Nucleic Acid Metabolism in the Developing Primary Leaf and Senescing Coleoptile of Germinating Oats

Nucleic acid metabolism in the coleoptile and primary leaf tissues of the germinating oat (Avena sativa L.) seedling was studied. The concentrations of the different species of nucleic acid present at various stages of development were determined and the amounts of each compared. All species of nucleic acid in the coleaptile increased as the tissue elongated; but, with the onset of senescence all species decreased, especially rRNA. Exposing dark grown coleoptiles to light did not modify their capacity to synthesize nucleic acids. In the rapidly developing leaf, all species of nucleic. acid increased throughout early germination. A general enhancement in the synthesis of all species of nucleic acids resulted when dark-grown-leaves were exposed to light. Furthermore, the tRNA/DNA ratio remained constant in both tissues during development, whereas the rRNA/DNA ratio changed.     

Partial purification of a ribosomal ribonucleic acid methylase from rat liver nuclei and methylation of undermethylated nuclear ribonucleic acid from regenerating liver of ethionine-treated rat

S-Adenosylmethionine-dependent ribosomal RNA (rRNA) methylase has been purified approx. 90-fold from rat liver nuclei. The partially purified methylase catalyzes the methylation of base and ribose in hypomethylated nuclear rRNA prepared from the regenerating rat liver after treatment with ethionine and adenine. The enzyme has an apparent molecular weight of about 3 x 10(4) and a sedimentation coefficient of 3.0 S. The enzyme is optimally active at pH 9.5 and sensitive to p-chloromercuribenzoate. Thiol-protecting reagents, such as dithiothreitol, are necessary for its activity, and the enzyme requires no divalent cations for its full activity. This enzyme did not efficiently transfer the methyl group to nuclear rRNA from normal rat liver, compared with hypomethylated nuclear rRNA. Methyl groups were mainly incorporated into pre-rRNA larger than 28 S, and the extent of 2'-O-methylation of ribose by this enzyme was greater than that of base methylation in the hypomethylated rRNA. No other nucleic acids, including transfer RNA (tRNA) and microsomal RNA from normal as well as ethionine-treated rat livers, tRNA from Escherichia coli, yeast RNA, and DNA from rat liver and calf thymus, were significantly methylated by this methylase. These results suggest that partially purified rRNA methylase from rat liver nuclei incorporates methyl groups into hypomethylated pre-rRNA from S-adenosylmethionine.     

The methylation of transfer ribonucleic acid during regeneration of the liver

Transfer ribonucleic acid¹ is methylated after the molecule is synthesized; at least eight enzymes are involved in the transfer of methyl groups (derived from methionine). The time courses of methylation and synthesis of tRNA during rat liver regeneration have been compared in an in vivo radioisotopic study, using 6-orotic acid-¹⁴C and ³H-methyl-L-methionine as precursors in double label pulses. Liver regeneration is a synchronized system in which biochemical events of the cell cycle are separable. Transfer RNA methylation increase precedes by several hours tRNA synthesis during regeneration, although the curves overlap. A ratio of the relative rate of methylation to the relative rate of synthesis has been made; that curve positively correlates with the rise and fall of protein synthesis during regeneration. It is clear that methylation and synthesis of tRNA are only weakly coupled; changing methyl content of the tRNA "pool" resulting from differential tRNA methylase and polymerase activities may regulate the rate of protein synthesis in the cell cycle at the translational level. The "pool sizes" of uridine monophosphate (UMP) and S-adenosylmethionine (SAM) were measured indirectly; UMP and SAM were isolated from perchloric acid supernatants and their specific activities were computed. Differential changes in radioactivity available to tRNA methylases and polymerases are not a source of artifact. That is, the control of both the synthesis and methylation of tRNA is at the enzyme level in vivo, rather than at some enzymatic step prior to those enzymatic reactions.     

Polyamines bound to nucleic acids during dormancy and activation of tuber cells of Helianthus tuberosus

Tuber tissue of Helianthus tuberosus L. (cv. OB1) contains a low amount of polyamines during dormancy but they are rapidly synthesized when tuber cells are activated in a growth medium and enter a new cell cycle. It was assumed that one of the reasons for this synthesis is that polyamines are necessary for the active conformation and correct functioning of nucleic acids. Complexes were found between spermine, spermidine and putrescine and rRNA, tRNA and an RNA fraction which contains poly(A) RNA and proteins. The amount of RNA-bound polyamines in the parenchyma cells of dormant tubers is dependent on the stage of dormancy and clearly increases (especially putrescine) when cells are activated. There are both tightly-bound and non-tightlybound polyamines. The significance of these bound polyamines is discussed in relation to their stabilizing role on nucleic acids.     

The effect of ethionine on ribonucleic acid synthesis in rat liver.

1. By 1h after administration of ethionine to the female rat the appearance of newly synthesized 18SrRNA in the cytoplasm is completely inhibited. This is not caused by inhibition of RNA synthesis, for the synthesis of the large ribosomal precursor RNA (45S) and of tRNA continues. Cleavage of 45S RNA to 32S RNA also occurs, but there was no evidence for the accumulation of mature or immature rRNA in the nucleus. 2. The effect of ethionine on the maturation of rRNA was not mimicked by an inhibitor of protein synthesis (cycloheximide) or an inhibitor of polyamine synthesis [methylglyoxal bis(guanylhydrazone)]. 3. Unlike the ethionine-induced inhibition of protein synthesis, this effect was not prevented by concurrent administration of inosine. A similar effect could be induced in HeLa cells by incubation for 1h in a medium lacking methionine. The ATP concentration in these cells was normal. From these two observations it was concluded that the effect of etionine on rRNA maturation is not caused by an ethionine-induced lack of ATP. It is suggested that ethionine, by lowering the hepatic concentration of S-adenosylmethionine, prevents methylation of the ribosomal precursor. The methylation is essential for the correct maturation of the molecule; without methylation complete degradation occurs.     

Metabolism of tRNA in rats with aflatoxin B1-induced hepatomas

This study describes effects of aflatoxin B1-induced hepatomas on RNA metabolism in rats. At 4 and 24 hours after the administration of L-(14CH3)-methionine, tRNA was isolated from the livers and hydrolyzed enzymatically to nucleosides which were quantitatively measured by HPLC. Radioactivity of the nucleosides was also determined. The data indicate that although tRNA methylation may be more rapid in livers with hepatomas, catabolism of tRNA in tumorous tissue is slower than in control livers. The large increase in some radioactive methylated nucleosides and bases by the tumor-bearing rats during the 24-hour period following the administration of labeled methionine indicates increased turnover of mRNA and rRNA as well as tRNA. Since degradation of tumor tRNA appears to be delayed, the excessive amounts of the urinary methylated nucleosides must be derived from RNA in nonneoplastic tissue.     

The Escherichia coli RlmN methyltransferase is a dual-specificity enzyme that modifies both rRNA and tRNA and controls translational accuracy

Modifying RNA enzymes are highly specific for substrate-rRNA or tRNA-and the target position. In Escherichia coli, there are very few multisite acting enzymes, and only one rRNA/tRNA dual-specificity enzyme, pseudouridine synthase RluA, has been identified to date. Among the tRNA-modifying enzymes, the methyltransferase responsible for the m(2)A synthesis at purine 37 in a tRNA set still remains unknown. m(2)A is also present at position 2503 in the peptidyl transferase center of 23S RNA, where it is introduced by RlmN, a radical S-adenosyl-L-methionine (SAM) enzyme. Here, we show that E. coli RlmN is a dual-specificity enzyme that catalyzes methylation of both rRNA and tRNA. The ΔrlmN mutant lacks m(2)A in both RNA types, whereas the expression of recombinant RlmN from a plasmid introduced into this mutant restores tRNA modification. Moreover, RlmN performs m(2)A(37) synthesis in vitro using a tRNA chimera as a substrate. This chimera has also proved useful to characterize some tRNA identity determinants for RlmN and other tRNA modification enzymes. Our data suggest that RlmN works in a late step during tRNA maturation by recognizing a precise 3D structure of tRNA. RlmN inactivation increases the misreading of a UAG stop codon. Since loss of m(2)A(37) from tRNA is expected to produce a hyperaccurate phenotype, we believe that the error-prone phenotype exhibited by the ΔrlmN mutant is due to loss of m(2)A from 23S rRNA and, accordingly, that the m(2)A2503 modification plays a crucial role in the proofreading step occurring at the peptidyl transferase center.     

Onset of nucleic acid synthesis during germination of Pisum sativum L.

Summary Measurments of total nucleic acid content of the embryonic axis indicated that massive net synthesis of both DNA and RNA was initiated at approximately 30 h after the onset of germination. The onset of net nucleic acid synthesis was marked by an increase in the rate of incorporation of [³H]thymidine into DNA, and of [³H]orotic acid and [³H]uridine into both DNA and RNA. rRNA was usually more heavily labelled than tRNA, but was not preferentially accumulated, suggesting a grater rate of turnover of rRNA than tRNA. Some incorporation of precursors occurred prior to the onset of net nucleic acid synthesis, particularly into RNA. This was taken to represent nucleic acid turnover. There was no evidence that the scavenging pathways for nucleotide biosynthesis were more important than the normal pathways in contributing precursors for net nucleic acid synthesis.     

The origin of the protein synthesis mechanism

The origin and development of the protein synthesis mechanism is considered in four successive steps. The genetic code is supposed to be controlled by the relative amount (availability) of various amino acids and nucleotides on the one hand, and utility on each amino acid in the polypeptide. on the other hand. Thus, more simple (inutile) and abundant amino acids tended to correspond to codons which were rich in the less frequent base species, G and C. Features of primitive tRNA in the discrimination of amino acid are discussed. Primitive tRNA is proposed to have a discriminator site for amino acid and, separated from it, an anticodon site for interaction with nucleotides. A hypothetical course of subdivision of various nucleic acid species is proposed. In the scheme, mRNA and ribosomal RNA (rRNA) were derived from more primitive insoluble RNA. DNA appeared in the late, not first, step of the development. Several other aspects of evolutionary development of the whole protein synthesis mechanism, e.g., role of the discriminator site on primitive tRNA, modification and subdivision of code catalogue into a more precise specification of amino acids, and possible primordial interactions between tRNA and tRNA-binding sites on insoluble rRNA, are discussed.     

Chemotactic responses of human polymorphonuclear leukocytes to cyclic GMP and other compounds

Some metabolic properties of small molecular weight nuclear RNA (snRNA) components have been studied in human lymphocytes cultured with PHA. Pulse-labelling experiments with ³H-uridine in 3 h-intervals around the onset of DNA synthesis showed no qualitative or quantitative differences in the snRNA labelling pattern. Long labelling experiment with ³H-methionine demonstrated the following relative degrees of methylation: tRNA (1.0), 5S RNA (0), D (0.3), 5.5S RNA (0.2), C (0.6), A (0.2), L (0) and rRNA (0.2). Chase-experiments with ³H-methionine showed that the snRNA components D, C and A are metabolically stable with half-lives of not less than 30 h. Actinomycin D (0.05 μg/ml) reduced markedly the synthesis of rRNA and 5 S RNA whereas the synthesis of D, C, A and L was unaffected or only slightly affected. Actinomycin D at a concentration of 0.25 μg/ml inhibited the synthesis of D, C and A. Cycloheximide (0.19 μg/ml) reduced the synthesis of D, C and rRNA to about 50% of control whereas 5S RNA synthesis was only slightly inhibited and tRNA synthesis was unaffected.     

tRNA chemical methylation. In vitro and in vivo formation of 1,7-dimethylguanosine at high concentrations of methylating agents

The methylation patterns produced in Escherichia coli B tRNA by a range of concentrations of the weak carcinogen dimethyl sulphate were examined with the following results: 1. 1,7-Dimethylguanosine was found to be formed in high amounts in the tRNA methylation reaction at high concentrations of methylating agent. 2. The dialkylated compound was recovered mainly in the form of derivatives, the spectral and chromatographic behaviour of which varied according to the procedures used for their isolation. Similar results were obtained for the in vivo methylation of rat-liver tRNA: after administration of a very high dose of the powerful carcinogen dimethylnitrosamine, 1,7-dimethylguanosine was found in rat-liver tRNA. Moreover, the analysis of the time-course of nucleic acid methylation indicated that this dialkylated product was still present in rat-liver tRNA when the major product of alkylation, 7-methylguanine, had almost completely disappeared.     

Neplanocin A. A cyclopentenyl analog of adenosine with specificity for inhibiting RNA methylation

The mechanism of action of the adenosine analog, neplanocin A (NPC), was investigated in human colon carcinoma cell line HT-29. Cell viability was reduced to 38 and 17% of control by 24-h exposure to 10(-5) and 10(-4) M NPC, respectively. Cytocidal activity was not affected by inhibition of adenosine deaminase with 2'-deoxycoformycin. Concomitant with decreased cell viability was the reduced incorporation of [14C]dThd and [3H]Leu, and to a lesser extent [3H]Urd, into acid-precipitable material. Labeling of rRNA and tRNA during drug treatment for 24 h with [methyl-3H]Met and [14C]Urd revealed that NPC primarily inhibited RNA methylation, and to a lesser extent, RNA synthesis. RNase T2 digests of total RNA indicated that base and 2'-O-methylation were inhibited to approximately the same degree. Metabolites of NPC were measured by reverse-phase high-performance liquid chromatography and it was found that the major drug metabolite was the drug analog of S-adenosylmethionine with little formation of the respective, S-adenosylhomocysteine metabolite. NPC was utilized to a very small degree for RNA synthesis where only 2 and 30 pmol of NPC/A260 were incorporated into rRNA and tRNA after 24-h exposure to 10(-5) and 10(-4) M NPC, respectively. These results indicate that NPC is metabolized to a metabolite of S-adenosylmethionine which is a poor methyl donor for RNA methyltransferases, and that the accompanying decrease in RNA methylation and protein synthesis appears to be related to its cytocidal activity.     

Feedback regulation of rRNA synthesis. A mutational alteration in the anti-Shine-Dalgarno region of the 16 S rRNA gene abolishes regulation

It was shown that induction of rRNA (and ribosome) synthesis from the lambda PL promoter/operator by temperature shift-up causes a repression of rRNA and tRNA synthesis from chromosomal genes. We have carried out experiments using a similar conditional rRNA gene expression system in which a mutational alteration was introduced in the anti-Shine-Dalgarno region at the 3'-end of the 16 S rRNA gene. It was found that the repression observed with the wild-type gene was largely abolished by the mutation. It appears that ribosomes inefficient in translational initiation are unable to cause feedback regulation of rRNA synthesis. It is suggested that the cell regulates rRNA (and tRNA) synthesis by monitoring the production of ribosomes, and that this monitoring is apparently carried out through their activity in the initiation (and perhaps subsequent steps) of translation.     

TRANSFER RNA AND THE REGULATION OF PROTEIN SYNTHESIS IN RAT CEREBRAL CORTEX DURING NEURAL DEVELOPMENT

Protein synthesis was measured in ribosomal systems derived from the cerebral cortex of 5-and 35-day-old rats. Under optimal conditions incorporation of radioactive leucine per mg ribosomal protein was four times higher with ribosomes from the younger animals than with ribosomes from the 35-day-old rats. This suggests that a decrease in the rate of protein synthesis occurs during neural development. Both ribosomes and the pH enzyme fraction from the cerebral cortex of 35-day-old rats had lower activities than preparations from the younger rats. Cerebral cortical ribosomes from 35-day-old animals had a lower polyribosome content than similar preparations from 5-day-old rats. A three-fold higher requirement for the pH 5 enzyme fraction was observed with the ribosomal system from 5-day-old rats, an observation which correlated with the yields of pH 5 enzyme and ribosomal protein from the younger tissue. The nature of the changes in the composition of the pH 5 enzyme fraction was investigated. Methylated albumin kiesselguhr (MAK) and Sephadex G-75 column chromatography showed that RNA from the pH 5 enzyme fraction was heterogeneous, containing tRNA, rRNA, and a small molecular weight RNA. This latter RNA, perhaps a degradation product of rRNA, comprised the greatest portion of RNA from the pH 5 enzyme fraction of cerebral cortex. The data obtained with MAK chromatography were used to estimate the total tRNA content of the cerebral cortex, with no age-related differences being observed. Since evidence of RNA degradation was seen, tRNA was also isolated by phenol extraction of whole cerebral cortex in the presence of bentonite. Purification of tRNA by NaCl and isopropanol fractionation gave preparations with no detectable rRNA or small molecular weight RNA. With this purification method, the tRNA yield was greater than estimated by the MAK method, demonstrating that losses of tRNA occurred during the cell fractionation steps. With the purification method 1.6 times more tRNA was obtained from the cerebral cortex of 5-day-old animals than from the older tissue. This higher level of tRNA in the younger, more active tissue appeared to involve all tRNA species, since in vitro aminoacyiation studies revealed nearly identical acceptance values for 18 individual amino acids. These results suggest that the rate of protein synthesis in cerebral cortex is regulated in part by the total amount of tRNA present to translate the higher level of polysome-bound mRNA.