Complex human glucocorticoid receptor dim mutations define glucocorticoid induced apoptotic resistance in bone cells

A mutation in the D-loop of the second zinc finger of the DNA-binding domain of the human glucocorticoid receptor (hGR), A458T (GR(dim)), has been suggested to be essential for dimerization and DNA binding of the GR, and genetically altered GR(dim) mice survive, whereas murine GR knockout mice die. Interestingly, thymocytes isolated from the GR(dim) mice were reported to be resistant to glucocorticoid-induced apoptosis. To further evaluate the dim mutations in glucocorticoid-induced apoptosis, we stably expressed either the hGR(dim) (A458T) or the hGR(dim4) (A458T, R460D, D462C, and N454D) mutant receptors in human osteosarcoma (U-2 OS) cells that are devoid of hGR and unresponsive to glucocorticoids. We analyzed these cell lines by comparison with a stable expression hGRα U-2 OS cell line, which undergoes apoptosis after glucocorticoid treatment. Transient reporter gene assays with glucocorticoid response element-driven vectors revealed that the hGR(dim) mutation had diminished steroid responsiveness and cells carrying the hGR(dim4) mutation were unresponsive to steroid, whereas glucocorticoid-induced nuclear factor κB repression was unaffected by either mutation. Interestingly, both the hGR(dim) and hGR(dim4) receptors readily formed dimers as measured by immunoprecipitation. Examination of GR-mediated apoptosis showed that hGR(dim) cells were only partially resistant to apoptosis, whereas hGR(dim4) cells were completely resistant to glucocorticoid-induced cell death despite remaining sensitive to other apoptotic stimuli. Global gene expression analysis revealed that hGR(dim4) cells widely regulated gene expression but differentially regulated apoptotic mRNA when compared with cells expressing wild-type hGRα. These studies challenge conclusions drawn from previous studies of GR dim mutants.     

Dexamethasone-induced inositol 1,4,5-trisphosphate receptor elevation in murine lymphoma cells is not required for dexamethasone-mediated calcium elevation and apoptosis

Glucocorticosteroid hormones, including dexamethasone, have diverse effects on immature lymphocyte function that ultimately lead to cell death. Previous studies established that glucocorticoid-induced alterations in intracellular calcium homeostasis promote apoptosis, but the mechanism by which glucocorticoids disrupt calcium homeostasis is unknown. Through gene expression array analysis, we found that dexamethasone induces a striking elevation of inositol 1,4,5-trisphosphate receptor (IP(3)R) levels in two murine lymphoma cell lines, WEHI7.2 and S49.A2. IP(3)R elevation was confirmed at both mRNA and protein levels. However, there was not a strong correlation between IP(3)R elevation and altered calcium homeostasis in terms of either kinetics or dose response. Moreover, IP(3)R knockdown, by either antisense or small interfering RNA, did not prevent either calcium disruption or apoptosis. Finally, DT40 lymphoma cells lacking all three IP(3)R isoforms were just as sensitive to dexamethasone-induced apoptosis as wild-type DT40 cells expressing all three IP(3)R isoforms. Thus, although alterations in intracellular calcium homeostasis contribute to glucocorticoid-induced apoptosis, these calcium alterations are not directly attributable to IP(3)R elevation.     

Glucocorticoid receptor heterozygosity combined with lack of receptor auto-induction causes glucocorticoid resistance in Jurkat acute lymphoblastic leukemia cells

Glucocorticoids (GC) induce apoptosis in malignant lymphoblasts, but the mechanism of this process as well as that of the clinically important GC resistance is unknown. We investigated GC resistance in Jurkat T-ALL cells in which ectopic GC receptor (GR) restores GC sensitivity, suggesting deficient GR expression. Jurkat cells expressed one wild-type and one mutated (R477H) GR allele. GR(R477H) ligand-binding-dependent nuclear import, as revealed by live-cell microscopy of YFP-tagged GR, was unaffected. Transactivation and transrepression were markedly impaired; however, GR(R477H) did not act in a dominant-negative manner, that is, did not prevent cell death, when introduced into a GC-sensitive cell line by retroviral gene transfer. Contrary to another GR heterozygous, but GC-sensitive, T-ALL model (CCRF-CEM), Jurkats expressed lower basal GR levels and did not auto-induce their GR, as revealed by 'real-time' RT-PCR and immunoblotting. Absent GR auto-induction could not be restored by transgenic GR and, hence, was not caused by reduced basal GR levels. Thus, inactivation of one GR gene results in haploinsufficiency if associated with lack of GR auto-induction.     

Analysis of glucocorticoid unresponsive cell variants using a mouse glucocorticoid receptor complementary DNA clone

We have used a glucocorticoid receptor cDNA isolated from a mouse lymphoma cell line to characterize receptor mRNA and genomic sequences present in wild type and mutant rat hepatoma (HTC) and mouse thymoma (S49 and WEHI7) cells. Wild type rat and mouse cell lines contain two receptor mRNAs, 5 and 7 kilobase pairs (kb) in length, which differ in the length of their 3'-untranslated regions. Levels of receptor mRNA present in mutant HTC, WEHI7, and S49 cells of the r- (receptorless) phenotype are decreased compared to wild type cells. This decreased level of receptor mRNA parallels the decreased level of total immunoreactive receptor protein found in these cells. S49 nt- (nuclear transfer minus) cells contain receptor mRNA levels which parallel their hormone binding and immunoreactive receptor levels. Cells of the r- and nt- phenotype contain no detectable deletions or rearrangements of the receptor gene. We conclude that r- cells have lesions which affect the expression of receptor mRNA. Surprisingly, HTC cells of the r- phenotype differ from WEHI7 and S49 r- cells in that HTC r- cells contain a lower level of receptor DNA than does their parental wild type cell line. Although these cells may contain multiple lesions, it appears that loss of receptor genomic sequences is responsible, in part, for the phenotype of the HTC r- cells. The S49 nti (nuclear transfer increase) cells produce glucocorticoid receptors of molecular weights 40,000 and 94,000. These cells produce, in addition to the wild type 5- and 7-kb receptor mRNAs, two other receptor messages 5.5 and 3.5 kb in length. RNA blot analysis using various portions of our receptor cDNA indicates that these are 5' truncated messages and suggests that the 40-kDa nti receptor is truncated at its NH2-terminal end. These data also indicate that the hormone and DNA-binding regions of the receptor are located in the COOH-terminal half of the protein.     

Expression of the glucocorticoid receptor from the 1A promoter correlates with T lymphocyte sensitivity to glucocorticoid-induced cell death

Glucocorticoid (GC) hormones cause pronounced T cell apoptosis, particularly in immature thymic T cells. This is possibly due to tissue-specific regulation of the glucocorticoid receptor (GR) gene. In mice the GR gene is transcribed from five separate promoters designated: 1A, 1B, 1C, 1D, and 1E. Nearly all cells express GR from promoters 1B-1E, but the activity of the 1A promoter has only been reported in the whole thymus or lymphocyte cell lines. To directly assess the role of GR promoter use in sensitivity to glucocorticoid-induced cell death, we have compared the activity of the GR 1A promoter with GC sensitivity in different mouse lymphocyte populations. We report that GR 1A promoter activity is restricted to thymocyte and peripheral lymphocyte populations and the cortex of the brain. The relative level of expression of the 1A promoter to the 1B-1E promoters within a lymphocyte population was found to directly correlate with susceptibility to GC-induced cell death, with the extremely GC-sensitive CD4+CD8+ thymocytes having the highest levels of GR 1A promoter activity, and the relatively GC-resistant alphabetaTCR+CD24(int/low) thymocytes and peripheral T cells having the lowest levels. DNA sequencing of the mouse GR 1A promoter revealed a putative glucocorticoid-response element. Furthermore, GR 1A promoter use and GR protein levels were increased by GC treatment in thymocytes, but not in splenocytes. These data suggest that tissue-specific differences in GR promoter use determine T cell sensitivity to glucocorticoid-induced cell death.     

Characterization of selective glucocorticoid-dependent responses in a glucocorticoid-resistant smooth muscle tumor cell line

The DDT₁ MF2 smooth muscle cell line was derived from an estrogen/androgeninduced leiomyosarcoma arising in the hamster ductus deferens. Growth of this cell line is arrested in Go/G1 by treatment with glucocorticoids. To facilitate the study of the mechanism of glucocorticoid-induced cell growth arrest, a glucocorticoid-resistant variant cell line, DDT₁ MF2 GR1 (GR1), was developed by genetic selection. Growth of this mutant cell line is completely resistant to the inhibitory action of glucocorticoids. However, we now demonstrate that both primary and secondary glucocorticoid-induced events still exist in the GR1 cell line. By analyzing the expression and genetic pattern of glucocorticoid receptor, no detectable rearrangement of the glucocorticoid receptor gene was found although the expression of both mRNA and protein levels of the receptor were lower in the variant compared to wild-type cells. In addition, we found that the expression of two growth-associated genes, Ha-ras and transforming growth factor β1 (TGF-β1) are down-regulated by glucocorticoids in wild-type DDT₁ MF2 cells but not in GR1 cells. These results indicated that the function or activity of glucocorticoid receptor in the GR1 cells is not qualitatively altered. Our data suggest that a lower glucocorticoid receptor level is not the real cause or at least not the single cause for the GR1 cell's loss of sensitivity to the inhibitory action of glucocorticoid. Instead, we postulate the existence of a defect downstream of the primary site of action of glucocorticoid receptor complexes in GR1 cells. © 1993 Wiley-Liss, Inc.     

Disruption of glucocorticoid receptor exon 2 yields a ligand-responsive C-terminal fragment that regulates gene expression

Mice in which exon 2 of the glucocorticoid receptor (GR) has been disrupted [GR exon 2 knockout (GR2KO)] have been used as a model to study the requirement for this receptor in a number of biological systems. A recent report showed that these mice actually express a truncated ligand-binding GR fragment, prompting us to ask whether this mutation truly results in a glucocorticoid-insensitive phenotype. Based on cDNA microarray analysis of fetal thymocytes, we found that glucocorticoids were able to enhance or repress activation-induced gene expression in GR2KO and wild-type thymocytes to a similar degree. Moreover, although changes in gene expression induced by glucocorticoids alone were blunted, the expression of a substantial number of genes in GR2KO thymocytes was modulated by stimulation with glucocorticoids. Among these genes, as confirmed by quantitative real-time PCR, was the classic glucocorticoid-responsive gene glutamine synthetase as well as genes implicated in T cell development and function such as IL-7 receptor alpha-chain and glucocorticoid-induced leucine zipper (GIL2). Thus, the truncated C-terminal GR2KO product, which lacks the major transactivation domain, retains, to a large extent, the ability to regulate gene expression both positively and negatively in a ligand-responsive manner when expressed in vivo.