Deborah L. Bellingham scite author profile

We have synthesized two peptides that correspond to unique regions of the amino-terminus of the human glucocorticoid receptor (GR). Peptides representing amino acids 245-259 and 346-367 (designated 59 and 57, respectively) were chosen on the basis of hydrophobicity/hydrophilicity ratios as well as overall proline content. These peptides were then used as antigens to produce epitope-specific antibodies that recognize and interact with human GR in a variety of physical states. Antiserum directed against each peptide recognizes denatured, [3H] dexamethasone mesylate-labeled GR as well as unliganded receptor on Western blots. In contrast to other antipeptide GR antibodies, these antibodies recognize and form stable complexes with unactivated and molybdate-stabilized forms of the GR, indicating that neither epitope is occluded when the receptor exists in an oligomeric state. Activated, 4S DNA-binding forms of the receptor are also recognized by both antibodies. The interaction of antibodies 59 and 57 with human GR in various states is highly specific based on the observation that preincubation of either antiserum with the appropriate peptide completely precludes the recognition of receptor by antibody. Titration analysis of antisera reveals that an increase in the antibody concentration cause discrete increases in the sedimentation coefficient of GR on sucrose gradients. These shifts occur under high salt conditions and are consistent with the formation of multiple stable antibody-receptor complexes. Interestingly, neither antibody interferes with the ability of the GR to be activated into a DNA-binding form or with the ability of the activated GR to interact with DNA cellulose. Consistent with these observations, both antibodies recognize and form stable complexes with GR when the receptor is associated with DNA fragments that contain specific glucocorticoid-responsive elements. Thus, both antibodies appear to recognize all known forms of the human GR protein. Using immunohistochemical techniques to visualize GR in HeLa S3 cells as well as in Chinese hamster ovary cells that stably express transfected human GR, a cytoplasmic location for receptor is observed in the absence of ligand. In contrast, immunoreactive GR is predominantly nuclear after hormone treatment, further supporting a role for nuclear translocation in GR function.

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Ligand-dependent down-regulation of stably transfected human glucocorticoid receptors is associated with the loss of functional glucocorticoid responsiveness

Bellingham¹

1992

Molecular Endocrinology

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The effect of glucocorticoids on the regulation of stably transfected human glucocorticoid receptors has been examined. Exposure of a Chinese hamster ovary-derived cell line containing stably transfected human glucocorticoid receptor genes and glucocorticoid-responsive dihydrofolate reductase genes to 5 nM dexamethasone resulted in a rapid, time-dependent reduction in the level of glucocorticoid receptor protein to 50% of control levels within 5 h of steroid treatment. This decrease in receptor protein was persistent, with a maximal 70% reduction observed even after 4 weeks of dexamethasone treatment. Immunocytochemical analysis of the influence of dexamethasone on stably transfected glucocorticoid receptors revealed efficient translocation of receptors to the nucleus within 1 h of hormone treatment. However, upon longer exposure to dexamethasone (5 h), immunoreactive glucocorticoid receptors were localized primarily to the cytoplasm. By 24 h of treatment, glucocorticoid receptors were absent from the cytoplasm and the nucleus, suggesting that the ligand-induced loss of glucocorticoid receptors may be a cytoplasmic event. The decrease in transfected glucocorticoid receptor protein was largely reflected by similar changes in steady state levels of human glucocorticoid receptor mRNA; however, the effects of hormone on receptor protein levels were more profound than on receptor mRNA. There was an initial rapid reduction in transfected glucocorticoid receptor mRNA to 50% of control levels within 2 h of dexamethasone treatment. This reduction was followed by a transient rise in mRNA expression after 12 h of hormone treatment. With prolonged exposure to dexamethasone (> 12 h) a second, more gradual decline in human glucocorticoid receptor mRNA was observed. This biphasic pattern of glucocorticoid receptor gene expression was not reflected at the level of receptor protein, suggesting that both transcriptional and translational control mechanisms may be involved in ligand-dependent receptor regulation. When cells were removed from dexamethasone after up to 48 h of treatment, glucocorticoid receptor mRNA levels fully recovered within 12 h. Receptor protein recovered only partially during this same time period. Down-regulation of glucocorticoid receptor protein and mRNA levels by dexamethasone in stably transfected cells led to corresponding reductions in the hormone sensitivity to two glucocorticoid-regulated genes: a transiently transfected chloramphenicol acetyltransferase receptor gene and a stably integrated dihydrofolate reductase gene. These results demonstrate that stably transfected human glucocorticoid receptors are subject to ligand-induced down-regulation in a heterologous cell line. Moreover, glucocorticoid receptor autoregulation appears to be a highly conserved mechanism for attenuating cellular responsiveness to hormone.

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Tissue-type plasminogen activator-induced invasion and metastasis of murine melanomas

Alizadeh

¹

,

Ma

²

,

Berman

³

et al. 1995

Current Eye Research

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The role of tissue-type plasminogen activator (tPA) in the 'spontaneous' as well as 'experimental' metastasis of ocular melanomas in mice was evaluated by transfecting the D5.1G4 murine melanoma cell line that possesses low metastatic activity and low tPA activity with a full length cDNA encoding human tPA. For comparison, a highly metastatic melanoma cell line (Queen's) that constitutively expresses high tPA production, was transfected with a cDNA coding for human plasminogen activator inhibitor type 1 (PAI-1). Unlike non-transfected controls, transfected D5.1G4 melanoma cells expressed high levels of tPA and produced extensive pulmonary metastases following intravenous injection. By contrast, PAI-1 transfected Queen's melanoma cells expressed low tPA activity and displayed significantly reduced metastatic potential compared with nontransfected controls. Moreover, PAI-1 transfected Queen's melanoma cells did not metastasize from the eye while nontransfected parental cells produced extensive spontaneous metastases. Expression of tPA activity in transfected and nontransfected cell lines was completely blocked by an anti-tPA antibody. This antibody significantly inhibited the organ localization and frequency of lung metastases of both Queen's and tPA-transfected D5.1G4 melanomas. This study demonstrates that tPA is involved in the metastasis of murine intraocular melanomas.

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Ligand-dependent down-regulation of stably transfected human glucocorticoid receptors is associated with the loss of functional glucocorticoid responsiveness.

Bellingham¹,

Sar²,

Cidlowski³

1992

Molecular Endocrinology

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The effect of glucocorticoids on the regulation of stably transfected human glucocorticoid receptors has been examined. Exposure of a Chinese hamster ovary-derived cell line containing stably transfected human glucocorticoid receptor genes and glucocorticoid-responsive dihydrofolate reductase genes to 5 nM dexamethasone resulted in a rapid, time-dependent reduction in the level of glucocorticoid receptor protein to 50% of control levels within 5 h of steroid treatment. This decrease in receptor protein was persistent, with a maximal 70% reduction observed even after 4 weeks of dexamethasone treatment. Immunocytochemical analysis of the influence of dexamethasone on stably transfected glucocorticoid receptors revealed efficient translocation of receptors to the nucleus within 1 h of hormone treatment. However, upon longer exposure to dexamethasone (5 h), immunoreactive glucocorticoid receptors were localized primarily to the cytoplasm. By 24 h of treatment, glucocorticoid receptors were absent from the cytoplasm and the nucleus, suggesting that the ligand-induced loss of glucocorticoid receptors may be a cytoplasmic event. The decrease in transfected glucocorticoid receptor protein was largely reflected by similar changes in steady state levels of human glucocorticoid receptor mRNA; however, the effects of hormone on receptor protein levels were more profound than on receptor mRNA. There was an initial rapid reduction in transfected glucocorticoid receptor mRNA to 50% of control levels within 2 h of dexamethasone treatment. This reduction was followed by a transient rise in mRNA expression after 12 h of hormone treatment. With prolonged exposure to dexamethasone (> 12 h) a second, more gradual decline in human glucocorticoid receptor mRNA was observed. This biphasic pattern of glucocorticoid receptor gene expression was not reflected at the level of receptor protein, suggesting that both transcriptional and translational control mechanisms may be involved in ligand-dependent receptor regulation. When cells were removed from dexamethasone after up to 48 h of treatment, glucocorticoid receptor mRNA levels fully recovered within 12 h. Receptor protein recovered only partially during this same time period. Down-regulation of glucocorticoid receptor protein and mRNA levels by dexamethasone in stably transfected cells led to corresponding reductions in the hormone sensitivity to two glucocorticoid-regulated genes: a transiently transfected chloramphenicol acetyltransferase receptor gene and a stably integrated dihydrofolate reductase gene. These results demonstrate that stably transfected human glucocorticoid receptors are subject to ligand-induced down-regulation in a heterologous cell line. Moreover, glucocorticoid receptor autoregulation appears to be a highly conserved mechanism for attenuating cellular responsiveness to hormone.

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