Proceedings of the Fourth International Congress on Hormonal Steroids contains plenary speeches and symposia from the Fourth International Congress on Hormonal Steroids held in Mexico City in September 1974
MECHANISM OF ACTION OF STEROID HORMONES
I.S. EDELMAN, The Cardiovascular Research Institute and the Departments of Medicine, and of Biochemistry and Biophysics of the University of California, School of Medicine, San Francisco, Ca. 94143, U.S.A.
SUMMARY
Despite the diversity in the target sites and physiological actions of the steroids, an impressive body of evidence has been assembled in support of a unitary theory of the mechanism of action of these hormones in vertebrates. The steroids set in motion a train of events, as follows: (a) penetration into the target cell, (b) stereo specific binding to high affinity receptors, (c) temperature-sensitive activation of the steroid–receptor complex, (d) attachment of the active complex to chromatin, (e) induction of RNA and protein synthesis, and (f) physiological expression of the induced protein. Although the overall sequence is well-defined, our knowledge of the molecular processes involved in each of these steps is still quite incomplete. Two of the major efforts now underway to elucidate these molecular processes involve, (a) purification and characterization, in terms of structure-function relations, of the putative receptors, and (b) studies on the nature of the interaction between steroid–receptor complexes and the genome. It is now apparent that steroids induce de novo synthesis of both messenger RNA (mRNA) and ribosomal RNA (rRNA); the role of the former in directing the synthesis of specific proteins is reasonably clear but that of the latter remains to be elucidated. The mechanism of induction is also under scrutiny since the observed increases in mRNA synthesis could arise in a variety of ways, e.g. negative or positive regulation of chromatin template (gene) activity, changes in processing of heterogeneous RNA to mRNA, effects on RNA polymerase or ribonuclease activities. Although steroidal regulation of RNA and protein synthesis is a dominant pathway, the possibility of direct actions on membranes or regulatory enzymes in some circumstances can not be excluded at the present time.
INTRODUCTION
In vertebrates, circulating hormones dominate the morphogenetic and physiological states of almost all tissues, throughout the life span. In the last 15 years, two unifying theories have emerged that account for most of these diverse cellular responses to hormones; the mediating roles of cyclic nucleotides [cyclic adenosine monophosphate and cyclic guanosine monophosphate] in the actions of peptide and catecholamine hormones, and induction of protein synthesis in the actions of steroid and thyroid hormones. The interrelationships between these two primary mechanisms are also under active study.
A wealth of evidence has led to widespread agreement on the sequence but not the details of events set in motion by the steroids in many well-defined target tissues [1–5]. An outline of this theory is shown in Fig. 1. The steroid enters the target cells, combines with a high affinity receptor forming an active complex that then binds to selective sites in the chromatin. The interaction between the hormone–receptor complex and the genome activates or derepresses transcription or post-transcriptional regulation of RNA synthesis. The products, mRNA and rRNA, dictate the synthesis of specific proteins whose properties determine the morphogenetic and physiological responses to the hormones. Although this receptor-effector system mediates many of the actions of steroid hormones, other basic mechanisms may also play a role, especially at very high concentrations of the hormones. This possibility will be alluded to briefly in relation to possible direct effects of steroids on the permeability properties of plasma and organelle membranes, or on enzymes (see below). The primary focus of attention in this report, however, will be on the induction mechanism (Fig. 1).
Fig. 1 General model of the receptor-induction mechanism of steroid hormone action. Modified from Feldman et al. [2].
Steroid receptors
The mode of steroid penetration into target cells has received little attention. In one system, however, uptake of estrogen by uterine cells appears to involve facilitated rather than simple diffusion [6].
The target cells responsive to a given steroid contain high affinity, saturable cytoplasmic binding proteins (mol. wt. ≅ 100,000 Daltons) and the uptake of the steroid precedes the appearance of the physiological effect. These and other findings, including (1) the stereospecificity of the high affinity binding proteins, (2) the close correlation between affinity of various steroids for the binding site and physiological potency, and (3) association of the steroid–protein complex with chromatin, lend credence to the inference that these high affinity binding proteins are receptors that mediate the biological response [1, 4].
The physical and biological characteristics of all of the steroid receptors, including that of 1,25 dihydrocholecalciferol (Vitamin D derivative) are remarkably homologous [1, 4]. The main features of these homologies will be illustrated for the most part by reference to studies with aldosterone, since this steroid has been the focus of my work for more than a decade [7].
The association of steroids with target cell nuclei was first revealed by autoradiography [7, 8]3H-Aldosterone was localized to the nuclear and perinuclear areas of toad bladder epithelium. In contrast, 3H-progesterone, an inactive steroid at low concentrations compared to aldosterone, was randomly distributed. Bogoroch (cited in Edelman [9]) explored the specificity of the observed binding in competition studies (Table 1). Excess estradiol-17β, which is inactive with respect to Na+ transport in the toad bladder, had no effect on the distribution of 3H-aldosterone but 9α-fluorocortisol, an active mineralocorticoid, significantly diminished both nuclear and cytoplasmic localization. These findings imply the existence of cytoplasmic and nuclear receptors, in vivo.
Table 1
Quantitative distribution of 3H-aldosterone between cytoplasm and nucleus of toad bladder epithelium by autoradiography
Competitive steroid (100:1) | Grains/nucleus | Grains/cytoplasm |
None | 2.66 | 0.79 |
17β-estradiol | 2.75 | 0.96 |
9α-fluorocortisol | 0.84 | 0.45 |
Toad bladders were exposed to 3H-aldosterone (5?3 × 10–8 M) for 30min with or without added steroid (5?3 × 10–6 M). Average of 200 cells counted per section. [Bogoroch, R. & Edelman, I. S., cited in [9]].
The receptors appear to reside in the cytoplasm pending availability of their respective steroids and then bind to chromatin sites after formation of the cytoplasmic complex. This “two-step” mechanism was independently proposed by Gorski et al. [10] and by Jensen et al. [11]. An important feature of this mechanism is the requirement for temperature activation of the complex for binding to the nucleus.
The cytoplasmic-nuclear transfer process and other features of the steroid–receptor system have been incorporated into the model shown in Fig. 2. The receptor is assumed to exist in an inactive and an active conformation in equilibrium, as formulated by Rubin and Changeux [12] for allosteric enzymes. This allosteric equilibrium model was applied to steroid receptors by Samuels and Tomkins [13] in order to account for the behaviour of steroids with mixed agonist and antagonist properties [suboptimal inducers—in their nomenclature]. The phenomenon of partial agonist-antagonist behaviour is illustrated in Table 2. In the isolated toad bladder system, 11-deoxycortisol elicited an increase in active Na+ transport, measured by the short-circuit current (SCC) technique, that was 30% of that caused by maximum doses of aldosterone and in combination with aldosterone inhibited the response by 71%. Thus total activity accounts for 100% occupancy of the putative receptors and can be rationalized as indicating that the affinity of 11-deoxycortisol for the two conformations is in the ratio of 30:70, active vs inactive. Primary agonists (e.g., aldosterone) would presumably have a high affinity for the active conformation and negligible affinity for the inactive conformation. The converse should hold for primary antagonists. Support for this model was obtained in studies with steroid antagonists. Baxter et al. [14] found that in hepatoma cells in tissue culture, progesterone inhibited induction of tyrosine amino-transferase by glucocorticoids and occupied cytoplasmic glucocorticoid receptor sites but failed to generate intra-nuclear complexes. Kaiser et al. [15, 16] reported that in rat thymocytes, the anti-glucocorticoid, cortexolone bound to the receptor but failed to transfer to nuclear binding sites. In our studies, the anti-mineralocorticoid, spirolactone-mineralocorticoid–receptor complexes (SC-26304) did not bind to nuclear acceptor sites in vivo (see Table 3), nor in reconstitution experiments with isolated nuclear or...
Erscheint lt. Verlag | 22.10.2013 |
---|---|
Sprache | englisch |
Themenwelt | Sachbuch/Ratgeber ► Natur / Technik ► Naturführer |
Medizin / Pharmazie | |
Naturwissenschaften ► Biologie ► Zoologie | |
ISBN-10 | 1-4831-4566-2 / 1483145662 |
ISBN-13 | 978-1-4831-4566-2 / 9781483145662 |
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