Ilka Nemere

1,25(OH)2-vitamin D3, a steroid hormone that produces biologic effects via both genomic and nongenomic pathways

The hormonally active form of vitamin D is 1,25(OH)2-vitamin D3 [1,25(OH)2D3]. This seco-steroid is the key mediator of the vitamin D endocrine system which produces biological effects in over 28 target tissues. In these target tissues, the biological responses may be generated both by a signal transduction mechanism which involves a nuclear receptor for 1,25(OH)2D3 that modulates gene transcription or a signal transduction pathway which involves rapid opening of Ca2+ channels which are externally located on the plasma membrane. This paper reviews the evidence in support of the pleiotropic effects of this steroid hormone and presents evidence that the receptor of the genomic effects is likely to be separate from the receptor/membrane recognition element which initiates the rapid nongenomic biological effects.

Identification of a membrane receptor for 1,25-dihydroxyvitamin D3 which mediates rapid activation of protein kinase C.

This paper is the first definitive report demonstrating a unique membrane receptor for 1,25‐dihydroxyvitamin D3(1,25(OH)2D3) which mediates the rapid and nongenomic regulation of protein kinase C (PKC). Previous studies have shown that 1,25(OH)2D3 exerts rapid effects on chondrocyte membranes which are cell maturation‐specific, do not require new gene expression, and do not appear to act via the traditional vitamin D receptor. We used antiserum generated to a [3H]1,25(OH)2D3 binding protein isolated from the basal lateral membrane of chick intestinal epithelium (Ab99) to determine if rat costochondral resting zone (RC) or growth zone (GC) cartilage cells contain a similar protein and if cell maturation‐dependent differences exist. Immunohistochemistry demonstrated that both RC and GC cells express the protein, but levels are highest in GC. The binding protein is present in both plasma membranes and matrix vesicles and has a molecular weight of 66,000 Da. The 66 kDa protein in GC matrix vesicles has a Kd of 17.2 fmol/ml and Bmax of 124 fmol/mg of protein for [3H]1,25(OH)2D3. In contrast, the 66 kDa protein in RC matrix vesicles has a Kd of 27.7 fmol/ml and a Bmax of 100 fmol/mg of protein. Ab99 blocks the 1,25(OH)2D3‐dependent increase in PKC activity in GC chondrocytes, indicating that the 1,25(OH)2D3‐binding protein is indeed a receptor, linking ligand recognition to biologic function.

Physiological importance of the 1,25(OH)2D3 membrane receptor and evidence for a membrane receptor specific for 24,25(OH)2D3

We have recently identified a membrane vitamin D receptor (mVDR) specific for 1,25‐dihydroxyvitamin D3 (1,25(OH)2D3) and shown that it mediates the rapid activation of protein kinase C (PKC) in growth zone chondrocytes (GCs). In this study, we examine the role of the 1,25(OH)2D3‐mVDR in chondrocyte physiology and provide evidence for the existence of a specific membrane receptor for 24,25‐dihydroxyvitamin D3 (24,25(OH)2D3‐mVDR). Fourth‐passage cultures of growth plate chondrocytes at two distinct stages of endochondral development, resting zone (RC) and growth zone (GC) cells, were used to assess the role of the mVDR in cell proliferation, PKC activation, and proteoglycan sulfation. To preclude the involvement of the nuclear vitamin D receptor (nVDR), we used hybrid analogs of 1,25(OH)2D3 with <0.1% affinity for the nVDR (2a, 1α‐CH2OH‐3β‐25D3; 3a, 1α‐CH2OH‐3β‐20‐epi‐22‐oxa‐25D3; and 3b, 1β‐CH2OH‐3α‐20‐epi‐22‐oxa‐25D3). To determine the involvement of the mVDR, we used an antibody generated against the highly purified 1,25(OH)2D3 binding protein from chick intestinal basolateral membranes (Ab99). Analog binding to the mVDR was demonstrated by competition with [3H]1,25(OH)2D3 using matrix vesicles (MVs) isolated from cultures of RC and GC cells. Specific recognition sites for 24,25(OH)2D3 in RC MVs were demonstrated by saturation binding analysis. Specific binding of 24,25(OH)2D3 was also investigated in plasma membranes (PMs) from RC and GC cells and GC MVs. In addition, we examined the ability of Ab99 to block the stimulation of PKC by analog 2a in isolated RC PMs as well as the inhibition of PKC by analog 2a in GC MVs. Like 1,25(OH)2D3, analogs 2a, 3a, and 3b inhibit RC and GC cell proliferation. The effect was dose dependent and could be blocked by Ab99. In GC cells, PKC activity was stimulated maximally by analogs 2a and 3a and very modestly by 3b. The effect of 2a and 3a was similar to that of 1,25(OH)2D3 and was blocked by Ab99, whereas the effect of 3b was unaffected by antibody. In contrast, 2a was the only analog that increased PKC activity in RC cells, and this effect was unaffected by Ab99. Analog 2a had no effect on proteoglycan sulfation in RC cells, whereas analogs 3a and 3b stimulated it and this was not blocked by Ab99. Binding of [3H]1,25(OH)2D3 to GC MVs was displaced completely with 1,25(OH)2D3 and analogs 2a, 3a, and 3b, but 24,25(OH)2D3 only displaced 51% of the bound ligand. 24,25(OH)2D3 displaced 50% of [3H]1,25(OH)2D3 bound to RC MVs, but 2a, 3a, and 3b displaced <50%. Scatchard analysis indicated specific binding of 24,25(OH)2D3 to recognition sites in RC MVs with a Kd of 69.2 fmol/ml and a Bmax of 52.6 fmol/mg of protein. Specific binding for 24,25(OH)2D3 was also found in RC and GC PMs and GC MVs. GC membranes exhibited lower specific binding than RC membranes; MVs had greater specific binding than PMs in both cell types. 2a caused a dose‐dependent increase in PKC activity of RC PMs that was unaffected by Ab99; it inhibited PKC activity in GC MVs, and this effect was blocked by Ab99. The results indicate that the 1,25(OH)2D3 mVDR mediates the antiproliferative effect of 1,25(OH)2D3 on chondrocytes. It also mediates the 1,25(OH)2D3‐dependent stimulation of PKC in GC cells, but not the 2a‐dependent increase in RC PKC activity, indicating that 24,25(OH)2D3 mediates its effects through a separate receptor. This is supported by the failure of Ab99 to block 2a‐dependent stimulation of PKC in isolated PMs. The data demonstrate for the first time the presence of a specific 24,25(OH)2D3 mVDR in endochondral chondrocytes and show that, although both cell types express mVDRs for 1,25(OH)2D3 and 24,25(OH)2D3, their relative distribution is cell maturation–dependent.

1,25-(OH)2D3 modulates growth plate chondrocytes via membrane receptor-mediated protein kinase C by a mechanism that involves changes in phospholipid metabolism and the action of arachidonic acid and PGE2.

1,25-(OH)2D3 (1,25) exerts its effects on growth plate chondrocytes through classical vitamin D (VDR) receptor-dependent mechanisms, resulting in mineralization of the extracellular matrix. Recent studies have shown that membrane-mediated mechanisms are involved as well. 1,25 targets cells in the prehypertrophic and upper hypertrophic zones of the costochondral cartilage growth plate (GC cells), resulting in increased specific activity of alkaline phosphatase (ALP), phospholipase A2 (PLA2), and matrix metalloproteinases (MMPs). At the cellular level, 1,25 action results in rapid changes in arachidonic acid (AA) release and re-incorporation, alterations in membrane fluidity and Ca ion flux, and increased prostaglandin E1 and E2 (PGE2) production. Protein kinase C (PKC) is activated in a phospholipase C (PLC) dependent-mechanism, due in part to the increased production of diacylglycerol (DAG). In addition, AA acts directly on the cell to increase PKC specific activity. AA also provides a substrate for cyclooxygenase (COX), resulting in PGE2 production. 1,25 mediates its effects through COX-1, the constitutive enzyme, but not COX-2, the inducible enzyme. Time course studies using specific inhibitors of COX-1 show that AA stimulates PKC activity and PKC then stimulates PGE2 production. PGE2 acts as a mediator of 1,25 action on the cells, also stimulating PKC activity. The rapid effects of 1,25 on PKC are nongenomic, occurring within 3 min and reaching maximal activation by 9 min. It promotes translocation of PKC to the plasma membrane. When 1,25 is incubated directly with isolated plasma membranes, PKCalpha is stimulated although PKCzeta is also present. In contrast, when isolated matrix vesicles (MVs) are incubated with 1,25, PKCzeta is inhibited and PKCalpha is unaffected. These membrane-mediated effects are due to the presence of a specific membrane vitamin D receptor (mVDR) that is distinct from the classical cytosolic VDR. Studies using 1,25 analogs with reduced binding affinity for the classical VDR, confirm that rapid activation of PKC by 1,25 is not VDR dependent. The membrane-mediated effects of 1,25 are critical to the regulation of events in the extracellular matrix produced by the chondrocytes. MVs are extracellular organelles associated with maturation of the matrix, preparing it for mineralization. MV composition is under genomic control, involving VDR-mechanisms. In the matrix, no new gene expression or protein synthesis can occur, however. Differential distribution of PKC isoforms and their nongenomic regulation by 1,25 is one way for the chondrocyte to control events at sites distant from the cell. GC cells contain 1a-hydroxylase and produce 1,25; this production is regulated by 1,25, 24,25, and dexamethasone. 1,25 stimulates MMPs in the MVs, resulting in increased proteoglycan degradation in mineralization gels, and increased activation of latent transforming growth factor-beta 1 (TGF-beta1).

Regulation of Intestinal Calcium Transport

Calcium is an essential ion in all organisms and participates in a variety of structural and functional roles. Calcium (re)absorption occurs in epithelia, including the intestine, kidney, mammary glands, placenta, and gills of fish. Its transport is regulated by a complex array of processes that are mediated by hormonal, developmental, and physiological factors involving the gastrointestinal tract, bone, kidney, and the parathyroids. Here we review the calcium transport mechanisms-paracellular, which is energy independent, and transcellular, which is energy dependent-primarily focusing on the intestine. We provide a new perspective on the facilitated diffusion and vesicular transport models to account for the emerging concepts on transcellular calcium transport. Finally, we discuss how 1,25(OH)2D3 and parathyroid hormone regulate calcium transport.

Steroid hormone receptors in target cell membranes.

Numerous reports of rapid steroid hormone effects in diverse cell types cannot be explained by the generally prevailing theory that centers on the activity of hormone receptors located exclusively in the nucleus. Cell membrane forms of steroid hormone receptors coupled to intracellular signaling pathways may also play an important role in hormone action. Membrane-initiated signals appear to be the primary response of the target cell to steroid hormones and may be prerequisite to subsequent genomic activation. Recent dramatic advances in this area have intensified efforts to delineate the nature and biologic roles of all receptor molecules that function in steroid hormone-signaling pathways. This work has profound implications for our understanding of the physiology and pathophysiology of hormone actions in responsive cells and may lead to development of nvoel approaches for the treatment of many cell proliferative, metabolic, inflammatory, reproductive, cardiovascular, and neurologic defects.

Evidence for distinct membrane receptors for 1α,25-(OH)2D3 and 24R,25-(OH)2D3 in osteoblasts

Abstract 1α,25-(OH) 2 D 3 exerts its effects on chondrocytes and enterocytes via nuclear receptors (1,25-nVDR) and a separate membrane receptor (1,25-mVDR) that activates protein kinase C (PKC). 24R,25-(OH) 2 D 3 also stimulates PKC in chondrocytes, but through other membrane mechanisms. This study examined the hypothesis that osteoblasts possess distinct membrane receptors for 1α,25-(OH) 2 D 3 and 24R,25-(OH) 2 D 3 that are involved in the activation of PKC and that receptor expression varies as a function of cell maturation state. 1α,25-(OH) 2 D 3 stimulated PKC in well differentiated (UMR-106, MC-3T3-E1) and moderately differentiated (ROS 17/2.8) osteoblast-like cells, and in cultures of fetal rat calvarial (FRC) cells and 2T3 cells treated with rhBMP-2 to promote differentiation. 24R,25-(OH) 2 D 3 stimulated PKC in FRC and 2T3 cultures that had not been treated to induce differentiation, and in ROS 17/2.8 cells. MG63 cells, a relatively undifferentiated osteoblast-like cell line, had no response to either metabolite. Ab99, a polyclonal antibody generated to the chick enterocyte 1,25-mVDR, but not a specific antibody to the 1,25-nVDR, inhibited response to 1α,25-(OH) 2 D 3 . 1α,25-(OH) 2 D 3 exhibited specific binding to plasma membrane preparations from cells demonstrating a PKC response to this metabolite that is typical of positive cooperativity. Western blots of these membrane proteins reacted with Ab99, and the Ab99-positive protein had an Mr of 64 kDa. There was no cross-reaction with antibodies to the C- or N-terminus of annexin II. The effect of 24,25-(OH) 2 D 3 on PKC was stereospecific; 24S,25-(OH) 2 D 3 had no effect. These results demonstrate that response to 1α,25-(OH) 2 D 3 and 24R,25-(OH) 2 D 3 depends on osteoblast maturation state and suggest that specific and distinct membrane receptors are involved.

Chemistry and conformation of vitamin D molecules.

1 alpha,25-Dihydroxyvitamin D3 (1,25) is a structurally unique steroid hormone because it not only possesses the complete 25-hydroxycholesterol side chain, but most notably, it possesses a seco-B triene structure (it lacks a B-ring and is usually depicted in a non-steroidal, extended conformation). In contrast, the classical steroid hormones possess a truncated side chain (progesterone, cortisol, and aldosterone) or no side chain (estradiol and testosterone) and they all possess the fully intact ABCD steroid rings. These structural differences render the seco-B-steroid 1,25 considerably more conformationally flexible. Since 1,25 is now known to target a myriad of tissues where specific interactions occur to produce an array of biological responses, it is of interest to determine whether different topologies of 1,25 (resulting from different conformational orientations of 1,25) are necessary to interact effectively at the different target sites. The array of biological responses include both non-genomic and genomic effects and there is considerable promise for the efficacy of 1,25 analogs as chemotherapeutic agents in a variety of human disease states. For the non-genomic calcium transport response of transcaltachia, the finding that two 6-s-cis locked analogs, 1 alpha,25-dihydroxyprevitamin D3 (pre-1,25) and 1 alpha,25-dihydroxylumisterol3 (1,25-Lumi), are equipotent to 1,25, points strongly to the involvement of the 6-s-cis conformer of 1,25 as the biologically active conformer. Since there is a continuum of easily interconvertible 6,7-single bond conformers of the seco-B ring available to 1,25, conformational minima (either local or global) may have little to do with the manner in which 1,25 is bound to receptor. For the genomic calcium transport response, and for other genomic (or non-genomic) effects, there is no clear evidence whether the steroidal (s-cis) or non-steroidal (s-trans) conformer of 1,25 is involved. In order to address this matter further, efforts are underway to evaluate other conformationally locked analogs of 1,25 which might mimic either the planar 6-s-trans-1,25 or some intermediate conformer between it and the planar-6-s-cis form.

Intestinal cell calcium uptake and the targeted knockout of the 1,25D3-MARRS (membrane associated, rapid response steroid binding) receptor/PDIA3/Erp57

We have crossed ERp57flx/flx mice with commercially available mice expressing villin-driven cre-recombinase. Lysates of intestinal epithelial cells were prepared from knock-out (KO) mice and littermates (LM) and used in Western blot analyses with Ab099 against the N terminus of the 1,25D3-MARRS (membrane-associated, rapid response steroid-binding) receptor: LM mice exhibited one positive band, which was absent in preparations from KO mice. Saturation analyses of cell lysates with [3H]1,25D3 revealed negligible binding in preparations from either female or male KOs. Lysates from female and male LM mice had similar affinities but different numbers of binding sites. Isolated enterocytes were tested for steroid-stimulated calcium uptake. Treatment of cells from female or male LM mice with 1,25D3 elicited enhanced calcium uptake in females and males within 5 min. Intestinal cells from KO mice exhibited a severely blunted or completely absent response to hormone. Confocal microscopy of intestinal cells revealed the presence of cell surface vitamin D receptors. However, antibodies to the vitamin D receptor failed to block 1,25D3-stimulated calcium uptake. In chick enterocytes we have found that the PKA pathway mediates calcium uptake. The time course for activation of PKA in mouse enterocytes paralleled that for enhanced calcium uptake and for LM females reached 250% of controls within 5 min, and 150% of controls in cells prepared from LM males. Enterocytes from female or male KO mice failed to exhibit steroid hormone-stimulated PKA activity, but did respond to forskolin with enhanced calcium uptake. We conclude that the 1,25D3-MARRS receptor is of central importance to steroid hormone-stimulated calcium uptake in mammalian intestinal cells.

Membrane receptors for steroid hormones: Signal transduction and physiological significance

Membrane receptors for steroid hormones affect signaling pathways that modulate nuclear function, influence neuronal activity, ion flow, and the circulatory system. Indeed, ‘new’ steroid hormones have been identified by their interaction with membrane‐initiated signaling systems. A brief summary of the FASEB Summer Research Conference devoted to these topics is presented in this mini‐review. In addition, attendees of the meeting propose introduction of the following terminology: membrane‐initiated steroid signaling (MISS) and nuclear‐initiated steroid signaling (NISS) to replace more inaccurate terms in current use.