Incorporation of tritiated adenosine into mouse ovum RNA

The total RNA of ovulated mouse ova has been examined by polyacrylamide gel electrophoresis. The amount of RNA present in the two main peaks observed, 28 S and 18 S ribosomal RNA, has been estimated as 0.20 ng.The RNA of ovulated mouse ova was labeled by exposure of growing mouse oocytes to adenosine-8-³H in vivo. For this purpose a small volume of a concentrated solution of the precursor was injected into the ovarian bursa, and ova were collected by superovulation at various subsequent times. The major growth phase of the oocyte is known to lie between 20 and 6 days before ovulation. Significant incorporation into egg RNA was observed when bursal injection was performed between 19 and 7 days, but not between 5 days and 1 day before ovulation.The types of labeled RNA in ova ovulated at five intervals between 19 and 7 days after bursal injection of adenosine-8-³H or uridine-5,6-³H were analyzed by polyacrylamide gel electrophoresis. The distribution of label on the gels demonstrated that the bulk of the label appeared in ribosomal RNA and transfer RNA. In addition labeled heterogeneous RNA was estimated to represent 10–15% of the total incorporation.     

Incorporation of 5S RNA into 16S-23S RNA complex

5S RNA as such is not incorporated into 16S-23S RNA complex formed under reconstitution condition. However, the addition of 50S ribosomal proteins, L5, L18 and L25/L15 results in its incorporation in stoichiometric amount. None of the proteins added individually is capable of incorporating 5S RNA into the complex. Of the different combinations in pairs that are possible out of the four proteins, the pairs L5, L18 and L15, L18 stimulate the incorporation to some extent. Of the four possible triplets, L5, L18, L25 or L5, L15, L18 is the most efficient for maximum incorporation of 5S RNA. The presence of all the four proteins is no more effective than the combinations of the three.     

Incorporation of different labelled precursors into chloroplast RNA of Chlorella

Summary Radioactive uridine is incorporated by Chlorella strain 211-8b/p into ribosomal subunits and their rapidly labelled RNA comigrates with chloroplast RNA on polycrylamide gels.Ribosomal particles which can be labelled by short pulses of orotic acid cosediment with the particles labelled by uridine pulses and contain the same RNA species as these when separated either on sucrose gradients or on polycrylamide gels. This incorporation is, like that of uridine, sensitive to rifampin and chloramphenicol, but insensitive to cycloheximide.A comparative study of short-time incorporation of uridine, orotic acid and guanosine into the RNA of Chlorella showed that all three precursors were incorporated mainly into RNA of chloroplastic origin. However, guanosine was also partly incorporated into cytoplasmic rRNA. Nitrogen-deficient cells always incorporated part of all three precursors into cytoplasmic rRNA, but the proportions of these were different among the different precursors.These results are consistent with the hypothesis that the described differences in the incorporation of the above mentioned precursors into RNA of different cellular compartments are largely attributable to effects of pool sizes.     

Kinetics of Incorporation of Uridine-C14 into L Cell RNA

Five components have been isolated from L cells by a combination of phenol extraction procedures and sedimentation analysis through sucrose gradients. These components are identified by their sedimentation rates. The 50S and 40S components are derived from the nucleus, the 32S and 18S from ribosomal RNA, and the 4S fraction is the soluble RNA of the cell. L cells were supplied with uridine-C¹⁴ under steady-state conditions and the rate of uptake of C¹⁴ into each component was measured. Analysis of the results suggests that the delay in entry of C¹⁴ into ribosomal RNA is occasioned by two sequential precursors and that 50S and 40S RNA meet the kinetic requirements for these precursors. 4S RNA seems to contain two components that label at different rates.     

Incorporation of Labeled Precursors into the RNA and Proteins of Lactic Dehydrogenase Virus

Lactic dehydrogenase virus was grown in primary mouse embryo cells and labeled with (3)H-uridine and (3)H-amino acids. Concentrated and purified virus was banded by isopycnic centrifugation in sucrose gradients, and infectivity and radioactivity were found to correspond at a density of 1.17 g/cm(3). The extracted viral RNA was resolved by electrophoresis in polyacrylamide-agarose mixed gels, and the mol wt was estimated to be 6.0 x 10(6).     

The Synthesis of 2′-C-Functionalised Nucleosides for Incorporation into Catalytic RNA

Abstract

Five 2′-C-functionalized nucleosides (1–5) have been prepared and incorporated into dinucleoside monophosphates. The effect of the functionality on the stability of the adjacent phosphodiester bond toward hydrolysis by nuclease enzymes and extremes of pH has been assessed.     

Incorporation of a kinin, N, 6-benzyladenine into soluble RNA

Kinin requiring tobacco and soybean tissues incubated on a medium containing N,6-benzyladenine-8-C¹⁴ incorporated C¹⁴ into several RNA components including adenylic and guanylic acids. About 15% of the label taken up by the tissues appeared in RNA while the remainder was distributed among several metabolites in the soluble, nonpolynucleotide fraction. Tissue grown on a kinin labeled in the side chain (N,6-benzyladenine-benzyl-C¹⁴) also incorporated a small, but nevertheless repeatable, amount of radioactivity into minor RNA components.

Ultracentrifugation studies and methylated albumin chromatography indicated that the bulk of the label from benzyladenine-benzyl-C¹⁴ is in soluble RNA. Approximately 50% of the C¹⁴ in soluble RNA is in a component which has chromatographic properties like that of benzyladenine.

It is suggested that the biological action of the kinins may hinge on their providing substituted bases in RNA in tissues which through differentiation no longer synthesize RNA-methylating enzymes. As an alternative it was hypothesized that a small amount of benzyladenine was incorporated into a m-RNA, acting there as a derepressing agent, perhaps by preventing its normal repressing function.

     

Incorporation of high molecular weight RNA into large artificial lipid vesicles.

By utilizing an ether infusion technique with lecithin, cholesterol, and dicetylphosphate, giant liposomes have been produced with diameters ranging from 0.5 to 2.0 microns. These liposomes have been used to sequester 4S, 16S, and 23S $\text{E. coli}$ [³H]RNA and can be effectively separated from non-liposome incorporated RNA by ribonuclease treatment followed by Sepharose 4B gel filtration. The [³H]RNA within these liposomes can be extracted and appears to be undegraded.     

Incorporation of Radioactive Precursors into DNA and RNA of Plasmodium knowlesi in vitro

SYNOPSIS. Cultures of the intra-erythrocytic stages of Plasmodium knowlesi incubated in vitro utilized all the pre-formed radioactive purines tested (adenine, adenosine, deoxvadenosine, guanine, guanosine and hypoxanthine) but none of the pyrimidines (thymine, thymidine, uracil, uridine, cytidine and deoxycytidine). They did, however, utilize the pyrimidine precursor orotic acid.
All precursors analysed, including deoxyadenosine, were incorporated into both DNA and RNA (in the ratio of ∼1:3) but 19% was incorporated into other unidentified compounds. ³Hadenosine was incorporated into adenine and guanine residues of both DNA and RNA.
No unambiguous evidence was obtained for any periodicity in the synthesis of DNA or RNA in our cultures, even tho cultures remained as synchronous in vitro as they are in vivo. An estimate is presented of the amount of DNA made during one cycle in vitro.     

Incorporation of Ribonucleic Acid Bases into the Metabolic Pool and RNA of E. coli

Labeled cytosine, adenine, and guanine are rapidly incorporated by E. coli. A fraction of the radioactivity passes directly into RNA with very little delay. The remainder enters a pool before being incorporated into RNA. The fractions entering the pool and the time constants for equilibration of the specific activity of the pool are widely different for the four RNA bases.