RNase-sensitive glucocorticoid-receptor complexes from HELA cell nuclei

Dexamethasone-receptor complexes can be extracted from HeLa cell nuclei by mild sonication. These complexes can account for 800-1000 binding sites/cell, and are indistinguishable from salt-extractable ones as judged by sucrose gradient centrifugation in the presence of 0.3 M KCl, showing a sedimentation coefficient of 3.6 S. These complexes, however, broadly sediment in the 7 to 3.6 S region of low salt sucrose gradients. Enzymatic treatment of soluble extracts from nuclear sonicates shows that RNA is associated to dexamethasone-receptor complexes.     

RNase A effects on sedimentation and DNA binding properties of dexamethasone-receptor complexes from HeLa cell cytosol

Dexamethasone-receptor complexes from HeLa cell cytosol sediment at 7.4S in low salt sucrose gradients, and at 3.8S in high salt gradients. If cytosol is heated at 25 degrees C, receptor complexes sediment at 6.9S in low salt, and at 3.6S in high salt gradients. RNase A treatment at 25 degrees C, instead, results in receptor complexes which sediment in low salt gradients as two major forms at 6.5 and 4.8S. Receptor complexes from RNase A-treated cytosols sediment as their counterparts from untreated cytosols in high salt gradients. Although the shift in sedimentation properties of receptor complexes at 2 degrees C is induced by RNase A, and not by other low molecular weight basic proteins or RNase T1, the effect can be also obtained by inactive RNase A. The catalytically active enzyme, however, is required to observe 6.5 and 4.8S complexes after cytosol incubations at 25 degrees C. Placental ribonuclease inhibitor prevents the appearance of RNase A-induced receptor forms at 25 degrees C, but not at 2 degrees C. Moreover, this inhibitor can prevent the 7.4 to 6.9S shift in sedimentation coefficient of receptor complexes caused by cytosol heating. Dexamethasone-receptor complexes from HeLa cell cytosol show low levels of binding to DNA-cellulose, and heating at 25 degrees C is required to observe a six-fold increase in DNA binding levels. RNase A treatment of cytosols at 2 degrees C does not result in significant enhancement in receptor complex binding to DNA. If RNase A treatment is carried out at 25 degrees C, however, DNA binding levels of receptor complexes increased by 25% over the values observed with control heated cytosol. This effect cannot be observed if RNase T1 substitutes for RNase A. Placental ribonuclease inhibitor can prevent the temperature-dependent increase in DNA binding properties of dexamethasone-receptor complexes either in the presence or absence of exogenous RNase A. These findings indicate that exogenous RNases can perturb the structure of dexamethasone-receptor complexes without being involved in the transformation process.     

Formation and characterisitcs of hepatic dexamethasone-receptor complexes of different molecular weight

The dexamethasone-binding receptor protein in rat liver cytosol has a Stokes radius of 61 Å and a sedimentation coefficient of 4.0 S. In contrast, cell nuclei labelled with [³H]dexamethasone in vivo or in vitro (reconstitution experiments with [³H]dexamethasone-labelled cytosol and isolated unlabelled nuclei) contain a high-salt-extractable dexamethasone-receptor complex with a Stokes radius of 30–36 Å and a sedimentation coefficient of 3.2 S. Exposure of liver homogenate or 1000 × g homogenate supernatant to low ionic strenght during preparation of cytosol resulted in conversion of the 61 Å to a 36 Å complex very similar to the intranuclear form of dexamethasone receptor. 61 → 36 Å complex-verting activity was present in both the 100 × g ?10 000 × g sediment of liver homogenate, from which it could be extracted by hypotonic media, and in the liver cell nuclei, from which it could be extracted by hypertonic media. Mild digestion of the 61 Å dexamethasone-receptor complex with trypsin also gave rise to a complex with a Stokes radius of 36 Å. Reconstitution experiments with isolated liver cell nuclei indicated that both the 61 Å and 36 Å dexamethasone-receptor complexes were taken up by the nuclei; reextraction of the nuclei incubated with the 61 Å complex revealed that this form had been converted to the 30–36 Å complex.Further digestion of teh 61 and 36 Å [³H]dexamethasone-receptor complexes with hypotonic extract of the 1000 × g ?10 000 × g sediment of liver homogenate or with trypsin resulted in formation of a third complex with a Stokes radius of 19 Å and a sedimentation coefficient of 2.5 S. The approximate molecular weights of the 61, 36 and 19 Å dexamethasone-receptor complexes were calculated as 102 000, 46 00 and 19 000, respectively, and the frictional ratios of the molecules as 1. 84, 1. 38 amd 1.00, respectively.It is concluded that the nuclear 30–36 Å dexamethasone-receptor complex is formed from the cytosol 61 Å complex by proteolytic digestion and that this latter protein contains at least two sites with a relatively high sensitivity to protelytic cleavage.     

Changes in heterogeneous nuclear RNP core polypeptide complements during the cell cycle

Mammalian heterogeneous nuclear RNP (hnRNP) subcomplexes are shown to be comprised of 14-17 basic A and B core group polypeptides (chrp) when subjected to two-dimensional immunoblot analysis. These proteins are normally confined to the nucleus but are distributed throughout the cell during mitosis. However, not all of the 17 protein spots are observed for all stages of the cell cycle. HeLa cell populations have been synchronized and the basic hnRNP core protein complement examined during S, G2, mitosis, and G1. During cell division several distinct chrp polypeptide species at 35 and 37 kD appear, while another of 37 kD and a chrp of 38 kD are diminished. These altered chrp complements are not due to any effects induced by thymidine treatment but appear to be physiological changes in the chrp polypeptide modification state. The new charge isomers found during mitosis are not the result of selective phosphorylation of the chrp polypeptides. However the nature of the modifications has yet to be determined. The mitosis-specific modified forms of the chrp polypeptides are found in the cytoplasmic fraction derived from mitotic cell populations. When this fraction is centrifuged upon sucrose density gradients the modified chrp polypeptides sediment from 30-200S in a distribution similar to that of hnRNP complexes isolated from the nuclei of randomly dividing cell populations. RNase digestion experiments indicate that the general substructure of the RNA/protein complexes in mitotic cell cytoplasm is similar to that of nuclear hnRNP isolated from unsynchronized cells or tissue.     

Discrete foci containing RNase A are found in nucleoli of HeLa cells after aging in culture

We have studied by means of ultrastructural immunocytochemistry the localization of RNase A in nuclei of HeLa cells in control conditions and following cell ageing in culture. We have found that roundish, electron dense foci, which contain a significant amount of RNase A, can be detected within nucleoli of aged cells. These bodies also contain RNA and lack ribosomal S3 proteins, and may represent either simple storage sites or areas where RNA degradation takes place.     

Discrete foci containing RNase A are found in nucleoli of HeLa cells aged in culture

We have studied by means of ultrastructural immunocytochemistry the localization of RNase A in nuclei of HeLa cells in control conditions and following cell ageing in culture. We have found that roundish, electron dense foci, which contain a significant amount of RNase A, can be detected within nucleoli of aged cells. These bodies also contain RNA and lack ribosomal S3 proteins, and may represent either simple storage sites or areas where RNA degradation takes place.Key words: nucleolus, RNase, electron microscopy, immunocytochemistry.     

Extraction of nuclear glucocorticoid-receptor complexes with pyridoxal phosphate

Rat thymic lymphocytes have saturable, specific receptors for glucocorticoids, which are localized predominantly in the nucleus following exposure of thymocytes to dexamethasone at 37°C. The present results demonstrate the dose-dependent extraction by pyridoxal phosphate of dexamethasone-receptor complexes from isolated thymocyte nuclei. On an equal molar basis, pyridoxal phosphate is considerably more effective than pyridoxal; pyridoxine, pyridoxamine phosphate and 5-deoxypyridoxal are ineffective. The release of the nuclear dexamethasone receptor complex is dependent on the integrity of the C4′ carboxaldehyde group of pyridoxal phosphate as evidenced by the inhibition of extraction of dexamethasone-receptor complexes by either hydroxylamine or semicarbazide. The dexamethasone which pyridoxal phosphate liberates from thymus nuclei is bound to a macromolecule which is of smaller size than unactivated cytoplasmic dexamethasone receptor.     

Proteasome subunit zeta,a putative ribonuclease,is also found as a free monomer

20 S Proteasomes are large proteinase complexes found in eukaryotic cells where they degrade cell proteins in an ATP-dependent manner. Proteasomes consist of 14 different subunits. One of them, zeta, was found in HeLa cells at a concentration of 890 g per g of cell protein. A large proportion of zeta was found in the free state rather than incorporated into proteasomes, namely 28% in HeLa cells and 37% in BSC-1 cells. Free zeta was found in both nuclei and cytoplasm. In HeLa cells free zeta had a t1/2 of 2.8 h, compared to 5 d for proteasomes, and did not exchange with zeta in proteasomes. We confirmed (Petit F et al.: Biochem. J. 326: 93–98 (1997)) that both 20 S proteasomes and free zeta subunits possess RNase activity though the activities were very low: 4 mMoles and 0.6 mMoles of tobacco mosaic virus RNA degraded per mole of enzyme per min, respectively. The physiological function of the relatively abundant zeta monomers is not known.     

Proteins associated with heterogeneous nuclear RNA in eukaryotic cells

When HeLa cell nuclei axe mechanically disrupted in either hypotonic or isotonic buffers, heterogeneous nuclear RNA is recovered from the post-nucleolar fraction in the form of EDTA-resistant ribonucleoprotein particles, which sediment between 40 S and 250 S in sucrose gradients containing 0.01 m or 0.15 m-NaCl. That the RNA in these particles is HnRNA² is indicated by its heterodisperse sedimentation (20 to 80 S) and its continued synthesis in concentrations of actinomycin D that selectively inhibit the synthesis of ribosomal RNA. The specificity of the HnRNA-protein complexes is evidenced by the failure of deliberate attempts to generate artificial RNP by the addition of deproteinized HnRNA to intact or disrupted nuclei at low ionic strength.The proteins bound to HnRNA are complex. In HeLa cells, HnRNP particles contain proteins with molecular weights from 39,000 to approximately 180,000 (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and isoelectric points between 4.9 and 8.3 (analytical isoelectric focusing). They are readily distinguishable from proteins in other cell fractions, including those in chromatin.Exposure of HeLa HnRNP particles to 0.5 m-NaCl reduces their average sedimentation velocity by approximately 30%. CsCl density-gradient analysis reveals that this is accompanied by the loss of a major portion of the proteins. However, a significant fraction of the HnRNP (25 to 30%) is resistant to high salt concentrations and continues to band at the same density as native HnRNP (1.43 g/cm³). This is true even after prolonged exposure (24 h) to high salt. The salt-resistant HnRNP is enriched for proteins above 60,000 molecular weight. In at least these two respects, this sub-class of HnRNP resembles “messenger RNP” prepared from cytoplasmic polyribosomes, which is also salt-stable and contains relatively high molecular weight proteins.HnRNP particles can also be recovered from HeLa cell nuclei lysed in high salt but these contain many extra proteins, notably histones, and sediment much faster in sucrose gradients than particles prepared as above. HnRNP is not liberated by extracting HeLa nuclei in 0.14 m-NaCl, pH 8.0 (Samarina et al., 1967) unless the temperature is 20 °C or higher. In this case the particles are converted to 45 S structures, which contain partially degraded HnRNA. 45 S particles can also be produced by subjecting 40 to 250 S HnRNP to a very limited digestion with pancreatic ribonuclease (1 to 2 hits/molecule).HnRNP particles have similar sedimentation velocities (40 to 300 S) when isolated under physiological ionic conditions from a variety of mammalian cells, including WI38 human diploid fibroblasts, mouse L-cells, monkey kidney cells and rat liver. However, electrophoresis reveals a distinct pattern of HnRNP proteins for each cell type. It is proposed that this cell-specificity reflects a situation in which HnRNA molecules that differ in nucleotide sequence are complexed with different sets of proteins, so that the resulting HnRNP particles are biochemically distinct at each genetic locus. This hypothesis is discussed in relation to the cytology of lampbrush and polytene chromosomes.     

Interaction of sodium thiocyanate with rat hepatic glucocorticoid-receptor complexes

0.1–0.3 M sodium thiocyanate greatly enhanced the rate of inactivation of unbound rat hepatic glucocorticoid receptors in vitro at 4°C. Prior treatment of the unbound glucocorticoid receptor with 10 nM molybdate (at 25°C for 30 min) protected the receptor from 0.3 M KCl, but not from 0.3 M NaSCN inactivation. When the [³H]dexamethasone-receptor complex was examined on sucrose density gradients containing 0.1 M NaSCN, the receptor sedimented as a 4 S complex rather than the 7 S form observed in 0.1 M KCl gradients. NaSCN was found to be more effective in the extraction of both in vivo and in vitro nuclear-bound [³H]dexamethasone-receptor complexes than KCl. At a concentration of 0.3 M, NaSCN extracted most of the specific nuclear-bound receptor. 50 mM NaSCN significantly blocked the thermal activation of preformed [³H]dexamethasone-receptor complexes. The chaotropic salt, NaSCN, appears therefore to have significant effects on glucocorticoid receptors in vitro. In addition, NaSCN appears to be a useful agent in quantitative extraction of steroid from nuclear-bound steroid-receptor complexes.     

Cellular factor affecting the stability of beta-globin mRNA

Messenger RNAs in eukaryotic cells exhibit a broad range of stabilities in vivo. Globin mRNA has a half life in excess of 50 h, but the half life of the c-myc oncogene mRNA is less than 20 min. Regulation of gene expression may be accomplished by a variety of mechanisms, including altering mRNA stability. We have examined the nuclear and cytoplasmic fractions of cells for factors affecting the metabolism of mRNA. Here we report that a HeLa whole-cell extract contains a factor that protects beta-globin mRNA from attack by RNases in a mouse erythroleukemia cell cytoplasmic extract. The factor is non-dialysable, inactivated by proteinase K and heat treatment, and resistant to RNase and DNase digestion. The HeLa cell factor resembles placental RNase inhibitor in that the mRNA-protecting activity is effective against RNase A and that treatment of the extract with N-ethylmaleimide completely destroys the protective activity. However, purified placental RNase inhibitor was unable to inhibit the RNase activity in the MELC cytoplasmic extract. These results suggest that the HeLa cell extract contains an RNase inhibitor (or inhibitors) with an activity or specificity that is distinct from that of placental RNase inhibitor.     

Subnuclear particles containing a small nuclear RNA and heterogeneous nuclear RNA

Five of the stable low molecular weight RNA species in the HeLa cell nucleus have been localized in RNP complexes in the cell nucleus. The two abundant species C and D and the three minor species F, G′ and H are found in RNP particles following two different methods of preparation. Sonication of nuclei releases the five small RNAs and also the hnRNA in RNPs that sediment in a range from 10 to 150 S. Alternatively, incubation of intact nuclei at elevated temperature and pH releases four of the small RNAs and degraded hnRNA in more slowly sedimenting structures.When nuclear RNPs obtained by sonication are digested with RNAase in the presence of EDTA, the hnRNA is degraded and the hnRNPs sediment at 30 S. The structures containing the small RNA species D are similarly shifted to 30 S particles by RNAase and EDTA but not by either agent alone. In contrast, the sedimentation of complexes containing species G′ and H are not altered by exposure to RNAase/EDTA and small RNA species C and F are unstable under these conditions.In isopycnic metrizamide/²H₂O gradients species D and hnRNA accumulate at a density characteristic of RNP particles. They have a similar but not identical distribution.Species D is released from large RNPs by salt concentrations of 0.1 m-NaCl or greater, while the hnRNA remains in large RNP particles. In contrast, the structures containing species G′ and H are stable in 0.3 m-NaCl. All five of the small nuclear RNA species and the hnRNAs are released from rapidly sedimenting complexes by the ionic detergent sodium deoxycholate.It is suggested that the low molecular weight RNA species play a structural role in RNP particles in the cell nucleus and that a subpopulation of species D may be associated with the particles that package the hnRNA.     

Age-dependent activation of glucocorticoid receptors in the liver of male rats

The binding of hepatic [3H] dexamethasone-receptor complexes to DNA-cellulose and purified nuclei was studied in the immature (3-week) and mature (26-week) Long-Evans male rats to determine the age-associated changes, if any, in the physicochemical properties of glucocorticoid-receptors. Our data show that heat activation (for 45 min at 25 degrees C) significantly enhances the binding of [3H] dexamethasone-receptor complexes to DNA-cellulose and purified nuclei at both the ages, with a greater magnitude in mature rats. Cross-mixing experiments (i.e. binding of activated cytosol from mature rats to nuclei of immature and vice-versa) show receptor specificity. Ca2+ activation (20mM Ca2+ for 45 min at 0 degrees C) also enhances the nuclear and DNA-cellulose binding at both the ages but to a similar extent. These findings indicate that some of the physicochemical properties (e.g. heat activation) of glucocorticoid receptor change, while others (e.g. Ca2+ activation) remain unchanged at these phases of the life span. The observed changes may lead to functional alterations in the tissue response as a function of age.     

Assembly of a polyadenylation-specific 25S ribonucleoprotein complex in vitro.

Extracts from HeLa cell nuclei assemble RNAs containing the adenovirus type 2 L3 polyadenylation site into a number of rapidly sedimenting heterodisperse complexes. Briefly treating reaction mixtures prior to sedimentation with heparin reveals a core 25S assembly formed with substrate RNA but not an inactive RNA containing a U----C mutation in the AAUAAA hexanucleotide sequence. The requirements for assembly of this heparin-stable core complex parallel those for cleavage and polyadenylation in vitro, including a functional hexanucleotide, ATP, and a uridylate-rich tract downstream of the cleavage site. The AAUAAA and a downstream U-rich element are resistant in the assembly to attack by RNase H. The poly(A) site between the two protected elements is accessible, but is attacked more slowly than in naked RNA, suggesting that a specific factor or secondary structure is located nearby. The presence of a factor bound to the AAUAAA in the complex is independently demonstrated by immunoprecipitation of a specific T1 oligonucleotide containing the element from the 25S fraction. Precipitation of this fragment from reaction mixtures is blocked by the U----C mutation. However, neither ATP nor the downstream sequence element is required for binding of this factor in the nuclear extract, suggesting that recognition of the AAUAAA is an initial event in complex assembly.     

RNA-protein interactions in the human RNase MRP ribonucleoprotein complex

The eukaryotic nucleolus contains a large number of small RNA molecules that, in the form of small nucleolar ribonucleoprotein complexes (snoRNPs), are involved in the processing and modification of pre-rRNA. One of the snoRNPs that has been shown to possess enzymatic activity is the RNase MRP. RNase MRP is an endoribonuclease involved in the formation of the 5' end of 5.8S rRNA. In this study the association of the hPop1 protein with the RNase MRP complex was investigated. The hPop1 protein seems not to be directly bound to the RNA component, but requires nt 1-86 and 116-176 of the MRP RNA to associate with the RNase MRP complex via protein-protein interactions. UV crosslinking followed by ribonuclease treatment and immunoprecipitation with anti-Th/To antibodies revealed three human proteins of about 20, 25, and 40 kDa that can associate with the RNase MRP complex. The 20- and 25-kDa proteins appear to bind to stem-loop I of the MRP RNA whereas the 40-kDa protein requires the central part of the MRP RNA (nt 86-176) for association with the RNase MRP complex. In addition, we show that the human RNase P proteins Rpp30 and Rpp38 are also associated with the RNase MRP complex. Expression of Vesicular Stomatitis Virus- (VSV) tagged versions of these proteins in HeLa cells followed by anti-VSV immunoprecipitation resulted in coprecipitation of both RNase P and RNase MRP complexes. Furthermore, UV crosslinking followed by anti-Th/To and anti-Rpp38 immunoprecipitation revealed that the 40-kDa protein we detected in UV crosslinking is probably identical to Rpp38.