Nuclear receptors. II. Intestinal corticosteroid receptors

Two corticosteroid receptors have been cloned; they are the glucocorticoid receptor and the mineralocorticoid receptor. These receptors are members of the steroid/thyroid/retinoid receptor family of nuclear transactivating factors, which are characterized by two highly conserved zinc fingers in the central DNA binding domain, a COOH-terminal domain that encompasses the ligand binding site, and a variable NH(2)-terminal domain. In addition to these cloned receptors, other corticosteroid receptors have recently been identified in intestine. Steroid binding studies have identified two novel putative corticosteroid receptors in intestinal epithelia, and molecular cloning studies have detected two low-affinity receptors in small intestine that are activated by corticosteroids and induce CYP3A gene expression. This article focuses on the identification of these novel corticosteroid receptors and the potential role they may play in intestinal physiology.     

Glucocorticoid receptors.

Glucocorticoid hormones are secreted uniquely from the zona fasciculata of the adrenal cortex, with marked circadian variation in basal levels and acute elevation in response to stress. Glucocorticoid receptors are almost ubiquitously distributed, and mediate a wide range of tissue-specific responses; in addition to classical, [3H]dexamethasone-binding GR (Type II receptors) there is excellent evidence that Type I sites (MR) act as mineralocorticoid receptors in some tissues but high affinity glucocorticoid receptors in others. Particular issues to be addressed in the presentation include: (i) the extent to which glucocorticoid receptor occupancy is modulated by extracellular (plasma-binding enzymes) or intracellular (proto-oncogenes) factors; (ii) whether or not there are specific response elements for Type I and II receptors; (iii) putative physiological roles for Type I, high affinity glucocorticoid receptors; (iv) evidence for glucocorticoid receptors other than classical GR and "MR". In summary, glucocorticoid receptors appear to be a final common pathway mediating and/or modulating circadian rhythms and stress responses. Cell-and tissue-specificity of response to a whole-body signal is determined by local pre-receptor, receptor and genomic differences. On the basis of previous studies on glucocorticoid secretion, and recent information on glucocorticoid action, it would at last appear possible to begin to construct a coherent physiology for glucocorticoid hormones.     

Hybrid receptors.

Many hormone and growth factor receptors form homomeric oligomers. Subunits of related receptors can be mixed to form hybrid receptors. These can have novel ligand-binding and signaling properties. The additional flexibility that results from the ability to independently regulate the expression and function of different component subunits greatly increases the spectrum of cellular responses to extracellular signals.     

Acetylcholine receptors.

Alpha-Bungarotoxin is one of a class of proteins, isolated from snake venoms, which antagonize the action of acetylcholine at vertebrate neuromuscular junctions and 'electroplaques' of electric fish. Alpha-Bungarotoxin blocks acetylcholine action irreversibly and may be labelled with either 125I or 3H. This irreversible binding is used as the basis of an in vitro assay for acetylcholine receptors, whether in intact tissue, membrane fragments or solubilized preparations. Acetylcholine receptors from Torpedo and denervated skeletal muscle have been solutilized and substantially purified using affinity chromatography. The distribution of acetylcholine receptors in several tissues has been determined, and an auto-immune response, induced by injection of purified Torpedo receptors, has been studied.     

Adenosine receptors.

With the recent purification and cloning of the A1AR and the cloning of the A2AR in association with the development of selective radioligands, we are now poised to begin to understand at the most fundamental level the structure, function, and regulation of adenosine receptors. Although adenosine's physiological effects have been appreciated for more than 60 years, we are only now ready to address questions at the biochemical and molecular biological levels. We are likely to begin to see evidence for a whole group of adenosine receptors undetected by previous technology. One era of adenosine receptor research has just ended, and we now enter the new with anxious anticipation.     

Mammalian collagen receptors.

Collagen-rich extracellular matrices are abundant and ubiquitous in the mammalian body. Collagens are not only essential for the mechanical stability of tissues, but are also intimately involved in controlling cell behaviour. The hallmark of collagens is a triple helix made up of polypeptide chains containing glycine-X-Y repeats. A structurally and functionally diverse group of cell surface receptors mediates the recognition of triple-helical collagen: integrins, discoidin domain receptors, glycoprotein VI, leukocyte-associated IG-like receptor-1, and members of the mannose receptor family. In this review, we discuss the structure and function of these receptors, focussing on the principles involved in collagen recognition.     

Cardiac histamine receptors.

Current evidence pertinent to the identification of cardiac histamine receptors in the guinea pig is reviewed. Pharmacological characterization has been aided by the use of selective agonists and antagonists for both types of histamine receptors. It appears that both H1 and H2 receptors mediate the cardiac effects of histamine. Histamine H2 receptors mediate the positive chronotropic and ventricular inotropic effects. H1 receptors mediate the negative dromotropic effect of histamine and possibly the atrial inotropic effect. Histamine-induced arrhythmias involve H1 receptors (arrhythmias of conduction) or H2 receptors (arrhythmias of automaticity), or both. The receptors mediating the histamine-induced increase in coronary flow are not as clearly defined: both H1 and H2 receptors might be implicated.     

Cerebellar GABAB receptors modulate function of GABAA receptors.

Interactions between GABAA and GABAB receptors were studied using muscimol-stimulated uptake of 36Cl- by membrane vesicles from mouse cerebellum. Baclofen inhibited muscimol-stimulated 36Cl- uptake and this action was more pronounced with longer flux times (30 vs. 3 s) and after predesensitization of GABAA receptors. Baclofen also inhibited 36Cl- flux by cortical membranes but was more effective with cerebellar preparations. The action of baclofen was stereoselective, calcium-dependent, and blocked by the GABAB receptor antagonist 2-OH-saclofen. It was mimicked by GTP-gamma-S but not by GDP-beta-S, which suggests that baclofen may be acting via a G protein. The action of baclofen was inhibited by U73122, an inhibitor of phospholipase C. However, the potassium channel blockers tetraethylammonium or Ba2+ did not affect the action of baclofen. The results show that activation of GABAB receptors can inhibit the function of GABAA receptors and suggest that this action involves either a nondesensitizing subtype of GABAA receptor or the rate or recycling of desensitized to nondesensitized receptors. We speculate that this action of baclofen results from activation of phospholipase C and phosphorylation of a subtype of GABAA receptor by protein kinase C.     

G protein-coupled receptors.

The diversity of the G protein-coupled receptor superfamily is now being realised with the molecular cloning of DNA encoding many new receptors and receptor subfamilies. The existing pharmacological definitions of receptor subtypes have been extended dramatically with identification of additional subtypes at the molecular level. Functional analysis of cloned receptors by expression in heterologous cell types has demonstrated that individual receptor subtypes can couple to a variety of different effector systems.     

Ionotropic glutamate receptors.

The glutamate-binding sites of ionotropic glutamate receptors are formed from two extracellular domains of a single subunit. Conformational changes induced by agonist binding produce mechanical processes that are translated into ion gating and receptor desensitization. The interactions between macromolecular assemblies of synaptic proteins and ionotropic glutamate receptors, and their subsequent roles in receptor clustering and specificity are being elucidated. Kainate receptor pharmacology is finally revealing its secrets as a result of the availability of selective pharmacological agents.     

Human placental calcitonin receptors.

Receptors for the hypocalcaemic hormone, calcitonin (CT), have been identified in a membrane fraction prepared from term human placentae. Binding of 125I-labelled salmon CT (125I-sCT) to the membranes was time- and temperature-dependent, saturable (Bmax. 58 +/- 11 fmol/mg of protein), of high affinity (Kd 80 +/- 21 pM) and poorly reversible. Species-specific CTs and CT analogues competed for 125I-sCT binding with potencies proportional to their known biological potencies. Various unrelated peptide hormones did not compete, indicating that receptor binding was specific for CT. Photoaffinity labelling using a derivatized biologically active sCT analogue, [Arg11,18,3-nitrophenylazide-Lys14]sCT, identified a receptor component of Mr approximately 85,000, comparable with findings in osteoclasts and other target cells. The presence of CT receptors in the human placenta supports other evidence that CT may have a role in the regulation of placental function.     

Beta-adrenergic receptors and myogenesis.

The rat myogenic cell line, L8, contains a beta-adrenergic catecholamine-sensitive adenylate cyclase. Prior to cell fusion, and continuing thereafter, beta-adrenergic sites, as determined by the stereospecific binding of (125I)-hydroxybenqylpindolol, I1(125I)IHYP] increases from 470 to 2000 sites/cell. There is also an increase in adenylate cyclase (2-5 fold) and endogenous cAMP (5-30 fold) following stimulation by catecholamine. The dissociation constant (KD) of (125I)IHYP for unfused and fused cell-homogenates, as determined by estimation with Scatchard analysis, by direct determination at receptor concentrations well below the KD, or by association (4.6 X 10(8) M-1 min-1); and dissociation (0.028 min-1) kinetics; ranged from about 40 to 70 pM. The acquisition of beta-receptors prior to fusion in L8 cells may implicate this system in the regulation of myogenesis.