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© The Rockefeller University Press,
0021-9525/2000//1199 $5.00
The Journal of Cell Biology, Volume 150, Number 5,
, 2000 1199-1208
Report |
Glucocorticoids Antagonize Ap-1 by Inhibiting the Activation/Phosphorylation of Jnk without Affecting Its Subcellular Distribution
amunoz{at}iib.uam.es
The immunosuppressive and antiinflammatory actions of glucocorticoid hormones are mediated by their transrepression of activating protein-1 (AP-1) and nuclear factor-kappa B (NF
B) transcription factors. Inhibition of the c-Jun NH2-terminal kinase (JNK) signaling pathway, the main mediator of AP-1 activation, has been described in extracts of hormone-treated cells. Here, we show by confocal laser microscopy, enzymatic assays, and immunoblotting that the synthetic glucocorticoid dexamethasone inhibited tumor necrosis factor 
(TNF-)–induced phosphorylation and activation of JNK in the cytoplasm and nucleus of intact HeLa cells. As a result, c-Jun NH2-terminal domain phosphorylation and induction were impaired. Dexamethasone did not block the TNF-–induced JNK nuclear translocation, but rather induced, per se, nuclear accumulation of the enzyme. Consistently with previous findings, a glucocorticoid receptor mutant (GRdim), which is deficient in dimerization, DNA binding, and transactivation, but retains AP-1 transrepressing activity, was as efficient as wild-type GR in mediating the same effects of dexamethasone on JNK in transfected Cos-7 cells. Our results show that glucocorticoids antagonize the TNF-–induced activation of AP-1 by causing the accumulation of inactive JNK without affecting its subcellular distribution.
Key Words: dexamethasone • activating protein-1 • tumor necrosis factor • c-Jun NH2-terminal kinase • nuclear translocation
© 2000 The Rockefeller University Press
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Introduction |
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B) transcription factors. There is evidence that the immunosuppressive and antiinflammatory actions of glucocorticoid hormones are mediated by their transrepression of AP-1 and NFB (Vayssière et al. 1997; Göttlicher et al. 1998; Karin 1998; Resche-Rigon and Gronemeyer 1998). Transrepression of AP-1 is also a key feature of the antitumor activity of glucocorticoids in mouse skin (Tuckermann et al. 1999). This is emphasized by the finding that, in contrast to glucocorticoid receptor (GR–/–) animals, GRdim mutant mice expressing a mutant hormone receptor (GRdim) that is deficient in dimerization, DNA binding, and transactivation, but retains AP-1 transrepressing activity, are viable (Reichardt et al. 1998). In addition, GRdim mediates repression of AP-1-dependent genes in mouse skin (Tuckermann et al. 1999). Moreover, defective AP-1 repression may explain resistance to the antiinflammatory effect of glucocorticoids in asthma patients (Adcock et al. 1995).
AP-1 is a group of dimeric factors constituted by members of the c-Jun and c-Fos families of protooncogenic products (Karin et al. 1997). AP-1 is activated by mitogens, oncoproteins, proinflammatory cytokines, such as tumor necrosis factor (TNF-) and interleukin-1, and ultraviolet radiation. c-Jun, the main component of AP-1, is activated by NH2-terminal phosphorylation on serines 63 and 73 (Ser63/73) by members of the c-Jun NH2-terminal Kinase (JNK) family (Minden and Karin 1997). Interactions between hormone-activated receptors and AP-1, competition for limiting amounts of common transcriptional coactivators, such as cAMP response element-binding protein (CREB)-binding protein (CBP), or binding to DNA have been proposed to explain the mutual antagonism between hormones acting through nuclear receptors and AP-1 (for a review see Göttlicher et al. 1998). In addition, we and others have recently described the inhibition of the JNK signaling pathway, and hence of c-Jun phosphorylation and AP-1 activation, in extracts of hormone-treated cells (Caelles et al. 1997; Swantek et al. 1997; González et al. 1999; Lee et al. 1999; Srivastava et al. 1999; Ventura et al. 1999). Remarkably, the generation of transgenic mice harboring a mutant allele of c-Jun with Ser63/73 mutated to alanines has shown that NH2-terminal phosphorylation of c-Jun is critical for stress-induced apoptosis and cellular proliferation in vivo (Behrens et al. 1999).
To gain insight into the mechanism of AP-1 interference by hormone-activated nuclear receptors, we have addressed the following questions. Does the synthetic glucocorticoid dexamethasone (Dex) inhibit JNK phosphorylation/activation in intact cells? Can Dex affect nuclear translocation of JNK? And, what is the mechanism of hormone-activated GR and what is its primary target?
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Materials and Methods |
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(Caelles et al. 1997). After Dex pretreatment, TNF- (10 ng/ml) or its vehicle (ethanol) was added to the cells. Thus, TNF- + Dex cells were incubated with Dex for 45 min plus the indicated period of TNF- stimulation. Dex-alone control cells were incubated with hormone during the pretreatment and throughout for the period of stimulation.
Immunocytochemistry
HeLa and Cos7 cells were rinsed twice in PBS, fixed with 3.7% paraformaldehyde in PBS for 15 min at room temperature, permeabilized with 0.5% Triton X-100 for 15 min, and were then treated with 0.1 M glycine in PBS for 15 min. The nonspecific sites were blocked by incubation with PBS containing 1% BSA or goat serum for 30 min at room temperature. Cells were then washed in PBS containing 0.05% Tween-20 for 5 min and incubated with the primary antibodies diluted in PBS for 1 h at room temperature or overnight at 4°C.
The following primary antibodies were used: rabbit polyclonal or mouse monoclonal anti–c-Jun phosphorylated on serine-63 (New England Biolabs, Inc., 9261S; or Santa Cruz Biotechnology, Inc., sc-822), rabbit polyclonal anti–c-Jun (Oncogene Research, PC06), mouse monoclonal against human JNK1 (BD PharMingen, 15701A), mouse monoclonal anti-JNK1 phosphorylated on threonine-183 and tyrosine-185 (Santa Cruz Biotechnology, Inc., sc-6254), and rabbit polyclonal anti-GR (Santa Cruz Biotechnology, Inc., sc-1003). The cells were incubated for 45 min with one of the following secondary antibodies: Texas red (TxR)-conjugated goat anti–rabbit (Jackson ImmunoResearch or Vector), FITC-conjugated goat anti–rabbit (Jackson ImmunoResearch), and TxR-conjugated goat anti–mouse (Jackson ImmunoResearch). To amplify the phospho-JNK and JNK1 staining, anti-mouse Ig-digoxigenin, F(ab')2-fragment, followed by antidigoxigenin-rhodamine (Boehringer), or biotinylated anti-mouse, followed by streptavidin-rhodamine (Jackson ImmunoResearch), secondary antibodies were used. Double immunofluorescence with anti-GR and antiphospho-JNK or anti-JNK1 was performed on samples of Cos7 cells transfected with wild-type GR (GRwt) or GRdim.
Confocal Microscopy and Quantification
Confocal microscopy was performed with an MRC-1024 laser scanning microscope (BioRad), equipped with an Axiovert 100 invert microscope (ZEISS), and using excitation wavelengths of 488 nm (for FITC) and 543 nm (for TxR). To measure fluorescence intensity in cell cultures treated with TNF- or preincubated with Dex before TNF-, 30 cells without prior selection of each culture were analyzed by laser spectroscopy performed with the confocal microscope and using a Plan-Apochromat 63x/1.4 oil immersion objective. The selection of rectangular regions of interest in the nucleus, excluding nucleoli, the adjustment of the confocal settings (iris, gain, black level), the same for each cell series, and the quantification of fluorescence intensities on a grey scale (0–255) was performed following the procedure of Leclerc et al. 1998. After correcting nuclear (N) and cytoplasmic (C) fluorescence intensities for background, the nucleocytoplasmic ratio (R=N–CN+C) for the JNK signal was calculated as described (Leclerc et al. 1998). Data were analyzed by Microsoft Excel on a Macintosh computer.
Subcellular Fractionation
To prepare whole-cell extracts, the monolayers were washed twice in PBS and the cells were lysed by incubation in RIPA buffer (150 mM NaCl, 1.5 mM MgCl2, 10 mM NaF, 10% glycerol, 4 mM EDTA, 1% Triton X-100, 0.1% SDS, 1% deoxycholate, 50 mM Hepes, pH 7.4, plus PPIM [25 mM β-glycerophosphate, 1 mM Na3VO4, 1 mM PMSF, 10 µg/ml leupeptin, 10 µg/ml aprotinin]) for 15 min on ice followed by centrifugation at 13,000 rpm for 10 min at 4°C. For subcellular fractionation, cells were lysed in nuclear precipitation buffer (NPB: 10 mM Tris HCl, pH 7.4, 2 mM MgCl2, 140 mM NaCl, plus PPIM) supplemented with 0.1% Triton X-100 by incubating on ice for 10 min. The lysate was layered onto 50% wt/vol sucrose/NPB and centrifuged at 13,000 rpm for 10 min. Supernatants were taken as cytosolic fraction. Pellets (nuclei) were washed with NPB and extracted with Dignam C buffer (20 mM Hepes, pH 7.9, 25% glycerol, 0.42 M NaCl, 1.5 mM MgCl2, 0.2 mM EDTA, 1 mM DTT, plus PPIM) to obtain the nuclear fraction.
Immune Complex Kinase Assay
JNK was immunoprecipitated from each subcellular fraction using 0.4 µg of an anti-JNK antibody (sc-474 from Santa Cruz Biotechnology, Inc.). JNK activity in the immunocomplexes was assayed by incubation with 1 µg glutathione S–transferase–c-Jun1-79 (GST-c-Jun) as substrate in the presence of 20 µM cold ATP and 1 µCi of 
[32P]ATP as described (Caelles et al. 1997).
Western Blotting
JNK, phosphorylated JNK, and MEK-1 were detected in subcellular extracts by immunoblotting using the specific antibodies sc-474 (Santa Cruz Biotechnology, Inc.), V7931 (Promega), and sc-219 (Santa Cruz Biotechnology, Inc.), respectively. Histone H10 was detected using an mAb donated by Prof. A. Alonso (Deutches Krebsforschung Zentrum, Heidelberg). Western blots were performed and developed using the ECL detection system (Amersham Pharmacia Biotech) using either HRP-conjugated anti-rabbit (for anti-JNK, antiphospho-JNK, and anti-MEK-1) or HRP-conjugated anti-mouse (for antihistone H10) antibodies (ICN).
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Results |
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. No signal over background was found in cells treated with vehicle or Dex alone (Fig. 1 A, a and b). Upon TNF- treatment, an intense punctate staining against a more diffuse signal appeared throughout the nucleus (except the nucleoli), whereas the cytoplasm remained negative (Fig. 1 A, c). The increase in phospho-c-Jun induced by 30-min treatment with TNF- was efficiently inhibited in Dex-treated cells (Fig. 1 A, c and d). Dex reduced the level of nuclear phospho-c-Jun induced by TNF- in HeLa cells by 
60% (Fig. 1 B). Unstimulated vehicle- and Dex-treated cells showed a similar low nuclear staining when an antitotal c-Jun antibody was used (Fig. 1 C, a and b). Upon TNF- treatment, a strong nucleoplasmic immunolabeling was observed (Fig. 1 C, c). In agreement with previous data (Caelles et al. 1997), Dex also inhibited the increase in total c-Jun protein caused by the transcriptional activation of the c-jun gene in response to TNF- (Fig. 1 C, c and d). Computer-assisted quantification revealed a 40% inhibition in TNF- + Dex cells with respect to cells treated with TNF- alone (Fig. 1 D).
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–induced dual phosphorylation and subsequent activation of JNK and its concomitant translocation into the cell nucleus (Karin et al. 1997; Minden and Karin 1997). Therefore, we next examined whether the reduction in phospho-c-Jun levels could be due to the inhibition of JNK activity within the nucleus. Immunofluorescence analysis by confocal microscopy using a specific antiphospho-JNK antibody showed that Dex reduced the level of cytosolic (56%) and nuclear (71%) phospho-JNK induced by TNF- (Fig. 2A and Fig. B). This result was confirmed by immunoblotting analysis (Fig. 2 C). To check whether this effect of Dex correlated with a decrease in enzymatic activity in both cellular compartments, we measured JNK activity in cytosolic and nuclear fractions. In agreement with immunofluorescence and immunoblotting data, Dex pretreatment led to significant reductions in JNK activity in both cytosolic and nuclear fractions (Fig. 2 D), which were consistent with the lower levels of nuclear phospho-JNK (Fig. 2A and Fig. B). In turn, these data are consistent with the reduction of phospho-c-Jun in Dex-treated cells when stimulated with TNF- (Fig. 1 A). Verification that nuclear proteins did not leak into the cytosolic fractions during the fractionation process was obtained through subsequent hybridization of Western membranes to detect histone H10, which localizes exclusively in the nucleus. Conversely, MEK-1 was detected only in cytosolic fractions (Fig. 2 D).
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–induced Nuclear Accumulation of JNK induced the nuclear accumulation of the enzyme, which was unchanged by Dex treatment (Fig. 3 A, b and c). Using two distinct antibodies (anti-JNK1/JNK3 sc-474 and anti-JNK1 15701A), the same increase (five- to sixfold) in fluorescence was found in the nucleus of TNF-–treated cells, irrespective of Dex pretreatment (Fig. 3 A, right), whereas cytoplasmic fluorescence did not change significantly upon any treatment (not shown). Measurement of JNK translocation by immunoblotting of subcellular fractions revealed that JNK was predominantly cytosolic in unstimulated HeLa cells, and confirmed that TNF- induced a similar increase in nuclear JNK content, irrespective of pretreatment with Dex (Fig. 3 B). A large amount of JNK remained in the cytosol even in TNF-–treated cells. The lack of significant differences in cytosolic JNK can be explained by the fact that JNK is abundant in the cytosol (30-fold higher than in the nucleus in unstimulated cells) and therefore only a small fraction of cytosolic JNK is mobilized to the nucleus. The apparent discrepancy between the levels of extranuclear JNK content observed by immunoblotting and immunofluorescence may be explained by the fact that the image obtained by confocal microscopy corresponds to a cellular slice, whereas immunoblotting of subcellular fractions allows a more precise estimation of JNK content in each fraction as takes into account their total size. It should be kept in mind that a minor degree of protein leakage during cellular fractionation and/or differences in fluorescence signal due to variations in epitope accessibility and microenvironment cannot be ruled out. Dex alone also caused a slight, but reproducible, accumulation of JNK in the nucleus (Fig. 3 C). This effect was progressive and led to a 2–2.5-fold increase in nuclear JNK content (Fig. 3 D). To rule out the possibility that Dex could affect basal JNK activity by itself, we performed JNK assays in cytosolic and nuclear fractions of HeLa cells upon hormone addition. As expected, Dex did not induce JNK activity, but inhibited the activation of this enzyme by TNF- (Fig. 3 E). The inhibition was simultaneous in cytosol and nucleus, with kinetics compatible with that of nuclear entry of hormone-bound GR (Htun et al. 1996). These results show that Dex alone caused an accumulation of inactive JNK in the nucleus and that Dex treatment did not affect the subcellular distribution of JNK induced by TNF-.
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addition to control or Dex-treated HeLa cells (not shown). In addition, we examined whether Dex treatment affected the amount of Hsp70 that is bound to JNK. However, the highly unspecific binding of this protein (even to agarose beads) precluded this analysis. Next, we examined whether a mutant form of GR (GRdim; Heck et al. 1994), which is unable to homodimerize, fails to bind DNA, and cannot transactivate GR element (GRE)-dependent promoters, could mediate Dex-induced JNK inhibition. Upon hormone binding, GRdim was as efficient as GRwt in inhibiting JNK activity (Fig. 4 A). We also analyzed whether GRdim, like GRwt, accumulates in the nucleus after Dex treatment. Both ectopically-expressed GRwt and GRdim translocate into the nucleus of transfected Cos-7 cells upon Dex addition (Fig. 4 B). This result emphasizes the DNA-binding–independent activities of GRdim and the transcription-independent inhibition of the JNK pathway by Dex (Caelles et al. 1997). Furthermore, it supports the link between AP-1 transrepression and JNK inhibition, and demonstrates that monomeric hormone-bound GR can mediate this effect.
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–induced JNK phosphorylation as observed in HeLa cells. Measurement of fluorescence intensity showed a 73 and 74% inhibition of nuclear phospho-JNK in GRwt- and GRdim-transfected cells, respectively. Likewise, in both types of transfected cells, Dex inhibited the increase in phospho-c-Jun and total c-Jun (not shown). Also as in HeLa cells, the accumulation of total JNK in the nucleus was not inhibited, but even slightly increased, by the hormone in both GRwt- and GRdim-transfected Cos-7 cells (Fig. 5 B, b). In agreement with this, Dex did not change the nuclear translocation of JNK induced by TNF- (Fig. 5 B, c and d).
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Discussion |
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. Rather, Dex by itself can promote the nuclear entry of inactive JNK in noninduced cells. These results were observed in two cell types, HeLa and Cos-7, and extend previous observations that JNK activity was reduced in extracts from cells treated with glucocorticoids, retinoids, thyroid hormone, or estrogens (Caelles et al. 1997; Swantek et al. 1997; González et al. 1999; Lee et al. 1999; Srivastava et al. 1999; Ventura et al. 1999). Our results differ from those reported for extracellular-regulated kinase (ERK), which suggested that kinase phosphorylation was necessary to induce homodimerization and subsequent nuclear translocation (Khokhlatchev et al. 1998). Differences in the mechanism of translocation between ERK and JNK, or perhaps cell type-specific differences, are also suggested by the finding that JNK1 is translocated into the nucleus of rat heart cells during ischemia, but that activation only takes place after reperfusion (Mizukami et al. 1997). Our results indicate a process other than JNK nuclear translocation for repression by hormone-bound GR. We had previously shown that 45-min pretreatment with Dex is sufficient for maximum inhibition of JNK, whereas half-maximum effect is obtained with a hormone treatment of only 10 min, which is coincident with the half-time of nuclear translocation of GR (Caelles et al. 1997). In addition, a mutant transactivation-deficient GR (LS7; Schena et al. 1989; Helmberg et al. 1995) was found to mediate JNK repression (Caelles et al. 1997). However, GR-LS7 mutant has been reported to keep residual transactivating activity (Heck et al. 1997). The finding now that GRdim is as efficient as GRwt in mediating the effects of Dex indicates rapid inhibition of JNK phosphorylation even by monomeric DNA binding-deficient, Dex-bound GR, which inactivates the enzyme in both cytosol and nucleus. This result demonstrates that the rapid inhibition of JNK does not require transcriptional activation by Dex, and also reinforces the DNA-binding independent activities of GR.
The effects of Dex have at least two possible explanations: direct or indirect inhibition of JNK activation in the cytoplasm in response to stress, and the activation of putative phosphatase(s). The negative result of the coimmunoprecipitation approach do not rule out a direct interaction between JNK and activated GR. Likewise attempts to coimmunoprecipitate JNK and its substrate c-Jun have failed, probably due to the existence of transient and/or weak interaction (Minden and Karin 1997), JNK and GR might form unstable complexes that impede their coimmunoprecipitation by current protocols. Alternatively, they could interact indirectly through intermediate proteins in the frame of the large multiprotein signalosome/COP9 complexes where JNK may be associated (Wei et al. 1998; Seeger et al. 1998). However, the signalosome-directed c-Jun activation is independent of JNK (Naumann et al. 1999). Regarding the second possibility, retinoids have been reported to induce MKP-1 phosphatase accumulation in nonsmall cell lung cancer cells (Lee et al. 1999). However, we have not found MKP-1 induction by Dex in HeLa cells (Caelles et al. 1997) and, furthermore, its kinetics in lung cancer cells is clearly delayed with respect to the inhibition of JNK by Dex in our system. These results, however, do not rule out the involvement of other phosphatase(s). It also remains to be determined whether JNK itself or any upstream component of the pathway is the primary target of hormone-activated GR. However, several studies suggest that Dex does not inhibit the immediate upstream kinases MEKK or SEK-1 (Caelles et al. 1997; Swantek et al. 1997; Lee et al. 1999).
Known JNK targets are mainly nuclear, such as c-Jun, ATF-2, Elk-1, and p53 (Karin et al. 1997; Minden and Karin 1997; Fuchs et al. 1998). Only NFAT4 has been proposed to be phosphorylated by JNK in the cytosol (Chow et al. 1997). However, the presence of high levels of active enzyme in the cytosol of stimulated cells suggests there may be other, unidentified substrates in this compartment. The inhibition of JNK activity by Dex in cytosol and nucleus also indicates the attenuation of stress-activated cytosolic pathways.
In two-hybrid experiments in yeast and in vitro, May et al. 1998 reported that the interaction between JNK and c-Jun does not require JNK catalytic activity. Interestingly, a regulated inhibitory domain in the NH2-terminal region (
domain) of c-Jun binding a putative inhibitor that could block its activation by JNK has been predicted (Baichwal and Tjian 1990). The finding that JNK binds the domain in resting cells led to the hypothesis that JNK itself could be a form of this inhibitor (Dai et al. 1995). Our results show that Dex inhibits c-Jun phosphorylation and activation without affecting the accumulation of JNK in the nucleus. Therefore, though a direct JNK-c-Jun interaction in Dex-treated cells has not been found, our data support the hypothesis that inactive JNK may behave as a inhibitor, thus preventing AP-1 activation. JNK activation is believed to contribute to inflammatory responses (Ip and Davis 1998), which, together with the recent finding that c-Jun phosphorylation is critical for stress-induced apoptosis and cellular proliferation in vivo (Behrens et al. 1999), and the implication of JNK in the control of p53 stability (Fuchs et al. 1998), suggests an important physiological role of JNK inhibition by glucocorticoids.
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Acknowledgments |
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M.V. González and J.M. González-Sancho were supported by postdoctoral fellowships from the Comunidad Autónoma de Madrid. This work was supported by grants from the Plan Nacional de Investigación y Desarrollo (SAF98-0060, 1FD97-0281-CO2-01), Comisión Interministerial de Ciencia y Tecnología, and Plan General de Conocimiento (PM96-0035), Ministerio de Educación y Cultura of Spain.
Submitted: 7 October 1999
Revised: 7 July 2000
Accepted: 7 July 2000
María Victoria González and Benilde Jiménez contributed equally to this work.
, tumor necrosis factor-.
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References |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
|---|
Adcock I.M., Lane S.J., Brown C.R., Lee T.H. & Barnes P.J.. Abnormal glucocorticoid receptor-activator protein 1 interaction in steroid-resistant asthma, J. Exp. Med., 182, 1995, 1951–1958.
Baichwal V.R. & Tjian R.. Control of c-Jun activity by integration of a cell-specific inhibitor with regulatory domain differences between v- and c-Jun, Cell., 63, 1990, 815–825.[Medline]
Behrens A., Sibilia M. & Wagner E.F.. Amino-terminal phosphorylation of c-Jun regulates stress-induced apoptosis and cellular proliferation, Nat. Genet, 21, 1999, 326–329.[Medline]
Caelles C., González-Sancho J.M. & Muñoz A.. Nuclear hormone receptor antagonism with AP-1 by inhibition of the JNK pathway, Genes Dev, 11, 1997, 3351–3364.
Chow C.W., Rincón M., Cavanagh J., Dickens M. & Davis R.J.. Nuclear accumulation of NFAT4 opposed by the JNK signal transduction pathway, Science, 278, 1997, 1638–1641.
Dai T., Rubie E., Franklin C.C., Kraft A., Gillespie D.A., Avruch J., Kyriakis J.M. & Woodgett J.R.. Stress-activated protein kinases bind directly to the domain of c-Jun in resting cellsimplications for repression of c-Jun function, Oncogene., 10, 1995, 849–855.[Medline]
Fuchs S.Y., Adler V., Buschmann T., Yin Z., Wu X., Jones S.N. & Ronai Z.. JNK targets p53 ubiquitination and degradation in nonstressed cells, Genes Dev, 12, 1998, 2658–2663.
Gabai V.L., Meriin A.B., Mosser D.D., Caron A.W., Rits S., Shifrin V.I. & Sherman M.Y.. Hsp70 prevents activation of stress kinases, J. Biol. Chem., 272, 1997, 18033–18037.
González M.V., González-Sancho J.M., Caelles C., Muñoz A. & Jiménez B.. Hormone-activated nuclear receptors inhibit the stimulation of the JNK and ERK signalling pathways in endothelial cells, FEBS Lett, 459, 1999, 272–276.[Medline]
Göttlicher M., Heck S. & Herrlich P.. Transcriptional cross-talk, the second mode of steroid hormone receptor action, J. Mol. Med, 76, 1998, 480–489.[Medline]
Heck S., Kullmann M., Gast A., Ponta H., Rahmsdorf H.J., Herrlich P. & Cato A.C.. A distinct modulating domain in glucocorticoid receptor monomers in the repression of activity of the transcription factor AP-1, EMBO (Eur. Mol. Biol. Organ.) J., 13, 1994, 4087–4095.[Medline]
Heck S., Blender K., Kullmann M., Göttlicher M., Herrlich P. & Cato A.C.. IB-independent downregulation of NF-B activity by glucocorticoid receptor, EMBO (Eur. Mol. Biol. Organ.) J, 16, 1997, 4698–4707.[Medline]
Helmberg A., Auphan N., Caelles C. & Karin M.. Glucocorticoid-induced apoptosis of human leukemic cells is caused by the repressive function of the glucocorticoid receptor, EMBO (Eur. Mol. Biol. Organ.) J, 14, 1995, 452–460.[Medline]
Htun H., Barsony J., Renyi I., Gould D.L. & Hager G.L.. Visualization of glucocorticoid receptor translocation and intranuclear organization in living cells with a green fluorescent protein chimera, Proc. Natl. Acad. Sci. USA, 93, 1996, 4845–4850.
Ip Y.T. & Davis R.J.. Signal transduction by the c-Jun N-terminal kinase (JNK)-from inflammation to development, Curr. Opin. Cell. Biol, 10, 1998, 205–219.[Medline]
Karin M.. New twists in gene regulation by glucocorticoid receptoris DNA binding dispensable?, Cell, 93, 1998, 487–490.[Medline]
Karin M., Liu Z. & Zandi E.. AP-1 function and regulation, Curr. Opin. Cell. Biol, 9, 1997, 240–246.[Medline]
Khokhlatchev A.V., Canagarajah B., Wilsbacher J., Robinson M., Atkinson M., Goldsmith E. & Cobb M.H.. Phosphorylation of the MAP kinase ERK2 promotes its homodimerization and nuclear translocation, Cell, 93, 1998, 605–615.[Medline]
Leclerc P., Jibard N., Meng X., Schweizer-Groyer G., Fortin D., Rajkowski K., Kang K., Catelli M.G., Baulieu E.E. & Cadepond F.. Quantification of the nucleocytoplasmic distribution of wild type and modified proteins using confocal microscopyinteraction between 90-kDa heat shock protein (Hsp90) and glucocorticoid receptor (GR), Exp. Cell. Res., 242, 1998, 255–264.[Medline]
Lee H.Y., Sueoka N., Hong W.K., Mangelsdorf D.J., Claret F.X. & Kurie J.M.. All-trans-retinoic acid inhibits Jun N-terminal kinase by increasing dual-specificity phosphatase activity, Mol. Cell. Biol., 19, 1999, 1973–1980.
May G.H.W., Allen K.E., Clark W., Funk M. & Gillespie D.A.F.. Analysis of the interaction between c-Jun and c-Jun N-terminal kinase in vivo, J. Biol. Chem., 273, 1998, 33429–33435.
Minden A. & Karin M.. Regulation and function of the JNK subgroup of MAP kinases, Biochim. Biophys. Acta, 1333, 1997, F85–F104.[Medline]
Mizukami Y., Yoshioka K., Morimoto S. & Yoshida K.. A novel mechanism of JNK1 activation, J. Biol. Chem, 272, 1997, 16657–16662.
Mosser D.D., Caron A.W., Bourget L., Denis-Larose C. & Massie B.. Role of human heat shock protein hsp70 in protection against stress-induced apoptosis, Mol. Cell. Biol, 17, 1997, 5317–5327.
Naumann M., Bech-Otschir D., Huang X., Ferrell K. & Dubiel W.. COP9 signalosome-directed c-Jun activation/stabilization in independent of JNK, J. Biol. Chem., 274, 1999, 35297–35300.
Reichardt H.M., Kaestner K.H., Tuckermann J., Kretz O., Wessely O., Bock R., Gass P., Schmid W., Herrlich P., Angel P. & Schutz G.. DNA binding of the glucocorticoid receptor is not essential for survival, Cell, 93, 1998, 531–541.[Medline]
Resche-Rigon M. & Gronemeyer H.. Therapeutic potential of selective modulators of nuclear receptor action, Curr. Opin. Chem. Biol, 2, 1998, 501–507.[Medline]
Schena M., Freedman L.P. & Yamamoto K.R.. Mutations in the glucocorticoid receptor zinc finger region that distinguish interdigitated DNA binding and transcriptional enhancement activities, Genes Dev, 3, 1989, 1590–1601.
Seeger M., Kraft R., Ferrell K., Bech-Otschir D., Dumdey R., Schade R., Gordon C., Naumann M. & Dubiel W.. A novel protein complex involved in signal transduction possessing similarities to 26S proteasome subunits, FASEB J, 12, 1998, 469–478.
Srivastava S., Weitzmann M.N., Cenci S., Ross F.P., Adler S. & Pacifici R.. Estrogen decreases TNF gene expression by blocking JNK activity and the resulting production of c-Jun and JunD, J. Clin. Invest., 104, 1999, 503–513.[Medline]
Swantek J.L., Cobb M.H. & Geppert T.D.. Jun N-terminal kinase/stress-activated protein kinase (JNK/SAPK) is required for lipopolysaccharide stimulation of tumor necrosis factor (TNF-) translationglucocorticoids inhibit TNF- translation by blocking JNK/SAPK, Mol. Cell. Biol, 272, 1997, 32056–32060.
Tuckermann J.P., Reichardt H.M., Arribas R., Richter K.H., Schütz G. & Angel P.. The DNA binding-independent function of the glucocorticoid receptor mediates repression of AP-1-dependent genes in skin, J. Cell Biol., 147, 1999, 1365–1370.
Vayssière B.M., Dupont S., Choquart A., Petit F., Garcia T., Marchandeau C., Gronemeyer H. & Resche-Rigon M.. Synthetic glucocorticoids that dissociate transactivation and AP-1 transrepression exhibit antiinflammatory activity in vivo, Mol. Endocrinol, 11, 1997, 1245–1255.
Ventura J.J., Roncero C., Fabregat I. & Benito M.. Glucocorticoid receptor down-regulates c-Jun amino terminal kinases induced by tumor necrosis factor in fetal rat hepatocyte primary cultures, Hepatology, 29, 1999, 849–857.[Medline]
Wei N., Tsuge T., Serino G., Dohmae N., Takio K., Matsui N. & Deng X-W.. The COP9 complex is conserved between plants and mammals and is related to the 26S proteasome regulatory complex, Curr. Biol., 8, 1998, 919–922.[Medline]
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