Post-Translational Modifications of the P2X(4) purinergic receptor subtype in the human placenta are altered in preeclampsia.

P2X(4) receptors are activated by extracellular ATP to raise intracellular calcium, thus altering cell signalling. ATP release occurs under pathophysiological, stress and adverse cell conditions; these are all increased in preeclampsia. Although P2X(4) is abundantly expressed in normal placenta neither the differences in the amount of protein nor its post-translational modifications have been studied in placentae from pregnancies complicated by preeclampsia. Thus we examined P2X(4) protein expression, localization and post-translational modifications in normotensive controls, term and preterm preeclamptic placentae. Densitometric analysis of Western blots showed a significant increase in P2X(4) protein expression in both term (p=0.002) and preterm preeclamptic (p=0.0008) placental samples compared to normotensive controls however the tissue localization of this receptor subtype was unaltered across the groups. Our data showed that P2X(4) is a nitrated protein in the placenta and this nitration is upregulated in preterm preeclamptic placenta compared to normotensive controls (p=0.03). We also demonstrated that P2X(4) is heavily glycosylated in the placenta by deglycosylation with PNGase F which reduced the protein product size by 23 kDa. We propose that P2X(4) acts within the syncytiotrophoblast to alter intracellular calcium and subsequent signalling pathways thereby restoring placental cell homeostasis following ATP-induced changes during pathophysiological conditions such as preeclampsia. We also propose that the post-translational modifications of nitration and glycosylation are required for the normal functioning of P2X(4).

Differential localization of prostaglandin E synthase isoforms in human placental cell types.

Increased prostaglandin E(2)(PGE(2)) synthesis involves multiple enzymes and two isoforms of the terminal enzyme of this biosynthetic pathway, PGE synthase (PGES), were recently identified. Cytosolic PGES (cPGES) is identical to the Hsp90 chaperone, p23, and is reportedly functionally coupled to constitutive PG endoperoxide H synthase-1 (PGHS-1). Microsomal PGES (mPGES), on the other hand, is inducible by proinflammatory cytokines such as IL-1beta. We have studied the cellular localization of both enzyme isoforms in human placenta at term and early gestation (10 weeks). Cytosolic PGES was immunolocalized to the fibroblasts and macrophages in villous stroma, whereas mPGES was localized in the extravillous trophoblasts (EVTs) as well as macrophages in both term and early gestation tissues. Microsomal PGES was also observed in cytotrophoblasts (CTs), but not in syncytiotrophoblasts (STs), in early gestation. Apoptotic early gestational STs were heavily stained with cPGES. We also investigated the cellular localization of cPLA(2)and PGHS-2 in early gestation and at term. Cytosolic PLA(2)was immunolocalized to the stroma and STs at term, but was only observed in CTs in early gestation. PGHS-2, on the other hand, was immunolocalized to both extravillous and STs in early gestation and at term. Our results suggest that mPGES could play a role in trophoblast invasion via its association with EVTs in the basal plate, whereas cPGES could be involved in apoptosis or repair mechanisms.

Oxygen derived free radicals in osteoclasts: the specificity and location of the nitroblue tetrazolium reaction.

Oxygen derived free radicals are generated by osteoclasts. In a novel culture system, isolated rat osteoclasts were stained when nitroblue tetrazolium (NBT) was reduced by cellular oxidants to formazan, an insoluble precipitate. Superoxide dismutase (SOD) inhibited the accumulation of formazan by the isolated osteoclasts. Osteoclasts in mouse calvarial organ cultures also reduced NBT to formazan. The reaction products were localized to the area of the osteoclast-bone interface. At the light microscopic level, the formazan granules appeared to be concentrated within the cytoplasm. Formazan accumulation was significantly inhibited by calcitonin (hCT). The inhibition of NBT reduction by SOD indicates that the isolated osteoclasts were capable of producing superoxide. The localization of the formazan granules between the external osteoclastic membrane and the bone, and the inhibition of this reaction during hCT exposure suggests that oxygen derived free radicals may contribute to bone resorption.