Development of the mammalian embryo relies upon nutritive functions fulfilled by the visceral endoderm and then by the liver (1). A part of these functions is accomplished by nutrient carrier proteins of the albumin gene family, a multigene locus expressed by the liver and subject to precise developmental controls. One albumin-related gene, the ␣ 1 -fetoprotein (AFP) 1 gene, is activated at the onset of liver differentiation and operates tightly coupled with liver growth (2, 3). In 1988, our group circumscribed a proximal AFP promoter element essential to AFP gene activity in hepatocytes, and distinct from promoter components regulating the other albumin loci (4). The AFP-specific activator was then identified as orphan receptor fetoprotein transcription factor (5-7), so named for its first identified target locus (genome data base nomenclature, 2 NR5A2 in the nuclear receptor nomenclature, Ref. 9); also referred to as LRH1 or CPF). FTF belonged to a primitive class of nuclear receptors and emerged as a critical lead to connect AFP gene activation with early embryonic growth and differentiation processes.Subsequent studies indicated that developmental FTF functions even preceded its activation of the AFP locus in hepatocytes. In situ hybridization analysis in the mouse at embryonic day 8 -9 showed abundant FTF transcripts in the foregut endoderm, before liver morphogenesis (10). Characterization of the FTF gene promoter also revealed a cluster of regulatory motifs conserved in distant species and potential targets of cell lineage specification factors (11). Among these were three proximal binding sites for GATA factors, known to be essential for visceral endoderm function (12, 13). Furthermore, three HNF genes important to liver differentiation, HNF1␣, HNF4␣, and HNF3, were found to each contain double FTF-binding sites in their proximal promoter and to be activated by FTF in transfection assays (11). Thus, a pivotal role was suggested for FTF in a transcriptional cascade using determination factors to activate FTF in prehepatic endodermal cells, and then using FTF to drive AFP and other effectors of the hepatic program.
Steroidogenic factor-1 (SF-1) (NR5A1) is an orphan nuclear receptor that plays a premier role in ovarian organogenesis. Recent studies document mRNA expression of the structurally related factor NR5A2 (FTF, LRH-1, SF-2) in the adult ovary and more specifically in granulosa cells and luteal cells but not theca cells. Conversely, SF-1 was shown to be expressed at higher levels in theca/interstitial cells. These latter observations raised the possibility that FTF/LRH-1 may control target gene expression in granulosa cells of developing follicles. Using quantitative PCR our results show that FTF/LRH-1 message is expressed at higher levels in the ovary than in liver or other tissues analyzed. We show by in situ hybridization and LacZ expression in ovaries of transgenic mice bearing an FTF-promoter-LacZ fusion gene that FTF/LRH-1 is selectively expressed in granulosa cells of rat and mouse ovaries and is not present in theca cells or interstitial cells. However, by a variety of approaches, we showed that SF-1 mRNA and protein are expressed in greater amounts than FTF/LRH-1 in granulosa cells of follicles at all stages of development. Expression of SF-1 mRNA and protein in granulosa cells was verified by in situ hybridization, immunohistochemistry of ovarian sections, and immunocytochemistry of cultured rat granulosa cells. The significance of SF-1 in regulating target gene activation was supported by EMSA. An abundant granulosa cell protein binding to the SF-1-binding motif (CCAAGGTCA) present in the aromatase promoter and an FTF/LRH-1 motif (TGTCCTTGAACA) in the alpha-fetoprotein promoter was supershifted by two SF-1-specific antibodies but not by an FTF antibody. Conversely, with the same probes, a less abundant protein/DNA complex present in liver and ovarian cell extracts was shifted by an FTF antibody but not by the SF-1 antibodies. SF-1 and FTF/LRH-1 were differentially regulated in vivo by estradiol, FSH and prolactin. Collectively these data indicate that granulosa cells of small and preovulatory follicles express both SF-1 and FTF/LRH-1 and that each orphan receptor may regulate target gene expression in these cells.
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