An unmethylated “3 SE” RNA in hamster mitochondria: A 5 S RNA-equivalent?

A novel low molecular weight (“3 S_E”) RNA associated with hamster cell mitochondria has been partially characterized. It was present at approx. 1:1 molar ratio with structural mitochondrial ribosomal RNA; it was unmethylated; and it resembled other mitochondrial RNA fractions in having a low content of G + C. These findings support the idea that 3 S_E RNA is a mitochondrial equivalent of 5 S ribosomal RNA.     

Axoplasmic RNA species synthesized in the isolated squid giant axon

Isolated squid stellate nerves and giant fiber lobes were incubated for 8 hr in Millipore filtered sea water containing [³H]uridine. The electrophoretic patterns of radioactive RNA purified from the axoplasm of the giant axon and from the giant fiber lobe (cell bodies of the giant axon) demonstrated the presence of RNA species with mobilities corresponding to tRNA and rRNA. The presence of labeled rRNAs was confirmed by the behavior of the large rRNA component (31S) which, in the squid, readily dissociates into its two constituent moyeties (17S and 20S). Comparable results were obtained with the axonal sheath and the stellate nerve. In all the electrophoretic patterns, additional species of radioactive RNA migrated between the 4S and the 20S markers, i.e. with mobilities corresponding to presumptive mRNAs. Chromatographic analysis of the purified RNAs on oligo(dT)cellulose indicated the presence of labeled poly(A)⁺ RNA in all tissue samples. Radioactive poly(A)⁺ RNA represented approximately 1% of the total labeled RNA in the axoplasm, axonal sheath and stellate nerve, but more than 2% in the giant fiber lobe. The labeled poly(A)⁺ RNAs of the giant fibre lobe showed a prevalence of larger species in comparison to the axonal sheath and stellate nerve. In conclusion, the axoplasmic RNAs synthesized by the isolated squid giant axon appear to include all the major classes of axoplasmic RNAs, that is rRNA, tRNA and mRNA.Special Issue dedicated to Prof. Holger Hydén.     

Low molecular weight RNAs hydrogen-bonded to nuclear and cytoplasmic poly(a)-terminated RNA from cultured chinese hamster ovary cells

A group of RNAs 90–100 nucleotides long were isolated by melting them from poly(A)-terminated nuclear or cytoplasmic RNA from cultured Chinese hamster ovary cells. Conditions that favor hydrogen bond formation allowed the reassociation of these low molecular weight RNAs with poly(A)-terminated RNA. The nuclear poly(A)-terminated molecules contained 1.3 moles of the low molecular weight RNAs per mole of poly(A), while the cytoplasmic poly(A)-terminated RNA contained only one seventh as much. These low molecular weight RNAs were also isolated from the total 4S RNA of either the nucleus or cytoplasm by polyacrylamide gel electrophoresis. They formed a prominantly labeled band of RNA in the gels after cells had been labeled with H₃³²PO₄ for 4 hr. The low molecular weight RNAs melted from the nuclear poly(A)-terminated RNA were slightly different (although not necessarily in primary nucleotide sequence) from those melted from the cytoplasmic poly(A)-terminated RNA.     

Studies on the bacteriophage MS2. XXIV. Hydrodynamic properties of the native and acid MS2 RNA structures

The molecular weight of native 26.6S MS2 RNA, of acidic 53.1S MS2 RNA and of formaldehyde-treated 36.1S MS2 RNA was determined by light-scattering studies. The three forms examined correspond to monomers. Also νv values were determined, and in conjunction with our previous estimates for S_20,W and [η], led again to the conclusion that formaldehyde-cross-linked 37S MS2 RNA is a monomer. On the basis of the experimentally observed R_G, [η], S_20,W, and νv values, and taking a prolate ellipsoid as a model, the hydrodynamic volume, the solvation water and the axial ratio could be deduced for the three conformations. In the “native” 26S form the RNA occupies only 8.2% of the hydrodynamic volume. The formation of the 36S and the 53S structures correspond largely to a loss of solvation water.     

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.     

Nature of the ribosomal RNA transcribed from the X and Y chromosomes of Drosophila melanogaster

In Drosophila melanogaster there is one nucleolar organizer (NO) on each X and Y chromosome. Experiments were carried out to compare the ribosomal RNAs derived from the two nucleolar organizers. ³²PO₄-labelled ribosomal RNA was isolated from two strains of D. melanogaster, one containing only the X chromosome NO, the other containing only the Y chromosome NO. 28 S and 18 S RNA from the two strains were subjected to a variety of “fingerprinting” and sequencing procedures. Fingerprints of 28 S RNA were very different from those of 18 S RNA. Fingerprints of “X” and “Y” 28 S RNA were indistinguishable from each other, as also were fingerprints of “X” and “Y” 18 S RNA. In combined “T₁ plus pancreatic” RNAase fingerprints several distinctive products were characterized and quantitated. Identical products were obtained from X and Y RNA, and the molar yields of the products were indistinguishable. Together these findings imply that the rRNA sequences encoded by the X and Y NOs are closely similar and probably identical to each other.Two further findings were of interest in “T₁ plus pancreatic” RNAase fingerprints: (1) in 28 S (as well as in 18 S) fingerprints several distinctive products were recovered in approximately unimolar yields. This indicates that 28 S RNA does not consist of two identical half molecules, though it does consist of two non-identical half molecules together with a “5.8 S” fragment. (2) Several methylated components in Drosophila rRNA also occur in rRNA from HeLa cells and yeast. This suggests that certain features of rRNA structure involving methylated nucleotides may be highly conserved in eukaryotic evolution.     

Synthesis and transport of various RNA species in developing embryos of Xenopus laevis.

Embryonic cells of Xenopus laevis were labeled for varying lengths of time, and their nuclear and cytoplasmic RNAs were analyzed, with the following results. (1) The synthesis of small nuclear RNAs (snRNAs) is detected from blastula stage on. (2) The initiation of 4 S and 5 S RNA syntheses occurs at blastula stage. However, while the former is transported into the cytoplasm immediately after its synthesis, the latter remains within the nucleus, until its transport starts later, concomitantly with that of 28 S rRNA. (3) As soon as “blastula” cells start to synthesize 40 S rRNA precursor at 5th hr of cultivation, 18 S rRNA is transported first; the transport of 28 S rRNA begins 2 hr later. (4) On a per-cell basis, poly(A)-RNA is synthesized in blastula stage at a much higher rate than in the later stages. About one-third of the total blastula poly(A)-RNA, and about one-fifth in the case of tailbud cells, is transported quickly into the cytoplasm. Then, it appears that the RNAs which are synthesized at early embryonic stages are transported to the cytoplasm without delays, except for 5 S RNA and snRNAs.     

Mitochondrial poly(A) RNA synthesis during early sea urchin development

The synthesis of mitochondrial messenger RNA during early sea urchin development was examined. Oligo(dT) chromatography and electrophoresis on aqueous or formamide gels of mitochondrial RNA from pulse-labeled embryos showed the presence of eight distinct poly(A)-containing RNA species, ranging in size from 9 to 22 S. Nuclease digestion of these RNAs revealed poly(A) sequences of 4 S size. Using sea urchin anucleate fragments, we were able to demonstrate that all eight messenger RNAs are transcribed from mitochondrial DNA, rather than being transcribed from nuclear DNA and imported into the mitochondria.There was no change in the electrophoretic profile of the eight poly(A) RNAs when embryos were pulsed with [³H]uridine at various times after fertilization. Neither was there any change in the incorporation of [³H]uridine into these species or in the percentage of total newly synthesized mitochondrial RNA that contains poly(A) sequences as development progresses. Even though these RNAs appear to be transcribed at a constant rate throughout early development, they were not detected in mitochondrial polysomes until 18 hr after fertilization.     

Differential accumulation of two size classes of poly(A) associated with messenger RNA during oogenesis in Xenopus laevis

The RNA of full-grown oocytes of Xenopus laevis contains two distinct size classes of poly(A), designated poly(A)_S and poly(A)_L, which contain 15–30 (mean = 20) and 40–80 (mean = 61) A residues, respectively. Both poly(A)_L and poly(A)_S are associated with RNA which is heterogeneous in size. The two classes of poly(A)⁺ RNA can be separated by affinity chromatography: Only poly(A)_L⁺ RNA binds to oligo(dT)-cellulose under appropriate conditions, but up to 50% of the poly(A)_S⁺ RNA can be isolated from the void fraction by binding to poly(U)-Sepharose. Both classes of poly(A)⁺ RNA are active as messenger RNA in an in vitro system and yield identical patterns of in vitro protein products. Previtellogenic oocytes contain almost exclusively poly(A)_L, which accumulates up to vitellogenesis but remains almost constant in amount (molecules/oocyte) during vitellogenesis and in the full-grown oocyte. Poly(A)_S accumulates (molecules/oocyte) from early vitellogenesis up to the full-grown oocyte. The total number of poly(A)⁺ RNA molecules per oocyte increases throughout oogenesis from 2 × 10¹⁰/previtellogenic oocyte [80–90% poly(A)_L] to 20 × 10¹⁰/full-grown oocyte (25–40% poly(A)_L). It is argued that poly(A)_S is protected from degradation in the oocyte, thus stabilizing the “maternal” poly(A)⁺ mRNA.     

Poly(A)+ RNA from Tetrahymena: Stimulation of Protein Synthesis in Vitro*†

SYNOPSIS Cell-free synthesis of high molecular weight polypeptides, programmed by RNA from Tetrahymena pyriformis strain W is reported, and methods for preparation of the RNA are described. The RNA was extracted by the SDS-phenol-chloroform-isoamyl alcohol technic. The bulk of extracted RNA was ribosomal and on sucrose gradients peaked at -17S and 25S. After heat denaturation all the 25S RNA was converted to 17S. indicating the presence of hidden breaks, possibly the result of nuclease activity during extraction. Nevertheless, when poly(A)–RNA was collected using oligo-(dT)-cellulose column chromatography, it promoted a 15–fold increase in incorporation of [35S] methionine into TCA-precipitable material. Slab-gel electrophoresis and autoradiography of the product revealed 12 different major polypeptides, varying in weight from 28.000 to 65,000 Daltons. A method for preparation of translatable RNA from Tetrahymena will make possible the comparison of messenger RNAs associated with specific cell structures and with different developmental events.     

Microbial identification by immunohybridization assay of artificial RNA labels

Ribosomal RNA (rRNA) and engineered stable artificial RNAs (aRNAs) are frequently used to monitor bacteria in complex ecosystems. In this work, we describe a solid-phase immunocapture hybridization assay that can be used with low molecular weight RNA targets. A biotinylated DNA probe is efficiently hybridized in solution with the target RNA, and the DNA-RNA hybrids are captured on streptavidin-coated plates and quantified using a DNA-RNA heteroduplex-specific antibody conjugated to alkaline phosphatase. The assay was shown to be specific for both 5S rRNA and low molecular weight (LMW) artificial RNAs and highly sensitive, allowing detection of as little as 5.2 ng (0.15 pmol) in the case of 5S rRNA. Target RNAs were readily detected even in the presence of excess nontarget RNA. Detection using DNA probes as small as 17 bases targeting a repetitive artificial RNA sequence in an engineered RNA was more efficient than the detection of a unique sequence.     

Complementarity of sequences in low molecular weight RNAs to regions of messenger and ribosomal RNAs.

Total low molecular weight nuclear RNAs of mouse ascites cells have been labeled in vitro and used as probes to search for complementary sequences contained in nuclear or cytoplasmic RNA. From a subset of hybridizing lmw RNAs, two major species of 58,000 and 35,000 mol. wt. have been identified as mouse 5 and 5.8S ribosomal RNA. Mouse 5 and 5.8S rRNA hybridize not only to 18 and 28S rRNA, respectively, but also to nuclear and cytoplasmic poly(A+) RNA. Northern blot analysis and oligo-dT cellulose chromatography have confirmed the intermolecular base-pairing of these two small rRNA sequences to total poly(A+) RNA as well as to purified rabbit globin mRNA. 5 and 5.8S rRNA also hybridize with positive (coding) but not negative (noncoding) strands of viral RNA. Temperature melting experiments have demonstrated that their hybrid stability with mRNA sequences is comparable to that observed for the 5S:18S and 5.8S:28S hybrids. The functional significance of 5 and 5.8S rRNA base-pairing with mRNAs and larger rRNAs is unknown, but these interactions could play important coordinating roles in ribosome structure, subunit interaction, and mRNA binding during translation.     

Ribonucleic acid from the higher plant Matthiola incana. Molecular weight measurements and DNA-RNA hybridisation studies.

The percentage of DNA from the crucifer Matthiola incana coding for different types of RNA was measured by filter saturation hybridisation experiments using RNA labelled in vivo. In addition, the melting curves of the various DNA - RNA hybrids formed and the buoyant densities of the DNA sequences complementary to different types of RNA were measured. 1. The RNA preparations used were 25, 18, and 5 S rRNA and 4 S RNA, purified by gel electrophoresis, and poly(A)-containing RNA purified by oligo-(dT)-cellulose chromatography. The molecular weights of the 25 S and 18 S rRNAs, calculated from the mobility in formamide-acrylamide gels relative to Escherichia coli RNA, are 1.25 - 10(6) and 0.64 - 10(6). The rRNA precursor has a molecular weight of approx. 2.1 - 10(6) and the average molecular weight of the poly(A)-containing RNA from both cotyledons and roots is 4 - 10(5). 2. The percentage of the genome, calculated on the basis of double-stranded DNA, coding for these RNAs and the estimated number of genes per haploid DNA amount are approximately 0.46% and 1100 for 25 S plus 18 S rRNA, 0.032% and 3600 for 5 S rRNA and 0.072% and 13 000 for 4 S RNA. In filter hybridisation experiments very little hybridisation of poly(A)-containing RNA was found. A rapidly-hybridising component is attributed to small amounts of contaminating rRNA. 3. M. incana DNA has a main band at 1.697 g - ml-1 in CsCl and a satellite constituting approximately 3% of the DNA, at 1.708 g - ml-1 - 25 and 18 S rRNA hybridise to DNA with a buoyant density of 1.701--2 g - ml-1. The buoyant density of 5 S DNA is slightly less at 1.700--1 g - ml-1. 4. S RNA hybridises to at least two separate regions, one within the main-band DNA and a second lighter component. None of the RNAs tested hybridised to the satellite DNA. The Tm of the DNA - RNA hybrids in 1 X SSC is 89 degrees C for 25 S rRNA, 85 degrees C for 5 S rRNA and 82 degrees C for 4 S RNA. 4. 5 and 4 S RNA preparations contain fragments which hybridise to sequences complementary to high-molecular-weight rRNA. This spurious hybridisation can be eliminated by competition with unlabelled high-molecular-weight RNA.     

Direct differential absorbance profiles of denaturing transitions in ribosomal and mRNA.

A direct method for measuring the derivative of thermal transition profiles (ΔA/ΔT), first described by Pavlov and Lyubchenko [Biopolymers 17 , 795–798 (1978)], is applied to the secondary structure of several eukaryotic ribosomal and messenger RNAs. The method consists of generating an effective ΔT between a sample and reference cuvette by altering the T_m (midpoint denaturation temperature) of one of the solutions with respect to the other. This can be done by changing salt concentration, solvent, pH, or ligands. Scanning the two cuvettes by varying the wavelength at different temperatures permits detailed examination of the base composition of differentially melting domains. We report here the ΔA/ΔT profiles generated by monovalent ion concentration differences for a number of high-molecular-weight natural RNAs, as well as the synthetic polynucleotides poly(rA) and “random” poly[r(A,G,U,C)]. The 18S and 28S rRNAs from chick embryos exhibit a reproducible series of peaks in the ΔA/ΔT profiles at low salt with ΔT = 4K. The high-temperature transitions in 28S rRNA appear to contain G·C base pairs exclusively, in contrast to those in 18S rRNA or any natural mRNA. Each mRNA we have examined (bacteriophage MS2, globin mRNA from rabbit reticulocytes, and procollagen mRNA from chick embryos) exhibits a distinctive ΔA/ΔT profile in low salt. The stability of many of the transitions in each of the mRNAs is no greater than that of the secondary structure in random poly(A,G,U,C) in low salt. More than 50% of the base pairing in procollagen mRNA actually “melts” below the mean for the random copolymer, indicating that despite its high G·C content, this mRNA contains a secondary structure that is exceptionally low in stability.     

In-vitro translation of messenger-RNA from developing bean leaves. Evidence for the existence of stored messenger-RNA and its light-induced mobilisation into polyribosomes

Poly(A)-containing messenger RNA was purified from polyribosomes isolated from the primary leaves of 7-day-old dark-grown seedlings of Phaseolus vulgaris var. Masterpiece. Analysis of the messenger RNA on 2.4% polyacrylamide gels showed that it consists of a heterogeneous population of molecules with an average molecular weight of 500,000. The nucleotide composition of the RNA was 16.0% cytidylic acid, 39.4% adenylic acid, 21.3% guanylic acid and 23.2% uridylic acid. Based on the degree of resistance of the RNA to digestion with ribonucleases A and T₁ the average length of the poly(A) sequence was calculated to be 120 nucleotides. No significant differences in mobility in polyacrylamide gels, nucleotide composition or polyadenylic acid content were found between the poly(A)-containing mRNA from polyribosomes of primary leaves of dark-grown plants and those given a 16 h white light treatment. Purified poly(A)-containing mRNA was shown to direct the incorporation of [³⁵S]methionine into proteins in an in vitro protein-synthesising system from wheat germ. The protein products were fractionated according to molecular size by electrophoresis in 15% polyacrylamide/urea/SDS gels and the protein bands were detected by fluorography. Messenger RNAs directing the synthesis of three polypeptides with molecular weights of 34,000, 32,000 and 25,000 were detected in polyribosomes of plants following white light treatment. These messenger RNAs were absent, or present in much lower amounts, in polyribosomal messenger RNA from leaves of dark-grown plants, although they were present in total cell poly(A)-containing RNA. This indicates that certain messenger RNAs may be stored in the dark and that light stimulates these RNAs to engage in polyribosome formation. Continuous far-red (730 nm) irradiation for 4 h also caused the appearance of these messenger RNAs in the polyribosomes although 5 min red light followed by 4 h darkness had little effect. This suggests that phytochrome acting in the high energy mode, may be the photoreceptor responsible for initiating the response.Abbreviations mRNA messenger-RNA - rRNA ribosomal RNA - oligo (dT) oligo (deoxythymidylic acid) - poly(A) polyadenylic acid - EDTA ethylenediamine-tetra-acetic acid - HEPES N-2-hydroxyethylpiperazine-N-2-ethane-sulphonic acid - SDS sodium dodecyl sulphate