THE SELECTIVE INTERRUPTION OF NUCLEOLAR RNA SYNTHESIS IN HELA CELLS BY CORDYCEPIN

Cordycepin is an analogue of adenosine lacking the 3'-OH. When incorporated into a growing RNA molecule, cordycepin prevents further elongation, thus producing a prematurely terminated RNA molecule. When HeLa cells are exposed to low concentrations of cordycepin, DNA and protein synthesis are unaffected during short exposure periods. The synthesis of completed ribosomal and ribosomal-precursor (45S) RNA is significantly depressed. Partially completed 45S ribosomal precursor molecules accumulate in the nucleolus. 18S ribosomal RNA can be cleaved from these incomplete precursors, while 32S ribosomal precursor cannot be produced from partially snythesized 45S molecules. The synthesis of transfer RNA is also reduced in the presence of cordycepin. The synthesis of the nuclear heterogeneous RNA species is unaffected by the drug while the cytoplasmic heterogeneous RNA is slightly reduced.     

Nucleotide sequence study of mouse 5.8S ribosomal RNA.

The primary structure of 5.8S mouse ribosomal RNA has been studied and compared to the structures previously established for other animal species. The results obtained show that mouse 5.8S ribosomal RNA yields pancreatic oligonucleotides with the same nucleotide sequence as the homologous oligonucleotides from rat cells. Furthermore T1 oligonucleotides of 5.8S ribosomal RNA from rat, mouse and human cells behave identically on fingerprinting fractionation and have the same composition as judged by pancreatic digestion. These results strongly suggest that the primary structures of 5.8S ribosomal RNA from rat, mouse and human cells are identical. This identity of structure is also found when the presence of several modified bases (psi and methylated bases) is considered. The findings emphasize the remarkable evolutionary stability of ribosomal gene structure. Comparison of the terminal regional of 5.8S RNA with those of 18S RNA reveals differences which imply a more complex mechanism underlying the maturation of 45S precursor RNA than the finding of identical structure would have suggested.     

ULTRASTRUCTURAL AND BIOCHEMICAL STUDIES ON THE PRECURSOR RIBOSOMAL PARTICLES ISOLATED FROM RAT LIVER NUCLEOLI

Sucrose density gradient analyses of pH 5.5 and pH 7.4 extracts from rat liver nucleoli revealed the presence of two broad peaks of approximately 60S and 80S, and 60S and 80–100S, respectively. Ribonucleoprotein (RNP) particles containing precursor ribosomal RNA in these peaks have been characterized by electron microscopy and RNA analyses. Spherical particles only were found in the 60S peak of the pH 5.5 extract, from which 28S RNA and smaller RNA (23S and 18S RNA) exclusively were extracted. In the broad 80S peak of the pH 5.5 extract, about 60% of the particles were spherical while 30% were rodlike. In the RNA species present there were 28S plus smaller RNA (80%) and 35S RNA (20%). The 60Speak of the pH 7.4 extract contained mainly spherical particles (84%), and the RNA species present was mostly 28S plus smaller RNA (89%). In addition to spherical particles (43%), a number of rodlike (31%) and filamentous molecules (26%) were observed in the heavier side of the 80–100S peak of the pH 7.4 extract, from which 45S (14%), 35S (26%), and 28S and smaller RNA (60%) were extracted. Thus the precursor ribosomal particles containing 45S RNA and 35S RNA appear to be filamentous and rodlike molecules, respectively. Folding of loose ribonucleoprotein filaments into compact, spherical, large subparticles may be part of the maturation process of ribosomal large subparticles, in addition to the so-called sequential cleavage of RNA.     

METABOLISM OF RIBOSOMAL PRECURSOR RIBONUCLEIC ACID IN KIDNEY

The labile precursors of ribosomal RNA in mouse kidney are preserved when nuclei rapidly isolated after sieving through multiple screens are swollen and cleansed in the presence of an RNase inhibitor before digestion with DNase and phenol extraction. The kinetics of nucleolar labeling analyzed on polyacrylamide gels show that 36S RNA is the major intermediate product in the catabolism of the original 45S RNA precursor to 32S RNA, from which 28S RNA is derived. Each kidney nucleus contains about 200–600 molecules of 45S RNA; the turnover time of the 45S pool is about 3 ± 2 min. Compared with HeLa cells, kidney nuclei have a different major intermediate product and a much smaller and more rapidly turning-over pool of ribosomal precursor RNA.     

RIBOSOME SYNTHESIS IN TETRAHYMENA PYRIFORMIS

The cellular site of synthesis of ribosomal RNA in Tetrahymena pyriformis was studied by analyzing the purified nuclear and cytoplasmic RNA from cells pulse labeled with uridine-³H. The results of studies using zonal centrifugation in sucrose density gradients show that the ribosomal RNA is synthesized in the nucleus as a large precursor molecule sedimenting at 35S. The 35S molecule undergoes rapid transformation through two main nuclear intermediates, sedimenting at about 30S and 26S. The smaller ribosomal RNA (17S) appears first in the cytoplasm and it seems to be absent from the nucleus. The apparent delay in the appearance of the larger ribosomal RNA (26S) in the cytoplasm is due to the presence of a larger pool of its precursors in the nucleus as indicated by pulse-chase experiments. The newly synthesized ribosomal RNA's appear in the cytoplasm as discrete 60S and 45S ribonucleoprotein particles, before their incorporation into the polysomes.     

Alterations in the maturation and structure of ribosomal precursor RNA in Novikoff hepatoma cells induced by 5-fluorocytidine

The effects of 5-fluorocytidine on ribosomal RNA maturation and structure in Novikoff hepatoma cells were investigated. Like other nucleic acid base analogues that are incorporated into RNA, this compound inhibits maturation of the 45S ribosomal RNA precursor. The 45S RNA precursor produced in the presence of 5-fluorocytidine has an abnormal electrophoretic mobility compared with that of the control precursor under nondenaturing conditions, but the two have identical mobilities under denaturing conditions. Under the conditions of these experiments, 5-fluorocytidine inhibited cellular protein synthesis only slightly, whereas equimolar concentrations of 5-azacytidine resulted in nearly 75% inhibition of this process. Despite this difference in the effects of the two analogues as well as the greater chemical lability of the 5-azacytidine, their effects on ribosomal RNA maturation are identical.