Abstract
The transcriptional activity of the glucocorticoid receptor (GR) is co-determined by its ability to recruit a vast and varying number of cofactors. We here identify Striatin-3 (STRN3) as a novel interaction partner of GR that interferes with GR’s ligand-dependent transactivation capacity. Remarkably, STRN3 selectively affects only GR-dependent transactivation and leaves GR-dependent transrepression mechanisms unhampered. We found that STRN3 down-regulates GR transactivation by an additional recruitment of the catalytic subunit of protein phosphatase 2A (PPP2CA) to GR. We hypothesize the existence of a functional trimeric complex in the nucleus, able to dephosphorylate GR at serine 211, a known marker for GR transactivation in a target gene-dependent manner. The presence of STRN3 appears an absolute prerequisite for PPP2CA to engage in a complex with GR. Herein, the C-terminal domain of GR is essential, reflecting ligand-dependency, yet other receptor parts are also needed to create additional contacts with STRN3.
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Introduction
Glucocorticoids (GC) exert effects at multiple levels of cellular functionality, including energy metabolism, cell fate and immune response. The majority of actions by hormonal GC ligands are mediated by the glucocorticoid receptor (GR), a transcription factor that can regulate gene expression in a positive or negative manner1, 2. To exert its gene regulatory effects, GR interacts, mainly via its ligand binding domain (LBD)3 with different proteins including other transcription factors, modifying enzymes, chromatin modulators, scaffold proteins, co-activators, co-repressors and co-chaperone proteins4.
GR-mediated gene promoter activation involves DNA binding of a homodimeric GR on a palindromic GC response element (GRE) in the promoter (simple GRE), from a coordinated DNA binding of a GR/transcription factor complex onto a so-called composite GRE or from a GR/transcription factor tethering mechanism. The latter two mechanisms can also form the basis for GR-mediated promoter repression5, 6. Recently, also a role for monomeric GR in direct target gene activation was discovered. More specifically, monomeric GR can bind to half sites and promote gene activation7. In an independent study using endogenous GCs, monomeric GR-binding to half-sites was found to be even more prevalent than homodimer binding, mediating transcription of tissue-specific target genes. In contrast, exogenous GC treatment induces GR dimer assembly to classic palindromic site-containing promoters of ligand-dependent genes. This event is at the expense of monomeric GR binding which vanishes from promoters of repressed genes8. These finding are important for the improvement of GR-based treatments. Among the widely studied anti-inflammatory actions of GCs is the GR-mediated repression of the activity of pro-inflammatory transcription factors such as NF-κB and AP1 via protein-protein interactions6. Although GCs are commonly used in the clinic for their potent anti-inflammatory properties, GCs are not always effective as a treatment due to the onset of glucocorticoid resistance (GCR); a phenomenon observed in many inflammatory conditions9.
GR’s post-translational modifications, such as phosphorylation, play a predominant role in determining and fine-tuning the receptor’s function10, 11. Accordingly, phosphorylated residues already described to influence the transcriptional activity of human GR are serine 203 (S203) and serine 211 (S211). Phosphorylated GR at S203 (pS203) is cytoplasmically contained and fails to bind GRE-dependent promoters, suggesting that GR pS203 is a transcriptionally inactive form of the GR. However, GR is transcriptionally more active when phosphorylated at S211, due to a conformational change, and an increased recruitment at GRE-containing promoters has been observed12.
By using the high-throughput mammalian protein-protein interaction trap (MAPPIT), we identified human Striatin-3 or alternatively S/G2 nuclear autoantigen (SG2NA) isoform alpha, STRN3α (hereafter referred to as STRN3) as a novel interaction partner of GR that negatively affects the GR-dependent transactivation pathway. STRN3 belongs to the striatin family of proteins, which consists of three members, namely Striatin, Striatin-3 and Zinedin, acting mainly as scaffold proteins13. The striatin family of proteins associates with kinases as well as phosphatases, including the major eukaryotic serine/threonine protein phosphatase 2 A (PP2A), forming the striatin-interacting phosphatase and kinase (STRIPAK) complex14, 15. STRN3 family members share a common protein structure consisting of four well-defined domains i.e. the caveolin-binding domain, the coiled-coil domain, the Ca2+-calmodulin-binding domain and the tryptophan-aspartate (WD)-repeat domain16 (Fig. 1A). Here, we found that the recruitment of STRN3 to GR indirectly suppresses GR transactivation, by allowing PPP2CA to be additionally recruited to facilitate GR dephosphorylation at S211. Our data thus support a role for STRN3 as an important check-point for GR functionality.
Results
STRN3 is a novel interaction partner of GR
Array MAPPIT17, a two-hybrid technology for the identification and analysis of protein-protein interactions in mammalian cells18,19,20 (Fig. 1B and C), was used to screen for interaction partners of GRα21 (hereafter referred to as GR). We identified Striatin-3 (STRN3) (Fig. 1A) as a novel specific interaction partner of GR (Fig. 1C). The interaction between STRN3 and GR was further enhanced upon activating the receptor with the synthetic GR agonist Dexamethasone (Dex) (Fig. 1C). Although the interaction was independently confirmed using co-immunoprecipitation analysis (Fig. 1D), the MAPPIT assay proved more sensitive in detecting a Dex ligand-enhanced interaction. To find out in which subcellular compartment endogenous GR and STRN3 reside, A549 cells were treated with solvent or DEX and subject to indirect immunofluorescence analysis (Fig. 2). In solvent-treated cells, GR was predominantly cytoplasmic, while STRN3 signal was present both in cytoplasm and nucleus. The subcellular distribution changed dramatically upon adding DEX for 2 h. Both GR and STRN3 displayed a predominantly nuclear phenotype, in support of a co-localization. To strengthen the hypothesis, the average Pearson correlation coefficients (PCC), indicative of a co-localization, of whole fields of 5 recorded images of at least 10 cells/field were determined as described by Dunn et al.22. PCC values range from 1 for two images of which fluorescence intensities are perfectly, linearly related, to −1 for two images of which fluorescence intensities are perfectly, but inversely, related to one another. The average Pearson correlation coefficient of the solvent control set-up for GR and STRN3 was 0.63 while the Pearson correlation coefficient of the DEX set-up for GR and STRN3 increased to a value of 0.90, indicating a linear relation between the signals for GR and STRN3. In conclusion, following DEX activation both proteins are most likely able to interact in the nucleus. In support of a cell type independent effect, similar data were obtained in HeLa cells, which have been reported to contain substantial amounts of endogenous STRN3 (Supplementary S1).
STRN3 is an inhibitor of the transactivation function of GR
To test the effect of STRN3 on GR-mediated transcription in mammalian cells, we used both over-expression and silencing approaches. First, a glucocorticoid response element (GRE)-dependent reporter gene construct was transfected in HEK293T cells, with an expression plasmid for GR since these cells endogenously do not contain functional GR23. Figure 3A demonstrates that STRN3 can inhibit the Dex-mediated transactivation capacity of GR. The last two control lanes show that STRN3 specifically affects GR-mediated gene expression and does not influence the activity of the reporter in the absence of over-expressed GR. Similar results were observed using HeLa cells, confirming that the effect of STRN3 is cell-type independent (Supplementary S2). To find out whether endogenous STRN3 modulates GR-mediated gene activation, we silenced endogenous STRN3 and monitored both GRE-dependent reporter gene activity (Fig. 3B and C) and endogenous GRE-dependent target genes (Fig. 3E). A549 cells were used, in which we previously optimized the silencing technology24 and which advantageously contain endogenous GR. STRN3 knockdown increased the Dex-mediated GRE-dependent reporter gene activity (Fig. 3B). Figure 3C represents the absolute counts of the luciferase activity of Figure 3B. Both Figure 3B and C show that STRN3 silencing does not cause a significant effect on GR basal activity in the absence of Dex. Figure 3D demonstrates an efficient knockdown of STRN3 of over 80%. In line herewith, the Dex-induced GRE-dependent mRNA expression of DUSP1, encoding MKP-1, PER1, ZFP and ECI2 (Fig. 3E), are also enhanced upon silencing of STRN3. Interestingly, the levels of ECI2 are enhanced in a statistical significant manner in the absence of Dex. We believe this result may reflect a promoter specific effect. Moreover, we could confirm the effect of STRN3 silencing on GR transactivation capacity by using a different STRN3 specific siRNA (Supplementary 3).
Activated GR also inhibits gene expression in a DNA-independent manner, via protein-protein interactions; a mechanism referred to as transrepression. To investigate whether endogenous STRN3 may influence transrepression, we studied the impact of STRN3 silencing on the ability of GR to block the activity of NF-κB, using a TNF-induced NF-κB-dependent reporter gene as read-out. Figure 3F demonstrates that STRN3 does not affect the NF-κB-targeting transrepression function of GR. Together; our results indicate that STRN3 may be a specific inhibitor of GR-mediated transactivation, but not transrepression.
STRN3 inhibits the transactivation function of other nuclear receptors
As STRN3 was previously described to reduce the activity of ERα25, we asked whether the observed effect of STRN3 was specific for the steroid receptor class of nuclear receptors, or else could be expanded to other nuclear receptor family members. Hereto, we compared the effect of STRN3 over-expression on progesterone-driven PR activity (Fig. 4A) and on GW647-driven PPARα activity (Fig. 4B), using their respective promoter elements coupled to luciferase reporters. In analogy with the results using GR, upon over-expression of STRN3 the ligand-mediated transactivation ability of both receptors is decreased. For PR, a decrease of 24% was observed and an even more prominent effect, almost 50%, is obtained for activated PPARα-driven PPRE-Luc activity (Fig. 4B). Already at the lowest concentration of transfected plasmid DNA, STRN3 was able to significantly inhibit PPARα transactivation.
STRN3 decreases GR transactivation via the dephosphorylation of serine S211
In human GR, phosphorylation of serine 211 (S211, mouse S220, rat S232) in its N-terminal domain is linked to receptor transactivation26 (Fig. 5A). Since we identified a STRN3-mediated decrease of GR transactivation, it was tempting to speculate that STRN3 may alter the phosphorylation status of S211 of human GR. Over-expressing increasing amounts of STRN3 in A549, as indicated, resulted in a gradual decrease in the cellular pool of GR, specifically phosphorylated at S211 upon Dex treatment (Fig. 5B). Of note, the highest transfected STRN3 concentration leads to an 80% repression of S211 phosphorylation (Supplementary S4A).
Complementary herewith, the opposite approach, i.e. silencing of STRN3, demonstrated an increment in the level of GR specifically phosphorylated at S211 upon Dex, of almost 40% (Fig. 5C, Supplementary S4B). Figure 5D demonstrates an efficient knockdown of STRN3. Taken together, these results support that the mechanism by which STRN3 inhibits the transactivation function of GR may be directly linked to receptor dephosphorylation (quantification of the bands is provided in Supplementary S4A and B). A kinetics experiment further showed that the effect of STRN3 on GR phosphorylation is most clear after 90 min Dex (Supplementary S5A and B).
Next, we wanted to test how STRN3 impacts on the nuclear pool of phosphorylated GR, which is able to directly mediate transactivation. Hereto, YFP-STRN3 was over-expressed in A549 cells, and lysates were subjected to a cytoplasmic and nuclear fractionation analysis. In presence of excess STRN3, a decrease in the Dex-mediated GR phosphorylation at S211 is prominent in the nuclear fraction, while no differences on GR distribution between cytoplasmic and nuclear compartments were apparent when comparing the same treatments (Fig. 5E). Hence, the effect of STRN3 on GR phosphorylation does not affect the ability of GR to accumulate in the nucleus, but targets the transactivation function of GR when still present within the nuclear compartment. Because the pS211 GR signal specifically decreases in the nucleus in presence of over-expressed STRN3 (Fig. 5E), we postulate that the interaction in the nucleus is most probably the functionally relevant interaction.
To strengthen our hypothesis that STRN3 hampers the activity of GR in a phosphorylation-dependent manner, we monitored GR transactivation upon replacing wild-type (WT) GR with a GR variant in which S211 is mutated to Alanine (A), and which is expected to have a lower, yet residual, activity compared to the WT GR27. STRN3 has now lost the ability to inhibit GR transactivation (Fig. 6A), confirming our earlier data that STRN3 mediates its effect by targeting phosphorylated GR at S211. To confirm that this mutation does not affect the interaction, which may in essence lead to the same conclusion, again a co-immunoprecipitation was performed. The result demonstrates that Flag-GR S211A is still able to physically interact with YFP-STRN3 (Fig. 6B).
PPP2CA mediates the effects of STRN3 on GR phosphorylation
STRN3 is a scaffold protein without enzymatic activity yet interacts with phosphatases and kinases. More specifically, STRN3 can bind to different subunits of protein phosphatase 2 A (PP2A) such as PPP2R1B, PPP2R1A, PPP2CB and PPP2CA16, 28. Ingenuity pathway analysis (IPA) was used to identify common phosphatases shown to bind both STRN3 and GR. This yielded two common phosphatases, namely, PPP2R1A and PPP2CA (Fig. 7A). Should one of these phosphatases be directly involved, specific silencing would maintain levels of phosphorylated S211 upon Dex despite the presence of STRN3. Following an efficient knockdown of PPP2CA protein of over 60% (Fig. 7B lanes 5–8, Supplementary S6), this prediction is exactly the result as observed in Fig. 6B. Upon siRNA targeting of PPP2R1A, S211 phosphorylation levels of GR were not affected (data not shown).
Having found that PPP2CA mediates the effects of STRN3, we next reasoned that the three proteins might co-exist in the same protein complex. Co-immunoprecipitation analysis following over-expression of all three components in HEK293T (Fig. 7C) demonstrates that GR, PPP2CA and STRN3 may be part of one complex, potentially explaining effects on GR phosphorylation and subsequently on transactivation. In line with our previous results, using co-immunoprecipitation to study the interaction between GR and STRN3 (Figs 1D and 6B), no ligand effect of Dex on the formation of the trimeric complex is observed. As expected, we observe a strong interaction between PPP2CA and STRN3 conform literature29. Surprisingly, we do not detect a previously described interaction between over-expressed GR and PPP2CA30. Our results indicate STRN3 as a crucial scaffold protein facilitating the interaction between GR and PPP2CA, which serves to modulate the function of GR. Since endogenous STRN3 could not be detected due to poor antibody quality specifically for IP and Western analysis, we checked in A549 cell lysate whether over-expressed and detectable Flag-STRN3 could pull down endogenous phosphorylated GR and/or endogenous PPP2CA. The result in Supplementary S7 demonstrates that upon immunoprecipitation of Flag-STRN3 endogenous GR phosphorylated at S211 was enriched already in absence of Dex. Although in presence of Dex, the co-immunoprecipitated pS211GR signal is similar, we speculate that this result nevertheless reflects an ongoing dephosphorylation, since in the input the ratio of pS211 GR for Dex-treated cells compared to solvent-treated cells is much higher. Co-immunoprecipitation analysis also demonstrated an additional interaction with endogenous PPP2CA, which again points to the presence of all three proteins in one complex.
To validate the importance of STRN3 for the recruitment of PPP2CA in the same complex with GR, we applied a phosphatase activity assay to compare the levels of phosphatase activity in the complexes in absence and presence of STRN3. Figure 7D shows that a GR-associated phosphatase activity is only detectable when Flag-GR, YFP-STRN3 and PPP2CA are over-expressed, confirming that STRN3 may be prerequisite for the recruitment of PPP2CA in the proximity of GR, whilst in the absence of STRN3, PPP2CA is not able to bind to GR.
The C-terminal domain of GR is important for a proper formation of the trimeric complex
We used various Flag-tagged GR deletion mutants encompassing different functional domains (Fig. 8A) of human GR to identify which region(s) is/are important for the interaction with STRN3 and PPP2CA (Fig. 8B). GR mutants carrying a deletion in the NTD or DBD, were all found to strongly interact with YFP-STRN3 (Del1-401, Del1-416, Del417-486). Actually, in all deletion variants of GR in which LBD is still present, a strong interaction with STRN3 is observed, suggesting an important role for this domain of GR. However, the interaction of GR with STRN3 is not lost, only weaker, when the GR-LBD is deleted (Del487-777). This result points to a role for (an)other domain(s) besides the LBD. Yet, if only the N-terminal of the GR is withheld, then the interaction is lost (Del417-777), dismissing this domain as an important contact point. Since a weak interaction is restored using GR Del487-777, in which both NTD and DBD are present, we could envisage a weak contact point involving the DBD. Contrary to this assumption, the deletion mutant Del417-486, which keeps only NTD and LBD intact, exhibits a strong interaction. However, bearing in mind LBD is still present in this mutant, it may be that interaction surfaces are more favorable between GR LBD and STRN3 for this particular GR mutant lacking only DBD. At any rate, domain analysis might not reflect proper folding and so misleading conclusions could be made. Nevertheless, our observations consistently support that the LBD of GR is important for this interaction, even though the LBD alone may not be sufficient for an optimal interaction.
We next studied which GR mutants allow for an additional association of PPP2CA and, hence, trimeric complex formation. As HEK293T cells express high levels of endogenous PPP2CA, no over-expression was needed to detect the binding of endogenous PPP2CA to YFP-STRN3 and Flag-GR deletion mutants. GR LBD is a prerequisite for the binding of PPP2CA to the trimeric complex since in both experimental set-ups using GR minus its LBD (Del487-777 and Del417-777), PPP2CA binding is completely absent (Fig. 8B). Even in the set-up using GR Del487-777, which still allows for a weak interaction with STRN3, the absence of GR LBD prevents a physical recruitment of PPP2CA to the complex, emphasizing again the importance of GR LBD. PPP2CA binds to the coiled-coil domain of STRN3, located close to the N-terminal domain of the STRN3 protein31. Consequently, we hypothesize that the LBD of GR interacts with STRN3 so that the coiled-coil domain of STRN3 can bring PPP2CA physically to GR LBD, from where it can reach its target, i.e. the N-terminally localized phosphorylated S211. In conclusion, our results suggest multiple contact points between GR and STRN3 and a prerequisite for GR LBD to enable a functional trimeric complex with PPP2CA, leading to a model as depicted in Fig. 8C.
Discussion
Because of the role of GR in different biological pathways and its use as a drug target32, analysis of its interactome contributes to comprehend its regulatory pathways. Here, STRN3 was identified as a novel interaction partner of liganded GR. Immunofluorescence analysis demonstrated that these two endogenous proteins co-localize in the nucleus, indicating the involvement of STRN3 in GR’s nuclear actions.
Over-expression of STRN3 decreased GR transactivation while silencing enhanced GR transactivation. In line herewith, STRN3 silencing also augmented endogenous mRNA levels of the GR-inducible target genes DUSP1, encoding MKP1, a potent anti-inflammatory mediator33, PER1, ZFP and ECI2. Of note, the levels of ECI2 were enhanced upon silencing of STRN3 even in the absence of Dex treatment. Since ECI2 is a PPARα/GRα co-controlled gene34 and PPARα may be also a target of STRN3 (Fig. 4B) it is tempting to speculate that the different regulation of ECI2 might be ascribed to an increased level control of this particular gene promoter. Interestingly, silencing of STRN3 did not interfere with the trans-repression pathway of GR (Fig. 3E) indicating that STRN3 may influence only the dimerization-dependent actions of GR. Phosphorylation of GR at S211 is a known prerequisite for the transcriptional activity of the receptor10, 27, 35. Over-expression of STRN3 causes decreased phosphorylation of GR at S211, whilst silencing of STRN3 leads to the enhancement of GR phosphorylation at the same residue. By using a GR mutant of S211 (S211A) we showed that the negative impact of STRN3 on GR transactivation is phosphorylation-dependent. Since the striatin family of proteins lacks enzymatic activity, a phosphatase may be recruited within the same complex that can alter the phosphorylation status of GR in the presence of STRN3. Tan and colleagues described a negative effect of rat STRN3γ on the actions of human Estrogen receptor α through dephosphorylation of the receptor at S118 by the catalytic subunit of PP2A, PPP2CA25. Although according to IPA, PPP2R1A could also be a candidate, in accord with the study of Tan et al. on ERα, only PPP2CA could be identified as the responsible enzyme dephosphorylating GR upon STRN3 over-expression. Its silencing lifts the negative effect of STRN3 on GR’s phosphorylation status, which further strengthens the hypothesis of a trimeric complex. Following amino acid sequence alignment analysis of human ERα with human GR, we observe that S118 of ERα does not correspond to S211 of GR (Supplementary S8), indicating a different mechanism of action by which STRN3 and PPP2CA control the activity of these two different, yet related, receptors. Our results indicate that STRN3 may act as an inhibitor not only of steroid but also of peroxisome proliferator-activated nuclear receptors. Of note, STRN3 has been described in the literature to modulate the actions of ER, as mentioned above, but also of the Mineralocorticoid receptor (MR)36. Apart from the nuclear effect of STRN3 on ER, it is also involved in the receptor’s membrane associated actions. More specifically, over-expression of striatin in endothelial cells resulted in an increase in ERα in the membrane-enriched fraction, containing EGFR and IGF-1 receptor (IGF-1R), and a slight decrease in nuclear ERα. Striatin serves as a scaffold directing ERα to the plasma membrane and bridges ERα with the GPCR (Gαi) complex to facilitate assembly of a membrane signaling complex required for rapid estrogen extra-nuclear activation of MAPK, Akt, and eNOS in endothelial cells37,38,39. A similar mechanism has been proposed for Striatin and MR. Accordingly, in endothelial cells and murine heart tissue, complexes between striatin and MR have been described that can be disrupted by aldosterone but cannot be restored by spironolactone40, 41. Activation of MR by high levels of aldosterone increases striatin levels in vascular cells and in tissues of mouse models with elevated aldosterone concentrations40, 42. Lowering striatin levels in endothelial cells reduces the aldosterone-mediated non-genomic MR-dependent ERK phosphorylation without affecting EGF-induced ERK phosphorylation or genomic MR signaling43. The relevance of striatin for MR signaling is further suggested by the analysis of heterozygous striatin KO mice with low striatin levels and salt sensitive blood pressure. In this model, the pAKT/AKT ratio, as part of another potential non-genomic MR signaling pathway, is reduced while MR expression and genomic signaling are increased44. Collectively, our data reporting the effect of STRN3 on GR and the first evidences for a possible effect on the nuclear actions of PR and PPARα, together with the published findings by other research groups on other steroid receptor members, pinpoint the STRN family of proteins as a prominent regulator of nuclear receptor actions.
Co-immunoprecipitation analysis revealed the possibility of the formation of a trimeric complex among GR, STRN3 and PPP2CA, however, with the present data we cannot conclude whether these interactions are direct, and/or whether more proteins are involved. In the absence of STRN3 over-expression, GR was not able to interact with PPP2CA in HEK293T. However, the interaction of PPP2CA with GR has been described previously to contribute to corticosteroid sensitivity in severe asthma by dephosphorylation of GR S226, a modification regulating receptor nuclear export30, 45. In our study, over-expression of STRN3 and the subsequent recruitment of PPP2CA did not affect receptor shuttling. The discrepancy between results may be attributed to the different cell lines tested. We believe that PPP2CA needs an intermediate protein to form the complex in which GR is recruited. Here, STRN3 serves as the scaffold protein that will attract PPP2CA to a complex with GR. Nevertheless, in a different cell line and under different conditions, PPP2CA might use another scaffold protein to engage GR in the complex. Another example in which STRN3 is an essential part of a trimeric complex is with the antioxidant protein DJ-1 and the survival kinase Akt, suggestive of a role in neuroprotection46. Combining the co-immunoprecipitation data for (phosphorylated) GR with the immunofluorescence-based endogenous co-detection between GR and STRN3, we bring forward that the formation of a protein complex between ligand-activated GR, STRN3 and PPP2CA most likely occurs in the nucleus, hereby influencing the transactivation capacity of GR.
Co-immunoprecipitation experiments with GR deletion mutants indicated that predominantly the LBD and, to a lesser extent, the very C-terminal part of the NTD spanning into the DBD of the GR are needed to interact with STRN3 while the LBD is crucial for the binding of endogenous PPP2CA. STRN3 oligomerizes and interacts with PPP2CA via its coiled-coil domain31. Collectively, we deduct that GR and STRN3 might interact in an antiparallel orientation so that the C-terminal domain of GR is in close proximity with the coiled-coil domain of STRN3, which are also the respective domains for PPP2CA binding.
Apart from the well-studied role of the GR-mediated transrepression pathway in immunosuppression47, 48, the transactivation pathway of GR has re-gained attention due to the activation of a cluster of genes with potent anti-inflammatory actions such as GILZ and DUSP149. One of the causes leading to GCR, a state in which the patients do not respond to the GC treatment50, is the elevated levels of Tumor Necrosis Factor (TNF); a potent pro-inflammatory cytokine33. TNF and GR interfere with each other’s signaling pathway, resulting in a mutual inhibition51. As proven before in vitro and in vivo treatment with Dex followed by TNF, diminished the efficiency of Dex and the subsequent GR activity by almost 50%, (Supplementary S9)52, 53. Preliminary data indicate that in liver samples from wild type mice injected with TNF, endogenous mRNA levels of STRN3 were induced upon TNF treatment (Supplementary S10A). It would be interesting to further investigate whether in acute inflammatory conditions induced by TNF, the inflammatory environment may alter the interactome of GR, favoring the up-regulation of co-factors with a potential negative effect on GR functionality, as a possible mechanism leading to GCR (Supplementary S10B). In conclusion, STRN3, the novel inhibitor interaction partner of GR, may contribute to a continuous recruitment of PPP2CA at the GR-STRN3 complex followed by a dephosphorylation of GR at S211, resulting in a decrease of GR transactivation (Fig. 8C). The mechanism may involve a platform created by GR and STRN3, which further assists PPP2CA to anchor to the complex and to mediate the dephosphorylation of GR at S211, linking to an overall diminished transactivation function of GR.
Methods
Plasmids
The MAPPIT pCLG-hGRα bait vector was generated by cloning the full size human GRα coding sequence in the pCLG vector backbone, which was described previously54. The pMG1-hSTRN3 prey vector was obtained by Gateway recombinatorial transfer of a full size STRN3 ORF cDNA from an entry clone selected from the human ORFeome collection version 5.155 into the pMG1 destination vector, as reported before56. A STAT3-responsive firefly reporter plasmid, pXP2d2-rPAP1-Luc57, was used to generate the MAPPIT readout.
The functional reporter assays involved the following plasmids: GRE-Luc reporter plasmid, which contains two copies of the glucocorticoid response element (GRE) and the pHD-Luc that contains the PPARα response element58. The human STRN3a from the human ORFeome V5.1 collection was cloned in two different vectors, pMet7-Flag-STRN3 and pMet7-YFP-STRN3a. hGRα and hPPARα were cloned into a pMet7-Flag vector, a pECFP-GRα and a pMet7-Flag-PPARα, respectively. The GR mutant with serine 211 (S211) mutated into Alanine (GR S211A) was generated via site directed mutagenesis of pEF-Flag-human GRα and checked by sequencing analysis. The primers used in PCR containing the mutation are the following: CCCCAGGTAAAGAGACGAATGAGGCTCCATGGAGATCAGACCTGTTG and CAACAGGTCTGATCTCCATGGAGCCTCATTCGTCTCTTTACCTGGGG. GR deletion mutants were cloned in pMet7-Flag and were chemically synthesized by Gene9 containing att sites for gateway cloning in the destination vectors. The mutants span the following deletions: Del1-401, Del1-416, Del417-486, Del417-777 and Del487-777. The human PPP2CA plasmid is from addgene and is cloned into a pBABE zeo vector59. pMet7-Flag-empty vector was used as mock DNA where appropriate, to reach the same amount of transfected DNA per well for all set-ups.
Antibodies
Anti-GR (rabbit, H300, Santa cruz Biotechnology), anti-PPP2CA (rabbit, Proteintech), anti-Phosphorylated S211 Glucocorticoid receptor (rabbit, cell signaling technology), anti-STRN3 [1) N-20, goat polyclonal, sc:16853, Santa cruz Biotechnology, used in immunofluorescence experiments, 2) S68, mouse monoclonal, MAI-46461, Thermo Scientific, 3) mouse monoclonal, 05-1115, Millipore] (1 and 2 successfully detect over-expressed STRN3 in western blots), anti-Flag (mouse, Sigma), anti-Flag (rabbit, Sigma), anti-Lamin A/C (mouse, Cell signaling technology), anti-GAPDH (rabbit, Abcam), anti-PARP-1 (H-250, Santa cruz Biotechnology), horseradish peroxidase-conjugated anti-mouse and anti-rabbit from Jackson Immunoresearch laboratories, Pierce donkey anti-rabbit secondary antibody dylight 800 or 680 and Pierce donkey anti-mouse secondary antibody dylight 680 (Thermo Scientific).
Cell culture
Human embryonic kidney T cells (HEK293T) and human lung carcinoma (A549) cells, basal or stably transfected with recombinant NF-κB- or GRE-dependent reporter genes60 were maintained in DMEM plus fetal bovine serum in a humidified atmosphere of 5% CO2 at 37 °C.
MAPPIT
HEK293T cells were cultured in 96-well microtiter plates in DMEM supplemented with 10% fetal bovine serum and transfected with bait (25 ng per well), prey (50 ng per well) and reporter (5 ng per well) plasmids, via standard calcium phosphate transfection, as described earlier56. Twenty-four hours after transfection, triplicate wells were treated either with vehicle (medium, non-active MAPPIT system) or leptin (100 ng/ml) plus medium or leptin plus Dex (1 µM). Another 24 h later, luciferase activity was measured using the Luciferase Assay System kit (Promega) on an Envision plate reader (Perkin Elmer)21. Luciferase fold change was determined by calculating the ratio of either leptin + medium/vehicle or leptin + Dex/vehicle (Fig. 1C). The amount of DNA transfected per well was kept constant to 100 ng/well by addition of empty vector plasmid.
Indirect Immunofluoresecence analysis
Cell fixation, methanol permeabilization and staining of A549 or HeLa cells were performed according to Cell Signaling guidelines. GR was visualized with the GR polyclonal (H300) antibody (Santa Cruz) while STRN3 was visualized with the STRN3 monoclonal (N20) antibody (Santa Cruz), both used at 1:200, followed by probing with Alexa Fluor® 488 (Invitrogen) and/or Alexa Fluor® 568 (Invitrogen), respectively at a concentration of 1:1000. Nuclei were visualized using 4′,6-diamidino-2-phenylindole (DAPI) staining at a concentration of 1:100. A motorized inverted IX81 FluoView FV1000 laser scanning confocal microscope (Olympus) was used to record high-resolution images.
Reporter gene assay
HEK293T cells were transfected with calcium phosphate. Plasmids encoding GR, PR and PPARα along with their respective response element-dependent reporters, GRE-Luc, PRE-Luc and PPRE-Luc were over-expressed in presence of a constitutive β-galactosidase expressing plasmid and in absence or presence of increasing amounts of Flag-STRN3 plasmid, as indicated in Figures’ legends. The experiments were performed in 96 well plates. 24 h after transfection, the medium was replaced with Optimem and 48 h after transfection the cells were stimulated with the respective nuclear receptor ligands for 6 h. Firefly luciferase read-outs were normalized to β-galactosidase activity.
Small interfering RNA (siRNA) transfection
All siRNAs used in this study were purchased from Dharmacon. Two different siRNA specific for human STRN3 were used to confirm the specificity of the assay [siGenome Smartpool (M-019145-01-0005) and On-target plus Smartpool (L-019145-01-0005)]. For human PPP2CA silencing, we used the On-target plus Smartpool siRNA (L-003598-01-0005). As a control siRNA, siControl Nontargeting was used. A549 cells were transfected with a final concentration of 50 nM with the above-mentioned siRNAs with Dharmafect 1 (Thermo Scientific) reagent according to the manufacturer’s instructions. Using reporter gene assays, 72 h after siRNA transfection, the cells were treated as specified under “Results”. In case of an additional plasmid transfection step, 24 h after siRNA transfection, the medium was changed to Optimem followed by plasmid DNA transfection of A549 cells using the Lipofectamine Plus protocol according to the manufacturer’s instructions. 48 h later, the cells were further processed for analysis.
Quantitative RT-PCR (qPCR)
Total RNA was prepared from A549 cells or mouse liver samples using the RNeasy mini kit (Qiagen). cDNA was synthesized using iScriptTM Advanced cDNA Synthesis Kit from Bio-Rad and analyzed using the Power SYBR Green Master Mix (Applied Biosystems). Expression levels were calculated using the comparative Ct method, normalized to the best performing housekeeping genes, GAPDH and β-actin, determined by Genorm61.
Co-immunoprecipitation and Western analysis
Experiments were performed in 10 cm petri dishes. HEK293T cells were harvested and homogenized in lysis buffer A (10 mM Hepes pH 7.5, 1.5 mM MgCl2, 10 mM KCL, 0.5 mM DTT, 0.1% NP-40 supplemented with a protease inhibitor cocktail (Roche)). Samples were subjected to two freeze-thaw cycli (−70 °C). Lysates were cleared by centrifugation at 13.000 rpm at 4 °C and incubated with 20 μl of Anti-Flag M2 Affinity Gel (Sigma Aldrich) overnight at 4 °C. Beads are washed 4× in buffer A supplemented with 150 mM NaCl and 0.5% Triton-X 100, re-suspended in Laemmli buffer and boiled for 1 min at 95 °C. Immunoprecipitates were either frozen at −20 °C or used for Western analysis using antibodies (diluted in blocking buffer at 1/1000 overnight) against GR, STRN3, Flag and PPP2CA.
Nuclear and cytoplasmic fractionation
Cells were collected and resuspended in 200 μl of ice-cold Buffer 1 pH 7.5 (10 mM Hepes, 10 mM KCL, 1 mM MgCl2, 5% glycerol, 0.5% EDTA, 0.5% EGTA) supplemented with protease inhibitor (Roche) and incubated on ice for 15 min. 1 μl 10% NP-40 was added prior to a vortexing step for 10 sec. The cytoplasmic fraction was collected after centrifugation for 5 min at 14.000 rpm at 4 °C. To the remaining pellet, 100 μl of Buffer 2 pH 7.5 (10 mM Hepes, 1% NP-40, 1 mM MgCl2, 400 mM NaCl, 10 mM KCl, 20% glycerol, 0.5 mM EDTA, 0.5 mM EGTA) was added, followed by a vortexing step for 2 sec and incubation at 4 °C for 30 min on a shaker. The nuclear fraction was collected after centrifugation for 15 min at 14.000 rpm at 4 °C.
Phosphatase activity assay
The DuoSet® IC kit, specific for the quantification of human/mouse/rat PP2A activity (R&D systems), was used according to the manufacturer’s instructions. This DuoSet® IC activity assay contains the basic components required for the development of capture assays to measure the activity of PPA in lysates. An immobilized capture antibody specific for the catalytic subunit of PP2A binds both active and inactive PP2A. After washing away unbound material, a synthetic phosphopeptide substrate is added that is dephosphorylated by active PP2A to generate free phosphate and phosphorylated peptide. The free phosphate is detected by a sensitive dye-binding assay using malachite green and molybdic acid. By calculating the rate of phosphate release, the activity of PP2A is determined. As a positive control, we used total lysate, and as negative controls we used lysate stimulated with the PP2A/B specific phosphatase inhibitor, Okadaic acid (100 nM) (Cell signaling technology, #5934). As a control for immunoprecipitation, we used over-expression of PPP2CA in absence of Flag-GR.
Reagents
Recombinant mouse and human TNF was produced in E. coli and purified to homogeneity in our laboratories. Mouse TNF and human TNF had a specific activity of 1.2 × 108 IU/mg or 3.7 × 107 IU/ml, respectively, and no detectable endotoxin contamination. Dexamethasone, Progesterone and GW7647 were purchased from Sigma.
Statistical analysis
Data are expressed as the mean ± S.E. Student’s t-tests (for comparisons between two groups) or one-way ANOVA analysis (for comparisons of ≥ 3 groups) followed by Tukey’s post hoc test was used for the statistical analyses, with 95% confidence intervals and with unpaired two-tailed analysis of variance. Error bars in the figures represent the mean ± S.E. *, **, *** represent p < 0.05, p < 0.01 and p < 0.001, respectively.
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Acknowledgements
VIB international PhD grant to I.P. FWO-Vlaanderen projects G044317N to K.B.D. and G035113N to C.L. Instituut voor Wetenschappelijk Technologisch onderzoek (IWT) Strategisch Basis Onderzoek (SBO-IWT) [100013 to C.L, J.T. and K.D.B.]; European Research Council (ERC) Advanced Grant [N340941 to J.T.]; Interuniversity Attraction Poles (IAP) Programme of the Belgian Science Policy [P7/13 to J.T. and K.D.B.].
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Ioanna Petta performed or guided all experimental work and wrote the first drafts of the manuscript. Nadia Bougarne performed co-immunoprecipitation experiments during the manuscript revision, Sofie Vandevyver, Marlies Ballegeer assisted partially with experimental work. Jolien Vandewalle assisted with the in vivo experiments. Sofie Desmet provided the supportive Figure 1 (response to reviewer’s #1 comment), Lode De Cauwer performed site directed mutagenesis to generate the GR mutant S211A, Jonathan Thommis performed the plasmid cloning for the GR deletion mutants, performed co-immunoprecipitation experiments during the manuscript revision and performed the indirect immunofluorescence experiments. Karolien De Bosscher performed the confocal microscopy for the co-localization experiments and designed the graphics of Figure 8. Sam Lievens supervised the array MAPPIT screens. Lien Dejager assisted with experimental design. Claude Libert, Tavernier and Karolien De Bosscher supervised the design and performance of the experiments and reviewed the manuscript. Ioanna Petta and Karolien De Bosscher both revised the manuscript in the revision phase.
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Petta, I., Bougarne, N., Vandewalle, J. et al. Glucocorticoid Receptor-mediated transactivation is hampered by Striatin-3, a novel interaction partner of the receptor. Sci Rep 7, 8941 (2017). https://doi.org/10.1038/s41598-017-09246-6
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DOI: https://doi.org/10.1038/s41598-017-09246-6
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