Anionic amino acid transport systems in isolated basal plasma membrane of human placenta

Assessment of Placental Sodium-Independent Leucine Uptake and Transfer in Trophoblast Cells

The placenta maintains the balance between nutrition and growth control of the fetus through selective and regulated supply of macronutrients such as carbohydrates, proteins, lipids, and critical micronutrients. Perturbations in the balanced supply of nutrients as found in gestational diseases and altered fetal development have been associated with changes in amino acid transport proteins, such as the System L amino acid heterodimeric exchangers LAT1/SLC7A5 and LAT2/SLC7A8. Syncytiotrophoblasts (STB) form the crucial cell layer at the placental barrier coordinating the transfer of essential amino acids such as leucine from the maternal to the fetal circulation. The System L-mediated leucine transport across the placental barrier is a Na+-independent process against a counter-directed gradient, maintained by a tightly regulated interplay between accumulative transporters, exchangers, and facilitators.The two methods described here allow to standardize and characterize the uptake kinetics of leucine in conventionally cultured BeWo cells and the transfer of leucine across the placental cell barrier using a BeWo monolayer in the Transwell® system.

Trichloroethylene Metabolite S-(1,2-Dichlorovinyl)-l-cysteine Stimulates Changes in Energy Metabolites and Amino Acids in the BeWo Human Placental Trophoblast Model during Syncytialization

Syncytialization, the fusion of cytotrophoblasts into an epithelial barrier that constitutes the maternal-fetal interface, is a crucial event of placentation. This process is characterized by distinct changes to amino acid and energy metabolism. A metabolite of the industrial solvent trichloroethylene (TCE), S-(1,2-dichlorovinyl)-l-cysteine (DCVC), modifies energy metabolism and amino acid abundance in HTR-8/SVneo extravillous trophoblasts. In the current study, we investigated DCVC-induced changes to energy metabolism and amino acids during forskolin-stimulated syncytialization in BeWo cells, a human villous trophoblastic cell line that models syncytialization in vitro. BeWo cells were exposed to forskolin at 100 μM for 48 h to stimulate syncytialization. During syncytialization, BeWo cells were also treated with DCVC at 0 (control), 10, or 20 μM. Following treatment, the targeted metabolomics platform, "Tricarboxylic Acid Plus", was used to identify changes in energy metabolism and amino acids. DCVC treatment during syncytialization decreased oleic acid, aspartate, proline, uridine diphosphate (UDP), UDP-d-glucose, uridine monophosphate, and cytidine monophosphate relative to forskolin-only treatment controls, but did not increase any measured metabolite. Notable changes stimulated by syncytialization in the absence of DCVC included increased adenosine monophosphate and guanosine monophosphate, as well as decreased aspartate and glutamate. Pathway analysis revealed multiple pathways in amino acid and sugar metabolisms that were altered with forskolin-stimulated syncytialization alone and DCVC treatment during syncytialization. Analysis of ratios of metabolites within the pathways revealed that DCVC exposure during syncytialization changed metabolite ratios in the same or different direction compared to syncytialization alone. Building off our oleic acid findings, we found that extracellular matrix metalloproteinase-2, which is downstream in oleic acid signaling, underwent the same changes as oleic acid. Together, the metabolic changes stimulated by DCVC treatment during syncytialization suggest changes in energy metabolism and amino acid abundance as potential mechanisms by which DCVC could impact syncytialization and pregnancy.

Amino Acids and Developmental Origins of Hypertension

During pregnancy, amino acids are important biomolecules that play essential roles in fetal growth and development. Imbalanced amino acid intake during gestation may produce long-term morphological or functional changes in offspring, for example, developmental programming that increases the risk of developing hypertension in later life. Conversely, supplementation with specific amino acids could reverse the programming processes in early life, which may counteract the rising epidemic of hypertension. This review provides an overview of the evidence supporting the importance of amino acids during pregnancy and fetal development, the impact of amino acids on blood pressure regulation, insight from animal models in which amino acids were used to prevent hypertension of developmental origin, and interactions between amino acids and the common mechanisms underlying development programming of hypertension. A better understanding of the pathophysiological roles of specific amino acids and their interactions in developmental programming of hypertension is essential so that pregnant mothers are able to benefit from accurate amino acid supplementation during pregnancy in order to prevent hypertension development in their children.

A systems perspective on placental amino acid transport

Placental amino acid transfer is a complex process that is essential for fetal development. Impaired amino acid transfer causes fetal growth restriction, which may have lifelong health consequences. Transepithelial transfer of amino acids across the placental syncytiotrophoblast requires accumulative, exchange and facilitated transporters on the apical and basal membranes to work in concert. However, transporters alone do not determine amino acid transfer and factors that affect substrate availability, such as blood flow and metabolism, may also become rate-limiting for transfer. In order to determine the rate-limiting processes, it is necessary to take a systems approach which recognises the interdependence of these processes. New technologies have the potential to deliver targeted interventions to the placenta and help poorly growing fetuses. While many factors are necessary for amino acid transfer, novel therapies need to target the rate-limiting factors if they are going to be effective. This review will outline the factors which determine amino acid transfer and describe how they become interdependent. It will also highlight the role of computational modelling as a tool to understand this process.

Transport of amino acids through the placenta and their role

Amino acids are transported across the human placenta mediated by transporter proteins that differ in structure, mechanism and substrate specificity. Some of them are Na+-dependent systems, whereas others are Na+-independent. Among these there are transporters composed of a heavy chain, a glycoprotein, and a light chain. Moreover, they can be differently distributed in the two membranes forming the syncytiotrophoblast. The transport mechanisms involved and their regulation are only partially known. In the placenta itself, part of the amino acids is metabolized to form other compounds important for the fetus. This occurs for instance for arginine, which gives rise to polyamines and to NO. Interconversion occurs among few other amino acids Transport is altered in pregnancy complications, such as restricted fetal growth.

Fetoplacental transport and utilization of amino acids in IUGR — a review

Amino acids have multiple functions in fetoplacental development. The supply of amino acids to the fetus involves active transport across and metabolism within the trophoblast. Transport occurs through various amino acid transport systems located on both the maternal and fetal facing membranes, many of which have now been documented to be present in rat, sheep and human placentas. The capacity of the placenta to supply amino acids to the fetus develops during pregnancy through alterations in such factors as surface area and specific time-dependent transport system expression. In intrauterine growth restriction (IUGR), placental surface area and amino acid uptakes are decreased in human and experimental animal models. In an ovine model of IUGR, produced by hyperthermia-induced placental insufficiency (PI-IUGR), umbilical oxygen and essential amino acid uptake rates are significantly reduced in the most severe cases in concert with decreased fetal growth. These changes indicate that severe IUGR is likely associated with a shift in amino acid transport capacity and metabolic pathways within the fetoplacental unit. After transport across the trophoblast in normal conditions, amino acids are actively incorporated into tissue proteins or oxidized. In the sheep IUGR fetus, however, which is hypoxic, hypoglycemic and hypoinsulinemic, there appear to be net effluxes of amino acids from the liver and skeletal muscle, suggesting changes in amino acid metabolism. Potential changes may be occurring in the insulin/IGF-I signaling pathway that includes decreased production and/or activation of specific signaling proteins leading to a reduced protein synthesis in fetal tissues. Such observations in the placental insufficiency model of IUGR indicate that the combination of decreased fetoplacental amino acid uptake and disrupted insulin/IGF signaling in liver and muscle account for decreased fetal growth in IUGR.

Distribution of Glutamate Transporters in the Human Placenta

Glutamate metabolism is known to be important for growth and development of the human fetus. The glutamate transporters EAAT1, EAAT2 and EAAT3 are key components of the glutamate-glutamine cycle and responsible for active transport of glutamate over the cell membrane. The placenta is thought to regulate glutamate transport during fetal development. Glutamate transporters have been found in placentae of rats, but their distribution in the human placenta is unknown. Therefore, the distribution of glutamate transporters EAAT1, EAAT2 and EAAT3 were analysed in the human placenta during normal pregnancies ending between 8 and 40 weeks of gestation and in placentae of intrauterine growth restricted infants with gestational ages between 28 and 35 weeks of pregnancy. Using immunohistochemistry, EAAT1 expression was found in the syncytiotrophoblast layer, while EAAT2 was detected in the syncytiotrophoblast layer and in endothelial cells of about 5 per cent of all fetal blood vessels. EAAT3 was observed in the endothelium of the fetal blood vessels in all placentae examined. However, expression was also found in the syncytio- and the cytotrophoblast layer of the fetal villi at 8 weeks of gestational age. The expression patterns of EAAT1, EAAT2 and EAAT3 suggest involvement in active transport of glutamate between the fetal and maternal blood circulation. No differences were found in the distribution of the glutamate transporters between control and IUGR placentae. Our data show specific localization of EAAT1, EAAT2 and EAAT3 in the human placenta during development.

Isoforms of amino acid transporters in placental syncytiotrophoblast: plasma membrane localization and potential role in maternal/fetal transport

Many cell proteins exist as isoforms arising either from gene duplication or alternate RNA splicing. There is growing evidence that isoforms with different, but closely related, functional characteristics are often directed to discrete cellular locations. Thus, specialized functions may be carried out by proteins of similar evolutionary origin in different membrane compartments. In polarized epithelial cells, this mechanism allows the cell to control amino acid transport independently at each of its specialized apical and basolateral plasma membrane domains. Investigations of isoform localization in these membranes have generally been performed in epithelia other than the placental trophoblast.This review of placental amino acid transporter isoforms first provides an overview of their properties and preliminary plasma membrane localization. We then discuss studies suggesting various roles of isoform localization in trophoblast function. To provide insights into the molecular basis of this localization in trophoblast, we present a review of current knowledge of plasma membrane protein localization as derived from investigations with a widely used epithelial model cell line. Finally, we discuss a potential approach using cultured trophoblast-derived cells for studies of transporter isoform localization and function. We hope that this review will stimulate investigation of the properties of trophoblast transporter isoforms, their membrane localization and their contribution to the cellular mechanism of maternal-fetal nutrient transport.

Nutrition in early life. How important is it?

While few would argue the importance of nutrition during adult life, temporary excess or deficiency has typically been thought to be of little long-term consequence. Recent data, summarized above, suggests that this may not be the case during in utero life, when alterations in the quantity or quality of nutrients provided may have life-long consequences. Perhaps even more surprisingly, decisions made in the neonatal period, such as whether to breastfeed or bottle feed, may have impacts on later health that, while small individually, have huge public health implications. Clarification of the links between adult health and fetal/neonatal nutrition are clearly required. Prospective studies, though difficult because of the time involved, will play a key role in this process, as will more basic research on the mechanisms underlying both normal and pathologic fetal development.

Regulation of glutamate transport and transport proteins in a placental cell line

We utilized HRP.1 cells derived from midgestation rat placental labyrinth to determine that the primary pathway for glutamate uptake is via system X, a Na(+)-dependent transport system. Kinetic parameters of system X activity were similar to those previously determined in rat and human placental membrane vesicle preparations. Amino acid depletion caused a significant upregulation of system X activity at 6, 24, and 48 h. This increase was reversed by the addition of glutamate and aspartate but not by the addition of alpha-(methylamino)isobutyric acid. Immunoblot analysis of the three transport proteins previously associated with system X activity indicated a trend toward an increase in GLT1, EAAC1, and GLAST1 immunoreactive protein contents by 48 h; cell surface expression of the same was enhanced by 24 h. Inhibition analysis suggested key roles for EAAC1 and GLAST1 in basal anionic amino acid transfer, with an enhanced role for GLT1 under conditions of amino acid depletion. In summary, amino acid availability as well as intracellular metabolism regulate anionic amino acid uptake into this placental cell line.

Glutamate uptake

Brain tissue has a remarkable ability to accumulate glutamate. This ability is due to glutamate transporter proteins present in the plasma membranes of both glial cells and neurons. The transporter proteins represent the only (significant) mechanism for removal of glutamate from the extracellular fluid and their importance for the long-term maintenance of low and non-toxic concentrations of glutamate is now well documented. In addition to this simple, but essential glutamate removal role, the glutamate transporters appear to have more sophisticated functions in the modulation of neurotransmission. They may modify the time course of synaptic events, the extent and pattern of activation and desensitization of receptors outside the synaptic cleft and at neighboring synapses (intersynaptic cross-talk). Further, the glutamate transporters provide glutamate for synthesis of e.g. GABA, glutathione and protein, and for energy production. They also play roles in peripheral organs and tissues (e.g. bone, heart, intestine, kidneys, pancreas and placenta). Glutamate uptake appears to be modulated on virtually all possible levels, i.e. DNA transcription, mRNA splicing and degradation, protein synthesis and targeting, and actual amino acid transport activity and associated ion channel activities. A variety of soluble compounds (e.g. glutamate, cytokines and growth factors) influence glutamate transporter expression and activities. Neither the normal functioning of glutamatergic synapses nor the pathogenesis of major neurological diseases (e.g. cerebral ischemia, hypoglycemia, amyotrophic lateral sclerosis, Alzheimer's disease, traumatic brain injury, epilepsy and schizophrenia) as well as non-neurological diseases (e.g. osteoporosis) can be properly understood unless more is learned about these transporter proteins. Like glutamate itself, glutamate transporters are somehow involved in almost all aspects of normal and abnormal brain activity.

Amino acid transporters in the human placenta

Amino acid transport across the human placenta is active, mediated by specific transporters in syncytiotrophoblast plasma membranes. Using functional criteria such as substrate specificity and sodium dependence, approximately 15 transport systems have been identified in the human placenta. Recently, the area of molecular biology of amino acid transporters has evolved rapidly and at least 25 cDNA clones coding for mammalian amino acid transporters or transporter subunits have been identified. The primary objective of this review is to integrate the available functional data on placental amino acid transport systems with recent molecular information on mammalian amino acid transporters. Furthermore, models for the mechanisms for net materno-fetal transfer of amino acids are discussed. Finally, the evidence to suggest that alterations in placental amino acid transport systems may play a crucial role in the regulation of fetal growth are presented briefly.

Placental transport and metabolism of amino acids

This review examines the placental transport and metabolism of amino acids, with a special emphasis on unifying and interpreting in-vivo and in-vitro data. For a variety of technical reasons, in-vivo studies, which quantify placental amino-acid fluxes and metabolism, have been relatively limited, in comparison to in-vitro studies using various placental preparations. Following an introduction to placental amino-acid uptake and transfer to the fetus, the review attempts to reconcile in-vitro placental transport data with in-vivo placental data. Data are discussed with reference to the measured delivery rates of amino acids into the fetal circulation and the contribution of placental metabolism to this rate for many amino acids. The importance of exchange transporters in determining efflux from the placenta into the fetal circulation is presented with special reference to in-vivo studies of non-metabolizable and essential amino acids. The data which illustrate the interconversion and nitrogen exchange of three groups of amino acids, glutamine-glutamate, BCAAs and serine-glycine, within the placenta are discussed in terms of the potential role such pathways may serve for other placenta functions. The review also presents comparisons of the sheep and human placentae in terms of their in-vivo amino-acid transport rates.

Maternal cocaine use and cigarette smoking in pregnancy in relation to amino acid transport and fetal growth

This review covers the weight of evidence that shows the association of cocaine and cigarette smoking in pregnancy with the impaired transplacental amino acid transport which might give rise to fetal growth restriction (IUGR). Vasoconstrictive effects of both cocaine and nicotine on the placental vasculature are clearly not the only cause for inhibition of placental amino acid uptake and transfer. In vitro studies strongly suggest that cocaine decreases the activity of placental amino acid transport system A and system N, and possibly system l and system y(+), while nicotine decreases the activity of system A. These findings are supported by cordocentesis studies in human IUGR pregnancies not resulting from drug abuse. More work is needed to be done in order to understand the potential additive or synergistic effect of cocaine and cigarette smoking on fetal growth and to determine the underlying cellular mechanisms of interaction with placental amino acid transporters.

Nutrient transport across the placenta

The placenta forms a selective barrier that functions to transport nutrients that are of critical use to the fetus. Nutrient transport across the placenta is regulated by many different active transporters found on the surface of both maternal and fetal facing membranes of the placenta. The presence of these transporters in the placenta has been implicated in the facilitation of nutrient diffusion and proper fetal growth. In this review, recent developments concerning nutrient transporters that regulate glucose, amino acid, fatty acid, and nucleoside transplacental movement are discussed.

Placental transport of leucine and lysine is reduced in intrauterine growth restriction

Intrauterine growth restriction (IUGR) is characterized by a reduction in fetal plasma concentrations of a number of essential amino acids. Whether this is caused by impaired placental transport is unknown. We studied transport of leucine and lysine in syncytiotrophoblast microvillous (MVM) and basal membrane (BM) vesicles isolated from uncomplicated (control) and IUGR pregnancies. In addition, we investigated the possibility that leucine uptake is stimulated by an outwardly directed glycine gradient. Uptake of 3H-L-lysine (0.1 microM) and 3H-L-leucine (0.25 microM) was studied at 37 degrees C using rapid filtration techniques. In IUGR, mediated uptake of lysine was reduced by 44% (p < 0.05) in BM and uptake of leucine was lower in both MVM (-46%, p < 0.05) and BM (-38%, p < 0.05) compared with control vesicles. Intravesicular glycine (2 mM) increased the uptake of leucine by 98% in MVM (p < 0.05). These data suggest that the activity of placental transporters for cationic and neutral amino acids is reduced in IUGR. We speculate that a reduced glycine gradient in the placenta in IUGR, due to reduction in system A activity, will impair leucine transport to the fetus, providing an additional mechanism for reduced placental transport of leucine in IUGR.

Glycoprotein composition in cyclophosphamide-induced lung fibrosis

The present study investigated the glycosylation state of proteins in lung tissue of a cyclophosphamide-induced model of pulmonary fibrosis in rats. In fibrotic lung, the carbohydrate constituents (total hexose, fucose, sialic acid and hexosamine) of salt-soluble, collagenase, elastase and papain digested glycoproteins were significantly higher compared to normal lungs. Interestingly, fibrotic lung tissues had higher activities of mannosyl, glucosyl, galactosyl, sialyl and fucosyl transferases than normal lung tissues. Similarly, mannosyl, glucosyl, galactosyl, sialyl and fucosyl transferases were higher in serum from rats with fibrosis than in that from normals. These data indicate that glycoprotein metabolism is significantly altered from normal in animals with interstitial lung fibrosis.

Activity and protein localization of multiple glutamate transporters in gestation day 14 vs. day 20 rat placenta

Concentrative absorption of glutamate by the developing placenta is critical for proper fetal development. The expression of GLAST1, GLT1, EAAC1, and EAAT4, known to be capable of D-aspartate-inhibitable and Na(+)-coupled glutamate transport (system X-AG), was evaluated in day 14 vs. day 20 rat chorioallantoic placenta. Steady-state mRNA levels were greater at day 20 for all transporters. Immunohistochemistry determined that the expression of GLAST1, GLT1, and EAAC1 was greater throughout the day 20 placenta and was asymmetric with respect to cellular localization. EAAT4 protein was not detected. System X-AG activity was responsible for most of the Na(+)-dependent glutamate uptake and was greater in day 20 than in day 14 apical and basal membrane subdomains of the labyrinth syncytiotrophoblast. Greater quantities of EAAC1 and GLAST1 protein were identified on day 20, and quantities were greater in basal than in apical membranes. GLT1 expression, unchanged in apical membranes, was decreased in basal membranes. These data correlate transporter mRNA and protein content with transport activity and demonstrate an increasing capacity for glutamate absorption by the developing placenta.

Different effects of class Ic and III antiarrhythmic drugs on vagotonic atrial fibrillation in the canine heart

Effects of class Ic drug pilsicainide and class III drug MS-551 were determined in the canine model of atrial fibrillation (AF) induced under vagal stimulation. Pilsicainide injected intravenously at a dose of 1.0 mg/kg over 3 min terminated AF in six of six dogs. After pilsicainide injection, the effective refractory period (ERP) of the right atrium (RA) increased (104 +/- 22 to 122 +/- 31 ms; p < 0.05), and intraatrial conduction time (CT) increased (24%; p < 0.05) in the RA during vagal stimulation. Wavelength index (WLI; ERP/CT), an estimate of the wavelength for reentry, was decreased slightly but significantly (-2%; p < 0.05) in the RA after pilsicainide. MS-551 injected intravenously at a dose of 0.5 mg/kg over a 3-min period terminated AF in three of eight dogs. An additional dose of 0.5 mg/kg of MS-551 terminated AF in three of the remaining five dogs. After MS-551 injection, ERP increased (100 +/- 30 to 143 +/- 28 ms; p < 0.05), but CT remained unchanged in the RA, and therefore WLI was increased significantly (48%; p < 0.01). Immediately before termination of AF with test drugs, mean AF intervals (FF intervals) increased, whereas the standard deviation of FF intervals did not change significantly. In conclusion, both pilsicainide and MS-551 effectively terminated vagotonic AF after an increase in FF intervals. However, changes in WLI were different between the two test drugs. Vagotonic AF could, therefore, be terminated either by prolongation of ERP or suppression of conduction with antiarrhythmic drugs.

An expression system for mammalian amino acid transporters using a stably maintained episomal vector

Despite its versatility and effectiveness in numerous studies, the vaccinia/HeLa cell expression model may not be optimal for the study of all transport proteins. To evaluate an alternative expression model for amino acid transport Systems ASC and X-AG, the mRNA content and transport activity encoded by human hippocampal ASCT1 cDNA and rat hippocampal EAAC1 cDNA, respectively, were measured in pDR2-cDNA-transfected human embryonic kidney 293 cells made competent by stable transfection with the Epstein-Barr neutral antigen-1 (EBNA-1) cDNA (293c18 cells) to evaluate the EBNA-1/293c18 expression system. The results show that (i) the EBNA-1/293c18 expression system results in a larger increase over background of Systems ASCT1 (6.4x) and EAAC1 (39x) transport activity than does the vaccinia/HeLa expression system (2.6x and 22x, respectively); (ii) transfection and hygromycin B selection for the pDR2 vector do not affect the endogenous transport velocities of Systems ASC, X-AG, or A; and (iii) the endogenous transport velocities of Systems ASC and X-AG in 293c18 cells were not affected by the expression of exogenous EAAC1 or ASCT1. We conclude that the EBNA-1/293c18 cell expression model represents a useful transient expression regimen to characterize mammalian amino acid transport proteins, especially for transporters that may exhibit relatively low activity in transient expression systems lacking a selection mechanism.

Effects of epidermal growth factor on maternal and fetal serum amino acid levels in rats

Pregnant rats were subcutaneously administered with mouse epidermal growth factor (EGF) at the concentration of 0, 100, or 200 micrograms/kg body weight/day from day 18 to 21 of gestation. The amino acid analysis by high-performance liquid chromatography demonstrated that the umbilical venous/maternal and fetal/maternal ratio of serum proline concentration increased in EGF dose-dependent manner accompanied by the increase in the ratios of total fetal weight and placental weight to maternal body weight gain. These results suggested that EGF regulates fetal growth by, as one of its possible mechanism, promoting placental proline supply from mother to fetus.

Radiation-induced lung injury in vivo: expression of transforming growth factor-beta precedes fibrosis

Cytokine release from irradiated cells has been postulated to start soon after irradiation preceding detectable clinical and pathological manifestation of lung injury. The expression of transforming growth factor beta (TGF beta), a fibrogenic and radiation-inducible cytokine, was studied from 1-16 weeks after the 15 and 30 Gray (Gy) of thoracic irradiation to rats. Thoracic irradiation caused an increase in TGF beta protein in bronchoalveolar lavage (BAL) fluid peaking at 3-6 weeks as compared to sham-irradiated control rats. Steady state TGF beta mRNA expression as shown by whole lung northern blot assay paralleled the TGF beta protein expression in BAL fluid. The peak of TGF beta protein increase in BAL fluid between 3 and 6 weeks coincided with the initial influx of inflammatory cells in BAL fluid, but preceded histologically discernable pulmonary fibrosis that was not apparent until 8-10 weeks after irradiation. In conclusion. TGF beta and mRNA and protein upregulation preceded the radiation-induced pulmonary fibrosis, suggesting a pathogenetic role in the development of radiation fibrosis.

The role of the placenta in fetal nutrition and growth

The placenta plays a key role in the nutrition of the fetus. It mediates the active transport of nutrients and metabolic wastes across the barrier separating maternal and fetal compartments, as well as modifying the composition of some nutrients through its own metabolic activity. The function of the placenta is essential to the growth of a healthy fetus; it is becoming apparent that the activities of the placenta are in turn modulated by signals originating from the fetus. Communication between placenta and fetus is especially critical in intrauterine growth retardation. The importance of the interaction of factors like insulin-like growth factor and epidermal growth factor with their receptors is becoming increasingly clear.

Isolation of syncytial microvillous membrane vesicles from human term placenta and their application in drug-nutrient interaction studies

The initial step in placental uptake of nutrients occurs across the syncytial microvillous membrane of the trophoblast. This study was designed to isolate syncytial microvillous membrane vesicles (SMMV) of human term placenta, to validate their purity and viability, and to investigate the interaction of several commonly used drugs with the transport of two essential nutrients: alanine and choline. SMMV were isolated according to an established procedure, but instead of homogenization the initial preparation step was replaced by mincing of placental tissue followed by gently stirring to loosen the microvilli. These modifications doubled the protein recovery and increased the enrichment in alkaline phosphatase, whereas no substantial contamination with basal membranes nor interfering subcellular organelles was found. The functional viability of the vesicles was evaluated through the transport of alanine. In accordance with literature, uptake was sodium-dependent, inhibitable by structural analogues, and saturable. A number of cationic drugs were were able to able to inhibit choline uptake, whereas no effect on alanine transport was observed. Anionic drugs, drugs of abuse, and catecholamines did not interfere with alanine transport either. In conclusion, our isolated SMMV provide a suitable tool for screening drug-nutrient interactions at the level of membrane transport. In view of the very low susceptibility of the alanine transporter to drug inhibition and the relatively high drug concentrations necessary to inhibit choline transport, it seems unlikely that clinically important drug interactions may occur with these nutrients.

Partial purification and kinetic properties of human placental cytosolic aspartate transaminase

Human placental cytoplasmic aspartate transaminase was purified 404-fold by heat treatment, ammonium sulfate fractionation, dialysis and DEAE-Sephadex chromatography. The pH optimum of the enzyme was 6.8 in either phosphate or cacodylate buffer. The Km values of alpha-ketoglutarate and L-aspartate were 2.06 and 22.5 mM, respectively. A 78% inhibition of the enzyme was noted at 4 mM concentration of maleate which inhibited the enzyme upon competing with alpha-ketoglutarate with a Ki value of 1.72 mM. The kinetic properties of this enzyme are compared with those of the enzyme from various mammalian and other sources. The data are discussed in terms of the probable effectiveness of this enzyme in catabolizing L-aspartate in placenta especially after the consumption of a high protein diet by the pregnant mother.

Characterization of Na(+)-dependent L-glutamate transport in canine erythrocytes

Characteristics of the high-affinity Na(+)-dependent L-glutamate transport system in canine erythrocytes were studied by using intact cells and resealed ghosts. The L-glutamate transport showed a precise dependence on extracellular Na+ and intracellular K+. Kinetical analysis revealed that two Na+ ions and one K+ ion were involved in each L-glutamate transport cycle. The L-glutamate transport was inhibited most potently by threo-3-hydroxyaspartate and L-cysteinesulfinate (at 25 microM, 83% and 79% inhibition, respectively) and weakly by dihydrokainate and DL-alpha-aminoadipate (at 25 microM, 21% and 17% inhibition, respectively). From these stoichiometrical and pharmacological properties we concluded that the L-glutamate transport system in canine erythrocytes is a product of the L-glutamate transporter gene family and resembles a neuronal transporter rather than a glial one. L-Glutamate uptake was increased by internal, but not external, HCO3- when the internal and external anions of the erythrocytes were replaced by several other anions. Moreover, this enhancement was blocked by inhibition of carbonic anhydrase, which indicated that L-glutamate transport was at least partly dependent on HCO3- generated inside the cells. These observations indicate that anion countertransport is coupled to the high-affinity Na(+)- and K(+)-dependent L-glutamate transport in canine erythrocytes.

The effects of cocaine on neutral amino acid uptake by human placental basal membrane vesicles

OBJECTIVE

Prior studies have demonstrated that cocaine binds to human placental microvillous membrane vesicles at a single high-affinity site and that both 10 and 500 nmol/L cocaine inhibit sodium-dependent alanine uptake. The purpose of this study was to characterize cocaine binding to human placental basal plasma membrane and to determine the effects of cocaine on basal vesicle uptake of alanine and leucine.

STUDY DESIGN

Basal vesicles were isolated from the placentas of uncomplicated human pregnancies with no history of cocaine use. The binding of tritiated cocaine to basal vesicle membrane and the uptakes of tritiated cocaine, alanine, and leucine were determined with filtration assays. Alanine and leucine uptakes were measured in the presence and absence of sodium and 10 and 500 nmol/L cocaine. Cocaine binding was characterized with Scatchard analyses, and uptakes were compared by means of Student t tests.

RESULTS

Tritiated cocaine bound to basal membrane at two separate high-affinity sites. Sodium-dependent alanine uptake was significantly inhibited only by 500 nmol/L cocaine. Sodium-independent amino acid uptake was unaffected by cocaine.

CONCLUSION

Cocaine may interfere with fetal growth by impairing the activity of sodium-dependent amino acid transporters in both the microvillous and basal membrane. These membranes may be differentially sensitive to the effects of cocaine on such transporters.

Chronic ethanol exposure inhibits insulin and IGF-1 stimulated amino acid uptake in cultured human placental trophoblasts

Maternal alcohol abuse during pregnancy can lead to abnormalities in fetal development, sometimes manifested as the fetal alcohol syndrome (FAS). Although intrauterine growth retardation is a hallmark of FAS, the pathophysiology is not fully understood. A contributing factor may be altered placental function. In this study, the effect of long-term exposure to ethanol on subsequent amino acid uptake by the cultured human placental trophoblasts was examined. Both Na(+)-dependent and Na(+)-independent pathways for AIB uptake were measured. As reported previously, insulin and IGF-1 enhanced Na(+)-dependent AIB uptake. Exposure to ethanol had no effect on basal (nonhormone treated) AIB uptake. However, 72-hr ethanol pretreatment of trophoblasts inhibited Na(+)-dependent AIB uptake under stimulation by insulin or IGF-1 in the absence of ethanol. Na(+)-independent uptake was not affected. Ethanol treatment had no effect on insulin or IGF-1 binding to cultured trophoblasts. These findings suggest that 72-hr ethanol treatment in cultured trophoblasts may affect postreceptor signal transduction in the insulin or IGF-1 pathways. Such changes have implications for the effect of ethanol on normal function of the human placenta, the major interface for maternal/fetal transfer of nutrients.

Sequential preparation of highly purified microvillous and basal syncytiotrophoblast membranes in substantial yield from a single term human placenta: inhibition of microvillous alkaline phosphatase activity by EDTA

The human placental syncytiotrophoblast is a highly polarised epithelial layer responsible for regulating materno-fetal exchange. We here describe a novel procedure for isolating paired fractions of the maternal-facing and fetal-facing plasma membranes from this syncytium, from a single placenta, without the need for homogenisation procedures. This reduces the potential for contamination of these membrane fractions by intracellular membranes, or from plasma membranes from other cell types within the placenta. Microvillous membrane vesicles (MVM) were obtained by gentle stirring of dispersed villous tissue. The tissue sedimented at the end of this procedure was subjected to sequential ultrasonication to release the basal membrane (BM). Crude MVM was subsequently purified on a discontinuous sucrose gradient. Crude BM was further purified using either discontinuous Ficoll or sucrose gradients. The Ficoll procedure, while producing a BM fraction extremely enriched in marker enzyme, resulted in unacceptably low protein recoveries and hence the sucrose gradient procedure was also adopted for BM. Yields for MVM and BM produced on sucrose density gradients approached 30 mg/100 g tissue. The MVM fraction was composed of vesicles of 232 +/- 9 (S.E.) nm diameter of which nearly 90% were 'right side out'. These membranes were 37-fold enriched in the marker enzyme alkaline phosphatase. Purified BM vesicles were 317 +/- 14 nm in diameter, also approximately 90% 'right side out' and over 40-fold enriched in dihydroalprenolol binding. Cross-contamination or contamination from intracellular membranes was negligible. MVM alkaline phosphatase activity was shown to be inhibitable in a dose- and time-dependent manner by EDTA present in the storage buffer.

Concentrations of amino acids in plasma from 45- to 47-week gestation mares and foetuses (Equus caballus)

Concentrations of 16 of 24 amino acids in plasma of foetuses were significantly higher, while four of 24 were lower, than their concentration in maternal plasma. The higher foetal concentrations of amino acids in plasma are similar to other species, with some exceptions, and suggest that equine placenta actively transports and concentrates amino acids into the umbilical circulation. Concentrations of nine of 24 amino acids were significantly lower in plasma from the umbilical artery compared to plasma from the umbilical vein, while no significant differences were present between maternal artery and vein plasma. The umbilical venous-arterial difference in concentrations of amino acids in plasma suggests the foetus extracts amino acids from the umbilical circulation for catabolism or protein synthesis, as in other species.

Basement membrane proteins in synovial membrane: distribution in rheumatoid arthritis and synthesis by fibroblast-like cells

Rheumatoid arthritis is a complex disease of unknown origin. In consequence of some immunological reactions, proliferative invading synovial tissue leads to destruction of normal joint architecture. The aim of this study was to investigate qualitative changes in extracellular matrix distribution of proliferating rheumatoid synovium and their cellular origin. Synovial tissues from 57 clinically indicated arthrotomies were investigated with immunofluorescence, using specific antibodies against extracellular matrix proteins in tissue slides and cultured cells, which were also studied for collagen biosynthesis. Results indicated that synovial fibroblast-like cells synthesize and secrete basement membrane proteins laminin and collagen type IV as e.g. endothelial cells or organogenic fibroblasts. Laminin and collagen type IV were specifically demonstrated pericellularly in the hyperplastic lining layer of active rheumatoid synovitis. These findings are discussed with respect to the possible implication of altered cell-matrix interactions in rheumatoid synovial proliferation.

ATP independent calcium transport and binding by basal plasma membrane of human placenta

The transport of large amounts of Ca2+ by the plasma membranes of human placental syncytiotrophoblast is essential to the mineralization of the growing fetal skeleton. We have investigated transport by the basal (fetal-facing) plasma membrane (BPM). Ca2+ was taken up by purified BPM vesicles in a time-dependent manner and equilibrium attained in approximately 60 min. The apparent equilibrium space was many fold higher than that determined using other substrates (e.g. leucine), suggesting that Ca2+ is concentrated or bound within the vesicles. The more rapid uptake and exit in the presence of A23187 indicates that membrane transport is rate limiting and that Ca2+ is internalized within the membrane space. The initial rate of uptake was approximately by measurement during the first 2 s of incubation. Concentration dependence data were fit to a Michaelis-Menten model with one saturable site and diffusion (Km = 12 microM; Vmax = 4 nmol/min/mg; KD = 39 nmol/min/mg/mM). Saturable Ca2+ binding (Kd = 16 microM; Bmax = 3.4 nmol/mg) was of lower capacity than previously observed for microvillous membrane.

Human placental syncytiotrophoblast expresses two pharmacologically distinguishable types of Na(+)-H+ exchangers, NHE-1 in the maternal-facing (brush border) membrane and NHE-2 in the fetal-facing (basal) membrane

We investigated whether highly purified preparations of basal (fetal-facing) membrane isolated from normal term human placentas possess Na(+)-H+ exchanger activity. Uptake of Na+ into basal membrane vesicles was stimulated many-fold by an outwardly directed H+ gradient. This H(+)-gradient-dependent uptake was inhibitable by amiloride and its analogues. Na+ uptake in these vesicles did not occur via a Na+ channel, as it was not influenced by changes in membrane potential and, in addition, was inhibited by benzamil only at high micromolar concentrations. The results indicate that the human placental basal membrane possesses Na(+)-H+ exchanger activity. We then studied whether this exchanger is similar to or distinct from the Na(+)-H+ exchanger described in brush border (maternal-facing) membrane preparations. For this purpose, we compared the pharmacological characteristics of the basal membrane Na(+)-H+ exchanger with those of the brush border membrane Na(+)-H+ exchanger. The basal membrane exchanger was about 20-fold less sensitive to inhibition by amiloride and about 70-fold less sensitive to inhibition by dimethylamiloride than was the brush border membrane exchanger. The exchanger activity in both membrane preparations was inhibitable by clonidine and cimetidine, but the inhibition patterns with these compounds were markedly different between basal and brush border membrane preparations. These data demonstrate that the basal membrane Na(+)-H+ exchanger is distinct from the brush border membrane Na(+)-H+ exchanger. The pharmacological profiles of these exchangers indicate that the human placental brush border membrane possesses the housekeeping or non-epithelial type Na(+)-H+ exchanger (NHE-1), whereas the basal membrane possesses the epithelial or apical type Na(+)-H+ exchanger (NHE-2).

Amino acid nutrition across the placenta

The placenta participates by metabolism, and not simply by transport to and from the fetus, in providing fetal needs for several amino acids, including leucine, glutamine, glutamate, serine, and glycine.

Na(+)-dependent transport of anionic amino acids by preimplantation mouse blastocysts

Negatively charged amino acids, such as aspartate and glutamate, were selected as substrates by low- and high-Km components of mediated Na(+)-dependent transport in preimplantation mouse blastocysts. These and other relatively small anionic amino acids with two carbon atoms between the negatively charged groups (or up to three carbon atoms when the groups were both carboxyl groups) interacted strongly with the low-Km component of transport, whereas larger anionic amino acids interacted weakly or not at all. The low-Km system was also stereoselective except in the case of aspartate. Moreover, transport was Cl(-)-dependent and slower at pH values outside the range 5.6-7.4. L-Aspartate, D-aspartate and L-glutamate each interacted strongly with the low-Km component of transport with Km values for transport nearly equal to their Ki values for inhibition of transport of one of the other amino acids. By these criteria, the low-Km component of transport of anionic amino acids in blastocysts appears to be the same as the familiar system X-AG that is present in other types of mammalian cells. In contrast, the high-Km component of transport in blastocysts preferred L-aspartate to L-glutamate, whereas the reverse is true for fibroblasts. Therefore, transport of anionic amino acids in blastocysts may occur via at least one process that has not been described in other types of cells. Roughly half of mediated glutamate and aspartate transport in blastocysts may occur via the high-Km component of transport at the concentrations of these amino acids that may be present in uterine secretions.

Changing cation levels (Mg2+, Ca2+, Na+) alters the release of glutamate, GABA and other substances from the guinea pig cochlea

We examined the effects of changes in cation levels (increased Mg2+ concentration combined with low Ca2+ concentration, and two low concentrations of Na+) on the perilymph levels of gamma-aminobutyric acid (GABA), glutamate (Glu), aspartate (Asp) and other substances. Artificial perilymph solutions containing normal (5 mM) and high (50 mM) levels of K+ were perfused through the perilymphatic compartment of the guinea pig cochlea to examine basal release (5 mM K+) and depolarization-induced release (50 mM K+). Each of the two K+ concentrations were contained in four different solutions: [I] normal artificial perilymph (NARP; NaCl, 137 mM; CaCl2, 2 mM; MgCl2, 1 mM;); [II] high Mg2+ (20 mM)/low Ca2+ (0.1 mM) (HMgLCa); [III] low Na+ (117 mM; LNa), and [IV] very low Na+ (NaCl, 0 mM; VLNa). The effluent was collected and assayed for eighteen primary amines by HPLC. Compared with NARP, the HMgLCa group had an increase in the high K(+)-induced release of Asp and Glu with no change in GABA. VLNa increased the normal K+ levels of Asp, Glu and GABA up to those observed with high K+ in NARP. VLNa increased the high K+ levels of Asp and Glu over fivefold compared with the high K+ levels in NARP, but decreased GABA. We ascribe the results to an interference with either a Na(+)-dependent uptake processes or a Na+/Ca2+ exchange carrier.

Endogenous L-glutamate transport in oocytes of Xenopus laevis

The existence of an endogenous Na(+)-glutamate cotransporter in the oocytes of Xenopus laevis is demonstrated. The transporter does not accept D-glutamate as substrate. The dependence on substrate displays two saturating components with low (K1/2 = 9 mM) and high (K1/2 = 0.35 microM) affinities for L-glutamate. The dependence on external Na+ exhibits a saturating component with a K1/2 value of about 5 mM and a component that has not saturated up to 110 mM Na+. In voltage-clamped oocytes, it is possible to demonstrate that Na(+)-dependent L-glutamate transport is directly coupled to countertransport of Rb+. The analysis of the voltage dependence of the Na+,K(+)-dependent L-glutamate uptake suggests that positive charges are moved inwardly during the transport cycle.

The role of the placenta in nutrition of the human fetus

Bidirectional transport across the placenta provides substrates required for fetal nutrition and prevents accumulation of metabolites in the fetal compartment. Transmission of compounds across the placental barrier occurs by diffusion and carrier-mediated transport. The technique of dual in vitro perfusion of an isolated cotyledon has provided important data for the human placenta. The high degree of permeability for hydrophilic molecules was recently confirmed by in vivo measurements that allow estimates of flux across the human placenta for a number of compounds. The bidirectional nature in transplacental exchange requires asymmetry in flux from the maternal to the fetal side or vice versa, which can be assured by a concentration gradient or an active transport system. There is increasing evidence that placental metabolism with active modification of the composition of nutrients released to the fetus in addition to transport plays an important role.