was extensively studied. The DNA from a recombinant plasmid D12 hybridized to a 1.3-kb poly(A)-rich mRNA. In proliferating myoblast cells, the 1.3-kb mRNA was more abundant in the polysomal fraction and mostly free in the non-dividing myotubes. In contrast to this mRNA, 90% of alpha and beta actin mRNAs were translated in both myoblasts and myotubes. Further analysis of distribution of the 1.3-kb RNA in the polysomal (active) and free (repressed) fractions in fusion-arrested postmitotic myotubes suggested that fusion of myoblasts was not necessary for the control of translation of this mRNA. Withdrawal of muscle cells from the cell cycle appeared to be involved in regulating translation of this mRNA. The presence of this mRNA was not, however, limited to muscle cells. This mRNA was also present in the repressed state in rat liver and kidney cells. These results, therefore, suggest that the 1.3-kb mRNA is probably translated during a particular phase of the cell cycle and is not translated in terminally differentiated non-dividing cells. Messenger RNA homologous to the 600-base-pair insert of the recombinant plasmid D12 was isolated by hybrid selection procedure from both polysomal mRNA of myoblasts and free mRNA of myotubes. Translation of the hybrid selected mRNAs from both myoblasts and myotubes in rabbit reticulocyte lysate cell-free system synthesized a 40-kDa polypeptide. These results suggest that the repressed population of 1.3-kb mRNA can be translated in vitro. The hybridization pattern of DNA from the recombinant plasmid D12 with rat genomic DNA suggested that the 1.3-kb mRNA is derived from moderately repetitive rat DNA with a repetition frequency of approximately 100 copies per haploid genome.     

A comparison of sequence complexity of nuclear and polysomal poly(A)+ RNA from different developmental stages ofXenopus laevis

Summary Nuclear poly(A)⁺ and polysomal poly(A)⁺ RNA were isolated from gastrula and early tadpole stages of the amphibianXenopus laevis. Complementary DNA was synthesized from all RNA preparations. Hybridization reactions revealed that at least all abundant and probably most of the less frequent nuclear and polysomal poly(A)⁺ RNA species present at the gastrula stage are also present at the early tadpole stage. On the other hand, there are nuclear RNA sequences at the latter stage which appear, if at all, only at lower concentrations at the gastrula stage. The polysomal poly(A)⁺ RNA hybridization reactions suggest the existence of polysomal poly(A)⁺ RNA sequences at early tadpole stages which are not present in the corresponding gastrula stage RNA.By cDNA hybridization with poly(A)^– RNA it could be shown that most of the poly(A)⁺ containing RNA sequences transcribed into cDNA were also present within the poly(A)^– RNA. It was estimated, that these sequences are 10 fold more abundant within the poly(A)^– polysomal RNA and 3–6 more abundant within the poly(A)^– nuclear RNA as compared to the poly(A)⁺ RNAs.     

Effect of a modified separation procedure on the size and protein-synthetic activity of membrane-bound liver polyribosomes

1. Various subcellular fractions containing ribosomes were isolated from rat liver. 2. In the presence of [(14)C]leucine and Sephadex-treated cell sap the radioactivity incorporated into the synthesized protein resulting from the incubation of microsomal preparations or deoxycholate-treated polyribosomes was dependent on the amount of rRNA incubated. In contrast, when Sephadex-treated post-mitochondrial supernatant was incubated, the radioactivity incorporated into the synthesized protein was independent of the amount of rRNA incubated. 3. Microsomal preparations and membrane-bound ribosomes, prepared by the standard procedure, incorporated less [(14)C]leucine into protein, per mg of rRNA incubated, than free or deoxycholate-treated polyribosomes; accordingly, polyribosomes associated with the former fractions were found mainly as monomers. 4. If microsomal fractions or membrane-bound ribosomes were prepared by a simple modification of the standard procedure, i.e. by centrifugation on to a ;cushion' of 2m-sucrose, their protein-synthesizing activity was of the same order as that of the original post-mitochondrial supernatant, and membrane-free and deoxycholate-treated polyribosomes; in this case polyribosome profiles showed that very little degradation had occurred and compared well with those obtained for post-mitochondrial supernatant and isolated polyribosomes. 5. A method is described (Appendix) that provides a rapid and reliable assessment of the concentration of rRNA in subcellular fractions.     

Gradient of RNA distribution in the cytoplasm of Acetabularia mediterranea

Radiochemical studies and electrophoresis showed that there exists an apico-basal gradient of RNA concentration in Acetabularia mediterranea cytoplasm. The main contribution to the formation of such a gradient is made by the different rates of RNA turnover in the cytoplasm rather than by the transfer of nuclear RNA. High molecular weight RNA fractions synthesized in the cytoplasm originate from chloroplast ribosomes; their sedimentation constants are close to those of 23S and 16S rRNA fractions of E. coli.     

Proteins of ribosome-bearing and free-membrane domains in Bacillus subtilis

In lysates of Bacillus subtilis a free-membrane fraction without ribosomes can be separated from the denser membrane-ribosome complexes. As determined by one-dimensional sodium dodecyl sulfate gel electrophoresis, these two fractions differ markedly in protein composition; at least six major bands (molecular weights, 130,000, 92,000, 68,000, 64,000, 45,000, and 31,000) are essentially unique to the complexed-membrane fraction (CM proteins), and two are unique to the free-membrane fraction. After growth was slowed, the proportion of the free-membrane fraction increased, but the composition of this fraction was the same, whereas after puromycin treatment, which abruptly increased the proportion of the free-membrane fraction, this fraction contained CM proteins. Thus, it appears that the two fractions recovered from growing cells represent topographically and functionally distinct domains. In addition, the effect of growth rate suggests that formation of the complexed domain is regulated at least roughly in parallel with the formation of ribosomes. The separation of these membrane fractions should facilitate the study of protein secretion, membrane topography, and morphogenesis in bacteria.     

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.     

Nuclear localization signal of SV40 T antigen directs import of plasmid DNA into sea urchin male pronuclei in vitro

Nuclear import of plasmid DNA mediated by a nuclear localization signal (NLS) derived from SV40 T antigen was investigated in a cell-free extract. In vitro assembled sea urchin male pronuclei were incubated in a 100,000g supernatant of a zebrafish fertilized egg lysate, together with fluorescently labeled plasmid DNA bound to NLS or nuclear import deficient reverse NLS (revNLS) peptides. After 3 hr, DNA-NLS, but not DNA-revNLS, complexes were bound around the nuclear periphery. We demonstrate that nuclear import of DNA-NLS complexes is a two-step process involving binding to, and translocation across, the nuclear envelope. Binding is ATP-independent, occurs at 0°C and is Ca²⁺-independent. By contrast, translocation requires ATP hydrolysis, Ca²⁺, is temperature dependent and is blocked by the lectin wheat germ agglutinin. Both binding and translocation are competitively inhibited by albumin-NLS conjugates, require heat-labile cytosolic factors, and are inhibited by N-ethylmaleimide treatment of the cytosol. Binding and translocation are differentially affected by cytosol dilutions, suggesting that at least two distinct soluble fractions are required for nuclear import. The requirements for NLS-mediated nuclear import of plasmid DNA are similar to those for nuclear import of protein-NLS conjugates in permeabilized cells. © 1996 Wiley-Liss, Inc.