REGULATION OF THYROTROPIN RECEPTOR GENE-EXPRESSION IN RAT FRTL-5 THYROID-CELLS

TSH receptor mRNA levels in FRTL-5 thyroid cells are autoregulated at a transcriptional level by the same hormones required for the growth and function of the cells: TSH, insulin, and insulin-like growth factor-I (IGF-I). Thus, the ability of TSH, via its cAMP signal, to down-regulate steady state receptor mRNA levels is preceded by the action of TSH to decrease pre-mRNA levels in nuclear run-on assays to the same quantitative level as evident in Northern analyses. In contrast, the receptor mRNA half-life is shown not to change when down-regulation is reversed by withdrawing TSH in the presence or absence of actinomycin-D. Evidence is additionally provided that TSH receptor mRNA levels are increased by insulin, IGF-I, or calf serum in both Northern and run-on assays. This action cannot be duplicated by hydrocortisone and is evident at more than 20-fold lower concentrations of IGF-I than insulin. Moreover, insulin, IGF-I, and/or calf serum are required for the autoregulatory negative transcriptional regulation of the TSH receptor by TSH/cAMP, as is the case for thyroglobulin. This occurs despite the opposite actions of TSH/cAMP on the two genes, positive in the case of thyroglobulin and negative with TSH receptor. The positive and negative regulatory actions, respectively, of insulin/IGF-I and TSH on receptor gene expression are associated with coincident increases or decreases in cell surface receptors measured by [I-125]TSH binding. The autoregulation additionally involves the interplay of a second cAMP-modulated regulatory factor, one which up-regulates TSH receptor mRNA levels rather than causing down-regulation. Thus, cycloheximide inhibits the transcriptional action of both TSH/cAMP and insulin/IGF-I/serum within 4 h, i.e. a rapidly synthesized protein is an intermediate in both cases. The presence of cycloheximide for as little as 1 h, however, uncovers the ability of TSH/cAMP to increase TSH receptor mRNA levels. This activity is the result of the action of a stable cAMP-induced activator which can be detected physiologically, i.e. in the absence of cycloheximide. For example, low levels of a cAMP analog (0.2 mM), as opposed to high levels (> 1 mM), can increase TSH receptor RNA levels. Low levels also accelerate the insulin/IGF-I-dependent return of receptor mRNA to normal levels after TSH withdrawal. The action of this positive regulator may also account for a transient increase in receptor mRNA levels before TSH/cAMP-induced down regulation is evident in Northern and run-on assays, i.e. within 1-2 h after TSH addition and maximal cAMP elevation. Thus, in run-on assays, TSH increases transcription 1 h after its addition, but decreases transcription by 4 h. The sum of the interplay of insulin, IGF-I, and TSH on TSH receptor gene expression appears, therefore, to be an interactive autoregulatory feedback mechanism to maintain TSH receptor activity on the cell surface.