SMADs and FOXL2 synergistically regulate murine FSHbeta transcription via a conserved proximal promoter element.

Pituitary FSH regulates ovarian and testicular function. Activins stimulate FSHβ subunit (Fshb) gene transcription in gonadotrope cells, the rate-limiting step in mature FSH synthesis. Activin A-induced murine Fshb gene transcription in immortalized gonadotropes is dependent on homolog of Drosophila mothers against decapentaplegic (SMAD) proteins as well as the forkhead transcription factor FOXL2 (FOXL2). Here, we demonstrate that FOXL2 synergizes with SMAD2, SMAD3, and SMAD4 to stimulate murine Fshb promoter-reporter activity in heterologous cells. Moreover, SMAD3-induction of Fshb promoter activity or endogenous mRNA expression is dependent upon endogenous FOXL2 in homologous cells. FOXL2/SMAD synergy requires binding of both FOXL2 and SMAD3 or SMAD4 to DNA. Of three putative forkhead-binding elements identified in the murine Fshb promoter, only the most proximal is absolutely required for activin A induction of reporter activity in homologous cells. Additionally, mutations to the minimal SMAD-binding element adjacent to the proximal forkhead-binding element abrogate activin A or FOXL2/SMAD3 induction of reporter activity. In contrast, a mutation that impairs an adjacent PBX1/PREP1 (pre-B cell leukemia transcription factor 1-PBX/knotted-1 homeobox-1) binding site does not alter activin A-stimulated promoter activity in homologous cells. Collectively, these and previous data suggest a model in which activins stimulate formation of FOXL2-SMAD2/3/4 complexes, which bind to the proximal murine Fshb promoter to stimulate its transcription. Within these complexes, FOXL2 and SMAD3 or SMAD4 bind to adjacent cis-elements, with SMAD3 brokering the physical interaction with FOXL2. Because this composite response element is highly conserved, this suggests a general mechanism whereby activins may regulate and/or modulate Fshb transcription in mammals.