Insulin-modulated transport of RNA from isolated live nuclei

The addition of 3 × 10^?7m insulin to a cell-free RNA transport system caused an increase of 50% in the release of messenger-like RNA from 30-min prelabeled rat liver nuclei. Insulin concentrations above 1.2 × 10^?6m inhibited RNA release. These hormonal effects were not observed when nuclei were prepared from the insulin-resistant Zucker rat (fa/fa), while the level of stimulation in the heterozygote was approximately one-half that observed with normal liver nuclei. Nuclei prelabeled for 120 min and releasing predominantly ribosomal RNA also did not respond to insulin added to the cell-free system. The hormone appears to affect primarily mRNA transport rather than processing.     

Some features of nucleo-cytoplasmic RNA transport from isolated nuclei

Messenger RNA is released preferentially from isolated rat liver nuclei in the presence of the ATP-generating system and cytosol. The release is suppressed by spermidine, while cytoplasmic RNase inhibitor was ineffective and PCMB like some other thiol-blocking agents inhibitory. Cytoplasmic SOD added to the system strongly suppressed RNA release. A similar effect could be obtained by anaerobiosis due to addition of SMP. In both cases the inhibition is reversed by cyanide.In contrast to normal liver where the generation of superoxide radicals takes place almost exclusively in microsomes and is coupled with the oxidation of NADPH, in mouse ascites hepatoma 22a the generation of superoxide radicals occurs mainly in the nuclear envelope and is coupled with the oxidation of both NADPH and NADH and inhibited by cyanide.Abbreviations PCMB p-Chloromercuri benzoate - SMP Submitochondrial particles - SOD Superoxide dismutase     

RNA metabolism in nuclei: selective transport of kappa exons from myeloma nuclei and adenoviral transcripts from infected HeLa nuclei.

Two independent systems and several analytical procedures have been used to establish that isolated mammalian nuclei selectively transport mature RNA polymerase I and II products. Murine myeloma nuclei retain physiologic restriction in our transport assay as assessed by the transport of the immunoglobulin kappa light chain mRNA and 18S and 28S rRNAs. Nearly 50% of the total kappa exons are transported as structurally intact mature mRNA molecules while less than 8% of either pulse-labeled or steady state kappa intron sequences are detected in the transported fraction. Ribosomal external transcribed spacer sequences also are absent in transported RNA. Release of cytoplasmic RNA from the outer nuclear membrane during the transport assay accounts for less than 10% of transported RNA. Nuclei isolated from adenovirus-infected HeLa cells at 20 hours post infection retain cellular actin mRNA and transport viral poly A+RNA. Ribosomal RNA is transported from infected nuclei although at a reduced rate compared to transport from mock-infected nuclei. Inhibition of transport of host mRNA is paralleled by the absence of pulse-labeled actin mRNA in the cytoplasm of infected cells. The implications of our transport data in relationship to intranuclear RNA trafficking are discussed.     

RNA transport from isolated nuclei of cultured Djungarian hamster cells

The in vitro system of RNA transport containing isolated nuclei of Djungarian hamster cells transformed by SV-40 virus was studied. A functional test for cytoplasmic contaminations of the nuclei was proposed. The release of the newly synthesized RNA was found to be dependent on the duration of incubation, temperature and pH of the incubation medium as well as on the presence of spermine, spermidine, dithiothreitol, Mg2+, EDTA, exogenous RNA, nucleoside triphosphates and cytosol. The results obtained indicate that RNA release is an active process with activation energy of 12 kcal/mol. ATP, GTP, CTP and UTP have equal ability to serve as energy sources for the release of RNA. The nucleoside triphosphatase activity of the nuclei was the same in the presence of these four nucleoside triphosphates.     

RNA metabolism in isolated nuclei: effect of temperature on RNA transport from intact and membrane-denuded nuclei

The kinetics of RNA transport from intact (both inner and outer nuclear membranes present) and membrane-denuded myeloma nuclei were monitored at temperatures between 10 and 37 degrees C. A linear rate for RNA transport was calculated and the log of RNA transported from membrane-denuded nuclei was greater than that transported from intact nuclei and ii) RNA transport from both nuclear preparations exhibited straight line Arrhenius plots. We conclude the nuclear envelope (or a nuclear matrix element) modulates the amount of RNA transported from nuclei and that nuclear membrane thermal phase transitions do not alter the apparent energy of activation for the transport process.     

Nucleocytoplasmic transport of RNA. The effect of 3''-deoxyadenosine triphosphate on RNA release from isolated nuclei.

The addition of 3'-deoxyadenosine (cordycepin) to cells in culture results in the inhibition of the appearance of mRNA in the cytoplasm through a mechanism thought to involve the inhibition of polyadenylate synthesis. I studied the effect of 3'-deoxyadenosine triphosphate, the physiologically active form of 3'-deoxyadenosine, on RNA release from isolated nuclei. Nuclei were isolated from baby-hamster kidney (BHK) fibroblasts that had been given a short pulse of radioactive uridine or adenosine in the presence of a low concentration of actinomycin D before harvest. RNA release from the isolated nuclei under the appropriate incubation conditions was time-, temperature- and ATP-dependent. 3'-Deoxyadenosine triphosphate inhibited RNA release from the isolated nuclei. However, RNA that was restricted to the nuclei during incubation with the drug could be chased out of the nuclei if the incubation medium was replaced with medium containing only ATP. The chased poly(A)+ (polyadenylated) RNA had shortened poly(A) tracts, indicating that poly(A)+ RNA with shortened poly(A) tracts can be transported out of the nucleus. An experiment was designed to test the effect of 3'-deoxyadenosine triphosphate on the release of poly(A)+ RNA at drug concentrations which caused 33 or 64% inhibition of RNA release. The release of poly(A)+ RNA and poly(A)- RNA (not polyadenylated) was equally inhibited by the drug. Thus, although 3'-deoxyadenosine triphosphate does inhibit release of RNA from the nucleus, it would appear that the drug does so through a mechanism independent of the inhibition of polyadenylation. The process that is inhibited must be one that is common to both poly(A)+ and poly(A)- RNA. The possibility that 3'-deoxyadenosine triphosphate inhibits a reaction at the nuclear membrane or nuclear pore complex is considered.     

RNA metabolism in nuclei isolated from HeLa cells.

Nuclei with low cytoplasmic contamination, capable of synthesizing RNA for an extended period of time, were prepared from HeLa cells. Besides elongating RNA chains already initiated in vivo, the nuclear preparation initiates the synthesis of new RNA chains. This was shown by labelling the newly synthesized RNA with [gamma-32P]GTP and by detecting the presence of labelled guanosine tetraphosphate among the alkaline hydrolysis products of synthesized RNA. By synthesizing RNA in the presence of each of the four gamma-32P-labelled nucleoside triphosphates, it was possible to conclude that RNA chain synthesis starts predominantly with a purine base. Both nucleolar and nucleoplasmic RNAs are made. The nuclear preparation methylates the nucleolar RNA by utilizing S-adenosyl-L-methionine as a methyl-group donor.     

RNA synthesis in isolated HeLa cell nuclei.

RNA synthesis has been studied in isolated nuclei of HeLa cells. The incubation medium has been optimized for RNA synthesis and the requirements for the presence of specific components previously used by other investigators has been examined. Nuclei isolated by centrifugation through 2 M sucrose synthesize RNA linearly for at least 1 h only at low temperature (25 degrees C). Low molecular weight RNA is found in the supernatant fraction after incubation; this RNA accounts for about 10% of the RNA synthesized. The RNA which remains within nuclei is of high molecular weight and processing of this RNA into molecules of the size of cytoplasmic mRNA does not seem to occur in isolated nuclei. We have studied the effect of an inhibitor of protein-nucleic acid interaction - aurintricarboxylic acid - on RNA synthesis by isolated nuclei. At concentrations below 0.1 mM, this drug does not inhibit RNA synthesis effectively, whereas at concentrations above 0.1 mM it inhibits RNA synthesis by about 80%. In view of the proposed mechanism of action of aurintricarboxylic acid, we suggest that completion of nucleotide chains initiated before nuclei isolation accounts for 20% of the RNA synthesized in our system by isolated nuclei, whereas nucleotide chains initiated during the in vitro incubation account for 80% of the RNA synthesized.     

The role of ATP in the transport of rapidly-labeled RNA from isolated nuclei of rat liver in vitro.

To understand the mechanism of the action of ATP on the in vitro transport of the rapidly-labeled RNA from isolated nuclei, the fate of ATP during the incubation as well as the effect of ATP, its analogues and other ribonucleoside triphosphates on the transport was examined and the following results were obtained. (1) More than 97% of added ATP remained acid soluble. No polyadenylation of the rapidly-labeled RNA in the released fraction by added ATP occurred although new polyadenylate segments smaller than 10 S were synthesized. (2) The addition of an ATP-generating system to the reaction mixture restored the initial rate of the release of the rapidly-labeled RNA from isolated nuclei. (3) Among the ribonucleoside triphosphates tested, ATP was most effective in stimulating the release. GTP was about 2/3 as effective as ATP. UTP showed some effect, but CTP showed no effect. EDTA was also non-effective. (4) When no ATP-generating system was added to the reaction mixture, AMP failed to mimic the effect of ATP. However, the combination of AMP and pyrophosphate could take the place of ATP. (5) Both AMP-CPP and AMP-PCP, the ATP analogues, showed the equal degree of their effect on the release, regardless of the position of the methylene bond. From these results, the principal role of ATP in the in vitro transport systems seemed to be its interaction with isolated nuclei to dissociate a structure which retains the rapidly-labeled RNA in the nucleus.     

Synthesis of messenger RNA-like molecules in isolated myeloma nuclei.

Nuclei isolated from mouse myeloma cells grown in tissue culture are capable of synthesizing RNA for prolonged periods of time. Addition of cytoplasmic extracts to the system stimulates slightly the rate and prolongs the time of synthesis. As judges by sedimentation in SDS and in formamide gradients, the size of the RNA synthesized is heterogeneous from smaller than 10S to larger than 45S, thus resembling in vivo made RNA. The characteristics of some of the RNA are in keeping with those expected to be for mRNA. Fifty percent of the RNA synthesis is sensitive to alpha-amanitin. After an incubation of two hours in the absence of alpha-amanitin about 10 percent of the newly synthesized RNA is found outside of the nuclei; it sediments with a broad distribution at 18S. A considerable fraction of the RNA that is released from nuclei in vitro can promote the formation of polyribosomes, and contains molecules that are polyadenylated and "capped".     

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.     

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.     

Proflavine sensitivity of RNA processing in isolated nuclei.

The intercalating agent proflavine inhibits the processing and subsequent release of preformed messenger RNA and ribosomal RNA from isolated liver nuclei to surrogate cytoplasm. The direct effect of proflavine on these processes, as monitored in a reconstituted cell-free system, supports the theory that base-paired segments (i.e. hairpin loops) in the precursor RNA's are involved as recognition sites in nuclear RNA processing.     

The RNA synthesizing capacity of nuclei isolated from cultured mouse cells.

Nuclei isolated from rapidly proliferating mouse L cells synthesize considerably more RNA than nuclei prepared from resting cells.     

Nature of the facilitated messenger ribonucleic acid transport from isolated nuclei.

Cytoplasmic macromolecules were previously identified which regulate both qualitatively and quantitatively the release of messenger-like RNA from isolated nuclei. These macromolecules are now shown to be denatured at 45-50 degrees C and their synthesis is sensitive to pactamycin or cycloheximide. The putative regulatory proteins are essentially quantitatively precipitated with high specificity from the cytosol by streptomycin at a concentration 10-fold higher than that used to precipitate RNA. The nuclear concentration-dependence of RNA transport from successive samples of nuclei strongly suggests that the regulatory factors are recycled. Quantitative changes in the sequences transported at various dilutions of the cytosol suggest that not all the different classes of the putative regulatory macromolecules are present in an effective concentration at any one dilution.