Differential effect of ATP on RNA and DNA release from nuclei of normal and neoplastic liver

HIV-1 Rev promotes the nuclear export of unspliced and singly spliced RNAs in a mammalian cell-free export system

Rev has been shown to promote the export of HIV-1 RNAs from Xenopus oocyte nuclei, but a system to examine the direct effect of Rev on HIV-1 RNA export in mammalian somatic cells does not exist. In this report, the development of a cell-free RNA export system using COS cells is described. This system is capable of examining the movement of RNA from nuclei of COS cells transfected with an HIV-1 proviral construct into reconstituted cytosol from nontransfected cells. A reproducible preparation of nuclei free of residual cytoplasmic RNA is demonstrated. Export of RNA from these nuclei into reconstituted cell-free extracts was saturable and dependent on temperature and energy. Further validation of the system was obtained by confirming that the nuclear export of HIV-1-unspliced and partially spliced RNAs was dependent upon the expression of HIV-1 Rev and that the presence of Rev appeared to decrease the export of an HIV-1-spliced RNA. The system was also able to demonstrate that Rev did not appear to significantly enhance the export of an HIV-1 protease-containing RNA that has been shown to be dependent upon Rev for maximal expression. Consequently, the system appears useful for the examination of parameters of nuclear export of HIV-1 and cellular RNAs.

Active transport of messenger ribonucleoprotein particles in a reconstituted cell-free system

The ability of a reconstituted cell-free system to transport mRNA as a ribonucleoprotein particle has been examined. Poly(A) messenger ribonucleoproteins (mRNPs), UV cross-linked after release from isolated liver nuclei in a cell-free system, exhibited a buoyant density of 1.33 g/cm3 in cesium sulfate and 1.47 g/cm3 in cesium chloride, values identical to those of poly(A) mRNP isolated directly from liver polysomes. Furthermore, the in vivo and in vitro transported mRNP showed a similar degree of resistance to RNase digestion and had sedimentation coefficients approximately 2.5 times that of the isolated mRNA. Release of both total mRNA and alpha 2 mu-globulin mRNA was proportional to the concentration of a specific cytoplasmic protein. Removal of the transport proteins from the cytosol with streptomycin sulfate provided a basal system incapable of supporting the active transport of alpha 2 mu-globulin mRNA. Hybridization of released RNA with a recombinant probe specific for intron 6 of alpha 2 mu-globulin showed that intron sequences were retained within the nucleus under optimal alpha 2 mu-globulin mRNA transport conditions and that the transported alpha 2 mu-globulin mRNA was of mature size.

Diadenosine tetraphosphate (Ap4A) is compartmentalized in nuclei of mammalian cells

The intracellular compartmentation of Ap4A in various growth and cell-cycle stages in mammalian cells was studied by applying a non-aqueous extraction procedure for cell nuclei. In both slowly and in exponentially growing Ehrlich ascites tumour cells from random cultures, more than 75% of the whole cellular Ap4A content is localized in the nuclei. In G1 and early S-phase cells of synchronized baby hamster kidney (BHK) fibroblast cultures, approx. 90% of the intracellular Ap4A pool is confined to the nuclear compartment. In contrast, Ap4A is distributed to nearly equal amounts between cytoplasm and nuclei during mid-S phase. After transition through the S-phase, increasing proportions of Ap4A (78% 18 h and 96% 22 h after serum replenishing, respectively) are again localized in the nuclear compartment.

Amino-acid-transfer reactions in isolated nuclei of Ehrlich ascites tumor cells

Nuclear enzymatic activities incorporating amino acids into acid-insoluble material were investigated with respect to their differentiation from protein biosynthesis, reaction optima, requisites and localization. The product of the reaction was analyzed with respect to its localization and nature. The nuclear activities are not inhibited by a number of inhibitors for protein biosynthesis. The reaction optima found are similar to those of other residual nuclear syntheses including the stringent dependence on ATP. All naturally occurring amino acids are utilized with different efficiencies. Their incorporation is neither cooperative nor competitive which points to individual incorporation mechanisms. Aminoacylation of tRNA may be involved because the incorporation is RNase-sensitive and aminoacylation of tRNA can be shown under the reaction conditions. The enzymatic activities are exclusively nuclear. Significant activity with unchanged characteristics is released by sonication. 70% of the radiolabel incorporated is exported across the nuclear envelope during the incubation. The residual 30% of the radiolabel is distributed without enrichment in any nuclear subfraction. The products are exclusively of polypeptide nature. Since distinct nuclear proteins (e.g. histones) which are definitely preformed in the cytoplasm by protein biosynthesis become radiolabelled by the incorporation of radiolabelled amino acids, it is evident that the incorporation takes place at preformed polypeptides. This is unequivocally proven by the incorporation of radiolabelled amino acids into exogenous proteins by means of the solubilized nuclear activities. The results indicate that the nuclear activity under investigation reflects a nuclear modification system for polypeptides which may be of similar importance as other post-translational modification systems.

Inhibition of RNA nucleo-cytoplasmic translocation by anti-nucleus antibody

Anti-nucleus antibody was raised by immunizing rabbits with rat liver nuclei, and purified by affinity-column chromatography. When purified anti-nucleus IgG molecules were introduced into FL cells by the erythrocyte-ghost fusion method with HVJ (Sendai virus), release of RNA from the nucleus into the cytoplasm was inhibited in the presence of alpha-amanitin, but nuclear accumulation of 125I-labeled non-histone chromosomal protein from the cytoplasm was not inhibited. These findings suggest that the nucleo-cytoplasmic transport mechanisms of RNA and nuclear proteins are different. The molecular weight of the antigen of this antibody was determined to be about 55K by the immunoblotting technique.

Characterization of an ATPase on the inside of rat-liver nuclear envelopes by affinity labeling

Nuclear envelope membranes from rat liver cells contain ATPases, one of which can be inhibited and irreversibly labeled by (S-dinitrophenyl)-6-mercaptopurine riboside triphosphate. Inhibition and covalent substitution of the ATPase are achieved only after disruption of the nuclei, the ATP analogue is inactive on the ATPase activity of whole nuclei or on vesicles of the membrane prepared after a modified heparin method of Bornens and Courvalin. Electron micrographs and scanning micrographs helped to establish the characterization of closed vesicles and intact nuclei. With the aid of (alpha-32P)-labeled, and of the (beta, gamma-32P)-labeled analogue, it was possible to demonstrate the incorporation of the nucleotide into a few protein regions of the nuclear membrane disc electrophoresis pattern.

The fluidity of the nuclear envelope lipid does not affect the rate of nucleocytoplasmic RNA transport in mammalian liver

The effects of in vitro and in vivo modifications of nuclear envelope lipid on DNa leakage and on ATP-stimulated RNA release from isolated rat liver nuclei were investigated. The modifications included corn-oil feeding of the animals to alter the fatty acid composition of the lipids, phospholipase treatment of the isolated nuclei, and extraction of the total lipid with Triton X-100. Significant changes in lipid composition and approximate order parameter values of the spin-label 5-doxylstearate resulted, but there was no significant effect on RNA transport rate. It was concluded that the nuclear envelope lipid does not play any important part in nucleocytoplasmic RNA transport in mammalian liver.

RNA metabolism in isolated nuclei: processing and transport of immunoglobulin light chain sequences

Transport of prelabeled RNA from isolated myeloma nuclei is studied using conditions that permit RNA synthesis. Cytosol and spermidine are not required to maintain nuclear stability and inhibited RNA release. Omission of ATP or GTP decreased release 25 to 40%. The stimulatory effect of ATP or GTP is not due to hydrolysis of the triphosphates by the nuclear envelope NTPase, since addition of quercetin (an inhibitor of this NTPase) has no effect on the quantity of RNA released. The size distribution and percentage of poly A-containing species released from nuclei incubated with or without ATP or the other rNTPs are identical. Hybridization analysis of nuclear RNA before the transport assay revealed mature and precursor k light chain mRNA sequences. Following the transport assay, a significant fraction of k mRNA precursors is chased into mature k mRNA which is found both in nuclear-retained and released RNA.

Transport of functional messenger RNA from liver nuclei in a reconstituted cell-free system

The reliability of a reconstituted cell-free system for messenger RNA processing and transport, consisting of isolated nuclei in fortified cytosol, has been evaluated in terms of the functionality and regulated release of the transported product. The poly(A) messenger RNA transport in vitro formed appropriate initiation complexes with ribosomes in an optimized translation system and had template activity comparable to that transported in vivo. The intra-nuclear origin of this messenger RNA is supported by pulse-labeling studies, its transport from detergent-treated nuclei and the absence of the release under non-transport conditions. Serum albumin was identified by immunoprecipitation and electrophoresis as one of the products synthesized when the transported RNA was translated in vitro. The transport of messenger RNA in the cell-free system was dependent on specific cytosol (soluble cytoplasmic) proteins. These proteins, which constitutes less than 0.1% of the total cytosol proteins, are precipitated wtih streptomycin with high specificity.

Regulated transport of messenger ribonucleic acid from isolated liver nuclei by nucleic acid binding proteins

Rat liver nucleocytosolic messenger ribonucleic acid (mRNA) transport is shown to be regulated by proteins with a high affinity for nucleic acids. In the cell-free system described, the energy-dependent transport of all RNA classes [transfer RNA (tRNA), mRNA, and ribosomal RNA (rRNA)] exhibited a dependence upon the availability of discrete minor sets of cytosol proteins. In addition to having a different level of saturation, only the mRNA "transport protein" activities are increased by adenosine cyclic 3',5'-phosphate (cAMP), an effect most likely mediated by a cAMP-dependent protein kinase. The mRNA transport proteins were isolated from cytosol by precipitation with streptomycin sulfate followed by deoxyribonucleic acid (DNA)-cellulose affinity chromatography, or from oligo-(thymidylate)-cellulose bound cytoplasmic messenger ribonucleoprotein (mRNP) particles by high-salt extraction. Either method yielded a protein fraction which exhibited a 1000-fold increase in mRNA transport activity as compared to cytosol. Over one-half of the mRNA transport activity is associated with the mRNP of the cell. A partial homology between the cytosol and mRNP-derived proteins was demonstrated by polyacrylamide gel electrophoresis. One major (20 000 daltons) and several minor proteins (23 000, 52 000, 54 000, and 72 000 daltons) were in common. Nuclear 4-5S exited from in vitro incubated nuclei in three phases, according to their differential in vivo rates of labeling and intranuclear pool sizes. The amount of nuclear RNA transported in vitro as mRNA (about 1.0%) agrees wtih the in vivo estimates. Additional evidence for in vivo equivalence was provided by the physicochemical characterization and bioassay of the RNA. The transported mRNA sedimented in urea-sucrose gradients as an 8-18S heterodisperse product. This RNA initiated cell-free translation with the synthesis of precursor peptides as diverse in size as those for albumin and alpha 2U-globulin. The relative abundancies of various transported mRNAs were different than the corresponding abundancies of liver cytoplasmic mRNAs.

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 wih the oxidation of both NADPH and NADH and inhibited by cyanide.

In vitro ribosomal ribonucleoprotein transport upon nuclear expansion

The interdependence of nuclear rRNA release and nuclear size is investigated in macronuclei isolated from Tetrahymena. Nuclei are induced to contract and to expand, without any structural disintegration of the nuclear envelope, by final Ca2+/Mg2+ (3:2) concentrations of 5 and 1.5 mM, respectively. Upon expansion, the average volume of nuclei increases from 600 +/- 42 to 811 +/- 76 micron3. Concomitantly, nuclei begin to release RNA following saturation kinetics. This RNA release stops immediately upon nuclear contraction. Similar to the in vivo situation, only advanced rRNA processing products are released in the form of ribosomal precursor particles, as identified in detail by polyacrylamide gel electrophoresis and rate zonal and isopycnic density gradient centrifugation. Three particle ty9es are released having average buoyant densities of 1.495, 1.470, and 1.532 g/cm3, exhibiting average sedimentation coefficients of 62, 62, and 35 S, and containing the immediate precursor to the 25S rRNA, 26S rRNA, and 17S rRNA, respectively. Tje rRNP release if ATP independent and noncoincident with the release of endogenous nuclear Pi, though it is Be2+ sensitive. Our data are compatible with the views that nuclear expansion is the prerequisite rather than the cause for the rRNP release and that nuclear pore complex associated ATPases play only, if at all, a minor role in nucleocytoplasmic exchange of rRNP.

Energy utilization and RNA transport: their interdependence

The interdependence of RNA transport and the metabolism of nucleotide additives was investigated. Rat-liver RNA was radioactively labeled in vivo for 45 min before isolation of liver nuclei, and the concentration dependence of RNA transport on nucleotide additives was determined. In a parrallel investigation, using nucleotide additives labeled in the base moiety, the distributions of label in the tri-, di-, and monophosphate forms were examined after various intervals of incubation. Analysis of results revealed that RNA transport was linearly related to the decline in energy charge of nucleotide additives, whith high statistical correlation. Kinetic analysis of labeled-nucleotide metabolism led to a simple schematic model for pathways for the utilization of high-energy phosphate bonds, and predictions of the scheme were confirmed by studies examining the effects of nucleotide analogues upon RNA transport. Data concerning inhibitors and chelators intimated that multiple avenues of inhibition and stimulation may potentially influence RNA transport. On the basis of previous data and the results presented in this communication, we conclude that nucleocytoplasmic RNA transport is dependent upon high-energy phosphate-bond hydrolysis and that nucleotides do not stimulate RNA transport via a simple chelation mechanism.

Nucleotides and coenzymes in nuclei isolated from rat liver

In rat-liver nuclei, isolated by the non-aqueous technique, the concentrations and labelling rates of the purine moiety of acid-soluble nucleotides were determined and compared with corresponding data for non-fractionated tissue and nuclei-free cytoplasm. Livers were used from untreated rats, from rats with a highly stimulated synthesis of NAD and from rats following a heavy metabolic load with adenosine. Under all circumstances, the nuclear and cytoplasmic concentrations of nucleotides (e.g. ATP and its dephosphorylated forms, pyridine nucleotides) and of free glucose were practically identical. Specific radioactivities after a pulse with formate also indicated a nucleo-cytoplasmic equilibrium for purine-containing nucleotides. It is concluded that precursor pools for nuclear biosyntheses as well as energy supply for other nuclear activities may be determined by an analysis of the non-fractionated tissue.

Age-dependence of nuclear RNA processing

Following a 3 hour in vivo labelling of cytoplasmic RNA in rat liver with orotic acid-6-14C under conditions where ribosomal RNA synthesis was suppressed, the proportion of labelled messenger-like RNA released to the cytoplasm which contained polyadenylate (poly(A)) tracts was about 3.0 times higher in the livers of juvenile (50 day) as compared to adult (180 day) rats. This discrepancy was confirmed in a cell-free system which consisted of isolated prelabelled nuclei in fortified cytosol. Thus under conditions where approximately 80% of the released labelled RNA was messenger-like, the proportion of polyadenylated labelled RNA transported to the homologous cytosol was 3.4-fold greater in the systems derived from juvenile as compared to adult rat liver. Through comparisons of homologous and heterologous systems it was determined that the age-dependent change in the metabolism of polyadenylated messenger RNA resides in the nucleus and not in the cytoplasm. This change, furthermore does not involve the known ATP-dependence of nuclear RNA release. Rather it must involve other age-dependent changes in the processing or transport of polyadenylated messenger RNA.