Alterations in chromatin structure are implicated in the activation of the steroid hormone response unit of the ovalbumin gene

Hormone-responsive genes rely on complex regulatory elements known as hormone response units to integrate various regulatory signals. Characterization of the steroid-dependent regulatory element (SDRE) in the check ovalbumin gene (--892 to --796) suggests that it functions as a hormone response unit. Previous studies using gel mobility shift assays and several types of footprinting analyses demonstrated that proteins bind to this entire element in vitro even in the absence of steroid hormones. However, the genomic footprinting experiments described herein indicate that the binding of three different proteins or protein complexes to the SDRE requires estrogen and corticosterone, suggesting that the chromatin structure of this site is restricted in vivo. Transfection experiments using linker scanning and point mutations support the contention that the binding of these three complexes is essential for induction of the ovalbumin gene by steroid hormones. In addition, functional analyses suggest that a fourth complex is also necessary for maximal induction. These and other data suggest that the SDRE functions as a hormone response unit to coordinate signals generated by two steroid hormones.     

The chicken ovalbumin promoter is under negative control which is relieved by steroid hormones.

Steroid hormone regulation of activity of the chicken ovalbumin promoter was studied by microinjection of chimeric genes into the nuclei of primary cultured oviduct tubular gland cells. The chimeric genes contained increasing lengths of ovalbumin gene 5'-flanking sequences fused to the sequence coding for the SV40 T-antigen. Promoter activity was estimated by monitoring synthesis of T-antigen. The activity of the ovalbumin promoter is cell-specifically repressed in these oviduct cells and the repression is relieved upon addition of steroid hormones. The -132 to -425 region of the ovalbumin promoter which is responsible for this negative regulation behaves as an independent functional unit containing the regulatory elements necessary for both repression (in the presence of steroid hormone antagonists) and induced derepression (in the presence of steroid hormones) of linked heterologous promoters.     

An oviduct-specific and enhancer-like element resides at about -3000 in the chicken ovalbumin gene

The chicken ovalbumin (Ov) gene is one of the best models to study tissue-specific gene regulation because it is only expressed in the oviduct. In this paper, a tissue-specific element was characterized by 5'-flanking region deletion in combination with in vivo gene electroporation (EP). Plasmids with varying lengths of truncated Ov 5'-flanking region fused to the Renilla luciferase reporter gene were transfected in vivo into oviduct, muscle, and pancreas. A chicken oviduct-specific and enhancer-like region (designated COSE) was implicated between -3100 and -2800. The COSE showed up-regulation of gene expression in oviduct, but not in muscle or in pancreas. The COSE region was further characterized by gel mobility shift assays using nuclear extracts from oviduct, pancreas and liver. With the region from -2900 to -2851, designated T2, there were two distinct protein-DNA complexes: one found only in oviduct extract and the other detected only in pancreas and liver. These data suggest a model where the regulation of Ov gene expression in the oviduct and non-oviduct tissues is exerted at least in part by the presence of protein modulators that bind to the COSE element.     

Estrogen Receptor Is Not Primarily Responsible for Altered Responsiveness of Ovalbumin mRNA Induction in the Oviduct From Genetically Selected High- and Low-Albumen Chicken Lines

The role of estrogen receptor on ovalbumin mRNA induction by steroid hormones was investigated in primary cultures of oviduct cells from estrogen-stimulated immature chicks of genetically selected high- and low-albumen egg laying lines (H- and L-lines). In experiment 1,the extent of ovalbumin mRNA induction and changes in estrogen and progesterone receptors were compared between the oviduct cells from H- and L-lines with or without steroid hormones in the culture medium. In experiment 2, the effect of estrogen receptor gene transfection on the induction of ovalbumin mRNA was studied in the oviduct cells from the L-line chicks. The results showed a close correlation of the changes in ovalbumin mRNA with the numbers of nuclear and total estrogen receptors in the oviduct cells but not with the numbers of nuclear and total progesterone receptors. Estrogen receptor gene transfection induced ovalbumin mRNA to a moderate extent in the absence of the steroid hormones. To our surprise, however, estrogen receptor gene transfection apparently suppressed the ovalbumin mRNA responsiveness to estrogen to a considerable extent. It was concluded, therefore, that the extent of estrogen receptor expression might not be primarily responsible for the differences in responsiveness to steroid hormones of oviduct cells from genetically selected H- and L-line chickens.     

Effects of serial hormone treatments on egg white protein synthesis. Further evidence of translational regulation

The administration of either progesterone or estrogen to withdrawn chicks several hours after a first dose of estrogen affected ovalbumin synthesis differently than its mRNA levels [S. S. Seaver (1981) J. steroid Biochem. 14, 949-957]. This suggested that the hormones were regulating the translation of ovalbumin directly. In this paper we report that serial hormone treatments also affect the rates of synthesis of two other egg white proteins, conalbumin and ovomucoid. When progesterone was administered 4 h after estrogen, conalbumin synthesis decreased. When either progesterone or a second dose of estrogen was administered 12 h after the first dose of estrogen, conalbumin synthesis increased. Serial hormone treatments did not always affect all three proteins similarly. At later times, administering progesterone after estrogen decreased ovomucoid synthesis but did not affect conalbumin or ovalbumin synthesis. To determine if the serial hormone treatments affect egg white protein mRNA's in a similar way, changes in ovalbumin and conalbumin mRNA levels were quantified in a rabbit reticulocyte cell-free translation system and were compared to changes in ovalbumin and conalbumin synthesis as measured in chick oviduct tissue minces. When serial hormone treatments were 12 h apart, ovalbumin and conalbumin synthesis was 50-300% higher than that predicted by the changes in ovalbumin or conalbumin mRNA levels. This is further evidence that translation of both conalbumin mRNA and ovalbumin mRNA is directly regulated by steroid hormones.     

Regulated expression of the chicken ovalbumin gene in a human estrogen-responsive cell line

To study the regulation of expression of the chicken ovalbumin gene by steroid hormones, the entire ovalbumin gene and its flanking sequences were cloned together with the bacterial gene for xanthine-guanine phosphoribosyltransferase in plasmid pBR322. This recombinant plasmid was linearized and used to transform an estrogen-responsive breast carcinoma cell line (MCF-7) which was shown to possess estrogen receptors and to be estrogen responsive. Transformants were selected by their ability to grow in a medium containing mycophenolic acid and xanthine. The entire ovalbumin gene was integrated into high molecular weight DNA within all transformants analyzed and it retained its original sequence organization. Ovalbumin mRNA and protein were identified from these transformant cells and they were found to be indistinguishable from the authentic counterparts. An 8- to 10-fold increase in the amount of ovalbumin mRNA was observed to be present in cells cultured in 10(-8)M estradiol. We also constructed a hybrid gene containing the 5'-flanking sequence and the first exon of the ovalbumin gene which was linked to the xanthine-guanine phosphoribosyltransferase gene such that expression of this bacterial gene would be promoted and regulated by the chicken sequences. After introduction of this hybrid gene into MCF-7 cells, we observed that the survival of the transformed cells in our selection medium was highly dependent on the presence of estradiol. Our results indicated that the chicken ovalbumin sequence was expressed properly and was regulated to some extent by estradiol in this heterologous system.     

The Relationship of the Estrogen Receptor to the Induction of Vitellogenin in Chicken and Xenopus Liver

The mechanisms involved in the regulation of gene expression in eukaryote cells, although an area of active research, are still largely unknown. This is at least partly due to the lack of good experimental model systems. One type of system which is being exploited with some considerable success is the induction of proteins by steroid hormones. Studies on the effects of estrogen and progesterone on the synthesis of the egg white proteins in the chick oviduct, for instance, have yielded substantial insight into both the regulation of protein synthesis by steroid hormones [1] and the arrangement of the DNA sequences coding for these proteins [2, 3].
The need for other good inducible systems clearly exists and the induction of vitellogenin, the precursor of the major egg yolk proteins, by estrogen in the livers of the chicken and frog ( Xenopus laevis ) is one that is attracting increasing interest. In common with the chick oviduct, large amounts of a specific protein are synthesised in response to a well defined hormonal stimulus. However, the induction of vitellogenin also has the advantage that the response is not complicated by the extensive hyperplasia that follows estrogen treatment in the chick oviduct [4, 5] and that vitellogenin may be induced in vitro [6–11].
The aims of this review are first to discuss recent data on the induction of vitellogenin and vitellogenin mRNA both in vivo and in vitro and then to relate this data to the properties of the estrogen receptor, present in chicken and Xenopus liver, which is thought to mediate the induction of vitellogenin by estrogen.