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Resistance to Store Depletion–induced Endothelial Injury in Rat Lung after Chronic Heart Failure

Departments of Physiology and Pharmacology and Pathology, and Center for Lung Biology, University of South Alabama, Mobile, Alabama

Correspondence and requests for reprints should be addressed to Mary I. Townsley, Ph.D., Department of Physiology, MSB 3074, University of South Alabama, Mobile, AL 36688. E-mail: mtownsley{at}usouthal.edu

	ABSTRACT

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Rationale: In chronic heart failure, the lung endothelial permeability response to angiotensin II or thapsigargin-induced store depletion is ablated, although the mechanisms are not understood. Objectives: To determine whether the ablated permeability response to store depletion during heart failure was due to impaired expression of store operated Ca²⁺ channels in lung endothelium. Methods: Heart failure was induced by aortocaval fistula in rats. Permeability was measured in isolated lungs using the filtration coefficient and a low Ca²⁺/Ca²⁺ add-back strategy to identify the component of the permeability response dependent on Ca²⁺ entry. Main Results: In fistulas, right ventricular mass and left ventricular end diastolic pressure were increased and left ventricular shortening fraction decreased compared with shams. Thapsigargin-induced store depletion increased lung endothelial permeability in shams, but not in fistulas. Permeability increased in both groups after the Ca²⁺ ionophore A23187 or 14,15-epoxyeicosatrienoic acid, independent of store depletion. A diacylglycerol analog had no impact on permeability. Increased distance between the endoplasmic reticulum and the plasmalemmal membrane was ruled out as a mechanism for the loss of the permeability response to store depletion. Endothelial expression of the endoplasmic reticulum Ca²⁺ ATPase was not altered in fistulas compared with shams, whereas the store-operated canonical transient receptor potential channels 1, 3, and 4 were downregulated in extraalveolar vessel endothelium. Conclusions: We conclude that the adaptive mechanism limiting store depletion–induced endothelial lung injury in the aortocaval model of heart failure involves downregulation of store-operated Ca²⁺ channels.

Key Words: calcium channels • permeability • secondary pulmonary hypertension

Although sustained pulmonary venous hypertension and high levels of edemogenic factors such as angiotensin II are common findings in chronic heart failure (CHF), alveolar edema and the resultant respiratory distress do not always occur (1–3). Structural remodeling of the pulmonary endothelial barrier appears to play a role in this process, because thickening of both the endothelial and the alveolar epithelial layers of the septal network has been reported in several animal models of heart failure and in humans with chronic pulmonary venous hypertension (4–8). However, endothelial adaptations to CHF and chronic pulmonary venous hypertension appear to contribute more than simple mechanical advantage due to structural remodeling. Ca²⁺ entry in lung endothelium activates signaling cascades, which promote the formation of endothelial gaps and increase the filtration coefficient (K_f) (8–10), a sensitive index of water conductance through the endothelial barrier in the intact lung. An important pathway for Ca²⁺ entry in lung endothelium is that linking depletion of the endoplasmic reticulum Ca²⁺ stores to activation of store-operated Ca²⁺ channels (SOCs) in the plasmalemmal membrane (9, 10). In the canine lung, store depletion–induced increases in endothelial permeability require epoxyeicosatrienoic acids (EETs) (11–13), P450 derivatives of arachidonic acid that have been implicated as soluble mediators of store depletion–induced Ca²⁺ entry in systemic endothelium (14). Moreover, in the rapid-ventricular-pacing canine model of CHF, store-dependent increases in permeability were ablated, a finding that correlated with downregulation of P450 epoxygenases and decreased synthesis of EETs (15).

We hypothesized that CHF could confer similar protection against thapsigargin-induced endothelial injury in rat lung. Because, in normal rat lung, EETs do not mediate thapsigargin-induced increase in permeability (16), we reasoned that any adaptation in regulation of endothelial permeability in this species after CHF must involve other mechanisms. Our study was designed to address three potential mechanisms: (1) displacement of endothelial endoplasmic reticulum away from the plasma membrane, which could impair physical coupling to SOCs (17, 18); (2) downregulation of canonical transient receptor potential proteins (TRPs), which are putative components of SOCs (19–23) and have been shown to be expressed in cultured rat lung endothelium (20, 24); and (3) global attenuation of Ca²⁺ entry and/or responsiveness to Ca²⁺. We used the aortocaval fistula model of CHF and the measure of K_f in lungs isolated 3 to 5 wk after sham surgery or creation of the fistula to evaluate altered regulation of endothelial permeability. Some of the results of these studies have been previously reported in the form of abstracts (25, 26).

	METHODS

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Aortocaval Fistula Model of CHF
Infrarenal aortocaval fistulas were created in CD40 rats (250–275 g) anesthetized with pentobarbital sodium (50 mg/kg, intraperitoneally), as described previously (27). Sham rats were subjected to surgery but no fistula was created. Use of animals adhered to the NIH guidelines for the care and use of laboratory animals; protocols were approved by the Institutional Animal Care and Use Committee. At 3 to 5 wk after surgery, animals were anesthetized for terminal studies. Terminal bodyweight and the wet weights of the right ventricle and left ventricle plus septum were measured. Hemodynamics (Millar catheter), left ventricular dimensions, and left ventricular shortening fraction (both via M-mode echocardiography) were evaluated. Lungs were isolated for ex vivo perfusion (16).

Assessment of Endothelial Permeability
Isolated lungs were perfused at constant flow with buffer containing 1.8 mmol/L CaCl₂ and 4% albumin unless noted (16, 28). Endothelial permeability was assessed by paired measurements of K_f at baseline and after treatment with the following: (1) 150 nmol/L thapsigargin to promote Ca²⁺ entry via SOCs (29, 30), (2) the Ca²⁺ ionophore A23187 (10 µmol/L) to test whether molecular targets critical for regulation of endothelial permeability retained their Ca²⁺ sensitivity after CHF, or (3) 14,15-EET (3 µmol/L) to assess a Ca²⁺ entry pathway regulated independent of store depletion (16). To confirm that 14,15-EET increased endothelial permeability in a Ca²⁺ entry–dependent manner after CHF, lungs from fistulas were perfused with a low Ca²⁺ buffer containing 0.02 mmol/L CaCl₂ and 4% bovine serum albumin (16). K_f was measured at baseline and after addition of 14,15-EET in low Ca²⁺, and then again after Ca²⁺ add-back to restore physiologic Ca²⁺ concentration (2.2 mmol/L). To evaluate the involvement of receptor-operated Ca²⁺ entry channels (31, 32), K_f was measured in normal rat lungs challenged with 100 or 300 µmol/L 1-oleoyl-2-acetyl-sn-glycerol (OAG), a diacylglycerol analog (23, 32); buffers contained 3% dextran and 1% albumin to limit OAG–albumin binding (16). To determine whether lung injury induced by 300 µmol/L OAG was due to Ca²⁺ entry, we used the low Ca²⁺/Ca²⁺ add-back strategy in a separate group of lungs: K_f was measured before and after addition of OAG at low Ca²⁺, and then again after Ca²⁺ add-back.

Endoplasmic Reticulum–Plasmalemmal Membrane Distance
Lung tissue was fixed by immersion in 3% glutaraldehyde, postfixed in osmium tetroxide, and embedded in PolyBed 812 resin (Polysciences, Inc., Warrington, PA). Sections (80 nm) were stained with uranyl acetate and Reynolds lead citrate and examined using transmission electron microscopy (Phillips CM 100; FEI Company, Hillsboro, OR). The minimal distance between the endoplasmic reticulum and the apical or basolateral plasmalemmal membrane was measured from random micrographs of endothelial cells in pulmonary arteries and microvessels (33).

Immunohistochemistry
Lungs from shams (n = 4) and fistulas (n = 5) were perfusion-fixed with 4% paraformaldehyde, paraffin-embedded, and sectioned (5 µm). Primary antibodies were used to detect expression of TRPC1 and TRPC4 (1:20; Santa Cruz Biotechnology, Santa Cruz, CA), TRPC6/TRPC7 (1:10; Santa Cruz Biotechnology), and TRPC3 (1:50; Alomone Laboratories, Jerusalem, Israel). To rule out loss of thapsigargin's pharmacologic target, the sarcoplasmic endoplasmic reticulum Ca²⁺ ATPase (SERCA), we also evaluated endothelial expression of SERCA2 and SERCA3 (1:10; Affinity BioReagents, Golden, CO).

Statistics
Data are means ± SEM. Means were compared using an unpaired t test or one-way analysis of variance with Tukey's post hoc t test. p values less than 0.05 were considered significant.

	RESULTS

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Documentation of CHF
Fistula patency was confirmed using transabdominal pulsed-Doppler ultrasound (Figures 1A and 1C) or direct visualization of oxygenated blood permeating into the inferior vena cava at terminal experiments. Left ventricular dimensions and left ventricular shortening fraction in sham animals (Table 1) were similar to those previously reported for normal rats (34–36). In contrast, fistulas exhibited left ventricular dilation (Figures 1B and 1D) and mild ventricular dysfunction, similar to that previously reported in this model (37, 38). Left ventricular end diastolic pressure increased 2.3-fold and left ventricular shortening fraction was reduced by 21% compared with shams. Secondary pulmonary hypertension was evidenced by increased right ventricular mass and the right ventricular/(left ventricular + septum) mass ratio in fistulas (Table 1). The increase in right ventricular mass positively correlated with left ventricular end diastolic pressure (r² = 0.64, p < 0.05).

View larger version (150K): [in this window] [in a new window]   Figure 1. Echocardiographic assessment of fistula patency and left ventricular function in the chronic heart failure (CHF) model. (A, C) Angio-mode Doppler images from representative sham and fistula animals, respectively. High-flow velocity limited to the abdominal aorta (a) was observed in shams but could also be seen in the inferior vena cava (vc) in fistulas. (B, D) M-mode echos in representative sham and fistula animals, respectively. Left ventricular dimensions were increased in the fistula group compared with shams (see Table 1 for detail).

View larger version (17K): [in this window] [in a new window]   Figure 2. Effect of store depletion via thapsigargin on endothelial permeability. Baseline (BL) and final Kf (F) were compared after treatment with thapsigargin. Thapsigargin increased endothelial permeability in shams (open bars, n = 7) but not in fistulas (hatched bars, n = 5). *p < 0.05 versus BL. Kf = filtration coefficient.

View larger version (28K): [in this window] [in a new window]   Figure 3. Effect of the Ca2+ entry agonists A23187 and 14,15–epoxyeicosatrienoic acid (14,15-EET) on endothelial permeability. (A) Kf was measured at baseline (BL) and after treatment (F) in shams (open bars) and fistulas (hatched bars); n = 5 in each group. A23187 significantly increased endothelial permeability in both groups. The 14,15-EET increased endothelial permeability in shams (n = 4) but not significantly in fistulas (n = 5) due to an exaggerated response in one of the fistula experiments. *p < 0.05 versus BL. (B) To show dependence of the 14,15-EET permeability response on Ca2+ entry, in fistulas (n = 5) we measured Kf using a low Ca2+/Ca2+ add-back strategy. The 14,15-EET increased endothelial permeability at low Ca2+, with further injury after Ca2+ add-back. *p < 0.05 versus BL.

Physical Coupling Mechanism
Physical coupling of the endoplasmic reticulum and the putative SOCs appears to be required for Ca²⁺ entry after depletion of the endothelial Ca²⁺ store (18, 21). Relative displacement of the endoplasmic reticulum from the plasmalemmal membrane in cultured lung microvascular endothelium has been believed to explain the resistance of this cell type to store-operated Ca²⁺ entry (33), compared with that in pulmonary artery endothelium. However, the distances between these two structures were no different in shams and fistulas in either the pulmonary artery or the septal capillary endothelium (Figure 4). This suggests that, despite the documented endothelial thickening after CHF (4–7), physical uncoupling by a means of increased distance between the store and SOCs is not likely to explain the adaptive protection observed after CHF in rat lung.

View larger version (18K): [in this window] [in a new window]   Figure 4. Distances between the endoplasmic reticulum and the endothelial plasmalemmal membrane in intact lungs from shams (n = 4) and fistulas (n = 3). Data points and horizontal lines represent individual and average measurements, respectively, in pulmonary artery (left) and septal microvessel (right) endothelial cells (EC). Although the endoplasmic reticulum and the plasma membrane tended to be more distant from each other at the basolateral aspect compared with that in the apical compartment of pulmonary artery endothelium, this trend was not significant. We found no significant differences between shams and fistulas at either site in either cell population.

View larger version (83K): [in this window] [in a new window]   Figure 5. Immunostaining for transient receptor potential proteins TRPC1, TRPC3, TRPC4, and TRPC6/7 in rat lungs. Expression of each TRPC isoform in endothelium was confirmed in small muscular or partially muscularized extraalveolar vessels (A) and conduit artery (B) from shams and fistulas. Expression of TRPC1, TRPC3, and TRPC4 in endothelial cells was downregulated in small pulmonary arterioles after CHF, whereas TRPC6/7 expression was unchanged. TRPC4 expression in the medial layer of large conduit pulmonary vessels was increased in fistulas. Original magnification = 40x. See text for more detail.

View larger version (75K): [in this window] [in a new window]   Figure 6. Expression of sarcoplasmic endoplasmic reticulum Ca2+ ATPase (SERCA) isoforms in rat lung. Expression of SERCA2 (left) and SERCA3 (right) in endothelium was confirmed in small muscular or partially muscularized extraalveolar vessels and conduit artery from shams (top row) and fistulas (bottom row). There were no apparent differences in endothelial SERCA expression after CHF. Original magnification = 40x.

View larger version (13K): [in this window] [in a new window]   Figure 7. Effect of receptor-operated Ca2+ entry on endothelial permeability. Baseline (BL) and final (F) Kf were compared after treatment with 1-oleoyl-2-acetyl-sn-glycerol (OAG). With physiologic extracellular Ca2+, OAG increased endothelial permeability at 300 but not at 100 µmol/L (n = 3 in each group). Using the low Ca2+/Ca2+ add-back strategy, 300 µmol/L OAG (n = 3) was found to have no impact on endothelial permeability. See text for more detail. *p < 0.05 versus BL.

	DISCUSSION

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In the rapid-ventricular-pacing canine model of CHF, the store depletion–dependent permeability response to both angiotensin II and thapsigargin was ablated (12, 13), a mechanism linked to decreased EET synthesis (15). Because in the aortocaval fistula model, elevation of pulmonary vascular pressures and plasma angiotensin II concentrations are common findings (2, 44), we asked whether the resistance to store depletion–induced lung injury is a protective adaptation that occurs exclusively in the canine model or if it is a more generic mechanism inherent to CHF. In the present study, we observed an approximately fivefold increase in K_f after treatment with thapsigargin in shams (Figure 2). However, thapsigargin did not alter endothelial permeability in fistulas, suggesting that the protection against store depletion–mediated lung injury may occur irrespective of the species or the model. Nonetheless, the mechanism appears to be species-dependent because EETs provide a link between store depletion and increased endothelial permeability in canine lung, but not in rat lung (11, 16).

Our data support the notion that CHF in the rat specifically leads to downregulation of SOCs in pulmonary endothelium, conferring protection against store depletion–induced lung injury. TRPCs have been postulated as putative SOCs (45, 46), and all but TRPC2 have been shown to be expressed in endothelium (24, 46). Functional SOCs require assembly of four TRPC subunits to form a tetrameric channel (31). Although the contribution of each isoform to Ca²⁺ entry initiated by store depletion is controversial (21, 45), heteromultimers formed by the association of TRPC1 and TRPC4 can be regulated by store depletion (20, 22). In contrast, heteromultimers of TRPC3 and TRPC6 or TRPC7 typically form a channel regulated by diacylglycerol (31, 47). However, functional channels composed of TRPC1 and TRPC3 subunits have been also described (32, 48, 49), and when expressed at low levels, TRPC3 may act as a SOC (23). In cultured pulmonary endothelium and vascular smooth muscle, mRNA encoding for TRPC1, TRPC3, TRPC4, TRPC6, and TRPC7 has been identified (24, 50, 51), and in the present study, protein expression in vivo was confirmed by immunohistochemistry. Overexpression of TRPC1 increased Ca²⁺ influx after store depletion in human umbilical vein endothelium (52), whereas antibodies against TRPC1 blocked a store-operated Ca²⁺ current in pulmonary artery endothelium (20). Furthermore, thrombin-induced store-operated Ca²⁺ entry and the resultant pulmonary endothelial permeability response are impaired in TRPC4^–/– mice (22). In fistulas, expression of TRPC1 and TRPC3 was not observed in the lung endothelium. TRPC4 expression was modestly maintained in endothelium from conduit vessels but it was not expressed in endothelium of small muscular or partially muscularized extraalveolar vessels. This is significant because thapsigargin-induced endothelial injury is localized to small extraalveolar vessels in the rat lung (9, 53, 54). Thus, downregulation of endothelial TRPC1, TRPC3, and/or TRPC4 in the fistula group could potentially explain the observed resistance to store depletion–induced lung injury.

Although our data show loss of endothelial TRPC3 as well as TRPC1 and TRPC4, in conjunction with loss of the store depletion–induced permeability response, we conclude that the TRPC3/TRPC6/TRPC7 subfamily does not play a direct role in regulation of endothelial permeability in rat lung. We base this conclusion on the observation that OAG had no impact on endothelial permeability in the isolated rat lung (Figure 7). OAG is often used as a tool to activate Ca²⁺ entry via TRPCs in heterologous expression systems, although the specific TRPC channels targeted are the subject of debate (23, 32, 39, 40). Complicating this issue is the potential for concomitant activation of protein kinase C (PKC) by OAG and phosphorylation-dependent downregulation of TRPC channels (39, 55). Whether these paradigms pertain to regulation of Ca²⁺ entry via TRPCs in endothelial cells may well depend on the isoforms of PKC and TRPCs endogenously expressed. OAG promoted endothelial Ca²⁺ entry via TRPC6 and increased hydraulic permeability (a component of the K_f) in frog mesenteric microvessels (56). In contrast, thapsigargin and thrombin induced TRPC1 phosphorylation via PKC in endothelium, Ca²⁺ entry, and barrier disruption (57). TRPC1, TRPC3 and TRPC6/7 are clearly expressed in endothelium of rat lung, yet OAG did not alter the filtration coefficient. Although 300 µmol/L OAG increased endothelial permeability in the rat lung, this was associated with a significant pressor response and neither effect was observed in the low Ca²⁺/Ca²⁺ add-back experiment, suggesting that the injury evoked by high-dose OAG at normal Ca²⁺ was secondary to mechanical endothelial injury (58). Collectively, our data, taken in light of other published work, provide strong inferential support for the conclusion that loss of endothelial TRPC1 and TRPC4 expression, but not TRPC3, in the aortocaval fistula model explains the resistance against store depletion–induced lung injury.

Store-operated Ca²⁺ entry appears to require conformational coupling between the endoplasmic reticulum and adjacent plasmalemmal membrane Ca²⁺ channels in some models (17, 21, 45). Furthermore, Cioffi and colleagues (21) and King and colleagues (33) found that increased endoplasmic reticulum–plasmalemmal membrane distance in cultured lung microvascular endothelium, compared with that in pulmonary artery endothelium, correlated with the reduced permeability response of microvascular endothelium to store depletion. In contrast, we found no difference in the distance at the apical aspect and a trend toward a smaller distance at the basolateral aspect of pulmonary microvascular endothelium in shams. This may relate to tensional forces on the microvasculature in intact lung, because peripheral vessels are subject to radial traction. In fact, endothelial thickness is less in small, nonmuscular, extraalveolar vessels from rat lung compared with that in pulmonary artery (59). Nonetheless, because endothelial thickness is increased in humans with CHF, and in the rapid ventricular pacing and aortic banding models of CHF (4–8), it was important to evaluate altered mechanical coupling between these two endothelial structures. However, we found no significant difference in distance in either the apical or the basolateral compartment of pulmonary or microvascular endothelium in the intact lung from shams and fistulas (Figure 4).

We also addressed whether the ablation of acute lung injury after store depletion in the aortocaval fistula model of CHF was due to decreased sensitivity of Ca²⁺ targets in endothelium critical for regulation of permeability or to a generic impairment of Ca²⁺ entry. Treatment with the Ca²⁺ ionophore A23187, a drug that produces a global rise in intracellular Ca²⁺, increased endothelial permeability in shams and fistulas. This suggests that once Ca²⁺ entry is promoted, the Ca²⁺ response of the endothelial contractile apparatus and junctional complexes is maintained after CHF, a conclusion also supported by the preserved response to 14,15-EET after CHF. A further implication of our results is that in rat lung endothelium, 14,15-EET activates a Ca²⁺ entry pathway distinct from that mediated by TRPC1, TRPC3, or TRPC4.

In conclusion, our study shows that ablation of store depletion–induced lung injury occurs in a high-output model of CHF in the rat, similar to previous reports in the canine CHF model (12, 13). Resistance to store depletion–induced pulmonary endothelial injury, but not to that evoked by 14,15-EET, indicates that the adaptation in CHF selectively targets Ca²⁺ entry regulated by store depletion in rat lung. Our data support the notion that loss of the store depletion permeability response is likely due to downregulated expression of TRPC1 and TRPC4 in pulmonary endothelial cells after CHF.

	Acknowledgments

 
The authors thank Dr. Greg Brower (Auburn University) and Sue Barnes (University of South Alabama) for their assistance with the fistula model of heart failure. They also thank Virginia Parks and Freda McDonald (University of South Alabama) for their technical assistance with ultrasound and electron microscopy, respectively.

	FOOTNOTES

 
Supported by National Heart, Lung, and Blood Institute grant HL-61955 and American Heart Association Southeast Affiliate predoctoral fellowship 0315049B.

Conflict of Interest Statement: None of the authors have a financial relationship with a commercial entity that has an interest in the subject of this manuscript.

Received in original form June 2, 2005; accepted in final form July 29, 2005

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