Gloria Riquelme

Clustering and Coupled Gating Modulate the Activity in KcsA, a Potassium Channel Model

Different patterns of channel activity have been detected by patch clamping excised membrane patches from reconstituted giant liposomes containing purified KcsA, a potassium channel from prokaryotes. The more frequent pattern has a characteristic low channel opening probability and exhibits many other features reported for KcsA reconstituted into planar lipid bilayers, including a moderate voltage dependence, blockade by Na+, and a strict dependence on acidic pH for channel opening. The predominant gating event in this low channel opening probability pattern corresponds to the positive coupling of two KcsA channels. However, other activity patterns have been detected as well, which are characterized by a high channel opening probability (HOP patterns), positive coupling of mostly five concerted channels, and profound changes in other KcsA features, including a different voltage dependence, channel opening at neutral pH, and lack of Na+ blockade. The above functional diversity occurs correlatively to the heterogeneous supramolecular assembly of KcsA into clusters. Clustering of KcsA depends on protein concentration and occurs both in detergent solution and more markedly in reconstituted membranes, including giant liposomes, where some of the clusters are large enough (up to micrometer size) to be observed by confocal microscopy. As in the allosteric conformational spread responses observed in receptor clustering (Bray, D. and Duke, T. (2004) Annu. Rev. Biophys. Biomol. Struct. 33, 53-73) our tenet is that physical clustering of KcsA channels is behind the observed multiple coupled gating and diverse functional responses.

Transverse tubules from frog skeletal muscle. Purification and properties of vesicles sealed with the inside-out orientation

Transverse tubule vesicles were isolated from frog skeletal muscle by a procedure initially described by Rosemblatt et al. (J. Biol. Chem. 256, 8140-8148 (1981)) and later modified by Hidalgo et al. (J. Biol. Chem. 258, 13937-13945 (1983]. A large fraction of the isolated vesicles (80-90%) were sealed, as indicated by the detergent induced increase in (Na+ + K+)-ATPase activity and ATP-dependent ouabain binding. To determine the orientation of the sealed vesicles binding of digoxin, a lipid soluble derivative of ouabain, was measured. The same values of ATP-dependent digoxin binding were found with or without detergents, indicating that all the vesicles that are sealed have the ATP site accessible, and hence are sealed with the cytoplasmic side-out (inside-out orientation). The transverse tubule preparation isolated from frog muscle is highly purified, as indicated by its cholesterol content and its (Na+ + K+)-ATPase activity; negligible contamination with sarcoplasmic reticulum was observed, as indicated by the protein composition and the lack of measurable Ca2+-ATPase activity of the isolated transverse tubules. High initial rates of Mg2+-ATPase activity were found, with the peculiar property of being inhibited during the course of the reaction. Addition of lysophosphatidylcholine or saponin partially prevented the inhibition of Mg2+-ATPase activity during the reaction.

Swelling-activated potassium currents of Ehrlich ascites tumour cells

The K+ and Cl- currents activated by Ca2+-ionophore treatment or by hypotonic cell swelling have been studied in Ehrlich ascites tumour cells by the patch-clamp technique. A charybdotoxin-inhibitable K+ current was activated by increasing intracellular Ca2+ concentration. In contrast, the K+ current activated by cell swelling was insensitive to charybdotoxin as well as to apamin, suggesting that channels different from those sensitive to Ca2+ are responsible for regulatory volume adjustments in these cells. The magnitude of the K+ and Cl- currents activated by hypotonic challenge was markedly temperature-dependent, possibly reflecting the temperature-dependence of enzymes involved in the intracellular signalling of cell volume regulation.

Regulation of human placental chloride channel by arachidonic acid and other cis unsaturated fatty acids

OBJECTIVE Arachidonic acid has been implicated in the modulation of various transport processes, including conductive chloride transport in brush border membranes in the human placenta. The purpose of this work was to explore the effects of some cis unsaturated fatty acids on the electrophysiologic properties of the maxi chloride channels present in apical membranes from human placenta. STUDY DESIGN Apical membrane chloride channels from human term placentas were reconstituted in giant liposomes. These cell-sized liposomes, generated by a cycle of dehydration and rehydration, are suitable for electrophysiologic studies by the patch-clamp method. RESULTS Low micromolar concentrations of arachidonic acid reversibly inhibit maxi chloride channels in excised patches. Other cis unsaturated fatty acids, such as oleic and linoleic acids, show similar blockade. The inhibition was dose dependent. The maxi chloride channel can also be inhibited by 4,4 -diisothiocyanatostilbene-2,2 -disulfonic acid, a known chloride channel inhibitor. CONCLUSIONS Our results identify the apical membrane maxi chloride channel as a possible electrophysi ologic counterpart of 4,4 -diisothiocyanatostilbene-2, 2 -disulfonic acid and cis unsaturated fatty acid-inhibited conductance previously described in brush border membranes of the human placenta. From a functional point of view the control of these channels by arachidonic acid may be of great importance in placental physiologic characteristics. Regulation of chloride channels could be important in the control of electrolyte and fluid transfer across the placenta. In addition, if these channels contribute to setting the membrane potential their regulation could have consequences for nutrient transport and delivery to the fetus. The electrophysiologic identification of these channels and their regulation might help to unravel their possible role in transplacental transport in normal and pathologic placental tissue.

Puroindoline-a and α1-purothionin form ion channels in giant liposomes but exert different toxic actions on murine cells

Puroindoline‐a (PIN‐a) and α1‐purothionin (α1‐PTH), isolated from wheat endosperm of Triticum aestivum sp., have been suggested to play a role in plant defence mechanisms against phytopathogenic organisms. We investigated their ability to form pores when incorporated into giant liposomes using the patch‐clamp technique. PIN‐a formed cationic channels (≈ 15 pS) with the following selectivity K+ > Na+ ≫ Cl–. Also, α1‐PTH formed channels of ≈ 46 pS and 125 pS at +100 mV, the selectivity of which was Ca2+ > Na+ ≈ K+ ≫ Cl– and Cl– ≫ Na+, respectively. In isolated mouse neuromuscular preparations, α1‐PTH induced muscle membrane depolarization, leading to blockade of synaptic transmission and directly elicited muscle twitches. Also, α1‐PTH caused swelling of differentiated neuroblastoma NG108‐15 cells, membrane bleb formation, and disorganization of F‐actin. In contrast, similar concentrations of PIN‐a had no detectable effects. The cytotoxic actions of α1‐PTH on mammalian cells may be explained by its ability to induce cationic‐selective channels.

Expression and Distribution of Nucleoside Transporter Proteins in the Human Syncytiotrophoblast

The plasma membrane distribution and related biological activity of nucleoside transporter proteins (NTs) were investigated in human syncytiotrophoblast from term placenta using a variety of approaches, including nucleoside uptake measurements into vesicles from selected plasma membrane domains, NT immunohistochemistry, and subcellular localization (basal, heavy, and light apical membranes as well as raft-enriched membranes from the apical domain). In contrast with other epithelia, in this epithelium, we have identified the high-affinity pyrimidine-preferring human concentrative nucleoside transporter (hCNT) 1 as the only hCNT-type protein expressed at both the basal and apical membranes. hCNT1 localization in lipid rafts is also dependent on its subcellular localization in the apical plasma membrane, suggesting a complex cellular and regional expression. Overall, this result favors the view that the placenta is a pyrimidine-preferring nucleoside sink from both maternal and fetal sides, and hCNT1 plays a major role in promoting pyrimidine salvage and placental growth. This finding may be of pharmacological relevance, because hCNT1 is known to interact with anticancer nucleoside-derived drugs and other molecules, such as nicotine and caffeine, for which a great variety of harmful effects on placental and fetal development, including intrauterine growth retardation, have been reported.

Placental Chloride Channels: A Review

The human placental syncytiotrophoblast (hSTB) is a polarized epithelial structure, that forms the main barrier to materno-fetal exchange. The chloride (Cl(-)) channels in other epithelial tissues contribute to several functions, such as maintenance of the membrane potential, volume regulation, absorption and secretion. Additionally, the contributions of Cl(-) channels to these functions are demonstrated by certain diseases and knock-out animal models. There are multiple lines of evidence for the presence of Cl(-) channels in the hSTB, which could contribute to different placental functions. However, both the mechanism by which these channels are involved in the physiology of the placenta, and their molecular identities are still unclear. Furthermore, a correlation between altered Cl(-) channels functions and pathological pregnancies is beginning to emerge. This review summarizes recent developments on conductive placental chloride transport, and discusses its potential implications for placental physiology.

17b-Estradiol and Tamoxifen Regulate a Maxi-Chloride Channel from Human Placenta

Steroid hormones have been implicated in the modulation of several transport processes, including conductive chloride transport in epithelial cells. Micromolar concentrations of these hormones have been determined in blood of pregnant women. The purpose of this work was to explore the effects of 17b-Estradiol, a steroid hormone, on the biophysical properties of the Maxi chloride channel present in apical membranes from human placental syncytiotrophoblast. Apical membrane chloride channels from human term placentas were reconstituted in giant liposomes suitable for electrophysiologic studies by the patch-clamp method. Low micromolar concentrations of 17b-Estradiol inhibit the Maxi chloride channels in excised patches in a potential-dependent manner. The addition of 1 mM 17b-Estradiol to the bath solution decreased the total current in the patch from 100% control to 71% at ?40 mV holding potential and the current was not affected by 17b-Estradiol at + 40 mV. However, the presence of the hormone did not affect the single-channel conductance, therefore its effect must be due to modulation of its open probability (Po). Interestingly, 17a-Estradiol did not change the total current in the patch. Tamoxifen, an antiestrogen, also showed inhibition, but in a voltage-independent manner. Our results suggest that the Maxi Cl? channel from human term placenta may be regulated by direct interaction of both compounds with the channel. From a functional point of view, the control of these channels by steroid hormones may be of great importance in placental physiology and their regulation may help to unravel their possible role in transplacental transport.

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 channels 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.

Distinct Lipid Rafts in Subdomains from Human Placental Apical Syncytiotrophoblast Membranes

We report on the characteristics of raft domains in the apical membrane from human placental syncytiotrophoblast (hSTB), an epithelium responsible for maternal–fetal exchange. Previously, we described two isolated fractions of the hSTB apical membrane: a classical microvillous membrane (MVM) and a light microvillous membrane (LMVM). Detergent-resistant microdomains (DRMs) from MVM and LMVM were prepared with Triton X-100 followed by flotation in a sucrose gradient and tested by Western and dot blot with raft markers (placental alkaline phosphatase, lipid ganglioside, annexin 2) and transferrin receptor as a nonraft marker. DRMs from both fractions showed a consistent peak for these markers, except that the DRMs from MVM had no annexin 2 mark. Cholesterol depletion modified the segregation in both groups of DRMs. Our results show two distinguishable lipid raft subsets from MVM and LMVM. Additionally, we found significant differences between MVM and LMVM in cholesterol content and in expression of cytoskeletal proteins. MVM is enriched in ezrin and β-actin; in contrast, cholesterol and cytokeratin-7 are more abundant in LMVM. These differences may explain the distinct properties of the lipid raft subtypes.