Françoise Mauray

β1 And β3 integrins have different roles in the adhesion and migration of vascular smooth muscle cells on extracellular matrix

Extracellular matrix receptors on ductus arteriosus smooth muscle cells (SMC) must enable the cells to migrate through both interstitial and basement membrane matrices to form intimal mounds during postnatal ductus closure. We examined the role of beta 1 and beta 3 integrin receptors on SMC adhesion and migration. Using a new assay to measure cell migration, we found that lamb ductus arteriosus SMC attach to and migrate over surfaces coated with fibronectin (FN), laminin (LN), vitronectin (VN), and collagens I (I) and IV (IV). Blocking antibodies, specific to different integrin complexes, showed that SMC adhesion to FN, LN, I, and IV depended exclusively on functioning beta 1 integrins with little, if any, contribution by the alpha V beta 3 integrin; on the other hand, cell migration over these substrates depended to a large extent on the alpha V beta 3 receptor. Immunofluorescent staining demonstrated that during the early phase of SMC migration, the beta 1 integrins organized rapidly into focal plaques that, with time, gradually covered the cells basal surface; on the other hand, the beta 3 receptor remained concentrated at all times at the cells margins. Ligand affinity chromatography and immunoprecipitation techniques identified a unique series of beta 1 integrins binding to each matrix component: FN (alpha 5 beta 1, alpha 3 beta 1, alpha V beta 1), LN (alpha 1 beta 1, alpha 7 beta 1), VN (alpha V beta 1), I (alpha 1 beta 1, alpha 2 beta 1), and IV (alpha 1 beta 1). In contrast, the beta 3 integrin, alpha V beta 3, bound to all the substrates tested: FN, LN, VN, I, and IV. The results indicate that beta 1 and beta 3 integrins may play different roles in attachment and migration as SMC move through the vascular extracellular matrix to produce obliteration of the ductus arteriosus lumen.

Permanent Anatomic Closure of the Ductus Arteriosus in Newborn Baboons: The Roles of Postnatal Constriction, Hypoxia, and Gestation

Permanent closure of the ductus arteriosus require loss of cells from the muscle media and development of neointimal mounds, composed in part of proliferating endothelial cells. We hypothesized that postnatal ductus constriction produces hypoxia of the inner vessel wall; we also hypothesized that hypoxia might lead to cell death and the production of vascular endothelial cell growth factor (VEGF), a hypoxia-inducible growth factor that stimulates endothelial proliferation. We mapped the distribution of hypoxia in newborn baboons and correlated it with the appearance of cell death (TUNEL technique), VEGF expression, and endothelial proliferation (proliferating cell nuclear antigen expression). In the full-term baboon (n = 10), the ductus was functionally closed on Doppler examination by 24 h after delivery. Regions of the ductus where the lumen was most constricted were associated with moderate/intense hypoxia; VEGF expression was increased in the hypoxic muscle media, and luminal endothelial cells, adjacent to the hypoxic media, were proliferating. Cells in the most hypoxic regions of the ductus wall were undergoing DNA fragmentation. In contrast, regions of the ductus with mild degrees of hypoxia had no evidence of cell death, VEGF expression, or endothelial proliferation. Cell death and endothelial proliferation seemed to be limited to regions of the full-term ductus experiencing moderate/intense hypoxia. In the premature baboon (67% gestation) (n = 24), only 29% closed their ductus by Doppler examination before d 6. None of the premature baboons, including those with a closed ductus by Doppler, had evidence of moderate/intense hypoxia; also, there was no evidence of cell death, VEGF expression, endothelial proliferation, or neointima formation by d 6. Therefore, the premature ductus is resistant to developing hypoxia, even when its lumen is constricted; this may make it susceptible to later reopening.

Regulation of Ductus Arteriosus Patency by Nitric Oxide in Fetal Lambs: The Role of Gestation, Oxygen Tension, and Vasa Vasorum

We hypothesized that nitric oxide (NO) production by the fetal ductus arteriosus is limited because of low fetal PO2, but that at neonatal PO2, NO might be an important regulator of ductus arteriosus tone. We exposed isolated rings of fetal lamb ductus arteriosus to elevated PO2. L-NG-nitro-L-arginine methyl ester (L-NAME), an inhibitor of nitric oxide synthase (NOS), and methylene blue and 6-anilino-5,8-quinolinedione (LY83583), inhibitors of guanylate cyclase, produced constriction of the ductus arteriosus. When ductus arteriosus rings were exposed to low PO2, L-NAME had no effect, and methylene blue and LY83583 had only a small effect on ductus arteriosus tone. Sodium nitroprusside and calcium ionophore A23187 relaxed ductus arteriosus rings more than aortic rings, and relaxed ductus arteriosus rings from immature fetuses more than those from late gestation fetuses. In contrast, ductus arteriosus rings from both early and late gestation were equally sensitive to 8-bromo-cGMP. By both reverse transcriptase-polymerase chain reaction and immunohistochemistry, endothelial cell NOS and inducible calcium-independent NOS, but not nerve cell NOS, were detected in the ductus arteriosus. Inducible NOS was expressed only by endothelial cells lining the ductus arteriosus lumen; in contrast, endothelial cell NOS was expressed by both luminal and vasa vasorum endothelial cells. The role of inducible NOS in the ductus arteriosus is uncertain because the potency of a specific inducible NOS inhibitor in constricting the ductus arteriosus was negligible compared with that of an endothelial cell NOS inhibitor. We speculate that NO may be an important regulator of ductus arteriosus tone at high but not low PO2. The endothelial cell NOS isoform found in vasa vasorum may be an important source of NO because removal of ductus arteriosus luminal endothelium only partially blocks the effects of L-NAME, methylene blue, and LY83583.

Cardiovascular effects of patent ductus arteriosus in preterm lambs with respiratory distress

We created a model for studying the cardiovascular and pulmonary effects of patent ductus arteriosus (PDA) in premature lambs with respiratory distress. In 47 fetal lambs at 129 to 133 days gestation (term, 145 days), we infiltrated the ductus arteriosus with formalin and placed a mechanical occluder about it so that its patency could be regulated. Two days later the lambs were delivered, given sheep surfactant, paralyzed, and their lungs mechanically ventilated. These premature lambs could more than double their left ventricular output when challenged with increasing degrees of left-to-right shunts through the PDA. This was accomplished by an increase in stroke volume, not by an increase in heart rate. During the 40-minute observation period, there was no change in dynamic compliance or functional residual capacity while the ductus was patent. When the ductus was patent, there was a significant increase in arterial PaO2 (even with small left-to-right shunts) and a decrease in PaCO2 (with large shunts). Despite the hearts ability to handle the increased volume load of a PDA, there were significant alterations in individual organ blood flows, resulting from a combination of decreased perfusion pressure and localized vasoconstriction. The abdominal organs had significant reductions in blood flow even with small PDA shunts. This decrease in organ blood flow may explain some of the pathophysiologic manifestations of PDA in preterm infants.

Effects of a protein-free, synthetic surfactant on survival and pulmonary function in preterm lambs

We have created a totally synthetic, protein-free surfactant (Exosurf) composed of dipalmitoylphosphatidylcholine, hexadecanol, and tyloxapol. We studied the effects of endotracheal instillation of Exosurf on survival and pulmonary function of preterm lambs delivered at 131 to 133 days gestation (term 148 days). Exosurf treatment was compared with instillation of surface-active material prepared from lung lavages of adult sheep and with no instillation. Lambs were delivered by cesarean section, paralyzed, and mechanically ventilated. The Exosurf group survived longer (80% alive at 11 hours) than did the no instillation group (30% alive at 11 hours) (P less than 0.05). There were no statistically significant differences between the Exosurf and sheep surfactant groups. We conclude that Exosurf, a synthetic surfactant, produces significant improvement in survival and pulmonary function in preterm lambs.

Combined Prostaglandin and Nitric Oxide Inhibition Produces Anatomic Remodeling and Closure of the Ductus Arteriosus in the Premature Newborn Baboon

After birth, the full-term ductus arteriosus actively constricts and undergoes extensive histologic changes that prevent subsequent reopening. These changes are thought to occur only if a region of intense hypoxia develops within the ductus wall after the initial active constriction. In preterm infants, indomethacin-induced constriction of the ductus is often transient and is followed by reopening. Prostaglandins and nitric oxide both play a role in inhibiting ductus closure in vitro. We hypothesized that combined inhibition of both prostaglandin and nitric oxide production (with indomethacin and N-nitro-l-arginine (L-NA), respectively) may be required to produce the degree of functional closure that is needed to cause intense hypoxia. We used preterm (0.67 gestation) newborn baboons that were mechanically ventilated for 6 d: 6 received indomethacin alone, 7 received indomethacin plus L-NA, and 16 received no treatment (control). Just before necropsy, only 25% of control ductus and 33% of indomethacin-treated ductus were closed on Doppler examination; in contrast, 100% of the indomethacin-plus-L-NA-treated ductus were closed. Control and indomethacin-treated baboons developed negligible-to-mild ductus hypoxia (EF5 technique). Similarly, there was minimal evidence of ductus remodeling. In contrast, indomethacin-plus-L-NA-treated baboons developed intense hypoxia in regions where the ductus was most constricted. The hypoxic muscle strongly expressed vascular endothelial growth factor, and proliferating luminal endothelial cells filled and occluded the lumen. In addition, cells in the most hypoxic regions were undergoing DNA fragmentation. In conclusion, preterm newborns are capable of remodeling their ductus, just like the full-term newborn, if they can reduce their luminal blood flow to a point that produces intense ductus wall hypoxia. Combined prostaglandin and nitric oxide inhibition may be necessary to produce permanent closure of the ductus and prevent reopening in preterm infants.

Increased shunt through the patent ductus arteriosus after surfactant replacement therapy

Instillation of surfactant into the trachea of preterm infants with respiratory distress syndrome is associated with a 90% incidence of patent ductus arteriosus. We studied the effects of surfactant therapy on the ductus arteriosus in 12 preterm lambs. Flow across the ductus arteriosus and systemic blood flow were calculated from radioactive microsphere injections. All developed respiratory failure (pH less than 7.1, Paco2 greater than 60) by 30 minutes after birth. Between 30 and 60 minutes after birth, six lambs were treated with tracheal instillation of 50 mg/kg surfactant lipid. By two hours after birth, treated lambs differed significantly from controls in pH (7.27 +0.02 vs 6.97 +0.08) and Paco2 (43.3 +4.1 vs 85 + 15). There were no differences in Pao2 or PGE2 concentrations or ductus arteriosus resistance, but there was a significantly larger shunt through the ductus arteriosus in treated lambs. This increased shunt resulted from the significant drop in pulmonary vascular resistance and not from a change in patency of the ductus arteriosus. Surfactant replacement may require interventions directed specifically at the patent ductus arteriosus in sick preterm infants.

PGE2 is a more potent vasodilator of the lamb ductus arteriosus than is either PGI2 or 6 keto PGFα

It has been shown in vitro that the lamb ductus arteriosus forms prostaglandins PGE2, PGF2alpha, 6 keto PGF1alpha (and its unstable precursor PGI2). In this study the relative potencies of these endogenous prostaglandins were investigated on isolated lamb ductus arteriosus preparations contracted by exposure to elevated PO2 and indomethacin. All the prostaglandins (except PGF2alpha) relaxed the vessel. This is consistent with the hypothesis that endogenous prostaglandins inhibit the tendency of the vessel to contract in response to oxygen. Only PGE2, however, relaxed the vessel at concentrations below 10(-8)M. PGI2 and 6 keto PGF1alpha had approximately 0.001 and 0.0001 times the activity of PGE2. Although PGE2 has been observed to be a minor product of prostaglandin production in the lamb ductus arteriosus, the tissues marked sensitivity to PGE2 might make it the most significant prostaglandin in regulating the patency of the vessel.

Vasa vasorum hypoperfusion is responsible for medial hypoxia and anatomic remodeling in the newborn lamb ductus arteriosus

Postnatal constriction of the full-term ductus arteriosus produces hypoxia of the muscle media. This is associated with anatomic remodeling (including smooth muscle death) that prevents subsequent reopening. We used late-gestation fetal and neonatal lambs to determine which factors are responsible for the postnatal hypoxia. Hypoxia [measured by 2-(2-nitro-1H-imidazol-1-yl)-N-(2,2,3,3,3-pentafluoropropyl) acetamide technique] and cell death (measured by terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling technique) were observed in regions of the constricted ductus wall within 4 h after delivery. Although there was a decrease in ductus luminal flow during the first 6 h after delivery (measured by Doppler transducer), the amount of oxygen delivered to the ductus lumen (3070 ± 1880 μmol O2 · min−1 · g−1) far exceeded the amount of oxygen consumed by the constricted ductus (0.052 ± 0.021 μmol O2 · min−1 · g−1, measured in vitro). Postnatal constriction increased the effective oxygen diffusion distance across the ductus wall to >3× the limit that can be tolerated for normal tissue homeostasis. This was owing to both an increase in the thickness of the ductus (fetus, 1.12 ± 0.20 mm; newborn, 1.60 ± 0.17 mm;p < 0.01) and a marked reduction in vasa vasorum flow (fetus, 0.99 ± 0.44 mL · min−1 · g−1; newborn, 0.21 ± 0.08 mL · min−1 · g−1;p < 0.01). These findings suggest that hypoxic cell death in the full-term ductus is caused primarily by changes in vasa vasorum flow and muscle media thickness and can occur before luminal flow has been eliminated. We speculate that in contrast with the full-term ductus, the preterm ductus is much less likely to develop the degree of hypoxia needed for vessel remodeling inasmuch as it only is capable of increasing its oxygen diffusion distance to 1.3× the maximally tolerated limit.

The Developmental Response of the Ductus arteriosus to Oxygen

We studied the isometric contractile effects of increased PO2 on isolated rings of lamb ductus arteriosus (from three different gestational age groups). When rings were stretched to initial lengths that result in a maximal contractile response for rings in that age group, the oxygen-induced contraction was 5.91 +/- 0.72 g/mm2 (+/-SEM, n = 18) in animals older than 135 days, 5.55 +/- 1.23 g/mm2 (n = 18) in animals between 111 and 130 days, and 3.85 +/- 0.75 g/mm2 (n = 19) in animals between 87 and 110 days. Only in the most immature vessels could a decrease in the tissues response to oxygen be observed.