Effects of alpha-amanitin, cycloheximide, and thioacetamide on low molecular weight nuclear RNA.

Studies were made on the effects of alpha-amanitin, cycloheximide, and thioacetamide on synthesis and content of low molecular weight nuclear RNA. Cycloheximide, an inhibitor of protein synthesis and the synthesis of 45S pre-rRNA and 5S RNA, also inhibited synthesis of nuclear U1 and U3 RNAs. alpha-Amanitin, an inhibited the synthesis of U1 and U2 low molecular weight nuclear RNA. Thioacetamide, which induces nucleolar hypertrophy and increased nucleolar RNA polymerase activity, markedly increased synthesis of 5.8S RNA and U3 RNA. These results show that syntheses of individual low molecular weight nuclear (LMWN) RNAs are controlled by different regulatory mechanisms. In particular, there appears to be a specific relationship between U3 RNA and functional states of the nucleolus.     

Hybridization of low molecular weight nuclear RNA with pre-mRNA from erythroid bone marrow cells and rabbit mRNA

Hybridization of labeled low molecular weight (LMW) nuclear RNA's to pre-mRNA from rabbit non-matured erythroid bone marrow cells or globin mRNA from reticulocytes revealed three RNA species having approximately 90, 100 and 160 nucleotides which are were specifically hybridized with purified cytoplasmic globin messenger RNA, while one (100 nucleotides) was also hybridized with rabbit 18S rRNA. The identity of these rabbit RNAs to LMW RNAs described for other animal species, as well as their possible hybridization sites and function are discussed.     

Murine oncornavirus high-molecular-weight RNA structure thermal stepwise dissociation of 70S murine leukemia-sarcoma virus to subunits and low-molecular-weight associated RNAs.

The thermal dissociation into subunits and low-molecular-weight (LMW) associated RNAs of the aggregate structure of 70S RNA of a murine leukemia sarcoma viral complex was studied. By polyacrylamide-agarose gel electrophoresis, it was found that at low temperature a fraction of the genome was converted into an intermediate population of RNA (Im.P) with an apparent molecular weight of 6.6 times 10-6. At higher temperature, the 70S RNA and the Im.P RNA were successively dissociated into two RNA subunits called "I" and "II" and 70S-associated LMW RNAs. The apparent molecular weight of subunit I was about 5 times 10-6 and that of subunit II was about 3.2 times 10-6. The release of 4S, 5S, 5.5S, and 8S RNAs from 70S RNA at various temperatures was studied by composite polyacrylamide gel electrophoresis. It was found that the nature of hydrogen bonding to the 70S RNA was different for each LMW RNA species. A possible relationship of the association between the subunits and each 70S-associated LMW RNA, based on their T-m values, is discussed.     

Mouse ubiquitous B2 repeat in polysomal and cytoplasmic poly(A)+RNAs: uniderectional orientation and 3''-end localization.

A cDNA library in pBR322 was prepared with cytoplasmic poly(A)+RNA from mouse liver cells. From 1 to 1.5% of clones hybridized to either B1 or B2 ubiquitous repetitive sequences. Several clones hybridizing to a B2 repeat were partially sequenced. The full-length B2 sequence was found at the 3'-end of abundant 20S poly(A)+RNA (designated as B2+mRNAx) within the non-coding part of it. B2+mRNAx is concentrated in mouse liver polysomes and absent from cytoplasm of Ehrlich carcinoma cells. The B2 sequence seems to be located at the 3'-end of some other mRNAs as well. To determine the orientation of the B2 sequence in different RNAs, its two strands were labeled, electrophoretically separated, and used for hybridization with Northern blotts containing nuclear, cytoplasmic and polysomal RNAs. In nuclear RNA, the B2 sequence is present in both orientations; in polysomal and cytoplasmic poly(A)+RNAs, only one ("canonical") strand of it can be detected. Low molecular weight poly(A)+B2+RNA [1] also contains the same strand of the B2 element. The conclusion has been drawn that only one its strand can survive the processing. This strand contains promoter-like sequences and AATAAA blocks. The latter can be used in some cases by the cell as mRNA polyadenylation signals.     

Microbial identification by immunohybridization assay of artificial RNA labels

Ribosomal RNA (rRNA) and engineered stable artificial RNAs (aRNAs) are frequently used to monitor bacteria in complex ecosystems. In this work, we describe a solid-phase immunocapture hybridization assay that can be used with low molecular weight RNA targets. A biotinylated DNA probe is efficiently hybridized in solution with the target RNA, and the DNA-RNA hybrids are captured on streptavidin-coated plates and quantified using a DNA-RNA heteroduplex-specific antibody conjugated to alkaline phosphatase. The assay was shown to be specific for both 5S rRNA and low molecular weight (LMW) artificial RNAs and highly sensitive, allowing detection of as little as 5.2 ng (0.15 pmol) in the case of 5S rRNA. Target RNAs were readily detected even in the presence of excess nontarget RNA. Detection using DNA probes as small as 17 bases targeting a repetitive artificial RNA sequence in an engineered RNA was more efficient than the detection of a unique sequence.     

Sequential Sepharose chromatographic isolation of polysomes and polysomal RNAs depleted in nuclear RNA from Xenopus.

Analyses of sequence complexities, stage specific gene expression, and mRNA sequence divergence require polysomal RNA preparations relatively free of nuclear RNA contamination. Conventional procedures for the isolation of uncontaminated polysomal RNAs which rely on sucrose density centrifugations are laborious and unsuitable for large scale isolations. We describe here a method using sequential Sepharose chromatography for isolating polysomes and polysomal RNAs depleted for nuclear RNA. Polysomes and polysomal RNAs isolated from livers of Xenopus stimulated to produce vitellogenin were capable of directing protein synthesis in vitro and showed little evidence of degradation. The polysomal RNAs contained less than 0.5% of nuclear RNA.     

Black beetle virus: messenger for protein B is a subgenomic viral RNA

Black beetle virus induces the synthesis of three new proteins, protein A (molecular weight, 104,000), protein α (molecular weight, 47,000), and protein B (molecular weight, 10,000), in infected Drosophila cells. Two of these proteins, A and α, are known to be encoded by black beetle virus RNAs 1 and 2, respectively, extracted from virions. We found that RNA extracted from infected cells directed the synthesis of all three proteins when it was added to a cell-free protein-synthesizing system. When polysomal RNA was fractionated on a sucrose density gradient, the messengers for proteins A and α cosedimented with viral RNAs 1 (22S) and 2 (15S), respectively. However, the messenger for protein B was a 9S RNA (RNA 3) not found in purified virions. Like the synthesis of viral RNAs 1 and 2, intracellular synthesis of RNA 3 was not affected by the drug actinomycin D at concentrations which blocked synthesis of host cell RNA. This indicated that RNA 3 is a virus-specific subgenomic RNA and, therefore, that protein B is a virus-encoded protein.     

Nuclear steady-state RNA from chicken immature red blood cells. Distribution of globin-coding and poly (A) sequences

Nuclear steady-state RNA and polysomal RNA of chicken immature red blood cells were isolated and separated on formamide sucrose gradients. For comparison the distribution of 9 S globin mRNA was investigated by gradient centrifugation of 125I-labelled mRNA. The material was either pooled into two fractions (less than 20 S; greater than 20 S) and translated in an Ehrlich ascites cell-free system or each gradient fraction was analyzed by hybridization with [3H]-poly (U) or [3H]-labelled DNA complementary to purified 9 S globin mRNA (globin cDNA). In neither case could evidence be obtained for the existence of a high molecular weight RNA as a probable globin mRNA precursor. Further analysis was performed by electrophoresis of RNA on exponential polyacrylamide gels in formamide and subsequent hybridization with cDNA. The results are consistent with those of gradient centrifugation and demonstrate that the distribution of globin-coding sequences in nuclear steady state RNA corresponds to that of cytoplasmic 9 S globin mRNA.     

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.     

Interstrand duplexes in Friend erythroleukemia nuclear RNA. The interaction of non-polyadenylated nuclear RNA with polyadenylated nuclear RNA and with small nuclear RNAs

Intermolecular duplexes among large nuclear RNAs, and between small nuclear RNA and heterogeneous nuclear RNA, were studied after isolation by a procedure that yielded protein-free RNA without the use of phenol or high salt. The bulk of the pulse-labeled RNA had a sedimentation coefficient greater than 45 S. After heating in 50% (v/v) formamide, it sedimented between the 18 S and 28 S regions of the sucrose gradient. Proof of the existence of interstrand duplexes prior to deproteinization was obtained by the introduction of interstrand cross-links using 4'-aminomethyl-4,5',8-trimethylpsoralen and u.v. irradiation. Thermal denaturation did not reduce the sedimentation coefficient of pulse-labeled RNA obtained from nuclei treated with this reagent and u.v. irradiated. Interstrand duplexes were observed among the non-polyadenylated RNA species as well as between polyadenylated and non-polyadenylated RNAs. beta-Globin mRNA but not beta-globin pre-mRNA also contained interstrand duplex regions. In this study, we were able to identify two distinct classes of polyadenylated nuclear RNA, which were differentiated with respect to whether or not they were associated with other RNA molecules. The first class was composed of poly(A)+ molecules that were free of interactions with other RNAs. beta-Globin pre-mRNA belongs to this class. The second class included poly(A)+ molecules that contained interstrand duplexes. beta-Globin mRNA is involved in this kind of interaction. In addition, hybrids between small nuclear RNAs and heterogeneous nuclear RNA were isolated. These hybrids were formed with all the U-rich species, 4.5 S, 4.5 SI and a novel species designated W. Approximately equal numbers of hybrids were formed by species U1a, U1b, U2, U6 and W; however, species U4 and U5 were significantly under-represented. Most of these hybrids were found to be associated stably with non-polyadenylated RNA. These observations demonstrated for the first time that small nuclear RNA-heterogeneous nuclear RNA hybrids can be isolated without crosslinking, and that proteins are not necessary to stabilize the complexes. However, not all molecules of a given small nuclear RNA species are involved in the formation of these hybrids. The distribution of a given small nuclear RNA species between the free and bound state does not reflect the stability of the complex in vitro but rather the abundance of complementary sequences in the heterogeneous nuclear RNA.(ABSTRACT TRUNCATED AT 400 WORDS)     

Primary and secondary structure of U8 small nuclear RNA

U8 small nuclear RNA is a new, capped, 140 nucleotides long RNA species found in Novikoff hepatoma cells. Its sequence is: m3GpppAmUmCGUCAGGA GGUUAAUCCU UACCUGUCCC UCCUUUCGGA GGGCAGAUAG AAAAUGAUGA UUGGAGCUUG CAUGAUCUGC UGAUUAUAGC AUUUCCGUGU AAUCAGGACC UGACAACAUC CUGAUUGCUU CUAUCUGAUUOH. This RNA is present in approximately 25,000 copies/cell, and it is enriched in nucleolar preparations. Like U1, U2, U4/U6, and U5 RNAs, U8 RNA was also present as a ribonucleoprotein associated with the Sm antigen. The rat U8 RNA was highly homologous (greater than 90%) to a recently characterized 5.4 S RNA from mouse cells infected with spleen focus-forming virus (Kato, N., and Harada, F. (1984) Biochim. Biophys. Acta, 782, 127-131). In addition to the U8 RNA, three other U small nuclear RNAs were found in anti-Sm antibody immunoprecipitates from labeled rat and HeLa cells. Each of these contained a m3GpppAm cap structure; their apparent chain lengths were 60, 130, and 65 nucleotides. These U small nuclear RNAs are designated U7, U9, and U10 RNAs, respectively.     

A new series of RNAs associated with the genome of spleen focus forming virus (SFFV) and poly(A)-containing RNA from SFFV-infected cells.

A series of low molecular weight RNAs (4.5 to 5.5S) as well as other 4 to 7S RNAs were dissociated from genomic RNA of spleen focus forming virus (SFFV) by heating. On two dimensional polyacrylamide gel electrophoresis, this series of RNAs gave a series of more than thirty spots. RNase T1 fingerprints of these spots were identical except for differences in 3'-terminal oligonucleotides, which were mainly due to different numbers of uridylic acid residues, larger RNA-molecules containing poly(U)sequences at their 3'-termini. This series of RNAs is also associated with poly(A)-containing nuclear and cytoplasmic RNAs from SFFV-infected cells.     

Differential association of transfer RNAs with the genomes of murine, feline and primate retroviruses

The tRNAs that are bound to the genomic RNAs of several murine, feline, and primate retroviruses have been identified. Transfer RNAs were divided into those loosely bound and those tightly bound by stepwise thermal dissociation of the 70 S RNA. They were then identified and semiquantitated by aminoacylation. Proline tRNA is the most tenaciously bound tRNA in several strains of murine leukemia virus, two strains of feline leukemia virus, and the primate viruses simian sarcoma, baboon endogenous, and gibbon ape lymphoma. In the feline xenotropic virus, RD-114, tRNAGly is enriched in the most tightly bound fraction. In Mason-Pfizer monkey virus, as in the murine mammary tumor virus, tRNALys is the tRNA most tenaciously bound to its genomic RNA. Besides the most tightly associated tRNA, one or more different tRNAs are found in relatively large amounts in association with the 70 S RNA. (For convenience, we refer to the largest RNA ccomplex (50-70 S) isolated from any of the retroviruses studies as '70 S' RNA.) These tRNAs can be distinguished from the most tightly bound tRNA by the fact that they can be dissociated at lower temperatures. However, they occur in the same relative abundance as the tightly bound tRNA.