A distinct microvascular endothelial gene expression profile in severe IUGR placentas.

The placental microvasculature is essential for efficient transfer of gases, nutrients and waste between the mother and fetus. Microvascular hypoplasia of the terminal villi is a common pathology in severe Intra Uterine Growth Restriction (IUGR). We used novel methods to obtain placental micro-vascular endothelial cells (PlMEC) from preterm control placentas (n = 3) and placentas from pregnancies with severe IUGR (n = 6) with absent or reversed end-diastolic velocity in the umbilical artery. Distal placental villous tissue was collected to enrich for intermediate and terminal villi. Tissue was digested and PlMEC positively selected using tocosylated magnetic Dynabeads labeled with Human Endothelial Antigen lectin. The purity of the PlMEC (94 ± 2 SD %) was assessed by CD31 and vimentin immunocytochemistry. RNA was extracted from the PlMEC samples and subjected to Affymetrix microarray analysis (U133Plus2 array chips). Comparison of preterm and IUGR PlMEC gene expression profiles identified BTNL9 and NTRK2 transcripts to be upregulated and SAA1 and SLAMF1 transcripts to be downregulated in all 6 IUGR cases relative to preterm controls. A third downregulated gene GNAS was identified to be near significance. Changes were demonstrated to be significant at the mRNA level by Real Time PCR in the PlMEC samples. Changes in the IUGR endothelium were confirmed at the protein level by immunohistochemistry for the 3 with available antibodies. We used a tissue microarray constructed from an independent cohort of placental samples from severe IUGR (n = 7), preeclamptic (n = 7), preterm control (n = 6) and term control (n = 6) pregnancies. Results confirmed differential endothelial expression of BTNL9, NTRK2 and SLAMF1 in IUGR versus preterm and term samples. These studies are the first to characterize PlMEC gene expression profiles thus we have advanced our understanding of the molecular basis of placental micro-vascular pathophysiology in fetal growth restriction.

Evidence for peroxynitrite formation in the vasculature of women with preeclampsia.

-Preeclampsia is a multisystemic disorder of pregnancy in which the normal vascular adaptations to pregnancy are compromised. Oxidative stress as well as endothelial cell dysfunction have been implicated as pathophysiological features of preeclampsia. Endothelial cells produce the vasorelaxant nitric oxide (NO). However, NO is also known to react with superoxide anions (produced under conditions of oxidative stress), yielding peroxynitrite that may impair vascular function. Our objective was to use immunohistochemical techniques to determine whether there is evidence of peroxynitrite formation in the maternal systemic vasculature of women with preeclampsia. Vessels were obtained from a biopsy of subcutaneous fat at the time of cesarean section from normal pregnant (n=7) and preeclamptic (n=7) women or at the time of hysterectomy from nonpregnant women (n=5). There were significantly more vessels staining with greater intensity for nitrotyrosine and endothelial NO synthase in the endothelium of vessels from women with preeclampsia compared with that of normal pregnant women or nonpregnant women. Both endothelial and smooth muscle cells from all vessels showed evidence for the presence of superoxide dismutase (SOD), an enzyme that scavenges superoxide anions. However, the intensity of staining for SOD in the endothelium was significantly lower in the preeclamptic and nonpregnant women than in normal pregnant women. These data of increased endothelial NO synthase, decreased SOD, and increased nitrotyrosine immunostaining in the maternal vasculature of women with preeclampsia suggest increased peroxynitrite formation. We speculate that peroxynitrite is involved in endothelial cell dysfunction in preeclamptic women and contributes to the pathophysiology of this pregnancy disorder.