Glucocorticoids inhibit the growth of AtT-20 mouse pituitary tumor cells

Cooperation between cyclin E and p27(Kip1) in pituitary tumorigenesis

Cushing's disease is caused by glucocorticoid-resistant pituitary corticotroph adenomas. We have previously identified the loss of nuclear Brg1 as one mechanism that may lead to partial glucocorticoid resistance: this loss is observed in about 33% of human corticotroph adenomas. We now show that Brg1 loss of function correlates with cyclin E expression in corticotroph adenomas and with loss of the cell cycle inhibitor p27(Kip1) expression. Because Brg1 is thought to have tumor suppressor activity, the present study was undertaken to understand the putative contribution of cyclin E derepression produced by loss of Brg1 expression on adenoma development. Overexpression of cyclin E in pituitary proopiomelanocortin cells leads to abnormal reentry into cell cycle of differentiated proopiomelanocortin cells and to centrosome instability. These alterations are consistent with the intermediate lobe hyperplasia and anterior lobe adenomas that were observed in these pituitaries. When combined with the p27(Kip1) knockout, overexpression of cyclin E increased the incidence of pituitary tumors, their size, and their proliferation index. These results suggest that cyclin E up-regulation and p27(Kip1) loss-of-function act cooperatively on pituitary adenoma development.

Regulatory network analyses reveal genome-wide potentiation of LIF signaling by glucocorticoids and define an innate cell defense response

While the hypothalamo-pituitary-adrenal axis (HPA) activates a general stress response by increasing glucocorticoid (Gc) synthesis, biological stress resulting from infections triggers the inflammatory response through production of cytokines. The pituitary gland integrates some of these signals by responding to the pro-inflammatory cytokines IL6 and LIF and to a negative Gc feedback loop. The present work used whole-genome approaches to define the LIF/STAT3 regulatory network and to delineate cross-talk between this pathway and Gc action. Genome-wide ChIP-chip identified 3,449 STAT3 binding sites, whereas 2,396 genes regulated by LIF and/or Gc were found by expression profiling. Surprisingly, LIF on its own changed expression of only 85 genes but the joint action of LIF and Gc potentiated the expression of more than a thousand genes. Accordingly, activation of both LIF and Gc pathways also potentiated STAT3 and GR recruitment to many STAT3 targets. Our analyses revealed an unexpected gene cluster that requires both stimuli for delayed activation; 83% of the genes in this cluster are involved in different cell defense mechanisms. Thus, stressors that trigger both general stress and inflammatory responses lead to activation of a stereotypic innate cellular defense response.

Role of Brg1 and HDAC2 in GR trans-repression of the pituitary POMC gene and misexpression in Cushing disease

Negative feedback regulation of the proopiomelanocortin (POMC) gene by the glucocorticoid (Gc) receptor (GR) is a critical feature of the hypothalamo-pituitary-adrenal axis, and it is in part exerted by trans-repression between GR and the orphan nuclear receptors related to NGFI-B. We now show that Brg1, the ATPase subunit of the Swi/Snf complex, is essential for this trans-repression and that Brg1 is required in vivo to stabilize interactions between GR and NGFI-B as well as between GR and HDAC2. Whereas Brg1 is constitutively present at the POMC promoter, recruitment of GR and HDAC2 is ligand-dependent and results in histone H4 deacetylation of the POMC locus. In addition, GR-dependent repression inhibits promoter clearance by RNA polymerase II. Thus, corecruitment of repressor and activator at the promoter and chromatin modification jointly contribute to trans-repression initiated by direct interactions between GR and NGFI-B. Loss of Brg1 or HDAC2 should therefore produce Gc resistance, and we show that approximately 50% of Gc-resistant human and dog corticotroph adenomas, which are the hallmark of Cushing disease, are deficient in nuclear expression of either protein. In addition to providing a molecular basis for Gc resistance, these deficiencies may also contribute to the tumorigenic process.

Inhibition of the MtTF4 tumor growth by dexamethasone

It is known that estradiol, but not progesterone or dihydrotestosterone, slows down the growth of the MtTF4 tumor. In the present paper, it is shown that: (1) this tumor contains glucocorticoid receptors, (2) its growth is also inhibited by treatment with dexamethasone (Dex), and (3) the growth rate of a cell line and several clones established from the tumor is negatively controlled by Dex 10(-7) M in culture medium containing 10% gelding serum. Unlike estradiol, Dex does not induce cell hypertrophy. This work suggests that the inhibition of the MtTF4 tumor growth by Dex may be due in part to a direct action on tumor cells and, taking into consideration previous reports, it allows us to forward the hypothesis that both Dex and estradiol inhibit MtTF4 tumor growth in two different ways.

CRF and cAMP regulation of POMC gene expression in corticotrophic tumor cells

The effects of corticotropin releasing factor (CRF) on pro-opiomelanocortin (POMC) gene expression were investigated in an anterior pituitary corticotrophic tumor cell line, AtT-20/D16-16. The results of mRNA dot blot hybridization assays suggested that CRF, at a concentration of 10(-7) M, positively regulates the expression of the POMC gene in AtT-20 cells in a concentration-dependent fashion. Evaluation of the time course of this effect indicated that CRF had a biphasic mode of action. CRF and alpha-amanitin (inhibitor of RNA polymerase II activity) were also found to affect POMC mRNA levels in a concentration-dependent fashion. Eight-bromo-cyclic adenosine monophosphate (8-Br-cAMP) produced biphasic effects on POMC mRNA levels, supporting evidence of a role for cAMP as a second messenger in the regulation of POMC gene expression. It was also found that alpha-amanitin negatively regulated basal and CRF-stimulated POMC mRNA levels at both the 2 hr and 24 hr time periods, supporting evidence for positive regulation of POMC by CRF at the transcriptional level.

Interactions of glucocorticoids with the AtT-20 cell: effect on protein accumulation

In order to investigate the mechanism through which glucocorticoids downregulate the number of their own receptors in the AtT-20 cell, the effect of glucocorticoids on cell protein metabolism was studied. Glucocorticoids were found to inhibit cellular protein accumulation when included in long-term cultures. The concentrations of agonists that cause a mid-maximal effect are similar to those needed to half-saturate the glucocorticoid receptor, suggesting that the growth-inhibiting effect is receptor-mediated. Two-dimensional electrophoresis of cytosolic extracts of treated and control cells suggested that the effect reflected a general suppression of overall protein accumulation rather than a selective effect on certain classes. Comparison of the protein to DNA ratio of control and dexamethasone-treated cells showed that the latter have higher ratios suggesting that cell composition may be altered by agonists. However, time-course studies of this effect indicated that this is basically an expression of a glucocorticoid effect on cell growth rather than a selective effect on protein metabolism. It is concluded that glucocorticoids inhibit overall AtT-20 cell growth and that this, in turn, manifests itself as a decrease in the rate of protein accumulation. It is suggested that this change in protein metabolism may be a minor component in the mechanism through which glucocorticoids decrease AtT-20 cell ACTH secretion and glucocorticoid receptor number.