Human progesterone receptor transformation and nuclear down-regulation are independent of phosphorylation

We have studied the phosphorylation of progesterone receptors (PR) in T47Dco human breast cancer cells using a monoclonal antibody directed against human PR called AB-52. This antibody recognizes both the A- (Mr approximately 94,000) and B- (Mr approximately 120,000) hormone binding proteins of PR, and was used to immunoprecipitate phosphorylated receptors isolated from cells incubated in vivo with [32P]orthophosphate. The specific activity, or phosphorylation levels, relative to protein levels was quantified by combined immunoblotting and autoradiography followed by densitometry. We find that immunopurified untransformed hormone-free receptors, which have a characteristic triplet B, singlet A structure, are phosphoproteins with similar levels of phosphate incorporation in all protein bands. If PR are first transformed to the nuclear binding form by treatment of cells with progesterone, and then labeled with [32P]orthophosphate, the receptor proteins are additionally phosphorylated. These chromatin-bound hormone occupied receptors incorporate five to 10 times more labeled phosphate per total receptor protein than do PR from untreated cells during the same [32P]incubation time. The second round of phosphorylation may also account for mobility shifts of transformed A- and B-receptors observed in sodium dodecyl sulfate-polyacrylamide gels. Both untransformed and transformed species of A- and B-receptors are phosphorylated only on serine residues, and neither the extent of phosphorylation, nor the phosphoamino acids, are affected by treatment of the cells with epidermal growth factor or insulin. We previously reported that after hormone binding and transformation of receptors to the tight chromatin binding state, PR undergo processing, or nuclear down-regulation. AB-52 was used to compare PR protein and phosphorylation levels when cells were treated for 0.5-48 h with progesterone or the synthetic progestin R5020. Both agonists lead to hyperphosphorylation of nuclear PR before phosphorylation levels decrease, in parallel with the drop in protein levels as receptors down-regulate. Treatment of cells with RU 486, an antiprogestin, leads to PR transformation as determined by immunoblotting, but subsequent down-regulation does not occur. After transformation, chromatin-bound RU 486-occupied receptors become intensely phosphorylated however, with specific activities 15 times greater than those of untransformed PR. Since these receptors are phosphorylated but not processed, the hormone-induced nuclear phosphorylation of PR is unlikely to be a signal for receptor processing.(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification of a phosphorylation site in the hinge region of the human progesterone receptor and additional amino-terminal phosphorylation sites

We have previously reported the identification of seven in vivo phosphorylation sites in the amino-terminal region of the human progesterone receptor (PR). From our previous in vivo studies, it was evident that several phosphopeptides remained unidentified. In particular, we wished to determine whether human PR contains a phosphorylation site in the hinge region, as do other steroid receptors including chicken PR, human androgen receptor, and mouse estrogen receptor. Previously, problematic trypsin cleavage sites hampered our ability to detect phosphorylation sites in large incomplete tryptic peptides. Using a combination of mass spectrometry and in vitro phosphorylation, we have identified six previously unidentified phosphorylation sites in human PR. Using nanoelectrospray ionization mass spectrometry, we have identified two new in vivo phosphorylation sites, Ser(20) and Ser(676), in baculovirus-expressed human PR. Ser(676) is analogous to the hinge site identified in other steroid receptors. Additionally, precursor ion scans identified another phosphopeptide that contains Ser(130)-Pro(131), a likely candidate for phosphorylation. In vitro phosphorylation of PR with Cdk2 has revealed five additional in vitro Cdk2 phosphorylation sites: Ser(25), Ser(213), Thr(430), Ser(554), and Ser(676). At least two of these, Ser(213) and Ser(676), are authentic in vivo sites. We confirmed the presence of the Cdk2-phosphorylated peptide containing Ser(213) in PR from in vivo labeled T47D cells, indicating that this is an in vivo site. Our combined studies indicate that most, if not all, of the Ser-Pro motifs in human PR are sites for phosphorylation. Taken together, these data indicate that the phosphorylation of PR is highly complex, with at least 14 phosphorylation sites.     

Regulation of progesterone receptor activity by cyclin dependent kinases 1 and 2 occurs in part by phosphorylation of the SRC-1 carboxyl-terminus

We described previously a novel role for cyclin A2/Cdk2 as a progesterone receptor (PR) coactivator. In reporter gene assays, cyclin A2 overexpression enhanced PR activity while inhibition of Cdk2 activity using the chemical inhibitor roscovitine or Cdk2 siRNA strongly inhibited PR activity. We demonstrate here that both Cdk1 and Cdk2 contribute to maximal induction of endogenous progestin responsive genes in T47D breast cancer cells. Our earlier studies suggested that the mechanism by which cyclin A2/Cdk2 enhances PR activity is via phosphorylation of steroid receptor coactivator-1 (SRC-1), which increases PR-SRC-1 interactions. To assess the importance of SRC-1 phosphorylation in the regulation of PR activity, SRC-1 was phosphorylated by cyclin A2/Cdk2 in vitro and seventeen phosphorylation sites were identified using biochemical techniques. We show that one of these sites, T1426 (adjacent to the C-terminal LXXLL nuclear receptor interaction motif), is an in vivo target of Cdks in mammalian cells and an in vitro target of Cdk1 and Cdk2. Phosphorylation of T1426 also contributes to SRC-1 coactivation potential, as mutation of the threonine target site to alanine results in reduced stimulation of PR activity by SRC-1. Together, these results suggest a role for Cdk1 and Cdk2 in the regulation of endogenous PR activity in part through phosphorylation of SRC-1.     

Phosphorylation of the chicken progesterone receptor

We have examined the phosphorylation of the chicken progesterone receptor in tissue slices and in vitro. The receptor is phosphorylated in tissue slices and this phosphorylation is stimulated by progesterone. As others have reported, partially purified receptor preparations contain a kinase activity which phosphorylates histones and receptor. We have shown that this activity can be separated from the receptor. The receptor is a substrate for several kinases, including the catalytic subunit of the cAMP-dependent protein kinase and PPdPK, a polypeptide-dependent protein kinase. Phosphorylation by the cAMP-dependent protein kinase results in an apparent increase in the molecular weight of the receptor when the receptor is analyzed by SDS-PAGE. These results are consistent with apparent changes in molecular weight observed for rabbit and human progesterone receptor upon treatment of tissue or cells with hormone.     

Differential hormone-dependent phosphorylation of progesterone receptor A and B forms revealed by a phosphoserine site-specific monoclonal antibody

Human progesterone receptor (PR) is phosphorylated on multiple serine residues (at least seven sites) in a manner that involves distinct groups of sites coordinately regulated by hormone and different kinases. Progress on defining a functional role for PR phosphorylation has been hampered both by the complexity of phosphorylation and the lack of simple, nonradioactive methods to detect the influence of ligands and other signaling pathways on specific PR phosphorylation sites in vivo. Toward this end, we have produced monoclonal antibodies (MAbs) that recognize specific phosphorylation sites within human PR including a basal site at Ser 190 (MAb P190) and a hormone-induced site at Ser 294 (MAb P294). Biochemical experiments showed the differential reactivity of the P190 and P294 MAbs for phosphorylated and unphosphorylated forms of PR. Both MAbs recognize specific phosphorylated forms of PR under different experimental conditions including denatured PR protein by Western blots and PR in its native conformation in solution or complexed to specific target DNA. As detected by Western blot of T47D cells treated with hormone for different times, hormone-dependent down-regulation of total PR and the Ser 190 phosphorylation site occurred in parallel, whereas the Ser 294 phosphorylation site was down-regulated more rapidly. This difference in kinetics suggests that the Ser 294 site is more labile than basal sites and is acted upon by distinct phosphatases. A strong preferential hormone-dependent phosphorylation of Ser 294 was observed on PR-B as compared with the amino-terminal truncated A form of PR. This was unexpected because Ser 294 and flanking sequences are identical on both proteins, suggesting that a distinct conformation of the N-terminal domain of PR-A inhibits phosphorylation of this site. That Ser 294 lies within an inhibitory domain that mediates the unique repressive functions of PR-A raises the possibility that differential phosphorylation of Ser 294 is involved in the distinct functional properties of PR-A and PR-B.     

Dimerization of the chicken progesterone receptor in vitro can occur in the absence of hormone and DNA

We have analyzed the dimerization of two forms of the chicken progesterone receptor (cPRA and cPRB) by nondenaturing gradient gel electrophoresis and chemical cross-linking with dimethylpimelimidate (DMP). We demonstrate by these two methods that the PRs assemble in vitro into dimers in the absence of DNA, and that dimerization does not require hormone. The cPRA homodimer binds quantitatively to its cognate DNA response element in our nondenaturing gradient gel assay. DMP cross-linking confirms that both forms of the receptor (cPRA and cPRB) assemble into dimers in solution. Finally, in a standard mobility shift assay, chemically cross-linked receptors bind to the progesterone DNA response element with high affinity. We conclude that the PR contains a dimerization motif, which can promote stable subunit-subunit contacts without the presence of hormone in vitro. The complex thus formed expresses sequence-specific DNA-binding activity indistinguishable from that observed in the presence of hormone.     

Synthesis of human progesterone receptors in T47D cells. Nascent A- and B-receptors are active without a phosphorylation-dependent post-translational maturation step

Human progesterone receptors (PR) are structurally complex. At basal states there are two forms: A-receptors of approximately 94 kDa and B-receptors which are triplets of approximately 114, 117, and 120 kDa. All the proteins bind hormone and are phosphorylated. By using PR-rich T47Dco human breast cancer cells, pulse-labeling with [35S]methionine, and receptor immunopurification with anti-PR monoclonal antibodies, we show that PR are synthesized as single B-proteins of 114 kDa and single A-proteins of 94 kDa. The mature B-triplets form 6-10 h later by post-translational phosphorylation at sites restricted to the B-proteins. This slow maturation is not required for PR activation to hormone binding states, however, since A- and B-receptors that are less than 15 min old respond to progestins by undergoing transformation and nuclear binding accompanied by a rapid secondary phosphorylation common to both proteins. These studies explain the complex structure of the mature human B-receptors and the transformed A- and B-receptors, and address issues dealing with A- and B-proreceptor synthesis and receptor activation rates.