RNA synthesis in nuclei isolated from early embryos of Xenopus laevis.

1. Rates of RNA synthesis in isolated Xenopus embryo nuclei decrease from blastula through gastrula and neurula stages to hatching tadpoles. 2. In blastula and gastrula nuclei, net synthesis of RNA continues for over 30 min, both in the presence of KCl at 0.4 M and in its absence. In nuclei from later stages, net synthesis continues for only about 10 min in the absence of KCl. 3. At low ionic strength, RNA synthesis in all nuclei is greater with optimum Mg-2+ (6 mM) than with optimum Mn-2+ (1 mM). At high ionic strength the reverse is true. 4. An unusual feature, which gradually disappears as development proceeds, is that curves relating RNA synthesis to KCl concentration show a peak at 0.1 M KCl. In blastula nuclei, RNA synthesis is more rapid at 0.1 M KCl than at 0.4 M. 5. This peak at low ionic strength is not observed in the presence of the initiation inhibitor rifamycin AF/013. It is concluded that the peak arises from initiation of RNA synthesis by an excess of RNA polymerases bound non-specifically to the isolated nuclei. The residual synthesis, representing elongation of chains that were initiated in vivo, still declines as development progresses. 6. In blastula nuclei, over half of the RNA synthesis is effected by polymerase II (inhibited by alpha-amanitin), the proportion remaining roughly constant with increasing ionic strength. In neurula nuclei, the proportion rises from about one-half to three-quarters. The initiation-dependent peak in blastula and gastrula nuclei is contributed by both alpha-amanitin-sensitive and alpha-amanitin-resistant enzymes.     

Identification of mRNA in the slime mold Physarum polycephalum.

Using a differential extraction procedure which had previously been shown to yield one nucleic acid fraction enriched in cytoplasmic RNA and another enriched in nuclear RNA, we have been able to isolate two polyadenylated RNA populations from microplasmodia of Physarum polycephalum. The poly(A)-containing RNA from the cytoplasmic-enriched fraction accounts for approximately 1.2% of the cytoplasmic nucleic acid, has a number-average nucleotide size of 1339+/- 39 nucleotides, and has been shown, in a protein-synthesizing system in vitro, to be capable of directing the synthesis of peptides which have also been shown to be synthesized in vivo by microplasmodia. The poly(A)-containing RNA from the nuclear-enriched fraction has a number-average nucleotide size of 1533 +/- 104 nucleotides and represents a mixture of cytoplasmic and nuclear adenylated RNA molecules. Based upon these observations, we have identified the polyadenylated RNA isolated from the fraction enriched in cytoplasmic nuclei acid as Physarum poly(A)-containing messenger RNA.     

The role of RNA primer in discontinuous DNA replication in isolated nuclei from HeLa cells

RNA-primed discontinuous DNA synthesis was studied in an in vitro system consisting of washed nuclei from synchronized S-phase HeLa cells. A new technique proved useful for the purification of short nascent fragments of DNA (Okazaki fragments). Mercurated dCTP was substituted for dCTP in the DNA synthesis reaction. Short nascent pieces (4–6 S) of mercurated DNA were found to bind preferentially to sulfhydryl-agarose, and could be eluted with mercaptoethanol. The isolated fragments were assayed for the presence of covalently linked RNA by the spleen exonuclease method described by Kurosawa et al. (Kurosawa, Y., Ogawa, T., Hirose, S., Okazaki, T. and Okazaki, R. (1975) J. Mol. Biol. 96, 653–664). Following a 30 s incubation with [³H]TTP in the absence of added ribonucleotides, approximately 20% of the nascent strands synthesized in washed nuclear preparations had RNA attached. These RNA primers either preexisted in the nuclei or were formed from endogenous ribonucleotides. The 5′ ends of the primers appeared to be largely in a phosphorylated state. In the absence of added ribonucleotides, these RNA-DNA linkages disappeared within 2 min, whereas if ribonucleotides were added, the number of RNA primers increased to 40% and remained at this level for greater than 2 min. To obtain maximal levels of RNA primer, the addition of all three of the ribonucleotides, rCTP, rGTP and rUTP (0.1 mM), as well as high levels of rATP (5 mM) was required. Addition of ribonucleotides also markedly enhanced the amount of nascent DNA fragments synthesized. However, in the absence of added ribonucleotides, after RNA primers had disappeared, nascent DNA fragments were still initiated at a significant rate. These results suggest that RNA primers play an important role in the initiation of Okazaki fragments but that synthesis can also be initiated by alternative mechanisms. An important role for ATP in RNA primer synthesis is suggested.     

Nuclear columns, Kinetics of RNA synthesis and release in isolated rat liver nuclei

By continuous perfusion of columns containing isolated immobilized rat liver nuclei with media containing labeled RNA precursors, the in vitro synthesis and release of RNA was studied. The combined reaction of synthesis and release could be adjusted to proceed at a constant rate. The reaction rate responded to variation of termperature, ionic conditions, nucleoside triphosphate concentration and to the addition of RNA polymerase inhibitors. During 60 min perfusion approximately equal amounts of radioactive low molecular weight RNA and of ribonucleoproteins were released. Pulse-chase experiments showed that the low molecular weight RNA was synthesized throughout the perfusion and released immediately after formation. The ribonucleoproteins were primarly labeled during the first period of perfusion and were gradually released. Synthesis of RNA contained in the ribonucleoproteins was inhibited by low alpha-amanitin concentrations, indicating that it was catalyzed by RNA polymerase II. The in vitro labeled ribonucleoproteins exhibited properties of the stable nuclear particles which can be extracted from isolated nuclei after rapid in vivo labeling of RNA. They had a buoyant density of 1.41--1.43 in CsCl, were partially unstable in 1% deoxycholate, but stable in 0.1% deoxycholate, in 100 mM NaCl and in 10 mM EDTA. Due to the dilution by the perfusion medium, the ribonucleoproteins sedimented with a peak at 22--27 S, and not at 30--45 S. The RNA synthesized in the immobilized nuclei was not degraded during the perfusion. Less than 20% was gradually released, whereby the 20--30 S peak zone was reduced. While the properties of the in vitro labeled ribonucleoproteins and of rapidly in vivo labeled ribonucleoproteins were the same, the kinetics of their release differed.     

Prior interaction of ATP with yeast mRNAs enhances protein synthesis at the initiation step

ATP hydrolysis is important for different stages of the protein synthesis process. A novel effect of this nucleotide was detected using mRNAs isolated from S. cerevisiae after phenol extraction of polysomes. When polysomal mRNA (pmRNA) or poly(A)(+) RNA were preincubated with ATP (approximately 3 mM, near physiological concentration), their translational activity in a cell-free system from yeast was stimulated 2-3 fold. This increased translational activity is specific for the poly(A)(+) RNA fraction, correlates with facilitated assembly of 80S initiation complexes, and is associated to increased synthesis of high molecular weight polypeptides. TCA precipitation assays of RNA incubated with [(14)C]ATP suggested an association of the nucleotide with the nucleic acid. The amount of [(14)C]ATP co-precipitated was dependent on magnesium (optimum at 5-6 mM), was partially inhibited by monovalent ions, and was maximal with poli(A)(+) RNA. Existence of RNA-associated kinases or ATPases appear unlikely since neither phosphorylation nor nucleotide hydrolysis were observed during preincubation of pmRNA with ATP. Another evidence of ATP-RNA interaction was an increased absorbance at 260 nm after incubation suggesting unwinding of the RNA secondary structure. Therefore, preincubation with ATP may affect the conformation of mRNAs and thereby facilitate the initiation of protein synthesis. This event could be part of an in vivo energy-dependent mechanism for translational control.     

Endogenous messenger ribonucleic acid-directed polypeptide chain elongation in a cell-free system from the yeast Saccharomyces cerevisiae.

An in vitro protein-synthesizing system from the yeast Saccharomyces cerevisiae has been made by a modification of the procedure for preparation of the Krebs ascites system. The protein synthetic activity is directed by endogenous messenger. Amino acid incorporation occurs over a broad range of magnesium and potassium concentration, being maximal at 6 and 85 mM, respcetively. The activity of this in vitro system is due to the elongation of polypeptides whose synthesis was initiated in vivo. The cell extract does not initiate synthesis with endogenous messenger ribonucleic acid (RNA), since 1 muM pactamycin, which blocks initiation on prokaryotic or eukaryotic ribosomes invitro, fails to decrease amino acid incorporation. Ten micromolar cycloheximide, however, inhibits incorporation by 87%. Moreover, this system is not stimulated by rabbit reticulocyte polysomal RNA, which directs the synthesis of hemoglobin in extracts of Krebs ascites cells. The translation of this messenger is not masked by high endogenous incorporation, because autoradiography of sodium dodecyl sulfate-polyacrylamide gels containing [35-S]methionine-labeled products shows that no hemoglobin is made. Preincubation of this system, which reduces the high endogenous incorporation by 80%, does not increase its capacity to be stimulated by either rabbit reticulocyte RNA or yeast polyriboadenylic acid-containing RNA. Polyuridylic acid, however, does stimulate polyphenylalanine incorporation. The failure of the yeast lysate to be stimulated by or to translate added natural messenger RNA, its insensitivity to low levels of pactamycin but inhibition by cycloheximide, and its relatively high magnesium optimum (the same as that for polyuridylic acid) suggest that it elongates but does not initiate polypeptide chains.     

Translation of silk fibroin messenger RNA in an Ehrlich ascites cell-free extract.

RNA identified by its base composition and T1 RNase oligonucleotide pattern as the message for silk fibroin was purified from mature posterior silk glands of Bombyx mori larvae and used to direct polypeptide synthesis in an Ehrlich ascites cell-free extract. Fibroin mRNA stimulated [3-H]alanine incorporation about 3- to 4-fold in the presence of 80 mM K+ and 4 mM Mg-2+. The stimulation was reduced in the presence of 5 times 10-minus 6 to 10-minus 4 M aurintricarboxylic acid, an inhibitor of the initiation of protein synthesis. The cell-free products were heterogeneous in size, including peptides as large as 100,000 daltons. They co-precipitated with carrier fibroin sequences after digestion with trypsin. A large fraction of the polypeptides synthesized in response to fibroin mRNA was precipitated by antiserum directed against amino acid sequences in noncrystalline region polypeptides of fibroin. Furthermore, after digestion with chymotrypsin, a major fraction of the cell-free products specifically co-precipitated with crystalline region sequences of native fibroin. The size and amino acid composition of the fibroin crystalline region polypeptides isolated from the cell-free products were similar to those from native fibroin.     

RNA synthesis in isolated polytene nuclei from Chironomus tentans

An RNA synthesizing system with isolated polytene nuclei from Chironomus tentans is described. This system allows one to monitor the effect of salt concentration on chromosome structure and to assign in vitro RNA synthesis to structural modifications of the chromosome (i.e. nucleoli, Balbiani rings and puffs).-At a salt concentration of 0.15 M monovalent cations (standard salt medium=SSM) chromosomal structure appears to be best preserved during in vitro incubation. At low and high ionic strength the bands decondense and the microscopically visible chromosomal structure is lost completely. These three states of condensation and decondensation are distinguished with respect to RNA synthesis: (1) in low salt overall RNA synthesis is depressed, (2) in SSM ribosomal RNA synthesis predominates and continues for 30 min, (3) in high salt RNA synthesis is stimulated 3–4 fold again. This stimulation is due solely to chromosomal, non-ribosomal RNA synthesis, which proceeds in high salt for more than 10 h, though new initiation of RNA chains is prevented. Molecular weight determinations of the RNA synthesized demonstrate a time dependent increase in size of the newly synthesized molecules under these conditions. — Autoradiographs of nuclei incubated in SSM reveal prominent label in nucleoli, significant label in Balbiani rings and rather reduced activity at other sites. Addition of various exogenous RNA polymerases does not markedly alter this pattern. Autoradiographs of nuclei incubated in high salt exhibit extensive RNA synthesis spread over the chromosomes. Preparations of autoradiographs from isolated chromosomes show that the high salt induced label is localized in single bands. Though the majority of bands is still unlabelled, the actual number of bands exhibiting incorporation in high salt is higher than in any individual functional state in vivo. These results are discussed in terms of activated and preactivated genes.     

Hormonal regulation of transcription of rDNA: use of nucleoside thiotriphosphates to measure initiation in isolated nuclei

Nuclei isolated from cultured mouse and rat cell lines initiated pre-rRNA chains at the correct site and with the correct nucleotide specificity (A for mouse, G for rat). Nucleic acid filter hybridization and S1 nuclease mapping were used to analyze the RNA products initiated with nucleoside (beta-S)triphosphates. Initiation of pre-rRNA was completely resistant to alpha-amanitin but was inhibited by either actinomycin D or heparin. Experiments with P1798 mouse lymphoma cells indicated that the antiproliferative effects of glucocorticoids on lymphoid cells includes a reduction in the ability of nuclei to initiate pre-rRNA chains.     

Enzymatic properties of viral replication complexes isolated from adenovirus type 2-infected HeLa cell nuclei.

When HeLa cell nuclei, isolated 17 h after infection with adenovirus type 2 (Ad2), were extracted with 200 mM ammonium sulfate, Ad2 nucleoprotein complexes were selectively released. These complexes contained a DNA polymerase activity that corresponded to DNA polymerase molecules actively engaged in Ad2 DNA replication. Under our high-salt (200 mM ammonium sulfate) incubation conditions, where no reinitiation occurred, full-length Ad2 DNA chains were synthesized by elongation of chains that had been initiated in vivo. This conclusion was further supported by density labeling experiments indicating that the in vitro DNA synthesis was semiconservative. Evidence is presented suggesting that at least part of the DNA polymerase molecules engaged in Ad2 DNA replication belong to the gamma class.     

Sensitivity of progesterone receptors to aurintricarboxylic acid: Inhibition of nuclear uptake,ATP and DNA binding

When hen oviduct cytosol samples containing progesterone receptor complexed to [³H]progesterone were included with isolated nuclei in presence of 0.2 mM aurintricarboxylic acid, more than 50% inhibition occurred in the uptake of progesterone receptor by the nuclei. The activated form of progesterone receptor appeared to be more sensitive to the presence of aurintricarboxylic acid since pretreatment of non-activated progesterone receptor with the inhibitor and the subsequent removal of the latter prior to activation did not result in the inhibition of receptor uptake by the nuclei. Also, the binding of progesterone receptor to columns of DNA-cellulose or ATP-Sepharose was abolished under simmilar conditions. When nuclei, ATP-Sepharose or DNA-cellulose were preincubated with the inhibitor prior to the addition of receptor preparations, no such inhibition resulted indicating that the inhibitor may be interacting with the receptor protein and not complexing to ATP, DNA or sites in the nuclei. The steroid binding properties of progesterone receptor, however, remained intact under these conditions. Both A and B forms of progesterone receptor are equally sensitive to aurintricarboxylic acid presence when tested for their nuclear uptake. Aurintricarboxylic acid was also found to be very effective at low concentrations (0.25 mM) in eluting the receptor complexes off ATP-Sepharose columns without disrupting the steroid binding properties of progesterone receptor. Our results suggest that auintricarboxylic acid is an effective inhibitor of progesterone receptor and that it may be acting by interfering with a site(s) on progesterone receptor which may be exposed upon activation and are involved in such processes as ATP binding, nuclear uptake and DNA binding. These observations suggest the use of aurintricarboxylic acid as a chemical probe for the analysis of progesterone receptor.     

Preparation of a cell-free extract from rat brain which can initiate protein synthesis in vitro

A cell-free protein synthesis system, derived from brains of 3 mo-old male Fischer-344 rats, has been characterized. The optimum conditions for amino acid incorporation in the system were 5 mM magnesium ion and 200 mM potassium ion. Incorporation depended on the addition of ATP, GTP, and an enegy-generating system, and was sensitive to addition of the drugs aurintricarboxylic acid and sodium fluoride, inhibitors of initiation of protein synthesis. Both 40S and 80S initiation complexes were labeled in vitro, using [³⁵S]methionine. Such labeling was sensitive to the protein synthesis inhibitors, aurintricarboxylic acid and sodium fluoride. The system, which can initiate protein synthesis, should be of use for examining mechanisms which underlie alterations in rat brain protein synthesis induced by various treatments.