Methylation status of 13S ribosomal RNA from hamster mitochondria: the presence of a novel riboside, N4-methylcytidine.

The ribosomal RNA ("13S" RNA) of the small ribosomal subunit of hamster cell mitochondria has been found to have a distinctive pattern of methylated residues. Each molecule contained, on the average, approximately one residue of m4Cp, m5Cp and m5Up, and two residues of m62Ap. The natural occurrence of m4Cp has not previously been reported; we propose that this nucleotide is homologous to its ribose-methylated congener, m4Cmp, which is characteristic of bacterial 16S ribosomal RNA. We detected neither m4Cp nor m4Cmp in the hamster cell cytoplasmic ribosomal RNA. This is the first documentation of a modified residue present in mitochondrial RNA but absent from the cytoplasmic RNA of the same cells.     

Transport of different RNA species from the nucleus to the cytoplasm in Xenopus laevis neurula cells

Isolated cells from Xenopus laevis neurulae were labeled, and the RNAs extracted from their nuclear and soluble cytoplasmic fractions were analyzed on polyacrylamide gels. In the soluble cytoplasm, 4S RNA emerged very rapidly, and this was immediately followed by the emergence of poly(A)-containing RNA and 18S ribosomal RNA. In contrast, the emergence of 28S ribosomal RNA was delayed by about 2 hr. The size distribution of cytoplasmic poly(A)-containing RNA was much smaller as compared to that of nuclear poly(A)-containing RNA. These results indicate that the newly synthesized RNAs in Xenopus neurula cells are transported from the nucleus to the cytoplasm in a characteristic sequence.     

Modification of mitochondrial ribosomal RNA from hamster cells: the presence of GmG and late-methylated UmGmU in the large subunit (17S) RNA

The methylated residues of the large subunit RNA (17 S) of hamster cell mitochondrial ribosomes have been characterized and quantitated. Digestion of 17 S RNA with alkali or ribonuclease T₂ yielded approximately one equivalent of GmpGp, a fractional equivalent of GmpUp and slightly less than an equivalent of UmpGmpUp. Pulse-labeling experiments indicated that the Um residue of UmpGmpUp was methylated relatively late, and that the GmpUp was derived from a partially methylated precursor to UmpGmpUp. No ψp was detected in 17 S RNA or in the small subunit (13 S) ribosomal RNA. We propose that the UmpGmpUp of 17 S RNA is homologous to a “universal” UmpGmp ψp sequence found in eukaryotic 28 S rRNA and possibly to similar, but incompletely methylated, sequences in fungal mitochondrial ribosomal RNA and in bacterial ribosomal RNA.     

Intracellular transport of nuclear ribosomal RNA in Acetabularia mediterranea]

The ribosomal RNA transport from a nucleus to a perinuclear cytoplasm and its following distribution in the cytoplasm of Acetabularia mediterranea cells were studied using transplantation of RNA-labeled rhizoid into unlabeled stalk. In addition rifamycin treatment was used for inhibition of cytoplasmic RNA synthesis. Acetabularia nuclei contain the stable RNA fractions similar to those present in some other eukaryotes. Nuclear 25S and 17S ribosomal RNA rapidly enter the rhizoid cytoplasm whereas the following trasfer of them to other regions of the cell is a very slow process. Within two days only an insignificant part of 25S and 17S ribosomal RNA is transferred from the rhizoid to the stalk and is distributed there over the base-apical gradient. No preferential transfer of the nuclear ribosomal RNA to the apical region was observed.     

Intracellular compartmentation of diadenosine tetraphosphate (Ap4A) and dTTP in rat liver

1. The intracellular compartmentation of diadenosine tetraphosphate (Ap4A) and of dTTP was studied in rat liver cells using non-aqueous glycerol for the isolation of cell nuclei. 2. This method allows a stepwise removal of cytoplasm from the nuclei. 3. The decrease in Ap4A or dTTP during the process was compared to the simultaneous decrease in RNA, which was taken to represent the cytoplasm. 4. In regenerating liver excised 24 hr after partial hepatectomy, Ap4A was almost equally distributed between the nucleus and cytoplasm. 5. In livers from unoperated control rats, the nuclear concentration of Ap4A was slightly elevated compared to that of whole cells. dTTP was only investigated in regenerating liver. 6. Significantly higher concentrations were found in the nuclear fractions. 7. The purest nuclei contained about 26% of whole cell levels of dTTP, while their RNA values had decreased to 7% of the whole cell RNA. 8. Considering that the liver cell nucleus comprises about 7% of the entire cell mass, a nuclear dTTP concentration of 26% indicates significantly higher dTTP levels in the nuclear compartment than in the cytoplasm of regenerating rat liver cells.     

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.     

STUDY OF RNA IN SUBCELLULAR FRACTIONS FROM RAT BRAIN: SIMULTANEOUS INCORPORATION OF [14C]URIDINE AND [3H]METHYL-l-METHIONINE

Abstract— By using a combination of subcutaneous and intraventricular injections of [¹⁴C]uridine and [³H]methyl- l -methionine we have obtained maximum incorporation in about 40 min of both radioactive precursors into nuclear RNA from rat brain. In this nuclear fraction we found at least two different types of RNA that were rapidly labelled. One of them incorporated both [¹⁴C]uridine and [³H]methyl groups and seemed to correspond to species of rRNA and their precursors. The other RNA fraction was less methylated or non-methylated and exhibited sedimentation coefficients distributed along a continuous 8–30 % sucrose density gradient. At least part of the latter type of RNA very probably was mRNA, but much of it must conespond to a different RNA similar to that recently described in HeLa cells by P enman , V esco and P enman (1968).
We also found that labelled 185 and 285 rRNA components began leaving the nucleus for the cytoplasm within 24 to 33 min after the radioactive precursors had been injected, and, in the cytoplasmic fraction, the patterns of incorporation for [¹⁴C]uridine and [³H]-methyl groups were similar for the 18S and 28S rRNA components. We estimate that in this fraction of rat brain the 18S rRNA component was 1·4 times more methylated than the 28S component. We also detected a lower sedimentation coefficient for the non- or slightly methylated, species of soluble RNA found in the cytoplasmic fraction.     

Low-molecular RNA subcellular localization and its binding strength with cellular structures

Some fractions of low molecular weight (LMW) nuclear RNAs were shown to be present in the cytoplasm of rat liver cells. In addition to known 4S tRNA, 5S and 5,8S rRNAs U3 and 8S1 LMW nuclear RNAs, 8SII and 8SIII LMW RNAs have been detected in RNA preparations of free total and membrane-bound polysomes. The U3 and 8SI polysoma I RNAs seem to be associated with high molecular weight polysomal RNA. Using thermal phenol fractionation, that some LMW RNAs were shown to be slightly bound to the cellular structures whereas some others are bound more tightly. Considerable amounts of LMW RNAs are tightly bound to the chromosome-nucleolar apparatus. They can be extracted only at 85 degrees C. The data presented are discussed with regard to LMW nuclear and polysomal RNAs functions.     

CHARACTERIZATION OF RAT BRAIN RIBONUCLEIC ACIDS BY AGAR GEL ELECTROPHORESIS

Abstract— —The characteristics of total and rapidly-labelled RNAs of rat brain were studied by agar gel electrophoresis. The bulk (more than 90 per cent) of total, nuclear and cytoplasmic brain RNA was represented by the 28 S, 18 S and 4 S RNA components. The 28 S/18 S RNA mass ratio in cytoplasmic RNA was 2·55. Lower values for this ratio were obtained with total and nuclear RNAs. Five minor RNA components were detected in total brain RNA with mobilities in agar gel corresponding to 24 S, 22 S, 14 S, 9 S and 6 S. Two broad rapidly labelled RNA components were detected in total and nuclear (but not in cytoplasmic) brain RNA with mobilities corresponding to about 45 S and 31 S. These fractions were of nuclear origin and resembled ribosomal precursor RNAs of other animal tissues. In cytoplasmic RNA the radioactivity and ultraviolet profiles coincided at all labelling times down to 1 hr. The G + C/A + U ratio of brain RNA was 1·50 for total RNA, 1·39 for nuclear RNA and 1·59 for cytoplasmic RNA. The G + C/A + U ratio of 1 hr-labelled total brain RNA (determined by ³²P-distribution) was 0·94. This ratio rose to 1·31 at 24 hr labelling. The possible significance of these results for the elucidation of ribosomal and messenger RNA metabolism in brain is discussed.     

NUCLEOLAR-DERIVED RIBONUCLEIC ACID IN CHROMOSOMES, NUCLEAR SAP, AND CYTOPLASM OF CHIRONOMUS TENTANS SALIVARY GLAND CELLS

The distribution of monodisperse high molecular weight RNA (38, 30, 28, 23, and 18S RNA) was studied in the salivary gland cells of Chironomus tentans. RNA labeled in vitro and in vivo with tritiated cytidine and uridine was isolated from microdissected nucleoli, chromosomes, nuclear sap, and cytoplasm and analyzed by electrophoresis on agarose-acrylamide composite gels. As shown earlier, the nucleoli contain labeled 38, 30, and 23S RNA. In the chromosomes, labeled 18S RNA was found in addition to the 30 and 23S RNA previously reported. The nuclear sap contains labeled 30 and 18S RNA, and the cytoplasm labeled 28 and 18S RNA. On the basis of the present and earlier analyses, it was concluded that the chromosomal monodisperse high molecular weight RNA fractions (a) show a genuine chromosomal localization and are not due to unspecific contamination, (b) are not artefacts caused by in vitro conditions, but are present also in vivo, and (c) are very likely related to nucleolar and cytoplasmic (pre)ribosomal RNA. The 30 and 23S RNA components are likely to be precursors to 28 and 18S ribosomal RNA. The order of appearance of the monodisperse high molecular weight RNA fractions in the nucleus is in turn and order: (a) nucleolus, (b) chromosomes, and (c) nuclear sap. Since both 23 and 18S RNA are present in the chromosomes, the conversion to 18S RNA may take place there. On the other hand, 30S RNA is only found in the nucleus while 28S RNA can only be detected in the cytoplasm, suggesting that this conversion takes place in connection with the exit of the molecule from the nucleus.     

Methylated nucleotide content of mitochondrial ribosomal RNA from hamster cells

We have examined the state of methylation of mitochondrial ribosomal RNA from cultured hamster (BHK-21) cells. Ethidium-sensitive, and hence mitochondrion-specific, methylation levels were determined using multiple isotope techniques and improved purification procedures. The larger mitochondrial rRNA species, 17 S RNA, was found to contain 0.13 methyl group per 100 nucleotides and the smaller, 13 S RNA, 0.37. Methylated nucleotide and base analysis indicated that 17 S RNA contained one ribose-methylated residue (UmUp) per molecule and one unidentified residue; and 13 S RNA contained one methylated cytosine residue, one N⁶-dimethyladenine residue and one thymine residue per molecule. Possible evolutionary implications of these findings have been discussed.     

Fractionation of nuclear and cytoplasmic ribonucleic acids from rat tissues on the methylated albumin–kieselguhr column

1. The conformation of RNA was found to affect its behaviour on methylated albumin-kieselguhr chromatography. The less regular the secondary structure of RNA, the more tightly it binds to the methylated albumin-kieselguhr column. 2. The presence of various denaturing agents (such as urea or perchlorate) in the medium while RNA was adsorbed on the column increased the resolving power of the technique as exemplified by the separation of rat liver rRNA into two distinct peaks. A special procedure for selective adsorption of the cytoplasmic DNA-like RNA on the preparative scale has been developed. Polyribosomal mRNA (rapidly labelled RNA formed in the presence of small doses of actinomycin D) can also be adsorbed selectively by the column. 3. A type of tissue specificity was detected in nuclear RNA from rat liver, kidney, thymus and spleen by using a modified salt and temperature gradient for the chromatographic fractionation (Lichtenstein, Piker & Shapot, 1967; Shapot, Lichtenstein & Piker, 1967). It was also found that cytoplasmic RNA from the different rat tissues contained no tenaciously bound fraction at all, whereas it constituted about 50% of the nuclear RNA. The problem of the possible biological function of the tenaciously bound fraction is discussed.     

RNA metabolsim during vegetative growth and morphogenesis of the cellular slime mold Dictyostelium discoideum

During vegetative growth of the cellular slime mold Dictyostelium discoideum, RNA is rapidly labeled by radioactive precursor and both the 25 S and the 17 S ribosomal RNA species appear in the cytoplasm 6–7 min after the onset of labeling. Thirty minutes after further incorporation of radioactive RNA precursors has been blocked, less than 10% of the label in RNA is associated with the nuclear fraction. After aggregation of the slime mold amoebae, RNA appears in the cytoplasm at a reduced rate, the small ribosomal subunit appearing in the cytoplasmic fraction more slowly than the larger ribosomal subunit. Some labeled RNA remains in the nuclei of developing cells long after the incorporation of ³H-uridine is blocked.     

Small RNAs of Tetrahymena thermophila

Highly purified nuclear and cytoplasmic RNAs were obtained from Tetrahymena thermophila BVII containing only a minimal amount of cross-contamination. In the nuclear RNA fraction we have detected at least 6 distinct snRNAs. Some of the RNA species showed microheterogeneity. SnRNAs of Tetrahymena thermophila are very similar to rat snRNAs, as far as length is concerned. Our cytoplasmic small RNA fraction contained two RNAs, 7S and T7, reported recently (18) as nuclear, particularly nucleolar RNAs. Moreover, we could detect only one cytoplasmic small RNA species Tc1, Tc2 was not observed.Neither the nuclear nor the cytoplasmic small RNA species are degradation products of ribosomal RNA as was shown by Northern blotting and following hybridization with pGY17 containing the entire transcribed region of the ribosomal DNA of Tetrahymena thermophila.     

Balbiani ring nucleotide sequences in cytoplasmic 75 S RNA of Chironomus tentans salivary gland cells

The giant puffs, the Balbiani rings (BR) 1 and 2 of Chironomus tentans polytene chromosomes synthesize large RNA molecules sedimenting at about 75S. An RNA fraction of approximately the same size is present in nuclear sap and cytoplasm. In situ hybridization of cytoplasmic 75S RNA and other electrophoretically defined cytoplasmic RNA fractions showed BR RNA to be confined to the 75S RNA, and absent in other high molecular-weight cytoplasmic RNA fractions, which indiates that BR RNA is transferred from the nucleus into the cytoplasm without an appreciable size reduction.     

STUDIES ON RAPIDLY LABELLED NUCLEAR RNA OF RAT BRAIN

—Methyl albumin kieselguhr chromatography (MAK) has been employed to separate rat brain nuclear RNA, labelled in vivo with [³H]uridine, into three major fractions. The first fraction (QI RNA) is ribosomal in nature for it has a high G + C/U ratio and is methylated by [methyl-³H] methionine. The other two fractions (Q2 RNA and TD RNA) are DNA-like for they exhibit a low G + C/U ratio and are labelled minimally by methionine. Pure ribosomal RNA chromatographs almost entirely in the Q1 RNA fraction. Labelling studies indicate that ribosomal RNA and DNA-like RNA behave differently. Initially, the label in the DNA-like RNA fractions increases rapidly and in a linear fashion for the first 30 min, but thereafter decreases rapidly and reaches a steady state level by 1 h and remains so up to at least the 2 h period. In contrast, the labelling of ribosomal RNA is much slower than that of DNA-like RNA during the first 30 min; however, unlike DNA-RNA, the labelling of ribosomal RNA still continues to increase linearly thereafter. Thus, during longer labelling periods, ribosomal RNA is labelled more rapidly than DNA-like RNA. It appears that the labelling of ribosomal RNA relative to DNA-like RNA is more rapid in liver than in brain.     

Subcellular localization of low-molecular-weight RNA components in rat liver.

The subcellular localization of the four major low-molecular-weight RNA components, D, C, A and L, was studied in rat liver cells. The cells were fractionated by a non-aqueous technique into a nuclear and a cytoplasmic fraction. The cytoplasm contained 43% of component D, 57% of component C and more than 80% of component L.     

Small RNA species in maize tissue

The low molecular weight RNA components of maize have been analyzed after labeling callus and leaf tissue with [³H]uridine in vitro. Electrophoresis of the isolated RNA on acrylamide slab gels reveals, apart from 5S and transfer RNA, three major and about five minor RNA species with chain lengths between 140 and 280 nucleotides. These RNA molecules are labeled as rapidly as 5S, transfer RNA, and do not represent degradation products of large ribosomal RNA molecules. Furthermore, like 5S and transfer RNA, these small RNA species are stable and show no detectable turnover within forty-eight hours. Fractionation of the tissue into crude subcellular fractions indicates a preferential association of some of the small stable RNA species with the nucleus, while others appear to be located in the cytoplasm. The low molecular weight RNA spectrum from the leaf is similar to that observed in callus, with the major small RNA species equally present in both tissues.Abbreviations tRNA transfer RNA - hnRNA heterogenous nuclear RNA - mRNA messenger RNA - scRNA small cytoplasmic RNA - snRNA small nuclear RNA