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Fasudil inhibits the myogenic response in the fetal pulmonary circulation

¹The Pediatric Heart Lung Center, Sections of Neonatology and Pulmonary Medicine, Department of Pediatrics, University of Colorado School of Medicine, Aurora, Colorado; and ²Neonatal and Pediatric Intensive Care Unit, Amiens University Medical Center, and PériTox, Unité Mixte 4285, National Institute of Industrial Environment and Risk, Faculty of Medicine, Jules Verne University of Picardy, Amiens, France

Submitted 9 May 2008 ; accepted in final form 28 July 2008

	ABSTRACT

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In addition to high pulmonary vascular resistance (PVR) and low pulmonary blood flow, the fetal pulmonary circulation is characterized by mechanisms that oppose vasodilation. Past work suggests that high myogenic tone contributes to high PVR and may contribute to autoregulation of blood flow in the fetal lung. Rho-kinase (ROCK) can mediate the myogenic response in the adult systemic circulation, but whether high ROCK activity contributes to the myogenic response and modulates time-dependent vasodilation in the developing lung circulation are unknown. We studied the effects of fasudil, a ROCK inhibitor, on the hemodynamic response during acute compression of the ductus arteriosus (DA) in chronically prepared, late-gestation fetal sheep. Acute DA compression simultaneously induces two opposing responses: 1) blood flow-induced vasodilation through increased shear stress that is mediated by NO release and 2) stretch-induced vasoconstriction (i.e., the myogenic response). The myogenic response was assessed during acute DA compression after treatment with N-nitro-L-arginine, an inhibitor of nitric oxide synthase, to block flow-induced vasodilation and unmask the myogenic response. Intrapulmonary fasudil infusion (100 µg over 10 min) did not enhance flow-induced vasodilation during brief DA compression but reduced the myogenic response by 90% (P < 0.05). During prolonged DA compression, fasudil prevented the time-dependent decline in left pulmonary artery blood flow at 2 h (183 ± 29 vs. 110 ± 11 ml/min with and without fasudil, respectively; P < 0.001). We conclude that high ROCK activity opposes pulmonary vasodilation in utero and that the myogenic response maintains high PVR in the normal fetal lung through ROCK activation.

calcium sensitization; persistent pulmonary hypertension of the newborn; pulmonary vascular resistances; lung development

In addition to its high basal PVR, the fetal pulmonary circulation is uniquely characterized by its ability to oppose vasodilation in response to diverse stimuli, including increased oxygen tension, acidosis, infusions of pharmacological vasodilators, and shear stress (5, 6, 8, 11, 12, 47). Although these stimuli cause fetal pulmonary vasodilation, this response is often transient; that is, the rise in fetal pulmonary blood flow and the fall in PVR are followed by a marked decrease in flow, despite continued exposure to dilator stimuli (6, 22). Time-dependent changes in pulmonary vascular tone also have been demonstrated in response to changes in hemodynamic forces induced by partial compression of the DA. Abrupt DA compression in the normal fetus initially increases fetal pulmonary artery pressure and flow, causing a rapid decline in PVR (5, 12, 47). However, during prolonged DA compression, pulmonary blood flow progressively decreases toward baseline values (5). These findings suggest that autoregulatory mechanisms exist in the fetal lung that oppose vasodilation and contribute to high PVR.

Mechanisms that oppose vasodilation in the fetal lung are incompletely understood, but past work suggests that high myogenic tone may contribute to this response. Physiologically, the myogenic response is defined by increased vascular tone induced by elevated intraluminal pressure (26, 47). Although lacking in the normal postnatal pulmonary circulation, the contribution of the myogenic response to high PVR in the normal fetus has previously been reported (9, 40, 46, 47). DA compression simultaneously induces two opposing responses: 1) blood flow-induced vasodilation through increased shear stress and 2) pressure-induced vasoconstriction (i.e., the myogenic response) (12, 47). Whether the myogenic response contributes to the physiological response to diverse dilator stimuli, including hemodynamic forces, in the developing lung is uncertain.

Studies of the systemic circulation have shown that the myogenic response may be mediated by depolarization-induced Ca²⁺ influx (28), activation of phospholipase C (24, 39), and calcium sensitization (32, 45). Calcium sensitization refers to the inhibition of myosin light chain phosphatase (MLCP), which prevents dephosphorylation of myosin light chains and allows for sustained contraction even if cytosolic Ca²⁺ levels fall (see review in Ref. 45). Rho-kinase (ROCK) has been shown to mediate the myogenic response in the adult systemic circulation and accounts for calcium sensitization in vascular smooth muscle (19, 31). ROCK inhibits MLCP by phosphorylating the myosin-binding subunit of MLCP, MYPT-1, and/or the MLCP inhibitor protein CPI-17 and thus augments smooth muscle cell contraction at any given intracellular concentration (19, 45). ROCK activity has been involved in vascular tone in various organs, such as coronary arteries (33), mesenteric artery (44), and cerebral arteries (23). Previous studies have shown that ROCK inhibitors (ROCKi) cause pulmonary vasodilation in the adult (2, 15, 17, 37, 38) and the fetal lung (41), but whether high ROCK activity contributes to the myogenic response and modulates time-dependent vasodilation in the developing lung circulation is unknown.

Therefore, we hypothesized that high ROCK activity modulates the myogenic response and regulates pulmonary blood flow during fetal life. To test this hypothesis, we performed a series of experiments in chronically prepared, late-gestation fetal lambs. We report that treatment with a ROCKi does not enhance flow-induced vasodilation but inhibits the myogenic response in fetal sheep. We also found that ROCKi sustains pulmonary vasodilation during prolonged DA compression. These findings suggest that high ROCK activity opposes pulmonary vasodilation in vivo and that the myogenic response maintains high PVR in the normal fetal lung.

	METHODS

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Twenty-four pregnant, mixed-breed (Colombia-Rambouillet) ewes were used in this study. All procedures and protocols were reviewed and approved by the Animal Care and Use Committee of the University of Colorado Health Sciences Center and followed the Guide for the Care and Use of Laboratory Animals established by the National Research Council.

Fetal Surgical Preparation

Surgery was performed at 126 ± 2 days gestation (term = 147 days) in fetuses from 11 singleton and 13 twin pregnancies after ewes had fasted for 24 h. Animals were given intramuscular penicillin G (600,000 units) and gentamicin (80 mg) immediately before surgery. Ewes were sedated with intravenous ketamine (800 mg) and diazepam (10 mg) and were intubated and ventilated with 1–2% isoflurane for the duration of the surgery. Under sterile conditions, a midline abdominal incision was made, and the uterus was externalized. A hysterotomy was made, and the left fetal forelimb was exposed. Polyvinyl catheters (20-gauge) were placed in the left axillary artery and vein and advanced in the ascending aorta (Ao) and superior vena cava (SVC), respectively. A left thoracotomy and pericardial incisions were made, and the heart and great vessels were exposed. With the use of a 16-gauge intravenous placement unit (Angiocath; Travenol, Deerfield, IL), a 22-gauge catheter was placed through purse-string sutures in the left pulmonary artery (LPA) to allow for selective drug infusions. With a 14-gauge intravenous placement unit (Angiocath; Travenol), 20-gauge catheters were placed in the main pulmonary artery (MPA) and left atrium. After gentle, blunt dissection of the bifurcation of MPA, a flow transducer (Transonic Systems, Ithaca, NY) was placed around the LPA to measure blood flow to the left lung (Q_LPA). The DA was exposed using gentle, blunt dissection. An inflatable vascular occluder (In Vivo Metric, Healdsburg, CA) was placed loosely around the DA. A catheter was placed in the amniotic cavity to serve as a pressure referent. The uterus was sutured, and a dose of ampicillin (500 mg) was given in the amniotic cavity. The catheters and flow transducer cable were externalized to a flank pouch on the ewe after the abdominal wall was closed. Postoperatively, ewes were allowed to eat and drink ad libitum and were generally standing within 1 h. All animals were treated with scheduled buprenorphine (0.6 mg every 8 h on day 1, 12 h on day 2, and 24 h on day 3). Further buprenorphine treatment was based on veterinary assessment of pain. All catheters were gently flushed daily with 1–2 ml of heparinized normal (0.9%) saline to maintain catheter patency.

Drug Preparation

A solution of N-nitro-L-arginine (L-NNA; Sigma, St. Louis, MO; 30 mg/ml) was prepared immediately before each study by first dissolving the drug in 1 M HCl and then neutralizing the solution to pH 7.4 with NaHCO₃ (41). The infusion rate was 0.1 ml/min over 10 min. Fasudil (HA-1077, catalog no. H-2330; LC Laboratories; 100 µg/ml) was dissolved in normal saline and infused in 1-ml aliquots. The infusion rate was 0.1 ml/min over 10 min.

General Study Design

Ewes were allowed to recover from surgery for a minimum of 24 h before the initiation of physiological studies. During physiological studies, pulmonary artery (PAP), aortic (AoP), and left atrium pressures (LAP) were measured by connecting the externalized catheters to computer-driven pressure transducers (MP100A; Biopac Systems, Santa Barbara, CA). Pressure transducers were calibrated using a mercury column manometer before each study. Pressure measurements were referenced to simultaneously recorded amniotic pressure. The flow transducer was connected to an internally calibrated flowmeter (Transonics Systems, Ithaca, NY) to measure Q_LPA. Before infusion of any drugs, a 20-min period of stable baseline hemodynamics was established during infusion of normal saline. Because normal saline was used as the vehicle for ROCKi, hemodynamic responses were compared with baseline variables. Hemodynamic variables, including PAP, AoP, and Q_LPA, were measured continuously for the duration of each study protocol. LAP was measured in two animals (3.0 ± 0.3 mmHg) to ensure the values were constant through all protocols and consistent with previous studies using fasudil in sheep (41). Left lung PVR was calculated using the formula (PAP – LAP)/Q_LPA, where LAP = 3 mmHg. Heart rate (HR) was determined from phasic pressure tracings. Arterial blood gas measurements included pH, PCO₂, PO₂, oxygen saturation (Sa_O2), and Hct (ABL 800; Radiometer, Copenhagen, Denmark).

Experimental Design

Protocol 1: effects of fasudil, a ROCKi, on the hemodynamic response during partial acute compression of the DA. The purpose of this protocol was to investigate the effects of acute infusions of fasudil on flow-induced pulmonary vasodilation due to increased shear stress. Saline (0.1 ml/min) was initially infused in the LPA catheter, and baseline measurements of Q_LPA, mean PAP (mPAP), mean AoP (mAoP), and HR were recorded every 10 min. After baseline measurements were recorded for a 30-min period, DA compression was performed for 10 min with or without infusion of fasudil (100 µg) in the LPA for 10 min before acute DA compression. From preliminary studies, this dose of fasudil was selected to cause minimal changes in basal PVR and to provide a stable baseline for short DA compression protocols. The degree of inflation of the DA occluder was set to increase mPAP by 15 mmHg from its baseline value (as described in Ref. 47). Mean PAP was kept constant through the compression period by readjusting the degree of inflation of the occluder as needed. During the compression period, data were recorded at 1, 5, and 10 min. These data were analyzed by comparing these responses with infusions of fasudil (100 µg over 10 min) without DA compression.

Protocol 2: hemodynamic effects of fasudil on the myogenic response in the ovine fetal lung during brief DA compression. The purpose of this protocol was to investigate the effects of an acute fasudil treatment during acute DA compression after L-NNA treatment. L-NNA (30 mg over 10 min) was used to inhibit endogenous NO production, to directly unmask the myogenic response during acute DA compression, as previously described (12, 47). L-NNA was infused over 10 min in the LPA, beginning 30 min before DA compression (12, 47). After a 30-min recovery period following the first DA compression, fasudil (100 µg over 10 min) was infused into the LPA, followed by a second DA compression.

To study the relationship between pulmonary artery pressure and blood flow after ROCKi treatment, we performed successive DA compressions at four different levels of mPAP, as previously described (5, 47). After baseline measurements were stable for a 30-min period, the DA occluder was partially inflated for successive 3-min periods to progressively increase PAP by 10, 20, 30, and 40% above baseline (47). Changes in Q_LPA, mPAP, mAoP, and HR were recorded during this 3-min period. This protocol was repeated in random order over 3 consecutive days that included DA compression after 1) saline infusion in the LPA (0.1 ml/min), 2) L-NNA treatment, and 3) combined L-NNA and fasudil treatments.

Protocol 3: hemodynamic effects of fasudil during prolonged DA compression in the ovine fetal lung. The first step of this protocol was to investigate the hemodynamic effects of prolonged fasudil infusions (for 2 h) on pulmonary blood flow, PVR, and pulmonary and systemic pressures. Saline (0.1 ml/min) was first infused in the LPA catheter, and baseline measurements were recorded for Q_LPA, mPAP, mAoP, and HR every 10 min. After baseline measurements were stable for a 30-min period, fasudil (10 µg/min for 2 h) was infused into the LPA. Hemodynamic measurements were continued for a 30-min recovery period.

The second step of this protocol was to investigate the effects of prolonged fasudil infusions during DA compressions for 2 h. After baseline measurements were obtained for 30-min, a 2-h DA compression was performed with or without concomitant infusion of fasudil (50 µg/min into the SVC for 2 h). The degree of inflation was set to increase mPAP by 15 mmHg from its baseline value (47). Mean PAP was kept constant through the compression period by readjusting the degree of inflation of the occluder. During the compression period, data were recorded every 5 min during the first 30 min, then every 10 min, and then until 30 min after the DA compression was released. These data were analyzed to compare to effects of DA compression with or without fasudil treatment and the response to fasudil without DA compression.

Statistical Analysis

Statistical analysis was performed with the StatView software package (SAS Institute, Cary, NC). Statistical comparisons were performed using repeated-measures analysis of variance and Fisher's protected least significant differences test. Results are means ± SE. The significance level was set at P < 0.05.

	RESULTS

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Protocol 1: Effects of Fasudil on the Hemodynamic Response to Partial Acute DA Compression

We found that intrapulmonary infusion of low doses of fasudil (100 µg over 10 min) did not enhance flow-induced vasodilation during brief (10 min) DA compression. Acute DA compression without fasudil increased mPAP above baseline by 30.2 ± 2.0% (from 46.6 ± 1.9 to 60.5 ± 1.7 mmHg; P < 0.001), increased Q_LPA by 80.9 ± 12.8% (from 73.4 ± 4.9 to 130.7 ± 9.0 ml/min; P < 0.001), and reduced PVR from 0.61 ± 0.04 to 0.45 ± 0.03 mmHg·ml^–1·min (P < 0.05) (Fig. 1, column A). During acute DA compression, HR increased from 159.8 ± 4.7 to 189.0 ± 6.0 beats/min (P < 0.01). Mean AoP (baseline value: 42.4 ± 1.2 mmHg) and blood gas parameters (baseline values: pH, 7.38 ± 0.01; PCO₂, 41.4 ± 1.3 mmHg; PO₂, 23.2 ± 1.0 mmHg; Sa_O2, 57.7 ± 3.6%; and Hct, 33.3 ± 1.4%) did not change during acute DA compression.

View larger version (22K): [in this window] [in a new window]   Fig. 1. Changes in mean pulmonary artery pressure (mPAP), left pulmonary artery flow (QLPA), and pulmonary vascular resistance (PVR) during partial compression of the ductus arteriosus (DA; column A, n = 9), fasudil infusion (100 µg over 10 min; column B, n = 8), and combined DA compression after fasudil infusion (column C, n = 7). Low-dose intrapulmonary infusion of fasudil, a Rho-kinase (ROCK) inhibitor, did not enhance flow-induced vasodilation during brief DA compression. Values are means ± SE. *P < 0.05 compared with baseline. βP < 0.05 compared with fasudil infusion alone.

Overall, the maximal increase in flow during acute DA compression alone was not different from values achieved during DA compression after infusion of low doses of fasudil (Fig. 1, columns A and C). Similarly, there was no statistical difference in the maximal decrease in PVR between acute DA compression with or without fasudil at the doses used for this study (Fig. 2).

View larger version (9K): [in this window] [in a new window]   Fig. 2. Response to brief (10 min) DA compressions, expressed as the percent change in PVR from baseline for the 3 study conditions (DA, n = 9; fasudil, n = 8; DA+fasudil, n = 7). As shown, fasudil did not augment the vasodilator effects during brief DA compression. Values are means ± SE. *P < 0.05. NS, not significant.

These studies were performed after treatment with the nitric oxide synthase inhibitor L-NNA, to unmask the myogenic response by blocking flow-induced vasodilation, as previously described (47). Forty minutes after L-NNA treatment, pulmonary hemodynamics were not significantly different from baseline values, although there were trends for increased mPAP and PVR and reduced Q_LPA (Fig. 3). Similarly, HR (baseline value: 153 ± 11 beats/min) and blood gas parameters (baseline values: pH, 7.36 ± 0.01; PCO₂, 37.7 ± 2.7 mmHg; PO₂, 24.4 ± 1.5 mmHg; Sa_O2, 66.8 ± 5.3%; and Hct, 29.8 ± 0.5%) did not significantly change after L-NNA infusion. The first DA compression after L-NNA treatment increased mPAP from 51.3 ± 2.2 to 65.1 ± 1.8 mmHg (P < 0.001) without altering Q_LPA, reflecting an increase in PVR from 0.74 ± 0.07 to 0.85 ± 0.07 mmHg·ml^–1·min (P < 0.05) (Fig. 3). DA compression after L-NNA infusion did not change HR, mAoP, or blood gas parameters.

View larger version (22K): [in this window] [in a new window]   Fig. 3. Hemodynamic responses to brief (10 min) DA compression (shaded bars) after N-nitro-L-arginine (L-NA) infusion and with and without fasudil treatment (A, n = 6). After L-NA administration, mPAP was increased by +28% above baseline during DA compression, resulting in a marked increase in PVR. After fasudil infusion, for a similar increase in mPAP, QLPA increased by 50% and PVR did not increase. Mean PAP, QLPA, and PVR changes are represented as superimposed plots on the same time scale in B. Values are means ± SE. ***P < 0.001 compared with baseline.

When expressed as the percent change of PVR from baseline, DA compression after L-NNA infusion increased by 15 ± 3%, which is strikingly different from the fall in PVR measured during DA compression alone (–27 ± 4%; P < 0.01 for comparison of treatment groups). Fasudil treatment before DA compression completely blocked the increase in PVR (+2 ± 2%; P < 0.05) (Fig. 4).

View larger version (8K): [in this window] [in a new window]   Fig. 4. Hemodynamic responses to a brief (10 min) DA compression alone, after L-NA administration, and with and without fasudil treatment, expressed as the percent change in PVR from baseline (n = 6). Compared with DA compression alone, DA compression after L-NA injection increased PVR. Fasudil treatment completely blocked the increase in PVR (P < 0.05 for all comparisons). Values are means ± SE. *P < 0.05; ***P < 0.001.

View larger version (14K): [in this window] [in a new window]   Fig. 5. Relationships between mPAP and QLPA (top) and PVR (bottom) after L-NA administration with (n = 4) and without (n = 4) fasudil treatment. As shown, QLPA increased linearly with the increase in mPAP and decreased PVR. After L-NA treatment, QLPA only slightly changed with serial increases in mPAP, and PVR increased linearly with the increase in mPAP. After both L-NA and fasudil treatment, QLPA increased linearly with mPAP, resulting in a linear decrease in PVR. The slope for QLPA was significantly increased after L-NA and fasudil compared with L-NA alone (P < 0.05).

Low-dose fasudil infusion caused a sustained increase in Q_LPA and a decrease in PVR for the entire 2-h study period. Mean PAP did not change during the study period (Fig. 6). There also were no changes in HR (baseline value: 174 ± 12 beats/min), mAoP (baseline value: 42.9 ± 1.8 mmHg), and blood gas parameters (baseline values: pH, 7.38 ± 0.01; PCO₂, 44.1 ± 2.2 mmHg; PO₂, 19.2 ± 1.9 mmHg; Sa_O2, 54.6 ± 4.7%; and Hct, 34.0 ± 2.4%). On an alternate day in these same animals, the hemodynamic effects of DA compression without pretreatment with L-NNA or concurrent infusions of fasudil were studied. As shown in Fig. 7, DA compression caused a progressive rise in Q_LPA during the first hour of study. However, despite maintaining mPAP constant, Q_LPA progressively decreased toward baseline values during the second hour of compression. In contrast, DA compression with continuous fasudil infusion led to a sustained elevation of Q_LPA throughout the entire 2-h study period (Fig. 7). Fasudil infusion during the 2-h DA compression caused a sustained decrease in PVR, whereas a 2-h partial DA compression alone resulted in only a transient decrease in PVR during the first hour (Fig. 7). HR increased to 203 ± 2 beats/min during fasudil infusion with DA compression compared with baseline (169 ± 13 beats/min; P < 0.05) and fasudil infusion alone (179 ± 9 beats/min; P < 0.05). Mean AoP and blood gas parameters did not change during acute DA compression (Table 1).

View larger version (13K): [in this window] [in a new window]   Fig. 6. Pulmonary hemodynamic response during prolonged fasudil infusion (10 µg/min for 2 h) into the left pulmonary artery (n = 6). Fasudil caused a sustained increase in QLPA and a decrease in PVR for the entire 120-min study period, which returned to the baseline 10 min after termination of drug infusion. No change was observed for PAP. *P < 0.05 compared with baseline.

View larger version (20K): [in this window] [in a new window]   Fig. 7. Changes in mPAP, QLPA, and PVR during prolonged DA compression with (n = 4) or without (n = 4) a concomitant fasudil infusion. Fasudil treatment caused a sustained increase in QLPA and decrease in PVR during DA compression, whereas DA compression alone resulted in only transient changes during the first hour, which were not sustained during the second hour. Values are means ± SE. *P < 0.05 between DA compression alone and DA compression with a concomitant fasudil infusion.

	DISCUSSION

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Past studies have suggested that increased myogenic tone maintains high PVR in the normal fetal lung (46, 47), but mechanisms that mediate the myogenic response in the fetus are poorly understood. Since ROCK activity contributes to the myogenic response in the postnatal systemic circulation (31), we studied the effects of ROCKi on the myogenic response in the fetal pulmonary circulation. We found that fasudil, a specific ROCKi, did not enhance flow -induced pulmonary vasodilation during brief DA compression in the ovine fetus. However, fasudil completely blocked the myogenic response induced by acute DA compression after inhibition of NO-mediated vasodilation with L-NNA. These findings suggest that high ROCK activity contributes significantly to the myogenic response in the fetal pulmonary circulation.

On the basis of previous work that demonstrated the inability to sustain vasodilation during prolonged exposure to diverse dilator stimuli in the fetal lung, we further hypothesized that a potent myogenic response opposed vasodilation in the fetal lung through increased ROCK activity. To study the role of ROCK activity on the pulmonary hemodynamic effects of prolonged DA compression, we infused low doses of fasudil during 2 h of DA compression. In contrast with the progressive fall in Q_LPA during DA compression, fasudil treatment led to sustained elevations of Q_LPA and reduced PVR. Overall, these findings suggest that activation of the myogenic response opposes pulmonary vasodilation during prolonged exposure to hemodynamic forces in the fetal lung.

This study is the first to demonstrate that ROCK activity mediates the myogenic response in the fetal pulmonary circulation and links high ROCK activity as a critical mechanism underlying time-dependent pulmonary vasodilation in the fetus. Past studies have demonstrated that many pulmonary vasodilators often have only a transient effect in the fetal lung despite prolonged treatment with such stimuli as increased oxygen tension, acetylcholine, bradykinin, histamine, tolazoline, prostaglandins, and hemodynamic forces induced during DA compression (6, 22). These past studies have shown that autoregulatory mechanisms exist in the fetal lung that oppose vasodilation and contribute to high PVR. In our study, we showed that fasudil, a ROCKi, can block the myogenic response during brief and prolonged DA compression and can cause sustained elevation of pulmonary blood flow with continuous infusion.

Recent studies have shown that pulmonary hypertension induced by chronic hypoxia is associated with increased ROCK expression and/or activity (20, 36). In vivo, prolonged fasudil treatment reduced the development of pulmonary hypertension and attenuated pulmonary artery remodeling in animal models (1, 17, 30, 36). Studies on the acute effects of ROCKi treatment of animals with pulmonary hypertension have consistently shown a striking decrease in mPAP, which is often greater than the effects of inhaled NO or calcium channel blockade (15, 25, 37, 38). Clinically, brief treatment with fasudil was recently shown to acutely lower PVR in patients with pulmonary artery hypertension, suggesting a potential therapeutic role (18, 21). Thus most studies on the pulmonary circulation have focused on the pathophysiological role of ROCK in the development and maintenance of pulmonary hypertension.

We found that fasudil, a ROCKi, can block the myogenic response induced by a partial DA compression with blockage of the blood flow-induced vasodilation. Past studies have shown that the myogenic response is involved in high PVR in the normal fetus (5, 9, 40, 46, 47). ROCK has been shown to mediate the myogenic response in the adult systemic circulation (23, 33, 44), but the presence of the myogenic response in the normal adult lung circulation has not been reported. However, a recent study suggested that myogenic tone may develop in small pulmonary arteries after chronic hypoxia in vitro, but this has yet to be demonstrated in the intact lung or whole animal (10). In our study, fasudil infusion, at low doses that were not sufficient to acutely decrease pulmonary vascular resistance alone, inhibited the myogenic response induced by DA compression, highlighting the contribution of ROCK to myogenic tone in the normal fetus (Fig. 8). Our results suggest that flow-induced vasodilation may be enhanced by prolonged infusions of fasudil during the initial 20–30 min of DA compression. This is likely due to inhibition of the pressure-induced vasoconstriction that is induced during DA compression (Fig. 7). Since the myogenic response is greater in fetal sheep exposed to chronic intrauterine pulmonary hypertension, an experimental model of PPHN (46), we speculate that ROCKi may have a significant effect on modulating vasoreactivity in the pathological setting as well as in normal fetal sheep.

View larger version (20K): [in this window] [in a new window]   Fig. 8. Schematic illustrating proposed mechanisms underlying the net effects of DA compression on fetal pulmonary blood flow during DA compression, which represent an equilibrium between flow-induced vasodilation and pressure-induced vasoconstriction (myogenic tone). Rho-kinase pathway is related to calcium sensitization, high vascular tone, and myogenic response, which are offset through activation of the nitric oxide (NO) pathway, which induces vasodilation. GC, guanylate cyclase; GTP, guanosine 5'-triphosphate; cGMP, guanosine 3',5'-cyclic monophosphate; Ca2+, intracellular calcium; MLC, myosin light chain; MLC-P, phosphorylated MLC; MLCK, MLC kinase; MLCPh, MLC phosphatase (active); MLCPh-P, phosphorylated MLC phosphatase (inactive).

Furthermore, other mechanisms may modulate the hemodynamic effects of acute DA compression in the fetus. For example, NO activates PKG, which can inhibit RhoA, suggesting that the loss of endothelium-derived NO production may augment ROCK activity in vascular smooth muscle (34), highlighting the complexity of interactions between these pathways.

Potential limitations of this study include only the use of fasudil as a ROCKi due to the extensive number of experiments in this study. However, we observed the same inhibitory effect on the myogenic response during acute DA compression with Y-27632, another ROCKi, as observed with fasudil treatment (data not shown). A major strength of this work is related to the fact that we performed these experiments in vivo with the chronically prepared, late-gestation fetal sheep model. However, these in vivo studies do not allow for the possibility of directly measuring rapid changes in ROCK activity. Further work is needed to determine specific arterial sites of the myogenic response within the lung vasculature, perhaps with the use of isolated conduit and small pulmonary arteries, as recently suggested by Broughton et al. (10).

We conclude that ROCK activity contributes to high PVR in the normal fetal pulmonary circulation, opposes vasodilation to hemodynamic forces due to DA compression, and mediates the striking myogenic response in the normal fetal pulmonary circulation before birth. We speculate that persistence of high myogenic reactivity may contribute to the pathophysiology of PPHN and that ROCK inhibitors may provide novel therapeutic strategies for treating severe pulmonary hypertension in newborns.

	GRANTS

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This project was supported by grants from the Société Française de Médecine Périnatale, the Conseil Régional de Picardie, France, and National Heart, Lung, and Blood Institute Grants R01 HL68702 (to S. H. Abman) and K08 HL072916 (to T. Grover).

	ACKNOWLEDGMENTS

 
We thank Gates Roe and Christine Hunt-Peacock for technical help.

	FOOTNOTES

 

Address for reprint requests and other correspondence: P. Tourneux, Médecine Néonatale et Réanimation Pédiatrique Polyvalente, CHU Amiens Nord, 1 place Victor Pauchet, 80054 Amiens Cedex 1, France (e-mail: tourneux.pierre{at}chu-amiens.fr)

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.

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