H. A. Pedrozo

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).

Potential Mechanisms for the Plasmin-Mediated Release and Activation of Latent Transforming Growth Factor-β1 from the Extracellular Matrix of Growth Plate Chondrocytes

Chondrocytes produce latent transforming growth factor-β1 (TGF-β1) in a small, circulating form of 100 kDa and also store latent TGF-β1 in their matrix in a large form of 290 kDa containing the latent TGF-β1 binding protein 1. As growth plate cartilage cells are exceptionally sensitive to TGF-β1 and are known to produce plasminogen activator, the role of plasmin in the activation of soluble and matrix-bound latent TGF-β1 was examined. As is true for other cell types, low-dose plasmin (0.01 U/ml) was found to release both active and latent TGF-β1 from chondrocyte matrix in a time-dependent manner over 3 h. However, high-dose plasmin (1.0 U/ml) was found to release active TGF-β1 more rapidly than low-dose plasmin, and this release ceased within 30 min; latent complex continued to be released over time (3 h). When high-dose plasmin was titrated against the serine protease inhibitors, aprotinin and α-(2-aminoethyl)benzenesulfonyl fluoride, results similar to low-dose plasmin were obtained, indicating that the...

TGFβ1 Regulates 25-Hydroxyvitamin D3 1α- and 24-Hydroxylase Activity in Cultured Growth Plate Chondrocytes in a Maturation-Dependent Manner

Abstract. Chondrocytes metabolize 25-(OH)D3 to the two active dihydroxylated forms of the secosteroid, 1,25-(OH)2D3 and 24,25-(OH)2D3. The aim of the present study was to examine the activity of the enzymes responsible for this metabolism, 1α-hydroxylase and 24R-hydroxylase, and their regulation by TGFβ1. Basal 1α- and 24R-hydroxylase activities were measured in homogenates of confluent, fourth passage rat costochondral resting zone and growth zone chondrocytes and mouse cortico-tubular cells (MCT) were used as a positive control. The cells were harvested and homogenized in buffer optimized to maintain the activity and stability of the hydroxylases. Homogenates were incubated for 90 minutes and 1α- and 24R-hydroxylase activities determined by measuring the conversion of [3H]-25-(OH)D3 to [3H]-1,25-(OH)2D3 and [3H]-24,25-(OH)2D3 using an HPLC with an inline radioisotope detector. Resting zone cells were also treated with various concentrations of recombinant human TGFβ1 for 24 hours, and enzyme activity in total cell homogenates as well as 24-hydroxylase mRNA levels were determined. In addition, [3H]-1,25-(OH)2D3 and [3H]-24,25-(OH)2D3 released into the conditioned media by resting zone chondrocyte cultures in response to TGFβ1 were measured.In culture, all three cell types were found to contain 1α- and 24R-hydroxylase activities. Basal 1α-hydroxylase specific activity was significantly higher than 24R-hydroxylase specific activity in all cells. RT-PCR confirmed that resting zone and growth zone cells expressed mRNA for 24R-hydroxylase. Treatment of resting zone cells with TGFβ1 increased 24R-hydroxylase mRNA levels in a dose-dependent manner. TGFβ1 also increased 24R-hydroxylase activity 2- to 5-fold and decreased 1α-hydroxylase activity by 20–30%. Similar changes were observed with MCT cells, but not growth zone cells. Production of [3H]-24,25-(OH)2D3 by resting zone cells increased with TGFβ1 treatment, while [3H]-1,25-(OH)2D3 production decreased. The effect was time- and dose-dependent, correlating with hydroxylase activity and 24-hydroxylase gene expression. These results demonstrate that growth plate chondrocytes contain the necessary enzymes to produce 1,25-(OH)2D3 and 24,25-(OH)2D3 from 25-(OH)D3. In addition, the activity of these enzymes in resting zone cells, but not growth zone cells, is regulated by TGFβ1 by increasing gene transcription, indicating that cell maturation-dependent autocrine/paracrine pathways exist for regulating vitamin D metabolite production.

A mechanism of adaptation to hypergravity in the statocyst of Aplysia californica

The gravity-sensing organ of Aplysia californica consists of bilaterally paired statocysts containing statoconia, which are granules composed of calcium carbonate crystals in an organic matrix. In early embryonic development, Aplysia contain a single granule called a statolith, and as the animal matures, statoconia production takes place. The objective of this study was to determine the effect of hypergravity on statoconia production and homeostasis and explore a possible physiologic mechanism for regulating this process. Embryonic Aplysia were exposed to normogravity or 3 x g or 5.7 x g and each day samples were analyzed for changes in statocyst, statolith, and body dimensions until they hatched. In addition, early metamorphosed Aplysia (developmental stages 7-10) were exposed to hypergravity (2 x g) for 3 weeks, and statoconia number and statocyst and statoconia volumes were determined. We also determined the effects of hypergravity on statoconia production and homeostasis in statocysts isolated from developmental stage 10 Aplysia. Since prior studies demonstrated that urease was important in the regulation of statocyst pH and statoconia formation, we also evaluated the effect of hypergravity on urease activity. The results show that hypergravity decreased statolith and body diameter in embryonic Aplysia in a magnitude-dependent fashion. In early metamorphosed Aplysia, hypergravity decreased statoconia number and volume. Similarly, there was an inhibition of statoconia production and a decrease in statoconia volume in isolated statocysts exposed to hypergravity in culture. Urease activity in statocysts decreased after exposure to hypergravity and was correlated with the decrease in statoconia production observed. In short, there was a decrease in statoconia production with exposure to hypergravity both in vivo and in vitro and a decrease in urease activity. It is concluded that exposure to hypergravity downregulates urease activity, resulting in a significant decrease in the formation of statoconia.

Effects of hypergravity on statocyst development in embryonic Aplysia californica

Aplysia californica is a marine gastropod mollusc with bilaterally paired statocysts as gravity-receptor organs. Data from three experiments in which embryonic Aplysia californica were exposed to 2 x g are discussed. The experimental groups were exposed to excess gravity until hatching (9-12 day), whereas control groups were maintained at normal gravity. Body diameter was measured before exposure to 2 x g. Statocyst, statolith and body diameter were each determined for samples of 20 embryos from each group on successive days. Exposure to excess gravity led to an increase in body size. Statocyst size was not affected by exposure to 2 x g. Statolith size decreased with treatment as indicated by smaller statolith-to-body ratios observed in the 2 x g group in all three experiments. Mean statolith diameter was significantly smaller for the 2 x g group in Experiment 1 but not in Experiments 2 and 3. Defective statocysts, characterized by very small or no statoliths, were found in the 2 x g group in Experiments 1 and 2.

Evidence for the involvement of carbonic anhydrase and urease in calcium carbonate formation in the gravity-sensing organ of Aplysia californica

Abstract. To better understand the mechanisms that could modulate the formation of otoconia, calcium carbonate granules in the inner ear of vertebrate species, we examined statoconia formation in the gravity-sensing organ, the statocyst, of the gastropod mollusk Aplysia californica using an in vitro organ culture model. We determined the type of calcium carbonate present in the statoconia and investigated the role of carbonic anhydrase (CA) and urease in regulating statocyst pH as well as the role of protein synthesis and urease in statoconia production and homeostasis in vitro. The type of mineral present in statoconia was found to be aragonitic calcium carbonate. When the CA inhibitor, acetazolamide (AZ), was added to cultures of statocysts, the pH initially (30 min) increased and then decreased. The urease inhibitor, acetohydroxamic acid (AHA), decreased statocyst pH. Simultaneous addition of AZ and AHA caused a decrease in pH. Inhibition of urease activity also reduced total statoconia number, but had no effect on statoconia volume. Inhibition of protein synthesis reduced statoconia production and increased statoconia volume. In a previous study, inhibition of CA was shown to decrease statoconia production. Taken together, these data show that urease and CA play a role in regulating statocyst pH and the formation and maintenance of statoconia. CA produces carbonate ion for calcium carbonate formation and urease neutralizes the acid formed due to CA action, by production of ammonia.

Regulation of statoconia mineralization in Aplysia californica in vitro

Statoconia are calcium carbonate inclusions in the lumen of the gravity-sensing organ, the statocyst, of Aplysia californica. The aim of the present study was to examine the role of carbonic anhydrase and urease in statoconia mineralization in vitro. The experiments were performed using a previously described culture system (Pedrozo et al., J. Comp. Physiol. (A) 177:415-425). Inhibition of carbonic anhydrase by acetazolamide decreased statoconia production and volume, while inhibition of urease by acetohydroxamic acid reduced total statoconia number, but had no affect on statoconia volume. Inhibition of carbonic anhydrase initially increased and then decreased the statocyst pH, whereas inhibition of urease decreased statocyst pH at all times examined; simultaneous addition of both inhibitors also decreased pH. These effects were dose and time dependent. The results show that carbonic anhydrase and urease are required for statoconia formation and homeostasis, and for regulation of statocyst pH. This suggests that these two enzymes regulate mineralization at least partially through regulation of statocyst pH.

Caloric restriction alters arterial blood pressure and baroreflex responsiveness of the spontaneously hypertensive rat

Aging is associated with an increase in blood pressure and the occurrence of hypertension. Caloric restriction retards the aging process, in general, and is a commonly used therapeutic approach to the control of high blood pressure. The aim of this study was to examine the effects of long term caloric restriction on mean arterial blood pressure, heart rate and the baroreflex responsiveness of spontaneously hypertensive (SH) rats. Male, 3-month-old SH rats were allowed to eat ad libitum or were fed only 60% of the ad libitum amount. After 4 months, cannulas were inserted in the left femoral artery and vein under anesthesia. On the following day the blood pressure and heart rate were measured in the conscious rat. The basal mean arterial pressure of the calorie restricted rats (166±4 mm Hg, N=5) was significantly less than that of the ad libitum fed rats (182±4 mm Hg, N=4). The basal heart rates of the calorie restricted and ad libitum fed rats were 296±12 beats/min and 323±8 beats/min, respectively. The difference between the means was not significant (p>0.1). Nitroprusside and phenylephrine infusions were used to induce hypotensive and hypertensive episodes, respectively. For nitroprusside, the relationship between the change in mean arterial pressure and the reflex heart rate response was significantly steeper in the calorie restricted group (1.90±0.37 beats/min/mm Hg) than in the ad libitum fed group (0.86±0.1 beats/min/mm Hg). For phenylephrine the relationships were 0.98±0.09 and 0.52±0.18 beats/min/mm Hg, respectively. These results demonstrate that chronic caloric restriction reduces mean arterial pressure and enhances baroreflex responsiveness in the SH rat.