1 Department of Medicine, University of Florida, and 2 Medical Research Service, Malcom Randall Veterans Affairs Medical Center, Gainesville, Florida 32608-1197
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ABSTRACT |
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We investigated whether nitric oxide (NO) upregulates a cyclic nucleotide-gated (CNG) channel and whether this contributes to sustained elevation of intracellular calcium levels ([Ca2+]i) in porcine pulmonary artery endothelial cells (PAEC). Exposure of PAEC to an NO donor, NOC-18 (1 mM), for 18 h increased the protein and mRNA levels of CNGA2 40 and 50%, respectively (P < 0.05). [Ca2+]i in NO-treated cells was increased 50%, and this increase was maintained for up to 12 h after removal of NOC-18 from medium. Extracellular calcium is required for the increase in [Ca2+]i in NO-treated cells. Thapsigargin induced a rapid cytosolic calcium rise, whereas both a CNG and a nonselective cation channel blocker caused a faster decline in [Ca2+]i, suggesting that capacitive calcium entry contributes to the elevated calcium levels. Antisense inhibition of CNGA2 expression attenuated the NO-induced increases in CNGA2 expression and [Ca2+]i and in capacitive calcium entry. Our results demonstrate that exogenous NO upregulates CNGA2 expression and that this is associated with elevated [Ca2+]i and capacitive calcium entry in porcine PAEC.
nitric oxide; lung; gene; upregulation
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INTRODUCTION |
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PATHOLOGICAL CONDITIONS associated with infections or injury lead to increased levels of nitric oxide (NO) and consequent cell injury and apoptosis in a variety of cell types including endothelial cells (35, 39, 48, 59). Excessive NO has been reported to elevate intracellular calcium levels (5, 10). The sustained high levels of intracellular calcium are cytotoxic to cells and are essential for NO-induced endothelial apoptosis (9, 23, 30, 32, 34). NO is known to elevate intracellular calcium levels through calcium release from intracellular stores, through the influx and extrusion of calcium across the plasma membrane, and through intracellular and intercellular diffusion of molecules, such as inositol 1,4,5-trisphosphate, which binds to its receptor on the endoplasmic reticulum and subsequently enhances the release of calcium from intracellular stores.
It is not known how NO-elevated calcium levels are sustained in a cell after the NO stimulus is removed, but NO upregulation of calcium-permeable channels, e.g., nonselective cation channels and voltage-dependent channels, may contribute to the sustained elevation of intracellular calcium levels (21, 27, 28, 57). Calcium-permeable, nonselective cation channels are believed to be a critical calcium entry pathway in the vascular endothelium (1, 26). Resting membrane potential is the electromotive force for moving ions, including calcium, through these channels. The calcium-permeable, nonselective cation channels in vascular endothelium have not been cloned; however, cyclic nucleotide-gated (CNG) cation channels, originally thought to be unique to sensory signal transduction in retinal and olfactory cells (22, 54), have been cloned and shown to be abundantly expressed in vascular endothelial cells in vivo and in vitro (18, 20, 52, 53). For instance, the mRNA for a rod-type CNG channel has been detected in tissues such as eye, lung, spleen, thymus, and smooth muscle (18, 20) and in various endothelia including those from aorta, medium-sized mesenteric arteries, and small mesenteric arteries (52, 53). The identified CNG channel subunits belong to two physiologically distinct subfamilies, CNGA and CNGB (11). There are four members, CNGA1, CNGA2, CNGA3, and CNGA4, in the CNGA subfamily and two members, CNGB1 and CNGB3, in the CNGB subfamily (12, 40, 50, 58). CNGA2 and CNGA4 can be activated by both cAMP and cGMP (13). CNGA2 can form a functional channel when expressed alone in heterologous expression systems. In contrast, CNGA4 does not form a functional channel alone but can modulate the channel properties of CNGA2. Native functional CNG channels may exist as heteromultimers containing some combination of both subunits. CNG cation channels are permeable to both calcium and monovalent cations, and channel activity is regulated by cyclic nucleotides (cAMP or cGMP).
The physiological role of CNG channels in endothelial cells is not fully understood, but it has been recently shown that CNG channels are involved in store-operated calcium entry in rat pulmonary artery endothelial cells (52). Thus it is possible that exogenous NO can upregulate the expression and/ or activity of CNG channels in lung endothelial cells. An NO-induced increase in CNG channel expression or activity could contribute to elevation of intracellular calcium. Because an increase in CNG channels would not be degraded immediately after removal of exogenous NO, it may also contribute to a sustained elevation of intracellular calcium. NO cytotoxicity is associated with sustained elevation of intracellular calcium (9, 23, 30, 32, 34). However, there is very little information about mechanisms to explain how exogenous NO-induced elevation of intracellular calcium is maintained after removal of NO. In the present studies, we investigated whether NO upregulates CNG channels and, if so, whether this contributes to sustained elevation of intracellular calcium levels via store-operated calcium entry in porcine pulmonary artery endothelial cells (PAEC).
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MATERIALS AND METHODS |
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Chemicals. The CNG channel antibodies were purchased from Alpha Diagnostic International (San Antonio, TX). The PolyATract mRNA isolation system was purchased from Promega (Madison, WI). Digoxigenin-labeled dideoxyuridinetriphosphates and Genius labeling and detection kits were obtained from Boehringer Mannheim (Indianapolis, IN). 2,2'-(Hydroxynitrosohydrazino)bis-ethanamine (NOC-18) and 2- phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (PTIO) were purchased from Calbiochem (San Diego, CA), and L-cis-diltiazem hydrochloride was from Biomol Research Laboratories (Plymouth Meeting, PA). All other chemicals were obtained from Fisher Scientific (Orlando, FL).
Cell culture and exposure to NO donor. PAEC were obtained from the main pulmonary artery of 6-mo-old pigs and were propagated in monolayer cultures as described by Zhang et al. (55). Fifth- to seventh-passage cells in postconfluent monolayers maintained in RPMI 1640 medium (Life Technologies, Grand Island, NY) with 4% fetal bovine serum (HyClone Laboratories, Logan, UT) and antibiotics were used for all experiments.
In the present study, NOC-18 and PTIO were used as NO donor and NO scavenger, respectively. To examine effects of prolonged exposure to NOC-18 and PTIO on cell viability, we incubated PAEC in wells of a 96-well plate in RPMI 1640 medium containing 0, 0.01, 0.02, 0.039, 0.078, 0.16, 0.31, 0.625, 1.25, 2.5, 5, and 10 mM NOC-18 and 0, 0.01, 0.02, 0.039, 0.078, 0.16, 0.31, 0.625, 1.25, 2.5, 5, and 10 mM PTIO for 18 h, respectively. The Rapid Cell Viability kit (Oncogene) was used to determine cell viability by following the manufacturer's instructions (data not shown). Viabilities of cells treated with concentrations of NOC-18 >5 mM or of PTIO > 5 mM were lower than those of control cells, i.e., incubated in 0 mM NOC-18 or PTIO. Therefore, 1 mM NOC-18, 2 mM PTIO, or 1 mM NOC-18 plus 2 mM PTIO was used in the present studies, because cell viabilities under these conditions were comparable to their controls. It has been reported that NO released from 1 mM NOC-18 results in steady-state levels of 1-3 µM NO in medium without any cofactors (3) (product technique data of Calbiochem). This is comparable to concentrations (1-30 µM) produced by endogenous inducible NO synthase in culture media and in plasma after cytokine stimulation or lung injury (43, 44). NO concentrations used in the clinical arena for inhalation treatment of pulmonary hypertension, acute lung injury, and cardiopulmonary failure are 15-30 ppm (5-10 µM) (4, 6, 24, 47). Given that the NO concentrations to which the lung endothelium is exposed are slightly lower than that in the inhaled NO gas, exposure of PAEC to 1-3 µM NO constitutes a physiologically relevant cellular model with which to study NO-mediated changes in CNG channel expression, intracellular calcium levels, and CNG channel-mediated capacitive calcium entry in vascular endothelial cells.Immunoblot analysis of protein levels of CNG channels in PAEC. Cell monolayers in 100-mm dishes were incubated in serum-free RPMI medium containing 0 (control) or 1 mM NOC-18 (NO) at 37°C for 18 h. Cell lysates (40 µg of protein) were loaded on 7.5% SDS-PAGE gels, electrophoresed, and blotted on polyvinylidene difluoride membranes as previously described (56). Anti-rat CNGB1 and anti-rat CNGA2 and CNGA4 antibodies (10 µg/ ml) were used to detect the CNG channel proteins in porcine PAEC. Band densities were determined on a densitometer scanner (MultiImager; Bio-Rad) to measure relative protein levels of the CNG channels in the endothelial cells.
To verify effects of NO released from NOC-18 on protein levels of CNG channels, we used an NO scavenger, PTIO. PAEC were preincubated in medium containing PTIO (2 mM) for 2 h, after which 0 mM (control) or 1 mM NOC-18 was added to the medium. Cell lysates (40 µM) were subjected to immunoblot analysis of CNGA2. To determine whether NO-modulated CNGA2 expression in PAEC is sustained after NO is removed from the medium, we subsequently incubated some control and NO-treated cells in medium without NOC-18 for 12 h. Cells were then collected for immunoblot analysis of CNGA2. To determine whether the by-product of NOC-18, H2N-CH2-NH-CH2-NH2, affects protein levels of CNG channels, we dissolved 10 mM NOC-18 in a Hanks' balanced salt solution (HBSS) buffer and kept it as a stock solution at room temperature for 10 days (about 5× half-life of NOC-18) to deplete NO. PAEC were then incubated in the NO-depleted solution (1 mM) and analyzed for protein levels of CNGA2. Relative levels of CNGA2 protein in by-product-treated PAEC were comparable to those in control cells (data not shown), indicating that elevated levels of CNGA2 protein in cells exposed to 1 mM NOC-18 were due to effects of NO and not NOC-18 by-products.RNA isolation and RT-PCR.
To assess the mRNA levels of CNGA2, we extracted total poly(A) RNA
directly from control and NOC-18 (1 mM, 18 h)-exposed PAEC with
the PolyATract mRNA isolation system (Promega) by following the
manufacturer's instructions (56). Based on the 3'-end
region of the isolated porcine CNGA2 cDNA (unpublished data), two
gene-specific primers were designed, a sense primer (5'-CCC TCG AAA GCA
ATA AAG ATG AGA AGA-3') and an antisense primer (5'-TTC CTG ATG GAA AGG
TTT ACG GGA ACA-3'). One-step RT-PCR was performed to amplify a 274-bp
fragment out of the mRNA target by using the Titan One Tube TR-PCR kit
(Boehringer Mannheim). Cycling parameters were as follows: one cycle of
94°C for 2 min; 10 cycles of 94°C for 30 s, 65°C for 30 s, and 68°C for 50 s; and 25 cycles of 94°C for 30 s,
65°C for 30 s, and 68°C for 55 s with cycle elongation of
5 s for each additional cycle. Primers for -actin were
used under identical conditions as an internal control. The RT-PCR products were analyzed on a 2% agarose gel. Band intensities were quantified on the densitometer scanner.
Determination of intracellular calcium levels. Changes in intracellular free ionized calcium concentration were measured by using the fluorescent calcium indicator fluo 3 acetoxymethyl ester (fluo 3-AM; Molecular Probes, Eugene, OR) and confocal microscopy. This cell-permeable dye can be hydrolyzed by intracellular esterases and trapped in cells as fluo 3. PAEC were grown in RPMI 1640 medium in 35-mm dishes with coverslips until cells reached 80-90% confluency. The preconfluent cell monolayers were then incubated in HEPES-buffered HBSS alone and in HBSS plus NOC-18 (1 mM) at 37°C for 6 h. To assess effects of calcium influx on NO regulation of intracellular calcium levels, we incubated some cells in the calcium-free HBSS containing 100 µM EGTA with or without exposure to 1 mM NOC-18 for 6 h, because cells incubated in the calcium-free HBSS for 6 h did not exhibit changes in morphology or viability. Thereafter, the cells were washed three times with ice-cold HBSS and loaded with 4 µM fluo 3-AM in HBSS for 30 min at room temperature in the dark. The dye-loaded cells were washed three times with cold HBSS and measured for fluorescent intensity by using a Zeiss LSM 510 laser scanning confocal microscope with an excitation wavelength of 488 nm and an emission wavelength of 526 nm. Fluorescence intensities (arbitrary units, a.u.) were measured in 50 selected cells and 5 empty spots (backgrounds). Average relative fluorescence intensities of control and NO-treated cells were calculated after being normalized to backgrounds.
To determine whether capacitive calcium entry into NO-treated endothelial cells contributes to the rise in intracellular calcium levels, we used an inhibitor of endoplasmic reticulum calcium ATPase, thapsigargin (Tg), to liberate calcium from intracellular stores. Cell monolayers on 35-mm dishes with coverslips were incubated in medium with NOC-18 (1 mM) for 18 h. Intracellular calcium levels were measured by using fluo 3-AM and confocal microscopy. Fluorescence intensities of 50 cells and 5 empty spots (backgrounds) were monitored. After stable baselines were obtained, Tg (final concentration 10 µM) was added to the medium. Tracings of fluorescence intensity changes of cells induced by Tg were recorded. Means of background fluorescence intensities were subtracted from means of cell fluorescence intensities. The ratios of F and F0 (means for the first 220 s) were calculated. To verify that calcium influx into cells contributes to the rise in intracellular calcium levels, we incubated some fluo 3-AM-loaded cells in calcium-free HBSS. Tracings of fluorescence intensities were assessed, and the F/F0 ratios were calculated. To determine whether CNG channels contribute to the capacitive calcium influx, we used a known blocker of native CNG channels, L-cis-diltiazem hydrochloride (Dil; final concentration 500 µM) (15, 25, 41, 46), and a nonselective cation channel blocker, LaCl3 (La3+; final concentration 100 µM) (16, 49), after cells were depleted of calcium stores by Tg. Tracings of F/F0 ratio changes were then assessed.Antisense inhibition of porcine CNGA2 gene expression. PAEC were transfected with an inducible vector, pIND/V5-His-Topo (Invitrogen, San Diego, CA), containing antisense CNGA2 gene or a GFP (green fluorescent protein; Clontech) gene (transfection control). In brief, the cDNA for CNGA2 was rescued from plasmid pNO18 (obtained from our differential screening experiment, unpublished data), and the ends were treated with Taq DNA polymerase and cloned into a mammalian expression vector to form pIND-CNGA2. The antisense orientation of the insert was verified by restriction enzyme digestion and sequencing (DNA Sequencing Laboratory, Interdisciplinary Center for Biotechnology Research, University of Florida). As a control for the transfection study, cDNA for GFP was cloned downstream of the inducible promoter to form pIND-GFP. PAEC were stably transfected with the inducible expression system encoding the antisense porcine CNGA2. To generate inducible clones, we transfected cell monolayers (passage 3) first with pVgRXR (a gene required for induction of antisense CNGA2 gene expression) and then with the pIND-CNGA2 construct. Transfection was carried out as described previously (55). Stable transfects were selected by culturing the cells in RPMI medium containing an antibiotic (neomycin) to eliminate the untransfected cells. For controls, clones containing GFP gene were generated as above with pIND-GFP instead of pIND-CNGA2 vectors.
The transfects were cultured in RPMI medium with or without 5 µM Ponasterone A for 24 h. Immunoblot analysis of CNGA2 in the pIND-GFP- or pIND-CNGA2-transfected cells was carried out to confirm the inhibition of CNGA2 expression. To determine the effects of inhibition of CNGA2 expression on NO-increased intracellular calcium levels and calcium influx, we incubated the antisense CNGA2- and the GFP-transfected PAEC in medium with or without NOC-18 (1 mM) for 18 h. Intracellular calcium levels were measured in these cells by using the fluo 3-AM calcium indicator and confocal microscopy. Tg, Dil, and La3+ were used to examine calcium store-operated calcium influx in antisense CNGA2- and GFP-transfected cells as described above.Statistical analysis. Within each experiment, control and treated cells were matched for cell line, number of passages, and state of cell confluence. Statistical significance for the effects of NO on CNGA2 protein/mRNA and fluorescence intensities was determined by analysis of variance and Student's t-test (51).
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RESULTS |
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Immunoblot analysis of CNG channel proteins in porcine PAEC.
Family members of CNG cation channels have been reported to be present
in vascular endothelium and associated with calcium influx (18,
20, 52, 53). To determine whether NO exposure alters expression
of these channels in endothelial cells, we carried out immunoblot
analysis to assess the steady-state levels of CNGA2, CNGA4, and CNGB1
protein. Figure 1A shows that
relative protein levels of CNGA2 in NO-treated cells were increased
40% compared with control cells (P < 0.05, n = 4), whereas relative levels of CNGA4 in NO-treated
and control cells were comparable. Because CNGB1 has been reported to
be present in vascular endothelium (18, 53), the weak
reaction between CNGB1 antibodies and CNGB1 protein in porcine PAEC may
be due to lack of antibody cross-reactivity, i.e., anti-rat CNGB1
antibody vs. porcine CNGB1 protein. Alternatively, the level of CNGB1
may be much lower than that of CNGA2 or CNGA4 protein in PAEC. As such,
we focused subsequent experiments on CNGA2.
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NO elevates intracellular calcium levels in PAEC.
To determine whether intracellular calcium levels are elevated after
exposure of endothelial cells to NO and whether calcium influx into
cells contributes to the elevation of intracellular calcium levels,
calcium levels of PAEC incubated in the calcium-replete or calcium-free
HBSS after exposure to NO or control medium were measured by using a
fluorescent dye, fluo 3-AM, for calcium and confocal microscopy. In the
presence of extracellular calcium, exposure of PAEC to 1 mM NOC-18 for
6 h increased intracellular calcium levels by 50% compared with
controls (Fig. 3B, +calcium; P < 0.05, n = 4). In the absence of
extracellular calcium, the NO elevation of intracellular calcium was
attenuated, because intracellular calcium levels in cells exposed to
NOC-18 or control medium were comparable (Fig. 3B,
calcium). These data suggest that NO elevates intracellular calcium
levels and that calcium influx contributes to the NO-elevated calcium
levels.
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CNG channels contribute to store-operated calcium influx in PAEC.
To determine whether calcium influx contributes to intracellular
calcium levels in PAEC after NO exposure, we recorded tracings of
fluorescence intensity changes in fluo 3-AM-loaded cells before and
after intracellular calcium stores were emptied in the presence or
absence of extracellular calcium. Intracellular calcium levels in cells
with emptied intracellular calcium stores were elevated, and the rise
in calcium levels was sustained for up to 1,500 s as determined by
fluorescence intensities (Fig. 4A) and
F/F0 ratios (Fig. 4B). In the absence of
extracellular calcium, Tg transiently elevated fluorescence intensities
(Fig. 4C) and F/F0 ratios (Fig. 4D),
but the sustained calcium signal was eliminated. These data suggest
that calcium influx into endothelial cells contributes to NO-increased
intracellular calcium levels in PAEC.
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Antisense inhibition of CNGA2 gene expression prevents NO-mediated
elevations in intracellular calcium levels and CNG channel-mediated
calcium entry in PAEC.
To examine whether suppression of the expression of the functional
subunit of the CNGA gene attenuates the NO-induced increase in
intracellular calcium levels and the CNG channel-mediated capacitive calcium influx, we transfected PAEC with antisense CNGA2 or a GFP gene
(transfection control). After the antisense gene was induced to express
for 24 h, the CNGA2 protein level in the antisense CNGA2-transfected cells was decreased to 20% of that observed in the
GFP-transfected cells as measured by immunoblot analysis (Fig.
6). Inhibition of CNGA2 expression also
attenuated the NO-induced upregulation of CNGA2 expression in PAEC
incubated with or without NOC-18 for 18 h (Fig. 6).
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DISCUSSION |
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In vascular endothelium, NO has been associated with activation of a calcium-permeable, nonspecific cation channel (28). Our data demonstrate that NO upregulates steady-state protein and mRNA levels of CNGA2, but not CNGA4, in porcine PAEC. The increased expression of CNGA2 is retained for up to 12 h after cessation of NO exposure. Because CNGA2 can form a functional channel, increased CNGA2 can lead to enhanced channel activity in NO-exposed endothelial cells. Increased protein levels were correlated with elevated mRNA, suggesting that NO may regulate CNGA2 gene expression by enhanced synthesis and/or stability of the mRNA for this CNG channel.
NO is known to increase cGMP levels via activation of the soluble guanylate cyclase (13, 38), which can activate CNGA2 (2). Levels of cGMP, but not cAMP, were elevated in cultured porcine PAEC exposed to 1 mM NOC-18 for 18 h (data not shown). The NO-increased cGMP may keep CNGA2 active, leading to a sustained rise in calcium. It is also possible, though less likely, that NO directly activates CNGA through modification of sulfhydryl groups (14).
NO-upregulated CNGA2 expression was associated with elevation of intracellular calcium levels and capacitive calcium entry in porcine PAEC in the current studies. Both the release of calcium from intracellular stores, most likely the endoplasmic reticulum, and the influx of calcium from the extracellular space, i.e., capacitive calcium entry, contribute to the NO-induced elevation of cytosolic calcium. NO and other oxidant stresses are known to mediate calcium influx in endothelial cells (5, 28, 33). Exogenous NO increased intracellular calcium levels in cultured porcine aortic endothelial cells (5). As such, our results are in agreement with previous observations in endothelial cells (5, 28, 33).
The present study also demonstrates that the CNG channel blocker Dil inhibited capacitive calcium influx induced by calcium store depletion in both control and NO-treated PAEC, suggesting that CNG channels contribute to the calcium influx. Inhibition of calcium entry by La3+ indicates that nonselective cation channels including CNG channels may play a role in maintaining intracellular calcium levels. Although CNGB1 has been shown to be present in vascular endothelial cells derived from systemic arteries (53) and sensitive to Dil (25), our results showed that CNGA2, but not CNGB1, was abundant and that CNGA2 expression was upregulated by NO exposure in porcine PAEC. Differences in CNGB1 abundance among vascular endothelial cells may be due to different animal species (guinea pig/rat vs. porcine) and/or origin of vascular bed (aorta/mesenteric arteries vs. pulmonary arteries). Differences in CNGA2 sensitivity to Dil may be due to a nonspecific chemical modulation and/or a selective response to Dil in specific cell types (rod cells vs. endothelial cells). However, irrespective of the effects of chemical modulation, the association between increased CNGA2 expression and elevated intracellular calcium levels has been verified by using antisense methodology to specifically suppress CNGA2 gene expression. Antisense inhibition of CNGA2 attenuated NO elevation of intracellular calcium levels and CNG channel-associated capacitive calcium entry in porcine PAEC, suggesting a role for NO modulation of CNG channels.
NO upregulation of CNGA2 expression may increase the number of the channels in a cell, consequently enhancing calcium entry and leading to elevation of intracellular calcium levels. CNG channels have been shown to play an important role in the regulation of calcium influx in endothelial cells (42, 52). Recently, it has been shown that in rat PAEC, a nonselective cation conductance attributed to channels regulated by cyclic nucleotides and endogenously expressed CNG channels mediated the nonselective cation current (52). Furthermore, a portion of the CNGA2 gene has been cloned from the rat PAEC and linked to store-operated calcium entry (52). Our results are in agreement with these reports and demonstrate the presence of functional CNG channels that contribute to capacitive calcium entry in PAEC.
Intracellular calcium has been shown to act as a signal transducer that modulates multiple cellular processes, including apoptosis (19, 31). Enhanced calcium influx has been observed in NO-induced apoptosis of mouse oligodendrocytes (9) and in glucocorticoid-stimulated thymocytes (29, 36). The initial calcium increase in apoptotic cells occurs via a controlled, physiological mechanism such as surface antigen receptor engagement on B cells leading to calcium increases that promote cell death (8). Therefore, NO-upregulated CNGA2 channels and a consequent increase in capacitive calcium influx and intracellular calcium levels may contribute to the triggering of apoptotic cascades in endothelial cells. In this study we did not examine the downstream effects of NO-increased intracellular calcium levels and its link with selective pathways in induction of apoptosis. However, accumulating evidence indicates that a calcium signal is associated with apoptosis (37). For example, elevated intracellular calcium can activate calcium-dependent protein kinases and phosphatases in B cell lines that have been reported to control apoptosis (7). Intracellular calcium can activate calpain, a calcium-dependent neutral proteinase, to induce apoptosis, because calpain is rapidly activated in apoptotic cells and the apoptosis is prevented by blocking calpain activation using specific inhibitors (45). Increase in intracellular calcium can also activate Ca2+/Mg2+-dependent endonuclease, leading to DNA fragmentation, the hallmark of apoptosis (17).
In conclusion, exogenous NO upregulates CNGA2 expression, which contributes to enhanced capacitive calcium influx and increased intracellular calcium levels in pulmonary vascular endothelial cells. The increased cytosolic calcium levels may be involved in cytotoxicity of NO, e.g., apoptosis, in endothelial cells. Our observations support the notion that the CNG channel, a type of nonselective cation channel, may play physiological and pathological roles in lung endothelium via calcium influx. Because the lung endothelium is a potential target for NO generated by the action of inducible NO synthase in alveolar macrophages and lung inflammatory cells and for NO administered as inhalation therapy, a better understanding of NO upregulation of CNG channel expression and calcium influx will help us to prevent potential pulmonary vascular dysfunction associated with NO inhalation therapy, lung inflammation, and acute lung injury that are associated with increased endogenous NO production.
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ACKNOWLEDGEMENTS |
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We thank Bert Herrera for tissue culture and Di-hua He for technical assistance.
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FOOTNOTES |
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This work was supported in part by the Medical Research Service of the Department of Veterans Affairs, National Heart, Lung, and Blood Institute Grants HL-58679 (J. M. Patel) and HL-52136 (E. R. Block), and a Career Investigator Award from the American Lung Association of Florida, Inc. (J. Zhang).
Address for reprint requests and other correspondence: J. Zhang, Research Service (151), VA Medical Center, 1601 S.W. Archer Rd., Gainesville, FL 32608-1197 (E-mail: zhangjl{at}medicine.ufl.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.
May 29, 2002;10.1152/ajpcell.00048.2002
Received 30 January 2002; accepted in final form 20 May 2002.
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