Overexpression of full-length human glucocorticoid receptor in Spodoptera frugiperda cells using the baculovirus expression vector system

We have expressed a full-length human glucocorticoid receptor (hGR) in Spodoptera frugiperda (Sf9) cells using the baculovirus expression vector system (BEVS). The level of expression is approximately 100-fold greater than in CEM-C7 cells. Between 0.5-1.0 mg hGR can be generated per liter of Sf9 cell culture. The expressed hGR is capable of binding glucocorticoids with specificity and high affinity. Covalent labeling with 3H-dexamethasone mesylate and Western blot analysis using a polyclonal antibody indicate that the molecular weight of the expressed protein is approximately 94 k. The nonactivated receptor sediments as a 8-9S complex in sucrose gradients and can be heat activated to a 4S form. The activated receptor is capable of retarding the migration of a 23 base-pair DNA fragment containing the glucocorticoid response element from the tyrosine aminotransferase gene. These data indicate that the expressed GR displays characteristics identical to those of GR from mammalian cells. By scaling up this culture we can, for the first time, obtain enough purified full-length receptor for crystallographic and functional studies which could provide new insight into exactly how hGR works.     

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.     

Glucocorticoid resistance

Glucocorticoids contribute fundame ntally to the maintenance of basal and stress-related homeostasis in all higher organisms. The major roles of these steroids in physiology are amply matched by their remarkable contributions to pathology. Glucocorticoid resistance is a rare familial, or sporadic condition characterized by partial end-organ insensitivity to glucocorticoids. The molecular basis of glucocorticoid resistance in several families and sporadic cases has been ascribed to mutations in the human glucocorticoid receptor α (hGRα) gene, which impair the ability of the receptor to transduce the glucocorticoid signal. Glucocorticoids are crucial for life, and therefore complete glucocorticoid resistance is uncommon. The purpose of this review is to discuss the many structural and functional features of the glucocorticoid receptor and also to evaluate the main clinical and laboratory characteristics of cortisol resistance. Published in Russian in Biokhimiyo, 2006, Vol. 71, No. 10, pp. 1328–1337.     

Stable overproduction of intact glucocorticoid receptors in mammalian cells using a selectable glucocorticoid responsive dihydrofolate reductase gene

We have generated several mammalian cell lines that stably express high levels of intact glucocorticoid receptor. These cells were created by cotransfecting a glucocorticoid-dependent dihydrofolate reductase (DHFR) gene into DHFR-deficient Chinese hamster ovary (CHO) cells together with a plasmid directing the expression of human glucocorticoid receptor. Using this approach, transfection frequencies indicate that the inclusion of glucocorticoid receptor cDNA increased the efficiency of DHFR transformation greater than 10-fold over nonreceptor control DNA. When a stably cotransfected line (designated MG/hGR) was subjected to short term growth in cytotoxic concentrations of the antifolate methotrexate, these cells strongly resisted growth inhibition when dexamethasone was present in the medium. This effect was steroid specific and was inhibited by the glucocorticoid antagonist RU38486. In an effort to exploit the methotrexate-induced coamplification properties of the DHFR gene as a means of creating cell lines having increased levels of glucocorticoid receptor, MG/hGR cells were chronically exposed to a relatively low concentration of methotrexate (50 nM). After this treatment a resistant line was isolated (MG/hGR/MTX50) that displayed complete dependence on exogenous glucocorticoid for growth. To investigate the molecular basis for the enhanced ability of MG/hGR/MTX50 cells to resist the cytotoxic effects of methotrexate in the presence of dexamethasone, glucocorticoid receptor protein in these cells was characterized and compared to parental CHO cells and methotrexate sensitive MG/hGR cells. Affinity labeling with [3H]dexamethasone mesylate and Western blot analysis with antiglucocorticoid receptor antiserum revealed that nontransfected CHO cells have virtually undetectable levels of glucocorticoid receptor protein whereas cotransfected MG/hGR cells contain at least 3 times more intact monomeric receptor protein of Mr 94,000. Correspondingly, analysis of receptor protein in MG/hGR/MTX50 cells indicated that these cells contain 8 to 10 times more glucocorticoid receptor than nontransfected CHO cells. Scatchard analysis of steroid binding curves revealed that these increases correspond to 6,600, 22,000 and 63,000 dexamethasone binding sites per cell for nontransfected CHO cells, cotransfected MG/hGR cells, and MG/hGR/MTX50 cells, respectively. Sedimentation profiles of native receptor in transfected and methotrexate-resistant cells further support the progressive increase in receptor content and demonstrate that glucocorticoid receptor exists in cotransfected cels as an oligomeric complex under hypotonic conditions (9S complex in the presence of 20 mM sodium molybdate, 7S in the absence of molybdate), which dissociates to a monomeric 4S species in the presence of 0.4 M KCl. These physicochemical properties are indistinguishable from those observed for the endogenous hamster glucocorticoid receptor and suggest that stably transfected human glucocort     

Evaluation of the role of ligand and thermal activation of specific DNA binding by in vitro synthesized human glucocorticoid receptor

We have used a DNA-binding/immunoprecipitation assay to analyze the capacity of human glucocorticoid receptor (hGR), generated in rabbit reticulocyte lysates, to bind DNA. In vitro translated hGR was indistinguishable from native hGR, as determined by migration on sodium dodecyl sulfate-polyacrylamide gels, sedimentation on sucrose density gradients, and reactivity with antipeptide antibodies generated against hGR. In addition, cell-free synthesized hGR was capable of specific binding to glucocorticoid response element (GRE)-containing DNA fragments. Using this assay system, we have evaluated the contributions of ligand binding and heat activation to DNA binding by these glucocorticoid receptors. In vitro translated hGR was capable of selective DNA binding even in the absence of glucocorticoid. Treatment with dexamethasone or the antiglucocorticoid RU486 had no additional effect on the DNA-binding capacity when receptor preparations were maintained at 0 C (no activation). In contrast, addition of either ligand or antagonist in combination with a heat activation step promoted DNA binding by approximately 3-fold over that of heat-activated unliganded receptors. Agonist (dexamethasone) was slightly more effective in supporting specific DNA binding than antagonist (RU486). DNA binding by in vitro synthesized GR was blocked by the addition of sodium molybdate to the receptor preparations before steroid addition and thermal activation. Addition of KCl resulted in less DNA binding either due to blockage of DNA-receptor complex formation or disruption of the complexes. The specificity of DNA binding by cell-free synthesized hGR was analyzed further by examining the abilities of various DNAs to compete for binding to a naturally occurring GRE found in the mouse mammary tumor virus-long terminal repeat. Oligonucleotides containing the consensus GRE were the most efficient competitors, and fragments containing regulatory sequences from glucocorticoid-repressible genes were somewhat competitive, whereas single stranded oligonucleotides were unable to compete for mouse mammary tumor virus-long terminal repeat DNA binding, except when competitor was present at extremely high concentrations. Together these studies indicate that hGR synthesized in rabbit reticulocyte lysates displays many of the same properties, including GRE-specific DNA binding, observed for glucocorticoid receptor present in cytosolic extracts of mammalian cells and tissues. Similarities between the effects of dexamethasone and RU486 suggest that the antiglucocorticoid properties of RU486 do not occur at the level of specific DNA binding.     

Glucocorticoid receptor expression in receptorless mutants isolated from the human leukemic cell line CEM-C7

The molecular basis for the loss of steroid binding activity in receptorless (r-) glucocorticoid-resistant (dexr) mutants isolated from the glucocorticoid-sensitive (dexs) cell line CEM-C7 was investigated. Although there was little binding of the reversibly associating ligand [3H]dexamethasone in r- mutants, labeling with the covalent affinity ligand [3H] dexamethasone 21-mesylate revealed significant amounts of a 92 kilodalton human glucocorticoid receptor (hGR) protein. Immunoblots of hGR protein in r- and normal cells showed that r- mutants expressed approximately half the amount of immunoreactive hGR protein seen in dexs cells. Comparison of the genomic organization of the hGR genes in normal and mutant cells revealed no discernable differences in the structure, or dosage, indicating that the r- phenotype was not the result of gross deletion or rearrangement of the hGR genes. In addition, r- cells expressed the same 7 kilobase mRNA as normal cells. More importantly, the amount of hGR mRNA expressed in r- cells was never significantly less, and in some cases was greater than, that seen in normal cells, indicating that the decrease in immunoreactive hGR protein seen in r- cells is not the result of loss of hGR mRNA expression. Taken together with the known mutation rate of the hGR gene(s) in these cells, these results suggest that the hGR genes in dexs CEM-C7 cells are allelic and that dexs cells express both a normal hGR protein and one with an altered steroid binding site. Furthermore, they suggest that the r- phenotype is acquired as the result of mutation within the coding region of the originally functional allele, leading to loss of ligand binding and expression of immunoreactive product.     

Hydrogen peroxide signaling is required for glucocorticoid-induced apoptosis in lymphoma cells

Glucocorticoid-induced apoptosis is exploited clinically for the treatment of hematologic malignancies. Determining the required molecular events for glucocorticoid-induced apoptosis will identify resistance mechanisms and suggest strategies for overcoming resistance. In this study, we found that glucocorticoid treatment of WEHI7.2 murine thymic lymphoma cells increased the steady-state [H(2)O(2)] and oxidized the intracellular redox environment before cytochrome c release. Removal of glucocorticoids after the H(2)O(2) increase resulted in a 30% clonogenicity; treatment with PEG-CAT increased clonogenicity to 65%. Human leukemia cell lines also showed increased H(2)O(2) in response to glucocorticoids and attenuated apoptosis after PEG-CAT treatment. WEHI7.2 cells that overexpress catalase (CAT2, CAT38) or were selected for resistance to H(2)O(2) (200R) removed enough of the H(2)O(2) generated by glucocorticoids to prevent oxidation of the intracellular redox environment. CAT2, CAT38, and 200R cells showed a 90-100% clonogenicity. The resistant cells maintained pERK survival signaling in response to glucocorticoids, whereas the sensitive cells did not. Treating the resistant cells with a MEK inhibitor sensitized them to glucocorticoids. These data indicate that: (1) an increase in H(2)O(2) is necessary for glucocorticoid-induced apoptosis in lymphoid cells, (2) increased H(2)O(2) removal causes glucocorticoid resistance, and (3) MEK inhibition can sensitize oxidative stress-resistant cells to glucocorticoids.     

Mutations in squirrel monkey glucocorticoid receptor impair nuclear translocation

To identify the determinants of impaired glucocorticoid receptor (GR) signaling in a model of glucocorticoid resistance, cloned GR from Guyanese squirrel monkeys (gsmGR) was tagged with enhanced green fluorescent protein, and nuclear translocation was examined in transfected COS1 cells. In keeping with evidence that gsmGR transactivational competence is impaired, we found that nuclear translocation is likewise diminished in gsmGR relative to human GR (hGR). Experiments with GR chimeras revealed that replacement of the gsmGR ligand binding domain (LBD) with that from hGR increased translocation. Truncated gsmGR constructs lacking the LDB after amino acid 552 also showed increased translocation even in the absence of cortisol. Three back-mutations of gsmGR to hGR (Thr551Ser, Ala616Ser, and Ser618Ala) in the LBD confirmed that these amino acids play a role in diminished translocation.     

Inhibition of ceramide synthesis ameliorates glucocorticoid-, saturated-fat-, and obesity-induced insulin resistance

Insulin resistance occurs in 20%-25% of the human population, and the condition is a chief component of type 2 diabetes mellitus and a risk factor for cardiovascular disease and certain forms of cancer. Herein, we demonstrate that the sphingolipid ceramide is a common molecular intermediate linking several different pathological metabolic stresses (i.e., glucocorticoids and saturated fats, but not unsaturated fats) to the induction of insulin resistance. Moreover, inhibition of ceramide synthesis markedly improves glucose tolerance and prevents the onset of frank diabetes in obese rodents. Collectively, these data have two important implications. First, they indicate that different fatty acids induce insulin resistance by distinct mechanisms discerned by their reliance on sphingolipid synthesis. Second, they identify enzymes required for ceramide synthesis as therapeutic targets for combating insulin resistance caused by nutrient excess or glucocorticoid therapy.