Decreases in local hormone biosynthesis and c-fos gene expression accompany differentiation of porcine preadipocytes

Summary To better understand possible autocrine or paracrine mechanisms involved in adipose tissue development, we have studied the biosynthesis of insulinlike growth factor I (IGF-I) and prostaglandin E₂ (PGE₂) by cultured porcine preadipocytes in response to factors known to modulate cell growth and differentiation. The expression of c-fos was also monitored because of the potential role of that proto-oncogene in coordination of growth and differentiation. Preadipocytes were grown to confluence and then maintained in one of three media treatments: a) standard medium supplemented with 10% fetal bovine serum (FBS), b) FBS supplemented with dexamethasone (Dex), c) FBS supplemented with dibutryladenosine 3′–5′-cyclic monophosphate. Indirect measurements of growth indicated that cell proliferation did not differ due to media type. Histochemical and enzymatic measurements of adipocyte development revealed that differentiation occurred only in those cultures exposed to Dex. The increase in adipocyte differentiation in response to Dex was associated with a decrease in c-fos and actin RNA expression whereas the decrease in c-fos RNA expression in response to Dex was small (approximately 40%); immunocytochemical analysis indicated that induction of Fos protein occurred only in undifferentiated cells. Thus, the cells responsible for the decrease in c-fos RNA expression are possibly those signaled to differentiate into adipocytes. Expression of IGF-I RNA and secretion of IGF-I and PGE₂ were also decreased in response to Dex treatment. These data provide the first demonstration that biosynthesis of IGF-I by preadipocytes can be modulated by a potent inducer of adipocyte differentiation. The combined results indicate that glucocorticoids may stimulate adipocyte differentiation by suppressing intracellular and putative intercellular mitogenic signals. This work was supported in part by grant HD 18447 from the National Institutes of Health, Bethesda, MD (G. J. H.). Mention of a trade mark, proprietary product, or specific equipment does not constitute a guarantee or warranty by the U. S. Department of Agriculture or University of Georgia and does not imply its approval to the exclusion of other products that may be suitable.     

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 size of the thyroid hormone receptor in chromatin

We have used radiation inactivation and target theory to determine the size of the functional unit for T3 binding in rat liver chromatin. The process involves exposure of frozen chromatin samples to a beam of high energy electrons produced in a linear accelerator and subsequent measurement of the residual capacity to bind hormone. Our experiments were carried out using three forms of solubilized chromatin: 1) sonicated, containing the receptor in fragments which sedimented faster than 30 S; 2) digested by nuclease, containing the receptor in a form which sedimented at 5-6 S; 3) digested by nuclease and made 0.5 M in KCl, containing the receptor in a form which sedimented at 3.8 S. We have shown that in each sample preparation the receptor retained the ability to bind T3 with the same capacity and affinity that had previously been measured with high molecular weight chromatin. Irradiation caused a reduction in the capacity to bind T3 but did not change the affinity of the remaining receptors for the hormone. In each preparation, the radiation resulted in a simple exponential loss of binding capacity with dose, indicating that a single target size was detected. Within the variation of the measurements, the target size for each form of the receptor was the same, 59,000 daltons.