Changes in RNA metabolism and accumulation of presumptive messenger RNA during transition from the growing to the quiescent state of cultured mouse fibroblasts.

Mouse fibroblasts maintained in tissue culture regulate total protein and ribosomal RNA synthesis co-ordinately with changes in the cellular growth state. Here we show that changes in the rate of synthesis of nuclear non-polyadenylic acid-containing RNA and the rate of accumulation and breakdown of cytoplasmic ribosomal RNA also accompany the transition from the resting to the growing cellular growth state, while the rate of synthesis of nuclear poly (A)-containing RNA and the rates of accumulation and breakdown of cytoplasmic poly(A) containing RNA (presumptive messenger RNA) are, however, only marginally changed. The small net increase (20% to 30%) in the amount of presumptive mRNA is considerably less than the observed increase in protein synthesis (two to threefold) during this transition. We also isolated and characterized extra-polysomal poly(A)-containing ribonucleoprotein particles from quiescent cultures that were similar to those particles obtained by treatment of polyribosomes with EDTA. These experiments suggest that the early increase in protein synthetic activity when quiescent, cultured cells are induced to grow is partially caused by an increased attachment of pre-existing mRNA molecules to free ribosomes.     

A small nuclear precursor of messenger RNA in the cellular slime mold Dictyostelium discoideum

Previous work (Firtel et al., 1972) showed that messenger RNA from the cellular slime mold Dictyostelium discoideum, like that from mammalian cells, contains a sequence of about 100 adenylic acid residues at the 3′ end. We show here that Dictyostelium nuclei, labeled under a variety of conditions, do not contain material analogous to the large nuclear heterogeneous RNA found in mammalian cells. Rather, the majority of pulse-labeled nuclear RNA that is not a precursor of ribosomal RNA does contain at least one sequence of polyadenylic acid; this RNA, with an average molecular weight of 500,000, appears to be only 20% larger than cytoplasmic messenger RNA.Pulse-labeling experiments show that the nuclear poly(A)-containing RNA is a material precursor of messenger RNA. Whereas previous work showed that over 90% of messenger RNA sequences are transcribed from non-reiterated DNA, we show here that about 25% of nuclear poly (A)-containing RNA is transcribed from reiterated DNA sequences and only 75% from single-copy DNA. We present evidence that a large fraction of the nuclear poly(A)-containing RNA contains, at the 5′ end, a sequence of about 300 nucleotides that is transcribed from repetitive DNA, and which is lost before transport of messenger RNA into the cytoplasm.Based on these and other results, we present a model of arrangement of repetitive and single-copy DNA sequences in the Dictyostelium chromosome.     

Synthesis of messenger and ribosomal RNA precursors in isolated nuclei of the cellular slime mold Dictyostelium discoideum

When incubated with all four ribonucleoside triphosphates, isolated nuclei of the cellular slime mold, Dictyostelium discoideum, will synthesize RNA linearly for 10 to 50 minutes, depending on the salt concentration of the reaction. A fraction (10 to 30%) of the RNA labeled in isolated nuclei binds to immobilized polyuridylic acid. By the following criteria this RNA species is identical to the messenger RNA precursor characterized in whole cells: (a) both contain polyadenylic acid sequences of identical size; (b) they have the same base composition; (c) they have the same mean size as determined by dimethylsulfoxide—sucrose centrifugation; (d) they renature to excess nuclear DNA with similar kinetics; and (e) synthesis of both RNAs is resistant to 2 to 3 μg of actinomycin D/ml. Two independent RNA polymerase activities appear to synthesize poly(A)-containing RNA in isolated nuclei. One is equally active at 0.01 m-KCl and 0.25 m-KCl and is resistant to α-amanitin; the other is considerably more active at the higher salt concentration and is sensitive to α-amanitin. By the criteria of sedimentation coefficients, base composition and sensitivity of synthesis to actinomycin D, the remainder (70 to 90%) of the RNA synthesized by isolated nuclei was identical to cellular ribosomal RNA or its precursors.     

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; )     

Selective inhibition of precursor incorporation into ribosomal RNA in gamma-irradiated Tetrahymena pyriformis.

Sublethal doses of gamma radiation are known to inhibit total RNA synthesis in the ciliate protozoan Tetrahymena. To determine if the synthesis of a particular class of RNA is preferentially inhibited, pulse-labeled RNA was isolated from normal exponentially growing cells, irradiated cells, and cells in which total RNA synthesis had recovered to the pre-irradiation level. The RNAs were analyzed by SDS-polyacrylamide gel electrophoresis and oligo(dT)-cellulose column chromatography. Inhibition of RNA synthesis primarily involves ribosomal RNA. However, radiation does not cause a delay in the processing of precursor rRNA or a preferential loss of either of the mature rRNAs. Following irradiation, poly(A)-containing RNA [poly(A+)RNA] is synthesized at a rate up to three times greater than the control rate. The elevated poly(A+)RNA synthesis occurs during the period of depressed rRNA synthesis and even after rRNA synthesis has recovered to its pre-irradiation rate. While the sizes of the total cellular ribonucleoside triphosphate pools are depressed in the irradiated cells, these pools probably do not represent the actual compartments containing the precursors for RNA synthesis, and the observed changes cannot explain the modifications in macromolecular synthesis in irradiated Tetrahymena.     

Participation of poly(ADP-ribosyl)ation in the depression of RNA synthesis caused by treatment of mouse lymphoma cells with methylnitrosourea

When mouse lymphoma cells (L-1210) are treated with methylnitrosourea, a DNA-damaging agent, polyadenosine diphosphoribose (poly(ADP-ribose)) synthetase activity increases 5-8-fold in 2-3 h, while RNA polymerase activity remains constant for an initial 2 h and then gradually decreases to 25-30% of the control level in 5 h. Both alpha-amanitin-sensitive and -resistant RNA polymerase activities are depressed to the same degree by the treatment with methylnitrosourea. The depression in RNA synthesis is virtually prevented when the treated cells are cultured in the presence of 3-aminobenzamide, a specific inhibitor of poly(ADP-ribose) synthetase. Analyses of the RNA extracted from the cells labeled with [3H]uridine by agarose gel electrophoresis and by poly(U)-Sepharose column chromatography show that the contents of ribosomal precursor RNA and poly(A)-containing RNA are both low in the methylnitrosourea-treated cells as compared with those in the untreated cells and that the reduction in the contents of these kinds of RNA is almost completely prevented by the addition of 3-aminobenzamide to the culture medium. These results suggest that the enhancement of poly(ADP-ribosyl)ation causes the decrease in both synthesis of ribosomal RNA and messenger RNA.     

Characterization and messenger activity of poly(A)-containing RNA from Chlorella.

Poly(A)-containing RNA was isolated by cellulose column chromatography from total RNA extracted from Chlorella fusca var. vacuolata 211/8p. RNA retained by the column was identified as poly(A)-containing RNA because it contained ribonuclease-resistant tracts, 25 to 55 nucleotides in length, from which not less than 80% of base was found to be adenine after acid hydrolysis. The base composition of poly(A)-containing RNA differed from that of RNA (largely ribosomal) which did not adsorb to cellulose, having a higher adenine content and a lower guanine content. Poly(A)-containing RNA was polydisperse including molecules with mobilities from 10S to 40S with a mean of about 20S. In an in vitro system derived from wheat-germ, protein synthesis was stimulated by adding poly(A)-containing RNA from Chlorella. Optimum conditions were established in this system with respect to the amount of poly(A)-containing RNA added and the concentration of KCl and Mg-2+. It is proposed that, in Chlorella, poly(A)-containing RNA includes cytoplasmic mRNA as has been shown for some other eucaryotic organisms.     

Biochemical studies of mammalian oogenesis: synthesis and stability of various classes of RNA during growth of the mouse oocyte in vitro

The synthesis of various classes of RNA in mouse oocytes at different stages of growth has been examined after incubating follicles in medium containing radiolabeled uridine. After fractionation on poly(U)-Sepharose of radiolabeled oocyte RNA, of which about 83% is associated with the nucleus after a 5-hr labeling period, revealed that about 40–50% of the radiolabeled RNA behaved as poly(A)-containing RNA. This value remained fairly constant during the period of oocyte growth in which oocyte diameter increased from about 35 to about 55 μm. After a 5-hr labeling, the percentage of radiolabeled poly(A)-containing RNA in either the fully grown dictyate oocyte, metaphase II oocyte, or one-cell embryo was about 20%. After a 5-hr labeling, agarose gel electrophoretic analysis of the radiolabeled species of oocyte RNA obtained after fractionation on poly(U)-Sepharose revealed the presence of a putative ribosomal RNA precursor, ribosomal (28 and 18 S) RNA, transfer plus 5 S RNA and heterodisperse poly(A)-containing RNA. A significant fraction of the radiolabeled RNA species was quite large (>40 S). The ratios of the relative proportions of the radiolabeled ribosomal RNAs and transfer plus 5 S RNA remained essentially constant during oocyte growth. The stability of various classes of RNA was examined by incubating follicles with radiolabeled uridine, washing the follicles free of radioactivity and culturing the follicles under conditions which support oocyte growth in vitro (Eppig, 1977). Under these conditions, total oocyte radiolabeled RNA was quite stable as determined by retention of acid-insoluble radioactive material ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 28}\text{days}$). However, under conditions in which oocytes are viable but do not grow, the half-life of total RNA was about 4.5 days. Poly(A)-containing RNA was also very stable; after 8 days in culture, about 50% of the radiolabeled poly(A)-containing RNA present after 5 hr of labeling was still present. Agarose gel electrophoretic analysis of radiolabeled RNA in oocytes after 4 days of culture and after fractionation on poly(U)-Sepharose revealed the presence of ribosomal (28 and 18 S) RNA, transfer plus 5 S RNA, and heterodisperse poly(A)-containing RNA. At this time, these RNAs are located in the oocyte cytoplasm. In addition, the molecular weight distribution of poly(A)-containing RNA was significantly lower than that after 5 hr of labeling. The ratios of the relative proportions of radiolabeled ribosomal RNAs and transfer plus 5 S RNA were quite similar to those after 5 hr of labeling.     

Changes in the synthesis of ribosomal ribonucleic acid and of poly(A)-containing ribonucleic acid during the differentiation of intestinal epithelial cells in the rat and in the chick.

Epithelial cells were isolated from rat and chick small intestine by techniques which separated subpopulations of differentiating villus and upper crypt cells from each other and from populations of mitotically dividing lower crypt cells. Incorporation of precursors into epithelial-cell DNA, cytoplasmic rRNA and cytoplasmic poly(A)-containing RNA occurred in the lower crypt cells in vivo when precursor was supplied from the vascular system of the intestine. Incorporation of precursor into 28S and 18S rRNA continued in the upper crypt cells, but occurred to only a very slight extent (if at all) in villus cells, whereas incorporation into poly(A)-containing RNA continued (at a diminishing rate) as the differentiating cells migrated along the villi. When precursor was supplied from the intestinal lumen, its incorporation into DNA and into rRNA of crypt cells was not very different from that observed with the other mode of precursor administration, but incorporation into villus-cell poly(A)-containing RNA then occurred at essentially the same rate in all intestinal epithelial cells in vivo. Cytoplasmic poly(A)-containing RNA appeared to turn over in rat crypt cells with a half-life not exceeding 24 h; crypt-cell rRNA showed no turnover and no evidence could be found for the presence of 'metabolic DNA'.     

Polyadenylic acid-containing RNA and its polyadenylic acid sequences newly synthesized in isolated embryonic cells of Xenopus laevis.

Newly synthesized polyriboadenylic acid [poly(A)]-containing RNA and its poly(A) sequences were isolated and characterized in Xenopus embryonic cells. Upon sedimentation analysis, the poly(A)-containing RNA labeled for 30 min showed a very heterogeneous size distribution ranging from 9 to >40 S. After 5 hr of labeling, the profile became much less heterogeneous and the main component was distributed in the 9–28 S region. The average molecular weight of 6.5–7.0 × 10⁵ daltons was calculated for the 5-hr labeled RNA. This poly(A)-containing RNA, comprising about 10% of the total labeled RNA, was metabolically stable and accumulated linearly for 5 hr. Gel electrophoresis of the RNA revealed the presence of little or no free poly(A) sequences. Most of the poly(A) sequences, which were isolated from 30-min labeled poly(A)-containing RNA migrated as a single discrete component approximately 150 nucleotides long. In contrast, they were slightly smaller (130 nucleotides long) and more heterogeneous, when obtained from the poly(A)-containing RNA labeled for 5 hr. From these results, it may be likely that the embryonic poly(A)-containing RNA is similar in size to the steady-state population of the poly(A)-containing RNA reported to occur in vitellogenic oocytes and cultured kidney cells of the same species.     

Turnover of polyadenylate-containing ribonucleic acid in Saccharomyces cerevisiae.

We examined the kinetics of incorporation of [3H]adenine into polyadenylate-containing ribonucleic acid [poly(A)-containing RNA] in yeast. The total poly(A)-containing RNA from spheroplasts and intact cells and the polysomal poly(A)-containing RNA exhibited similar incorporation kinetics. At 30 C half-saturation of the pool of poly(A)-containing RNA with label occurred in approximately 22 min. Since precursor pools appeared to require 5 min to saturate with label, we conclude that at 30 C messenger RNA molecules in yeast decay with an average half-life of 17 min.     

Biochemical studies of mammalian oogenesis: kinetics of accumulation of total and poly(A)-containing RNA during growth of the mouse oocyte

Kinetics of accumulation of total and poly(A)-containing RNA have been measured during growth of the mouse oocyte. Total RNA from oocytes isolated at discrete stages of growth was determined by two independent microassays. The full-grown oocyte contained about 0.60 ng of RNA. Kinetics of accumulation of total RNA with respect to oocyte volume were biphasic. Small, growing oocytes (about 30 pl) contained about 0.20 ng of RNA/oocyte. The amount of RNA increased in a quasi-linear fashion until oocyte volume was about 160 pl, at which point there was about 0.57 ng of RNA/oocyte. Thus oocytes about 65% of their final volume had accumulated about 95% of the total amount of RNA present in the fully-grown oocyte. The relative amount of poly (A)-containing RNA in oocytes of various size was determined by in situ hybridization of [3H] poly (U) to ovarian sections from juvenile mice of known age, followed by autoradiography. The kinetics of accumulation of poly (A)-containing RNA were similar to those of total RNA; oocytes about 70% of their final volume had accumulated about 95% of the amount of poly (A)-containing RNA present in the fully-grown oocyte. The poly(A)-containing RNA resided predominantly in the cytoplasm and no obvious cytoplasmic localization was observed. Kinetics of accumulation of total RNA, which is mainly ribosomal, and poly (A)-containing RNA were consistent with levels of RNA polymerases I and II measured by others during oocyte growth (Moore and Lintern-Moore, '78). The number of ribosomes that could be made from the amount of rRNA present at various stages of growth was compared to the actual number of ribosomes calculated from a published morphometric study (Garcia et al., '79). Kinetic differences in accumulation between the theoretical and actual number of ribosomes suggested oocyte ribosomes are recruited into cytoplasmic lattice structures. These structures accumulate during oocyte growth and have been postulated to be a ribosomal storage form. In addition, the results from this study are compared to results derived from lower species.     

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.     

Comparison of poly(A)-containing RNAs in different cell types of the lower eukaryote Schizophyllum commune

Poly(A)-containing RNAs were isolated from morphologically different cells of the fungus Schizophyllum commune. Using mRNA markers the number-average length of poly(A)-containing RNA in total RNA and in purified poly(A)-containing RNA was estimated as 1100 nucleotides. Number-average length of poly(A)-tracts was 33 nucleotides. 2.5% of total RNA is poly(A)-containing RNA and probably up to 7.5% are non-polyadenylated polydisperse RNA sequences. Saturation hybridization of poly(A)-containing RNA to gap-translated [3H]DNA resulted in 16% of the reactive single-copy DNA to become S1 nuclease resistant. It was found that purified poly(A)-containing RNA represented the entire RNA complexity, i.e. 10 000 different RNA sequences in S. commune. RNA sequences isolated from morphologically different mycelia and from fruiting and non-fruiting mycelia were identical for at least 90%.     

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.     

The stability, polyadenylic acid content and ribonucleoprotein form of nulcear ribonucleic acid in artichoke.

A nuclear preparation, containing 60-80% of the total tissue DNA and less than 0.5% of the total rRNA, was used to characterize the nuclear RNA species synthesized in cultured artichoke explants. The half-lives of the nuclear RNA species were estimated from first-order-decay analyses to be: hnRNA (heterogeneous nuclear RNA) containing poly(A), 38 min; hnRNA lacking poly(A), 37 min; 2.5 X 10(6)-mol. wt. precursor rRNA, 24 min; 1.4 X 10(6)-mol.wt. precursor rRNA, 58 min; 1.0 X 10(6)-mol.wt. precursor rRNA, 52 min. The shorter half-lives are probably overestimates, owing to the time required for equilibration of the nucleotide-precursor pools. The pathway of rRNA synthesis is considered in terms of these kinetic measurements. The rate of accumulation of cytoplasmic polydisperse RNA suggested that as much as 40% of the hnRNA may be transported to the cytoplasm. The 14-25% of the hnRNA that contained a poly(A) tract had an average molecular size of 0.7 X 10(6) daltons. The poly(A) segment was 40-200 nucleotides long, consisted of at least 95% AMP and accounted for 8-10% of the [32P]orthophosphate incorporated into the poly(A)-containing hnRNA. Ribonucleoprotein particles released from nuclei by sonication, lysis in EDTA or incubation in buffer were analysed by sedimentation through sucrose gradients and by isopycnic centrifugation in gradients of metrizamide and CsCl. More than 50% of the hnRNA remained bound to the chromatin after each treatment. The hnRNA was always associated with protein but the densities of isolated particles suggested that the ratio of protein to RNA was lower than that reported for mammalian cells, The particles separated from chromatin were not enriched for poly(A)-containing hnRNA.     

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.     

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.     

Ribosomal RNA metabolism in cucumber leaf mesophyll protoplasts.

Aspects of the metabolism of RNA have been studied in enzymatically isolated protoplasts from cotyledon and first leaf mesophyll tissue of two cultivars of cucumber. The first leaf mesophyll protoplasts incorporated (3H)-uridine into ribosomal RNA at a constant rate for up to 25 hr in a simple salts medium and for up to 45 hr in a growth medium. Pulse-chase labelling experiments on such preparations showed a rapid dilution of the intracellular (3H)-uridine pool(s) and a high metabolic rate in the cells in one cultivar but not in another. Gel electrophoretic analysis of the RNA from both cotyledon and first leaf protoplasts showed that both protoplast types incorporated either (14C)- or (3H)-uridine into ribosomal RNA species. Incorporation of (3H)-uridine into chloroplasts RNA was minimal in cotyledon protoplasts, but significant in leaf protoplasts. Greater incorporation into the chloroplast RNA species could be achieved by longer pulses. Synthesis of all of the ribosomal RNA species was sensitive to actinomycin D at 10 and 25 mug/ml concentrations in all protoplasts tested.