Small nuclear RNA molecules in nuclear ribonucleoprotein complexes from mouse erythroleukemia cells

Direct cross-linking of snRNP proteins F and 70K to snRNAs by ultra-violet radiation in situ

Protein-RNA interactions in small nuclear ribonucleoproteins (UsnRNPs) from HeLa cells were investigated by irradiation of purified nucleoplasmic snRNPs U1 to U6 with UV light at 254 nm. The cross-linked proteins were analyzed on one- and two-dimensional gel electrophoresis systems, and the existence of a stable cross-linkage was demonstrated by isolating protein-oligonucleotide complexes from snRNPs containing 32P-labelled snRNAs after exhaustive digestion with a mixture of RNases of different specificities. The primary target of the UV-light induced cross-linking reaction between protein and RNA was protein F. It was also found to be cross-linked to U1 snRNA in purified U1 snRNPs. Protein F is known to be one of the common snRNP proteins, which together with D, E and G protect a 15-25 nucleotide long stretch of snRNAs U1, U2, U4 and U5, the so-called domain A or Sm binding site against nuclease digestion (Liautard et al., 1982). It is therefore likely that the core-protein may bind directly and specifically to the common snRNA domain A, or else to a sub-region of this. The second protein which was demonstrated to be cross-linked to snRNA was the U1 specific protein 70K. Since it has been shown that binding of protein 70K to U1 RNP requires the presence of the 5' stem and loop of U1 RNA (Hamm et al., 1987) it is likely that the 70K protein directly interacts with a sub-region of the first stem loop structure.

Isolation and characterization of nuclear particles containing rapidly labelled hnRNA and snRNA in combination with a distinct set of polypeptides of Mr 74000 and 72000

A heterogeneous RNP structure has been isolated from rat liver nuclei by a method previously used for the isolation of 30S RNP complexes carrying heterogeneous RNA (hnRNA) [1]. The RNP sediments in sucrose gradients with s-values of 70-110S. Formaldehyde-fixed preparations band at Q = 1.40 in isopycnic CsCl gradients. The RNP structure is composed of a heterogeneous population of polypeptides, prominent among which are two proteins with Mr 74000 and 72000. It contains both rapidly labelled RNA as well as several species of snRNA, as demonstrated by double-labelling experiments and gel electrophoresis. Treatment of rats with alpha-amanitin leads to a significant decrease in the amount of recovered RNP. In the presence of 0.7 M NaCl the s-value of the complex changes from 70-110S to 40-80S. The RNP structure is stable to mild RNase A or micrococcal nuclease digestion. Transmission electron microscopy reveals the presence of a heterogeneous population of particles with a mean diameter of 300-360 A. The isolated RNP structure differs completely from the well-known monoparticle or polyparticle hnRNP complexes and from the 30S or smaller snRNP particles but could be similar to or identical with the heterogeneous complex described by Jacob et al. [29].

Transcription-dependent localization of U1 and U2 small nuclear ribonucleoproteins at major sites of gene activity in polytene chromosomes

The location and dynamics of small nuclear ribonucleoproteins (snRNPs) were studied in salivary gland polytene chromosomes of Chironomus tentans by immunofluorescence with specific snRNP antibodies. Monoclonal antibody against the snRNP Sm antigens reacted at all sites of transcription (puffs and Balbiani rings). The amount of snRNP immunofluorescence was strictly dependent on transcription, increasing in parallel with gene activation and decreasing upon repression. Identical patterns of localization and transcriptional dependence were observed with antibodies specific for U1 or U2 snRNPs. These latter results show that the involvement of U1 and U2 snRNPs in transcription-related processes involves a high proportion, rather than small subsets, of active gene loci. In addition, the colocalization of U1 and U2 snRNPs at loci known to contain only one messenger RNA transcription unit (e.g. Balbiani ring 2) raises the possibility that both of these snRNPs interact with the same transcript. Finally, the lack of immunofluorescence at repressed loci indicates that snRNPs are not structural components of the chromatin (DNP) fiber, and also shows that unused snRNPs are not stored in chromatin. These latter points, and the growing evidence for the involvement of U1 snRNP in splicing, suggest that nascent pre-mRNA is the major chromosomal binding site for snRNPs.

Synthesis and assembly of human small nuclear ribonucleoproteins generated by cell-free translation

Cell-free translation of human poly(A)+ RNA was carried out to generate and analyze the protein constituents of small nuclear ribonucleoprotein (snRNP) particles. The snRNP proteins were identified by immunoprecipitation with sera from patients with systemic lupus erythematosus. Size fractionation of mRNA prior to translation revealed that these snBNP proteins are all encoded by separate messages. One of the proteins (the A protein, molecular weight 32,000) was seen to lose antigenicity upon RNase treatment either when extracted from cells or when generated in vitro. RNase treatment of immunoprecipitated snRNPs released the A protein in an electrophoretically pure form. Analysis of snRNPs translated in vitro revealed the presence of unassembled and assembled particles as determined by sucrose density gradient sedimentation. Post-translational assembly of snRNPs involving both RNA-protein binding (as revealed by A protein antigenicity) and associations of other snRNP proteins occurred in the in vitro system employed here. In addition, the presence of unassembled snRNP proteins permitted the determination of the precise antigen peptides recognized by Sm and RNP autoimmune sera. It was observed that Sm sera are capable of recognizing each of the eight snRNP proteins, whereas RNP sera recognize only two of the eight.

Human U1 and U2 small nuclear ribonucleoproteins contain common and unique polypeptides

Immunoprecipitation of human small nuclear ribonucleoproteins (snRNPs) containing the small nuclear RNAs U1, U2, U4, U5, and U6 with two antibodies produced in certain patients suffering from systemic lupus erythematosus was used to identify the polypeptides present on human U1 and U2 snRNPs. U1 and U2 snRNPs contain both common and unique polypeptides; visualization of the differences was possible through the use of non-methionine protein labeling and partial fractionation of snRNP populations. To facilitate comparisons with results from other laboratories, we have designated the snRNP polypeptides by their molecular weights. Four small polypeptides, P8, P9, P10, and P12, of 8,000 to 12,000 daltons, are each present in equal amounts on both U1 and U2 snRNPs. U1 snRNPs also contain a unique 30,000-dalton polypeptide, P30, whereas U2 snRNPs contain a unique 27,000-dalton, methionine-deficient polypeptide, P27. A closely migrating pair of polypeptides, P23 and P22, of 23,000 and 21,500 daltons, respectively, is present on both snRNPs; U2 snRNPs are enriched in the former, and U1 snRNPs are enriched in the latter.

Separation and characterization of low-molecular-weight nuclear RNA species that inhibit cell-free protein synthesis

Various RNA fractions were isolated from nuclei of 12-day lactating rat mammary glands and examined for their ability to inhibit cell-free protein synthesis. Although total nuclear RNA was generally inactive, material contained in the poly(A)+ nuclear RNA fraction and the low-molecular-weight RNA derived from total nuclear RNA by sucrose gradient centrifugation, inhibited the translation of several mRNAs but not poly(U) or poly(A). Separation of the small nuclear RNAs by preparative polyacrylamide-urea gel electrophoresis allowed the identification of at least three active inhibitor RNA species. These differed both with respect to their ability to inhibit protein synthesis, and in their mechanism of action. While two of the RNA species inhibited elongation the other inhibited initiation of protein synthesis.

Isolation and characterization of hnRNA-snRNA-protein complexes from Morris hepatoma cells

Of the RNA labelled after incubation of hepatoma cells with radioactive precursors for 20 and 150 min. 35% and 70%, respectively, can be isolated from nuclei by two consecutive extractions with 0.14 M NaCl at pH 8. The isolated RNA is complexed with nuclear proteins forming structures with sedimentation coefficients of less than 30 S to greater than 100 S. Similar complexes from rat liver isolated under the same experimental conditions show coefficients of 30-40 S. The RNA-associated proteins are similar, on the basis of sodium dodecyl sulphate/polyacrylamide gel electrophoresis, to the respective proteins of other cell types. The presence on these RNP complexes of six discrete small nuclear RNAs (snRNA) has been established. Experiments with a reversible inhibitor of RNA synthesis, D-galactosamine, demonstrated, differences in the turnover of hnRNA and snRNA. The half-lives of the six snRNA species has been determined, varying from 32 h for snRNA species a, b and d, to 22 h for snRNA species e and f and to 13 h for snRNA species c. Treatment of the nuclear extracts with 0.7 M and 1 M NaCl results in dissociation of hnRNA from the 'core' and other polypeptides, whereas snRNA remains complexed with polypeptides of Mr 54 000-59 000. Incubation of the nuclear extracts at 0 C with low doses of pancreatic R Nase (up to 1.5 micrograms/ml), which renders approximately 80% of the hnRNA acid-soluble and cleaves most of the snRNA, results in conversion of the high-molecular-weight hnRNPs to 30-S structures, without disrupting the 30-S RNP. Treatment of the nuclear extracts with higher doses of RNase (3 micrograms/ml) leads to disruption of the 30-S RNP and release of the hnRNA-associated proteins, underlining the importance of hnRNA-protein interaction for the retainment of the hnRNP structures.

Human U1 and U2 small nuclear ribonucleoproteins contain common and unique polypeptides

Immunoprecipitation of human small nuclear ribonucleoproteins (snRNPs) containing the small nuclear RNAs U1, U2, U4, U5, and U6 with two antibodies produced in certain patients suffering from systemic lupus erythematosus was used to identify the polypeptides present on human U1 and U2 snRNPs. U1 and U2 snRNPs contain both common and unique polypeptides; visualization of the differences was possible through the use of non-methionine protein labeling and partial fractionation of snRNP populations. To facilitate comparisons with results from other laboratories, we have designated the snRNP polypeptides by their molecular weights. Four small polypeptides, P8, P9, P10, and P12, of 8,000 to 12,000 daltons, are each present in equal amounts on both U1 and U2 snRNPs. U1 snRNPs also contain a unique 30,000-dalton polypeptide, P30, whereas U2 snRNPs contain a unique 27,000-dalton, methionine-deficient polypeptide, P27. A closely migrating pair of polypeptides, P23 and P22, of 23,000 and 21,500 daltons, respectively, is present on both snRNPs; U2 snRNPs are enriched in the former, and U1 snRNPs are enriched in the latter.

Human U1 loci: genes for human U1 RNA have dramatically similar genomic environments

We have cloned and sequenced several distinct loci from the human genome whose sequences agree exactly and are colinear with the sequence of the small nuclear RNA U1. There appear to be 100-150 such U1 loci in the human genome. Although these loci are not in close clusters or in small tandem repeats in the genome, the majority of them have remarkably similar genomic environments. Several potential RNA polymerase termination sites exist in the immediate 3' flanking regions of the loci studied; however, no TATA box is found in the immediate 5' flanking sequences. These observations, with the findings of others concerning the transcription of U1, suggest that U1 RNA is synthesized from a family of transcription units. These data are consistent with the proposal that RNA polymerase II may synthesize primary transcripts from these transcription units, which are processed at both the 5' and 3' ends to yield mature U1 RNA and possibly other RNA species of unknown function.

Small nuclear RNAs from Drosophila KC-H cells; characterization and comparison with mammalian RNAs

Small molecular weight nuclear RNAs were extracted from cultured Drosophila KC-H cells and characterized by their electrophoretic mobilities in 5--15% gradient acrylamide gels or in 10% acrylamide-7 M urea gels. Comparison between the electrophoretic profiles of these SnRNAs with those from human and mouse cells revealed striking similarities and allowed for assignation of band nomenclatures as established for mammalian cells. Comparison of mobilities in the two gel systems also permitted correspondence between the different nomenclatures established by various groups for this class of RNAs, as well as an approximate estimate of their molecular sizes.

Base-pairing interactions between small nuclear RNAs and nuclear RNA precursors as revealed by psoralen cross-linking in vivo

The psoralen derivative 4'-aminomethyl-4,5',8-trimethylpsoralen (AMT) reacts with base-paired regions of RNA and forms interstrand covalent cross-links. Since psoralens permeate living cells, they can be used to probe RNA-tRNA interactions in vivo. We used AMT to investigate whether small nuclear RNAs are base-paired with high molecular weight nuclear RNA in the cell. Intact HeLa cells were treated with AMT, and high molecular weight RNA was isolated under denaturing conditions from nuclei or from subnuclear fractions. The presence of base-paired snRNAs in the high molecular weight nuclear RNA was examined by electrophoresis after photochemical reversal of the cross-links. We found snRNA U3 and 5.8S rRNA to be cross-linked to nucleolar RNA. IN contrast, snRNA U1 was crosslinked to high molecular weight RNA in ribonucleoprotein particles containing hnRNA. The U1 base-paired to hnRNA was identified by its hybridization with a cloned U1 DNA sequence after reversal of the cross-links. These results demonstrate that U1 is base-paired with hnRNA in vivo, suggesting a role in mRNA processing.

Particles containing small molecular weight nuclear RNAs (snRNPs). Structure and possible functions

Recent knowledge on snRNPs is reviewed in this paper. The relevant findings of our laboratory were essentially as follows: Particles containing small nuclear RNAs (snRNAs) were characterized ten years ago. More recently Lerner et al. have shown that particles containing snRNAs react with antibody produced in autoimmune disease. Furthermore, the snRNA (some of them are probably involved in 'splicing') were found associated with hnRNP. In the present work we have studied structures, extracted from hnRNP that contain snRNAs. We were able to obtain and purify ribonucleoproteins complexes containing some of the snRNAs. These particles (snRNPs) are very stable. They were purified by three different successive cycles of centrifugation under denaturing conditions. The particles are characterized by a density of 1,43 g/cm3 in CsCl and a sedimentation coefficient of 11--12S. They contain five species of snRNAs (U1, U2, U4, (U5), U6 according to the nomenclature of Lerner et al.) and at least one polypeptide with a molecular weight of about 15000 daltons. An other particle containing only U5 was also isolated. These snRNPs are not disaggregated in media destabilizing ionic forces, hydrophobic interaction or hydrogens bonds and seem to different from the snRNPs described by Lerner et al.

A possible regulatory mechanism in RNA processing and its implication for posttranscriptional sequence control during differentiation of cell function

1. This paper is concerned with the possible molecular mechanism for RNA processing including posttranscriptional sequence control underlying the differentiation of cell functions. 2. It was previously postulated that intramolecular double-stranded hairpin structures present at 5'- and 3'-terminal regions of a 'pre-mRNA' are key elements for RNA splicing [24]. 3. In this paper the possibility is considered that the splicing of 'pre-mRNA' can be regulated in such a way that the formation of the proper double-stranded hairpin structures is prevented by the binding of low-molecular-weight nuclear RNA (LnRNA) to the terminal regions and/or to the nucleotide sequences around the exon-intron and intron-exon joint sites of the 'pre-mRNA' molecules. 4. Complementarity assessment of nucleotide sequences of rat preproinsulin 'pre-mRNA' and rat LnRNA, i.e. Ul, showed that Ul RNA is capable of forming stable double-standard intermolecular structures around the joint sites of preproinsulin 'pre-mRNA' and may prevent the formation of intramolecular double-stranded structures required for RNA splicing. This may imply a regulatory (inhibitory) role for Ul RNA in the processing of 'pre-mRNA'. 5. A possible regulatory role of LnRNA in RNA splicing is discussed in relation to the determination of the mRNA population to be translated in the cytoplasm during differentiation of cell functions.

Purification and characterization of a simple ribonucleoprotein particle containing small nucleoplasmic RNAs (snRNP) as a subset of RNP containing heterogenous nuclear RNA (hnRNP) from HeLa cells

A ribonucleoprotein complex whose RNA complement consists exclusively of small nuclear RNA species (snRNA) has been purified from particles containing heterogenous nuclear RNA (hnRNP) from HeLa cells. This was accomplished by taking advantage of their ability to band at a density of about 1.43 g/cm3 in plain cesium chloride as well as in cesium chloride gradients containing 0.5% sarkosyl without prior aldehyde fixation. After these two steps of equilibrium density centrifugation, these snRNPs were still largely contaminated by free proteins (and especially phosphoproteins). A final step of purification by velocity sedimentation in a sucrose gradient containing 0.5 M cesium chloride and 0.5% sarkosyl was efficient in completely eliminating all free proteins. U1, U2, U4, U5 and U6 species according to the nomenclature of Lerner et al. (Nature, (1980) 283, 220-224) were found in these purified snRNPs, while a significant part of U6 and a small amount of U2 were found in the bottom fraction. 5S species behaved entirely as free RNA and is presumably a contaminant of cytoplasmic origin. Electrophoresis of proteins from snRNP labeled in vivo with (35S) methionine, revealed four bands with migrations corresponding to molecular weights ranging between 10,000 and 14,000 daltons.

Intracellular distribution of low molecular weight RNA species in HeLa cells

Intracellular distributions of the low molecular weight RNA species of HeLa cells were determined by a nonaqueous method of cell fractionation, in which lyophilized cells were homogenized and centrifuged in anhydrous glycerol. The nonaqueous method was used to avoid artifactual extraction of weakly bound nuclear RNA during cell fractionation. We found that the mature small RNA species K, A, C, and D were almost entirely (greater than 95%) nuclear, and that mature 4S tRNA was partially (5-10%) nuclear. Our results gave higher nuclear content of the mature species K, A, C, and 4S than was shown previously with conventional aqueous cell fractionation. The nonaqueous method also gave higher nuclear proportions of some short-lived precursors to mature small RNAs. We found that approximately one-half of recently synthesized pre-4S RNA and more than one-half of recently synthesized 5S RNA were nuclear, whereas these species had been thought to be cytoplasmic from previous work. The species C' and D', precursors to the stable nuclear species C and D respectively, were found to be partially nuclear, also in contrast to earlier work. The stable cytoplasmic species L (oncornavirus 7S RNA) was found to be mostly nuclear shortly after synthesis.

The release of 40S hnRNP particles by brief digestion of HeLa nuclei with micrococcal nuclease

Brief digestion of HeLa nuclei with mirococcal nuclease releases monomer hnRNP particles as well as monomer and polynucleosomes. Sucrose gradient analysis of the nuclease released material reveals a series of small A260 peaks overlapping a more predominant peak in the 40S region of the gradient. Analysis of the proteins, DNa, and RNA in successive gradient fractions has confirmed that the smaller peaks are monomer and polynucleosomes, and that the larger peak is 40S hnRNP. Like 40S particles isolated by low salt extraction or by sonication, the nuclease released particles are composed of rapidly labeled RNA associated with a group of non-histone proteins the most predominant of which are the 32,000-44,000 MW proteins previously identified as core hnRNP proteins. These results provide further evidence that 40S hnRNP particles exist as discrete structural components of larger in vivo ribonucleoprotein complexes.

Inhibition of cell-free protein synthesis by low-molecular-weight nuclear polyadenylate-containing ribonucleic acid species isolated from the lactating guinea pig

1. Poly(A)-containing RNA was isolated from the nuclei of mammary gland, liver and brain of lactating guinea pigs. 2. Total nuclear poly(A)-containing RNA from mammary gland inhibited mRNA-directed protein synthesis by a wheat-germ cell-free system. It also inhibited the endogenous activity of the wheat-germ and other cell-free systems. It did not inhibit a wheat-germ cell-free system directed by poly(U). 3. Total nuclear poly(A)-containing RNA from liver and brain did not inhibit the mRNA-directed wheat-germ system. 4. Fractionation of the nuclear poly(A)-containing RNA revealed inhibitory activity in the less than 10 S fraction from mammary gland as well as that from liver and brain. 5. The mechanism of protein-synthesis inhibition appeared to be at the level of elongation. 6. The inhibitory activity could be reversed in a wheat-germ system by increasing the amount of S-30 supernatant. 7. The mechanism of inhibition of protein synthesis is discussed in relation to other RNA species known to inhibit such systems.