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Formation and function of ceramide-enriched membrane platforms with CD38 during M₁-receptor stimulation in bovine coronary arterial myocytes

Department of Pharmacology and Toxicology, Medical College of Virginia, Virginia Commonwealth University, Richmond, Virginia

Submitted 11 June 2008 ; accepted in final form 20 August 2008

	ABSTRACT

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
CD38 contains an ADP ribosylcyclase domain that mediates intracellular Ca²⁺ signaling by the production of cyclic ADP-ribose (cADPR), but the mechanisms by which the agonists activate this enzyme remain unclear. The present study tested a hypothesis that a special lipid-raft (LR) form, ceramide-enriched lipid platform, contributes to CD38 activation to produce cADPR in response to muscarinic type 1 (M₁) receptor stimulation in bovine coronary arterial myocytes (CAMs). By confocal microscopic analysis, oxotremorine (Oxo), an M₁ receptor agonist, was found to increase LR clustering on the membrane with the formation of a complex of CD38 and LR components such as GM₁, acid sphingomyelinase (ASMase), and ceramide, a typical ceramide-enriched macrodomain. At 80 µM, Oxo increased LR clustering by 78.8%, which was abolished by LR disruptors, methyl-β-cyclodextrin (MCD), or filipin. With the use of a fluorescence resonance energy transfer (FRET) technique, 15.5 ± 1.9% energy transfer rate (vs. 5.3 ± 0.9% of control) between CD38 and LR component, ganglioside M₁ was detected, further confirming the proximity of both molecules. In the presence of MCD or filipin, there were no FRET signals detected. In floated detergent-resistant membrane fractions, CD38 significantly increased in LR fractions of CAMs treated by Oxo. Moreover, MCD or filipin attenuated Oxo-induced production of cADPR via CD38. Functionally, Oxo-induced intracellular Ca²⁺ release and coronary artery constriction via cADPR were also blocked by LR disruption or ASMase inhibition. These results provide the first evidence that the formation of ceramide-enriched lipid macrodomains is crucial for Oxo-induced activation of CD38 to produce cADPR in CAMs, and these lipid macrodomains mediate transmembrane signaling of M₁ receptor activation to produce second messenger cADPR.

lipid microdomains; sphingolipid; lipid mediator; smooth muscle; calcium signaling

Recently, lipid-raft (LR) clustering on the cell membrane is emerging as a novel mechanism mediating the transmembrane signaling in response to various stimuli in a variety of cell types, including lymphocytes, endothelial cells, and neurons (15, 16, 41). It has been shown that clustered membrane LRs form membrane signaling platforms, in particular, the ceramide-enriched platforms or macrodomains. These lipid platforms may recruit or aggregate various signaling molecules such as trimeric G proteins, small G proteins, sphingomyelin (SM), tyrosine kinases, NADPH oxidase subunits, phosphatases, and many others, resulting in the activation of different signaling pathways. Recent studies have reported that LRs are closely associated with the CD38 pathway in various lymphocytes and these LRs may be responsible for endocytosis of CD38 and the activation of certain signaling pathways (35, 46). However, the identity of these LRs remains unclear, and it is also unknown whether LRs during its clustering are involved in cADPR-mediated Ca²⁺ signaling. In previous studies, a rapid activation and translocation of acid sphingomyelinase (ASMase) into LRs were observed in response to various stimuli such as FasL, TNF-, and endostatin (29, 33, 41). Moreover, our previous work also demonstrated that lysosomal ASMase contributes to the formation of LR redox signaling platforms by hydrolyzing SM to produce ceramide, which produces ceramide-enriched macrodomains or LR platforms, ultimately resulting in endothelial dysfunction (18). Based on these observations, the present study was designed to test the hypothesis that ceramide-enriched LR platforms may mediate an agonist-induced transmembrane signaling of CD38 and thereby participate in Oxo-induced CD38 activation to produce cADPR in coronary arterial myocytes (CAMs). To test this hypothesis, we first characterized the formation of ceramide-enriched LR clusters in CAMs in response to Oxo. We then examined the role of this LR clustering in aggregation and activation of CD38 in the membrane of these cells and explored the related molecular mechanisms mediating Oxo-induced ceramide production and LR platforms formation via ASMase/ceramide pathway. Furthermore, we determined whether this ceramide-enriched signaling platform with activated CD38 contributes to Ca²⁺ release in CAMs, ultimately leading to the constriction of coronary arteries.

	MATERIALS AND METHODS

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Bovine hearts were purchased from a local slaughterhouse and were used to isolate coronary artery smooth muscle cells. No living animals were used for the present study, and therefore there was no concern over vertebrate animal use.

Cell culture. Bovine CAMs were cultured as described previously (3, 42–45). Briefly, coronary arteries dissected from bovine hearts were first rinsed with 5% FBS in medium 199 containing 25 mM HEPES with 1% penicillin, 0.3% gentamycin, and 0.3% nystatin and then cut into segments, and the lumen was filled with 0.4% collagenase in medium 199. After 30 min of incubation at 37°C, the arteries were flushed with medium 199. The strips of denuded arteries were placed into gelatin-coated flasks with medium 199 containing 10% FBS with 1% L-glutamine, 0.1% tylosin, and 1% penicillin-streptomycin. CAMs migrated to the flasks within 3–5 days. Once cell growth was established, the arteries were removed and growing CAMs were cultured in medium 199 containing 20% FBS. The identification of CAMs was based on positive staining by an anti--actin antibody. Cells of passages 2–4 were used in the present study.

Confocal analysis of LR clusters in CAMs. Individual LRs are too small (50 nm in diameter) to be resolved by standard light microscopy; however, if LR components are cross-linked in living cells, clustered raft protein and lipid components can be visualized by fluorescence microscopy. For microscopic detection of LR platforms, CAMs were grown on glass coverslips and then treated with different doses of Oxo (20–120 µM; Sigma, St. Louis, MO) for 15 min to induce clustering of LRs. In additional groups of cells, LR disruptors filipin (1 µg; Sigma) or methyl-β-cyclodextrin (MCD; 100 µM; Sigma) or an ASMase inhibitor desipramine (Des, 10 µM; Sigma) were added and incubated for 20 min before Oxo stimulation.

These cells were then washed in cold PBS and fixed for 10 min in 4% paraformaldehyde and blocked with 1% BSA in TBS for 30 min. GM₁ gangliosides enriched in LRs were stained by Alexa488-labeled cholera toxin B (Alexa488-CTXB, 1 µg/ml) (Molecular Probes, Eugene, OR). The stained cells were then extensively washed, fixed in 4% paraformaldehyde for another 10 min, and mounted on glass slide with Vectashield mounting media (Vector, Burlingame, CA). The staining of LRs was visualized using an Olympus scanning confocal microscope (Olympus, Tokyo, Japan) at excitation/emission of 495/519 nm. The patch or macrodomain formation of Alexa488-labeled CTX, namely, gangliosides complex, represents the clusters of LR. Clustering was defined as one or several intense spots or patches, rather than diffuse fluorescence on the cell surface, whereas a vast majority of unstimulated cells displayed a homogenous or diffuse distribution of fluorescence throughout the membrane. In each experiment, the presence or absence of clustering in 200 cells was independently scored by unwitting researchers after the criteria for positive spots of fluorescence were specified. Cells that displayed a homogenous distribution of fluorescence were indicated negative. Results were given as the percentage of cells showing one or more clusters after indicated treatments.

Colocalization of LR clusters and CD38, ASMase, or ceramide in CAMs. For dual-staining detection of the colocalization of LRs and ceramide or ASMase, CAMs were first incubated with Alexa488-labeled CTX as described in Confocal analysis of LR clusters in CAMs and then with mouse anti-ceramide IgM antibody (1:200; Alexis Biochemicals, San Diego, CA) or goat anti-ASMase antibodies (1:200; Santa Cruz, Santa Cruz, CA) separately in different groups of cells, which was followed by Cy3-conjugated anti-mouse or Texas red-labeled anti-goat (Molecular Probes, Eugene, OR) secondary antibody as needed, respectively.

Fluorescence resonance energy transfer measurement. To further determine the molecular complex in LR clusters, CAMs were stained with tetramethylrhodamine isothiocyanate (TRITC) -labeled CTXB and FITC-labeled anti-CD38 antibody and then visualized under a confocal microscope. An acceptor bleaching protocol was employed to measure the fluorescence resonance energy transfer (FRET) efficiency (31, 36). After the prebleaching images were normally taken, the laser intensity at an excitation wavelength of the acceptor (TRITC) was increased from 50 to 98 W/cm² and continued to excite the sample cells for 2 min to bleach the acceptor fluorescence. After the excitation intensity was adjusted back to 50 W/cm², the postbleaching image was then taken. The FRET images were obtained by the subtraction of the prebleaching image from the postbleaching image and shown in blue color. After the measurement of FITC fluorescence intensity in images acquired at pre- and postbleaching as well as the FRET images, a FRET efficiency was calculated through the following formula: E = (FITC_post – FITC_pre)/FITC_post x 100% as described previously (14), where FITC fluorescence intensity was obtained from labeling of CD38.

Assay of ASMase activity. The activity of ASMase in CAMs was determined as described in our previous studies (39). Briefly, homogenates from CAMs were centrifuged at 1,000 g for 10 min to remove cell nuclei, and 50 µl of the supernatant homogenate were used for enzyme activity analysis. The ASMase activity was measured using radiolabeled substrate, [N-methyl-¹⁴C]-SM (Perkin-Elmer Life Sciences). The assay mixture contained 100 nmol of SM (1,154 dpm/nmol) in 100 mM sodium acetate (pH 5.0), 0.1% Triton X-100, and 0.1 mM EDTA. After incubation at 37°C for 1 h, the reaction was stopped by adding 1.5 ml of chloroform:methanol (2:1 vol/vol), followed by an addition of 0.2 ml of water. A portion of the aqueous phase was transferred to scintillation vials and counted in a liquid scintillation counter for radioactivity of the reaction product, [¹⁴C]choline phosphate.

Floatation of membrane LR fractions. To isolate LR microdomain fractions from cell membrane, CAMs were lysed in 1.5 ml morpholinoethanesulfonic acid-buffered sample buffer containing (in µmol/l) 25 morpholinoethanesulfonic acid, 150 NaCl, 1 EDTA, 1 PMSF, and 1 Na₃VO₄ and a mixture of "complete" protease inhibitors and 1% Triton X-100 (pH 6.5). Cell extracts were homogenized by five passages through a 25-gauge needle. Homogenates were adjusted with 60% OptiPrep Density Gradient medium to 40% and overlaid with discontinuous 30% to 5% OptiPrep Density Gradient medium. Samples were centrifuged at 32,000 rpm for 30 h at 4°C using a SW32.1 rotor. Fractions were collected from top to bottom. For immunoblot analysis of LR-associated proteins, these fractions were precipitated by mixing with equal volume of 30% trichloroacetic acid and 30 min of incubation on ice. Precipitated proteins were spun down by centrifugation at 13,000 rpm at 4°C for 15 min. The protein pellet was carefully washed with cold acetone twice, air dried, and then resuspended in 1 mol/l Tris·HCl (pH 8.0), which was ready for immunoblot analysis.

Western blot analysis. For immunodetection of LR-associated proteins, 50 µl of resuspended proteins were subjected to SDS-PAGE, transferred onto a nitrocellulose membrane, and blocked as described previously (41). The membrane was probed with primary monoclonal antibodies of anti-flotillin-1 (1:1,000, a LR marker proteins; BD Biosciences, San Jose, CA), anti-CD38 (1:1,000, BD Biosciences), or anti-ASMase (1:1,000, Santa Cruz) overnight at 4°C, followed by an incubation with horseradish peroxidase-labeled anti-mouse or anti-goat IgG (1:5,000). The immunoreactive bands were detected by chemiluminescence methods according to the manufacturer's instruction and visualized on Kodak Omat film. The intensity of the immunoreactive bands was quantified by densitometry.

HPLC analysis of ADP-ribosyl cyclase activity in CAMs. To determine ADP-ribosyl cyclase activity, homogenates from CAMs (100 µg protein) were incubated with 100 µM β-nicotinamide guanine dinucleotide (β-NGD⁺) at 37°C for 90 min. β-NGD⁺ was used as a substrate to determine ADP-ribosyl cyclase activity because this enzyme is able to convert NGD into cyclic GDP-ribose (cGDPR) at the same reaction efficiency as working to convert β-NAD⁺ into cADPR, but cGDPR unlike cADPR may not be hydrolyzed by cADPR hydrolase. Therefore, the use of β-NGD⁺ will maximally detect the production of this enzyme by the blockade of a further hydrolysis of its products. After the reaction, the mixtures were centrifuged at 4°C through an Amicon microultrafilter at 13,800 g to remove proteins, and then cGDPR was analyzed by HPLC with a fluorescence detector (Agilent 1100 series HPLC system and G1321aspectrofluorometer). The excitation wavelength of 300 nm and the emission wavelength of 410 nm were used to detect cGDPR produced via cADP-ribosyl cyclase. All HPLC data were collected and analyzed by an Agilent Chemstation. Nucleotides were resolved on a 3-µm Supelcosil LC-18 column (4.6 x 150 mm) with a 5-µm Supelcosil LC-18 guard column (4.6 x 20 mm, Supelco, Bellefonte, BA). The injection volume was 20 µl. The mobile phase consisted of 150 mM ammonium acetate (pH 5.5) containing 5% methanol (solvent A) and 50% methanol (solvent B). The solvent system was a linear gradient of 5% solvent B in A to 30% solvent B in A over 1 min, held for 25 min, and then increased to 50% solvent B over 1 min. The flow rate was 0.8 ml/min. Peak identities were confirmed by the comigration with known standards. Quantitative measurements were performed by the comparison of a known concentration of standards.

Measurement of intracellular Ca²⁺ concentration in CAMs. Determination of intracellular Ca²⁺ concentration in CAMs was performed to determine the contribution of LR-CD38 platforms to cADPR-mediated Ca²⁺ signaling. Briefly, CAMs were cultured on a glass coverslip to reach 60–70% confluence, and the culture medium was then removed. The cells were next loaded with fura-2 acetoxymethyl ester (fura-2 AM, 5 µM; Molecular Probes) at 37°C for 30 min and incubated for 20 min to allow a complete hydrolysis of intracellular fura-2 AM to fura-2 in a Ca²⁺-free Hanks' buffered saline solution containing (in mM) 137 NaCl, 5.4 KCl, 4.2 NaHCO₃, 3 Na₂HPO₄, 0.4 KH₂PO₄, 0.5 MgCl₂, 0.8 MgSO₄, 10 glucose, and 10 HEPES (pH 7.4). The coverslip was mounted horizontally on a Nikon Diaphoto TMD inverted microscope (Nikon, Japan). Oxo (80 µM) was added to the bath solution to induce Ca²⁺ release. This dose of Oxo was used in our several previous studies where muscarinic type 1 (M₁) receptor was activated and cADPR and related Ca²⁺ release were produced in CAMs (11, 38). To examine the specificity of Oxo and the role of LRs in Oxo-induced Ca²⁺ release, the cells were pretreated for 15 min with 8-bromo-cADPR (8-Br-cADPR, a cADPR antagonist at 30 µM), LR disruptors, filipin (1 µg) or MCD (100 µM), or an ASMase inhibitor, Des (10 µM), and then Oxo-induced Ca²⁺ release was redetermined. All these experiments were conducted in Ca²⁺-free Hanks' buffer. A SPOT digital camera (SPOT RT Monochrome; Diagnostic Instruments) was used to record fura-2 fluorescence images. Metafluor imaging and analysis software (Universal Imaging) was used to acquire, digitize, and store the images.

Vascular reactivity in perfused small coronary arteries in vitro. Vascular reactivity in isolated perfused and pressurized small bovine coronary artery was measured as described previously (11). The intramural coronary arteries (<300 µm in diameter) were dissected from fresh cow hearts and assembled between two glass tips. After a 60-min equilibration period under the transmural pressure of 60 mmHg, Oxo (80 µM) was added to the bath solution to induce vasoconstriction. When Oxo-induced contraction reached a stable plateau, the internal diameters of the arteries were measured and recorded. To examine the contribution of ASM/ceramide and LR/CD38 pathway to Oxo-induced vasoconstriction, the arteries were pretreated for 20 min with one of the following compounds: nicotinamide (Nicot; 6 mM; an inhibitor of ADP-ribosyl cyclase), 8-Br-cADPR (30 µM; a cADPR antagonist), LR disruptors, MCD (100 µM), and filipin (1 µg), or an ASMase inhibitor, Des (10 µM). Oxo (80 µM) was added and the vasoconstrictor response was observed as described in the protocol without these components. The contractile responses to Oxo were expressed as the percent reduction in vascular internal diameters.

Statistics. Data are presented as means ± SE. Significant differences between and within multiple groups were examined using ANOVA for repeated measures, followed by Duncan's multiple-range test. Student's t-test was used to determine the significance of difference in two groups of experiments. P < 0.05 was considered statistically significant.

	RESULTS

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Cofocal microscopy of Oxo-induced LR clustering in CAMs. Figure 1A presents the typical fluorescent confocal microscopic images depicting Alexa488-CTX-labeled patches on the cell membrane of CAMs. Under the resting condition (control), there was only a diffuse fluorescent staining on the cell membrane, indicating a possible distribution of a single LR. When CAMs were incubated with Oxo, some large fluorescent dots or patches were detected on the cell membrane, indicating LR patches or macrodomains. Figure 1B summarized the effects of different doses of Oxo on the LR clustering by counting these LR clusters or patches. It was found that under control condition, CAMs displayed a small percentage with LR clustering (19.6 ± 3.9%). After these cells were stimulated with Oxo, LR-clustered positive cells increased significantly in a dose-dependent manner. At 80 µM, Oxo increased LR clustering by 65.7 ± 9.4% (P < 0.05, n = 5). This Oxo-induced LR clustering effect was abolished by LR disruptors, MCD and filipin, respectively. Des, a selective inhibitor of ASMase, also inhibited this Oxo-induced LR clustering.

View larger version (22K): [in this window] [in a new window]   Fig. 1. Oxotremorine (Oxo)-induced lipid-raft (LR) clustering in coronary arterial myocytes (CAMs) membrane in the absence or presence different LR disruptors. A: representative images of control and Oxo-stimulated CAMs stained with Al488-cholera toxin B (CTXB). B: CAMs were stimulated with different doses of muscarinic type 1 (M1) receptor agonist, Oxo (20–120 µM) for 15 min to induce LR clustering. C: CAMs were stimulated with Oxo (80 µM, 15 min) before and after pretreatment with LR disruptors, methyl-β-cyclodextrin (MCD; 100 µM), filipin (1 µg), or with a selective acid sphingomyelinase (ASMase) inhibitor, desipramine (Des, 10 µM) for 20 min. Shown is the percentage of cells displaying LR clustering. Values presented are means ± SE (n = 5 experiments with analysis from more than 1,000 cells). *P < 0.05 and **P < 0.01 vs. control; ##P < 0.01 vs. Oxo-treated group.

View larger version (36K): [in this window] [in a new window]   Fig. 2. Fluorescence resonance energy transfer (FRET) between a fluorophore pair, FITC (donor) and tetramethylrhodamine isothiocyanate (TRITC; acceptor) labeled anti-CD38 antibody and LR component, GM1 binder, CTXB, respectively. Acceptor (TRITC) bleaching protocol was applied to detect the FRET efficiency. A: typical images depicting FRET between FITC-conjugated anti-CD38 antibody and TRITC-conjugated CTXB in a control and Oxo-treated CAM, respectively. B: means ± SE of FRET efficiency from 5 experiments. Oxo was found to increase the FRET efficiency, and LR disruptors, MCD (100 µM), filipin (1 µg) or ASMase inhibitor Des (10 µM) attenuated Oxo-induced increase in FRET efficiency. **P < 0.01 vs. control; ##P < 0.01 vs. Oxo-treated group.

View larger version (19K): [in this window] [in a new window]   Fig. 3. Western blot analysis of CD38 and ASMase in LR fractions isolated from CAMs stimulated by Oxo. A: CAMs were treated with Oxo (80 µM, 15 min) alone or with 20-min pretreatment of MCD (100 µM), filipin (1 µg), or Des (10 µM). Fractions between 5% and 30% gradients were designated as LRs as indicated by the marker protein flotillin-1. The blot pattern for CD38 and ASMase represents 5 individual experiments. B: quantified data of the ratio of CD38 or ASMase in LR fraction to that of total in each membrane blot (LR/Total). It was found that Oxo stimulated both CD38 and ASMase aggregation into LR fractions, which was significantly attenuated by LR disruptors and ASMase inhibitors. *P < 0.05 vs. control; #P > 0.05 vs. control (n = 5 experiments).

View larger version (67K): [in this window] [in a new window]   Fig. 4. Confocal microscopic analysis of ceramide (Ceram) and ASMase colocalization in LR clusters in CAMs. A: the cells stained with Texas red (TR)-conjugated anti-ASMase antibody and Alexa488 (Al488)-CTXB. B: the cells stained with Cy3-conjugated anti-ceramide antibody and Alexa488-CTXB. Ceramide and ASMase were found to be colocalized with LR marker when CAMs were stimulated by Oxo. This Oxo-induced colocalization can be blocked by pretreatment of the cells with LR disruptors (MCD or filipin) and ASMase inhibitor, Des.

View larger version (15K): [in this window] [in a new window]   Fig. 5. Effects of Oxo on ASMase and ADP-ribosylcyclase activity in CAMs in the absence or presence of LR disruptors. A: summarized ASMase activity of CAMs treated with Oxo (80 µM, 15 min) alone or with 20-min pretreatment of MCD (100 µM), filipin (1 µg), or Des (10 µM). Values are means ± SE of 5 experiments. Prot, protein. **P < 0.01 vs. control; #P < 0.05 vs. Oxo-treated group. B: summarized ADP-ribosylcyclase activity of CAMs treated with Oxo (80 µM, 15 min) alone or with 20-min pretreatment of MCD (100 µM), filipin (1 µg), or nicotinamide (Nicot; 6 mM) or Des (10 µM). Values are means ± SE from 5 experiments. **P < 0.01 vs. control (Ctrl); #P < 0.05 vs. Oxo-treated group; ##P < 0.01.

Association of ceramide-enriched lipid-CD38 platforms with Oxo-induced intracellular Ca²⁺ release in CAMs. To further determine the role of ceramide-enriched lipid-CD38 platforms in the regulation of intracellular Ca²⁺ release, we examined Oxo-induced intracellular Ca²⁺ release in CAMs under control conditions and when they were treated with LR disruptors, MCD or filipin, and ASMase inhibitor, Des. In Fig. 6A, typical microscopic digitalized signal plots of Ca²⁺ release within CAMs bathed in Ca²⁺-free solution are presented. It is clear that in the presence of 8-Br-cADPR (a cADPR antagonist), Des, MCD or filipin, Oxo-induced Ca²⁺ release in CAMs was significantly reduced compared with Oxo stimulation alone. Calculated Ca²⁺ concentrations under different conditions are presented in Fig. 6B. In response to Oxo stimulation, intracellular Ca²⁺ concentration increased from 149.8 ± 32.7 to 495.0 ± 130.6 nM in CAMs. This Oxo-induced increase in intracellular Ca²⁺ levels could be attenuated or blocked by inhibition of LR clustering or formation of ceramide-enriched platforms either with LR disruptors or ASMase inhibitor.

View larger version (15K): [in this window] [in a new window]   Fig. 6. Association of ceramide-enriched lipid-CD38 platforms with Oxo-induced intracellular Ca2+ release in CAMs and vessel constriction in small coronary arteries. A: representative recording of fura-2 Ca2+ signals by a high speed wavelength switch microscopic imaging system. F340/F380, emission fluorescence ratio with excitation at 340 and 380 nm. B: summarized intracellular free Ca2+ level in CAMs treated with Oxo (80 µM, 15 min) alone or with 20-min pretreatment of MCD (100 µM), filipin (1 µg), 8-bromo-cADPR (8-Br; 30 µM), or Des (10 µM). Values are means ± SE from 5 experiments. [Ca2+]i, intracellular Ca2+ concentration. C: summarized data showing the constriction of small coronary arteries treated with Oxo (80 µM, 15 min) alone or with 20 min pretreatment of MCD (100 µM), filipin (1 µg), or Nicot (6 mM) or Des (10 µM). Values are means ± SE of 5 experiments. *P < 0.05 vs. Oxo-treated group.

	DISCUSSION

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
The main findings of the present study are that 1) Oxo induced LR clustering in CAMs as shown by the formation of larger membrane LR patches as detected by confocal microscopy; 2) Oxo induced an aggregation of CD38 in LR clusters with enriched ceramide, which resulted in the increased activity of CD38 as ADP-ribosylcyclase, and disruption of LRs inhibited the effects of Oxo on this enzyme activity; and 3) blockade of ASMase/ceramide inhibited Oxo-induced LR clustering and consequent CD38 activation and cADPR production, whereby an Oxo-induced increase in intracellular Ca²⁺ release and vasoconstriction was significantly attenuated. These results support our hypothesis that ceramide-enriched LR platforms mediate Oxo-induced transmembrane signaling of CD38 and thereby activate its ADP-ribosylcyclase to produce cADPR in CAMs.

Despite the increasing evidence that cADPR signaling becomes an essential mechanism in the regulation of the intracellular Ca²⁺ level in a variety of mammalian cells (6, 19), so far it remains unknown what mechanism mediates cADPR production in response to various agonists or stimuli and how a transmembrane signaling upon agonist stimulation occurs to activate cADPR producing enzyme and leads to responses of intracellular effectors. Moreover, there is evidence that CD38, a major enzyme producing cADPR in mammalian cells or tissues, is mainly present on the surface of cells serving as an ectoenzyme (1). It is imperative to know how an ectoenzyme could produce a second messenger to mediate intracellular Ca²⁺ signaling as an important function of cADPR. In the present study, we tested a novel hypothesis that LRs may form a signaling platform in vascular smooth muscle cells where CD38 can be aggregated and activated to produce cADPR when these cells are stimulated by agonists. This LRs-mediated transmembrane signaling may represent a novel mechanism initiating cADRP production and subsequent signaling cascade. The rationale of this hypothesis is based on the fact that the LRs may serve as anchoring platforms for organizing components of the signal transduction systems (8, 12, 30) and thereby participate in cellular signaling. In this regard, these LRs are known as specialized membrane microdomains rich of cholesterol and sphingolipids, which act as organizing centers by sequestering specific sets of proteins for different cellular activities such as membrane molecular trafficking and signal transduction (2). In vascular smooth muscle cells, LRs have been demonstrated to play an important role in several cell signaling pathways, such as agonist-induced Ca²⁺ release, phosphorylation of EGF receptor, and activation of RhoA (7, 17, 24). Using confocal microscopic analysis of GM₁ labeling by CTX as a marker of LR clusters, we found that under control conditions, LRs were diffusely distributed throughout the membrane of CAMs and that stimulation of these cells with Oxo resulted in a dose-dependent formation of CTX-positive fluorescent patches, which represented LR clusters or macrodomains. This suggests that LR clustering occurs in arterial smooth muscle cells in response to agonists such as Oxo. Given its well-known signaling role, this LR clustering may be of importance in mediating signal transduction or functional response in these vascular smooth muscles. Indeed, we demonstrated that this LR clustering was coupled to CD38 aggregation, as shown in confocal microscopic colocalization analysis, FRET detection, and membrane flotation of LR fractions. These LR-CD38 complex or membrane platforms may result in CD38 translocation and activation by agonists such as Oxo. To our knowledge, these results for the first time provide direct evidence that LRs are able to be clustered with aggregation of CD38 in vascular smooth muscle cells. In previous studies, this LR-mediated CD38 clustering was also reported in T-cells or B-cells, which participates in the regulation of T-cell or B-cell function by facilitating critical associations or interactions with other signaling molecules such as myosin heavy chain class II, CD9, N-Ras, Akt, Erk, Lck and CD3- (4, 25, 46, 48). However, the regulation of lymphocyte function by LR clustering has not been linked to its function of cADPR production and consequent Ca²⁺ mobilization.

In the present study, we provided further evidence that the aggregation of CD38 via LR clustering is involved in the activation of this enzyme to produce cADPR. By HPLC analysis of cGDPR production as an ADP-ribosyl cyclase activity, Oxo was found to significantly increase the activity of CD38 in CAMs, which was blocked by LR disruptors MCD and filipin. This suggests that LR clustering in these cells importantly contribute to the activation of CD38 as a cADPR-producing enzyme. To further determine the role of LR clustering in cADPR-mediated signaling, we addressed whether the activation of CD38 via LR clustering is attributed to Oxo-induced Ca²⁺ release response in CAMs. It has been reported that CD38 is a crucial pathway mediating Ca²⁺ release, and our previous work also demonstrated that cADPR-mediated Ca²⁺ mobilization represents an important signaling pathway participating in the Ca²⁺ regulation in vascular smooth muscle cells and in the vasoconstrictor response of coronary arteries when M₁ ACh receptor is activated (40). Consistent with these previous studies, the present study found that Oxo induced Ca²⁺ release from the SR in CAMs buffered in Ca²⁺-free solution and that 8-Br-cADPR, an antagonist of cADPR, could block the action of Oxo. Interestingly, in the presence of LR disruptors, MCD or filipin, Oxo-induced Ca²⁺ release was substantially attenuated. In another series of experiments, we also examined the contribution of this LR clustering with CD38 to the vasoconstrictor response to Oxo. It was found that Oxo induced significant vasoconstriction with a maximal response of 47.2 ± 6.8% in perfused and pressurized small coronary arteries, which was significantly blocked by the LR disruptor, MCD or filipin. Taken together, these results indicate that LRs and their clustering importantly participate in the regulation of vascular function associated with CD38 activation and cADPR-mediated Ca²⁺ release in coronary arteries. To our knowledge, this represents the first report elucidating the functional association of LR clustering with CD38 activity to produce cADPR in the regulation of intracellular Ca²⁺ level of arterial myocytes and vasomotor response in coronary arteries. Previous studies also demonstrated the formation of LR-CD38 complex in lymphocytes in response to different stimuli (4, 25, 46). However, these studies did not demonstrate the correlation between the production of cADPR and agonist receptor functions when LR clustering occurred, but they assumed that CD38 may serve as a pleiotropic molecule in LR clusters, whose behavior or function is independent from its enzymatic activity in these cells (46). In some other studies, CD38 in LRs has been demonstrated as an interacting membrane molecule to facilitate the formation of different signaling complex in lymphocytes, which activates several different phosphorylation pathways to regulate cell proliferation or apoptosis (7, 48).

It should be noted that although Oxo or M₁ agonist may not be a major regulator of coronary vascular tone under physiological conditions, the use of this compound represents a prototype of agonists that stimulates cADPR production and induces vasoconstriction of bovine coronary arteries because bovine coronary arteries did not respond to angiotensin II or norepinephrine to produce vasoconstriction based on our experience working on this type of arteries for more than 10 years. Another comparable vasoconstrictor in these arteries is to thromboxane A₂ mimetic, U-46619, a commonly used agonist in these bovine arteries, but this compound produces vasoconstriction through Ins(1,4,5)P₃ independent of LRs. With respect to agonists or stimuli that use cADPR as second messengers, recent studies have demonstrated that there are Oxo in smooth muscle cells, cholecystokinin in pancreatic acinar cells, glucose in pancreatic β-cells, physiological contact or fertilization in the eggs, histamine and oxytoxin in myometrial cells, and thrombin in platelets. Based our results in using Oxo, an agonist producing comparable vasoconstriction to Ins(1,4,5)P₃ stimulator, we believe the LR-mediated activation of ADP-ribosylcyclase demonstrated in the present study is mainly attributed to this type of agonists. This LR-signaling mechanism may not be used by other Ca²⁺ regulatory pathways.

To explore the mechanism by which Oxo induces the formation of LR clusters with CD38 in CAMs, we tested a hypothesis that ASMase or ceramide plays a critical role in Oxo-induced LR clustering and thereby contributes to corresponding functional changes in CAMs or coronary arterial smooth muscle. There is considerable evidence that rapid activation and translocation of ASMase into cell membrane trigger or facilitate the formation of LR clusters in response to different stimuli (22). Recent studies in our laboratory have shown that lysosome-associated vesicle transportation or trafficking of ASMase from intracellular compartments to cell membrane is a prerequisite for ASMase activation in the process of LR clustering in endothelial cells (18). This ASMase translocated into cell membrane hydrolyzes SM to produce ceramide and leads to the formation of ceramide-enriched macrodomains or LR platforms, which cluster or recruit some receptors or signaling molecules (22). The present study provided several lines of evidence that this translocated ASMase and consequently produced ceramide are present in LR clusters with CD38 in CAMs and that ceramide production from ASMase importantly contributes to the formation and function of LR clusters with CD38. First, under stimulation of Oxo, ASMase and ceramide were found to be aggregated in LR clusters with CD38, as shown by the colocalization of GM₁ labeled by Alexa-CTX and ASMase, and ceramide labeled by Texas red-conjugated anti-ASMase antibody and Cy3-conjugated anti-ceramide antibody, respectively. Second, by membrane floatation, ASMase was found to be enriched in LR fractions and ASMase activity significantly increased in these fractions. The ASMase inhibitor, Des, could block these effects, but LR disruptors did not have obvious effects on Oxo-induced ASMase activation. These results suggest that ASMase enrichment and activation are involved in Oxo-induced LR clustering, and even ASMase activation precedes the LR clustering because the LR disruptors could not block the increased ASMase activity stimulated by Oxo. Third, a biochemical analysis demonstrated that ASMase inhibition by Des significantly blocked ADP-ribosylcyclase activity of CD38 in CAMs, indicating that ASMase importantly contributes to CD38 activation to produce cADPR. Fourth, functional studies by the measuring intracellular Ca²⁺ level in CAMs and the vasoconstrictor response of coronary arteries to Oxo provided evidence that ASMase inhibition attenuated the effect of Oxo-induced Ca²⁺ activation and vasoconstriction in these arteries. All these results support the view that ASMase and its product ceramide pathway play a crucial role in Oxo-induced LR clustering and consequently CD38 activation and that the formation of these ceramide-enriched lipid platforms importantly participate in the CD38-cADPR-mediated signaling upon activation of M₁ receptor in CAMs.

Oxo or some other agonists may produce Ca²⁺ release and consequent vasoconstriction through several pathways such as activation of plasma membrane Ca²⁺ channels and Ins(1,4,5)P₃ production and resulting intracellular Ca²⁺ release. However, these two pathways will be blocked by using a Ca²⁺-free bath solution in our Ca²⁺ assay and vasoreactivity studies as a routine in such studies. Under this condition, Ca²⁺ influx is blocked and therefore its role in mediating Oxo action was minimized. In addition, it was reported that when cells are bathed in Ca²⁺ free solution, PLC failed to respond to any stimulus to produce Ins(1,4,5)P₃ (34). Therefore, there was only a minimal action of Ins(1,4,5)P₃ in such preparations. However, our results did not exclude the action of Ca²⁺ influx or Ins(1,4,5)P₃ in the action of Oxo or other agonists under other conditions.

There was a concern regarding alternative pathways for cADPR production. It has been demonstrated that a soluble protein, ADP-ribosyl cyclase and its membrane-bound homologous CD38 and CD157, are involved in the production of cADPR with the substrate NAD⁺ by a cyclizing reaction (9, 23), which has been shown in a variety of cells and tissues such as sea urchin eggs, pancreatic acinar cells, human T lymphocytes, rat brain, and rat smooth muscle cells. Over the last 10 years, we have demonstrated that this cADPR-mediated Ca²⁺ signaling is present in cardiovascular tissues such as the myocardium, renal microvessel, and coronary arteries (10, 32, 38). We also demonstrated that ADP-ribosylcyclases activity is primarily derived from CD38 (a GPI-anchored protein) in coronary arterial smooth muscle. In addition, other studies reported that CD38 internalization is of importance in mediating cADP-ribose production in cell cytosol (14, 47). Therefore, based on current understanding, the high level of ADP-ribosylcyclase activity to convert NAD⁺ to cADPR may be associated with the internalization of a membrane-bound enzyme, although there may be some unidentified pathways. One such unidentified pathway was reported recently in myometrial cells, which possesses ADP-ribosylcyclase activity to produce cADPR and NAADP independent of CD38 and CD157 (28). In addition, CD38-mediated cADPR has been reported to be enhanced by protein kinase A and cAMP-regulated guanine nucleotide exchange factor II (20). It seems that different type of cells may use different enzymatic pathways to produce cADPR. This CD38-independent pathway for cADPR production has not yet been demonstrated in vascular smooth muscle cells. However, our results in the present studies did not exclude the role of this CD38-independent pathway in mediating vascular reactivity under other conditions or when these cells are stimulated by other agonists.

In summary, the present study demonstrated that Oxo stimulated LR clustering in CAMs and that a membrane signaling complex or platforms could be formed by LR clustering. This LR clustering or formation of signaling platforms importantly participates in Ca²⁺ transient response of CAMs to Oxo and corresponding coronary arterial constriction. The Oxo-induced formation of LR signaling platform with CD38 as a complex was dependent on the enrichment and activation of ASMase and consequent production of ceramide. Therefore, it is the ceramide-enriched macrodomain or lipid platforms that mediate the action of Oxo in mediating CD38 translocation and activation, thereby producing cADPR to induce Ca²⁺ release from the SR of CAMs. This LR clustering and consequent formation of signaling platforms may represent an important mechanism that is implicated in CD38/cADPR-mediated signaling in coronary arterial smooth muscle in response to vasoactive agonists such as Oxo.

	GRANTS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
This study was supported by National Institutes of Health Grants HL-57244, HL-75316, and DK-54927.

	FOOTNOTES

 

Address for reprint requests and other correspondence: P.-L. Li, Dept. of Pharmacology and Toxicology, Medical College of Virginia Campus, Virginia Commonwealth Univ., 410 N. 12th St., Richmond, VA 23298 (e-mail: pli{at}vcu.edu)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

^* S.-J. Jia and S. Jin contribute equally to this work.

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