Processing of truncated mouse or human rRNA transcribed from ribosomal minigenes transfected into mouse cells.

The processing of pre-rRNA in eukaryotic cells involves a complex pattern of nucleolytic reactions taking place in preribosomes with the participation of several nonribosomal proteins and small nuclear RNAs. The mechanism of these reactions remains largely unknown, mainly because of the absence of faithful in vitro assays for most processing steps. We have developed a pre-rRNA processing system using the transient expression of ribosomal minigenes transfected into cultured mouse cells. Truncated mouse or human rRNA genes are faithfully transcribed under the control of mouse promoter and terminator signals. The fate of these transcripts is analyzed by the use of reporter sequences flanking the rRNA gene inserts. Both mouse and human transcripts, containing the 3' end of 18S rRNA-encoding DNA (rDNA), internal transcribed spacer (ITS) 1, 5.8S rDNA, ITS 2, and the 5' end of 28S rDNA, are processed predominantly to molecules coterminal with the natural mature rRNAs plus minor products corresponding to cleavages within ITS 1 and ITS 2. To delineate cis-acting signals in pre-rRNA processing, we studied series of more truncated human-mouse minigenes. A faithful processing at the 18S rRNA/ITS 1 junction can be observed with transcripts containing only the 60 3'-terminal nucleotides of 18S rRNA and the 533 proximal nucleotides of ITS 1. However, further truncation of 18S rRNA (to 8 nucleotides) or of ITS 1 (to 48 nucleotides) abolishes the cleavage of the transcript. Processing at the ITS 2/28S rRNA junction is observed with truncated transcripts lacking the 5.8S rRNA plus a major part of ITS 2 and containing only 502 nucleotides of 28S rRNA. However, further truncation of the 28S rRNA segment to 217 nucleotides abolishes processing. Minigene transcripts containing most internal sequences of either ITS 1 or ITS 2, but devoid of ITS/mature rRNA junctions, are not processed, suggesting that the cleavages in vivo within either ITS segment are dependent on the presence in cis of mature rRNA sequences. These results show that the major cis signals for pre-rRNA processing at the 18S rRNA/ITS 1 or the ITS2/28S rRNA junction involve solely a limited critical length of the respective mature rRNA and adjacent spacer sequences.

Mapping of the major early endonuclease cleavage site of the rat precursor to rRNA within the internal transcribed spacer sequence of rDNA.

The endonuclease cleavage of 41 S pre-rRNA to yield 32 S and 21 S pre-rRNA constitutes a major early step in the processing of pre-rRNA in rat liver. The 5'-terminus of 32 S pre-rRNA and the 3'-terminus of 21 S pre-rRNA were precisely located within the rDNA sequence by S1 nuclease protection mapping and use of appropriate rDNA restriction fragments. The 5'-terminus of 12 S pre-rRNA, an initial product of 32 S pre-rRNA processing, was also mapped within the rDNA sequence. The 5'-termini of 32 S and 12 S pre-rRNA coincide and map within a 14-residue T-tract (non-coding strand) at 161-163 bp upstream from the 5'-end of the 5.8 S rRNA gene. The 3'-terminus of 21 S pre-rRNA maps within the same T-tract. These results show that the endonuclease cleavage occurs within a U-tract in the internal transcribed spacer 1 sequence of 41 S pre-rRNA. The homogeneity of the 5'- or 3'-termini of 32 S, 12 S and 21 S pre-rRNA indicates also that the terminal processing of these molecules, if any, is markedly slower. The coincidence in the location of 32 S and 12 S pre-rRNA 5'-termini shows further that the endonuclease cleavage of 32 S pre-rRNA precedes the removal of its 5'-terminal segment to yield 5.8 S rRNA. The absence in the whole pre-rRNA internal transcribed spacer of sequences complementary to the target U-tract suggests that the endonuclease cleavage, generating 32 S and 21 S pre-rRNA, occurs in a single-stranded loop of U-residues.

Toyocamycin inhibition of ribosomal ribonucleic acid processing in an osmotic-sensitive adenosine-utilizing Saccharomyces cerevisiae mutant.

An adenosine-utilizing mutant of Saccharomyces cerevisiae (SY 15 ado) is isolated after remutagenesis of an osmotic-sensitive strain, auxotrophic for adenine, with ethyl methanesulfonate. It is shown that the SY15ado mutant can be used to achieve experimental conditions under which cell growth and RNA Synthesis are directly dependent on exogenous adenosine. After starvation for adenosine, toyocamycin is incorporated into pre-rRNA chains of SY15ado cells replacing adenosine residues. The extent of this replacement depends on the concentration of added toyocamycin. Lower doses slow down processing of pre-rRNA into mature rRNA with an accumulation of 27 S and 20 S pre-rRNA. At higher concentrations toyocamycin blocks the last steps of pre-rRNA processing i.e. the conversions 27 S pre-rRNA leads to 25 S rRNA and 20 S pre-rRNA leads to 18 S rRNA. It appears that the main site of toyocamycin action is at the last steps of ribosome formation, while transcription and the early stages of pre-RNA processing are less affected.

Effect of cycloheximide on the in vivo and in vitro synthesis of ribosomal RNA in rat liver.

The action of low (5 mg/kg body wt;) and high (20 mg/kg body wt.) doses of cycloheximide, both causing a rapid and almost complete inhibition of protein synthesis in rat liver is investigated. Short-term (15 min) [14C]orotate incorporation into nucleolar rRNA in vivo is inhibited only by the high dose acting for periods longer than 1 h. The effect may be correlated with a strongly reduced labelling of the cellular pool of free uridine nucleotides. These results indicate that in vivo transcription of rRNA genes may not be under stringent control. The activity of template-bound RNA polymerase A in nuclei isolated from animals treated with both doses of cycloheximide is reduced within 1 h to about 50% of controls reaching nearly plateau levels at longer times of action of the drug. The differential effect of cycloheximide inhibition of protein synthesis on in vivo and in vitro rRNA synthesis suggests the existence of elongation control protein(s) characterized by a rapid turnover and a loose association with the nucleus.

A 12 S precursor to 5.8 S rRNA associated with rat liver nucleolar 28 S rRNA.

The pre-rRNA and rRNA components of rat and mouse liver nucleolar RNA were analysed. It was shown that upon denaturation, part of the 32 S pre-rRNA is converted into 28 S rRNA and 12 S RNA. The 12 S RNA from mouse (Mr, 0.36 X 10(6)) is larger than the one from rat (Mr, 0.32 X 10(6). The 12 S RNA chain is intact and resists denaturation treatment. The non-covalent binding of this RNA with nucleolar 28 S rRNA is stronger than that of 5.8 S rRNA with 28 S rRNA. Hybridization with a rat internal-transcribed spacer rDNA fragment identifies 12 S RNA as corresponding to the 5'-end non-conserved segment of 32 S pre-rRNA, including 5.8 S rRNA. The significance of the formation of a 12 S precursor to 5.8 S rRNA in the biogenesis of ribosomes in mammalian cells is discussed.

Electron microscopic localization of silver staining NOR-proteins in rat liver nucleoli upon D-galactosamine block of transcription.

The method for electron microscopy of the Ag-staining of NOR-specific proteins was adapted to tissue sections from solid organs. The distribution of the Ag-staining proteins in rat liver nucleoli after complete block of transcription caused by D-galactosamine was investigated. In control animals, the Ag-staining proteins are associated with the fibrillar components of nucleoli. After block of transcription, positive Ag-staining is observed in the condensed fibrillar components of segregated nucleoli and later in the derived dense nucleolar fibrillar remnants. The granular components and the spherical bodies in segregated nucleoli are negative. It is concluded that in interphase nucleoli the Ag-staining NOR proteins are associated with the fibrillar components and with the derived nucleolar fibrillar remnants. The positive Ag-staining does not reflect the actual transcription of rRNA genes since it is present in both transcribed and non-transcribed r-chromatin.

Cloning and high level expression of a synthetic gene for human basic fibroblast growth factor.

A gene encoding human basic fibroblast growth factor has been chemically synthesized, cloned and expressed in Escherichia coli as a biologically active protein. The 465 bp gene was assembled by enzymatic ligation of 6 pairs of oligonucleotides and cloned in the expression vector pLCII downstream from the strong PL promoter. This promoter directed the synthesis of a fusion protein between a 31 amino acids fragment of the lambda phage cII protein and bFGF. A four amino acid recognition sequence for the site-specific protease fXa was introduced in the plasmid construct and this allowed cleavage of the fusion protein at the boundary between cII and bFGF. bFGF was purified close to homogeneity using a Heparin-Sepharose column and Mono S cation exchange chromatography. The use of the pLCII expression system resulted in the accumulation of 20 to 25 mg of purified bFGF per l of bacterial culture. The recombinant bFGF was mitogenic for mouse 3T3 fibroblasts and the dose-response curve was similar to the one for native bFGF.

Isolation of active transcription complexes from animal cell nuclei by nitrocellulose binding.

A method for the rapid isolation of active transcription complexes from animal cell nuclei is described. The method is based on the observation that, after lysis of nuclei with the detergents Sarkosyl and Triton X-100, transcription complexes are selectively bound to nitrocellulose. The nitrocellulose filters retain 80-90% o the RNA labelled briefly in vitro and about 10% of the nuclear DNA. The bulk of the retained DNA is in the size range of 20 kb. Transcription complexes involving both RNA polymerase I and II are retained by nitrocellulose. The nitrocellulose-bound transcription complexes preserve almost all of their RNA polymerase activity. The size distribution of the RNA product shows that bound transcription complexes retain also most of their growing RNA chains. The possibility to use selective retention by nitrocellulose in the analysis of transcriptionally active genes is discussed.

Evidence for interaction of 5.8S rRNA with the 5'- and 3'- terminal segments of Saccharomyces cerevisiae 25S rRNA.

The possible sites of 5.8S:25S rRNA interaction in Saccharomyces cerevisiae are investigated by blot-hybridization of in vivo 32P-labelled 5.8S rRNA with restriction fragments from the 25S rRNA gene. Strong hybridization signals are obtained with fragments from the 5'-end (nucleotides 1 to 494) and the 3'-end (3066 to 3391) of the gene. The fragments from the remaining part of the gene are negative. A computer analysis of the known Saccharomyces cerevisiae 5.8S (Rubin 1973) and 25S (Georgiev et al. 1981) rRNA sequences show a markedly higher complementarity between 5.8S rRNA and the 5'- and 3'-terminal segments of 25S rRNA corresponding to the hybridization positive rDNA fragments. In accordance with the experimental and sequence analysis data, two alternative end-to-end base pairing models of possible 5.8S:25S rRNA binding are proposed. Both models imply that 5.8S rRNA connects the 5'- and 3'-terminal segments of 25S rRNA, but differ in the extent of preservation of the secondary structure typical of free 5.8S rRNA. It is suggested that the requirement for 5'- and 3'-end binding of 23S rRNA in Escherichia coli is conserved in evolution and that in eukaryotes 5.8S rRNA plays the role of joining together the two ends of L-rRNA molecules.