Ribonucleoprotein particle appearing during sporulation in yeast.

During sporulation of Saccharomyces cerevisiae, most strains accumulate an unmethylated 20S RNA. Contrary to previous reports, this sporulation 20S RNA is distinct from the short-lived methylated 20S RNA precursor of 18S rRNA. This RNA species was found in a cytoplasmic 32S ribonucleoprotein particle consisting of one single-stranded 20S RNA molecule and 18 to 20 identical protein subunits of molecular weight 23,000. The ribonucleoprotein particle was resistant to ribonuclease digestion, although purified 20S RNA was ribonuclease sensitive. Both the RNA and the protein of the 32S ribonucleoprotein particle were only synthesized under conditions that induce sporulation. The accumulation of 20S RNA depended on continued protein synthesis but was actinomycin D insensitive, despite a high guanine-plus-cytosine content. Synthesis of 20S RNA stopped when cells were removed from sporulation conditions and placed in growth medium.     

Characterization of ribonuclease P isolated from rat liver cytosol.

Rat liver ribonuclease P was isolated from a cytosolic fraction and shown to have optimal activity in the presence of 1 mM MgCl2 and 150-200 mM KCl using Escherchia coli pre-tRNA(Tyr) as substrate. In cesium sulfate isopycnic density gradients, the enzyme had a buoyant density of 1.36 g/ml, indicating that it is a ribonucleoprotein complex. Analysis of the RNAs in the enzyme sample purified through two successive Cs2SO4 density gradient steps revealed the copurification of two major species of RNA (RRP1 and RRP2) along with several less abundant RNAs. Rat liver ribonuclease P activity was insensitive to micrococcal nuclease pretreatment. However, the nuclease-treated preparations contained several incompletely degraded RNA species that may have been sufficient to support the ribonuclease P activity. When RNase A was substituted for micrococcal nuclease, the ribonuclease P activity was diminished by greater than 90%, suggesting the requirement for an RNA subunit for activity.     

Analysis of High-Molecular-Weight Ribonucleic Acid Associated with Intracisternal A Particles

Intracisternal A particles, known primarily for their association with various tumors, have been shown to contain high-molecular-weight (HMW) ribonucleic acid (RNA) by velocity centrifugation, using linear glycerol gradients. This HMW RNA is sensitive to ribonuclease digestion and alkali treatment but is resistant to Pronase treatment. By a double-labeling experiment, HMW RNA was shown to be intrinsic to intracisternal A particles and not to have resulted from cytoplasmic polysomal RNA aggregation. By a reconstitution experiment, it was determined that the results were not due to C-type virus contamination. The synthesis of HMW RNA in intracisternal A particles is inhibited by actinomycin D and ethidium bromide. These observations emphasize that there are probably some taxonomic relationships between intracisternal A particles and oncogenic RNA viruses.     

Ribonucleic acid synthesis by spermatozoa from the rat and hamster

Spermatozoa from the cauda of the epididymis of the hamster and rat were incubated with [5-(3)H]uridine and glucose. By using a procedure avoiding bacterial and other cellular contamination, sonic extracts were prepared and digested with deoxyribonuclease and Pronase. Radioactive RNA of high molecular weight was isolated by two methods: (a) gel filtration on Sephadex G-75 columns and (b) polyacrylamide-gel electrophoresis in which it migrated in the region of 28S and 23S RNA markers. The macromolecules were alkali-labile and hydrolysed by ribonuclease. From (3)H radioactivity and E(260) of the isolated RNA the rate of incorporation of uridine into RNA of spermatozoa was calculated to be 0.1-0.5nmol/h per mg of RNA.     

Polyadenylate-protein complexes in resting and growing 3T3 cells.

The properties of the ribonuclease resistant cytoplasmic ribonucleoprotein particles were studied in contact-inhibited and serum induced proliferating 3T3 cells. The RNP particles were fractionated by oligo (dT)-cellulose chromatography and banded in CsSO4 gradients. The main RNP fraction, eluted with 25% formamide, contained the major ribonuclease resistant RNA sequences in both resting and growing cells. The protein component of this fraction had a molecular weight of about 72,000 in contact-inhibited cells and 81,000 in serum induced cells.     

HnRNP from HeLa cells contain a ribonuclease active on double-stranded RNA.

A ribonuclease D, i-e acting against double-stranded RNA structures like poly r(AU), was identified in ribonucleoprotein structures containing the heterogenous nuclear RNA (hnRNP) from HeLa cells. This activity could not however be detected in intact hnRNP but only after passage through a DEAE-cellulose column or digestion by a combination of ribonucleases A+T₁. This enzyme does not degrade poly r(A)-poly d(T) nor poly r(A), nor does it yield mononucleotides, excluding the possibility of a non-specific exonuclease type of activity like phosphodiesterase. It is inhibited by ethidium bromide and double-stranded RNA and resembles in all respects so far investigated the ribonuclease D previously isolated from Krebs cells by Rech et al (Nucl. Acids Res. 1976, 3, 2055–2065).     

Two specific ribonucleoprotein fragments from rat liver 60S ribosomal subunits

K+-depleted 60S ribosomal subunits from rat liver were submitted to a mild treatment with ribonuclease T1. Ribonucleoprotein fragments could be separated on sucrose gradients only when the digested subunits were partially deproteinized with a high KCl concentration (0.6 M) which removed seven proteins more or less completely and 5S RNA. The RNA and protein content of each fragment has been characterized. The largest ribonucleoprotein enclosed two RNA fragments of about 950,000 and 750,000 daltons and all the salt-resistant proteins except L5. The smallest one enclosed protein L5 (with L11, L17 and L26 in small amounts) and a 67,000 RNA piece. The subsequent hydrolysis of the large ribonucleoprotein produced several other ribonucleoproteins. One of them has been fully characterized: it enclosed a 250,000 RNA fragment and protein L12 (with L11, L25 and L30 in smaller amounts).     

The Ribonuclease P Database.

Ribonuclease P is the endoribonuclease responsible for the removal of leader sequences from tRNA precursors. Ribonuclease P is a ribonucleoprotein, and in bacteria the RNA alone is capable of pre-tRNA processing in vitro, i.e. it is a catalytic RNA. The Ribonuclease P Database is a compilation of ribonuclease P sequences, sequence alignments, secondary structures, three-dimensional models and accessory information, in the form of a hypertext document available via the Worldwide Web.     

A Mycoplasma protein homologous to mammalian SRP54 recognizes a highly conserved domain of SRP RNA.

A protein homologous to SRP54, a subunit of the mammalian signal recognition particle (SRP), was identified in Mycoplasma mycoides. The mycoplasma protein was expressed in E.coli and purified to near homogeneity. It was shown to bind specifically in vitro to a small mycoplasma RNA with structural features related to the RNA component of SRP. These findings provide evidence of a ribonucleoprotein complex in mycoplasma reminiscent of SRP. A part of the RNA was protected from ribonuclease digestion in the presence of the SRP54 homologue. The protected region contains structural elements that have been highly conserved in SRP RNAs during evolution.     

Secondary structure of pre-mRNA in nuclear ribonucleoprotein particles

The secondary structure of pre-mRNA in the specific nuclear ribonucleoprotein particles was investigated. After ribonuclease treatment of nuclear particles the majority of double-stranded RNA sequences was conserved. The in vivo existence of hairpin-like RNA structures is discussed.     

The structure of the RNA binding site of ribosomal proteins S8 and S15.

Proteins S8 and S15 from the 30 S ribosomal subunit of Escherichia coli were bound to 16 S RNA and digested with ribonuclease A. A ribonucleoprotein complex was isolated which contained the two proteins and three noncontiguous RNA subfragments totaling 93 nucleotides, that could be unambiguously located in the 16 S RNA sequence. We present a secondary structural model for the RNA moiety of the binding site complex, in which the two smaller fragments are extensively base-paired, respectively, to the two halves of the large fragment, to form two disconnected duplexes. Each of the two duplexes is interrupted by a small internal loop. This model is supported by (i) minimum energy considerations, (ii) sites of cleavage by ribonuclease A, and (iii) modification by the single strand-specific reagent kethoxal. The effect of protein binding on the topography of the complex is reflected in the kethoxal reactivity of the RNA moiety. In the absence of the proteins, 5 guanines are modified; 4 of these, at positions 663, 732, 733, and 741, are strongly protected from kethoxal when protein S15 is bound.     

Identification of a nuclear ribonucleoprotein particle which contains incompletely spliced HIV-1 RNAs

Unspliced and partially spliced HIV RNAs are transported to the cytoplasm by the HIV encoded Rev protein. In the present study, a ribonucleoprotein complex which contains such incompletely spliced HIV RNA is identified. Soluble nuclear extracts were prepared from the lymphocyte cell line H9/IIIB that constitutively produces HIV-1 from a stably integrated provirus. Sucrose gradient centrifugation of the extracts and subsequent analysis of the gradient fractions by a ribonuclease protection assay revealed a population of incompletely spliced HIV-1 RNAs which accumulates in the 100S region of the gradient. Similar analysis of cellular mRNAs including beta-actin and glyceraldehyde 3-phosphate dehydrogenase (GAPDH) revealed that these RNA molecules also exhibit characteristic sedimentation profiles in sucrose gradients. This study suggests that nuclear ribonucleoprotein particles containing incompletely spliced HIV-1 RNAs are amenable for biochemical characterisation.     

The ribonuclease P database.

Ribonuclease P is responsible for the removal of leader sequences from tRNA precursors. Ribonuclease P is a ribonucleoprotein, and in bacteria the RNA subunit alone is catalytically active in vitro, i.e. it is a ribozyme.The Ribonuclease P Database is a compilation of ribonuclease P sequences, sequence alignments, secondary structures, three-dimensional models, and accessory information, available via the World Wide Web.     

Recent insights into the structure and function of the ribonucleoprotein enzyme ribonuclease P

In bacteria, the tRNA-processing endonuclease ribonuclease P is composed of a large ( approximately 400 nucleotide) catalytic RNA and a smaller ( approximately 100 amino acid) protein subunit that is essential for substrate recognition. Current biochemical and biophysical investigations are providing fresh insights into the modular architecture of the ribozyme, the mechanisms of substrate specificity and the role of essential metal ions in catalysis. Together with recent high-resolution structures of portions of the ribozyme, these findings are beginning to reveal how the functions of RNA and protein are coordinated in this ribonucleoprotein enzyme.     

The road to RNase P

In 1989, Sidney Altman and Thomas R. Cech shared the Nobel Prize in Chemistry for their discovery of catalytic properties of RNA. Cech was studying the splicing of RNA in a unicellular organism called Tetrahymena thermophila. He found that the precursor RNA could splice in vitro in the absence of proteins. Altman studied ribonuclease P (RNase P), a ribonucleoprotein that is a key enzyme in the biosynthesis of tRNA. RNase P is an RNA processing endonuclease that specifically cleaves precursors of tRNA, releasing 5' precursor sequences and mature tRNAs. RNase P is involved in processing all species of tRNA and is present in all cells and organelles that carry out tRNA synthesis. What follows is a personal recollection by Altman of how he came to study this remarkable enzyme.     

Electron Microscopy of the Nucleic Acid of Mouse Mammary Tumor Virus

Mouse mammary tumor virus (MTV) was isolated from the milk of RIII mice by density-gradient centrifugation in Ficoll. The homogeneity of the preparation was demonstrated in electron micrographs. The nucleic acid was extracted with phenol in the presence of Pronase. Its viral origin was attested by failure of ribo-nuclease and deoxyribonuclease treatment of the virus preparation to destroy the filamentous molecules; after phenol extraction, the molecules were destroyed by ribonuclease but not by deoxyribonuclease. Rotary shadowed preparations were examined in the electron microscope. The length distribution of the RNA filaments showed peaks at 1.2, 2.4, and 3.6 mum. The molecular weight of the longest molecule of MTV-RNA was estimated as 3.6 x 10(6) daltons.     

Regulation of polyribosome formation and protein synthesis in the uterus. Isolation of cytoplasmic ribonucleoprotein particles and the principal properties of the cell-free protein-synthesizing system

1. Three procedures for isolating ribonucleoprotein particles from the cytoplasmic fraction of rat-uterus homogenates are described. By procedure 1, ribonucleoprotein particles were isolated in the presence of 5mm-Mg(2+) and 25mm-K(+), and the postmitochondrial supernatant fraction was made to 1.3% (w/v) in potassium deoxycholate. About 50% of the RNA and protein of the microsomal fraction was recovered in the monomeric ribosomes isolated. By procedure 2, ribonucleoprotein particles were isolated in the presence of 10mm-Mg(2+) and 0.1m-K(+), and in the absence of detergent. The ribosomes obtained were primarily polymeric, but recovery of microsomal RNA and protein was only 32%. By procedure 3, ribonucleoprotein particles were isolated according to procedure 1 but without the use of detergent. A mixture of polymeric and monomeric ribosomes was obtained, and the recovery of microsomal RNA and protein was about 60%. 2. Uterine polymeric and monomeric ribosomes, isolated by procedure 3 and designated ;polyribosomal preparation', were examined for protein-synthesizing capabilities. The principal properties of the cell-free protein-synthesizing system containing the polyribosomal preparation are described. The efficiency of amino acid incorporation in the complete system incubated for 30min. and containing the polyribosomal preparation was found to be either 2.5 molecules of [(14)C]leucine or 2.2 molecules of [(14)C]-valine incorporated/ribosome. Assay of the preparation in the complete cell-free system containing 10mm-sodium fluoride indicated that 40% of the incorporation activity is a result of initiation of new polypeptide chains and 60% is due to completion of previously existing chains. Monomeric ribosomes obtained by various treatments of the polyribosomal preparation with sodium fluoride, ribonuclease and potassium deoxycholate had decreased incorporation activity in the cell-free system. However, monomeric ribosomes obtained by treatment with sodium fluoride only had an incorporation activity 50% greater than that of monomers obtained by treatment with ribonuclease only. 3. The results indicate that uterine polymeric and monomeric ribosomes are sites of amino acid incorporation in vivo and in vitro. It is concluded that most polymeric and monomeric ribosomes occurring in the cytoplasmic fraction of the uterus are free and unattached to membranes, and that the polyribosomes are relatively unstable.     

Mutual interactions between subunits of the human RNase MRP ribonucleoprotein complex

The eukaryotic ribonuclease for mitochondrial RNA processing (RNase MRP) is mainly located in the nucleoli and belongs to the small nucleolar ribonucleoprotein (snoRNP) particles. RNase MRP is involved in the processing of pre-rRNA and the generation of RNA primers for mitochondrial DNA replication. A closely related snoRNP, which shares protein subunits with RNase MRP and contains a structurally related RNA subunit, is the pre-tRNA processing factor RNase P. Up to now, 10 protein subunits of these complexes have been described, designated hPop1, hPop4, hPop5, Rpp14, Rpp20, Rpp21, Rpp25, Rpp30, Rpp38 and Rpp40. To get more insight into the assembly of the human RNase MRP complex we studied protein–protein and protein–RNA interactions by means of GST pull-down experiments. A total of 19 direct protein–protein and six direct protein–RNA interactions were observed. The analysis of mutant RNase MRP RNAs showed that distinct regions are involved in the direct interaction with protein subunits. The results provide insight into the way the protein and RNA subunits assemble into a ribonucleoprotein particle. Based upon these data a new model for the architecture of the human RNase MRP complex was generated.