Diverse calcium channel types are present in the human placental syncytiotrophoblast basal membrane.

The functional expression of calcium channels has been scarcely studied in human placental syncytiotrophoblast. We have presently sought to characterize Ca(2+) currents of the healthy syncytiotrophoblast basal membrane using purified basal membranes reconstituted in giant liposomes subjected to patch-clamp recordings. We detected presence of channels with high permeability to Ca(2+) (relative PCa/PK up to 99.5) using K(+) solutions in symmetric conditions. Recordings performed in Ba(2+) gradients showed Ba(2+)-conducting channels in 100% of experiments. Ba(2+) total patch currents were consistently blocked by addition of NiCl(2), Nifedipine (L-type voltage-gated calcium channel blocker) or Ruthenium Red (TRPV5-TRPV6 channel blocker); Nifedipine and Ruthenium Red exerted a synergic blocking effect on Ba(2+) total patch currents. Immunohistochemistry of placental villi sections evidenced presence of alpha(1) subunit of voltage-gated calcium channels and TRPV5-TRPV6 channels in basal and apical syncytiotrophoblast plasma membranes; these three calcium channels were also detected in purified basal and apical fractions using Western blot. These results show the presence of three types of calcium channels in the syncytiotrophoblast basal membrane by both functional and molecular means. These basal membrane calcium channels would not be directly involved in mother-to-fetus Ca(2+) transport, but could participate in other relevant trophoblast processes, such as exocytosis and Ca(2+) transport regulation.

Large chloride channel from pre-eclamptic human placenta.

Chloride transport involving conductive pathways participates in numerous epithelial functions, such as membrane voltage maintenance, solute transport and cell volume regulation. Evidence points to involvement of transepithelial chloride transport in such functions in placental syncytiotrophoblast. A molecular candidate for physiologic conductive chloride transport in apical syncytiotrophoblast membrane is a Maxi-chloride channel with distinct biophysical properties: conductance over 200 pS, multiple substates, voltage dependent open probability, and permeation to anionic amino acids. Pre-eclampsia, a high incidence pathology of pregnancy, exerts great impact on fetal morbi-mortality. This relies, among others, on intrauterine growth restriction (IUGR), thought to be mediated by diminished blood flow to the placenta, with growing knowledge regarding contribution of other factors. The Maxi-chloride channel's properties suggest it could be altered in this pathology. We have characterized the apical chloride channels from pre-eclamptic placentae, reconstituted in giant liposomes suitable for patch-clamp electrophysiological studies. In n=33 experiments from n=6 pre-eclamptic placentae we observed a chloride-permeable channel with similar biophysical properties to the channel from normal tissue (n=29 experiments from n=15 placentae). However, the main conductance state showed diminished magnitude (<150 pS), and the open probability versus voltage relationship exhibited a flattened curve instead of the bell-shaped curve of normal placentae. These results are the first evidence of a functionally altered ionic channel from placental syncytiotrophoblast in pre-eclampsia. Considering the abundance of chloride-conducting channel activity in human apical membrane and their relevance in epithelial function in general, these alterations could greatly disturb numerous placental functions that rely on syncytiotrophoblast integrity.