Structural characterization of the chicken SF-1/Ad4BP gene

SF-1/Ad4BP was identified as a master regulator controlling steroidogenic P-450 genes and belongs to the steroid hormone receptor superfamily. It is expressed in the adrenal cortex, gonads, and pituitary gonadotroph. Targeted disruption of the mouse SF-1/Ad4BP gene showed that it plays a critical role in the development of the steroidogenic tissues and pituitary gonadotroph. We have recently cloned the chicken SF-1/Ad4BP cDNA and have now cloned the chicken SF-1/Ad4BP gene and analyzed its promoter activity. This gene consists of seven exons as well as mammalian counterparts and spans about 15 kb. In mice, the gene encodes another protein, ELP, but we could not find the open reading frame of ELP in the chicken SF-1/Ad4BP gene. The promoter of this gene included five putative cis elements (E, CCAAT, GC and TATA boxes and a GA-rich element), although no TATA box has been found in mammalian counterparts. The E and CCAAT boxes moderately affected promoter activity and the GA-rich element and TATA box were essential for the expression of the chicken SF-1/Ad4BP gene.     

Heterogeneity of Ovarian Theca and Interstitial Gland Cells in Mice

It has been established that two developmentally and functionally distinct cell types emerge within the mammalian testis and adrenal gland throughout life. Fetal and adult types of steroidogenic cells (i.e., testicular Leydig cells and adrenocortical cells) develop in the prenatal and postnatal period, respectively. Although the ovary synthesizes steroids postnatally, the presence of fetal-type steroidogenic cells has not been described. We had previously established transgenic mouse lines in which fetal Leydig cells were labeled with an EGFP reporter gene by the FLE (fetal Leydig enhancer) of the Ad4BP/SF-1 (Nr5a1) gene. In the present study, we examined the reporter gene expression in females and found that the reporter gene is turned on in postnatal ovaries. A comparison of the expressions of the EGFP and marker genes revealed that EGFP is expressed in not all but rather a proportion of steroidogenic theca and in interstitial gland cells in the ovary. This finding was further supported by experiments using BAC transgenic mice in which reporter gene expression recapitulated endogenous Ad4BP/SF-1 gene expression. In conclusion, our observations from this study strongly suggest that ovarian theca and interstitial gland cells in mice consist of at least two cell types.     

Differential gene dosage effects of Ad4BP/SF-1 on target tissue development

Ad4BP/SF-1 (NR5A1) was identified as a key regulator of the hypothalamus-pituitary-gonadal and -adrenal axes. Loss-of-function studies revealed that Ad4BP/SF-1 is essential for the development of these tissues and spleen. Here, we generated transgenic mouse with BAC recombinants carrying a dual promoter and Tet-off system. These recombinants have a potential to express lacZ and Ad4BP/SF-1 in the tissues where endogenous Ad4BP/SF-1 is expressed. However, protein level of Ad4BP/SF-1 varied among the tissues of the transgenic mice and probably thereby the target tissues are affected differentially. The BAC-transgenic mice were applied to rescue Ad4BP/SF-1 KO mouse. Interestingly, the mice successfully rescued the gonad and spleen but failed to rescue the adrenal gland. This variation might be dependent on in part the protein expression levels among the tissues and in part on differential sensitivities to the gene dosage.     

Developmental links between the fetal and adult zones of the adrenal cortex revealed by lineage tracing

The nuclear receptor Ad4BP/SF-1 is essential for development of the adrenal cortex and the gonads, which derive from a common adrenogonadal primordium. The adrenal cortex subsequently forms morphologically distinct compartments: the inner (fetal) and outer (definitive or adult) zones. Despite considerable effort, the mechanisms that mediate the differential development of the adrenal and gonadal primordia and the fetal and adult adrenal cortices remain incompletely understood. We previously identified a fetal adrenal-specific enhancer (FAdE) in the Ad4BP/SF-1 locus that directs transgene expression to the fetal adrenal cortex and demonstrated that this enhancer is autoregulated by Ad4BP/SF-1. We now combine the FAdE with the Cre/loxP system to trace cell lineages in which the FAdE was active at some stage in development. These lineage-tracing studies establish definitively that the adult cortex derives from precursor cells in the fetal cortex in which the FAdE was activated before the organization into two distinct zones. The potential of these fetal adrenocortical cells to enter the pathway that eventuates in cells of the adult cortex disappeared by embryonic day 14.5. Thus, these studies demonstrate a direct link between the fetal and adult cortices involving a transition that must occur before a specific stage of development.