Multiple conserved segments of E1 small nucleolar RNA are involved in the formation of a ribonucleoprotein particle in frog oocytes.

E1/U17 small nucleolar RNA (snoRNA) is a box H/ACA snoRNA. To identify E1 RNA elements required for its assembly into a ribonucleoprotein (RNP) particle, we have made substitution mutations in evolutionarily conserved sequences and structures of frog E1 RNA. After E1 RNA was injected into the nucleus of frog oocytes, assembly of this exogenous RNA into an RNP was monitored by non-denaturing gel electrophoresis. Unexpectedly, nucleotide substitutions in many phylogenetically conserved segments of E1 RNA produced RNPs with abnormal gel-electrophoresis patterns. These RNA segments were at least nine conserved sequences and an apparently conserved structure. In another region needed for RNP formation, the requirement may be sequence(s) and/or structure. Base substitutions in each of these and in one additional conserved E1 RNA segment reduced the stability of this snoRNA in frog oocytes. Nucleolar localization was assayed by fluorescence microscopy after injection of fluorescein-labelled RNA. The H box (ANANNA) and the ACA box are both needed for efficient nucleolar localization of frog E1 RNA.

Small nucleolar RNAs.

Many small RNA species associate with the nucleolar structure. Some of these small nucleolar RNAs (snoRNAs) are required for cleavage processing of ribosomal RNA precursors. There are many pseudouridine residues and methylated riboses in mature ribosomal RNA. For most, if not all, of these modifications, each site is selected by base pairing with a specific snoRNA species. Some snoRNAs are needed for the 2'-O-ribose methylation of at least one spliceosomal small nuclear RNA. Many snoRNAs, particularly in yeast, are generated from independent transcription units. Most vertebrate snoRNAs are produced by processing of introns from protein-coding transcripts. Some snoRNAs are made by processing of introns from non-protein-coding transcripts.

Three small nucleolar RNAs that are involved in ribosomal RNA precursor processing.

Three small nucleolar RNAs (snoRNAs), E1, E2 and E3, have been described that have unique sequences and interact directly with unique segments of pre-rRNA in vivo. In this report, injection of antisense oligodeoxynucleotides into Xenopus laevis oocytes was used to target the specific degradation of these snoRNAs. Specific disruptions of pre-rRNA processing were then observed, which were reversed by injection of the corresponding in vitro-synthesized snoRNA. Degradation of each of these three snoRNAs produced a unique rRNA maturation phenotype. E1 RNA depletion shut down 18 rRNA formation, without overaccumulation of 20S pre-rRNA. After E2 RNA degradation, production of 18S rRNA and 36S pre-rRNA stopped, and 38S pre-rRNA accumulated, without overaccumulation of 20S pre-rRNA. E3 RNA depletion induced the accumulation of 36S pre-rRNA. This suggests that each of these snoRNAs plays a different role in pre-rRNA processing and indicates that E1 and E2 RNAs are essential for 18S rRNA formation. The available data support the proposal that these snoRNAs are at least involved in pre-rRNA processing at the following pre-rRNA cleavage sites: E1 at the 5' end and E2 at the 3' end of 18S rRNA, and E3 at or near the 5' end of 5.8S rRNA.

Intracellular localization and unique conserved sequences of three small nucleolar RNAs.

Three human small nucleolar RNAs (snoRNAs), E1, E2 and E3, were reported earlier that have unique sequences, interact directly with unique segments of pre-rRNA in vivo and are encoded in introns of protein genes. In the present report, human and frog E1, E2 and E3 RNAs injected into the cytoplasm of frog oocytes migrated to the nucleus and specifically to the nucleolus. This indicates that the nucleolar and nuclear localization signals of these snoRNAs reside within their evolutionarily conserved segments. Homologs of these snoRNAs from several vertebrates were sequenced and this information was used to develop RNA secondary structure models. These snoRNAs have unique phylogenetically conserved sequences.

5'ETS rRNA processing facilitated by four small RNAs: U14, E3, U17, and U3.

The nucleolus, the compartment in which the large ribosomal RNA precursor (pre-rRNA) is synthesized, processed through a series of nucleolytic cleavages and modifications into the mature 18S, 5.8S, and 28S rRNAs, and assembled with proteins to form ribosomal subunits, also contains many small nucleolar RNAs (snoRNAs). We present evidence that the first processing event in mouse rRNA maturation, cleavage within the 5' external transcribed spacer, is facilitated by at least four snoRNAs: U14, U17(E1), and E3, as well as U3. These snoRNAs do not augment this processing by directing 2'-O-methylation of the pre-rRNA. A macromolecular complex in which this 5'ETS processing occurs may then function in the processing of 18S rRNA.

Intron-encoded small nucleolar RNAs: new RNA sequence variants and genomic loci.

Three small nucleolar RNAs (snoRNAs) whose 5' termini are monophosphorylated, termed E1, E2 and E3, were reported earlier, and E1 and E3 are encoded in pre-mRNA gene introns. In the present work, the ends of these snoRNAs were identified by analysis of terminal mononucleotides, and heterogeneity was observed at the 3' ends of E1 and E2 RNAs. Two new E1 RNA species were detected in HeLa cells by cDNA cloning. Four novel human genomic loci were identified that have E1 or E3 sequence homology. The sequence CTAGAGCACYSAATCTGGAT (where S = C or G and Y = C or T), that is present three nucleotides downstream from the coding region of an E1 RNA-encoding gene, lies in the same location in a different human genomic locus (which has a E1-homology sequence whose expression has not been detected yet), suggesting that this sequence may be functional.

Genes for E1, E2, and E3 small nucleolar RNAs.

We have found earlier three small nucleolar RNA (snoRNA) species, named E1, E2, and E3, that have unique nucleotide sequences and may participate in ribosome formation. The present report shows that there is a monophosphate at the 5' end of each of these three snoRNAs, suggesting that their 5' termini are formed by RNA processing. E1, E2, and E3 human genomic sequences were isolated. Apparently, the E2 and E3 loci are genes for the main E2 and E3 RNA species, based on their full homology, while the E1 locus is a gene for an E1 RNA sequence variant in HeLa cells. These loci do not have any of the intragenic or flanking sequences known to be functional in other genes. The E1 gene is located within the first intron of the gene for RCC1, a protein that regulates onset of mitosis. There is substantial sequence homology between the human E3 gene and flanking regions, and intron 8 and neighboring exons of the gene for mouse translation initiation factor 4AII. Injection of the human E1, E2, and E3 genes into Xenopus oocytes generated sequence-specific transcripts of the approximate sizes of the respective snoRNAs. We discuss why the available results are compatible with specific transcription and processing occurring in frog oocytes.

Three new small nucleolar RNAs that are psoralen cross-linked in vivo to unique regions of pre-rRNA.

We have recently described three novel human small nucleolar RNA species with unique nucleotide sequences, which were named E1, E2, and E3. The present article describes specific psoralen photocross-linking in whole HeLa cells of E1, E2, and E3 RNAs to nucleolar pre-rRNA. These small RNAs were cross-linked to different sections of pre-rRNA. E1 RNA was cross-linked to two segments of nucleolar pre-rRNA; one was within residues 697 to 1163 of the 5' external transcribed spacer, and the other one was between nucleotides 664 and 1021 of the 18S rRNA sequence. E2 RNA was cross-linked to a region within residues 3282 to 3667 of the 28S rRNA sequence. E3 RNA was cross-linked to a sequence between positions 1021 and 1639 of the 18S rRNA sequence. Primer extension analysis located psoralen adducts in E1, E2, and E3 RNAs that were enriched in high-molecular-weight fractions of nucleolar RNA. Some of these psoralen adducts might be cross-links of E1, E2, and E3 RNAs to large nucleolar RNA. Antisense oligodeoxynucleotide-targeted RNase H digestion of nucleolar extracts revealed accessible segments in these three small RNAs. The accessible regions were within nucleotide positions 106 to 130 of E1 RNA, positions 24 to 48 and 42 to 66 of E2 RNA, and positions 7 to 16 and about 116 to 122 of E3 RNA. Some of the molecules of these small nucleolar RNAs sedimented as if associated with larger structures when both nondenatured RNA and a nucleolar extract were analyzed.

Three small nucleolar RNAs of unique nucleotide sequences.

Three small RNA species were detected in human cells, and their cDNAs were synthesized and cloned. These RNAs are nucleolar, are 207, 154, and 135 nucleotides long, and are named E1, E2, and E3, respectively, and their unique nucleotide sequences suggest that they may belong to an additional family of small nucleolar RNAs. The 5' ends of these three RNAs do not appear to have a trimethylguanosine cap or another type of cap. Apparent homologs of these three RNAs were detected in mouse, rabbit, and frog cells, suggesting their universal importance. They are housekeeping RNA species, since they are present in all rabbit tissues analyzed.

RNA synthesis and stability in UV-irradiated and nonirradiated mouse L cells.

In mouse L cells, relatively low doses of UV light (e.g., about 35 J/m2) induced the rapid breakdown of the molecules of many RNA species transcribed shortly before irradiation. This included 28S, 18S, 5.8S, and 5S rRNA, U1, U2, U3, U4, and U5 small nuclear RNA, but not the main band of transfer RNAs or 7SL RNA. At higher UV doses, an RNA band that contains tRNAleu was also degraded rapidly after UV irradiation. RNA molecules synthesized long before irradiation (e.g., 22 h for small RNAs, 4 h for large rRNAs) were not affected. Our results suggest that the maturation and/or assembly into fully mature ribonucleoprotein particles of several small RNA species is not completed 4 h after transcription. The effect of UV radiation occurred in mouse L cells, but not in human HeLa or KB cells. In a previous report, L cells were transformed by DNA transfection with two mouse U1b RNA genes, named U1.1 and U1.2. We observed now that, in L cells transformed with the U1.2 gene, the ratio of radioactivity in the apparent U1b and U1a RNA precursors after 5 min of labeling was about 20 times higher than a) this ratio in briefly labeled L cells that had been transformed with the U1.1 gene, and b) the ratio of radioactive mature U1b and U1a RNA after 20 h of chase in L cells transformed with the U1.2 gene. These results suggest that very high levels of U1b RNA are transcribed from the exogenous U1.2 gene copies, followed by the rapid degradation of most of these transcripts.

Ultraviolet light-induced inhibition of small nuclear RNA synthesis.

Two apparently distinct types of inhibition of the synthesis of U1, U2, U3, U4, and U5 small nuclear RNA, induced by ultraviolet (UV) radiation, have been described before: immediate and delayed. Our present observation can be summarized as follows: a) neither the immediate nor the delayed inhibition appear to be mediated by the formation of cyclobutane pyrimidine dimers, since they were not prevented by photoreactivating light, in ICR 2A frog cells; b) the inhibition of U1 RNA synthesis, monitored in HeLA cells within the first few minutes after irradiation, extrapolated to a substantial suppression at time zero of postirradiation cell incubation, providing further support for the proposal that the immediate inhibition is a reaction separate from the delayed UV light-induced inhibition of U1 RNA synthesis; c) the transition from the pattern of the immediate inhibition to that of the delayed inhibition (disappearance of the UV-resistant fraction of U1 RNA synthesis and increased rate of inhibition) occurred gradually, without an apparent threshold, within the first 2 hr of incubation after irradiation; and d) the incident UV dose that resulted in a 37% level of residual U1 RNA synthesis (D37) during the delayed inhibition was about 7 J/m2, with an apparent UV dose threshold, and was about 60 J/m2 for the immediate inhibition.

Metabolism of small RNAs in cultured human cells.

There are gaps in what is known about the metabolism of some mammalian small RNA species. Our present observations can be summarized as follows. The level of radiolabeled mature U1 RNA doubled between 2 and 24 hr of label chase, while that of all other small RNA species tested did not change. These results are compatible with the possibility that the nucleotide precursor pool for U1 RNA transcription may be partly segregated, or that there may be a second pathway of U1 RNA formation. Precursors of nucleolar U3 RNA were detected whose electrophoretic mobilities are equivalent to those of transcripts approximately 14 and approximately 8 nucleotides longer than the mature species, and which are apparently cytoplasmic. The ladder of U2 RNA precursors showed a gap, suggesting that some of the cleavages during U2 RNA processing are endonucleolytic. We detected an apparent U5 RNA precursor whose electrophoretic mobility is equivalent to that of a species approximately 1 nucleotide longer than mature U5 RNA. There was a predominant band in the middle of the ladder of U4 RNA precursors (apparently approximately 3 nucleotides longer than mature U4 RNA) which suggests that U4 RNA maturation may pause briefly at that intermediate. There are apparently two additional species of mature hY3 RNA, which are less abundant and are about 1 and 2 bases longer than the major hY3 RNA species. An apparent hY3 RNA precursor was detected, which may be approximately 2-3 nucleotides longer than the main mature hY3 RNA species.

Adenovirus infection retards ribosomal RNA processing.

Eight hours after infection of KB cells with adenovirus type 12, the rate of conversion from the 32S ribosomal RNA (rRNA) precursor to mature 28S and 5.8S rRNA decreased. An additional RNA species was detected, which appears to be novel, on the basis of its estimated size (about 6.5 kilobases) and its high level of radiolabeling early after infection at low multiplicity.

Metabolism of U6 RNA species in nonirradiated and UV-irradiated mammalian cells.

We observed a series of rapidly labeled U6 RNA bands, which were hybrid selected with U6 DNA, in nonirradiated human cells. The electrophoretic mobility of these bands in denaturing gels was lower than that of the known mature U6 RNA species, and was equivalent to transcripts up to approximately 7 nucleotides longer. These multiple U6 RNA species lost their label during a chase without a proportional increase in radioactivity in the known mature U6 RNA, which suggests that a substantial fraction is not processed into the major mature U6 RNA. During a label chase, the multiple U6 RNA bands appeared first in the cytoplasmic fraction and later in nuclei. One of the major rapidly labeled U6 RNA bands had the electrophoretic mobility of an RNA species one nucleotide shorter than the known mature U6 RNA. UV light induced a UV dose-dependent, preferential disappearance of recently synthesized molecules of the U6 RNA species of higher gel electrophoretic mobility, including the known mature U6 RNA. Since this effect was seen in cells pulse-labeled immediately before or after irradiation, it suggests that UV radiation induces the specific degradation of the electrophoretically faster moving species of U6 RNA, which are apparently shorter chains. The effect of UV light was RNA species-specific, was not seen in molecules synthesized long (e.g., 22 hr) before irradiation, and occurred in human and mouse cells.

Effect of ultraviolet light on the expression of genes for human U1 RNA.

Two types of UV-light-induced inhibitions of the synthesis of small nuclear RNA species U1, U2, U3, U4, and U5 were described previously: an immediate inhibition and a separate, delayed suppression that requires 1-2 hr of postirradiation cell incubation and UV doses that are about tenfold lower. In the present report, U1 RNA transcription in isolated nuclei from HeLa cells, assayed by RNAase T1 protection, reproduced the delayed inhibition. The sizes of the protected RNA fragments suggest that it is the initiation of U1 RNA transcription that is blocked during this inhibition. Transient expression of a marked human U1 RNA gene that contains 425 and 92 nucleotides of the 5' and 3' flanking sequences, respectively, showed delayed, but not immediate inhibition (while the endogenous U1 RNA genes exhibited immediate suppression). This indicates that continuity of the U1 gene flanking sequences beyond those segments and/or chromosomal integration of the U1 gene are not needed for the delayed inhibition, but may be required for the immediate inhibition. Irradiation of a U1 RNA gene, followed by its injection into Xenopus laevis oocyte nuclei, did not reproduce the immediate or delayed inhibitions. This suggests that direct UV radiation damage to DNA in the U1 RNA gene region is not the critical lesion in either the immediate or delayed UV-light-induced inhibitions of U1 RNA synthesis. In addition, the RNAase T1 protection pattern of transcripts synthesized in isolated nuclei from nonirradiated HeLa cells suggests that these cells may produce small amounts of U1 RNA molecules with variant nucleotide sequences in the mature region of the transcript.

Inhibition of small nuclear RNA synthesis by ultraviolet radiation.

It was reported earlier that the biosynthesis of small nuclear RNAs (snRNAs) (U1, U2, U3, U4, and U5) shows an unexpected great sensitivity to ultraviolet (UV) radiation (254 nm). In this "early" inhibition, snRNA formation is suppressed immediately after exposure to UV light. There is also a second "late" inhibition of snRNA biosynthesis which requires lower doses of UV radiation and 1-2 h of postirradiation cell incubation to develop fully. In the present work we asked which step, within the metabolic pathway leading to the accumulation of newly made snRNA, is affected by UV light. Both for the early and late UV radiation-induced inhibitions: (a) similar results were obtained after pulse labeling or pulse chasing the radiolabel, implying that UV light did not decrease the stability of newly made snRNA; and (b) gel electrophoretic analysis of radiolabeled RNA that had been hybrid selected with cloned snRNA genes showed no accumulation of putative snRNA precursors, suggesting that UV radiation did not block snRNA processing. Instead, when transcription was carried out in isolated nuclei from irradiated cells, the effects of "early" and "late" inhibition were reproduced, indicating that transcription was affected. The early suppression appears to be a separate reaction from the late inhibition, since U1 snRNA transcription in isolated nuclei was inhibited in the absence of postirradiation cell incubation. There is a small fraction of snRNA synthesis that is resistant to high UV light doses (greater than or equal to 870 J/m2) right after irradiation, but is sensitive to lower doses (less than or equal to 36 J/m2) when the cells are incubated for 2 h after irradiation.

Effect of UV light on small nuclear RNA synthesis: increased inhibition during postirradiation cell incubation.

It has been shown previously that the synthesis of small nuclear RNAs (snRNAs) U1, U2, U3, U4, and U5, in contrast to that of all other RNA species tested, decreases markedly within 2 h of cell incubation after exposure to UV light (254 nm), while pyrimidine dimers are being removed from DNA. We examined the possibility that the postirradiation cell incubation-dependent, UV light-induced inhibition of snRNA synthesis might reflect hypersensitivity of the snRNA transcriptional domains to single-stranded DNA nicks or relaxation of DNA torsional stress or both that occur during DNA repair. This late suppression of snRNA biosynthesis was as pronounced in UV light-irradiated (DNA incision-deficient) xeroderma pigmentosum fibroblasts (complementation group A) as in irradiated normal human fibroblasts. The synthesis of snRNAs was not preferentially sensitive to gamma radiation (which produces single-stranded DNA breaks) or novobiocin or nalidixic acid (which induce DNA relaxation). Neither of these two drugs prevented the UV light-induced inhibition of snRNA synthesis observed during postirradiation cell incubation. These results suggest that the late suppression of snRNA synthesis does not result from hypersensitivity of snRNA transcriptional domains to single-stranded DNA cleavages or relaxation of DNA torsional strain. The UV light-induced late inhibition of snRNA synthesis: shows an inactivation curve whose slope differs from that observed immediately after irradiation; is seen in untransformed cells as well as established cells lines; and has been conserved between birds and mammals.

Detection of intranuclear clusters of Sm antigens with monoclonal anti-Sm antibodies by immunoelectron microscopy.

It has been shown that small nuclear RNA (snRNA) species U1, U2, U4, U5, and U6 are found in the nucleus in the form of small nuclear ribonucleoprotein particles (snRNPs), and that anti-Sm antibodies react with snRNP polypeptides, which are associated with all five snRNAs. We report here a novel intranuclear complex, denoted "Sm cluster," detected by immunostaining with monoclonal anti-Sm antibodies in HeLa cells.