Effect of hypoxia on hepatic DNA methylation and tRNA methyltransferase in rat: similarities to effects of methyl-deficient diets.

Young rats were maintained in a 10% oxygen atmosphere for 2, 6, and 10 days and administered normal rat chow and water ad libitum. Thereafter, their hepatic S-adenosyl-L-methionine (AdoMet) and activity and mRNA levels of AdoMet synthetase were assayed. AdoMet levels decreased by 45% after 10 days; hepatic AdoMet synthetase also declined by approximately 40%. In rats with low hepatic AdoMet, the mRNA level of AdoMet synthetase also declined by up to 80%. No significant change in AdoMet or AdoMet synthetase was noted in pair-fed normoxic rats. DNA hypomethylation was determined in terms of incorporation of [3H]methyl of AdoMet incorporated at unmethylated sites in DNA in reactions mediated by methylases HpaII and SssI. As compared to the normal hepatic DNA, [3H]methyl group incorporation in the 10-day hypoxic DNA was almost double in the HpaII-mediated reaction and approximately 10-fold in the SssI-mediated reaction. Hepatic tRNA methyltransferase activity doubled after 10 days of hypoxia. However, hypoxic rats showed no detectable mRNA transcripts for c-myc and c-fos oncogenes on Northern blot analysis. These observations show that because of subnormal activity of AdoMet synthetase, hypoxic liver is depleted of AdoMet, even when the animals are administered a complete diet. However, unlike rats on chronic lipotrope-deficient diets, hypoxic rats on a complete diet show no aberrant expression of oncogenes.

The effect of sinefungin and synthetic analogues on RNA and DNA methyltransferases from Streptomyces.

Sinefungin is an antibiotic structurally related to S-adenosylmethionine. It has been described as an inhibitor of RNA transmethylation reactions in viruses and eukaryotic organisms, but not in bacteria. We show here that sinefungin strongly inhibits RNA methyltransferase activity, but not the biosynthesis of these enzymes in Streptomyces. All the methylated bases found in Streptomyces RNA (1-methyladenine, N6-methyladenine, N6,N6-dimethyladenine and 7-methylguanine) are inhibited by this antibiotic. Experiments with sinefungin analogues show that specific changes in the ornithine radical of the molecule still preserve its inhibitory capability. The substitution of the adenine radical by uridine causes the loss of the inhibitory effect. These results and our former studies on Streptomyces DNA methylation, suggest that nucleic acid modification is the main target of sinefungin in Streptomyces.