The addition of 5′ cap structures occurs early in hnRNA synthesis and prematurely terminated molecules are capped

After cells were labeled by brief exposure to ³H-methyl-L-methionine, the majority of labeled 5′ terminal cap I (m⁷GpppN₁mpN₂p) oligonucleotide structures were in nuclear RNA (hnRNA) molecules ～750 nucleotides or less in length. After longer label times, the proportion of cap I structures in nuclear molecules longer than mRNA rose to approximately 60% of the total, but approximately 40% of the cap I structures were still in molecules shorter than ～750 nucleotides. The cap I structures in both long and short hnRNA chains contained all four 2′ methylated nucleotides in the N₁ position in about the same proportion as in mRNA. None of the large hnRNA molecules could be demonstrated to contain 5′ pppXp termini; the only such terminus in high molecular weight RNA was pppAp which was decreased markedly by low doses of actinomycin and is presumably the terminus of pre-rRNA. These results raise the possibilities that hnRNA chains can initiate with any of the four nucleotides, that capping occurs very close to or at the start of hnRNA chain synthesis and that approximately 40% of the hnRNA chains may be prematurely terminated.     

Rates of synthesis and turnover of 5′ cap structures of hnRNA and mRNA and their changes during sea urchin development

The relationship between heterogeneous nuclear RNA (hnRNA) and messenger RNA (mRNA) synthesis has been studied as a function of the development of the sea urchin embryo through the use of methyl incorporation. Several parameters in the metabolism of capped hnRNA and mRNA of early blastula and late gastrula stages have been investigated by measuring the kinetics of transfer of methyl groups from S-adenosylmethionine to the 5′ cap structures in nuclear and cytoplasmic RNA:

• 1 The rate constants for the decay of hnRNA caps and the synthesis of mRNA caps are equal to within experimental error. This equality indicates a flux of precursor hnRNA caps to mRNA caps with a very high degree of conservation of the hnRNA caps. This conservation holds for each embryonic stage.
• 2 From literature data on the labeling kinetics of GTP and mRNA, we have calculated the decay constant of a putative mRNA precursor component of hnRNA. The value of this constant is very close to that for the decay constant of hnRNA caps. Hence, all hnRNA caps and some portion of their associated hnRNA sequences behave kinetically as the pre-mRNA fraction. This kinetically ascribed pre-mRNA comprises approximately 30% of the hnRNA mass.
• 3 The part of the hnRNA which does not serve as precursor to mRNA turns over at least twice as rapidly as the pre-mRNA fraction.
• 4 During development from early blastula to late gastrula, the rate of hnRNA cap synthesis drops from 2 × 10³ molecules/min/cell to half of this value. This decline is parallel to the decline in total hnRNA synthesis and thereby confirms the constant degree of capping of hnRNA, as previously reported. We infer that the pre-mRNA fraction of hnRNA remains nearly constant during this developmental period.

     

Heterogeneous nuclear RNA-protein fibers in chromatin-depleted nuclei

The heterogeneous nuclear RNA-protein (hnRNP) fibers in HeLa cell nuclei are visualized by a nuclear subfractionation technique which removes 96% of the chromatin in a single step and 99% in a two-step elution but leaves the bulk of the hnRNA complexed with the remnant nuclear structure or lamina. Both steady-state and newly synthesized (approximately 15-s label) hnRNA are associated with the remnant nuclei to about the same extent. This association does not appear to depend on the presence of chromatin and exists in addition to any possible association of hnRNP with chromatin itself. Electron microscopy of partially purified nuclear hnRNA complexes shows that the hnRNP fibers form a ribonucleoprotein network throughout the nucleus, whose integrity is dependent on the RNA. Autoradiography confirms that hnRNA is a constituent of the fibers. The RNA network visualized in these remnant nuclei may be similar to RNA networks seen in intact cells. The hnRNA molecules appear to be associated with the nuclear lamina, at least in part, by unusual hnRNA sequences. More than half of the recovered poly(A) and double-stranded hnRNA regions remains associated with the nuclear structures or the laminae after digestion with RNase and elution with 0.4 M ammonium sulfate. In contrast, the majority of oligo(A), another ribonuclease resistant segment, is released together with most of the partially digested but still acid-precipitable single- stranded hnRNA and the hnRNP proteins not eluted by the ammonium sulfate alone. These special RNA regions appear to be tightly bound and may serve as points of attachment of the hnRNA to nuclear substructures. It is suggested that hnRNA metabolism does not take place in a soluble nucleoplasmic compartment but on organized structures firmly bound to the nuclear structure.     

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.     

5'' Caps in hnRNA: absence of m32,2,7G and size distribution of capped molecules.

In HeLa cells the "small nuclear" RNA has a cap II 5' structure (8)-- m32,2,7G(5') pppXmpYmp-- where X and Y are 2'0 methylated adenosine and uridine. In contrast hnRNA contains only cap I structures were the 2'0 methylated residue may be any base as was earlier reported for cytoplasmic mRNA (8,9,11). With a clear distinction between the source of these two caps an analysis of the size distribution of capped hnRNA could be performed which revealed over 65% of the capped hnRNA molecules were larger than cytoplasmic mRNA.     

The small nuclear RNAs of the cellular slime mold Dictyostelium discoideum. Isolation and characterization

Three species of small nuclear RNA from the lower eucaryote Dictyostelium discoideum have been isolated and characterized with regard to size, cellular abundance, modified nucleotide content, and 5'-end structures. Previous studies had shown that the nuclei of mammalian cells contain a number of discrete low molecular weight, nonribosomal, nontransfer RNA molecules known as small nuclear RNAs. The mammalian small nuclear RNAs range in size from approximately 100 to 250 nucleotides and are quite abundant, in some cases approaching ribosomal RNA in number of copies/cell. Some of these molecules have an unusual cap structure at their 5'-ends similar to that found on eucaryotic messenger RNAs, and a number contain a characteristic set of internal modifications as well. Our results indicate that the small nuclear RNAs of Dictyostelium resemble their counterparts in higher eucaryotic cells structurally, but are present in significantly fewer copies/cell. The implications of these findings for small nuclear RNA function are discussed.     

5'-terminal structures of poly(A)+ cytoplasmic messenger RNA and of poly(A)+ and poly(A)- heterogeneous nuclear RNA of cells of the dipteran Drosophila melanogaster.

Structures at the 5′ terminus of poly (A)-containing cytoplasmic RNA and heterogeneous nuclear RNA containing and lacking poly(A) have been examined in RNA extracted from both normal and heat-shocked Drosophila cells. ³²P-labeled RNA was digested with ribonucleases T₂, T₁ and A and the products fractionated by a fingerprinting procedure which separates both unblocked 5′ phosphorylated termini and the blocked, methylated, “capped” termini, known to be present in the messenger RNA of most eukaryotes.Approximately 80% of the 5′-terminal structures recovered from digests of poly(A)-containing Drosophila mRNA are cap structures of the general form m⁷G^5′ppp^5′X(m)pY(m)pZp. With respect to the extent of ribose methylation and the base distribution, the 5′-terminal sequences of Drosophila capped mRNA appear to be intermediate between those of unicellular eukaryotes and those of mammals. Drosophila is the first organism known in which type 0 (no ribose methylations), type 1 (one ribose methylation), and type 2 (two ribose methylations) caps are all present. In contrast to mammalian cells, the caps of Drosophila never contain the doubly methylated nucleoside N⁶,2′-O-dimethyladenosine. Both purines and pyrimidines can be found as the penultimate nucleoside of Drosophila caps and there is a wide variety of X-Y base combinations. The relative frequencies of these different base combinations, and the extent of ribose methylation, vary with the duration of labeling. The large majority of poly(A)-containing cytoplasmic RNA molecules from heat-shocked Drosophila cells are also capped, but these caps are unusual in having almost exclusively purines as the penultimate X base.Greater than 75% of the 5′ termini of heterogeneous nuclear RNA (hnRNA) containing poly(A) and greater than 50% of the termini of hnRNA lacking poly (A) are also capped. Triphosphorylated nucleotides, common as the 5′ nucleotides of mammalian hnRNA, are rare in the poly(A)-containing hnRNA of Drosophila. The frequency of the various type 0 and type 1 cap sequences of cytoplasmic and nuclear poly (A)-containing RNA are almost identical. The caps of hnRNA lacking poly(A) are also quite similar to those of poly-adenylated hnRNA, but are somewhat lower in their content of penultimate pyrimidine nucleosides, suggesting that these two populations of molecules are not identical.     

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.     

Globin mRNA precursor. Cross-linking in situ of double-stranded segments with aminomethyltrioxalen.

The globin mRNA sequences present in duck erythroblast nuclei appear under non-denaturing conditions to be associated with heterogeneous nuclear RNA (hnRNA) molecules of various sizes. Under denaturing conditions, however, the bulk of the globin mRNA sequences associated with hnRNA are released as molecules of size close to that of the active globin mRNA. To find out whether hydrogen-bonded structures occur in situ or arise after RNA extraction, nuclei were treated with aminomethyltrioxalen and exposed to ultraviolet light. This treatment generates covalent links between opposite strands of double-stranded nuclei acids, which were visualised by electron microscopy. It appears that, after cross-linking, a fraction of the globin mRNA sequences present in nuclei is associated with high-molecular-weight hnRNA molecules by a link found associated with a band of 0.9 x 10(6) molecular weight approximately. It is suggested that within the erythroblast nucleus, globin mRNA sequences are associated by hydrogen bonds with RNA of high molecular weight. These structures may represent intermediate steps in globin mRNA processing.     

Characterization of the Low-Molecular-Weight RNAs Associated with the 70S RNA of Rous Sarcoma Virus

Two low-molecular-weight RNAs are associated with the 70S RNA complex of Rous sarcoma virus: a previously described 4S RNA and a newly identified 5S RNA. The 4S RNA constitutes 3 to 4% of the 70S RNA complex or the equivalent of 12 to 20 molecules per 70S RNA. It exhibits a number of structural properties characteristic of transfer RNA as revealed by two-dimensional electrophoresis of oligonucleotides obtained from a T1 ribonuclease digest of the 4S RNA species. The 5S RNA is approximately 120 nucleotides in length, constitutes 1% of the 70S RNA complex or the equivalent of 3 to 4 molecules per molecules of 70S RNA, and is identical in nucleotide composition and structure to 5S RNA from uninfected chicken embryo fibroblasts. Melting studies indicate that the 5S RNA is released from the 70S RNA complex at the same temperature required to dissociate 70S RNA into its constituent 35S subunits. In contrast, greater than 80% of the 4S RNA is released from 70S RNA prior to its conversion into subunits. The possible biological significance of these 70S-associated RNAs is discussed.     

Biosynthesis and utilization of extensively undermethylated poly(A)+ RNA in CHO cells during a cycloleucine treatment.

The role of RNA methylations in the control of mRNA maturation and incorporation into polysomes has been investigated through a study of the effects in vivo of cycloleucine, a specific inhibitor of S-adenosyl-methionine mediated methylation. During the cycloleucine treatment, the rate of biosynthesis of hnRNA and its subsequent polyadenylation were only slightly reduced as compared with untreated cells. However a significant lag-time in the cytoplasmic appearance of poly(A)+ undermethylated molecules was observed, in parallel with a transient shift in the average size of hnRNA towards higher molecular weight. Nevertheless, the total amount of pulse-labelled poly(A)+ mRNA transferred to cytoplasm after a long chase time (3 h.) was approximately the same for both cycloleucine-treated and control cells. Extensively undermethylated poly(A)+ cytoplasmic RNAs, possessing a 5' terminal cap were incorporated into polysomes in proportions very similar to control messenger molecules. These results suggest that a normal level of methylation is not stringently required for the production of the functional mRNA molecules although it appears to be of importance for the kinetics of the maturational process.     

A new class of small nuclear RNA molecules synthesized by a type I RNA polymerase in HeLa cells

A new class of previously undetected small RNA molecules with a range of discrete sizes between 6S and 10S has been identified in HeLa cell nuclei. They differ in size and location from the previously described small nuclear RNA species (snRNA). These RNA molecules were initially found by selective RNA labeling in vitro in isolated nuclei. The in vitro products migrate in gel electrophoresis in the region from 6–10S with predominant components between 8S and 10S. They are labeled in the presence of very high concentrations of α-amanitin (150–400 μg/ml), suggesting they are synthesized by a type I polymerase. Unlike the major polymerase I product, ribosomal precursor RNA, however, these molecules are found in the nucleoplasm and their labeling is not affected by pretreatment of cells with low concentrations of actinomycin D (0.04 μg/ml). Their formation by a presumptive polymerase I type of enzyme is the basis of their tentative designation as small nuclear polymerase I (snPI) RNAs.The snPI RNA molecules appear to be associated with chromatin and the nuclear matrix. They can be selectively eluted from nuclei leaving most of hnRNA behind. This association is used as the basis of fractionation procedures which separate these molecules from hnRNA and permit the demonstration of the synthesis of at least the most predominant of these RNA molecules in vivo. w     

Antibodies elicited by N2,N2-7-trimethylguanosine react with small nuclear RNAs and ribonucleoproteins

The 5' ends of U1, U2, U3, U4, and U5 small nuclear RNAs (snRNA) are capped by a structure which contains N2,N2-7-trimethylguanosine (m2,2,7 G). m2,2,7 G was used as hapten to raise antibodies in rabbits, and these antibodies were linked to Sepharose. When deproteinized RNA was passed through this antibody column, these snRNA species were retained by the column. Conversely, 4 S, 5 S, 5.8 S, U6, and 7 S RNA, whose 5' termini do not contain m2,2,7 G, were not recognized. After a nuclear extract was loaded on the column, U1 RNA and some U2 RNA were retained. Therefore, the 5' ends of at least U1 RNA are accessible when this RNA species is in small nuclear ribonucleoprotein particle (snRNP) form. This is of interest, since it has been proposed that the 5' terminus sequence of U1 RNA may hybridize with splice junctions in heterogeneous nuclear ribonucleoprotein particles (hnRNP) during mRNA splicing. The retention of m2,2,7 G-containing RNA species by these antibodies is not due to association of snRNAs or snRNPs with heterogeneous nuclear RNA (hnRNA) or hnRNP (and antibody recognition of 7-monomethylguanosine residues in hnRNA), since the reaction still occurs after removal of hnRNA or hnRNP by sucrose gradient centrifugation.