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. 1973 Dec;70(12 Pt 1-2):3852–3856. doi: 10.1073/pnas.70.12.3852

Suppression of DNA Synthesis in Hepatoma Cells Exposed to Glucocorticoid Hormone In Vitro

John N Loeb 1,2, Carmia Borek 1,2, Lucy L Yeung 1,2
PMCID: PMC427343  PMID: 4149435

Abstract

Glucocorticoid hormone is shown to markedly suppress DNA synthesis in a line of rat hepatoma cells in vitro. In the presence of 300 nM hydrocortisone or 30 nM dexamethasone the incorporation of radioactive thymidine falls to 50% of control levels by 36 hr, and at higher concentrations of hormone inhibition can be noted as early as 12 hr and is nearly complete by 24 hr. This inhibition of radioactive thymidine incorporation reflects a true suppression of DNA synthesis, is accompanied by a corresponding inhibition of cell proliferation, and is readily reversible upon subsequent removal of hormone. In contrast to previously described effects of the glucocorticoid hormones on various cells of lymphoid origin, the inhibition of DNA synthesis in these hepatoma cells is not accompanied by appreciable cell lysis or by degradation of preformed DNA, and even when [3H]thymidine incorporation into DNA is inhibited by 90% or more, incorporation of [14C]uridine into RNA proceeds with little change. These findings all parallel previous observations on the effects of glucocorticoid hormone on the livers of intact animals and suggest that studies on the mechanism of the inhibition of DNA synthesis in the present more isolated system may lead to a better understanding of the means by which these compounds inhibit liver growth in vivo.

Despite the ready suppressibility of DNA synthesis in these hepatoma cells and in two other cell lines of liver origin, none of these cell lines was found to be inducible for tyrosine aminotransferase. The apparent dissociation between two “steroid-sensitive” phenomena is of interest and warrants further investigation.

Keywords: growth, cell proliferation, thymidine incorporation, enzyme induction, tyrosine aminotransferase

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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