The putative 15 S precursor of globin mRNA contains a poly (A) sequence

[3H] Uridine or [3H] adenosine pulse-labelled nuclear RNA was isolated from chicken immature red blood cells and separated on denaturing formamide sucrose gradients. RNA of each gradient fraction was hybridized with unlabelled globin DNA complementary to mRNA (cDNA) and subsequently digested by RNAase A and RNAase T1. The experiments revealed two RNA species with globin coding sequences sedimenting 9 S and approx. 15 S, the latter probably representing a precursor of 9 S globin mRNA. A poly (A) sequence was demonstrated in this RNA by two different approaches. Nuclear RNA pulse-labelled with [3H] uridine was fractionated by chromatography on poly (U)-Sepharose. Part of the 15 S precursor was found in the poly(A)-containing RNA. In the second approach 15 S RNA pulse-labelled with [3H]adenosine was hybridized with globin cDNA, incubated with RNAase A and RNAase T1 and subjected to chromatography on hydroxyapatite. The hybrids were isolated and after separation of the strands degraded with DNAase I, RNAase A and RNAase T1. By this procedure poly(A) sequences of approximately 100 nucleotides could be isolated from the 15 S RNA with globin coding sequences. The poly(A) sequence was completely degraded by RNAase T2.     

The properties and function of rapidly-labelled nuclear RNA

Summary Nuclei were isolated from cultured cells of Acer pseudoplatanus L. previously pulse-labelled with [5-³H]uridine or [³²P]phosphate and the properties of the rapidly-labelled RNA were studied. Polyacrylamide gel electrophoresis showed ribosomal RNA precursors and processing intermediates with molecular weights of 3.4, 2.5, 1.4 and 1×10⁶ daltons, together with polydisperse RNA. The relative proportions of ribosomal RNA precursors and polydisperse RNA varied according to the length of the labelling period, but after 30 min approximately 90% of the radioactive RNA was polydisperse. The relationship between this polydisperse RNA and messenger RNA was investigated. The percentage of total nuclear RNA retained by chromatography on oligodeoxythymidylic acid-cellulose columns varied from 6% to 16% depending on the length of the labelling period. This RNA fraction, which has an adenylic acid content of approximately 45%, is assumed to represent RNA with polyadenylic acid sequences attached. A larger proportion of the nuclear polydisperse RNA lacked polyadenylic acid. Both types of polydisperse RNA were similar in size and during polyacrylamide gel electrophoresis migrated as broad peaks with an average molecular weight of approximately 10⁶ daltons. The polydisperse nuclear RNA that lacks polyadenylic acid was found to be similar in nucleotide composition to ribosomal RNA and is assumed to represent growing chains of ribosomal precursor RNA. After short labelling times the majority of the radioactivity incorporated into nuclear RNA is present in molecules of this type. This suggests that the designation of pulse-labelled polydisperse RNA as messenger RNA or precursor to messenger RNA solely on the basis of rapid labelling and size heterogeneity is unsound. The average molecular weight of the polyadenylic acid-containing messenger RNA from the cytoplasm was less than that of the corresponding nuclear RNA (6 and 9×10⁵ daltons respectively). This suggest either that the majority of the nuclear polyadenylic acid-containing RNA does not enter the cytoplasm, or if it does, that it first undergoes a reduction in size.Abbreviations rRNA ribosomal RNA - mRNA messenger - RNA poly(A), polyadenylic acid, poly(A) and poly(A) - RNA RNA with and without poly(A) sequences attached - poly(U) polyuridylic acid - oligo (dT)-cellulose cellulose with oligo deoxythymidylic acid covalently attached - C cytidylic acid - A adenylic acid - G guanylic acid - U uridylic acid     

A characterization of globin mRNA sequences in the nucleus of duck immature red blood cells

Studies were performed with duck immature red blood cells to identify and characterize the globin mRNA sequences in nuclear RNA. Annealing of ³H-globin cDNA to unlabeled nuclear RNA has identified three distinct size classes of nuclear RNA molecules containing globin mRNA sequences. The largest size class contained 1–2% of total nuclear globin mRNA sequences and sedimented through 85% formamide-sucrose gradients at the same rate as 28S ribosomal RNA. Chromatography on oligo(dT)-cellulose indicated that most of these molecules are not polyadenylated. The bulk of nuclear globin mRNA sequences (70%) was contained in polyadenylated RNA molecules which sedimented at 16.5S. The remainder of nuclear globin mRNA sequences (～30%) was detected in molecules sedimenting at 10S (the position of cytoplasmic globin mRNA).To determine whether a precursor-product relationship exists between these nuclear molecules and cytoplasmic globin mRNA, pulse-label and chase experiments were performed. Labeled globin mRNA sequences were assayed by annealing to globin cDNA-cellulose. Labeled 28S nuclear globin RNA sequences could not be detected, perhaps due to technical reasons. 16.5S nuclear globin RNA was labeled and chased into cytoplasmic globin mRNA sequences. The half-life of 16.5S nuclear globin RNA was estimated to be less than 30 min. These results demonstrate that in duck immature red blood cells, globin mRNA is transcribed as a larger precursor. Furthermore, size characterization of this precursor during pulse-label and chase periods suggests that it is processed within the nucleus to 10S globin RNA.     

Ribonucleoprotein organization of polyadenylate sequences in HeLa cell heterogeneous nuclear RNA.

Ribonucleoprotein particles containing heterogeneous nuclear RNA (Pederson, 1974) were isolated from HeLa cells and digested with ribonucleases A and T₁ at high ionic strength. The nuclease-resistant material, comprising 9.4% of the initial acid-insoluble [³H]adenosine radioactivity, was further fractionated by poly(U)-Sepharose chromatography. The bound fraction eluted from the column with 50% formamide and banded in cesium sulfate gradients (without aldehyde fixation) at a buoyant density characteristic of ribonucleoprotein (1.45 g/cm³). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of this material revealed two Coomassie blue-stained bands. The major polypeptide had a molecular weight of 74,000 a less prominent band had a molecular weight of 86,000. The RNA components contained 74.4 mol % AMP and 17.7 mol % UMP. Polyacrylamide gel electrophoresis of the RNA, labeled with [³H]adenosine, demonstrated the presence of molecules 150 to 200 nucleotides in length (poly(A)), as well as molecules 20 to 30 nucleotides long (oligo(A)). Both poly(A) and oligo(A) sequences have previously been identified in HeLa heterogeneous nuclear RNA. These data demonstrate that both the poly (A) and oligo(A) sequences in HeLa heterogeneous nuclear RNA exist in vivo tightly complexed with specific proteins.     

Physical and chemical characterization of purified ovalbumin messenger RNA.

Preparative agarose gel electrophoresis under denaturing conditions has been successfully employed to purify large quantities of ovalbumin mRNA from hen oviducts. The mRNA thus prepared is physically homogeneous based on its migration as a single component on electrophoresis in both analytical acid-urea agarose gels and formamide-containing, neutral polyacrylaminde gels; it also sediments as a single peak in sucrose gradients containing 70% formamide. The mRNA is chemically free of ribosomal RNA contamination since its oligonucleotide fingerprint map after complete T1 ribonuclease digestion contains no detectable specific large oligonucleotide markers of ribosomal RNAs. It is also not contaminated by other biologically active messenger RNAs because, when it is added to the cell-free wheat germ translation system, the only protein product synthesized is ovalbumin as analyzed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and specific immunoprecipitation. Ovalbumin mRNA has a nucleotide composition of 32.3% A, 21.0% G, 25.7% U, and 20.7% C [(A+U)/(G+C) equal 1.41]. The mRNA contains a heterogeneous poly(A) tract ranging from 20 to 140 residues with a number average chain length of 62 adenylate residues. The molecular weight of the sodium salt of the purified mRNA is approximately 650,000 +/- 63,000, corresponding to a chain length of 1890 +/- 180 nucleotides, as determined by electron microscopy under completely denaturing conditions. This value is in close agreement with the values obtained from: (a) sucrose gradient centrifugation in the presence of 70% formamide; (b) evaluation of poly(A) content in the mRNA and the number average chain length of its poly(A) tract; and (c) sedimentation velocity studies in the presence of 3% formaldehyde. When 125I-labeled ovalbumin mRNA is allowed to hybridize with a large excess of chick DNA, the observed kinetics of hybridization reveal no appreciable reaction between the mRNA and the repeated sequences of the chick DNA, although the mRNA appears to be approximately 600 nucleotides longer than necessary to code for ovalbumin. It thus appears that the entire ovalbumin mRNA is primarily transcribed from a unique sequence in the chick genome.     

Nuclear steady-state RNA from chicken immature red blood cells. Distribution of globin-coding and poly (A) sequences

Nuclear steady-state RNA and polysomal RNA of chicken immature red blood cells were isolated and separated on formamide sucrose gradients. For comparison the distribution of 9 S globin mRNA was investigated by gradient centrifugation of 125I-labelled mRNA. The material was either pooled into two fractions (less than 20 S; greater than 20 S) and translated in an Ehrlich ascites cell-free system or each gradient fraction was analyzed by hybridization with [3H]-poly (U) or [3H]-labelled DNA complementary to purified 9 S globin mRNA (globin cDNA). In neither case could evidence be obtained for the existence of a high molecular weight RNA as a probable globin mRNA precursor. Further analysis was performed by electrophoresis of RNA on exponential polyacrylamide gels in formamide and subsequent hybridization with cDNA. The results are consistent with those of gradient centrifugation and demonstrate that the distribution of globin-coding sequences in nuclear steady state RNA corresponds to that of cytoplasmic 9 S globin mRNA.     

Complexity and characterization of polyadenylated RNA in the mouse brain

The complexity of nuclear RNA, poly(A)hnRNA, poly(A)mRNA, and total poly(A)RNA from mouse brain has been measured by saturation hybridization with nonrepeated DNA. These DNA populations were complementary, respectively, to 21, 13.5, 3.8, and 13.3% of the DNA. From the RNA Cot required to achieve half-sturation, it was estimated that about 2.5–3% of the mass of total nuclear RNA constituted most of the complexity. Similarly, complexity driver molecules constituted 6–7% of the mass of the poly(A)hnRNA. 75–80% of the poly(A)mRNA diversity is contained in an estimated 4–5% of the mass of this mRNA. Poly(A)hnRNA constituted about 20% of the mass of nuclear RNA and was comprised of molecules which sedimented in DMSO-sucrose gradients largely between 16S and 60S. The number average size of poly(A)hnRNA determined by sedimentation, electron microscopy, or poly(A) content was 4200–4800 nucleotides. Poly(A)mRNA constituted about 2% of the total polysomal RNA, and the number average size was 1100–1400 nucleotides. The complexity of whole cell poly(A)RNA, which contains both poly(A)hnRNA and poly(A)mRNA populations, was the same as poly(A)hnRNA. This implies that cytoplasmic polyadenylation does not occur to any apparent qualitative extent and that poly(A)mRNA is a subset of the poly(A)hnRNA population. The complexity of poly(A)hnRNA and poly(A)mRNA in kilobases was 5 × 10⁵ and 1.4 × 10⁵, respectively. DNA which hybridized with poly(A)mRNA renatures in the presence of excess total DNA at the same rate as nonrepetitive tracer DNA. Hence saturation values are due to hybridization with nonrepeated DNA and are therefore a direct measure of the sequence complexity of poly(A)mRNA. These results indicate that the nonrepeated sequence complexity of the poly(A)mRNA population is equal to about one fourth that observed for poly(A)hnRNA.     

RIBOSOME SYNTHESIS IN TETRAHYMENA PYRIFORMIS

The cellular site of synthesis of ribosomal RNA in Tetrahymena pyriformis was studied by analyzing the purified nuclear and cytoplasmic RNA from cells pulse labeled with uridine-³H. The results of studies using zonal centrifugation in sucrose density gradients show that the ribosomal RNA is synthesized in the nucleus as a large precursor molecule sedimenting at 35S. The 35S molecule undergoes rapid transformation through two main nuclear intermediates, sedimenting at about 30S and 26S. The smaller ribosomal RNA (17S) appears first in the cytoplasm and it seems to be absent from the nucleus. The apparent delay in the appearance of the larger ribosomal RNA (26S) in the cytoplasm is due to the presence of a larger pool of its precursors in the nucleus as indicated by pulse-chase experiments. The newly synthesized ribosomal RNA's appear in the cytoplasm as discrete 60S and 45S ribonucleoprotein particles, before their incorporation into the polysomes.     

Biochemical evidence of haploid gene activity in spermatogenesis of the mouse

Mice were exposed to two X-ray doses of 300 and 100 R with 4 days interval in order to deplete the testes of spermatogonia and early meiotic cells. After X-ray treatment, the seminiferous tubules were labelled in culture with radioactive RNA precursors, dispersed into single cells by trypsin treatment and these were fractionated into several cell classes by velocity sedimentation at unit gravity in a Ficoll gradient. With this method quasi-homogeneous populations of middle-late pachytene spermatocytes and round spermatids (steps 1–8 of spermiogenesis) were obtained. RNA was extracted from these two cell types and analysed by linear sucrose gradient fractionation and by affinity chromatography on a poly(U)-Sepharose column. The results showed that round spermatids, as well as pachytene spermatocytes, synthesize both ribosomal RNA (rRNA) and poly(A)⁺ RNA (presumptive messenger RNA) (mRNA). The post-meiotic synthesis of RNA ceases completely in mid-spermiogenesis after nuclear elongation in spermatids has set in.     

Differential subnuclear distribution of polyadenylate-rich ribonuclei acid during induction of egg-yolk protein synthesis in male Xenopus liver by oestradiol-17 beta.

A 4-8-fold increase in the rate of hepatic nuclear RNA synthesis occurred within 11 h after a single injection of oestradiol-17 beta to male Xenopus to induce egg-yolk protein synthesis. 2. By using a gentle procedure for fractionating nuclei into their major structurally different components [J. R. Tata& B. Baker (1974) Exp. Cell Res. 83. 111-124], it was found that the hormone-induced increase in the total amount of newly made RNA was associated with a 2-10-fold increase in the poly(A) content of nuclear RNA. 3. When the poly (A) content of nuclear RNA was determined by hybridization to poly[3H](U) or specific binding to oligo(dT)-cellulose, most of the increase (10-fold) in poly (A) content of newly synthesized RNA was associated with the euchromatin fractions, whereas the increase was less marked in the other subnuclear fractions. 4. Resolution of nuclear RNA into poly (A)-poor and poly(A)-rich RNA species by chromatography on oligo(dT)-cellulose, followed by polyacrylamide-gel electrophoresis with sodium dodecyl sulphate or in the pressence of 99% formamide, revealed that the hormone caused a preferential enhancement of high-molecular-weight (25S-60S) poly (A)-rich HnRNA (heterogeneous nuclear RNA,) much of which was associated with euchromatin and not with the nuclear sap. 5. Induction of vitellogenin in male frogs was in particular characterized by the appearance of a high-molecular-weight polyadenylated component exhibiting a peak at 35-36S, i.e. a molecular weight of approx. 2.05x10(6)+/-0.15x10(6). Although there is no evidence as yet that such a polyadenylated high-molecular-weight nuclear RNA species contains sequences corresponding to vitellogenin mRNA, it is possible that a high proportion of the most stable form of the putative nuclear precursor to vitellogenin mRNA induced by oestrogen in male Xenopus liver may be only marginally bigger than the cytoplasmic mRNA, and may at any one time be predominantly associated with the euchromatin fraction.     

A precursor of globin messenger RNA

The size of pulse-labeled globin messenger RNA nucleotide sequences was investigated, to determine whether newly transcribed globin mRNA molecules are larger than steady-state globin mRNA. Molecular hybridization techniques were used to compare directly the sedimentation of steady-state (unlabeled) and pulse-labeled (radioactive) globin mRNA sequences in the same analytical sucrose gradient. In gradients containing 98% formamide, radioactive globin mRNA sequences from mouse fetal liver cells labeled for 15 to 20 minutes with [³H]uridine sediment in a broad band with a peak at approximately 14 S, while steady-state globin mRNA sediments at 10 S. The large radioactive RNA can be recovered from one gradient and recentrifuged in a second gradient, in which it again sediments in a broad band with a peak at 14 S. The large radioactive RNA is cleaved to 10 S during a 75-minute “chase” with either actinomycin D or unlabeled uridine plus cytidine. The estimated half-life of the precursor is 45 minutes or less under these conditions. A covalent RNA precursor larger than 18 S with a similar turnover rate is not observed.     

Different binding of poly(A)-containing and poly(A)-free fractions of nuclear ribonucleic acid to ribosomes from rat liver.

Total nuclear RNA extracted from nuclei of rat liver cells by phenol/chloroform in the presence of sodium dodecyl sulphate was separated by combined gel filtration on Sepharose 4 B and affinity chromatography on poly(U) Sepharose into fractions differing in their molecular weights and contents of poly(A) sequences. The poly(A)-containing 45-S RNA became labelled most rapidly if rats were administered [3H] orotic acid. This fraction showed a high template activity when added to postmitochondrial supernatants of the Krebs ascites tumour. Fractions of nRNA, free of poly(A) sequences, had no stimulating effect on protein synthesis in this system. The 45-S RNA-containing poly(A) was readily bound to crude polyribosomes from rat liver at 0 degrees C and both ATP and GTP were necessary for this reaction. Sucrose gradient analyses provided evidence that this RNA species is bound predominantly to 80-S ribosomes. No binding was obtained with polyribosomes washed with 0.5 M KCl. The binding ability of washed polyribosomes was restored by the addition of the ribosomal wash fraction or rat liver cytosol. Crude polyribosomes bound significantly lower quantities of nRNA species free of poly(A) when compared with poly(A)-45-S RNA. The label was scattered through the whole ribosomal sedimentation pattern with no predominant peaks and the binding reaction required neither soluble factors nor nucleotide cofactors. The labelling kinetics and high template activity of poly(A)-45-S nRNA indicate that this fraction contains precursors of cytoplasmic mRNA. Requirements for soluble factors and nucleotide cofactors in the binding of this RNA species to 80-S ribosomes suggest that this binding, unlike that of other nRNA species, has a specific mechanism resembling that of mRNA binding during peptide initiation.     

The identification of globin messenger ribonucleic acid in newt erythropoietic cells.

Polyadenylated [poly(A)+]-RNA isolated from newt (Triturus cristatus) erythropoietic cells contained two main species sedimenting at 9S and 25S, and minor amounts of a 15-20S component. The 9S poly(A)+-RNA fraction induced synthesis of newt haemoglobin and globins in frog oocytes and in an mRNA-dependent rabbit reticulocyte lysate, confirming its identity as newt globin mRNA. Translation of 9S globin mRNA in reticulocyte lysate was concentration-dependent, the patterns of globin synthesis suggesting both preferential utilization and unequal amounts of the different globin mRNA subspecies. Globin mRNA activity was also evident in the 25S poly(A)+-RNA fraction whose localization in polyribosomes excluded its function as a nuclear globin mRNA precursor. Denaturation in formamide and estimation of its relative methyl content indicated that the 25S poly(A)+-RNA fraction contained equimolar amounts of 9S globin mRNA and 26S rRNA. Translation of the 25S fraction in reticulocyte lysate was less efficient than that of comparable amounts of 9S globin mRNA and induced a pattern of globin synthesis similar to that obtained with subsaturating amounts of 9S mRNA. The 25S mRNA-rRNA complex was considered to be a non-physiological aggregate generated by extraction of RNA in the presence of buffers of moderate to high ionic strength.     

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.     

STUDIES ON THE LABELLING PATTERNS OF RNA FROM CEREBRAL CORTEX NUCLEI

RNA labelling patterns in nuclei from rat cerebral cortex were investigated subsequent to intracerebral injection of [³H]uridine. Although there was a rapid uptake of label into the ‘heavy’ regions when nuclear RNA was analysed in density gradients, it was not possible to show conclusive evidence for 455 ribosomal precursor RNA. Methyl-ation of 18S and 28S nuclear RNA became evident only after 2 hr and did not appear to involve the intermediacy of RNA species of higher molecular weight.