Pulmonary arteries of Williams syndrome patients exhibit altered serotonin metabolism genes and degenerated medial layer architecture.

BACKGROUND: Williams-Beuren syndrome (WS) is characterized by cardiovascular abnormalities associated with a multigene deletion on 7q11.23, in particular elastin (ELN). Peripheral pulmonary artery stenosis (PPAS) frequently affects pediatric patients with WS. Molecular investigation of WS pulmonary arterial (PA) tissue is limited by tissue scarcity. METHODS: We compared transcriptomes, tissue architecture, and localized changes in protein expression in PA tissue from patients with WS (n = 8) and donors (n = 5). RESULTS: Over 100 genes were differentially expressed at the ≥4-fold level, including genes related to the serotonin signaling pathway: >60-fold downregulation of serotonin transporter SLC6A4 and >3-fold upregulation of serotonin receptor HTR2A. Histologic examination revealed abnormal elastin distribution and smooth muscle cell morphology in WS PA, with markedly shorter, disorganized elastin fibers, and expanded proteoglycan-rich extracellular matrix between muscle layers. CONCLUSIONS: There were significant abnormalities in the PA expression of genes regulating serotonin signaling, metabolism, and receptors in WS. Those changes were associated with distinct changes in the arterial structure and may play a role in the stenosis-promoting effects of elevated shear stress at PA bifurcations in WS. IMPACT: Serotonin pathway signaling is significantly altered in the pulmonary arteries of patients with Williams syndrome and severe peripheral arterial stenosis. The present study compares the histological and biochemical characteristics of pulmonary arteries from patients with Williams syndrome to those of controls, something that has not, to our knowledge, been done previously. It demonstrates marked abnormalities in the pulmonary arteries of patients with Williams syndrome, especially significant pathologic alterations in the signaling of the serotonin pathway. The findings of this study provide direction for the development of potential therapies to treat pulmonary artery stenosis in patients with Williams syndrome.

Tetralogy of Fallot: aorto-pulmonary collaterals and pulmonary arteries have distinctly different transcriptomes.

BACKGROUND: Tetralogy of Fallot patients with pulmonary atresia (TOF/PA) present a pulmonary blood supply directly from aortic collateral arteries. Major aorto-pulmonary collateral arteries (MAPCAs) present substantial clinical and surgical management challenges. Surgical operations to reestablish and promote further development of a pulmonary arterial connection preferentially utilize MAPCAs for reconstruction of central pulmonary arteries. However, the propensity of some MAPCAs to develop stenosis rather than growth may impair the response to reconstructions. METHODS: Probe sets prepared from MAPCAs, PA, and aorta mRNA were used to interrogate human genome microarrays. We compared expression differences between pairs of the three vessels to determine whether MAPCAs display distinct expression patterns. RESULTS: Functional clustering analysis identified differences in gene expression, which were further analyzed by gene ontology classification. A subset of highly regulated genes was validated using quantitative PCR. Expression differences among vessel types were observed for multiple gene classes. Of note, we observed that MAPCAs differentially express several genes at much higher levels than either PA or aorta. CONCLUSION: MAPCAs differ from PA or aorta by significantly altered levels in gene expression, suggesting a transcriptional basis for their physiology that will guide a further understanding of the pathobiology of MAPCAs and TOF.

Deep Hypothermic Circulatory Arrest Activates Neural Precursor Cells in the Neonatal Brain.

BACKGROUND: Use of antegrade cerebral perfusion (ACP) as an alternative neuroprotection strategy to deep hypothermic circulatory arrest (DHCA) in the setting of cardiopulmonary bypass in neonates has become a common approach, although the value of ACP over DHCA remains highly debated. This study investigated the disruption to neonatal brain homeostasis by DHCA and ACP. METHODS: Neonatal pigs (7 days old) undergoing bypass were assigned to 4 groups: DHCA at 18°C and ACP at 18°, 25°, and 32° for 45 minutes (n = 6 per group). ACP was initiated through the innominate artery and maintained at 40 mL/kg/min. After bypass, all animals were maintained sedated and intubated for 24 hours before being euthanized. Brain subventricular zone tissues were analyzed for histologic injury by assessing apoptosis and neural homeostasis (Nestin). RESULTS: Histologic examination showed no significant ischemic/hypoxic neuronal death at any cooling temperature among the 4 treatment groups. However, we detected a significantly higher apoptotic rate in DHCA compared with ACP at 18°C (P = .003-.017) or 25°C (P = .012-.043), whereas apoptosis at 32°C was not different from DHCA. Of note, we identified increased Nestin expression in the DHCA group compared with all ACP groups (P range = .011-.041). CONCLUSIONS: Neonatal piglet ACP at 18° or 25°C provides adequate protection from increased brain cellular apoptosis. In contrast to ACP, however, DHCA induces brain Nestin expression, indicating activation of neural progenitor cells and the potential of altering neonatal neurodevelopmental progression. DHCA has potential to more profoundly disrupt neural homeostasis than does ACP.

Pulmonary arteriovenous shunting in the normal fetal lung.

OBJECTIVES: We hypothesized that pulmonary arteriovenous shunting (PAVS) is normally present in fetal lungs and that cavopulmonary anastomosis-induced PAVS may represent a return to an earlier morphologic stage of development. BACKGROUND: The surgical superior cavopulmonary anastomosis is performed as part of the staged Fontan pathway to treat univentricular forms of congenital heart disease; PAVS is a known sequela after superior cavopulmonary anastomosis and may have important clinical consequences. Although the etiology and true morphology of the structures responsible for PAVS are unknown, a leading theory is that PAVS is caused by absence of normal hepatic venous drainage to the pulmonary circulation. METHODS: To determine whether normal fetal lungs demonstrate PAVS, we performed contrast echocardiograms on 13 fetal lambs, 8 neonatal lambs, 4 juvenile lambs, and 4 adult sheep using a blended mixture of saline and blood injected directly into the proximal pulmonary artery. RESULTS: Pulmonary arteriovenous shunting was detected by direct epicardial echocardiography in all fetal lambs (n = 13) and neonatal animals studied at one and three days of life (n = 4) and in two of four animals studied at six to nine days of life. Pulmonary arteriovenous shunting was not present in animals studied at four weeks of life (n = 2) and in adult sheep (n = 5). CONCLUSIONS: These studies demonstrate that PAVS is normally present in late gestation fetal and early neonatal lambs but then disappears during the later neonatal period. Furthermore, these findings suggest that PAVS associated with cavopulmonary anastomosis or other processes affecting the developing pulmonary circulation may represent a return to an earlier morphologic stage of development.

Morphological studies of pulmonary arteriovenous shunting in a lamb model of superior cavopulmonary anastomosis.

We sought to identify and characterize the abnormal vascular structures responsible for pulmonary arteriovenous shunting following the Glenn cavopulmonary shunt. Superior cavopulmonary shunt is commonly performed as part of the staged pathway to total cavopulmonary shunt to treat univentricular forms of congenital heart disease, however, clinically significant pulmonary arteriovenous malformations develop in some patients after the procedure. The causes of pulmonary arteriovenous malformations and other pulmonary vascular changes that occur after cavopulmonary shunt are not known. Using a juvenile lamb model of superior cavopulmonary anastomosis that reliably produces pulmonary arteriovenous malformations, we performed echocardiography and morphological analyses to determine the anatomic site of shunting and to identify the vascular structures involved. Pulmonary arteriovenous shunting was identified by contrast echocardiography in all surviving animals (n = 40) following superior cavopulmonary anastomosis. Pulmonary vascular corrosion casts revealed abnormal tortuous vessels joining pulmonary arteries and veins in cavopulmonary shunt animals but not control animals. In conclusion, unusual channels that bridged pulmonary arteries and veins were identified. These may represent the vascular structures responsible for arteriovenous shunting following the classic Glenn cavopulmonary shunt. Detailed analysis of these structures may elucidate factors responsible for their development.