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

Host RNA Packaging by Retroviruses: A Newly Synthesized Story

A fascinating aspect of retroviruses is their tendency to nonrandomly incorporate host cell RNAs into virions. In addition to the specific tRNAs that prime reverse transcription, all examined retroviruses selectively package multiple host cell noncoding RNAs (ncRNAs). Many of these ncRNAs appear to be encapsidated shortly after synthesis, before assembling with their normal protein partners. Remarkably, although some packaged ncRNAs, such as pre-tRNAs and the spliceosomal U6 small nuclear RNA (snRNA), were believed to reside exclusively within mammalian nuclei, it was demonstrated recently that the model retrovirus murine leukemia virus (MLV) packages these ncRNAs from a novel pathway in which unneeded nascent ncRNAs are exported to the cytoplasm for degradation. The finding that retroviruses package forms of ncRNAs that are rare in cells suggests several hypotheses for how these RNAs could assist retrovirus assembly and infectivity. Moreover, recent experiments in several laboratories have identified additional ways in which cellular ncRNAs may contribute to the retrovirus life cycle. This review focuses on the ncRNAs that are packaged by retroviruses and the ways in which both encapsidated ncRNAs and other cellular ncRNAs may contribute to retrovirus replication.

Mouse nucleolin binds to 4.5S RNAh, a small noncoding RNA

4.5S RNAh is a rodent-specific small noncoding RNA that exhibits extensive homology to the B1 short interspersed element. Although 4.5S RNAh is known to associate with cellular poly(A)-terminated RNAs and retroviral genomic RNAs, its function remains unclear. In this study, we analyzed 4.5S RNAh-binding proteins in mouse nuclear extracts using gel mobility shift and RNA-protein UV cross-linking assays. We found that at least nine distinct polypeptides (p170, p110, p93, p70, p48, p40, p34, p20, and p16.5) specifically interacted with 4.5S RNAhin vitro. Using anti-La antibody, p48 was identified as mouse La protein. To identify the other 4.5S RNAh-binding proteins, we performed expression cloning from a mouse cDNA library and obtained cDNA clones derived from nucleolin mRNA. We identified p110 as nucleolin using nucleolin-specific antibodies. UV cross-linking analysis using various deletion mutants of nucleolin indicated that the third of four tandem RNA recognition motifs is a major determinant for 4.5S RNAh recognition. Immunoprecipitation of nucleolin from the subcellular fractions of mouse cell extracts revealed that a portion of the endogenous 4.5S RNAh was associated with nucleolin and that this complex was located in both the nucleoplasm and nucleolus.

Survival motor neuron protein in the nucleolus of mammalian neurons

Spinal muscular atrophy (SMA) is an inherited motor neuron disease caused by mutations in the survival motor neuron gene (SMN1). While it has been shown that the SMN protein is involved in spliceosome biogenesis and pre-mRNA splicing, there is increasing evidence indicating that SMN may also perform important functions in the nucleolus. We demonstrate here through the use of a previously characterized polyclonal anti-SMN antibody, abSMN, that the SMN protein shows a striking colocalization with the nucleolar protein, fibrillarin, in both nucleoli and Cajal bodies/gems of primary neurons. Immunoblot analysis with antifibrillarin and two different anti-SMN antibodies reveals that SMN and fibrillarin also cofractionate in the insoluble protein fraction of cultured cell lysates. Immunoprecipitation experiments using whole cell extracts of HeLa cells and cultured neurons revealed that abSMN coprecipitated small amounts of the U3 small nucleolar RNA (snoRNA) previously shown to be associated with fibrillarin in vivo. These studies raise the possibility that SMN may serve a function in rRNA maturation/ribosome synthesis similar to its role in spliceosome biogenesis.

Molecular cloning and in vitro transcription of rat 4.5S RNAH genes

4.5S RNAH (4.5S RNA associated with poly A containing RNA) has extensive homology to major interspersed repeat B1 in rodent genomes. We developed a new cloning technique for screening genomic library that eliminates the signal produced by repeated sequences or pseudogenes and applied it to cloning of 4.5S RNAH genes. Six phage clones (2, 3, 6, 9, 10 and 15) which hybridize with 4.5S RNAH were isolated from a rat gene library by this method. The restriction fragments containing the 4.5S RNAH locus were subcloned into plasmids and sequenced. Clones 2, 3, 9 and 15 contained one to five base substitutions in the coding region for 4.5S RNAH and were probably pseudogenes. In clone 2, the 4.5S RNAH locus was linked directly with the identifier sequence. Clone 6 contained three copies of the 4.5S RNAH gene (6a, b and c) which were clustered in the same direction within 455 base pairs. 6b was linked directly with 6c and ubiquitous repetitive DNA sequences B2 were inserted immediately after 6a and 6c. These three sequences as well as the sequence in clone 10 were colinear with rat 4.5S RNAH. In an in vitro transcription system, only clone 10 gave intact 4.5S RNAH.

Cloning and characterization of rat 4.5S RNAI genes

Genomic clones containing genes for 4.5S RNAI, which is an abundant small nuclear RNA found in rodent cells, were obtained from a rat genomic library. Thirty-four clones that formed RNase A resistant hybrids with 3'-end-labeled 4.5S RNAI were isolated, and seven of them (clones lambda I39, lambda I41, lambda I42, lambda I51, lambda I106, lambda I123 and lambda I154) were characterized by sequencing and in vitro transcription. Clones lambda I41 and lambda I123 carry one and two genes, respectively, with identical sequences to that of 4.5S RNAI and are actively transcribed in vitro. However, the other five clones contain sequences that seem to be pseudogenes for 4.5S RNAI, since they have nucleotide substitutions or deletions in the sequence corresponding to 4.5S RNAI or are not transcribed. Four clones (lambda I39, lambda I42, lambda I106 and lambda I154) were found to have 13-18 nucleotide-long direct repeats flanking the 4.5S RNAI sequences. The genomic organization of the genes and their related sequences is discussed.

Stable tRNA precursors in HeLa cells

Two tRNA precursors were isolated from 32P-labeled or unlabeled HeLa cells by two dimensional polyacrylamide gel electrophoresis, and were sequenced. These were the precursors of tRNAMet and tRNALeu, and both contained four extra nucleotides including 5'-triphosphates at their 5'-end and nine extra nucleotides including oligo U at their 3'-end. These RNAs are the first naturally occurring tRNA precursors from higher eukaryotes whose sequences have been determined. In these molecules, several modified nucleosides such as m2G, t6A and ac4C in mature tRNAs were undermodified. Two additional hydrogen bonds were formed in the clover leaf structures of these tRNA precursors. These extra hydrogen bonds may be responsible for the stabilities of these tRNA precursors.

Co-ordinate control of gene expression. Muscle-specific 7 S RNA contains sequences homologous to 3'-untranslated regions of myosin genes and repetitive DNA

We have cloned and sequenced a complementary DNA copy (pSS48) of a novel muscle-specific, low molecular weight RNA, 7 S RNA, isolated from embryonic chick cardiac muscle cells. The hybridization pattern of plasmid pSS48 DNA to chick genomic DNA suggests that 7 S RNA is derived from the repetitive chick DNA with a repetition frequency of about 300 copies per haploid genome. Under low stringency, pSS48 DNA also hybridizes with high specificity to the single copy gene for chick myosin light chain (MLC) and to myosin heavy chain (MHC), and possibly to other co-ordinately expressed genes for chick muscle proteins. The sequence analysis of recombinant plasmids pSS48, pML10 and pMHC8, for 7 S RNA, MLC mRNA and MHC RNA, respectively, indicated that short nucleotide stretches homologous to 7 S RNA reside in the 3' untranslated regions of the respective genes. The 7 S RNA sequence appears to be highly specific for the chick muscle tissue, since RNA and DNA from several sources did not hybridize to pSS48 DNA. Furthermore, the 7 S RNA-like sequence(s) appears in chick blastodermal cells preferentially earlier than the onset of transcription of genes for major muscle proteins. These results, taken together, suggest a possible function for 7 S RNA in expression of muscle-specific genes during chick development.

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)

Nucleotide sequence of nuclear 5.4 S RNA of mouse cells

The nucleotide sequence of nuclear 5.4 S RNA, a new species of small nuclear RNA (snRNA) of mouse cells, was determined. The 5.4 S RNA consists of 138 nucleotide residues containing 1 mol each of 2,2,7- trimethylguanosine (m3(2,2,7) G), 2'-O-methyladenosine (Am), 2'-O-methyluridine (Um) and pseudouridine as modified nucleosides. This RNA has a cap structure, m3(2,2,7) ++GpppAm -, at its 5'-terminus and sequences complementary to the terminal consensus sequences of introns. The sequence complementary to the 5'-splice junction, A-U-C-C-psi-U-A-C-C-U-G, is very similar to the 5'-terminal sequence of U1 RNA.

Drosophila melanogaster U1 and U2 small nuclear RNA genes contain common flanking sequences

The flanking sequences of three U2 genes (or pseudogenes) and one U1 gene of Drosophila melanogaster have been determined. Comparison of the sequences reveals a remarkable homology between position -30 and -65 upstream from the structural genes, starting with a TATA box-like sequence. The 3' flanking regions are also conserved in all genes and contain a canonical A-A-T-A-A-A polyadenylation signal.

Chemical modification of cytosine residues of U6 snRNA with hydrogen sulfide (nucleosides and nucleotides. Part 49 [1])

Sulfhydrolysis of cytosine residues to 4-thiouracil residues in mouse U6 snRNA was carried out to examine the secondary structure of U6 snRNA. The cytosine residues at positions 6, 42 and 68 were modified significantly, and at positions 11, 19 (or/and 25), 61 and 66 in moderate extent. Based on the result, the plausible secondary structure of U6 snRNA is discussed.

Small RNA molecules related to the Alu family of repetitive DNA sequences

A rodent 4.5S RNA molecule with extensive homology to the Alu family of interspersed repetitive DNA sequences has been found physically associated with polyadenylated nuclear and cytoplasmic RNAs (W. Jelinek and L. Leinwand, Cell 15:205-214, 1978; S. Haynes et al., Mol. Cell. Biol. 1:573-583, 1981). In this report, we describe a 4.5S RNA molecule in rat cells whose RNase fingerprints are identical to those of the equivalent mouse molecule. We show that the rat 4.5S RNA is part of a small family of RNA molecules, all sharing sequence homology to the Alu family of DNA sequences. These RNAs are synthesized by RNA polymerase III and are developmentally regulated and short-lived in the cytoplasm. Of this family of small RNAs, only the 4.5S RNA is found associated with polyadenylated RNA.

Chemical modification of cytosine residues of mouse 5 S ribosomal RNA with hydrogen sulfide. (Nucleosides and nucleotides 43)

Cytosine residues of nucleic acids were converted to 4-thiouracil residues with hydrogen sulfide in pyridine and water to examine the secondary and tertiary structures of mouse 5 S rRNA. The cytosine residues at positions 10, 24, 34 (or 36), 39, 44 (or 46) and 63 were converted preferentially when the treatment was carried out at 28 degrees C. This result supports the model of the secondary structure of 5 S rRNA of Nishikawa, K. and Takemura, S. ((1974) FEBS Lett. 40, 106-109) consisting of five helices and five loops. As the temperature was increased to 35 degrees C, additional cytosine residues in positions 26, 52 and 78 were modified to moderate extents.

Oligo(U) sequences present in sea urchin maternal RNA decrease following fertilization

Oligo(U) tracts were identified and measured in RNA from sea urchin eggs and embryos using a quantitative assay based on the amount of [3H]poly(A) protected from RNase T2 in duplexes with the oligo(U). The oligo(U) amounted to 0.0035% of egg RNA (0.063 X 10(-12) g/egg) and decreased to 0.0015% (0.027 X 10(-12) g/embryo) by 2 hr after fertilization. The oligo(U) tracts had a maximum size of 15-30 nucleotides and were associated with two size classes of RNA. In eggs about half were in 100 to 200 nucleotide RNA and half in mRNA-sized molecules. After fertilization, the oligo(U) in the population of large-mRNA-sized molecules was greatly reduced.

The genes coding for 4 snRNAs of Drosophila melanogaster: localization and determination of gene numbers

Four small nuclear RNAs (snRNAs) have been isolated from Drosophila melanogaster flies. They have been characterized by base analysis, fingerprinting, and injection into Axolotl oocytes. The size of the molecules and the modified base composition suggest that the following correlations can be made: snRNA1 approximately U2-snRNA; snRNA2 approximately U3-snRNA; snRNA3 approximately U4-snRNA; snRNA4 approximately U6-snRNA. The snRNAs injected into Axolotl oocytes move into the nuclei, where they are protected from degradation. The genes coding for these snRNAs have been localized by "in situ" hybridization of 125-I-snRNAs to salivary gland chromosomes. Most of the snRNAs hybridize to different regions of the genome: snRNA1 to the cytological regions 39B and 40AB; snRNA2 to 22A, 82E, and 95C; snRNA3 to 14B, 23D, 34A, 35EF, 39B, and 63A; snRNA4 to 96A. The estimated gene numbers (Southern-blot analysis) are: snRNA1:3; snRNA2:7; snRNA3:7; snRNA4:1-3. The gene numbers correspond to the number of sites labeled on the polytene salivary gland chromosomes.

Small RNA molecules related to the Alu family of repetitive DNA sequences

A rodent 4.5S RNA molecule with extensive homology to the Alu family of interspersed repetitive DNA sequences has been found physically associated with polyadenylated nuclear and cytoplasmic RNAs (W. Jelinek and L. Leinwand, Cell 15:205-214, 1978; S. Haynes et al., Mol. Cell. Biol. 1:573-583, 1981). In this report, we describe a 4.5S RNA molecule in rat cells whose RNase fingerprints are identical to those of the equivalent mouse molecule. We show that the rat 4.5S RNA is part of a small family of RNA molecules, all sharing sequence homology to the Alu family of DNA sequences. These RNAs are synthesized by RNA polymerase III and are developmentally regulated and short-lived in the cytoplasm. Of this family of small RNAs, only the 4.5S RNA is found associated with polyadenylated RNA.

Precursor molecules of both human 5S ribosomal RNA and transfer RNAs are bound by a cellular protein reactive with anti-La lupus antibodies

The small ribonucleoproteins recognized by anti-La autoantibodies contain a heterogeneous mixture of small RNAs from uninfected mammalian cells. The identity of many of these has now been established by the discovery of precursor forms of 5S rRNA and of certain tRNAs among La RNAs from HeLa cells. The small fraction of 5S rRNA molecules that exist as La ribonucleoproteins in vivo possess 1 or 2 additional U residues at their 3' ends. Such 5S molecules bound to the La protein have also been identified with in vitro nuclear transcription systems. Pulse-chase experiments performed both in vivo and in vitro support the idea that most newly synthesized 5S rRNA molecules are transiently associated with the La protein. Cell extracts contain a processing activity that converts longer in vitro-synthesized 5S RNA transcripts into molecules of mature size. The presence of in vivo tRNA precursors in the heterogeneous mixture of La RNAs is demonstrated by the identification of precursor forms of five different specific tRNAs (Meti, Asp, Gly, Glu, Asn). After in vitro transcription of a tRNA gene (tRNAiMet), only products the size of precursor molecules are precipitable by anti-La antibodies. The realization that virtually every known RNA polymerase III product associates at least initially with the La antigen suggests that this protein plays an essential role in the synthesis or maturation of all class III transcripts.

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.

Small nuclear RNAs in cellular growth and differentiation. I: metabolic alterations seen in Friend erythroleukemic cells

Electrophoretic analysis of near steady-state labeled nuclear RNA obtained from Friend virus-transformed murine erythroleukemic cells reveals the presence of at least 15 small nuclear RNAs (snRNAs) distinct from ribosomal 5.8S or 5S. Identical qualitative distributions were obtained from logarithmically growing, stationary-phase, and dimethyl sulfoxide-induced, terminally differentiated cultures, indicating the constitutive synthesis of all snRNAs regardless of the proliferative or differentiated state of the cells. However, several quantitative differences in nuclear snRNA levels were observed. Progression from rapidly growing to stationary-phase cultures was accompanied by the marked reduction in accumulation of all snRNAs except the 4.5S snRNAs. Particularly striking were the decreases in levels of U3 and the U1 group, snRNAs that are relatively abundant. Similar reductions were noted when cells were induced to differentiate, except that decreases in the levels of U2 and 4.5S were more dramatic than those seen for cells entering stationary-phase. The data thus demonstrate that snRNA levels may be regulated both in association with changes in proliferative capacity of cells and with changes in gene expression that occur during terminal differentiation.

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.

Transcriptional control regions of the adenovirus VAI RNA gene

By constructing deletion mutations in cloned adenovirus types 2 and 5 VAI genes and measuring the ability of altered templates to direct transcription of VAI RNA in HeLa cell extracts, we have located two transcriptional control regions. The first is an intragenic region located between positions +9 and +72 relative to the 5' end of the VAI(A) RNA. Those deletions examined within these sequences abolished the transcription of mutant templates in HeLa cell extracts. The second control region includes 5' flanking sequences which abut the VAI coding region. Mutations here can reduce the efficiency with which the VAI gene is transcribed. Nucleotide sequence similarities were noted on comparison of the VAI intragenic control region to tRNA sequences, which lead us to speculate that the transcriptional regulation of these two types of genes may be quite similar; the adenovirus VA genes may even have evolved from a tRNA gene(s).

Ubiquitous, interspersed repeated sequences in mammalian genomes

DNA base sequence comparisons demonstrate that the principal family of 300-nucleotide interspersed human DNA sequences, the repetitive double-strand regions of HeLa cell heterogeneous nuclear RNA, and specific RNA polymerase III in vitro transcripts of cloned human DNA sequences are all representatives of a closely related family of sequences. A segment of approximately 30 residues of these sequences is highly conserved in mammalian evolution because it is also present in the interspersed repeated DNA sequences of Chinese hamsters. Further DNA sequence comparisons demonstrate that a portion of this highly conserved segment of repetitive mamalian DNA sequence is similar to a sequence found within a low molecular weight RNA that hydrogen-bonds to poly(A)-terminated RNA molecules of Chinese hamsters and a sequence that forms half of a perfect inverted repeat near the origin of DNA replication in papovaviruses.