Characterization and metabolic regulation of a liver-specific 5.4-kilobase mRNA whose synthesis is transcriptionally induced by carbohydrates and repressed by glucagon and cyclic AMP.

Four clones derived from a carbohydrate-induced rat liver cDNA library were found to hybridize with a 5.4-kilobase mRNA species encoding a 36 kDa protein. This mRNA was abundant in the liver, barely detectable in adipocytes and kidney, and absent from the other tissues tested. In the liver, the mRNA was fully induced by a carbohydrate-rich diet, but was undetectable during both starvation and feeding with a protein-rich or lipid-rich diet. Adrenalectomized, thyroidectomized and diabetic animals did not express the mRNA in their liver when re-fed with the carbohydrate-rich diet. When these animals were given the missing hormone, the amount of hybridizable RNA returned to normal values, but administration of the hormone alone failed to induce mRNA synthesis in starved animals. Both glucagon and its second messenger, cyclic AMP, abolished the induction of the mRNA in re-fed animals. Exogenous insulin, whatever the dose, did not reverse the inhibitory action of glucagon. In an isolated nuclei transcription system, no detectable RNA transcripts were found in starved animals, whereas feeding the animals with the carbohydrate-rich diet led to a maximum rate of gene transcription. Although unidentified, this mRNA proves to be a remarkable marker of dietary and hormonal control of gene expression in vivo. It will provide a useful model for further analysis of the role of cyclic AMP in regulating the transcription of eukaryotic genes.