Role of phosphorylation on DNA binding and transcriptional functions of human progesterone receptors.

To study the function of human progesterone receptor (hPR) phosphorylation, we have tested four sets of serine to alanine substitution mutants: 10 serine clusters, located in regions common to both hPR isoforms (the M-series mutants) were mutated in A-receptors and B-receptors; 6 serine clusters located in the B-upstream segment (BUS; the B-series mutants) were mutated individually and collectively and cloned into B-receptors and into BUS-DBD-NLS, a constitutive transactivator, in which the AF3 function of BUS is fused to the DNA binding domain (DBD) and nuclear localization signal (NLS) of hPR. Transcription by most of the M-series mutants resembles that of wild-type A- or B-receptors. Mutation of 3 sites, Ser190 at the N terminus of A-receptors, a cluster of serines just upstream of the DBD, or Ser676 in the hinge region, inhibits transcription by 20-50% depending on cell or promoter context. These sites lie outside the AF1 activation function. M-series mutants are substrates for a hormone-dependent phosphorylation step, and they all bind well to DNA. Progressive mutation of the B-series clusters leads to the gradual dephosphorylation of BUS, but only the 6-site mutant, involving 10 serine residues, is completely dephosphorylated. These data suggest that in BUS alternate serines are phosphorylated or dephosphorylated at any time. However, even when BUS is completely dephosphorylated, both BUS-DBD-NLS and full-length B-receptors remain strong transactivators. Mutant B-receptors also do not acquire the dominant negative properties of A-receptors, and they retain the ability to activate transcription in synergy with 8-Br-cAMP and antiprogestins. We conclude that phosphorylation has subtle effects on the complex transcriptional repertoire that distinguishes the two hPR isoforms and does not influence transactivation mediated by AF1 or AF3, but subserves other functions.

A third transactivation function (AF3) of human progesterone receptors located in the unique N-terminal segment of the B-isoform.

Human progesterone target tissues contain two progesterone receptors: B-receptors (hPRB), which are 933 amino acids in length, and A-receptors (hPRA), which lack the N-terminal 164 amino acids. The two isoforms differ functionally when they are occupied by agonists or antagonists. We postulated that the unique 164-amino acid, B-upstream segment (BUS) is in part responsible for the functional differences between the two isoforms and have constructed a series of hPR expression vectors encoding BUS fused to isolated down-stream functional domains of the receptors. These include the two transactivation domains: activation function-1 (AF1), located in a 90-amino acid segment just up-stream of the DNA-binding domain (DBD) and nuclear localization signal (NLS), and AF2, located in the hormone-binding domain. BUS is a highly phosphorylated domain, and contains the serine residues responsible for the hPRB triplet protein structure. The construct containing BUS-DBD-NLS binds tightly to DNA when aided by accessory nuclear factors. In HeLa cells, BUS-DBD-NLS strongly and autonomously activates transcription of chloramphenicol acetyltransferase (CAT) from a promoter containing two progesterone response elements (PRE2-TATAtk-CAT). Transcription levels with BUS-DBD-NLS are equivalent to those seen with full-length hPRB, and are higher than those seen with hPRA. BUS specifically requires an intact hPR DBD to be transcriptionally active. DBD mutants that cannot bind DNA or whose DNA binding specificity has been switched to an estrogen response element cannot cooperate in BUS transcriptional activity. The function of BUS-DBD-NLS is promoter and cell specific. It does not transactivate a CAT reporter driven by the mouse mammary tumor virus promoter in HeLa cells and poorly transactivates PRE2-TATAtk-CAT in PR-negative T47D breast cancer cells. However, in the breast cancer cells, BUS-DBD-NLS transactivation of PRE2-TATAtk-CAT can be reconstituted by either elevating cellular levels of cAMP or linking BUS and DBD to AF1 or AF2 of hPR, each of which alone is also inactive in these cells. We conclude that hPRB contains a unique third activation function (AF3) located within BUS and requiring the functional DBD of hPR. Depending on the promoter or cell tested, AF3 can activate transcription autonomously, or it can functionally synergize with AF1 or AF2. Autonomous AF3 function may explain the unexpected transactivating actions of antiprogestin-occupied hPRB, an issue of importance in hormone-resistant breast cancers and in tissue-specific agonist-like effects of hormone antagonists.