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.     

Multiple states of U3 RNA in Novikoff hepatoma nucleoli

U3 RNA, a capped small nuclear RNA found thus far only in the nucleolus, has been implicated in the processing and/or transport of preribosomal RNA [Busch, H., Reddy, R., Rothblum, L., & Choi, Y. C. (1982) Annu. Rev. Biochem. 51, 617-654]. Tris(hydroxymethyl)aminomethane (Tris) (10 mM, pH 7.0) extracts of Novikoff hepatoma nucleoli, which contained about 80% of total nucleolar U3 RNA, were analyzed by sucrose density gradient centrifugation. Approximately 65% of the U3 RNA was bound to greater than 60S preribosomal ribonucleoprotein (RNP) particles, and about 15% sedimented at less than 20 S. The association between the 65% of U3 RNA that was bound to the preribosomal RNP particles was stable up to 55 degrees C. About 10% of U3 RNA was base paired to preribosomal RNA after deproteinization at 22 degrees C. The base-paired fraction of U3 RNA was released from the preribosomal RNA by heating to 45 degrees C or treating with 4 M urea. These results show that of the total nucleolar U3 RNP, (a) about 55% is bound to preribosomal RNP particles primarily by protein interactions, (b) about 10% is base paired to preribosomal RNA, (c) approximately 15% sedimented slowly and consisted presumably of free U3 RNP particles, and (d) the remaining 20% of U3 RNP was not extractable using 10 mM Tris buffer. On the basis of the different association states of U3 RNP particles, a model is proposed for the binding and dissociation events which take place between U3 RNP and preribosomal RNP particles.     

Characterization of RNA synthesis in mid-pachytene spermatocytes of the rat

In this paper the RNA synthesis in mid-pachytene spermatocytes of the rat has been studied. The results show that RNA synthesized by these cells is mostly high molecular weight RNA comparable to HnRNA of somatic cells. In comparison with the rapid metabolism of HnRNA in somatic cells, HnRNA in pachytene spermatocytes is stable and remains in the nucleus for a considerable time. About 30% of this HnRNA contains a poly(A) sequence, although no difference in the rate of metabolism between poly(A)+ and poly(A)− RNA was observed. Based on these results it is suggested that at least a part of the RNA which is synthesized by pachytene spermatocytes is stored in the cells and utilized later during spermatogenesis when the RNA synthesis of the spermatids ceases, but protein synthesis is still active for about 2 weeks.     

Effect of 5-bromodeoxyuridine on heterogeneous nuclear RNA in rat hepatoma cells.

Heterogeneous nuclear RNA HnRNA) was isolated from untreated and 5-bromodeoxyuridine (BrdUrd) treated hepatoma tissue culture (HTC) cells. analysis of this RNA by either electrophoresis on polyacrylamide-agarose gels or centrifugation in sucrose gradients demonstrated that BrdUrd caused a shift in the labeled HnRNA population toward a smaller size distribution. This effect was produced by concentrations of BrdUrd which specifically lower the level of the differentiated enzyme tyrosine aminotransferase, but do not greatly affect cell growth. Differential binding to oligo(dT) cellulose was used to fractionate HnRNA further into classes containing poly(A) (alpha), oligo(A) (beta) or neither category of A-rich sequences (gamma). BrdUrd did not alter the relative rates of uridine incorporation into the three classes. The shift in the labeled HnRNA population due to BrdUrd was observed in all three subclasses of HnRNA.     

Isolation of informoferes from rat liver : Effects of α-amanitin and actinomycin D

RNP particles carrying rapidly labelled RNA (informoferes) were isolated from rat liver nuclei by extraction with isotonic and 0.3 M salt buffer at pH 8 either with or without ultrasonic treatment. The importance of preliminary extraction of the nuclei with the isotonic salt buffer at a lower pH of 7 or in the presence of 50 mM EDTA is demonstrated. Administration of α-amanitin or of actinomycin D, in doses inhibiting the labelling of the heterogeneous RNA with RNA precursors in the range of 60–85%, reduces the amount of informoferes recovered. The informoferes isolated from treated animals are highly depleted in HnRNA. They still contain, however, low molecular RNA species with a slower turnover than the HnRNA. The polypeptide pattern observed after acrylamide gel electrophoresis of the informofere proteins is qualitatively changed in the treated preparations, whereas the ratio of protein to RNA decreases. In the presence of RNase inhibitor the informoferes are recovered in form of polymer structures. α-Amanitin and actinomycin D significantly reduce the amount of polymers recovered.     

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.     

Ribonucleoprotein organization of eukaryotic RNA. XXX. Evidence that U1 small nuclear RNA is a ribonucleoprotein when base-paired with pre-messenger RNA in vivo

U1 small nuclear RNA is thought to be involved in messenger RNA splicing by binding to complementary sequences in pre-mRNA. We have investigated intermolecular base-pairing between pre-mRNA (hnRNA) and U1 small nuclear RNA by psoralen crosslinking in situ, with emphasis on ribonucleoprotein structure. HeLa cells were pulse-labeled with [3H]uridine under conditions in which hnRNA is preferentially labeled. Isolated nuclei were treated with aminomethyltrioxsalen , which produces interstrand crosslinks at sites of base-pairing between hnRNA and U1 RNA. hnRNA-ribonucleoprotein (hnRNP) particles were isolated in sucrose gradients containing 50% formamide, to dissociate non-crosslinked U1 RNA, and then analyzed by immunoaffinity chromatography using a human autoantibody that is specific for the ribonucleoprotein form of U1 RNA (anti-U1 RNP). After psoralen crosslinking, pulse-labeled hnRNA in hnRNP particles reproducibly bound to anti-U1 RNP. The amount of hnRNA bound to anti-U1 RNP was reduced 80 to 85% when psoralen crosslinking of nuclei was omitted, or if the crosslinks between U1 RNA and hnRNA were photo-reversed prior to immunoaffinity chromatography. Analysis of the proteins bound to anti-U1 RNP after crosslink reversal revealed polypeptides having molecular weights similar to those previously described for U1 RNP. These proteins did not bind to control, non-immune human immunoglobulin G. These results indicate that the subset of nuclear U1 RNA that is base-paired with hnRNA at a given time in the cell is a ribonucleoprotein. This raises the possibility that these proteins, as well as U1 RNA itself, may participate in pre-mRNA splice site recognition by U1 RNP.     

A COMPARISON BETWEEN HETEROGENEOUS NUCLEAR RNA AND POLYSOMAL MESSENGER RNA IN HELA CELLS BY RNA-DNA HYBRIDIZATION

Heterogeneous nuclear RNA (HnRNA) and mRNA from cytoplasmic polyribosomes of HeLa cells have been compared by RNA-DNA hybridization tests. 1 µg of HeLa cell DNA binds 0.05–0.10 µg of either HnRNA or mRNA. In addition, HeLa DNA that is preexposed to unlabeled HnRNA was found to have a reduced capacity to bind either HnRNA or mRNA. The results are compatible with considerable sequence similarity in the two types of RNA but, as is discussed, firm conclusions are precluded by imperfections of the hybridization reaction as presently employed.     

Rat liver nuclear skeleton and small molecular weight RNA species

Small molecular weight RNA species (smwRNAs) were studied in rat liver nuclei with and without chromatin as well as with and without nuclear envelope and nucleoplasm. From all the species identified, only two, N5 and 5Sb, were related to ribosomes. The others were localized exclusively in the nuclear skeleton or the spongelike network that was described in the preceding communication. This network or protein matrix contains a less abundant but exclusive set of molecules designated 5Sa, N1, and 4.5S, as well as other more abundant molecules which also exist in rat liver endoplasmic reticulum but not in polysomes or postribosomal RNP complexes. The smwRNAs behave like HnRNA; they remain located in the nuclear skeleton when nuclei are deprived of nucleoplasm and chromatin. With the information presently available, it is not possible to know whetherer both species are in the same or different RNP complexes and whether some of the smwRNAs contribute to the architecture of the nuclear skeleton. Distinct from any other nuclear RNA species, smwRNAs have two unique properties: facility of extraction, and resistance to nuclear ribonuclease digestion.     

An umbraviral protein,involved in long-distance RNA movement,binds viral RNA and forms unique,protective ribonucleoprotein complexes

Umbraviruses are different from most other viruses in that they do not encode a conventional capsid protein (CP); therefore, no recognizable virus particles are formed in infected plants. Their lack of a CP is compensated for by the ORF3 protein, which fulfils functions that are provided by the CPs of other viruses, such as protection and long-distance movement of viral RNA. When the Groundnut rosette virus (GRV) ORF3 protein was expressed from Tobacco mosaic virus (TMV) in place of the TMV CP [TMV(ORF3)], in infected cells it interacted with the TMV RNA to form filamentous ribonucleoprotein (RNP) particles that had elements of helical structure but were not as uniform as classical virions. These RNP particles were observed in amorphous inclusions in the cytoplasm, where they were embedded within an electron-dense matrix material. The inclusions were detected in all types of cells and were abundant in phloem-associated cells, in particular companion cells and immature sieve elements. RNP-containing complexes similar in appearance to the inclusions were isolated from plants infected with TMV(ORF3) or with GRV itself. In vitro, the ORF3 protein formed oligomers and bound RNA in a manner consistent with its role in the formation of RNP complexes. It is suggested that the cytoplasmic RNP complexes formed by the ORF3 protein serve to protect viral RNA and may be the form in which it moves through the phloem. Thus, the RNP particles detected here represent a novel structure which may be used by umbraviruses as an alternative to classical virions.     

Expression of hepatitis delta virus RNA deletions: cis and trans requirements for self-cleavage, ligation, and RNA packaging.

The hepatitis delta virus (HDV) genome is a circular, single-stranded, rod-shaped, 1.7-kb RNA that replicates via a rolling-circle mechanism. Viral ribozymes function to cleave replication intermediates which are then ligated to generate the circular product. HDV expresses two forms of a single protein, the small and large delta antigens (delta Ag-S and delta Ag-L), which associate with viral RNA in a ribonucleoprotein (RNP) structure. While delta Ag-S is required for RNA replication, delta Ag-L inhibits this process but promotes the assembly of the RNP into mature virions. In this study, we have expressed full-length and deleted HDV RNA inside cells to determine the minimal RNA sequences required for self-cleavage, ligation, RNP packaging, and virion assembly and to assess the role of either delta antigen in each of these processes. We report the following findings. (i) The cleavage and ligation reactions did not require either delta antigen and were not inhibited in their presence. (ii) delta Ag-L, in the absence of delta Ag-S, formed an RNP with HDV RNA which could be assembled into secreted virus-like particles. (iii) Full-length HDV RNAs were stabilized in the presence of either delta antigen and accumulated to much higher levels than in their absence. (iv) As few as 348 nucleotides of HDV RNA were competent for circle formation, RNP assembly, and incorporation into virus-like particles. (v) An HDV RNA incapable of folding into the rod-like structure was not packaged by delta Ag-L.     

RNA recognition by autoantigens and autoantibodies

The La, Ro, Sm and RNP autoantigens have been intensely studied over the past decade since cDNAs encoding autoantigens have become available. Most of these autoantigens are closely associated with RNA in RNP particles and molecular studies have provided insights into their modes of recognition and binding to RNA. For example, a common RNA Recognition Motif (RRM) was found to be a critical component of the RNA-binding domain of these autoantigens and the three dimensional structure of the RRM has been solved. As described in other articles in this series, the presence of La, Ro, Sm and RNP autoantibodies correlates with disease subsets, such as Sjogren's syndrome, systemic lupus erythematosus and other connective tissue diseases. Immunological analysis of sera from autoimmune patients using recombinant autoantigens has revealed that multiple epitopes reside along the proteins and these represent both continuous and discontinuous (conformational) autotopes. Findings to date support a model of autoantibody induction which involves the direct presentation of proteinaceous autoantigens to the immune system. Circumstantial evidence has suggested that immunological crossreactivity between systemic autoantigens and structural components of infectious agents may play an initial role in the autoimmune response to certain antigens. However, the etiology of autoimmune diseases is probably multifactoral with genetic and other immune features acting on the organismal level. In addition, RNA molecules themselves can be autoantigens with higher order structural conformations which are recognized by RNP-type autoantibodies. Immune crossreactivity and/or direct presentation may generate autoantibodies reactive with conformational RNA epitopes. If crossreactivity with components of cellular or infectious agents give rise to RNA epitopes, they may represent structural or functional mimetics of the primary epitopes that actually drive the response. These ideas are discussed with respect to the role of mimetic processes in molecular recognition during autoimmunity.     

Spliceosomal U snRNP core assembly: Sm proteins assemble onto an Sm site RNA nonanucleotide in a specific and thermodynamically stable manner.

The association of Sm proteins with U small nuclear RNA (snRNA) requires the single-stranded Sm site (PuAU(4-6)GPu) but also is influenced by nonconserved flanking RNA structural elements. Here we demonstrate that a nonameric Sm site RNA oligonucleotide sufficed for sequence-specific assembly of a minimal core ribonucleoprotein (RNP), which contained all seven Sm proteins. The minimal core RNP displayed several conserved biochemical features of native U snRNP core particles, including a similar morphology in electron micrographs. This minimal system allowed us to study in detail the RNA requirements for Sm protein-Sm site interactions as well as the kinetics of core RNP assembly. In addition to the uridine bases, the 2' hydroxyl moieties were important for stable RNP formation, indicating that both the sugar backbone and the bases are intimately involved in RNA-protein interactions. Moreover, our data imply that an initial phase of core RNP assembly is mediated by a high affinity of the Sm proteins for the single-stranded uridine tract but that the presence of the conserved adenosine (PuAU.) is essential to commit the RNP particle to thermodynamic stability. Comparison of intact U4 and U5 snRNAs with the Sm site oligonucleotide in core RNP assembly revealed that the regions flanking the Sm site within the U snRNAs facilitate the kinetics of core RNP assembly by increasing the rate of Sm protein association and by decreasing the activation energy.     

Polysomal and cytoplasmic mRNP particles containing 7S(L) RNA

Nuclear RNP complexes, cytoplasmic mRNP particles and free and membrane-bound polysomes were prepared from rat liver and their low-molecular-mass RNA components were analyzed on polyacrylamide/formamide gels. The separated small RNAs transferred to diazophenylthioether paper were hybridized to the nick-translated recombinant plasmid pA6 containing cDNA sequences for the low-Mr RNA called 7S(L) RNA. Nuclear RNP particles and free and membrane-bound polysomes were found to contain 7S(L) RNA. In the cytoplasm 7S(L) RNA could be identified as the major small RNA in 20-S cmRNP particles.     

Use of RNA Tertiary Interaction Modules for the Crystallisation of the Spliceosomal snRNP Core Domain

RNA is known to perform diverse roles in the cell, often as ribonucleoprotein (RNP) particles. While the crystal structure of these RNP particles could provide crucial insights into their functions, crystallographic work on RNP complexes is often hampered by difficulties in obtaining well-diffracting crystals. The small nuclear ribonucleoprotein (snRNP) core domain, acting as an assembly nucleus for the maturation of snRNPs, plays a crucial role in the biogenesis of four of the spliceosomal snRNPs. We have succeeded in crystallising the human U4 snRNP core domain containing seven Sm proteins and a truncated U4 snRNA variant. The most critical factor in our success in the crystallisation was the introduction of various tertiary interaction modules into the RNA that could promote crystal packing without altering the core structure. Here, we describe various strategies employed in our crystallisation effort that could be applied to crystallisation of other RNP particles.